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Short communication

Drag coefficient of Solid Recovered Fuels (SRF)

Gregory Dunnu *, Jörg Maier, Uwe Schnell, Günter Scheffknecht

Institute of Combustion and Power Plant Technology – IFK, University of Stuttgart, Pfaffenwaldring 23, 70569 Stuttgart, Germany

a r t i c l e i n f o

 Article history:

Received 18 May 2010

Received in revised form 16 June 2010Accepted 24 June 2010

Available online 6 July 2010

Keywords:

Solid Recovered Fuels

Numerical simulation

Drag coefficient

Co-combustion

a b s t r a c t

The numerical simulation of Solid Recovered Fuels (SRF) co-combustion in pulverised coal power plants

requires a flexible particle model, which among other properties should be able to predict the aerody-

namic behaviour of the irregular-shaped particles, especially their trajectories along the boiler axis. Thiswill help to provide vital information on whether the SRF particles are entrained in the combustion gases

or drop to the boiler bottom. One difficulty encountered in the process is the true value of the drag coef-

ficient (C D) of the coarse SRF particles. Most of the numerical simulation codes calculate the particle tra-

  jectories by integrating the force balance of the particles in which the C D plays an important role. As a

result, a true C D of SRF will definitely lead to more realistic results.

In this short communication, the authors have taken a practical approach in determining the C D of the

SRF. It was found that within the Newton’s law range the C D of the SRF lies between 0.6 and 2.0 with a

mean value of 1.5. The results were further validated by correlating the calculated lift velocities of SRF

using different C D values and that obtained through experiment.

Ó 2010 Elsevier Ltd. All rights reserved.

1. Introduction

The numerical simulation of Solid Recovered Fuels (SRF) co-

combustion in pulverised coal power plants based on numerical

calculations requires a flexible particle model, which should be

able to predict:

1. Species and gas phase reactions,

2. mass transfer, and

3. the aerodynamic behaviour of the irregular-shaped particles,

especially their trajectories along the boiler axis.

The latter will help provide vital information on whether the

SRF, which are generally coarse particles, are entrained in the com-

bustion gases or fall to the boiler bottom. One difficulty encoun-

tered in the process is the true value of the drag coefficient of 

such fuel particles. Most of the numerical simulation codes calcu-

late the particle trajectories by integrating the force balance of the

particles in which the C D plays an important role. As a result, a true

C D of SRF will definitely lead to more realistic results.

In comparison to SRF, the particle sizes of coal dust are in the

micron range and their form can be approximated to be spherical.

Hence in numerical calculations their aerodynamic behaviour can

be approximated by that of spheres. Unlike coal dust, SRF derived

from municipal solid waste (MSW) are coarser with particle sizes

in the range of centimetres. They are loose, fluffy and of course

their aerodynamic behaviour cannot be approximated to that of spheres. In this research work the authors have taken practical

steps to determine the aerodynamic properties of SRF, namely

the effective particle diameter and the C D of the particles. The re-

sults of the research work concerning the effective diameter have

been discussed elsewhere [1], therefore this paper will only deal

with the drag coefficient of SRF particles.

SRF is produced in special waste treatment facilities operated

by both private and public companies. Input materials are munici-

pal waste streams and production residues. Also included are pack-

aging materials, paper/cardboard and textiles. The common

process technologies used are:

Mechanical processing in order to separate the high-calorific

fraction and to remove unwanted components (e.g. PVC), and

mechanical–biological treatment plants with process-inte-

grated separation and processing of high-calorific fractions.

Depending on the production line, the SRF products are mainly

produced as bales, fluff, soft or hard pellets. Wastes suitable for the

production of SRF are defined according to the waste catalogue and

the Commission Decision 2000/532/EC1. According to the waste

categories, the input materials can be separated in five main groups:

0016-2361/$ - see front matterÓ 2010 Elsevier Ltd. All rights reserved.doi:10.1016/j.fuel.2010.06.039

* Corresponding author. Tel.: +49 71168563750; fax: +49 711 685 63491.

E-mail addresses: gregory.dunnu@ifk.uni-stuttgart.de , dunnu@ivd.uni-stuttgart.

de (G. Dunnu).

1 Decision (2000/532/EC) has subsequently been amended by Commission Decision

2001/118/EC of 16 January 2001, Commission Decision 2001/119/EC of 22 January

2001 and Commission Decision 2001/573/EC 23 July 2001.

Fuel 89 (2010) 4053–4057

Contents lists available at ScienceDirect

Fuel

j o u r n a l h o m e p a g e : w w w . e l s e v i e r . c o m / l o c a t e / f u e l

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1. Wood, paper, cardboard and cardboard boxes,

2. textiles and fibres,

3. plastics and rubber,

4. other materials (e.g. waste ink, used absorbers, spent activated

carbon), and

5. High-Calorific Fractions – HCF from non-hazardous mixed col-

lected wastes.

The SRF used in this study is pictured in Fig. 1 together with its

percentage weight compositions. It is made of high-calorific frac-

tion (HCF) derived from municipal solid waste (MSW). The particle

sizes range between 3 mm and 25 mm with a d50 of 9.8 mm.

2. Experiments

 2.1. Determination of aerodynamic lift velocity (ALV) of SRF particles

The ALV depicts a characteristic parameter that is used to de-

scribe the ability of the SRF to be fully suspended in a gas stream.

It is determined at room temperature and later corrected to flue

gas conditions. This parameter gives an estimated value of the

essential gas stream velocity needed to prevent the SRF particles

from falling to the bottom ash hopper before they are completely

burned. The experimental set-up built to determine the ALV of 

the SRF particles is shown in Fig. 2. It consists of a 1000 mm fall

column with a wire mesh mounted at 500 mm. SRF particles are

dropped on the mesh one after the other and the air flow rate

needed to just lift it is recorded. With this set-up the ALV of a par-

ticle is measured as the velocity of air in the fall column that is

needed to create the lift force necessary to just suspend a particle

above the mesh. The results obtained under laboratory conditions

are transferred to a real boiler after correlating them to the existing

conditions in the boiler. The formula [2] linking the two conditions

is derived as:

ALVFG ¼ ALVmeasured  ffiffiffiffiffiffiffiffiqf 

qFGr  ð1Þ

where qf  is the density of air, and qFG is the density of flue gas (FG).

The theoretical model of the set-up is developed based on Rey-

nolds number calculations. Considering the balance of forces acting

on a suspended particle in a fluid, the forces of buoyancy, drag and

gravity acting on it are summarized as:

gravity À buoyancy À drag ¼ accelerationforce ð2Þ

At equilibrium position, Eq. (2) becomes:

pd3 p

6ðq p À q f Þ g À C DðReÞ

1

2q f 

ALV2

 f 2w

pd2 p

4¼ 0 ð3Þ

thus leading to the following expression for the drag coefficient:

C DðReÞ ¼4

3f 

2w

gdp

ALV2

ðqp À qf Þ

qf 

;

Newton’s law region ð500 < Re < 2 Â 105

Þ ð4Þ

Here qf  is the air density, qA is the particle density, dP is the

equivalent circle diameter, C D (Re) is the drag coefficient, ALV is

the aerodynamic lift velocity and f w is the wall factor correction,

calculated using Eq. (5).

Munroe f w ¼ 1 Àdp

D

1:5

; 1036 Rep 6 10

4; 0:1 6 dp=D 6 0:8

ð5Þ

The introduction of f w is based on the fact that when the diam-

eter of a settling particle is significant compared to the diameter of 

the fall column (D), the settling velocity is reduced. The effect of 

boundaries on terminal velocity is corrected using the correlation

preferred by Munroe [3]. This was selected because most of the cal-

culated Re of the SRF particles and the ratio of particle diameter to

diameter of the fall column lies within the limits of this equation.

 2.2. Particle size measurements using image analysis method

The dp of the SRF were determined using particle image analysis

method (PIAM), here the maximum projected area of the individ-

ual particles are extracted from digital photographs. Earlier re-

search (1) has shown that particle size measurement using this

method gives data that captures the aerodynamic properties of 

the particles. This is supported by the fact that particles fall with

their maximum projection area perpendicular to the direction of 

fall, and a size measure representing this maximum projection area

is most likely to relate to behavioural (aerodynamic) properties [4].

An illustration to demonstrate this phenomenon is for e.g. when a

piece of paper is falling, it will almost and always fall with the larg-

est surface facing the direction of fall. In view of this the ability to

describe precisely the largest projected area of a particle will im-

mensely help in any modelling of particle trajectories in boilersand industrial furnaces. Validation work on this method has previ-

ously been published by the authors [1]. The equivalent circle

diameter (dp) is then calculated using Eq. (6). Fig. 3 illustrates

the principle of measurement.

The characteristic parameter (dp) is defined as the diameter of a

circle with the same area as the maximum projection of a particle,

computed as:

dp ¼

 ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi4 Â Maximum Projection Area

p

r ð6Þ

In comparisons, sieve analysis which is the most commonly

used method for particle size analysis has been shown to be

unsuitable for detailed analysis of SRF particles. The reasons are

Fig. 1. SRF derived from HCF of MSW and its compositions in weight percent.

4054 G. Dunnu et al. / Fuel 89 (2010) 4053–4057 

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that SRF are characterized by very heterogeneous mixtures, fluffy

materials, and variable particle densities. They entangle each other

and agglomerate during sieving. Particles can wrongly be classified

simply by the orientation of which they approach the sieve aper-

ture, thus slipping through the sieve when the shortest sides of 

the particles are correctly aligned to the sieve opening. A funda-

mental difference between the two methods is that, particle sizes

determined by PIAM capture more of the aerodynamic properties

than when sieve analysis is used. In this respect, PIAM was used

to determine the aerodynamic diameters as a function of the max-

imum projected area of the SRF particles.

3. Results and discussions

 3.1. The drag coefficient of SRF 

The drag coefficients for the individual SRF particles were deter-

mined using Eq. (4). The results show that the C D values for theloose SRF fractions effectively lie between 0.6 and 2.0 with a mean

value of 1.5 in the Newton’s law region. In Fig. 4, a scatter plot of 

the results as a function of Reynolds numbers is shown. It is ob-

served that C D is independent of the Reynolds number in this

region.

In comparisons, the data published by Lapple and Shepherd [5]

for cylinders and disc-shaped objects shown in Fig. 5 show that thedrag coefficients of both shapes in the Newton’s law range are also

independent of the Reynolds number, and the magnitude is about

twice as high compared to spheres. In their research, cylinders and

disc-shaped objects were defined as follows;

– cylinder  defined as object with infinite length with axis perpen-

dicular to the direction of motion, and

– disc-shaped defined as objects with flat side perpendicular to the

direction of motion.

The fractions found in SRF, namely paper, plastic-foils, and tex-

tiles, can be described as loose, flat, and fluffy objects. Their aero-

dynamic behaviour can be linked to that of disc-shaped

materials, hence the C D of SRF were compared with that of disc-

shaped materials as published in literature. In the Newton’s lawrange, the drag coefficient of cylinders and disc-shaped objects

stays constant. After superimposing the results, the hatched area

indicated in Fig. 5 shows the values of SRF and that of Lapple and

Shepherd Fig. 5. It can be seen that both are found in the same

vicinity. In view of this, the approximation of the aerodynamic

behaviour of SRF to that of disc-shaped objects is a plausible

assumption.

Additional validation is performed by correlating the experi-

mental and theoretical results in two scenarios. First using a C D of 

1.5, and secondusinga C D of 0.5to calculatethe ALV. Fig. 6a,b shows

the correlation between ALV of several single particles calculated

using Eq. (4) with drag coefficients of 1.5 and 0.5 and experimental

results. The ideal line is a reference with gradient unity. It repre-

sents the case where the experimental values are the same as thetheoretic values. Comparing the reference line to the other lines

Fig. 2. Set-up to determine the aerodynamic lift velocity (ALV) of SRF particles [2].

L

B

P

 A circle with area equal to the

projected area of particle P

dp

Key

L: Major Axis Length P: Maximum projection area of a particle

B: Minor axis length dp: Equivalent circle diameter 

Fig. 3. Measurement principle of image analysis method for particle size analysis.

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reveals that the ALV calculated using a C D value of 1.5 provides the

best correlation between theoretic and experimental values. The

gradients of the lines arecloser to the referenceline than those esti-

mated using C D = 0.5. Moreover, the lines with PIAM data2 show a

much better correlation between experimental values and theoreti-

cal values than those with sieve analysis data3. These comparisons

clearly confirm that the C D of SRF estimated to be 1.5 can be used

for calculations with higher accuracy. The correlations also showed

Fig. 4. Drag coefficient of SRF as a function of Reynolds number.

Sieve analysis data used

y = 1,94x

R2 = 0.7

PIAM data usedy = 0,96x

R2 = 0.7

Ideal

y = x

R2

= 1

0

1

2

3

4

5

6

7

0.0 0.5 1.0 1.5 2.0 2.5 3.0

ALV (experiment), m/s ALV (experiment), m/s 

Sieve analysis data used

y = 3.53x

R2 = 0.6 PIAM data used

y = 1.35x

R2 = 0.6

Ideal

y = x

R2 = 1

0

1

2

3

4

5

6

7

0.0 0.5 1.0 1.5 2.0 2.5 3.0

   A   L   V

   (  c  a   l  c  u   l  a   t  e   d   ) ,  m   /  s

   A   L   V

   (  c  a   l  c  u   l  a   t  e   d   ) ,  m   /  s

(a) ALV calculated with C  D = 1.5 (b) ALV calculated with C  D = 0.5 [1]

Fig. 6. Comparison of ALV using different C D values.

2 PIAM data means particle sizes determined by particle image analysis. 3 Sieve analysis data means particle sizes determined by sieve analysis.

Fig. 5. C D of spheres, disks, cylinders, and SRF. Source: Perry’s Chemical Engineers’ Handbook 7th Ed. (Original: Lapple and Shepherd, Ind. Eng. Chem.,1940, 32, 605 [5]).

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significant differences in results between particle size data derived

from sieve analysis method and PIAM.

 3.2. Effect of combustion on C D

Three main factors determine the drag of burning solid particles

[6]:

1. The mass transfer due to the combustion process,

2. Temperature gradient between particle and ambient medium,

and

3. Surface and volumetric reactions on the particle and in its

boundary layer.

The influences of the above factors on the particle drag differ

widely. For example, mass transfer leads to thickening of the

boundary layer and reduction of the drag coefficient, whereas tem-

perature difference between particle and medium affects mainly

the variation of the physical properties of the fluid. Irrespective

of this, several researches have shown contrary views.

Experimental investigations of the drag of a burning particle

(coal, charcoal, coke) published by Babii and Kuvaev [7] over a

wide ranges of particle diameters, oxygen concentration and initial

ambient temperatures: 0.1 < d < 15 mm, 0.21 < C < 100%, 300 < T <

1400 K, have shown that the drag coefficient of burning particles

is larger than that of non-burning ones in the Stokes’ law and inter-

mediate region, but unaffected in the Newton’s law region. Con-

trary, the data published by Ogasawara et al. [8] concerning the

drag coefficient of a burning cylindrical and spherical particles

(cylinder, d = 3.52 mm; spheres, d = 9.7 mm) showed significant

differences between burning and non-burning particles, with burn-

ing particles having a reduced drag coefficient of up to 30% and 40%

for cylinders and spheres, respectively.

The drag coefficients of different fractions found in the SRF

might not remained unchanged during combustion. Therefore,

consideration should be given especially to the non-char bear-

ing particles like plastics in numerical calculations. In this case,

their form and drag rapidly changes. As such the appropriate

assumptions and boundary conditions should be outlined con-

cerning individual non-char bearing fractions of the SRF and

how their drag coefficients might vary in the combustion

process.

4. Conclusions

It has been shown in this work that the aerodynamic parame-

ters, namely the drag coefficient and the lift velocity of SRF parti-

cles are essential inputs to the overall aerodynamic behaviour.

The results showed that the drag coefficients of SRF particles with-

in the Newton’s law region have values which range between 0.6

and 2 with a mean of 1.5. The mean value was a very good input

in the estimation of the aerodynamic lift velocity SRF using Rey-

nolds number based calculation.

References

[1] Dunnu G, Hilber T, Schnell U. Advanced size measurements and aerodynamicclassification of solid recovered fuel particles. Energy Fuels 2006. doi: 10.1021/ef0600457.

[2] Dunnu G, Maier J, Hilber T, Scheffknecht G. Characterisation of large solidrecovered fuel particles for direct co-firing in large PF power plants. Fuel, 2009.doi:10.1016/j.fuel.2009.03.004.

[3] Munroe HS. Trans AIMME, 1888–1889, 17. 637–657.[4] Sneed ED, Folk RL. Pebbles in the Lower Colorado river, Texas, a study in particle

morphogenesis. J Geol 1958;66:114–50.[5] Lapple CE, Shepherd CB. Calculation of particle trajectories. Ind Eng Chem

1940;32.[6] Yarin LP, Hetsroni G. Combustion of two-phase reactive media. 2004, ISBN 3-

540-40339-6,1–45.[7] Babii VI, Kuvaev JaF. Combustion of coal dust and coal dust flame calculation (in

Russian). Energoatomizdat, 1986, Moscow.[8] Ogasawara M, Adachi T, Yashiki T. Study of the drag of cylinder and sphere with

flames supported in air stream. Jpn Soc Mech Eng 1967;33(10):825–32.

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