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CHAPTER 1PRINCIPLES OF GAS PROCESSING
1. OVERVIEWThe natural gas used in our homes and industr ies does not come out of the ground ready to be burned for
heat and fuel. The gas often contains too many contaminants at the wellhead to meet the quality
specifications set by natural gas buyers. In addition, the natural gas stream may contain natural gas
liquids (NGLS, or hydrocarbon liquids) that could have increased value when separated from the gas
stream. So the gas is put through a series of processes in order to make it usable. Those processes used
to remove contaminants and separate. NGL's are referred to as processing.
SYMBOL TYPICAL NATURAL GAS STREAM
Methane ( C1 ) For home and industr ial use as a fuel ( stove, water heater, etc. )Ethane ( C2 ) Makes glycol, anti-freeze ,plastics, etc.Propane (C3 ) Used as a commercial fuel .Isobutane ( C4 ) Used in making plastics, and as a gasoline Spiker Normal ButaneProducts. ( NC4) Used as a fuel, also for making plastics and certain rubber products.Pentane ( C5+ ) Pentane plus anything heavier ( or containing more than five carbonatoms ) is basically gasoline.
SYMBOL CONTAMINANTSNitrogen ( N2 ) Has no BTU value, just takes up space in the gas stream.Carbon Dioxide ( CO2) Reduces the BTU rating of the gas, and is also corrosive.Hydrogen Sulfide(H2S ) Is corrosive and toxic.Water ( H2O ) IS corrosive to pipeline, and can lead to the formation of hydrates .
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SEPARATIONGas processing starts at the wellhead. When gas comes out of the ground, it normally contains liquids
such as oil and water. These liquids must be separated from the gas before the producer can sell the gas.
This separation is usually accomplished at the wellhead using a device known as a three phase separator.
Three Phase Vertical Separator
GAS OUTLET
FINAL
CENTRIFUGAL
GAS LIQUID
SEPARATION
SECTION
INLET DIVERTER
BAFFLEWELL
STREAM
INLET GAS EQUALIZER
PIPE
LIQUID LEVEL
CONTROL
LIQUID QUIETING
BAFFLE
LIQUID DISCHARGE
VALVES
DRAIN
CONNECTION
LIQUID
OUTLET
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METERINGThe separated gas is then routed through a meter station and sent to a processing facility. Metering is a
critical function because in order to maximize profits it is important to know how much gas is leaving the
well. and how much is arriving at the processing facility. A major difference in those amounts could
indicate a breakage in the pipeline.
GAS GATHERINGAfter metering, the gas moves through a pipeline to a processing facility. To process gas efficiently, it is
usually piped from many producing locations to a central processing facility. This is much more efficient
and economical than setting up separate processing facilities for each production stream. Bringing
various Quantit ies of gas together at one location for processing is call ed gas
Gas gathering systems are composed of pipelines and "booster" stations that increase the gas pressure
as needed to. move the gas to its destination. These systems can range from one mile to thousands of
miles in length.
PROCESSINGOnce the gas reaches the central processing facility, it is put through several processes to meet sales
Quality specifications. These processes can be broken down into two major categories: Removal of
contaminants and removal of natural gas l iquids (NGLS).
ORIFICEFITTING
ORIFICE METER &
RECORDER
METER MANIFOLD
METER
PIPING
CHECK
VALVE
VENT
VALVE
ORIFICE PLATE THERMOWELLS
ORIFICE
FITTING
METER TUBE
Typical Meter Station
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2. CONTAMINANTSPipeline companies have stringent gas quality requirements that must be met before gas can be shipped
through their pipelines. Therefore, there are several contaminants that must be removed or reduced tocertain levels before the gas can be sold. The most common contaminants are water (H2O), hydrogen
sulfide (H2S), and non-combustible inert gases l ike carbon dioxide (CO2) and nitrogen (N2).
WATERWater (H2O) in natural gas can cause hydrates to form. Hydrates are a combination of hydrocarbon
molecules and water that form a solid. They will deposit on pipeline interiors and restr ict the flow of gas
and also contributes to corrosion in pipelines.
HYDROGEN SULFIDE
HYDRATE
CRYSTALS
CORROSION
PIP
NATURAL GAS
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Hydrogen sulfide (H2S) is a corrosive, toxic gas that is found in many natural gas streams. H2S is a highly
toxic substance that can be deadly if proper safety procedures are not followed.
NON-COMBUSTIBLE INERT GASESNon combustible inert gases, such as nitrogen, must be removed from a gas stream for various reasons.
The primary reason is they do not burn, so they have no value as a fuel. These gases are therefore taking
up valuable space in the pipeline. In addition, individual non-combustible inert gases have certain
properties that make them undesirable in the gas stream. Carbon dioxide, for example, becomes cor-
rosive when mixed with water.
3. REMOVAL OF WATERIn order to prevent hydrate formation, and to reduce corrosion in pipelines, water must be removed from
the gas stream. The most common methods for water removal are: liquid desiccants, solid bed
desiccants and methanol injection.
LIQUID DESICCANTSThe process of removing water from a substance is called dehydration. Although there are several
methods for r emoving water from a natural gas stream, the most common method uses a liquid desiccantknown as glycol. ( A desiccant is defined as a . "drying agent:')
Glycol absorbs water from the wet gas stream, thereby "drying" the gas. The two most widely used glycol
dehydration methods are AN ethylene glycol (T.E.G.) contactor column and an ethylene glycol (E.G.)
injection system.
GAS
GLYCOL
O = WATER
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NATURAL GASCERAMIC
BALLS
FLOATING
SCREEN
ADSORBEN
PELLETS
CERAMIC BALLS
DEHYDRATEGAS
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MOLECULAR SIEVE BEDRegeneration of the pellets is accomplished when a small volume of heated gas is fed through the unit.
The heat causes the water to evaporate, and the water vapor is carried out of the dehydration system by
the gas stream. The hot gas is cooled, all owing the water to condense. The dry gas is recycled back to the
inlet phase, or used elsewhere if it meets quality specifications. Silica beds are another form of solid
desiccant. The process of dehydration with a silica bed is identical in principle to the molecular sieve.
Silica beds, however, do not rely on polarity to attract the water out of the gas stream. Silica beds work
because the concentration of water in the silica is so much less than the water concentration in the gas
that the water in the gas stream is adsorbed into the silica. Silica beds are not as effective as molecular
sieves for drying gas.
SOLID DESICCANT DEHYDRATORSWhen the highest possible dew point depression is r equired, the solid desiccant dehydration system is the
most effective type. It is not uncommon to process gas through these systems with a resultant residual
water vapor in the outlet gas of less than 1/2 lb. per MMscf. In the average system, this amount might
correspond to a dew point of -400F. Dehydrators of this type are manufactured as packaged units ranging
in, capacity from 3 to 500 MMscf/d, with design pressures of fr om 300 to 2,500 psig. Solid desiccant units
find their greatest application in gas tr ansmission line systems.
The essential components of a sol id desiccant dehydration are:
1. An inlet gas stream separator, usually a filter separator
2. Two or more adsorption towers (adsorbers or contactors) filled with a granular gas-drying material
3. A high-temperature heater to provide hot regeneration gas for drying the desiccant. in the
towers
4. A regeneration gas cooler for condensing water f rom the hot regeneration gas;
5. A regeneration gas separator to remove water f rom the regeneration gas stream; and
6. Piping, manifolds, switching valves, and controls to direct and control the flow of gases
according to process requirements.
The foll owing terms apply to the technology of solid desiccant dehydrators:Wet gas: is gas containing water vapor prior to flowing through the adsorber towers.
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Dry gas: is gas that has been dehydrated by flowing through the adsorbers.Regeneration gas is wet gas that has been heated in the regeneration gas heater to temperatures of
400F to 460F. This gas is passed through a saturated adsorber tower to dry the tower and remove thepreviously adsorbed water.
Desiccant is a solid granulated drying medium that has an extremely large effective surface area per unit
weight because of a mul titude of microscopic pores and capil lary openings. 'A typical desiccant may have
as much as 4 mil l ion square feet of surface area per pound.
The term adsorption refers to the effect that natural forces have on the surface of a solid in tending to
capture and hold vapors and liquids on its surface. Adsorption processes, as opposed to absorption
processes, do not involve chemical reactions. Adsorption is purely a surface phenomenon. In most
dehydration systems, activated alumina (bauxite) or a sil ica gel desiccant is used. Adsorbents are specific
in nature, and not all adsorbents are equally effective.
Different molecules art attracted to adsorbents at different rates. Because of this, adsorbents are
capable of separating materials preferentially, in either gaseous or liquid phases. The separation is.
accomplished by passing the stream to be treated through the tower packed with a bent. The degree of
adsorption is a function of operating temperature and pressure; adsorption, up to a point, increases with
pressure increase and decreases with temperature increase. A bed may be regenerated, either by
decreasing its pressure or by increasing its temperature.
Adsorber towers are made ready for new adsorption cycles by increasing the bed temperature and
passing a stream of veryhot gas through it. The hot natural gas not only supplies heat but also acts as a
carrier to remove the water vapor from the bed. After the bed is heated to a predetermined temperature,
it is cooled by the flow of unheated gas and thus made ready for another cycle. Figure 5 is a flow diagram
of a two-tower solid desiccant dehydration unit. The wet inlet gas stream first passes through an efficientinlet separator where free liquids, entrained mist, and solid particles are removed. This part of the
system is very important, since free liquids may damage or destroy the desiccant bed and solids may plug
it. If the plant happens to be downstream of an amine unit or a compressor station, a filter inlet separator
should be used.
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At any given time, one of the towers will be on stream in the adsorbing cycle, and the other tower will be
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in the process of being regenerated and cooled. Several automatically operated switching valves and a
controller route the inlet gas and regeneration gas to the proper tower at the proper time. Typically, a
tower will be on the adsorb cycle for 4-12 hours, with 8 hours being the most common time cycle. The
tower being regenerated will be heated for about 6 hours and, cooled during the remaining 2 hours.Large-volume systems may have three towers as shown in figure. At any given time, one tower will be in
the adsorption cycle, one tower will be in the heating cycle, and the remaining tower will[ be in the
cooling cycle.
As the wet inlet gas flows downward through the tower on the adsorption cycle, all of the adsorbed gas
components are adsorbed at different r ates. The water vapor is immediately adsorbed in the top layers of
the bed. Dry hydrocarbon gas components (ethane, propane, butane, etc.) passing on down through the
bed are also adsorbed, with the heavier components displacing the lighter components at the cycle
proceeds. As the upper layers of desiccant become saturated with water, the lower layers begin to see
wet gas and begin adsorbing the water vapor, displacing the previously adsorbed hydrocarbon
components. For each component in the inlet gas stream, there will be a section of bed depth, fr om top to
bottom, where the desiccant is saturated with that component and where the desiccant is just starting to
see that component. The depth of bed from saturation to initial adsorption is known as the mass transfer
zone. This is simply that zone or section of the bed where a component is transferring its mass from the
gas stream to the surface of the desiccant.
As the flow of gas continues, the mass transfer zones move downward through the bed, and water
displaces all of the previously adsorbed gases until finally the entire bed is saturated with water vapor.
When the bed is completely saturated with water vapor, the outlet gas will be just as wet as the inlet gas.
Obviously, the towers must be switched from adsorb cycle to regeneration cycle before the bed has
become completely saturated with water.
Regeneration gas is supplied by taking a portion of the entering wet-gas stream across a pressure-
reducing valve that forces a port ion of the upstream gas through the regeneration system. In most plants,
a flow controller regulates the volume of regeneration gas taken. This gas is sent through a heater,
usually a salt bath type, where it is heated to 400F-450F and then piped to the tower being regenerated.
The relationship between regeneration gas temperature and desiccant bed temperature for a typical 8-
hour cycle is shown in figure. At about 240F, water begins boiling, and the bed continues to heat up, but
more slowly, since water is being driven out of the desiccant. After all the water has been removed,
heating is continued to drive off any heavier hydrocarbons and contaminants, which will not vaporize at
low temperatures. With cycle times of 4 hours or more, the bed will be properly regenerated when the
outlet gas temperature has reached 350F to 375F.
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