ContentsACKNOWLEDGEMENT....................................................................................................................3

Authors..........................................................................................................................................3

DEDICATED TO..........................................................................................................................4

Our................................................................................................................................................4

Parents,.......................................................................................................................................4

Respected Teachers................................................................................................................4

&.....................................................................................................................................................4

INTRODUCTION..............................................................................................................................6

INRODUCTION................................................................................................................................7

Cement...........................................................................................................................................7

History........................................................................................................................................7

Development of strong concretes..................................................................................................9

Types of modern cement..............................................................................................................11

Hydraulic Cements.................................................................................................................11

Portland Cement.......................................................................................................................12

Portland Cement Blends.......................................................................................................12

Portland Blast Furnace Cement................................................................................................12

Portland Fly Ash Cement..........................................................................................................13

Portland Pozzolan Cement........................................................................................................13

Masonry Cements.....................................................................................................................13

Expansive Cements...................................................................................................................14

Non-Portland Hydraulic Cements............................................................................................14

Pozzolan-Lime Cements............................................................................................................14

Calcium Aluminate Cements.....................................................................................................15

Calcium Sulfoaluminate Cements.............................................................................................15

Natural Cements.......................................................................................................................15

Geopolymer Cements...............................................................................................................16

1

Environmental Impacts..........................................................................................................16

Chemical Composition of Portland Cement..................................................................................17

Properties of Major Constituents of Portland Cement...............................................................18

Minor Constituents.......................................................................................................................19

Gypsum (CaSO4.2H2O)...............................................................................................................19

Free Lime (CaO)........................................................................................................................19

Magnesia (MgO).......................................................................................................................20

Titanium Oxide (TiO2)................................................................................................................20

Phosphorus Pentoxide (P2O5)....................................................................................................20

Raw Materials...........................................................................................................................21

1-Lime Stone.............................................................................................................................21

2-Clay........................................................................................................................................21

Capacity Selection in Pakistan......................................................................................................22

Sector Overview.......................................................................................................................22

CEMENT INDUSTRY IN PAKISTAN..................................................................................................23

Pakistan Cement Market..............................................................................................................24

1-North.....................................................................................................................................24

2-South.....................................................................................................................................24

Cement Industry Growth..............................................................................................................26

Conversion................................................................................................................................27

Looking Into the Future................................................................................................................29

List of Cement Industries in Pakistan............................................................................................31

SURVEY OF SOME CEMENT INDUSTRIES IN PAKISTAN..................................................................32

SURVEY OF SOME CEMENT INDUSTRIES IN PAKISTAN................................................................33

1-Mapple Leaf Cement.............................................................................................................33

2-D.G Khan Cement Company Limited.....................................................................................33

3-Lucky Cement Limited...........................................................................................................33

4-Kohat Cement Company Limited...........................................................................................33

5-Pakistan Cement Company Limited.......................................................................................34

6-Fauji Cement Company Limited.............................................................................................34

Manufacturing Methods and Process Selection...........................................................................38

2

A-Wet Process..........................................................................................................................38

B-Dry Process............................................................................................................................38

Dry Process Versus Wet Process...................................................................................................39

Choice Of Process.....................................................................................................................40

MATERIAL BALANCE.....................................................................................................................41

MATERIAL BALANCE.....................................................................................................................42

QUALITY CONTROL FORMULAE...................................................................................................43

1. Silica Ratio:........................................................................................................................43

2. Lime Saturation Factor......................................................................................................43

3. Hydraulic Ratio.................................................................................................................43

4. Alumina Ratio:..................................................................................................................44

5. Burn Ability Index..............................................................................................................44

RAW MIX PREPARATION...........................................................................................................45

DRY RAW MIX COMPOSITION...................................................................................................47

RAW MATERIAL REQUIRED.......................................................................................................49

CLINKER COMPOSITION...............................................................................................................52

ENERGY BALANCE.........................................................................................................................53

ENERGY BALANCE.........................................................................................................................54

Input Heat Calculations.............................................................................................................54

Heat Input by Consumption of Fuel......................................................................................54

Heat Input As Sensible Heat In Fuel..........................................................................................54

2-Sensible Heat In Kiln Feed.....................................................................................................55

a-Dry Feed Required To Produced One Ton Clinker..............................................................55

b-Feed Water Present In Kiln Feed...........................................................................................55

3-Secondary Air Sensible Heat..................................................................................................56

Basis: 1 Ton of Coal.....................................................................................................................56

5. Primary Air Sensible Heat........................................................................................................58

Output Heat Calculation...............................................................................................................59

1) Heat of Reaction..................................................................................................................59

2) Heat Losses with Kiln Exit Gases...............................................................................................60

a. Exit gas from coal burning:-.................................................................................................60

3

B-Exit Gas From Kiln Feed.........................................................................................................61

c. Exit Gas Analysis (Excess Air).................................................................................................63

3. Heat Loss Due To Mixture in Raw Mix.....................................................................................64

4-Heat In Clinker At Kiln Discharge...............................................................................................65

Heat Loss Radiation And Convection............................................................................................65

Heat Balance Sheet.......................................................................................................................66

EQUIPMENT DESIGN.....................................................................................................................67

EQUIPMENT DESIGN.....................................................................................................................68

Kiln Design................................................................................................................................68

Calculation For The Diameter Of The Rotary Kiln..................................................................68

Calculation Of The Length Of The Rotary Kiln...........................................................................70

Basis: 6700 ton/day clinker..................................................................................................70

Kiln Slope..................................................................................................................................71

Degree Of The Kiln Filling..........................................................................................................71

Kiln filling degree fluctuates within the limits of about 5 – 17%. Independent from the kiln’s diameter............................................................................................................................71

Revolution Of The Rotary Kiln...................................................................................................72

Thermal Load Of The Cross – Section Of The Burning Zone..........................................................72

Residence Time.........................................................................................................................72

Thermal Expansion Of The Rotary Kiln......................................................................................73

a) Linear Expansion...................................................................................................................73

b) Expansion along Diameter....................................................................................................74

c) Expansion Along circumference............................................................................................74

Vertical Load Of Kiln.....................................................................................................................75

Horse Power Requirement Of The Rotary Kiln..............................................................................77

a-Load horse power..................................................................................................................77

Friction horse power.................................................................................................................77

CRUSHER.......................................................................................................................................79

PRINCIPLE OF CRUSHING..........................................................................................................79

Selection of Crushing Machinery..............................................................................................80

Selected Crusher Type..............................................................................................................80

Primary Crushing......................................................................................................................82

4

Jaw Crusher:.............................................................................................................................82

Overload Safety Device.............................................................................................................83

Speed Of Rotation.....................................................................................................................84

Calculation Of Speed Of Rotation.............................................................................................84

Capacity Of Jaw Crusher...........................................................................................................85

By LEWENSON..........................................................................................................................86

Drive Power For Jaw Crusher........................................................................................................87

Designing Of Raw Material Crusher.............................................................................................88

Motor For Feed Driving.............................................................................................................88

Crusher For Lime Stone Crushing..............................................................................................88

Motor For Driving Crusher........................................................................................................89

Motor For Driving Feeding Rolls...............................................................................................89

Belt Conveyor...........................................................................................................................89

Motor For Driving Belt..............................................................................................................89

Crusher Capacity.......................................................................................................................89

Crusher Capacity Required.......................................................................................................90

Crusher Hopper Capacity..........................................................................................................90

Feeder Capacity for Crusher.....................................................................................................90

Transportation from Crusher....................................................................................................91

Maximum Capacity of Dumpers...............................................................................................91

VERTICAL ROLLER MILL.................................................................................................................93

Grinding Action Developed In The Roller Mill...............................................................................94

Draw In Action Of The Grinding Element......................................................................................95

Grinding Bed Formation...............................................................................................................96

BALL MILL...................................................................................................................................111

The Critical Speed...................................................................................................................111

Dia Of The Ball Mill.................................................................................................................111

According to Tavrov’s formula................................................................................................111

Dynamic Angle Of Repose Of Grinding Balls...........................................................................113

Distribution Of Grinding Media In The Mill Cross Section.......................................................113

Degree Of The Ball Charge......................................................................................................113

5

Total Grinding Ball Charge......................................................................................................113

Grinding Ball Charge And Clinker Load...................................................................................114

According to Mardulier...........................................................................................................114

Ball Mill Power Demand.........................................................................................................114

Empirical formula for Ball Mill Power.....................................................................................114

Blanc’s formula.......................................................................................................................114

Bond’s Equation......................................................................................................................115

Apply Bond’s Equation............................................................................................................115

Site Selection..............................................................................................................................116

Site Selection..............................................................................................................................117

Raw Materials Availability.......................................................................................................117

Market....................................................................................................................................117

Energy Availability..................................................................................................................117

Climate....................................................................................................................................118

Transportation Facilities.........................................................................................................118

Water Supply..........................................................................................................................118

Waste Disposal.......................................................................................................................118

Labor Availability....................................................................................................................119

Taxation And Legal Restrictions..............................................................................................119

Site Characteristics.................................................................................................................119

Flood And Fire protection.......................................................................................................120

Community Factors.................................................................................................................120

PLANT SAFETY.............................................................................................................................121

PLANT SAFETY.............................................................................................................................122

OPERATIONAL SAFETY AND PRECAUTIONS............................................................................122

COST ESTIMAION........................................................................................................................124

COST ESTIMAION........................................................................................................................125

COST OF PRODUCTION...........................................................................................................125

Material..............................................................................................................................125

Labor.......................................................................................................................................125

Fuel.........................................................................................................................................126

6

Power.....................................................................................................................................126

Other Supplies:.......................................................................................................................127

Overhead Charges..................................................................................................................127

COST ESTIMATION OF PROJECT..................................................................................................128

PURCHASE EQUIPMENT COST....................................................................................................128

Purchased Equipment Cost.....................................................................................................128

PURCHASED EQUIPMENT COST..............................................................................................129

Purchased Equipment Cost.................................................................................................129

Total Direct Cost.........................................................................................................................130

Total Direct Cost = 9.075x109 Rs.....................130

Indirect cost................................................................................................................................131

Total Indirect Cost = 3.713x109 Rs................................................131

Total Capital Investment =Fixed Capital Investment + Working Capital Investment...........................................................................................................132

Cost of Production......................................................................................................................132

Fixed Cost...................................................................................................................................133

Market Price...............................................................................................................................133

Pay out Period of the Plant.........................................................................................................134

Instrumentation & Process Control............................................................................................135

Instrumentation And Process Control........................................................................................136

OBJECTIVES:............................................................................................................................136

Safe Plant Operations:............................................................................................................136

Production Rate:.....................................................................................................................136

Product Quality:......................................................................................................................136

Cost:........................................................................................................................................136

Hardware Elements Of Control System:.....................................................................................137

Process:..................................................................................................................................137

Measuring Elements:..............................................................................................................137

Transducers:...........................................................................................................................137

Transmission Lines:.................................................................................................................137

Controller:...............................................................................................................................137

Final Control Element:............................................................................................................138

7

Recorder:................................................................................................................................138

General Control Systems:...........................................................................................................138

Open Loop System:.................................................................................................................138

Closed Loop System:...............................................................................................................138

Feed back Control System:.....................................................................................................139

Forward Control System:........................................................................................................139

Combined Control System:.....................................................................................................139

Cascade Control System:........................................................................................................139

Modes Of Control:......................................................................................................................140

Proportional Control:..............................................................................................................140

Proportional Derivative Control:.............................................................................................140

Proportional Integral Control:.................................................................................................141

Proportional Integral Derivative Control:..........................................................................141

Typical Control System...............................................................................................................141

Recommended Thermocouple...................................................................................................142

For Kiln Process.......................................................................................................................142

Type – R..................................................................................................................................142

Temperature Indicator Controller:.........................................................................................142

Level Controller:.....................................................................................................................142

Pressure Controller:................................................................................................................142

Flow Controller:......................................................................................................................143

Alarm & Safety Tips:...............................................................................................................143

Interlocks:...............................................................................................................................143

THE LETTER CODES FOR INSTRUMENT SYSTEM.....................................................................144

NOTE:......................................................................................................................................145

ENVIROMENTAL PROTECTION & ENERGY UTILIZATION.........................................146

ENVIROMENTAL PROTECTION AND ENERGY UTILIZATION.......................................................147

ENVIROMENTAL PROTECTION IN THE CEMENT INDUSTRY.....................................................147

COST OF ENVIRONMENTAL PROTECTION...............................................................................148

ENVIROMENTAL PROTECTION AS A PROBLEM OF PLANT LOCATION:....................................148

IMPACT OF ENVIRONMENTAL STANDARDS ON ENERGY CONSIDERATION:.....................149

8

TECHNICAL AND MANAGERIAL IMPEDEMENTS FOR IMPROVING ENERGY EFFICIENCY.........150

FUTURE TREND IN ENERGY EFFICINCY AND SUGGESTIONS OF STRATEGIES...........................151

MODREN FOUR STAGE SUSPENTION PREHEATER KILN..........................................................152

EFFICIENT USE OF CEMENT IN CONCRETE..............................................................................153

SUGGESTIONS.............................................................................................................................154

INDUSTRIAL LEVEL..................................................................................................................154

NATIONAL LEVEL.....................................................................................................................155

Bibliography................................................................................................................................165

9

A PROJECT DESIGN REPORT ONPRODUCTION OF ORDINARY PORTLAND

CEMENT

Submitted to:BAHAUDDIN ZAKARIYA UNIVERISTY, MULTAN

In Partial Fulfillments of the Requirements for the Degree ofB.Sc. Chemical Engineering

Session: 2004-2008

Submitted by: Adnan Waheed 2K4-CHE-157

Supervised by:

Engr.Tariq MalikEngr. Najaf Ali Awan

INSTITUTE OF ENGINEERING & TECHNOLOGICAL TRAININGNFC IET MULTAN

10

ACKNOWLEDGEMENT In the name of ALLAH, the all Corroborate Possessor of Majesty and

Splendor, the Omnipresent, The whole benevolent and ever merciful. Who’s

generosity and magnificence able us to complete to make this humble

contribution to already existing ocean of knowledge.

All praises to his last messenger Hazrat Muhammad (Peace Be Upon

Him) who is a source of guidance and knowledge for humanity as a whole is an

ever inspiring for all the learned personals by the order of ALLAH almighty.

In presenting this design report of production of Ordinary Portland Cement

6700 MTPD,we express our heart felt thanks to our project advisor, Engr. Tariq Malik and Engr. Najaf Ali Awan for his guidance, valuable suggestions and

constructive criticism in preparation of this design report.

We are grateful to our director Dr. M. Afzal Haque for providing us all the

facilities and encouragement regarding this project.

Our acknowledgment is also due to our Head of Chemical Engineering

Department Syed Nasir Abbas Abdi, for all his full moral support as well as his

helpful suggestions whenever needed.

The authors also express their appreciation to Cement Research Institute & Development Center and D.G.Khan Cement Company Limited for

helping us in taking difficult data and values of this project faced by us time to

time.

Authors

11

12

DEDICATED TOOur

Parents,Respected Teachers

&Sincere Friends

13

INTRODUCTION

INRODUCTION

Cement “Portland cement is the product obtained by finely

pulverizing clinker produced by calcining to incipient fusion and intimate

and properly proportioned mixture of agrillaceous and calcareous

materials.”

14

In the most general sense of the word, cement is a binder, a substance

which sets and hardens independently, and can bind other materials

together. The name "cement" goes back to the Romans who used the term

"opus caementitium" to describe masonry which resembled concrete and

was made from crushed rock with burnt lime as binder. The volcanic ash

and pulverized brick additives which were added to the burnt lime to obtain

a hydraulic binder were later referred to as, cimentum, cäment and

cement. Cements used in construction are characterized as hydraulic or

non-hydraulic.

The most important use of cement is the production of mortar and concrete

- the bonding of natural or artificial aggregates to form a strong building

material which is durable in the face of normal environmental effects.

History The earliest construction cements are as old as construction,

and were non-hydraulic. Wherever primitive mud bricks were used, they

were bedded together with a thin layer of clay slurry. Mud-based materials

were also used for rendering on the walls of timber or "wattle and daub"

structures. Lime was probably used for the first time as an additive in these

renders, and for stabilizing mud floors. A "daub" consisting of mud, cow

dung and lime produces a tough and water-proof coating, due to

coagulation, by the lime, of proteins in the cow dung. This simple system

was common in Europe until quite recent times. With the advent of fired

bricks, and their use in larger structures, various cultures started to

experiment with higher-strength mortars based on bitumen (in

Mesopotamia), gypsum (in Egypt) and lime (in many parts of the world).

It is uncertain where it was first discovered that a combination of hydrated

non-hydraulic lime and a pozzolan produces a hydraulic mixture, but

15

concrete made from such mixtures was first used on a large scale by the

Romans. They used both natural pozzolans (trass or pumice) and artificial

pozzolans (ground brick or pottery) in these concretes. Many excellent

examples of structures made from these concretes are still standing,

notably the huge monolithic dome of the Pantheon in Rome. The use of

structural concrete disappeared in medieval Europe, although weak

pozzolanic concretes continued to be used as a core fill in stone walls and

columns.

Modern hydraulic cements began to be developed from the start of the

Industrial Revolution (around 1700), driven by three main needs:

Hydraulic renders for finishing brick buildings in wet climates

Hydraulic mortars for masonry construction of harbor works etc, in contact

with sea water.

Development of strong concretes In Britain particularly, good quality building stone became ever more

expensive during a period of rapid growth, and it became a common

practice to construct prestige buildings from the new industrial bricks, and

to finish them with a stucco to imitate stone. Hydraulic limes were favored

for this, but the need for a fast set time encouraged the development of

new cements. Most famous among these was Parker's "Roman cement".

This was developed by James Parker in the 1780s, and finally patented in

16

1796. It was, in fact, nothing like any material used by the Romans, but

was”Natural cement" made by burning septaria - nodules that are found in

certain clay deposits, and that contain both clay minerals and calcium

carbonate. The burnt nodules were ground to a fine powder. This product,

made into a mortar with sand, set in 5-15 minutes. The success of "Roman

Cement" led other manufacturers to develop rival products by burning

artificial mixtures of clay and chalk.

John Smeaton made an important contribution to the development of

cements when he was planning the construction of the third Eddystone

Lighthouse (1755-59) in the English Channel. He needed a hydraulic

mortar that would set and develop some strength in the twelve hour period

between successive high tides. He performed an exhaustive market

research on the available hydraulic limes, visiting their production sites,

and noted that the "hydraulicity" of the lime was directly related to the clay

content of the limestone from which it was made. Smeaton was a civil

engineer by profession, and took the idea no further. Apparently unaware

of Smeaton's work, the same principle was identified by Louis Vicat in the

first decade of the nineteenth century. Vicat went on to devise a method of

combining chalk and clay into an intimate mixture, and, burning this,

produced”artificial cement" in 1817. James Frost, working in Britain,

produced what he called "British cement" in a similar manner around the

same time, but did not obtain a patent until 1822. In 1824, Joseph Aspdin

patented a similar material, which he called Portland cement, because the

render made from it was in color similar to the prestigious Portland stone.

All the above products could not compete with lime/pozzolan concretes

because of fast-setting (giving insufficient time for placement) and low

early strengths (requiring a delay of many weeks before formwork could be

removed). Hydraulic limes, "natural" cements and "artificial" cements all

17

rely upon their belite content for strength development. Belite develops

strength slowly. Because they were burned at temperatures below 1250°C,

they contained no alite, which is responsible for early strength in modern

cements. The first cement to consistently contain alite was that made by

Joseph Aspdin's son William in the early 1840s. This was what we call

today "modern" Portland cement. Because of the air of mystery with which

William Aspdin surrounded his product, others (e.g. Vicat and I C Johnson)

have claimed precedence in this invention, but recent analysis of both his

concrete and raw cement have shown that William Aspdin's product made

at North fleet, Kent was a true alite-based cement. However, Aspdin's

methods were "rule-of-thumb": Vicat is responsible for establishing the

chemical basis of these cements, and Johnson established the importance

of sintering the mix in the kiln.

William Aspdin's innovation was counter-intuitive for manufacturers of

"artificial cements", because they required more lime in the mix (a problem

for his father), they required a much higher kiln temperature (and therefore

more fuel) and because the resulting clinker was very hard and rapidly

wore down the millstones which were the only available grinding

technology of the time. Manufacturing costs were therefore considerably

higher, but the product set reasonably slowly and developed strength

quickly, thus opening up a market for use in concrete. The use of concrete

in construction grew rapidly from 1850 onwards, and was soon the

dominant use for cements. Thus Portland cement began its predominant

role.

18

Types of modern cementHydraulic Cements Hydraulic cements are materials which set and harden after

combining with water, as a result of chemical reactions with the mixing

water and, after hardening, retain strength and stability even under water.

The key requirement for this is that the hydrates formed on immediate

reaction with water are essentially insoluble in water. Most construction

cements today are hydraulic, and most of these are based upon Portland cement, which is made primarily from limestone, certain clay minerals, and

gypsum, in a high temperature process that drives off carbon dioxide and

chemically combines the primary ingredients into new compounds. Non-

hydraulic cements include such materials as (non-hydraulic) lime and

gypsum plasters, which must be kept dry in order to gain strength, and

oxychloride cements which have liquid components. Lime mortars, for

example, "set" only by drying out, and gain strength only very slowly by

absorption of carbon dioxide from the atmosphere to re-form calcium

carbonate.

Setting and hardening of hydraulic cements is caused by the formation of

water-containing compounds, forming as a result of reactions between

cement components and water. The reaction and the reaction products are

referred to as hydration and hydrates or hydrate phases, respectively. As a

result of the immediately starting reactions, a stiffening can be observed

which is very small in the beginning, but which increases with time. After

reaching a certain level, this point in time is referred to as the start of

setting. The consecutive further consolidation is called setting, after which

the phase of hardening begins. The compressive strength of the material

then grows steadily, over a period which ranges from a few days in the

19

case of "ultra-rapid-hardening" cements, to several years in the case of

ordinary cements.

Portland CementPortland cement is the most common type of cement in general

usage, as it is a basic ingredient of concrete, mortar and most non-

speciality grout. The most common use for Portland cement is in the

production of concrete. Concrete is a composite material consisting of

aggregate (gravel and sand), cement, and water. As a construction

material, concrete can be cast in almost any shape desired, and once

hardened, can become a structural (load bearing) element.

Portland Cement BlendsThese are often available as inter-ground mixtures from cement

manufacturers, but similar formulations are often also mixed from the

ground components at the concrete mixer.

Portland Blast Furnace Cement It contains up to 70% ground granulated blast furnace slag, with the

rest Portland clinker and a little gypsum. All compositions produce high

ultimate strength, but as slag content is increased, early strength is

reduced, while sulfate resistance increases and heat evolution diminishes.

Used as an economic alternative to Portland sulfate-resisting and low-heat

cements.

Portland Fly Ash Cement It contains up to 30% fly ash. The fly ash is pozzolanic, so that

ultimate strength is maintained. Because fly ash addition allows a lower

20

concrete water content, early strength can also be maintained. Where

good quality cheap fly ash is available, this can be an economic alternative

to ordinary Portland cement.

Portland Pozzolan Cement It includes fly ash cement, since fly ash is a pozzolan, but also

includes cements made from other natural or artificial pozzolans. In

countries where volcanic ashes are available (e.g. Italy, Chile, Mexico, and

the Philippines) these cements are often the most common form in use.

Portland Silica Fume cement

Addition of silica fume can yield exceptionally high strengths, and cements

containing 5-20% silica fume are occasionally produced. However, silica

fume is more usually added to Portland cement at the concrete mixer.

Masonry Cements These are used for preparing bricklaying mortars and stuccos, and

must not be used in concrete. They are usually complex proprietary

formulations containing Portland clinker and a number of other ingredients

that may include limestone, hydrated lime, air entertainers, retarders, water

proofers and colouring agents. They are formulated to yield workable

mortars that allow rapid and consistent masonry work. Subtle variations of

Masonry cement in the US are Plastic Cements and Stucco Cements.

These are designed to produce controlled bond with masonry blocks.

Expansive Cements These contain, in addition to Portland clinker, expansive clinkers

(usually sulfoaluminate clinkers), and are designed to offset the effects of

21

drying shrinkage that is normally encountered with hydraulic cements. This

allows large floor slabs (up to 60 m square) to be prepared without

contraction joints.

Non-Portland Hydraulic CementsPozzolan-Lime Cements

Mixtures of ground pozzolan and lime are the cements used by the

Romans, and are to be found in Roman structures still standing (e.g. the

Pantheon in Rome). They develop strength slowly, but their ultimate

strength can be very high. The hydration products that produce strength

are essentially the same as those produced by Portland cement. Slag-lime

cements

Ground granulated blast furnace slag is not hydraulic on its own, but is

“activated” by addition of alkalis, most economically using lime. They are

similar to pozzolan lime cements in their properties. Only granulated slag

(i.e. water-quenched, glassy slag) is effective as a cement component.

Super sulfated cements

These contain about 80% ground granulated blast furnace slag, 15%

gypsum or anhydrite and a little Portland clinker or lime as an activator.

They produce strength by formation of ettringite, with strength growth

similar to a slow Portland cement. They exhibit good resistance to

aggressive agents, including sulfate.

Calcium Aluminate Cements These are hydraulic cements made primarily from limestone and

bauxite. The active ingredients are monocalcium aluminate CaAl2O4 (CA in

22

Cement chemist notation) and Mayenite Ca12Al14O33 (C12A7 in CCN).

Strength forms by hydration to calcium aluminate hydrates. They are well-

adapted for use in refractory (high-temperature resistant) concretes, e.g.

for furnace linings.

Calcium Sulfoaluminate Cements These are made from clinkers that include ye’elimite (Ca4 (AlO2)6SO4

or C4A3 in Cement chemist’s notation) as a primary phase. They are used

in expansive cements, in ultra-high early strength cements, and in "low-

energy" cements. Hydration produces ettringite, and specialized physical

properties (such as expansion or rapid reaction) are obtained by

adjustment of the availability of calcium and sulfate ions. Their use as a

low-energy alternative to Portland cement has been pioneered in China,

where several million tonnes per year are produced. Energy requirements

are lower because of the lower kiln temperatures required for reaction and

the lower amount of limestone (which must be endothermically

decarbonated) in the mix. In addition, the lower limestone content and

lower fuel consumption leads to a CO2 emission around half that

associated with Portland clinker. However, SO2 emissions are usually

significantly higher.

Natural Cements These correspond to certain cements of the pre-Portland era,

produced by burning argillaceous limestone at moderate temperatures.

The level of clay components in the limestone (around 30-35%) is such

that large amounts of belite (the low-early strength, high-late strength

mineral in Portland cement) are formed without the formation of excessive

23

amounts free lime. As with any natural material, such cements have very

variable properties.

Geopolymer Cements These are made from mixtures of water-soluble alkali silicates and

aluminosilicate mineral powders such as metakaolin.

Environmental ImpactsCement manufacture causes environmental impacts at all stages of

the process. These include emissions of airborne pollution in the form of

dust, gases, noise and vibration when operating machinery and during

blasting in quarries, consumption of large quantities of fuel during

manufacture, release of CO2 from the raw materials during manufacture,

and damage to countryside from quarrying. Equipment to reduce dust

emissions during quarrying and manufacture of cement is widely used, and

equipment to trap and separate exhaust gases are coming into increased

use. Environmental protection also includes the re-integration of quarries

into the countryside after they have been closed down by returning them to

nature or re-cultivating them.

Cement manufacture can also provide environmental benefits by using

wastes from certain other industries, including slag from steel manufacture,

fly ash from coal burning, silica fume from silicon and ferrosilicon

manufacturing, and sometimes recycled concrete from demolition of older

structures.

Chemical Composition of Portland CementPortland cement consists of mainly lime (CaO), silica (SiO2), alumina

(Al2O3), and iron oxide (Fe2O3). The combined content of the four oxides is

approximately 90% of the cement weight and they are generally referred as the

24

‘major oxide’. The remaining 10% consists of magnesia (MgO), alkali oxides

(Na2O and K2O), Titania (TiO2), phosphorus pentaxide (P2O5), and gypsum (A few

percent of gypsum is added during grinding to regulate the setting time of the cement).

These are referred to as ‘minor constituents’. An idea of the composition of present-day,

Portland cement can be obtained from the approximate limits in the following table.

OXIDE

CaO

SiO2

Al2O3

Fe2O3

MgO

Na2O + K2O

TiO2

P2O5

SO3

COMPOSITION (WT %)

60-67

17-25

3-8

0.5-6.0

0.1-5.5

0.5-1.3

0.1-0.4

0.1-0.2

1-3

Properties of Major Constituents of Portland Cement Compound Alite Belite --------

Celite

Chemical Tricalcium silicate Dicalcium silicate Tricalcium aluminate

tetracalcium

Formulae 3CaO.SiO2 (C3S) 2 CaO.SiO2. (C2S) 3CaO.Al2O3(C3A)

aluminoferrite

25

55% 10-19% 5-12%

4CaO.Fe2O3.Al2O3

2-8%

Rate of Rapid (hours) Slow (days) Instantaneous very

rapid

Hydration

(minutes)

Strength Rapid (days) Slow (weeks) Very rapid very

rapid

Development (one day) (one

day)

Ultimate high probably high Low Low

Strength

Heat of Medium: Low: very high:

Medium:

Hydration 500 j/g 250 j/g 850j/g 420

j/g

Remarks Characteristic unstable in water, imparts

to the

Constituent of Portland sensitive to sulphate cement

its

Cements attack

characteristic

Color Grey

Minor Constituents

Gypsum (CaSO4.2H2O)Gypsum is added during grinding of the clinker in order to regulate

the setting time of the cement. There is an optimum gypsum content which

imparts to the cement maximum strength and minimum shrinkage, and this

optimum depends on the alkali oxides and C3A contents of the cement and

on its fineness.

26

On the other hand, the gypsum content must be limited because an excess

may cause cracking and deterioration in the set cement. This adverse

effect is due to the formation of ettringite (C3A.3CaSO4.31H2O) resulting

from reaction between gypsum and C3A.

Free Lime (CaO)The presence of free (uncombined) lime in the cement may occur

when the raw materials used in the manufacturing process contain more

lime than can combined with the acidic oxides SiO2, Al2O3, and Fe2O3.

Alternatively, free lime may occur when the amount of lime in the raw

materials is not excessive, but when its reaction with the oxides is not

complete after the clinkering process due to coarse raw meal and low heat

input.

Magnesia (MgO)The raw material for the cement usually contains a certain amount of

MgCO3 which on burning dissociates to magnesium oxide and carbon

dioxide. The magnesia does not combine with the major oxides. Some of it

is taken up in solid solution in the clinker material, and the remainder

crystallizes as periclase (MgO).

Alkali Oxides (K2O, Na2O)

27

The alkali oxides are introduced into the cement through the raw

materials and their content varies from 0.5% to 1.3%. On burning, the

alkali oxides combine, usually, with sulfur trioxide (SO3) giving a solid

solution of sodium potassium sulfate which tends to have the approximate

composition 3K2SO4. Na2SO4.

Titanium Oxide (TiO2)Titania (TiO2) occurs in the cement to a small extent and its content

varies from 0.1% to 0.4%. The titamia is introduced onto the cement

through the clay of the shale used in its manufacture.

Phosphorus Pentoxide (P2O5)The (P2O5) is usually introduced into the cement through the

limestone used in its manufacture. Its presence slower the cement

hardening because it breaks down the C3S to C2S, which contains the

(P2O5) in solid solution and CaO.

Raw MaterialsTwo types of raw materials are necessary for the production of

Portland cement, one rich in calcium such as limestone, and one rich in

silica such as clay.

1-Lime StoneCalcium carbonate (CaCO3) is wide spread in nature. Calcium

carbonate of all geological formations qualifies for the production of

28

Portland cement. The purest grades of lime stone are calspar (calcite) and

aragonite. Calcite crystallizes hexagonally and aragonite is rhombic. The

specific gravity of calcite is 2.7 and of aragonite are 2.95. The hardness of

lime stone depends on its geological age. The hardness of limestone is

between 1.8 and 3.0 of the Moh’s scale of hardness. Only the purest

varieties of lime are white.

Lime stone usually contains admixtures of clay substance, iron and

aluminum compounds, which influence its colour. In cement raw material

the lime component is generally represented up to an amount of 74-80%.

2-ClayClay is another raw material for cement manufacturing. Clay is

formed by the weathering of alkali and alkaline earth containing aluminum

silicates and of their chemical conversion products, mainly feldspar and

mica. The main component of clay is formed by hydrous aluminum

silicates.

Iron hydroxide is the principal colouring agent in clays; also organic

matter may give the clay with different colors. Clays with no impurities are

white. In addition to natural raw material some plants use slag and

precipitated carbonated obtained as by product from ammonium sulfate

industry Sand, waste bauxite and iron ore is some time used in small

amount to adjust the composition of the mixture.

Gypsum is added to regulate the setting time of the cement.

Capacity Selection in Pakistan

29

Sector OverviewThere are 29 cement production units in the country. Upto May

2007, the total installed cement production capacity is 36.841 million tones.

By the end of June 2011, the installed cement capacity will touch to the

level of 49.597 million tones.

Due to political instability and lack of allocation of funds for public

sector development program, cement industry of Pakistan was in the

recession phase had registered an average growth rate of 2.96% for the

period from 1990 to 2002. For the period from 2003 to 2007 cement

industry of Pakistan had registered an average growth rate of 20%. The

boost in cement sector is because of the rising construction activity in the

country, reconstruction activity in Afghanistan and increasing development

expenditure by the government. Construction of dames and export of

cement in the future will also increase the demand of Cement in Pakistan.

So to meet the future demand of the cement in Pakistan 6700 ton per day capacity (the minimum feasible) plant should be designed.

CEMENT INDUSTRY IN PAKISTAN

The Cement industry of Pakistan plays a vital role in the socio

economic development of the country. The development of cement

sector has made rapid strides, both in public and private sectors

during the last two decades. At the time of independence there were

only four units in the county having the capacity of 470,000 tons per

annum. These units were located at Karachi, Rohr, Wan, and Dandot.

30

The country at present has almost attained self-sufficiency in the

supply of cement with very little imports whatsoever during the last

few years.

But now, it has exceeded 36.841 million tones per anima as a

result of establishment of new manufacturing facilities and expansion

by the exiting units. Privatization and effective price decontrol in

1991-92 hearted a new era in which the industry has research a level

where surplus production after meeting local demand is expected in

2006.

The competitive environment, in the cement sector contributes

to the common benefits of the industry and the end users. Infect, the

framework of mixed economy is today truly evidence in cement sector

leading to the maximization of social and economic advantages.

The cement industry in Pakistan faces two serious threats:

closure of units based on the wet process. And the poor cash flow

rendering the units in capable of debts servicing due to the increasing

cast of electricity and furnace oil.

Pakistan has remained a net importer of the cement but due to the

privatization of the units operating under state control and

subsequent expansion programs by the new owners supported by

financial institution has pushed the industry to a point where the

country is bound to reach an oversupply situation. However, the

recent increase in the energy cast provides opportunity sustain the

situation for a relatively longer period. It would be possible because

31

the expansion by the existing units and establishment of new units

are being delayed.

Pakistan Cement MarketPakistan’s cement market is divided into two distinct regions.

1-North

2-South

1-NorthThe northern region comprises the entire province of Punjab, NWFP, Azad

Kashmir and upper parts of Balochistan, whereas the southern region

comprises the entire province of Sindh and some parts of Balochistan.

2-SouthTraditionally, the southern region has always been surplus in cement

production but with the establishment of more plants in the northern parts

of the country the regions has become almost sufficient in the supply of

cement.

Demand Vs SupplyThe demand supply gap which for the decade was in favour of

manufactures is now set to switch the other way with supply outpacing

demand by the end of 2006. Historically the demand has grown at an

average rate of 22.74% in the northern region while 22.65% in the

Southern region. There is much pessimism about the industry, future due

to the tremendous increase in supply expected by the end of next year.

32

The way new plants are being established and existing plants are

undertaking expansion, the demand supply equation is creating surpluses.

However, it has been observed that actual progress is slower than planned

to avoid a possible glut situation. This will effectively narrow down the gap

between demand and supply and thereby, ease the pressure on prices.

Factors that can possible change the surplus position into the near

equilibrium between the demand and supply are:

1. Formation of manufacturer’s cartel to avoid price decline.

2. Delay in implementation of planned additions and expansions.

3. Efforts to export cement.

4. Increase in demand if construction of some of the mega-sized

infrastructure project starts.

More CompetitionAs the cement market is moving from virtual “sellers” market to an

oversupply situation, it is expected that when prices stagnate and

profitability becomes a function of volume and economics of scale, location

advantages and proximity to markets will become extremely important

factors.

At present the freight charges are a massive 20% of the retail prices. The

plants located very close to each other and tapping the same market will

have to expand their markets, which will increase their freight expenses.

33

Dandot, pioneer, Mapple Leaf and Gharibwal are all located with in a

radious of 100 kilometers and are selling bulk of their production in the

same areas and will this face serious competition from each other.

Cement Industry Growth With the resurgence in demand, improvement at retention

level, coal conversion and debt restructuring, cement industry has entered

the era of improving profitability. With growth of the economy being linked

to infrastructure development, special emphasis was being paid to the

construction sector. The prospects of economic growth and construction

sector are being linked to each other.

Presently, a number of factors are attributed to this tremendous growth

represented by various indicators. Cement exports, mainly to Afghanistan

doubled during the three quarter period of the current years, Attaining a

level of 0.78 millions tones, but that accounts of only 8% of the total

production.

For a third world country like Pakistan in the process of development,

cement is very a very important commodity. The number of cement plants

and their production volume gives an indication of the stage of the

development in the country.

The cement industry in Pakistan, with a fixed investment of over 79 billion

rupees has started recovering at an increased pace after waging a long

struggle to survive. Domestic demand for cement, which was 66% of

capacity last year, was expected to reach over 92-95% by the end of

current financial year. But it surpassed the expectations and is already

34

utilizing 92-95% capacity due to unprecedented increase in demand of

cement. These phenomena generated optimism about the future prospects

of the cement industry in the country.

The government plays a vital role in the development of infra structure, it is

important for steering the economy towards accelerated growth. The

economy is now poised to take off, in the backdrop of all the positive

indicators. The government is also trying its utmost to bring local and

foreign investment in the different sectors of the economy. In order to

attract new investment for industrialization, substantial fiscal incentives

have been offered by the government to improve infra structure, which

would be huge quantities of cement.

ConversionConversion from furnace oil plants to coal firing system has already

taken place in majority of the cement processing units, which have started

getting high benefits, but they are also reluctant to pass on the benefits to

the consumer on the pretext that the industry has suffered great losses in

the past due to the high prices of furnace oil hence unless the losses of the

past are recovered they are not in the position to pass on the benefits of

end users. On the contrary, the experience shows that when ever the

prices of oil were increased the traditional cast was always passed on to

the consumers.

The conversion of furnace oil plants to coal fired the production cost of the

company resulting in the improved bottom-line. It is reported that the

domestic coal is not a very high quality how ever the processing and

35

blending the local coal with the imported one can produce required heating

content that is much cast –effective than the furnace oil.

End users would also be given their due share in the larger interest of the

economy, because reduction in price means increase in economic activity.

The cement industry has benefited a lot by shifting towards dry process.

Installation of electrostatic precipitators and preheaters, automation of

processes and installation of online analyzer which has resulted in

environmentally better and energy efficient industries. The production of

cement is high-energy intensive process. The cement manufacturers that

have utilized 100% of their installed production capacity are busy in the

rebottling process to further enhance their capacities. They require

upgrading of certain portions their production process to increase their

capacity. This might add one million in cement production capacity of the

country it would however come under pressure by 2007 planned additional

capacity would be operational.

However cement demand from PSDP is directly linked to actual

government spending on mega projects where the work on mega projects

where the work on mega projects remains slow and the government

however has not made any announcement regarding the construction of

any mega dam project.

Looking Into the Future

The radical change in the fuel system that from furnace oil to coal

and the increase in demand for cement has lifted the spirits of the industry

36

in fact in a sense plays the role of a mother industry if all the development

of infrastructure base of the country is taken into account. The increase in

consumption also pushes the economic activity. Besides encouraging

increase in cement consumption through positive policies and use the

cement in large public sector projects, this strong industrial sector

deserves incentives through considerable relaxation in the government

levies to make it competitive in the export market.

Besides current export trend to Afghanistan which has injected a

new life in our sick cement industry, there were ample scope of export in

the countries like Bangladesh where annual demand for cement is

estimated 5 million tons a year, Sri Lanka 3 million tons, Singapore 5

million tons, Egypt 4 million tons, Myanmar 1million tons, Vietnam 1 million

tons, Malaysia 2 million tons and Nepal 0.5 million tons All these countries

are not the producers of cement and meet their cement needs through

imports.

Another factor to keep this sector vibrant is to use cement in the

construction of huge national project of Gawader port in Balochistan,

Karachi-Makran coastal highways. The use of cement in huge network of

irrigation canals and new projects contributing in bridging the gap bet

demand and supply in cement network.

The cement outlook for cement industry looks positive. The capacity

utilization in the current year has improved due to increase in demand. The

earning of cement sector will show further growth in the fourth quarter

ending June, 30 owing to better retention prices, improved volume and

stable to declining production cost.

37

List of Cement Industries in Pakistan

1-D.G Khan Cement Company Limited2-Dandot Cement Company Limited

38

3-Gharibwal Cement Limited4-Javedan Cement Company Limited5-Mustehkam Cement Limited6-National Cement Industries Limited7-Pioneer Cement Limited8-Thatta Cement Company Limited9-Zeelpak Cement Industries10-State Cement Corporation of Pakistan Limited11-Bestway Cement Limited12-Cherat Cement Company Limited13-Dadabhoy Cement Industries14-Essa Cement Industries15-Fecto Cement Limited16-Galadari Cement (Gulf) Limited17-Haryana Asbestos Cement Industries Limited18-Anwarzaib White Cement Limited19-Associated Cement Rohri Limited20-Nizampur Cement Plant 21-Pakistan Slag Cement Industries Limited22-Sakhi Cement Limited23-White Cement Industries Limited24-Mapple Leaf Cement25-Askari Cement Limited26-Lucky Cement 27-Kohat Cement Company Limited28-Pakistan Cement Company Plant29-Fauji Cement Company Plant

39

SURVEY OF SOME CEMENT

INDUSTRIES IN PAKISTAN

40

SURVEY OF SOME CEMENT INDUSTRIES IN PAKISTAN

The cement industries in Pakistan are:-

1-Mapple Leaf Cement 2-D.G Khan Cement3-Lucky Cement4-Kohat Cement Company Limited5-Pakistan Cement Company Plant 6-Fauji Cement Company Plant

1-Mapple Leaf CementPlant Capacity: 6,700 + 5,000 (TPD) plantPlant Location: Located in Daudkhel District Mianwali at Northern PakistanProducts: Ordinary Portland Cement White Cement Sulfate Resisting Cement Low Alkali Oil Well Cement

2-D.G Khan Cement Company LimitedPlant Capacity: 6,700(TPD) plantPlant Location: Located In Dera Ghazi Kahar, District Punjab, Pakistan Products: Ordinary Portland Cement Sulfate Resisting Cement

3-Lucky Cement LimitedPlant Capacity: 4,200(TPD) plantPlant Location: Located In Mian Indus Highway, Pezu District Lucky Marwat, N.W.F.P Products: Ordinary Portland Cement Sulfate Resisting Cement Slag Cement

4-Kohat Cement Company LimitedPlant Capacity: 6,700(TPD) plant

41

Plant Location: Located at Kohat, Pakistan Products: White Cement (Kohat Super White) Grey Cement

5-Pakistan Cement Company Limited

Plant Capacity: 6,000(TPD) plantPlant Location: Located at Kalar Kahar, District Chakwal, Punjab, Pakistan Products: Ordinary Portland Cement Sulfate Resisting Cement

6-Fauji Cement Company Limited

Plant Capacity: 7,200(TPD) plantPlant Location: Located at Jhang Bahtar, Tehsil Fateh Jhang, District Attock, Punjab, Pakistan Products: Ordinary Portland Cement

42

Cement:- The product obtaining by calcining the intimate and proper proportionate mixture of argillaceous and calcareous material to produce clinker and then adding gypsum to it.

Raw Materials

1-CalcareousA-LimestoneB-Chalk

2-AgrillaceousA-ClayB-ShaleC-SlateD-Gypsum

Manufacturing Process:- There are two (2) processes for manufacturing of cement.

1-Dry Process2-Wet Process

Manufacturing Steps:-

1-Crushing & grinding of raw material2-Storage of raw material3-Correction Vats4-Kiln Feeder5-Rotary Kiln6-Collection of Clinker7-Grinding Of Clinker with gypsum8-Packing & Storage

43

44

45

Manufacturing Methods and Process Selection

Two fundamental methods are known for the preparation of the feed for

rotary kilns:

a. The Wet Process; slurry with a water content of approximately 18 – 45%

is prepared in wash mills or by wet grinding.

b. The Dry Process, where the dry state of the raw material components is

exploited to prepare the raw mix.

A-Wet Process1. The long wet process rotary kiln with internal heat exchangers such as

chains, segments of other arrangements.

2. The short wet process rotary kiln without internal installation, working in

conjunction with a heat exchanger for partial drying of the slurry. These

heat exchangers are known under the terms “slurry dryers”,

“concentrator”, “calcinatory”.

3. The medium long wet process rotary kiln with preliminary mechanical

dewatering of the slurry by suction or pressure filters. For disintegration

and final drying of the filter cake fed into the rotary kiln with a moisture

content of 15 – 20%, the kiln is furnished with a short chain section.

4. The short wet process rotary kiln without internal installation with

mechanical preliminary dewatering of the slurry. The resulting filter cake is

then processed to nodules. These are fed into a preheater , or to a heat

exchanger grate.

B-Dry Process1. The long dry process rotary kiln without internal installation.

46

2. The long dry process rotary kiln with internal heat exchangers, such as

chains, refractory bridges, etc.

3. The short dry process rotary kiln working in conjunction with preheaters,

such as suspension preheaters.

4. The dry process rotary kiln with waste boiler.

Dry Process Versus Wet Process The basic advantage of the dry production method over the wet

process is the lower specific heat consumption for clinker burning.

When deciding which production method to select for a new project, it

should be realized that there is no general valid rule, because of the

absence of a uniform method for a comparable appraisal of the

effectiveness of both production methods, and consequently the

impossibility of proving unequivocally the superiority of one over the

other method.

For this purpose, Expert developed a formula which tells in what case

the wet or dry process can be economically applied. However, the

factors used in this formula are based on charge prices of the

socialistic planned economy, and are therefore not applicable in the

domain of the competitive economy.

Previously, clinker produced by the wet method was considered to be

of higher quality and uniformity, because of the better homogenization

of the raw components in the state of slurry. Now, highly sophisticated

pneumatic homogenizing machinery and methods for dry raw mix,

allow the preparation of the raw mix with the same degree of uniformity

as raw mix prepared by the wet method. There is no difference in the

quality of the clinker.

Proportioning of dry raw material components to the required

composition is much easier than proportioning of moist, wet or plastic

raw material component. It is known that grinding of slurry requires a

lower grinding cost. When grinding the same material to the same

47

fineness, dry grinding requires approximately 30% more energy than

wet grinding. However, this advantage is neutralized by the fact that

the dry grinding wear rate of mill liners and grinding media is only 30 –

40 % of the wet grinding wear rate. Thus the higher wet grinding wear

rate offsets the cost of higher energy consumption of dry grinding of

the raw mix.

A wet process cement plant requires about 20% more silo volume for

slurry storage, compared to the raw mix silo volume of a dry process

cement plant with equal capacity.

A conventional heat consumption figure for the wet production process

is 860,000 Btu/bbl of clinker, whereas the heat consumption figure for

the dry process suspension pre heater kiln is roughly 529,000 Btu/bbl;

the difference is 331,000 Btu/bbl in favor of the dry process. For

example, using an average price of $ 0.35 per million Btu (1000 cf of

natural gas), and an assumed plant capacity of 3,850,000 bbl/year, we

get $ 447,000 saving per year on fuel.

The volume of kiln exit gases per bbl of clinker in the dry production

process is 529 cf natural gas X 12 = 6348 scf combustion gases plus

1815 scf carbon dioxide form raw mix, thus a total of 8163 scf/bbl.

The gas volume for the wet process is 860 cf gas X 12 = 10,320 scf

combustion gases, plus 1815 scf carbon dioxide, plus 323 lb water X

20 =6460 scf water vapor from slurry . The total volume of kiln exit

gases for the wet process is 18,595 scf, thus 18,595 – 8163 = 10,432

scf/bbl of clinker more than at the dry process.

48

Choice Of Process As a result of above discussion, the Dry Process is selected for the

manufacturing of Portland cement.

MATERIAL BALANCE

49

MATERIAL BALANCE

ANALYSIS OF LIMESTONE, CLAY AND CLINKER

Component

C1

Limestone

(Wt.% )

C2

Clay

(Wt. %)

C3

Clinker

(Wt. %)

SiO2 1.29 48.72 20.89

Al2O3 0.32 12.03 5.378

Fe2O3 0.10 2.60 3.53

CaO 53.53 7.95 62.64

SO3 0.02 0.02 0.04

MgO 0.70 2.93 2.5

Na2O 0.81 0.74 0.48

Cl2 0.003 0.005 -

K2O 0.04 2.14 0.85

Insoluble

residue - - 1.7

LOI 43.18 22.86 -

50

QUALITY CONTROL FORMULAE1. Silica Ratio:As SR = [SiO2]/ (Al2O3 + Fe2O3)By putting values, we get

SR = 20.89/[5.378 +3.53]

SR = 2.34

Range = 1.9 - 3.2 (In Range)

2. Lime Saturation FactorAs LSF = CaO / [2.8SiO2 + 1.65 AI2O3 + 0.35.Fe203]

By putting values, we get

= 62.64/ [(2.8 x20.89) + (1.65 x5.378) + (0.35 x3.53)]

= 62.64/68.60

=0.91

Range = 0.5 - 1.3 (In Range)

51

3. Hydraulic Ratio HR = CaO/ [SiO2 + Al2O3 + Fe2O3]

By putting value, we get

HR = 62.64 / [20.89+ 5.378 +3.53]

= 2.1

Range = 1.7-2.3 (In Range)

4. Alumina Ratio:AR = Al2O3 / Fe2O3

By putting values, we get

AR = 5.378/3.53

= 1.52

Range = 1.5-2.5 (In Range)

From these formulae it has been proved that the cement obtained

from this clinker has well and quality control is maintained.

5. Burn Ability IndexBI = C3S/ [C4AF + C3A]Where

C3S = 4.07 Hca - (7.6HSi + 6.72 HAl + 1.43HFe + 2.85 HMg)

And

52

HSi, HAl, HFe and HMg are compositions of SiO2, Al2O3, Fe2O3 and MgO

in clinker.

Putting the values, we get

= (4.07 x62.64) – {(7.6 x 20.89) + (6.72 x5.378) + (1.43 x 3.53) + (2.85 x

2.5)}

=47.87

C4AF = 3.04 HFe

C4AF = 3.04 x 3.53 = 10.73

C3A = 2.65 HAl - 1.69 HFe

C3A = 2.65 x 5.378 - 1.69 x 3.53

C3A = 8.29

Putting all these values in Eq.1, we get

BI = 47.87/[10.73 + 8.29]

BI = 2.52

RAW MIX PREPARATION

Hydraulic Modulus

HM = C/[S + A + F]

53

HM = Cm/[Sm + Am + Fm] (For raw mix)

According to this method of calculations:

Cm = [XC1 + C2] / [X + 1]

Sm = [XS1 + S2] / [X+1]

Am = [XA1 +A2] / [X+1]

Fm = [XF1 + F2] / [X+1]

Where 'X' is parts of limestone in raw mix

C1 = Composition of CaO in limestone

C2 = Composition of CaO in clay

S1, A1, F1 = Composition of SiO2, Al2O3 & Fe2O3 in limestone

S2, A2, F2 = Composition of SiO2, Al2O3 & Fe2O3 in Clay

Putting these values of Cm, Sm, Am & Fm in above formula we get

HM = (XC1+ C2)/ (X+1)___________________ [{(XS1+S2)/(X+1)}+{(XA1+A2)/(X+1)}+{(XF1+F2)/(X+1)}]

By solving and rearranging, we get

X = HM (S2+A2+F2)-C2

C1-HM (S1+A1+F1)

Assume HM = 2.1

Putting the values we get

X= 2.1 (48.718+12.03+2.6)-7.95

53.53-2.1(1.29+0.32+0.1)

X = 2.5

54

If HM Value of clinker is 2.1, we have to mix 2.5 parts of lime stone

and one part of clay.

Thus raw mix consists of

R1 = [2.5 /3.5]x 100 = 71.43%

R2 = [1/3.5] x100 = 28.57%

Where

R1 =composition of limestone in raw mix

R2 =Composition of clay in raw mix

DRY RAW MIX COMPOSITION

SiO2 =SiO2 X R1 +SiO2 x R2

=1.29 x 0.7143 +48.718 x 0.2857

=14.84 %

AI2O3 =Al2O3X R1 + Al2O3x R2

= [0.32 x 0.7143] + [12.03x 0.2857]

=3.66%

F e2O3 = Fe2O3 x R1 + Fe2O3 x R2

= [0.1 x 0.7143] + [2.6x 0.2857]

= 0.814%

CaO = CaO x R1 +. CaO x R2

=[53.53 x 0.7143] + [7.95x 0..2857]

= 40.51%

MgO = MgO X R1 + MgO x R2

55

= [0.7 x 0.7143] + [0.93x.2857]

=1.34%

Na2O = Na2O X R1 + Na2O x R2

= [0.81x 0.7143] + [0.74x 0.2857]

= 0.79 %

K2O = K2OX R1 + K2O x R2

= [0.04 x 0.7143] + [2.14 x 0.2857]

=0.64%

SO3 = SO3 X R1 + SO3 X R2

= [0.02 x 0.7143] + [0.02 x .2857]

= 0.02%

Cl= Cl X R1 + Cl X R2

= [0.003 x 0.7143] + [0.005 x 0.2857]

= 0.00357%

LOl =LOI x R1 + LOI x R2

= [43.18 x 0.7143] + [22.86 x 0.2857]

=37.37%

So Dry Raw Mix Composition

SiO2 14.8 4%.

Al2O3 3.66%

Fe2O3 0.814%

CaO 40.51%

MgO 1.34%

56

Na2O 0.79%

K2O 0.64%

SO3 0.02 %

Cl 0.00357

LOI 37.37%

Total 99.99

RAW MATERIAL REQUIRED

BASIS: 6700 TPD clinker (Dry basis)Raw mixture required for 1 ton= 100/ (100-LOI)

= 100/ (100-37.37)

= 1.597 ton/day

Raw mix required for 6700 TPD

=1.597 x 6700

=10699.99 tons/day

Dust factor =1.005

Raw mix required for 6700 T/day

=10699.9x 1.005

=10753.4 TPD

Moisture in raw material = 0.5%

57

Lime Stone =[10753.4/0.995]x 0.7143

=7719.7 TPD

Clay =[10753.4/0.995] x 0.2857

=3087.7 TPD

For 6700 tons/day manufacture of cement, we requireLimestone =7719.7 TPDClay =3087.7 TPD

SiO2 = SiO2 raw mix x 6700

1-[LOI/100]

=0.1484/[1-0.3737] x 6700

=1587.54 TPD

Al2O3 = Al2O3 raw mix x 6700

1-[LOI/100]

=0.0366/[1-0.3737] x 6700

=391.62 TPD

Fe2O3 = Fe2O3 raw mix x 6700

1-[LOI/100]

= 0.00814 / [1-0.3737] x 6700

58

= 87.09 TPD

CaO = CaO raw mix x 6700

1-[LOI/100]

=0.4051/[1-0.3737] x 6700

=4334.66 TPD

MgO = MgO raw mix x 6700

1-[LOI/100]

= 0.0134/[1-0.3737] x 6700

= 143.38TPD

SO3 = S03 raw mix. x 6700

1-[LOI/100]

= 0.0002/[1-0.3737] x 6700

=2.14 TPD

Na2O = Na2O raw mix x 6700

1-[LOI/100]

=0.0079/[1-0.3737] x 6700

=84.53 TPD

K2O = K2O raw mix x 6700

1 - [LOl/ 100]

= 0.0064/[1-0.3737] x 6700

= 68.48 TPD

Cl = Cl raw mix x 6700

1 - [LOl/ 100]

=0.000036/[1-0.3737] x 6700

= 0.385 TPD

59

CLINKER COMPOSITION

SiO2 1587.54tons/day

Al2O3 391.67tons/day

Fe2O3 87.09 tons/day

CaO 4334.67 tons/day

MgO 143.38 tons/day

SO3 2.14 tons /day

Na2O 54.53 tons/day

K2O 68.48 tons/day

Cl 0.385 tons/day

Total 6699.9tons/day

60

ENERGY BALANCE

61

ENERGY BALANCEThe energy balance is carried out on the pre calciner kiln system.

During the balance many assumed values may appear as due to

unavailability of data.

Input Heat Calculations

Heat Input by Consumption of FuelBy the calculations it was found that the coal required to produced 1ton of

Clinker = 0.120 ton.

Calorific value of Coal =6700, 000 kcal/ ton

Heat input through the combustion of fuel

=0.12 x 6700,000

=804,000 kcal/ton of clinker

For 6700 ton clinker = 804,000 x 6700

=5.41 x 109 kcal/6700 ton clinker

About 60% fuel is burning in calciner and about 40% burning is carried out at kiln.

62

Heat Input As Sensible Heat In FuelMass of coal =0.12 ton/ton of clinker

Mean specific heat capacity of coal = 225 kcal / ton.oC

Temperature of coal at inlet =100oC

Reference temperature =25 oC

Heat input = m Cp ∆t

= 0.12 x 225 x (100 – 25)

=2025 kcal/ ton clinker

For 6700 ton of clinker =1.355 x 107 kcal/6700 ton

clinker

2-Sensible Heat In Kiln Feed

a-Dry Feed Required To Produced One Ton Clinker= 1/[1 – (LOI/100)]

=1/[1 – 0.3737]

= 1.597 ton /ton of clinker

Temperature of feed at pre heater entrances = 60 oC

Specific heat of dry feed = 236 kcal/ton. oC

Reference temperature = 25 oC

Heat input as sensible heat = m Cp ∆t

= 1.597 x 236 x (60 – 25)

=13191kcal/ton of clinker.

b-Feed Water Present In Kiln Feed = 0.5% (water in kiln feed for dry

Process should be less than 1%)

Temperature of feed = 60 oC

63

Reference temperature = 25 oC

Specific heat of water = 1000 kcal/ton oC

Sensible heat due to water in kiln feed = (0.5/100) x1.597x100x (60-25)

= 279 kcal/ton of clinker

Total sensible heat in kiln feed = 13191+279

= 13470 kcal/ton of clinker

For 6700 ton of clinker =9.03x107 kcal/6700 ton of clinker

3-Secondary Air Sensible Heat

Coal required = 0.12 ton

Coal used for burning has following analysis

Ultimate Analysis

C = 86.70%

H = 2.2%

O = 2.9%

N2 = 0.8%

S = 0.5%

Ash = 6.9%

Combustion of fuel gives following reaction

C + O2 CO2

H2 + ½ O2 H2O

S + O2 SO2

64

N2 + 2O2 2NO2

Basis: 1 Ton of Coal Theoretical Air Required

According to the above four reaction, oxygen required for combustion

= 2.312 + 0.176 + 0.0183 + 0.01

= 2.5163 ton of O2

O2 present already in coal = 0.029 ton

So net O2 required = 2.5163 – 0.029

=2.4873 ton of O2

Air required 23 ton O2 present in = 100 ton of Air

1 ton O2 present in = 100/23 ton Air

2.4873 ton O2 present in = 100 x 2.4873/ 23

= 10.81 ton of Air /ton of coal

One ton clinker required coal = 0.12 ton

So Air required to produced one ton clinker = 10.81 x 0.12

= 1.297 ton Air /ton of clinker

For 6700 ton clinker = 1.297 x 6700

= 8689.9 ton Air /6700 ton clinker

Excess Air depends upon type of fuel and burner,

Assume excess air used = 12%

Total Air required = 1.12 x 1.297

= 1.452 ton Air/ ton clinker

About 60% of this Air required for combustion is fed as secondary Air

So mass of secondary Air =1.452 x 0.6

=0.872 ton Air /ton clinker

Temperature of secondary Air = 900oC

Reference temperature = 25oC

Specific heat of secondary Air = 279.9 kcal/ton.oC

65

Heat input in secondary Air = m Cp ∆t

= 0.872 x 279.9 x (900 – 25)

= 213461.8 kcal/ton clinker

For 6700 ton of clinker = 213461.8 x 6700

= 1.43 x 109 kcal/6700 ton clinker

5. Primary Air Sensible Heat

About 40% of total air is fed as primary Air, primary air required for combustion

= 1.452 x 0.4

= 0.581 ton Air /ton clinker

Temperature of primary Air = 25oC

Specific heat of primary Air = 239 kcal/ton.oC

Heat input as sensible heat = m Cp ∆t

=0.581 x 239 x (25 – 25)

= 0 kcal/ton clinker

66

Output Heat Calculation1) Heat of ReactionThe raw mix yield the following analysis of clinker

Component percentage (%)

SiO2 20.89

Al2O3 5.378

Fe2O3 3.53

CaO 62.64

MgO 2.5

Na2O 0.48

SO3 0.04

K2O 0.85

I.R 1.5

67

During the clinker formation exothermic and endothermic reaction takes place,

the heat evolved can be calculated as

Heat of Reaction = 4.11%Al2O3 + 6.48%MgO + 7.646%CaO –

. 5.11%SiO2 – 0.59%Fe2O3

= 4.11 x 5.378 + 6.48 x 2.5 + 7.64 x 62.64 – 5.11 x

. 20.89 – 0.59 x 3.53

= 0.59 x 3.53

= 408.04 kcal/kg clinker

= 408040kal/ton clinker

For 6700 ton clinker = 2.734 x 109 kcal/6700 ton clinker

2) Heat Losses with Kiln Exit Gases

a. Exit gas from coal burning:-

As the composition of coal is

Ultimate Analysis

C = 86.70%

H = 2.2%

O = 2.9%

N2 = 0.8%

S = 0.5%

Ash = 6.9%

Combustion of fuel gives following reaction

68

C + O2 CO2

H2 + ½ O2 H2O

S + O2 SO2

N2 + 2O2 2NO2

Air required to produced 1 ton clinker = 10.814 x 0.12

= 1.297 ton/ton clinker

N2 in Air = 1.297 x 0.77

= 0.9987 ton N2/ton clinker

CO2 in exit gases = 44 x 0.897/12

= 3.179 ton CO2 / ton of coal

CO2 formed for 1 ton of clinker = 3.179 x 0.12

= 0.381 ton CO2 /ton clinker

H2O in exit gases = 18 x 0.022/2

= 0.198 ton H2O /ton coal

For 1 ton clinker = 0.198 x 0.12

= 0.237 ton H2O/ton clinker

SO2 in exit gases = 64 x 0.005/32

= 0.01 SO2 /ton of coal

SO2 for 1 ton clinker = 0.01 x 0.12

=1.2 x 10-3 ton SO2 /ton clinker

NO2 in exit gases = 60 x0.008/28

= 0.0171 ton NO2 /ton coal

NO2 for 1 ton clinker = 0.0171 x 0.12

= 2.05 x 10-3 ton NO2/ton clinker

Total exit due to fuel burning = 0.381 + 0.237 + 1.2 x 10-3 + 2.05 x 10-3

= 0.4079 ton gas/ton clinker

69

B-Exit Gas From Kiln Feed

Kiln feed required = 1.597 ton feed / ton clinker

Composition of feed

Component Percentage (%)

SiO2 14.84

Al2O3 3.66

Fe2O3 0.814

CaO 40.51

MgO 1.34

LOI 37.37

CaCO3 CaO + CO2

MgCO3 MgO + CO2

56 ton CaO required = 100 ton CaCO3

0.4051 ton CaO required = 100 x 0.4051/56

= 0.724 ton CaCO3/ton feed

For 1 ton clinker = 0.724 x 1.597

= 1.156 ton CaCO3 /ton clinker

40 ton MgO required = 84 ton MgCO3

0.0134 ton MgO required = 84 x 0.0134/40

= 0.02814 ton MgCO3/ton feed

For 1 ton clinker = 0.02814 x 1.597

= 0.045 ton MgCO3 /ton clinker

CO2 evolved due to CaCO3

70

= 44 x 1.156/100

= 0.51 ton CO2 / ton clinker

CO2 evolved due to MgCO3 = 44 x 0.045/84

= 0.024 ton CO2 /ton clinker

Total CO2 due to kiln feed = 0.51 + 0.024

= 0.534 ton CO2/ton clinker

H2O (free) evaporated in kiln feed = 0.5 x 1.597/100

= 0.008 ton H2O/ton clinker

H2O Combined evaporated = (0.02/1.597) x (0.00075%SiO2) +

(0.0035%Al2O3)

= (0.02/1.597) x (0.00075 x 14.84) +

(0.0035 x 3.66)

=0.014 ton water/ ton clinker

Total water due to feed in exit gases = 0.008 + 0.014

= 0.022 ton water/ton clinker

c. Exit Gas Analysis (Excess Air) Excess Air = 12%

Weight of Excess Air = %age excess air x air used for

Combustion

= 0.12 x 1.297

=0.1556 ton Air / ton clinker

N2 in excess air = 0.1556 x 0.77

= 0.1198 ton N2/ton clinker

O2 in excess air = 0.1556 x 0.23

= 0.0358 ton O2/ton clinker

Weight of gases in exit gases as follows

71

N2 = 0.9987 + 0.12 = 1.118 ton /ton clinker

CO2 = 0.381 + 0.534 = 0.915 ton /ton clinker

O2 = 0.358 ton /ton clinker

H2O = 0.0237 + 0.02 = 0.0437 ton /ton clinker

SO2 = 1.2 x 10-3 ton /ton clinker

NO2 = 0.002052 ton /ton clinker

Exit gas temperature is 300oC. Its specific heat is given as

CO2 = 259.9 kcal /ton.oC

H2O = 489.9 kcal /ton.oC

N2 = 259.9 kcal /ton.oC

SO2 = 179.9 kcal /ton.oC

O2 = 239.9 kcal /ton.oC

NO2 = 249.5 kcal /ton.oC

T1 = 25oC

T2 = 300 oC

Heat loss due to

CO2 = m Cp ∆t

= 0.915 x 259.9 x (300 – 25)

= 65379.3 kcal/ton clinker

H2O = m Cp ∆t

= 0.449 x 489.98(300-25)

= 5887.37 kcal/ton clinker

N2 = m Cp ∆t

= 1.118 x 259.9 x (300-25)

= 79906.25 kcal/ton clinker

O2 = m Cp ∆t

= 0.0358 x 239.9 x (300-25)

= 2361.81kcal/ton clinker

SO2 = m Cp ∆t

=1.20 x 179.9 x (300-25)

72

= 59.37kcal/ton clinker

NO2 = m Cp ∆t

= 0.002055 x 249.9 x (300-25)

= 141.22 kcal/ton clinker

Therefore total heat output due to exit gas =1543735.02 kcal/ton clinker

For 6700 ton clinker =153735.02 x 6700

=1.03x109kcal/6700 ton clinker

3. Heat Loss Due To Mixture in Raw Mix Moisture in raw mix = 0.5%

Raw mix required = 1.597 ton/ton clinker

Specific heat of water =1000 kcal/tonoC

Latent heat of vaporization =510 kcal/ton

Temp. Of kiln feed =60oC

Heat loss due to moisture = m Cp ∆t+mλ

= (0.5/100) x 1000 x (100-25)

+ (0.5/100) x 1.597 x 510

= 7.984+4.072

= 12.056 kcal/ton clinker

For 6700 ton =12.056 x 6700

=80775.2 kcal/6700ton clinker

=8.07x104 kcal/6700ton clinker

4-Heat In Clinker At Kiln Discharge

Reference temperature T1=25oC

Temp. of clinker at outlet of kiln T2=1300 oC

Specific heat of clinker at 1300oC = 270 kcal/tonoC

Heat loss Due to Clinker Discharge = m Cp ∆t

= 1 x 270 x (1300-25)

= 344250 kcal/ton clinker

73

For 6700 ton =344250 x 6700

= 2.306x109 kcal/6700 ton clinker

Heat Loss Radiation And Convection

Heat loss by convection and radiation from whole the system is given as;

= 90.149 kcal/kg clinker

= 90149 kcal/ton clinker

For 6700 ton = 90149 x 6700

= 6.04x 108 kcal/6700 ton clinker

Heat Balance Sheet

Heat Input Kcal/6700 ton clinker

Heat Input by Consumption of Fuel 5.41x109

Heat Input As sensible Heat in Fuel 1.355x107

Sensible Heat in Kiln Feed 9.03x107

Primary Air Sensible Heat 1.43x109

Secondary Air Sensible Heat 0.0

Total 6.94 x 109

74

Heat Output Kcal/6700 ton clinker Heat of reaction 2.734 x 109

Heat losses with kiln exit gases 1.3 x 109

Heat losses due to moisture in raw mixture 8.07 x 104

Heat in clinker at kiln discharge 2.306 x 109

Heat losses by radiation and convection 6.04 x 108

Total 6.94 x 109

75

EQUIPMENT DESIGN

76

EQUIPMENT DESIGNKiln Design

Calculation For The Diameter Of The Rotary Kiln

Basis 6700 ton/day clinker

Martin’s formula considering thermodynamic condition in the rotary kiln:

This formula reads

Q = 2.826D2 . V/Vg

Notation:

Q = Kiln capacity, t/h

D = Kiln diameter on bricks, m

V = Gas velocity in the gas discharge end, m/s

Vg = Specific gas volume, m3/kg clinker

Since the kiln capacity formulas take into consideration only a

fraction of the factors influencing the kiln’s capacity, they have merely

limited application.

Applying martin’s formula to dry kiln of a capacity of 125 t/h (3000

t/day) with the kiln diameter 4.15m on the bricks, we get following results.

125 = 2.826(4.15)2 V/Vg

V/Vg = 2.568

Keeping the same value of V/Vg, for a dry process cement kiln of

capacity 279.167 t/h (6700 t/day), the diameter of the kiln will be as

follows;

77

279.167 = 2.826D2 (2.568)

D2 = 38.47

D2 = 6.2m

Similarly the outlet diameter of the kiln will be given as:

125 = 2.826 (3.75)2 V/Vg

V/Vg = 125/[2.826(3.75)2 ]

V/Vg = 3.145

Where 3.75m is the on brick dia of a 125t/h capacity dry process kiln.

The same ratio of V/Vg for a 279.167t/h (6700 ton/day) capacity kiln.

Replacing values in martin’s formula:

279.167 = 2.826 D2 (3.145)

D2 = 31.41

D = 5.6 m

78

Calculation Of The Length Of The Rotary Kiln

Basis: 6700 ton/day clinkerThe length of the rotary kiln can be calculated by the formula:

Q = D.L [45 + K {(D/L) – 0.02}]

1000 [1 + (W – 40)(1.6/100)]

The above formula is simplified for dry process when water contents will be

zero.

Q = D.L [45 + K {(D/L) – 0.02}]

Notation;

Q = Rotary Kiln capacity/h

D = Mean Kiln dia on brick, m

L = length of the kiln, m

K = characteristic index of kiln, t/h.m2

Data

Q = 279.167 t/h

D = 5.902 m

K = 3064 t/h.m2

The length can be calculated as follows;

279.167 = 5.902 x L [45 + 3064{(5.902/L) – 0.02}]

L = 64.75 m

79

Kiln SlopeNo generally valid rule exists for the proper slopes of rotary kiln.

Rotary kilns show slopes from 2 to 6%. Lower kiln slopes require higher

number of revolutions. This has the benefit of better mixing of the kiln feed,

together with a more intensive heat exchange. Lower slopes also permit

higher degrees kiln filling or kiln load.

The following kiln slopes were found by Bohman to the correct.

5% slope for kiln with dia upto 9’2”

4% slope for kiln with dia from 9’10” to 11’2”

3% slope for kiln with dia above 11’2”

As until now, this recommendation is proved good, since most of the

rotary kilns with dia above 11’2”, show slopes of about 2 – 3.5% on the

basis of the result of Bohman the slope assigned to the kiln is 3%.

Degree Of The Kiln Filling The feed form a segment of the rotary kiln’s cross-

section. The area ratio of this segment to the area of the kiln’s cross-section

expressed in percent is called kiln’s degree or percent of filling.

Kiln filling degree fluctuates within the limits of about 5 – 17%. Independent from the kiln’s diameter.

Selecting degree of kiln filling 15%.

From the graph of %age filling and centric angle the following results were

obtained for kiln.

Kiln load = 15%

Centric angle ά = 108o

80

Revolution Of The Rotary Kiln Form the graph between kiln dia and revolutions in the case of

circumferential speed of 14.7 in/sec, kiln revolutions were calculated to be

1.8rpm.

Thermal Load Of The Cross – Section Of The Burning Zone The quantity of heat which glows during one hour through 1 m2 of the

cross –section of the kiln’s burning zone. Formulae read:

Qp = 1.4 x 106 x D (kcal/m2.h)

Qp = 1.4 x 106 x (5.902)

Qp = 8.26 x 106 kcal/m2.h

Residence Time Formula for calculating residence time of the rotary kiln is:

Residence time = t = 1.77 x L x 6.325 x F

P x D x N

Notation:

t = Residence time, min

L = Length of rotary kiln, m

D = Diameter of rotary kiln, m

P = Slope of the kiln degree

N = Number of revolutions per min

F = Factor = 1

Replacing values, we get

t = 1.77 x 64.75 x 6.325 x 1

1.717 x 5.902 x 1.8

t = 39.74 min

By using proper kiln slope and varying the number of revolutions, can control the

residence time (t).

81

Thermal Expansion Of The Rotary Kiln

a) Linear ExpansionWhen in operation, length and circumference of the rotary kiln are larger

than in the inactive state. These circumferences must be taken into

consideration, so that the riding rings can always rest entirely on the roller and

that the seals on both ends of the kiln will not be impaired.

The linear expansion in the rotary kiln’s length is given as:

A1 = α [{(t1 + t2)/2} – t] L1

A2 = α [{(t1 + t2)/2} – t] L2

Notation:

α = Linear expansion index for steel, = 0.000012

t1 = Highest temperature on the kiln’s circumference

= 350oC

t2 = temperature on the kiln’s ends, 155oC and 60oC respectively

L1&L2 = Length from the highest temperature point to both kiln ends

L1 = 10.79 m = 10790mm

L2 = 53.96 m = 53960mm

T = Ambient Temperature = 25oC

Then the linear expansion is given as:

A1 = 0.000012[{(350+155)/2} – 25] 10790

= 29.456 mm

A2 = 0.000012[{(350+60)/2} – 25] 53960

= 116.55mm

Total expansion = 29.45 + 116.55

= 146.01mm

Linear expansion, expressed in percent = 146.01 x 100/64750

= 0.225%

82

b) Expansion along DiameterThe formula is given as:

= α (300 – t) D

= 0.000012(300 – 25)6200

= 20.46mm

c) Expansion Along circumference From previous case it is clear that the kiln’s dia on heating will be 6220.46mm.

Some result can be obtained after considering the expansion in the

circumference.

Expansion = α (300 – t) U

U = π D

= 3.1415 x 6200

= 19477.87 mm

Expansion = 0.000012 (300 – 25) x 19477.87

= 64.28 mm

Expansion Along total circumference = 19477.87 + 64.28

= 19542.45mm

Kiln’s dia in hot state = 19542.45/ π

= 6220.45mm

83

Vertical Load Of Kiln

The vertical load of kiln is due to the

a) Mass of kiln shell

b) Mass of kiln lining

a) Mass of kiln shell

D = Dia of kiln shell (without lining) = 6.2m

L = Length of kiln shell = 64.75m

Thickness of kiln sheet = 0.02m

Area = (D22 – D1

2) π

Area = (6.242 – 6.22) x 3.1415

Area = 1.56 m2

Density of steel (at 200oC) = 7830kg/m3

Volume of kiln shell = Area x length

= 1.56 x 64.75

= 101.01 m3

Mass of kiln shell = volume x density

= 101.01 x 7830

= 790908.3 kg

b) Mass of kiln lining

Dia of kiln with lining = 5.78m

Dia of kiln without lining = 6.2m

Length of kiln = 64.75m

84

Cross sectional area of lining = (6.22 – 5.782) x 3.1415

= 15.8m2

Length of calcining zone = 64.75 x 0.4 = 25.9m

= 25900mm

Length of burning zone = 64.75 x 0.35 = 22.66m .

=22660mm

Length of cooling zone = 64.75 x 0.25 = 16.19 m .

16190mm

Mass of lining in calcining zone (fire bricks) = 25.9 x 15.8 x 2100

= 859362kg

Mass of lining in burning zone = 22.66 x 15.8 x 2550

= 912971.4 kg

Mass of lining in cooling zone = 16.19 x 15.8 x 2900

= 741825.8kg

Total Mass of lining = 859362 + 912971.4 + 741825.8 =2514159.2kg

Density of fire bricks

Having basic material chansotte = 2100kg/m3

Density of high Alumina bricks

Having basic material bauxite = 2550 kg/m3

Having basic material dolomite = 2900 kg/m3

Total vertical load of kiln = Mass of kiln shell + Total mass

of lining

= 790908.3 + 2514159.2

= 3305067.5kg

85

Horse Power Requirement Of The Rotary Kiln

Horse power requirement can be calculated by the following

formula:

a-Load horse power It is calculated by formula:

Hp = (D x Sin θ)3 x N x L x K

Notation

D = Inside kiln dia (ft)

Sin θ = Factor calculated by % of kiln load

N = RPM of kiln

L = Length of kiln (ft)

K = 0.00076 for dry process.

Data

D = 20.33 ft

Kiln load = 15 %

Sin θ = 0.82 ( from the graph)

N = 1.8 RPM

L = 212.38 ft

Hp = (20.33 x 0.82)3 x 1.8 x 212.38 x 0.00076

= 1346 hp

Friction horse power Formula for friction horse power is given as:

86

Hp = W x bd x td x N x F x 0.0000092

rd

Notation

W = Total vertical load on all roller shaft bearing (lb)

bd = Roller shaft bearing dia, inch

rd = Roller dia, inch

td = Riding tyre dia. inch

N = RPM of kiln

F = Co-efficient of friction of roller bearing, 0.018 for oil

Lubricated bearing.

Hp = 7286351.8 x 16 x 174 x 1.8 x 0.018 x 0.0000092

42

= 143.96 hp

Total horse power required = Load horse power + friction horse power

= 1346 + 143.96

= 1489.96 hp

= 1111.9 KW

87

CRUSHER

PRINCIPLE OF CRUSHINGThe raw materials are quarried in lumps up to 1-2 m and must be reduced

to less than 0.2 mm. This reduction is carried out in two stages, crushing down to

25 mm because the mill is designed for a feed of that maximum size and

subsequent grinding. Raw materials occur in widely varying forms and a large

range of crusher types is available. Combination, i.e. the process of fragmenting

materials, can be effected according to three different principles.

Impact: (Hammer, crusher, drier-crusher)

Compression: (Jaw crusher, cone crusher)

Shearing: (roll-jaw crusher, roller crusher)

The relationship between feed size and exit size of the material is termed as

the reduction factor. Crushers with high reduction factors like hammer crushers

can crush to the required size in one stage. The material is delivered from the

quarry usually by dampers, and tipped into the reinforced inlet chute whose

bottom a lamellate conveyor is feeding the crusher.

88

The remaining crusher types are used for very hard and abrasive respectively

soft and sticky materials. They all have low reduction factors and in the cement

factory they are normally operated in multi-stage crushing.

After the first stage, the fine fraction of pre-crushed material is removed on a

vibrating screen and added to the coarse fraction which is finish crushed in a

smaller secondary cone crusher.

Selection of Crushing Machinery The table should be guidance to the selection of crushers for cement

raw materials.

Material Crusher usedLimestone, hard., abrasive Cone crusher

Jaw crusher

sandstone, hard and massive Cone Crusher

Selected Crusher Type

1. Jaw Crusher2. Blake Jaw crusher3. Hammer crusher

The hammer crushers without inlet grate are basically secondary

crushers, but their robust and sturdy design makes them well-suited for primary

crushing for materials which have been quarried by ripping or similar fragmenting

methods as well as for gypsum and raw coal. They can also handle materials

containing some degree of moisture.

89

Hammer crushers without inlet grate are available with rotational speeds

suitable for primary as well as secondary crushing, and can be tailored to suit

individual raw materials. The slot widths in the outlet grates may be adapted to

the operational conditions in question.

Hammer crushers without inlet grate are available with one or two sets of

rotors. The rotor shafts are fitted with hammer discs on which the hammers are

pivotally mounted.

The rotor shafts run in sturdy oil bath-lubricated roller bearings and are

supported on the crusher casing of heavy cast steel and welded up sections

bolted together. The casing is fined with replaceable wear plates.

The double hammer crusher has a heavy anvil with replaceable crushing

plates which are adjustable in relation to the hammers to compensate for wear.

The double hammer crusher has a heavy anvil with replaceable crushing jaws

and outlet grate, both of which can be adjusted to compensate for wear.

The single hammer crusher has an outlet grate with replaceable grate

bars and an adjustable crushing plate.

90

Hammer crushers without inlet grate are designated EUI (single without

inlet grate) and DUI (double without inlet grate), followed by two digits specifying

the diameter across the hammers and the width of the rotor unit.

Primary Crushing For outlet slots 34 ≥50 mm, base calculations on 1.2 x rated output

for the motor size stated.

For outlet slots 34 ≥75 mm, base calculations on 1.4 x rated output

for the motor size stated.

For outlet slots 34 ≥1000mm, base calculations on 1.6 x rated

output for the motor size stated.

For secondary crushing, outlet slots larger than 34 mm are used only in

exceptional cases.

Jaw Crusher:

In the cement industry the jaw crusher is in general use; this is due to its

relatively simple design and also to the circumstance that this is manufactured in

large units. The jaw crusher serves mainly as a primary crusher. The size

reduction of the crusher feed is performed between two crusher jaws; one of

them is stationary, and the other is moved by toggle pressure. The jaws are lined

with ribbed liners, consisting of chill cost or quenched steel. The crusher frame

consists of cast steel; frames of large units consist of 4 to 6 assembled sectional

steel frame plates.

To crush hard, semi-hard and brittle rocks, ribbed liners are used. The

included angle of the ribs amounts to 90-100°. For crushing of coarser and

considerably harder rocks, the ribs should be corrugated; here the rib angle

should be 100-110°. For large and very hard rocks, liners with more widely

91

spaced ribs are used. The most effective ratio between the rib width and its

height is expressed as:

t ~ 2 /3hDepending on the size of the crusher feed, the width of the ribs in Jaw

crushers employed as primary crushers 2 to 6 inches. Jaw crushers employed

as secondary crushers have ribs with a width of 0.4-1.6 inches. The width of the

crushers discharge opening is being measured from the fop of the rib of one liner

to the opposite notching of the other liner; it is the distance between the planes.

When working very hard materials, the ribs generate lateral forces which have a

negative influence on the swing Jaw shaft, in such cases even jaw liners are

preferred.

For the pre crushing of limestone, so called super elevated ribs are

successfully employed. Every third or fourth rib has a greater height than the

normal liner ribbing. Formation of lamella or needle-shaped pieces in the crushed

material is hereby prevented. The greater wear shows at the lower part of the

fixed jaw plate; next the lower part of the swing jaw plate. The constructional

design of the jaw liners makes it possible to turn over a worn jaw liner 180°, so

that the worn sides come upwards, this makes it possible to extend the life time

of the jaw liners. The liners consist of austenitic manganese steel with a Mn

content of 12-14%. The life time of the liners amounts to 800-1000 working

hours, depending upon the hardness of the crushed material.

Overload Safety DeviceIf unbreakable objects such as tramp iron, digger teeth etc, enter the

crusher, they can cause considerable damage to the crushing elements. To

prevent this, toggle plates which shatter, when tramp iron causes an overload

were developed as safety devices for protecting the crusher from serious

damage. Two different modifications of safety toggle plates with predetermined

cracking lines. After cracking, the toggle plates have to be replaced; this usually

results in an extended interruption of production time.

92

To avoid this, a hydraulic overload safety device has been developed;

because of it un-crushable objects can automatically be removed from the

crushing space without any interruption of operation. With this construction the

stationary jaw is designed as a swing jaw, capable of giving way and having its

fulcrum at the upper end. The lower end is supported on three hydraulic cylinders

the pistons of which are in the front end position when the swing jaw is closed.

In case an un-crushable object enters the space between the crushing

jaws, the resulting over-pressure in the hydraulic system opens the jaw and the

foreign materials falls out of the crushing space. Subsequently, the hydraulic

cylinders move the swing jaw back to the normal operating position. During this

procedure the feeding of the material to be crushed is automatically interrupted,

whereas the crusher drive runs continuously. The increase in investment cost for

the hydraulic protection device is approximately 25% of the crusher price.

Speed Of Rotation

In addition to its size, the through put capacity of a jaw crusher is also

determined by the number of revolutions. However, the speed of rotation should

not be excessive, since practical experience has proved that an increase in

speed beyond a certain limit does not yield an increase in capacity. The

backward and forward motion of the swing jaw must be regulated so as to give

the crushed material enough time to leave the discharge opening of the crusher.

The formula derived for the speed of rotation of the jaw is

n = √(tgα)/S

n = Number of revolutions/min

S = Way length of the swing jaw

α = Angle of the crusher jaw, degree

93

Calculation Of Speed Of Rotation

Feed opening = 47 x 36 inches

Jaw crusher angle = α = 22°

Way length of swing jaw = S = 4.5 cm

n = √(tgα)/S

= tan√(22/45)

However, regarding the friction between the crusher feed and crusher jaw

the upper limit of the jaw crusher recommended is 170 RPM.

Capacity Of Jaw Crusher

According to LEWENSON

Q = 150 n.b.s.d.µ.r

Where,

Q = crushed capacity, ton/hr

B = Width of the Jaw, centimeter

d = mean size of the crushed material

n = RPM of drive shaft

Loading factor of crushed material depending upon its physical property.

µ = about 0.25 to 0.5

r = specific gravity of crushed feed (Ton/m3)

94

RPM of Drive shaft = 220 RPM

Width of the swing Jaw = 1.20 m

Amplitude of swing jaw = S = 4.5 centimeters

Mean size of crushed material = 0.17 meter

Specific gravity of limestone =2.7 ton/m3 (Perry)

µ = 0.3 (By literature for limestone)

By LEWENSON

Q = 150 x 170 x 1.20 x0.045 x 0.17 x 0.3 x 2.7

Q =190 Ton/hr.

By TAGGART

Q=0.093 b.d.

Where,

Q = crushed capacity, ton/hr

b= Width of the Jaw, centimeter

d = size of the crushed material

b=120 cm

d=17 cm

95

SO,Q = 0.093 x 120 x 17

Q = 190 Ton/hr.

Drive Power For Jaw Crusher

According to Viand's formula

N=0.0155 b.D

Where,

N=Jaw Crusher motor size

b=Width of swing jaw, cm

D=Maximum dimension of crusher feed, cm

According to Lewenson's formula

N = [n.b (D2-d2)]/0.34Where,

N = Motor size of jaw crusher

n = RPM of the main drive shaft

b= Width of the swing jaw, meter

D = Mean dimension of crusher feed

So,Width of Jaw = b = 1.2 meter

RPM of main shaft = n = 170 RPM

Dimension of crushed feed = D = 0.5 meter.

Dimension of crushed feed = 0.17 meter

According to Viand's formula

96

N = 0.0255 x 120 x 50

N=153 HP

According to Lewenson's formula

N = 170 x 1.2 [(0.5) 2 - (0.17) 2 ]

0.34

N = 132 HP

Safety factor = 10~15%

Actual Motor HP = 132(1.15)

=152 HP

Designing Of Raw Material CrusherHeavy Duty Feeder For Limestone Feeding

SIZE : 2200*10000mm

WIDTH : 2200mm

DISTANCE OF CENTER : 100000mm

Motor For Feed Driving

POWER: 55Kw

ROTATING SPEED: 980rpm

Crusher For Lime Stone Crushing

97

INPUT SIZE: 2400*2500mm

ROTATING SPEED: 375rpm

CAPACITY: 650 T/Hr

Motor For Driving CrusherPOWER: 1000Kw

VOLTAGE: 6000V

Motor For Driving Feeding Rolls

POWER: 45KW

VOLTAGE: 380V

ROTATING SPEED: 740rpm

Belt Conveyor

CAPACITY: 650T/Hr

BELT SPEED: 106 m/s

Motor For Driving Belt

POWER: 18.5KW

Crusher Capacity

Qdk = Kiln Capacity = 6700 TPD

BDls = Bulk density of limestone = 1.4 tons/m3

98

K1 = Factor for converting clinker = k1 = 1.8

Cl = Total lime stone component = 85 %

Tcrw = No. of days Crusher runs = 6 days/week

Thd = No of hours Crusher runs in a day = 12 hours/day

Ht = Hopper to hold material equivalent to Crusher = 20 min

RMw = Raw material req. per week = Qdk*K1*7

= 6700* 1.8*7

= 84420 tons/week

LSw = Lime stone req. per week = Cl*RMw/100

= 85*84420/100

= 71757 tons/week

Crusher Capacity Required Qcr = Lsw / Tcrw * Thd

= 71757/(6*12)

= 996.62tons/hr

Crusher Hopper Capacity

Hv = (Qcr * Ht) / (BDls * 60)

= (996.62*20) / (1.4*60)

= 237.29 m3

Feeder Capacity for Crusher

As

Qcr = 996.62 tons/hr

99

k2 = 1.2 (Over capacity factor)

Qcrf = Qcr * k2

= 1195.94 tons / hr

Transportation from Crusher

Q tcro = 1.5 * Qcr

= 1494.93 tons / hr

Maximum Capacity of Dumpers

Vd = Hv / Nd

= 237.29/2

= 118.64 m3

100

Where

Nd = No of Dumpers = 2

Hv = Hopper capacity = 237.29 m3

101

Size & DimensionSetting

dimensions, inches

Size of the feed opening 47 x 35

Max. feed size 23

Width of discharge opening 6-8

Drive shaft RPM 170

Drive motor HP 152

Throughput capacity t/hr 190

Fly Wheel diameter 82

Width of fly Wheel 21

Weight of crusher, Ton 68

Width, inches 148

Height 89

Length 177

VERTICAL ROLLER MILL

102

The vertical mill is the most common type of mill for grinding of raw materials. Due to excellent grinding efficiency combined with a high production capacity as well as a high drying capacity, this type of mill has replaced the ball mill now a day. Rollers mills have a lower energy consumption than ball mills, and require less space per unit and capacity at substantial lower investment cost. Roller mills are developed to work as air swept grinding mills. The working Principe of vertical roller mills is based on two to four grinding rollers with shaft carried on hinged arms and riding on a horizontal grinding table or grinding bowl.

A common characteristic of all the roller mill is that size reduction is effected by rollers or grinding table traveling over a circular bed of material and that the material, after passing under the rollers, is subjected to a preliminary classifying action by a stream of air sweeping through the mill. Depending on the air flow velocity, a certain proportion of the pulverized material is thus carried into a classifier (Air separator ) which normally forms an integral feature of the upper part of the casing of the mill. Oversize particles rejected by the classifier fall back into the grinding chamber, while the fines are swept with the air out of the mill and are collected in a filter or a set of cyclones. As the pneumatic conveying of the material in the mil to the separator requires considerable air flow rate, and as the material leaving the grinding bed and carried up into the classifier comes into intimate contact with air, roller mills are especially suitable for drying of moist feed materials in combination with grinding. This is particularly advantageous because these mills can accept large quantities of hot air or gas at relatively low temperature. The roller mills employed in cement industry have grinding elements of various shapes. Thus, in some mills there are cylindrical rollers, in other the rollers are of truncated conical shape or have flat lateral rollers and a convex circumferential surface. The force that keeps the rollers pressed in contact with the bed of material on the grinding path may be centrifugal force, spring pressure, tension action etc.

Design Features.

The material is comminuted by the grinding element rolling on a circular bed of feed material. The larger pieces of material are crushed by the rollers while the smaller one are reduced by the rubbing action. The pulverized material spilling over the edge of grinding table is entrained by the high velocity stream of air, so that the smaller particles are swept upward into the classifier, and the coarser one fall back on the roller path.

Grinding Action Developed In The Roller Mill.

This is the preliminary classifying effect, as distinct from the final separation accomplished in the internal classifier in the upper part of the casing. Because of the shorter residence time of the feed material in the grinding chamber, the bed of material is kept substantially free from fine particles which do not require further grinding, unnecessarily load the mill and tend to form undesirable agglomerations. The important basic conditions for effective grinding in a roller mill are that the grinding element develops a good draw in action and

adequate pressure and that a stable bed of material is formed.

Draw In Action Of The Grinding Element.

103

The particles of feed materials are gripped between the roller and

grinding table. The larger which project above the other and are first subjected to

the grinding action, are broken down.

Compaction Of The Bed Of Material.104

In roller mills, the maximum feed particle size of between 1/20 and 1/ 15 of the roller diameter are permissible. If the material coarser than this is fed to the mill, then there is a danger that the coarser particle will not be drawn in under the rollers but will simply displaced be i.e. pushed in front of the rollers. Furthermore, with in the permissible maximum particle size limit, the draw in action is governed by the granulometric composition and coefficient of friction of the feed material. Thus the bed of material should possess adequate stability so as not to be displaced by the rollers. Also, in order that the rollers do indeed roll on the material and not merely slide along, a sufficiently large frictional force must be developed between their circumference and the material. It may occur when the mill is operating in steady state conditions, the granulometric composition of the feed material changes drastically, due to segregation on emptying the feed hopper, so that the mill temporally receives only feed material. This way adversely affect the stability of the bed, part of the material is displaced, the depth of the bed is, therefore, reduced and the pressure on the rollers to be unchanged. The specific pressure exerted on the material is increased. It may thus happen that the rollers punch through; the bed is displaced, causing mill vibration. As the condition of the feed material is liable to vary with regard to it grind ability, composition granulometric, and moisture content, mill should be designed keeping in view to achieve adequate draw in capacity of the rollers that will deal effectively with any variation likely to occur in the mill feed material. Measures required to achieve adequate draw in capacity of the rollers includes, providing the rollers and roller path with raised ridges and utilizing the joints of renewable segments on these components to provide positive grip.

Grinding Bed Formation.

The grinding process that the material undergoes between the rollers and the roller path on the grinding table comprises the following actions.

Drawn - In Of The material.

In conjunction with the reduction in size there occurs intensive spatial re- arrangement of the individual particles under crushing load. The compressive and shearing forces associated with crushing load have a further size reducing effect, mainly by attrition which indeed the key factor in achieving fine pulverization in a roller mill. The final size reduction is achieved substantially by rubbing together of the material particles subjected to compression and shear while undergoing rearrangement of their position in the bed. To accomplish this requires the fulfillment of several conditions.- Sufficiently high specific grinding pressure - Sufficiently large number of points and area of contact of the particle in relation to one another.- Sufficient large number of movement of the particles in relation to one another.These conditions are directly interrelated, if the bed of material increases in depth, the specific pressure exerted on the material, for a given pressure applied by the rollers, becomes less, if the depth of the bed decreases, the specific pressure increases, but the scope for relative movement of the particles is restricted and number of their points and areas of contact is reduced. Hence every bed of material in a roller mill must be a compromise between the specific grinding pressure that pulverize the material and the bed depth needed for achieving the product fineness required. In most cases, if the mill is fed with material which is uniform in its granulometric composition and size reduction properties and which develop sufficient friction, a stable bed of more or lessConstant depth is formed on the grinding table. With difficult materials there is a scope for modifying and controlling the depth of the bed by dam rings. If the materials are too dry and has a high contents of fine particles, stabilization of the bed may be achieved by moistening it. For grinding of soft materials such as marl, the addition of high grade hard limestone is required primarily for correction of the deficient chemical composition of the raw material, improves the performance of roller mills in term of throughput and of operational behavior. To achieve such improvement, the limestone should be as coarse as possible within the bed consisting largely of softer and finer particles. Particles including a very high proportion of recycled classifier rejects that have already been crushed, the coarse limestone particles act as individual “Hard spot" that offer high resistance to the rollers and cause them to lift slightly. The rollers with their mechanical or hydro pneumatic spring action then fall back onto the bed and performCorrespondingly more size reduction on the finer particles they then encounter. Moreover, these hard spot promote more intensive spatial re - arrangement of the particle of material in the bed and thus help to loosen it up, which likewise makes for more effective fine pulverization.

105

Grinding Speed

106

The grinding speed is determined by the dimensions of the grinding table and the magnitude of the centrifugal force needed for transporting the material. Apart from minor differences bound up with individual design feature of the various mills, the grinding speed is much the same in all the usual roller mills for any given grinding ring diameter.There is a characteristic value k which expresses the time of action of the grinding pressure (contact force per effective unit area) and provide a criterion for comparing roller mills differing in design:

k = Z PV W

kgsec

m2

z = number of rollers p = total contact force (kg )v = angular velocity. Rolling circle radius (m / secW = effective width of rollers ( m ).

The effective width of conically tapered rollers can be taken as 100% of the actual width of the contact surface, while for rollers with convex surface about 60% may be adopted. For convex surface roller, a more precise value can be found by examining the extent of wear on the rolling surface.

In Roller Mills size reduction take place by two mechanism : by crushing and by direct attrition on heavy bed of material. The particles of feed materials are gripped between the rollers and the grinding rings. The larger ones, which project above the other and are the first to be subjected to the crushing action, are broken. In conjunction with the reduction in size there occurs intensive spatial rearrangement of the individual particles under crushing load. The compressive and shearing forces associated with this have a further size reducing effect, mainly by attrition, which is indeed a key factor in achieving fine pulverization in a roller mill which in turn is a function of angle of friction between material and and the metal of grinding element. The limiting value of specific friction coefficient ( ) is constant for a given material. It is found that the larger the diameter of the grinding element, the larger the feed size it can be accepted. Contact area is proportional to Wd, where W is the roller width and d is the roller diameter.

107

Contact Area.

KW net( )

The theoretical power consumption of a vertical roller mill is expressed by the formula

N =

Where

KT A Z V

A = roller projected area m^2KT = specific grinding pressure kNz = number of rollers v = grinding track speed m/ secN = Mill power intake Kw

Capacity Of Roller Mill.

Rollers Projected Area

A = DR WR

DR = Roller diameter (m).WR = Roller width (m)

For Attox Mill The Flowing Applies

KTN

DR W

DRKT : typically 500 ~ 700

DR 0.6 Do Do

0.2 Do (m)

n =

108

W =

DM 0.8 Do Do

56

Do

Where

Do = Table diameter (m).

The following formulae apply for roller mills :

F = FR FH KN

where

F = Grinding force (kN).FR = Roller grinding force (kN).FH = hydraulic grinding force ( kN)Mr = Roller assembly weight one roller ( kg )

But kN FR = MR

9.811000

The grinding force consists of

109

Phyd Dcyl2 DPiston

2

4

100

FH =kN( )

And

The specific grinding pressure will then be

KTFA

kN

m2

KT DR WT =

Where

T = Roller pressure per roller (kN)KT = specific roller pressure (kN)DR = Roller diameter ( m )W = Roller width ( m)

110

DMn60

V =

V = velocity at mean diameter of track (DM) m/ sec DM = Mean diameter of track ( m).n = Table speed ( rpm)

The power absorption of each roller is the tangential load on the table * T times the velocity at the mean diameter of the grinding track. Expressed by the specific rollerpressure KT

N = z T V = z KT DR W DM n60

N = 0.844 KT D2.5Which inserted in the above equation gives This reveals that the capacity of vertical mill, by direct upscaling, grows with the dimension in

power 2.5. The capacity factor here 0.844 varies by different mills designs between 0.4- 1.0 .Most vertical mills for coal and cement raw meal are operated with a specific roller pressure KT between 400 and 800 kN/m^2.The coefficient of rolling friction is about 1/3 of the gripping angle. The gripping angle increases with the grinding bed thickness upto a certain critical value, depending on the material and to a lesser degree on the surface of the rooler. The friction coefficient therefore, also grows with the grinding bed thickness upto a certain limit, which with smooth roller is usually in the range as follows :

Friction coefficient

Cement raw material 0.09 +/ - 0.02Coal 0.10 +/ - 0.02Cement 0.06 +/ - 0.01

The specific power consumption N/P and thereby the mill capacity P, depends not only on the grindability of the material and the required fineness, but also on the efficiency of the classifier, the air flow and other operational parameter. Typical value for cement raw materials are in the range 5 ~ 8 kwh / ton.

Material Movement On The Table.

In vertical mills the grinding table not only functions as a grinding member but also as a spreader dishes that distributes and transport the fresh material to the rollers. The speed of the table is so high that the centrifugal force exceeds the materials' friction against the table. The material particles are therefore in constant sliding motion toward the peripheryof the table. For identical centrifugal field, the table rpm must be inversely proportional to the square root of the table diameter.

For optimum operation table speed should be at such a value, which will give low mill vibration and maximum capacity at minimum power consumption. Table speed is determined by its diameter and by the magnitude of centrifugal force required for transporting the material.Its value is same for all type of roller mills.

111

56 Do56

The high value gives a proportionally high production, also much higher vibration in case of hard materials. The shape of material layer and the movement of the particle are determined by the table profile, the table speed, the return of the material and friction against the table.

Roller mill production rate depends upon gas flow through the mill. Constant quantity of air flow is essential for stable mill operation. Mill output and gas flow can be approximated by a straight line exponential function.

Mill output =

Where V is the gas flow and a and b are the empical constant.Minimum specific air flow is needed to maintain the rate of production in roller mill to carry the feed through the mill, classifier, and dust collector. The mill fan capacity is kept at higher rate than the specified volume of gases to cope with changes in gas temperature in the mill circuit and possible false air supply. An average of 10 % is taken for false air. Normally 2.3 kg gases per kg of clinker are required for vertical mill to grind raw mix. Normally 1.8 to 2.00 kg preheater gases per kg of clinker are available, hence it is possible to use entire preheater gas in the roller mill.At the nozzle ring, a gas velocity of around 80 to 90 m/sec is maintained. Nozzles are normally inclined at 45 degree to the grinding table which gives cyclonic effect to the material leaving the grinding table and coarse particles are thrown against the wall. Following gas velocities are maintained inside the mill above the rollers.

Gas Flow Through The Mill.

a Vb

MPS And Polysius Make Roller Mills

For proper operation of air classifier, a gas velocity of 3.2 m / sec should be maitained at the rotor of the classifier and 10 m / sec at the mill exit

112

1.5 Do

Loeshche And Atox Make Roller Mills

2.5 Do

Where Do is the table diameter.

Mill Differential Pressure Adjustment.Mill differential pressure has a strong influence on mill capacity. Mill differential pressure is effected by grinding table speed. As table speed increases, more and more material is thrown on the table in the form to rain down evenly over the table area and the differential pressure increases which is an indicator for the mill loading and is always used for controlling the mill feed rate. Increase in product fineness also results in decrease in differential pressure. Mill differential pressure is controlled by feed rate to the mill and hydraulic pressure on rollers. Generally differential pressure in the mill in mm H2O is given by :

350 Dop =

Where Do is the outer diameter of the grinding table in meter. Differential pressure is limited by ability of the system fan to provide the static pressure.

Mill exit temperature is very important for proper mill operation. Changes in mill temperature is caused by variation in moisture content of the feed. Mill temperature is controlled by regulating hot gases flow into the mill. Changing mill exit temperature cause change in gas volume, hencechange in gas velocity inside the mill. Continuously varying mill conditions upset the internal balance of circulating load and destroyed the stability of the material bed .It has been found that fluctuating mill exit temperature results in reducing the mill capacities as much as by 50%.Generally mill exit temperature are maintained in raw mill at 85 to 95 oC and 80 to 85 oC in coal mill subject to the % of volatile matter. High mill temperature cause damage to seals, journals and bearings.

Mill Exit Temperature.

113

All vertical mills operate with some slippage or speed difference between the surface of the roller and the grinding table. The slippage generates shear forces that contributes to the grinding and prevent agglomerates. The maximum slippage at the sides of the rollers 9 and 44% of the roller speed. The slippage causes no extra wear. Practically it appears that slippage has very little influence on the roller wear rate. Experience shows that the wear primarily where the pressure is highest which is close to the rolling point a little outside the middle of rollers. This is due to compression which generates a far largerShear than the slippage.

Slippage And Wear In Vertical Roller Mill.

114

The clinker cooling process greatly influences the mineralogical composition as

well as the structure of the clinker. Besides this the grind ability and quality of the

cement is also affected by the rate of cooling. Clinker cooling is very essential because

of the following reasons,

1. Mechanical transportation of hot clinker to storage point is difficult to convey.

2. Hot clinker has negative effect on the grinding process.

3 Reclaiming of useful heat energy from hot clinker is about 200 kcal/kg clinker is an

important factor for lowering production cost.

4. Proper and effective cooling improves the quality of cement.

Selection Criteria Of Clinker Cooler The following requirement should be considered in choosing the

appropriate type of cooler

Obtaining good quality clinker by optimum cooling rate.

Final cooling of the clinker to the lowest possible temperature.

Maximum thermal efficiency.

Best adaptation to the burning system preceding the cooler.

Least possible pollution impact on the environment.

Low susceptibility to faults i.e. minimum down time.

Low capital cost.

Low power consumption.

Low wear and maintenance cost.

Favourable heat balance with a high degree of recuperation to obtain secondary

air temperature as stable and high as possible to achieve overall kiln operating

stability and good fuel efficiency.

Cooler exit air temperature should be as low as possible and volume as small as

possible to assure a minimal amount of heat wasted to atmosphere.

CLINKER COOLING

The sizes of cooler are normally designed on the basis of the the following

operating

parameters.

Grates specific loading 30 ~ 40 tpd per cubic meter of grates at nominal kiln

output.

clinker temperature cooler inlet 1350 ~ 1450, 0C

cooler outlet 65 ~ 100, oC

The cooling air required to reclaimed heat and obtained the desired temperature of

the clinker is 3 ~ 3.5 kg air/ kg clinker.

About 1.00 ~ 1.2 of the cooling air is used as secondary and tertiary air in the kiln

and precalciner and the rest of this air vented or utilized for drying in coal mill.

The cooler capacity and size is normally designed keeping in view the normal kiln

output and expected maximum kiln production per day.

G =

115

Cooler Selection Criteria On The Basis Of Cooler Size

1. Weight of clinker in the cooler,

G=A*h*ρG= weight of clinker in cooler (Kg)

A= area of the grates grate surface (m2) = 52.8

h= clinker bed depth (m ) = 0.500m

ρ = clinker density (kg/m3 ) = 1350 kg/ m3

Cooler Performance Calculation

A h

52.8 0.500 1350 3.564 104 kg

116

35.64 tons

The clinker retention time in the cooler can be calculated on

theoretical basis for the purpose of selection. The bed depth is directly

proportional to the grate speed. If the area of the cooler, the bed depth under

normal operating condition for a given kiln out put rate and density of clinker

are known, then the clinker retention time can be calculated by the equation:

T =( A*h* ρ) * 60/Gt

Area of grate surface = A = 48.6 m2

Clinker bed depth = h = 0.660m

Density of clinker = ρ = 1350kg/m3

T = ( 52.8 * 0.5 * 1350 * 60)/100000

= 21.4 min.

Clinker Residence Time In Cooler

V = 21.4 x 100000/(60 x 1350)

V = 26.42m3

=279166.167x 0.347

=96870.8 m3/hr

117

Volume Of The Clinker Residing In The Cooler At Any Time

V = T*Gt/ (60* ρ )

Gt = Grate Speed

One of the most commonly used way of designating the efficiency

of cooler is by using the heat recuperation efficiency. The heat

recuperation efficiency expresses the ratio of the heat contained in the hot

clinker to the cooler that is returned to the preprocess in the form of

secondary and tertiary air

Secondary and tertiary air required for heat saving kilns per kg of

clinker at the rate of 0.85 ~ 0.95 NM^3/kg of clinker. herefore, secondary

air required per kg of clinker is assumed in the range of 0.347 to 0.373

NM^3 as well as he tertiary air 0.569 ~ 0.587Nm^3

Kiln production per day= 6700 tons

6700 x 1000/24 = 279166.67 kg/hr.

Secondary Air Required Per hr

Density of ir at NTP = Do = 1.21 kg/m3

=11213.67/279166.67

Q = mCp(T2-T1)

=0.419*0.239*(825-25)

=80.12 kcal/kgxcl

118

Volume of secondary air at NTP = 96870.8Nm3

Mass of secondary air at NTP = m = Do* Vo

=1.21*96870.8

=117213.67 Kg

Kg Of Secondary Air Required Per Kg Of Clinker

=0.419

Heat Contents In Secondary Air

=163870.83m3/kg cl

Do=1.2m3/kg

=196644.99/279166.67

=0.704kcal/kg cl

=0.419*0.235*(975-25)

119

Tertiary Air Requirement

Kiln output rate = 279166.167kgs/hr

Tertiary air required per kg of clinker = 0.587 Nm3

Therefore tertiary air required per hr = 279166.167*0.587

Vo=163870.83m3

DomVo

Vo

M =163870.83*1.2

=196644.99 kg

Kg Of Tertiary Air Required Per Kg Of Clinker =

Heat Contents From Tertiary Air =

=93.54kcal/kg cl

Do= 1.21m3/kg

Vo= 279167x1.363

=380504.621m3

Mass = 380504.621*1.21

= 460410.59kgs

120

kgs of tertiary air required per hour = 117213.67kg

kgs of tertiary air required per hour =196644.99 kg

killn out put rate=279.167ton/hr

=279.167*1000

=2.79x105 kg/hrVent Air At Cooler Outlet

vent air at cooler outlet is exhausted at the rate of 1.363 ~ 1.4 Nm3 per kg of

clinker.

r

Kg of excess air per kg of of clinker in cooler

=460410.59/279167

=1.65 kg of excess air/kg of clinker

BALL MILL

The Critical Speed

The critical speed of a ball mill is that speed of rotation at which the

centrifugal power neutralizes the force of gravity which influences the grinding

balls; the grinding ball do not fall and therefore, perform grinding work.

Critical speed = n = 76.6/√3.6

Dia Of The Ball Mill

Basis capacity = 6700 ton/day

According to Tavrov’s formula

Q = q× (a×b×c)/1000×6.7×v×√D.√GN

121

Where

V = Volume = Π/4*d2 * L

Q = Mill capacity

q = Specific mill capacity = 40kg\kwh

a = Grinding index = 0.7143 ×1.2+0.2857 ×1.4 = 1.26

b = Correction index for fine grinding = 0.82

c = Correction type for mill type =0.9

N = No. of revolutions 1/4*d2

Putting all above parameter in eq.

279.167 =40× (1.26×0.82×0.9)/1000×6.7×п/4×D2L√D√(D2L/(1/4)D2L)

D2.5L = 713.98

Since for Ball mill

L/D = 2

Let

L/D = 2.8 (length to dia ratio)

D2.5L = 713.98

D =4.87 meter

Dia of ball mill =4.87 meter

Length of ball mill = 4.87×2.8 =13.64m

Therefore, critical speed =76.6/√4.87 =34.71RPM

Working speed is 65.90% of critical speed

So,

122

N =32/√D

=32/√4.87

= 14.47 RPM

Critical speed = 34.71 RPM

Working speed = 14.47 RPM

Optimum speed is one half or one third of critical speed.

Dynamic Angle Of Repose Of Grinding BallsTheoretical calculation shows that the maximum kinetic energy of the fall balls is

at a dynamic angle of repose equal to 35˚ 20’. Some time its value is 54˚40’.

Distribution Of Grinding Media In The Mill Cross SectionSince angle of repose =35˚20’

It means 35% of total ball is lifted and 63% of the total grinding ball falls.

Degree Of The Ball Charge For steel ball = 28-45%

For sylphs = 25-33%

Total Grinding Ball Charge

According to stierninG = 4000 D2L

Where

123

G = total weight of ball charge in kg.

D = inner dia of mill in meter = 4.87m

L = useful mill length =13.64m

G = [4000(4.87)2 ×13.364] /2

= 649843.06kg

=649.84 ton

Grinding Ball Charge And Clinker Load

According to MardulierSteel ball charge/clinker charge =8.1 to10.1

Steel ball charge = 45% of total ball

So,

weight of ball charge = 649.84×0.45

= 292.43ton

Therefore, clinker charge =292.43/10 = 29.24 ton

Ball Mill Power Demand

Empirical formula for Ball Mill Power

P = 12.5×G

G = 649.84 Ton

124

P = 12.5×649.84

= 8123 Hp

Blanc’s formula

P = C.G√D

C = index relating to grinding ball and mil charge (From grinding index,Peery)

C = 7.00

G = 649.84 Ton

D = 4.87 m

P = 7.0 × 649.84 ×√4.87

P = 10038.5 Hp

Bond’s Equation

W = [10w√P]-[10w√F]

Basis capacity = 6700 Ton/day

Gypsum = 352 ton/day

Clinker = 6700 Ton/day

Standard size of clinker 80% passing 9/16 inch F = 14300microns

Standard size of cement

80% passing through 37 microns

Work index for clinker

13.49×1.3 = 17.53

(1.3 is dry grinding factor)

125

Apply Bond’s Equation

W = 10×17.53 - 10×17.53

√37 √14300

= 28.83 – 1.46 = 27.7 kwh/ton

= 27.37×1.113 = 30.46 kwh/ton

1.113 = cement fine product fraction

Cement production =293.833ton/hr

= 293.833×30.46

=8950.15 × 1.341

Power = 11993.2 hp

126

Site Selection

Site Selection

Raw Materials Availability The source of raw material is one of the most

important factors influencing the selection of a plant site. This is partially true if

large volumes of raw material are consumed, because location near the source

of raw material permits considerable reduction in transportation and storage

charges, attention should be given to the purchased price of the raw materials,

distance from the source of supply, freight or transportation expenses, availability

and reliability of supply, purity of the raw material and storage requirement.

127

Market The location of markets or intermediate distribution center affects the cost

of product distribution and the time of shipping. Proximity to the major markets is

an important consideration in the selection of a plant site, because the buyer

usually finds it advantageous to purchase from nearby source. Note that markets

are needed for by-product as well as for major final products.

Energy Availability Power and steam requirements are high in most industrial

plants, and fuel is ordinarily required to supply these utilities. Consequently,

power and fuel can be combined as one major factor in the choice of a plant site.

Electrolytic processes require a cheap source of electricity. If the plant requires

large quantities of coal or oil, location near a source of fuel supply may be

essential for economics operation.

Climate If the plant is located in a cold climate, cost may be

increased by the necessity for construction of protective shelters around

the process equipment, and special cooling towers or air conditioning

equipment may be required if the prevailing temperature are high.

Transportation Facilities Water, railroads, and highways are the common means

of transportation used by major industrial concerns. The kind and amount of

products and raw material determine the most suitable types of transportation

facilities. In any case, care attention should be given to local freight rates and

128

existing railroad lines. The proximate to railroad center and the possibility of

canal, river, lake, or ocean must be considered.

Water Supply The process industries use large quantities of water for cooling,

washing, steam generation, and as raw material in plants, therefore, must be

located where dependable supply of water is available. A large river or lake is

preferable, although deep well or artesian wells may be satisfactory if the amount

of water required is not too great.

Waste Disposal In recent years, many legal restrictions have been placed on the

methods for disposing of waste materials from the process industries. The site

selected for a plant should have adequate capacity and facilities for correct waste

disposal. Even though given areas have minimal restrictions on pollution, it

should not be assumed that this condition will continue to exits.

Labor Availability The type and supply of labor available in the

vicinity of a proposed plant site must be examined. Consideration should be

given to prevailing pay scales, restrictions on number of hours worked per week,

competing industries that can cause dissatisfaction or high turnover rates among

the workers, and variation in the skill and productivity of the worker.

Taxation And Legal Restrictions State and local tax rates on property income,

unemployment insurance and similar items vary from location to another.

129

Similarly, local regulations on zoning, building codes and transportation facilities

can have major influence on the final choice of a plant site.

Site Characteristics Characteristics of the land at a proposed plant site should be

examined carefully. The topography of the tract of land and the soil structure

must be considered, since either or both may have a pronounced effect on

construction costs. The cost of the land is important as well as local building

costs and living conditions. Future changes may make it desirable or necessary

to expand the plant facilities.

Flood And Fire protection Many industrial plants are located along rivers or near

large bodies of water, and there are risks of flood or hurricane damage. Before a

plant site is chosen, the regional history of natural events of this type should be

examined and consequences of such occurrences considered. Protection from

losses by fire is another important factor in selecting the plant location. In case of

a major fire, assistances from outside fire departments should be available. Fire

hazards in the adjacent areas of plant site must be overlooked.

130

Community FactorsThe characters and facilities of a community can have quite an effect on

the location of the plant. If a certain number of facilities for satisfactory living of

plant personals do not exist, it often becomes a burden for the plant to subsidize

such facilities. Cultural facilities of the community are important to sound growth.

Mosques, libraries, schools, civil theatres etc do much to make a community

progressive. Recreation activities deserve special considerations.

131

PLANT SAFETY

PLANT SAFETY

OPERATIONAL SAFETY AND PRECAUTIONS The ultimate goal of safety and fire protection is

the complete protection of personnel injury, loss of life and destruction of

property as a result of accidents, fires, explosion or other hazardous situation.

The process industries introduce a wide range of hazards as a result of presence

of sizeable quantities of flammable and sometimes unstable materials,

132

Frequently at high temperature, which promote

ignition or decomposition with high pressure the potential energy release is

increased in the presence of structural failure, explosion, detonation, or violent

exothermic reaction.

In order to safeguard against accidents due

mechanical failure under severing operating condition, the equipment should be

designed to meet the specifications and need of recommended authorities. For

example, the design and construction of pressure vessels and storage tanks

should follow A.P.I or A.S.M.E. codes, and they should be tested two or more at

the design pressure.

Beside consideration of safety in the design of

equipment, it is essential to select adequate instrument and control for safe

operation. Safety beside other factor acts as a guide-line in the design of control

system.

Clear and effective operating procedures play an

important role in safe operation of chemical plant. The equipment manufacturers

normally provide operating instructions. But, in the plant where hundreds of small

units are held it is necessary to lay down standard operating procedure (S.O.P)

to ensure safe start up, operation and shut down.

Accident on plant often results during handling and storage of hazardous

material. Injury to plant personnel may also result due to the toxicity of chemical

being handled. It is therefore necessary to have a full understanding of chemical

and physical properties of the materials being handled.

1. Delayed symptoms accruing within 48 hours after breathing light nitrous

oxide fumes. This form of poisoning occurs most frequently in industry.

2. Mild immediate effects from which recovery is apparently complete after

which pneumonia eventually follows:-

In type case of `NO` poisoning, the sequences of events may be:

i) A few breaths of apparently harmless gas.

ii) Only slight discomfort with the worker continuing his job.

133

iii) 5-8 hours after exposure, the victim’s lips and ears become

cyanotic.

3. Increasing difficulty in breathing follows, accompanied by chocking,

dizziness and irregular respiration. Severe untreated cases frequently

terminated fatally from excessive pulmonary congestion or suffocation.

Remedial measures to be taken as soon as possible after an indication

that poisoning has occurred are:

i) Patient should be moved to uncontaminated atmosphere and no

physically excretion permitted. But result should be enforced.

ii) Patient should breathe 100% Oxygen for 30 minutes every 6

hour. If after this time breathing is normal O2 inhalation may be

discontinued.

iii) During period of O2 inhalation patient should exhale against a

positive pressure of about 4 cm water unless there is indication

or history of cardiovascular failure. This is intended to prevent

the development of pulmonary.

134

COST ESTIMAION

135

COST ESTIMAION

COST OF PRODUCTION

MaterialThe cost of raw materials differs with in wide limits between one plant and

another. Factors affecting it are royalties payable, the nature and accessibility of

the deposit, its hardness the amount of overburden the depth available and are

proximity to the works. A hard stone which requires drilling and its blasting before

it can be handled will necessarily cost more per ton than soft material which can

be dug direct with a digger. Again, as the removal of overburden is and

unremunerative operation it adds to the cost in proportion to its depth. if there is

little material available above water level we may be necessary to go lower, in

which the case of cost continued pumping is incurred except in the case of clay

or soft chalk, which can be dug below water. If the quarry is reasonably close to

the works it may be found convenient to erect the crushing or washing plant in

the quarry, and when the wet process is adopted the slurry can be conveniently

pumped to the works. On the other hand, it may be necessary to load the

material into trucks or vessels and convey them for long distance.

Labor Unless labor is exceptionally is cheap, hand labour must be replaced by

machinery in every department, and an output of two tons or more per day for

every man employed on manufacturing operation may be looked for in modern

plant. This takes no account of men employed on repair work or on packing ang

shipping, and is of course only an approximate guide. It varies with the

arrangement and equipment of the factory, and especially in cases where raw

material or power may be purchased.

136

Fuel

The type of coal is to be used is usually settled by considerations of

price, the particularly applies to the coal used for burning where something like

one quarter of the work cost of manufacturing. Cement is incurred. Some coals

are so high in ash content, or otherwise unsuitable, that they are not satisfactory

no matter how they cheap may be. In England bituminous coals of fair quality are

so readily obtainable that price becomes the final arbiter, and this in turn is

affected by the relative positions of cement works and collieries and the means

and cost of transport. In the best modern practice not more than 5 cwt. Of coal of

12,600 B.T.U's per lb. are used for burning a ton of cement on the wet process,

and approximately 1 cwt. less per tons on the dry process. Oil is not used in

British works as its cost is high in comparison with coal.

Power

Coal for power is usually of a more specialized character, depending

upon the type of power plant, and as the tonnage required is so much smaller

than that used in burning the higher cost of the selected quality is not of such

serious import. If waste heat boilers are installed and power is obtained from the

kiln gases, than the quantity of power coal required is further reduced. When

electric power coal required is obtain from the kiln gases, and then the quantity of

power coal required is further reduced. Where electric power is purchased its

cost is usually on a sliding scale subject to coal prices and other factors.

Agreements for such supplies customarily contain provisions for peak and

minimum loads and in designing a new plant a careful balancing of units should

be made in order to secure a constant load factor.

137

Other Supplies:

Gypsum, stores, lubrication oils etc. are usually purchased and costs can

be calculated fairly accurately as a rule about 5% of raw gypsum stone is

likely to be used. Some cements works have contracts under which their

requirements of lubricants are supplied at a fixed price per ton of cement

produced. Haulage and transportation again are much influenced by the

location of the works in relation to material deposits and market. Machinery

repairs and replacement are usually a heavy item, and the saving which

can be affected under this head in designing a new plant is often

considerable. The item, of course, tends to rise in every plant as time

passes, and cement works machinery, notwithstanding its robust

construction, has a relatively short life.

Overhead Charges

The cost of administration and management is usually the inverse ratio to the

output, the larger the plant the less the cost per ton under this head. Rates and

taxes, and insurance may amount to as much as 6 to 8 %of the manufacturing

cost. Allowances of depreciation and obsolescence of plant and machinery

should be at least 5% of their first cost and may well be 10% in some cases if a

sound and conservative financial policy is purchased. Charges for raw materials

depletion and reserves will depend upon very variable factor, and must be

determined separately in each case.

138

COST ESTIMATION OF PROJECT Before an industrial plant can be put into operation, a large amount of

money must be supplied to purchase and install the necessary machinery and

equipment, land and service facilities must be obtained and plant must be

created complete with all piping, controls and services. In addition it is necessary

to have money available for the payment of expenses involved in the plant

operation.

PURCHASE EQUIPMENT COST On way of estimating the equipment cost is by the use cost indexes.

Because prices change considerably with time, due to change in equipment cost,

other specifically to labor construction material or other specialized fields. A cost

index is merely a number for given year showing the cost at that time when the

past value is known. The equitant cost at the present time will be:

Purchased Equipment Cost = Original cost x (Index value at present time index) x (Capacity of present plant ) 0.6

(Value at time original cost is obtained)(Capacity of original plant)0.6

The value of Marshal and Steven installed equipment index process for

process industry, with base year 2005=1152, and in 2008 it is 1200.

On the other hand, to estimate the cost of equipment when no cost data are

available for particular size or operational capacity involved the Logarithmic

relationship known as "Six-tenth-factor rule" is quite effective. According to this

rule, if cost of the given unit at capacity is known, the cost of similar unit with x

time the capacity of the first is approximately (X)0.6 time the cost of the initial unit.

139

PURCHASED EQUIPMENT COST

Purchased equipment cost can calculate by capacity ratio method or what is

known as “Six-tenth-factor rule”.

From a working industry purchased equipment cost for

Purchased equipment cost for 2500 ton per day on dry basis =1.57x109 Rs.

For 6700 ton per day capacity of same plant

Purchased Equipment Cost E = Original cost x (Index value at present time index) x (Capacity of present plant ) 0.6

(Value at time original cost is obtained)(Capacity of original plant)0.6

E = 1.57x10)9x (1200/1152) x (6700/2500)0.6

E =2.95x109 Rs.

140

Total Direct Cost Purchased equipment cost = 2.95x109 Rs.

Purchased equipment installed = 39% E

= 2.95 x 109 x 0.39

= 1.15x109 Rs.

Instrumentation installed = 26% E

= 2.95 x 109 x 0.26

= 7.6x108 Rs.

Conveyor Belt installed =31% E

= 2.95 x 109 x 0.31

= 9.14x108 Rs.

Electrical (installed) = 10 %

= 2.95 x 109 x 0.1

= 2.95x108 Rs.

Building (included services) = 29% E

= 2.95 x 109 x 0.29

= 8.55x108 Rs.

Land = 6% E

= 2.95 x 109 x 0.6E

= 1.77x108 Rs.

Yard improvement = 12% E

= 2.95 x 109 x 0.12

= 3.54x108 Rs.

Service facilities = 55% E

= 2.95 x 109 x 0.55

= 1.62x109 Rs.

Total Direct Cost = 9.075x109 Rs.

141

Indirect cost

Engineering and supervision = 32% E

=2.95 x109 x 0.32

= 9.44x108 Rs.

Construction Expenses = 34% E

=2.95x109 x 0.34

= 1.00x109 Rs.

Legal expenses = 4% E

= 2.95x109 x 0.04

= 1.18x108 Rs.

Contractor fee = 19% E

= 2.95x109 x 0.19

= 5.61x109 Rs.

Contingency = 37% E

= 2.95x109 x 0.37

= 1.09x109 Rs.

Total Indirect Cost = 3.713x109 Rs.

Fixed Capital Investment = 9.075x109 + 3.713x109 Rs.

= 12.788x109 Rs.

142

Working Capital Investment = 15% ( Fixed Capital Investment)

= 0.15x12.788x109

= 1.92x109 Rs.

Total Capital Investment =Fixed Capital Investment + Working Capital Investment

=12.788x109 + 1.92x109

Total Capital Investment = 14.69x109 Rs.

Cost of Production

Variable Cost Rs. /Ton Rs. /Bag

1. Raw and Packing Material 326.93 16.352. Fuel and power 1432.03 71.603. Stores and Spares 154.74 7.74 (Including Repair & Maintenance)

Subtotal 1913.70 95.69

Fixed Cost1. Salaries & Wages 156.67 7.832. Depreciation 206.65 10.333. Admin & Selling Expenses 97.19 4.864. Financial Expenses 378.69 18.935. Misc.Expenses 93.05 4.65

143

Sub Total 932.25 46.61Total Cost of Production 2,845.95 142.30(Variable Cost + Fixed Cost)

Market Price

Cost of production 2,845.95 142.30 Excise Duty 750.00 37.50 Sales Tax @ 15% 539.39 29.97Average Freight & Un-loading 600.00 30.00 Dealers Commission 140.0 7.0Manufactures profit @ 10% on Equity 497.54 24.88

Market Price (Total) 5,372.89 268.64

Pay out Period of the Plant

Pay out period = total capital investment Annual profit + annual depreciation

Total Cement produced per day = 6700(clinker) + 352 (gypsum 5% )

= 7052 ton/day

144

Annual Profit = 497.54 x 7052 x 300

= Rs. 1052595624

Annual Depreciation = 206.65 x 7052 x 300

= Rs. 437188740

Total Capital Investment = Rs. 14.69 x 109

Pay out Period = 14.69 x 109

1052595624 + 437188740

= 9.86 years

145

Instrumentation & Process Control

Instrumentation And Process Control

No plant can be operated unless it is adequately instrumented. The

monitoring of flow .pressure, temperature and level is necessary in almost every

process in ordered that the plant operator can see that all parts of plant are

functioning as required. Additionally it may be necessary to record and display

may other quantities which are more specific to the particular process in

question. For example, the composition of process stream, the heat radiation

produce or humidity of the gas stream.

146

OBJECTIVES: The primary objective of the designer then specifying

instrumentation and control scheme are;

Safe Plant Operations: To keep the process variables within known safe operating limit

To detect dangerous situations as they develop and to provide alarms and

automatic shutdown system

.

Production Rate: To achieve the design product output.

Product Quality: To maintain the product composition within the specified quality standards.

Cost: To operate at the lowest production cost.

Hardware Elements Of Control System:

Process: “Material together with equipment, the physical and chemical

operation that occurs” is called process.

Measuring Elements: The instruments used to measure the process variables such as;

Pressure

Temperature.

Flow rate.

147

Level.

Transducers:It converts the unstandard signals (sensor signal) into standard signals (control

signals).

Transmission Lines: These are used to carry the signals from measuring device to controller.

Standard electronic signal 4-20 mA.

Standard pneumatic signal 3-15psig.

Controller: It generate the error by comparing process signal with set point and

sending theses signals to final control elements.

Final Control Element: It receives the signal from the controller and by some predetermines

relationships changes the energy input to the process.

Recorder: It is used to give the visual demonstration about the behavior of the

process.

General Control Systems:Following are the important general control systems.

Open and close loop system.

Feedback control system.

148

Forward control system.

Combined control system.

Cascade control system.

Open Loop System: Control system in which information about the

controlled variable is not used to adjust any of the system inputs to compensate

for variation in the process variables. These terms is used to indicate

uncontrolled process dynamic.

Closed Loop System: The control system in which the controlled

variable is measured and the result of this measurement is used to

manipulate one of the process variable.

Feed back Control System: In a close loop control system

information about controlled variable is feed back as the basis for the controlled

of the process variable .for automatic control ,a measuring device is used as the

signal. The signal is feed to a controller, which compare it with a preset desired

value or set point, if a difference exists the controller send a signal to final control

element.

Forward Control System: Process disturbances are measured and

compensate without waiting for a change in a controlled variable, to indicate a

disturbance has occurred. It is also useful when a final controlled variable cannot

be measured.

149

Combined Control System: Forward feed control system can

rarely fulfill the entire control requirement so that feed control is normally used in

combination with forward feed control system .such arrangement reduces

accuracy and amount of process knowledge ,detailed requirement for

specification of transfer function.

Cascade Control System: It is often used for minimizing disturbance

entering in a slow process. it also speed up the response of the control system

by reducing time constant relating the manipulated variable process output.

Instead of adjusting the final control element such as control valve, the output of

primarily controller is made the set point of secondary controller.

Modes Of Control:The various type of control are called “mode” and they determine the type of

response obtained. in other words these describes the action of the controller

that is the relationship of output signal to the input or error signal .it must be

noted that it is the error that actuates the controller. The four basic modes of

controls are;

Proportional control

Proportional derivative control

Proportional integral control

Proportional integral derivative control.

150

Proportional Control: The output of proportional controller is fixed

multiple of the measured error, that is, proportional controller is simply a

multiplier. In this control system the controller variable is measure and signal is

compared with a set point. The difference is the error

() Manipulated variable derives the final control element.

Which is amplified Kc times by proportional gain. The output of proportional

controller,

This controller is used when precise control is necessary. Offset and oscillatory

response is tolerated. A special type of proportional control is on off control. it is

simplest and most common mode of control such as thermostat used in space

heating and refrigeration.

Proportional Derivative Control: In this kind of control,

offset remains but response to any change becomes smooth i.e. problem of

oscillatory response can be overcome by use of this type of controller.

Proportional Integral Control: The output of Proportional integral control

consists of two parts, the first proportional to the error and second proportional to

the integral of the error. Even small errors can eventually provide enough

controller output to force the error to zero. This controller removes the offset but

response of the system to a change may not be smooth.

Proportional Integral Derivative Control: Three modes of

controller combine an action of Proportional, integral and derivative

elements into a single events. proportional elements give faster transient

151

response but more oscillatory, integral element eliminates steady state

offset and derivative elements allows higher proportional gain. This kind of

controller is used to give very precise control and it is most expensive of

all.

Typical Control SystemA collective general description of the instruments used will be given which may

be conveniently divided into following groups.

Temperature recorder

Temperature indictor controller

Level controller

Pressure controller

Flow controller

Temperature recorder

The thermo couples are the most common Temperature measuring devices,

particularly in industry. Since mercury may react with chemicals to form explosive

components, the use of mercury filled pressure spring thermometer is avoided.

These are used to measure Temperature of the stream entering the units.

Recommended Thermocouple

For Kiln Process

Type – R- positive wire is PT 87-RH13

- negative wire is platinum

- milli volts (minimum to maximum) per oC = 0.00645 – 0.0118

- Temperature Range -18 to 1704oC

- Good at high temperatures, poor below 538oC

-

152

Temperature Indicator Controller: The normal method of

controlling a heat exchanger is to measure the exit temperature of the fluid

being processed and to adjust the input of the cooling or heating medium

to control the desired temperature. Therefore temperature recorder

controllers are installed to control the heat exchanger.

Level Controller: In any equipment where interface exits between two

phases (e.g. liquid, vapor) some, means of equipments as is usually done

for the automatic control of the flow from the equipment.

Pressure Controller: Pressure control will be necessary for most system

handling vapor or gas. The method of control will depend on the nature of

process.

Flow Controller: Flow control is usually associated with inventory control

in a storage tank or other equipment. There must be a reservoir to take up the

changes in the flow rate. To provide flow control on a compressor or pump

running at fixed speed and supply a near constant volume output, by pass control

would be used.

Alarm & Safety Tips: Alarms are used to alert the operators of serious

and potentially hazardous, deviations in process conditions .key instrument are

fitted with switches and relays to operate audible and visual alarms on the control

153

panels. Where delay or lack of response by the operator is likely to lead rapid

development of a hazardous situation. The instruments would be fitted with a trip

system to take action automatically to alert the operators, such as shutting down

pumps, closing valves, operating emergency system.

The basic components of an automatic trip system are;

A sensor to monitor the control variable and provide an output signal when

present value is exceeded.

A link to transfer the signal to the actuator usually consisting of the system

of pneumatic or electric relays.

An actuator to carry out the required action, close or open the valve,

switch off motor.

Interlocks: Where it is necessary to follow a fixed sequence of operations,

interlocks are included to prevent operators departing from the required

sequence. They may be incorporate in the control system design as pneumatic

or electric relay or may be mechanical interlocks. Various propriety special

interlocks and key system are available.

THE LETTER CODES FOR INSTRUMENT SYSTEM

Property measured

First lette

Indicating only

Recording only

Controlling only

Indicating and

Recording and

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r controlling

controlling

Flow rate F FI FR FC FIC FRC

Level L LI LR LC LIC LRC

Pressure P PI PR PC PIC PRC

Temperature

T TI TR TC TIC TRC

Radiation R RI RR RC RIC RRC

Weight W TI WR WC WIC WRC

Quality analysis

Q WI QR QC QIC QRC

NOTE: The letter A can be added to indicate the alarm, with H and L

placed next to the instrument circle to indicate high or low.

D is used to show difference or differential, PD for pressure differential.

F as the second letter indicates ratios e.g. FFC = flow ration controller.

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The first letter indicate the property measured e.g. F = flow subsequent letter

indicate the function e.g. I = indicating.

RC = recorder controller.

The suffixes E and A can be added to indicate the emergency action and / or

alarm functions. The instrument connecting lines should be drawn in manner to

distinguish them from the main process lines. Dotted or crosshatched lines

normally used.

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ENVIROMENTAL PROTECTION &

ENERGY UTILIZATION

ENVIROMENTAL PROTECTION AND ENERGY UTILIZATION

ENVIROMENTAL PROTECTION IN THE CEMENT INDUSTRY

The cement industry’s duties in the relation to the environment come price

mainly the following form of population:

1. Prevention of air population;

2. Noise abatement;

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3. Prevention of vibration;

4. Protection of landscape and watercourses.

Environmental protection has for many decades been par and parcel of the

entrepreneurial problems of our industry. it is gratifying to note that cement

manufacturing to note that cement manufacturing activities are not among those

industries that more particularly come in for criticism in the public debate on

population prevention. I can furthermore be noted that the cement industry has

recognized and accepted the principle of causer responsibility before it became a

subject of conservationist discussion.

Expert understanding of this comprehensive statutory requirement and their

implementation calls more and more for not only the technical knowledge of the

cement engineer, but also for substantial legal knowledge. The professional

image of cement and process engineer will therefore have to undergo an

evolution towards the training of environmental engineering legal experts.

The consequences of this mass of legislation as a cause of cost and as

a deterrent to investment are something that may also appropriately be

mentioned at this point.

COST OF ENVIRONMENTAL PROTECTION

In terms of amount spent by industry as a whole upon environmental

protection, the rock product industry and thus the cement industry occupies a

leading position.

As revealed by the latest survey conducted by the institute of expenditure on

environmental protective measures in the rock products industry in the years

1971-1975 amounted to 105 of the overall capital expenditure. The order of

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magnitude of the operating cost in respect to environmental protection can at

present only be estimated within approximate ranges

All public discussions on the burden that that can be imposed on the

economy in fulfillment of environmental protection requirements should be on

based on considerations of effect upon return on investment.

ENVIROMENTAL PROTECTION AS A PROBLEM OF PLANT LOCATION: In the past, the prerequisite condition for establishing

new cement plant sites or for the expansion or reestablishment of existing plants

consisted in satisfactory coming to terms with the conventional planning factors

such as raw material availability technical infrastructure, marketing possibilities

and earning power.

In recent years, however new planning criteria such as regional

development, zonal economic planning, anti pollution planning, scheme for built-

up-areas, land scope preservation and nature reserves, to mention just a few

have emerged as important factors in deciding where to locate a cement work.

The latitude and scope available for varying the sitting of the work are further

narrowed down sometime to point of impracticability, by the imperative need to

remain close to the source of raw material. A further difficulty is that the forward

planning of public authorities more particularly the municipalities seldom

extended for more than ten years ahead. Whereas planner concerned with

industrial raw material supplies have to think in term of 30-50 years in assessing

the development potential of site if a dependable decision as to plant location is

to be made.

In addition to this uncertainty of planning there accrued changes, relatively

short notice, in the requirement imposed by the environmental protection

regulations. The statutory requirement on completion of the official approval and

licensing procedure are often found to change in relation to these, which existed

at the start of planning of an industrial project, has become an entrepreneurial

risk.

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The minimum distance of industrial and commercial installations from

residential areas, which in instances have to be compiled with also, increase the

area of land required for quarries and cement works. Thus the total area required

for quarry and works site is increased almost fourfold.

IMPACT OF ENVIRONMENTAL STANDARDS ON ENERGY CONSIDERATION: The cement industry in Pakistan has been

observing environmental standards for the fall out of dust from Raw Dry grinding,

cement grinding, packing, by controlling emission of dust by bag filters and

electrostatic precipitator. The clinker dust in air is collected in multi cyclones

before discharge. We need a constant check and efficient use of this equipment

and may also go in for improved equipments where necessary. But we are not

controlling fall out of dust from the flue gases of existing to two stage suspension

preheat kiln in due course of time and will have to install electrostatic

precipitators in such units. In these kiln where conversion would not be possible,

we would have to go for dust collection equipment for flue gases. The other

aspects of environmental standards are the following;

1-Noise abatement

2-Prevention of vibration

3-Prevention of land scope and water courses

These aspect have not been received much attention in Pakistan as mostly

the factories were as, with the tremendous growth in cities residential areas have

stretched to cement factories in some cases. We will have to take cognizance of

these facts ultimately for the existing factories and for planning the new sites for

cement factories.

Sound insolating buildings may be necessary in some cases and ventilation

through silencers coupled with cooling the building may be required, in future.

The energy requirement will increase in future for observing environmental

standards.

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TECHNICAL AND MANAGERIAL IMPEDEMENTS FOR IMPROVING ENERGY EFFICIENCY

The great demand of cement in country is keeping the industry in working on

top speed and improvement in energy efficiency us not receiving the attention as

it should as it would entail more stoppage for modification and conversion which

cannot be afforded at present. But this to some extent, is compensated by high

capacity utilization about 90% and keeping the imports of cement to minimum

possible. The new projects however being planned on energy efficient modern

processes.

The government and industry relationship is quite good there is a barrier in

improving energy efficiency. As a matter of fact, the government is keeping

abreast of energy consumption and requirement of the industry. There is

incentive to employees on production basis, which also help in energy efficiency

indirectly.

The most important impediment in energy efficiency improvement is in training

and technical assistance. The cement technology like other technologies is

developing fast and it will be difficult to have improvement in energy efficiency

without imparting good training and giving assistance to developing countries for

operating modern energy saving cement plants efficiently. The training and

assistance to developing countries for operating modern energy saving cement

efficiently. The training and assistance should be in operation, maintenance and

instrumentation so that the developing countries are able to keep the automatic

control system in every good condition. The training in the latest energy efficient

plants should not be less than the six months in any field It will be of interest to

note that when cement factories were being established in fifties and sixties, the

training period of personnel varied from six months to a year. Such training

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should be given to middle management technical personnel ant technical

assistants in the form of experts should also be provided

.

FUTURE TREND IN ENERGY EFFICINCY AND SUGGESTIONS OF STRATEGIES

1. The pattern of consumption of energy in cement industry is;

75% to 95% energy as fuel for drying and calcining process and 10-25% for

generating electrical power consumed. There has been much improvement in

efficient use of fuel energy during the last 25 years; the modern dry process

suspension preheated kiln with calcinatory has improved the efficiency of energy

utilization from (28 to 50%) of the theoretical requirement. The improvement in

utilization of electrical energy about 75% is in the raw meal and cement grinding

processes, where the utilization of energy efficiency has not exceeded 20% The

useful utilization is not in size reduction and greater part of energy emission is

lost in the form of friction, heat and noise emission.

The only useful utilization of fuel energy in cement industry is for calcining

and for drying the raw materials and slurry. We should therefore go in for dry

process as for as possible and wet grinding is necessary; we should filter the

slurry to a reasonable moisture, for drying by the hot gases from two stage

preheated kiln.

The losses of fuel energy on other side are;

Losses through flue gases.

Losses through cooler, sealing rings.

Losses through radiation.

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MODREN FOUR STAGE SUSPENTION PREHEATER KILN

The present day suspension pre heater-calcinator kiln utilizes the energy

in the flue gases and hot gases from cooler for drying the raw material and

source of air to calciner. The improvement of pre calcination process in

suspension-preheated kiln has increased the calcinations. From 40-90% in the

suspension preheated by secondary firing from a pre calcining furnace installed

between the preheated and kiln inlet. This increase the kiln output capacity for

the same kiln volume and vice versa. This kiln capacity may be increased by

70% the thermal load in the kiln is reduced which increases the refectory life kiln

availability.

EFFICIENT USE OF CEMENT IN CONCRETE

The structural use of cement is governed by various codes where the use

of cement is properly controlled, in relationship to quality, quantity of cement,

aggregates and environmental conditions. Presently mixes are specially

designed according to strength, which they give on maturity and this varies from

aggregates to aggregate.

The codes are fairly broad based and for larger works these can be further

refined where the quality control could be employed. However in smaller jobs

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where the quality control cannot be established properly, some extra use of

cement is unavoidable. In this respect the design parameters and limitations laid

in various codes, need proper implementation.

The efficient use of cement can further be ensured by maximum utilization

of pre casting and pre stressing techniques which;

1. Reduces the consumption of cement as well as steel, which is also a

sources and imported item in many developing countries.

2. Produces high strength concrete under factory-controlled conditions,

which is more economical to use as against lower strength concrete for

and equal load carrying capacity.

The administrative authorities need to carry out following action;

Report maximum to design-cum-construction bid which will arouse,

encourage and will reward maximum techniques that will save cement

and overall cost.

Standardize a few say one or more dozens precast and prestressed

concrete members at the National level so that standard shuttering could

be used and production cost reduced on account of greater repetitive

use shuttering.

Private industrialists be encouraged to set up plants for manufacture of

hallow pre stressed concrete planks by extrusion methods and

manufacture of Light Weight Aggregates which go a long way in

economizing construction and improving insulations an energy

economizing step.

Considerable cement can be saved from non-use as cement plasters

can be replaced by gypsum /lime plaster inside the buildings. Similarly

for masonry work can be done in lime or in mud.

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SUGGESTIONS

INDUSTRIAL LEVEL1. All new plants should be based on latest energy efficient cement

technologies proved beyond doubt.

All plants where possible should be based on dry process 4 stage

suspension preheated kiln preferably with pre calciner. As these are very

modern, highly sophisticated plants, we should get technical assistance

for one year in the form of expert for operation, maintenance

instrumentation and control equipment, after commercial production. A

large number of middle management technical officers are trained in

foreign countries on such plants in these fields.

2. The wet plant may be converted to semi wet-wet or dry process plant in

due course of time but should be planned in advance.

3. The insolating firebricks should be tried where possible.

4. The moisture should be kept at minimum.

5. Belt conveyor possible may substitute the transportation by dumper.

6. The site should be chosen where homogeneous materials are available

and an economic raw mix with reference to burn ability can be designed.

7. We should try to reduce losses through cooler and sealing rings and

modify it where necessary.

8. The power factor the ratio of working power in KW or KVA in delivered

power may appear directly or indirectly on utility bills. It may be retained as

an option on the part the utility. Most operation can and should work within

the range of 90-95%. Working below 85% range contributes to poor

energy affiance.

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NATIONAL LEVEL1. The government should encourage establishment of only latest energy

efficient plant of cement technologies proved beyond doubt.

2. The government may provide direct incentive to cement industry, that

those factories which improve fuel consumption per ton of clinker on

yearly basis, from their most efficient fuel consumption recorded so far,

for each type of product, by allowing the savings so accrued to be tax

free. The new plant who improves upon their guaranties of fuel

consumption will also be considered similarly.

3. We should promote generation of power on coal near their deposits near

the investment in coal machinery for power generation may be much

lesser as compared to cement industry so that natural gas is available to

cement and other industries.

4. In case it is not possible those cement factories are nearer to coal

deposits should use coal but the Government as a policy matter should

help them to have better profitability than the cement factories fired with

natural gas, as an incentive.

REGIONAL LEVEL

1. The technical assistance in the form of technical experts and training to

middle management technical personnel is provided by the developed

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countries in the region for operation maintenance, instruments and control

of modern cement plants.

2. The development work in cement technology in the region should be

made available to regional countries.

3. Regional financing agencies should help in modernization and balancing

as well as new projects preferably with untied loans.

Bibliography

Perry & Green Perry’s Chemical Engineering Hand Book Peter Timmerhaus & Ronald E. West Plant Design and Economics

for Chemical Engineers Welter H. Duda Cement Data Book D.Q. Kern Process Heat Transfer George T. Austin Shreve’s Chemical Process Industries

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Abdul Majid Hand Book For Cement Engineers McCabe Smith Herriot Unit Operation of Chemical Engineering Coulson and Richardson’s Chemical Engineering

In addition we are also thankful to various industries for their co-operation & co ordination with us in a friendly manner to accomplish this project.

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