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Natural-gas processing

October 15, 2023

Natural-gas processing is a range of industrial processes designed to purify raw natural gas by removing contaminants such as solids, water, carbon dioxide (CO2), hydrogen sulfide (H2S), mercury and higher molecular mass hydrocarbons (condensate) to produce pipeline quality dry natural gas[1] for pipeline distribution and final use.[2] Some of the substances which contaminate natural gas have economic value and are further processed or sold. Hydrocarbons that are liquid at ambient conditions: temperature and pressure (i.e., pentane and heavier) are called natural-gas condensate (sometimes also called natural gasoline or simply condensate).

A natural-gas processing plant in Aderklaa, Austria

Raw natural gas comes primarily from three types of wells: crude oil wells, gas wells, and condensate wells. Crude oil and natural gas are often found together in the same reservoir. Natural gas produced in wells with crude oil is generally classified as associated-dissolved gas as the gas had been associated with or dissolved in crude oil. Natural gas production not associated with crude oil is classified as “non-associated.” In 2009, 89 percent of U.S. wellhead production of natural gas was non-associated.[3] Non-associated gas wells producing a dry gas in terms of condensate and water can send the dry gas directly to a pipeline or gas plant without undergoing any separation processIng allowing immediate use.[4]

Natural-gas processing begins underground or at the well-head. In a crude oil well, natural gas processing begins as the fluid loses pressure and flows through the reservoir rocks until it reaches the well tubing.[5] In other wells, processing begins at the wellhead which extracts the composition of natural gas according to the type, depth, and location of the underground deposit and the geology of the area.[2]

Natural gas when relatively free of hydrogen sulfide is called sweet gas; natural gas that contains elevated hydrogen sulfide levels is called sour gas; natural gas, or any other gas mixture, containing significant quantities of hydrogen sulfide or carbon dioxide or similar acidic gases, is called acid gas.

Types of raw-natural-gas wells Edit

  • Crude oil wells: Natural gas that comes from crude oil wells is typically called associated gas. This gas could exist as a separate gas cap above the crude oil in the underground reservoir or could be dissolved in the crude oil, ultimately coming out of solution as the pressure is reduced during production. Condensate produced from oil wells is often referred to as lease condensate.[6]
  • Dry gas wells: These wells typically produce only raw natural gas that contains no condensate with little to no crude oil and are called non-associated gas. Condensate from dry gas is extracted at gas processing plants and is often called plant condensate.[6]
  • Condensate wells: These wells typically produce raw natural gas along with natural gas liquid with little to no crude oil and are called non-associated gas. Such raw natural gas is often referred to as wet gas.
  • Coal seam wells: These wells typically produce raw natural gas from methane deposits in the pores of coal seams, often existing underground in a more concentrated state of adsorption onto the surface of the coal itself. Such gas is referred to as coalbed gas or coalbed methane (coal seam gas in Australia). Coalbed gas has become an important source of energy in recent decades.

Contaminants in raw natural gas Edit

See also: Natural-gas condensate

Raw natural gas typically consists primarily of methane (CH4) and ethane (C2H6), the shortest and lightest hydrocarbon molecules. It often also contains varying amounts of:

Natural gas quality standards Edit

Raw natural gas must be purified to meet the quality standards specified by the major pipeline transmission and distribution companies. Those quality standards vary from pipeline to pipeline and are usually a function of a pipeline system's design and the markets that it serves. In general, the standards specify that the natural gas:

  • Be within a specific range of heating value (caloric value). For example, in the United States, it should be about 1035 ± 5% BTU per cubic foot of gas at 1 atmosphere and 60 °F (41 MJ ± 5% per cubic metre of gas at 1 atmosphere and 15.6 °C). In the United Kingdom the gross calorific value must be in the range 37.0 – 44.5 MJ/m3 for entry into the National Transmission System (NTS).[9]
  • Be delivered at or above a specified hydrocarbon dew point temperature (below which some of the hydrocarbons in the gas might condense at pipeline pressure forming liquid slugs that could damage the pipeline.) Hydrocarbon dew-point adjustment reduces the concentration of heavy hydrocarbons so no condensation occurs during the ensuing transport in the pipelines. In the UK the hydrocarbon dew point is defined as <-2 °C for entry into the NTS.[9] The hydrocarbon dewpoint changes with the prevailing ambient temperature, the seasonal variation is:[10]
Seasonal variation of hydrocarbon dewpoint
Hydrocarbon dewpoint 30 °F (–1.1 °C) 35 °F (1.7 °C) 40 °F (4.4 °C) 45 °F (7.2 °C) 50 °F (10 °C)
Months December

January

February

March

April

November

May

October

June

September

July

August

The natural gas should:

  • Be free of particulate solids and liquid water to prevent erosion, corrosion or other damage to the pipeline.
  • Be dehydrated of water vapor sufficiently to prevent the formation of methane hydrates within the gas processing plant or subsequently within the sales gas transmission pipeline. A typical water content specification in the U.S. is that gas must contain no more than seven pounds of water per million standard cubic feet of gas.[11][12] In the UK this is defined as <-10 °C @ 85barg for entry into the NTS.[9]
  • Contain no more than trace amounts of components such as hydrogen sulfide, carbon dioxide, mercaptans, and nitrogen. The most common specification for hydrogen sulfide content is 0.25 grain H2S per 100 cubic feet of gas, or approximately 4 ppm. Specifications for CO2 typically limit the content to no more than two or three percent. In the UK hydrogen sulfide is specified ≤5 mg/m3 and total sulfur as ≤50 mg/m3, carbon dioxide as ≤2.0% (molar), and nitrogen as ≤5.0% (molar) for entry into the NTS.[9]
  • Maintain mercury at less than detectable limits (approximately 0.001 ppb by volume) primarily to avoid damaging equipment in the gas processing plant or the pipeline transmission system from mercury amalgamation and embrittlement of aluminum and other metals.[7][13][14]

Description of a natural-gas processing plant Edit

There are a variety of ways in which to configure the various unit processes used in the treatment of raw natural gas. The block flow diagram below is a generalized, typical configuration for the processing of raw natural gas from non-associated gas wells showing how raw natural gas is processed into sales gas piped to the end user markets.[15][16][17][18][19] and various byproducts:

Raw natural gas is commonly collected from a group of adjacent wells and is first processed in a separator vessels at that collection point for removal of free liquid water and natural gas condensate.[23] The condensate is usually then transported to an oil refinery and the water is treated and disposed of as wastewater.

The raw gas is then piped to a gas processing plant where the initial purification is usually the removal of acid gases (hydrogen sulfide and carbon dioxide). There are several processes available for that purpose as shown in the flow diagram, but amine treating is the process that was historically used. However, due to a range of performance and environmental constraints of the amine process, a newer technology based on the use of polymeric membranes to separate the carbon dioxide and hydrogen sulfide from the natural gas stream has gained increasing acceptance. Membranes are attractive since no reagents are consumed.[24]

The acid gases, if present, are removed by membrane or amine treating and can then be routed into a sulfur recovery unit which converts the hydrogen sulfide in the acid gas into either elemental sulfur or sulfuric acid. Of the processes available for these conversions, the Claus process is by far the most well known for recovering elemental sulfur, whereas the conventional Contact process and the WSA (Wet sulfuric acid process) are the most used technologies for recovering sulfuric acid. Smaller quantities of acid gas may be disposed of by flaring.

The residual gas from the Claus process is commonly called tail gas and that gas is then processed in a tail gas treating unit (TGTU) to recover and recycle residual sulfur-containing compounds back into the Claus unit. Again, as shown in the flow diagram, there are a number of processes available for treating the Claus unit tail gas and for that purpose a WSA process is also very suitable since it can work autothermally on tail gases.

The next step in the gas processing plant is to remove water vapor from the gas using either the regenerable absorption in liquid triethylene glycol (TEG),[12] commonly referred to as glycol dehydration, deliquescent chloride desiccants, and or a Pressure Swing Adsorption (PSA) unit which is regenerable adsorption using a solid adsorbent.[25] Other newer processes like membranes may also be considered.

Mercury is then removed by using adsorption processes (as shown in the flow diagram) such as activated carbon or regenerable molecular sieves.[7]

Although not common, nitrogen is sometimes removed and rejected using one of the three processes indicated on the flow diagram:

  • Cryogenic process (Nitrogen Rejection Unit),[26] using low temperature distillation. This process can be modified to also recover helium, if desired (see also industrial gas).
  • Absorption process,[27] using lean oil or a special solvent[28] as the absorbent.
  • Adsorption process, using activated carbon or molecular sieves as the adsorbent. This process may have limited applicability because it is said to incur the loss of butanes and heavier hydrocarbons.

NGL fractionation train Edit

The NGL fractionation process treats offgas from the separators at an oil terminal or the overhead fraction from a crude distillation column in a refinery. Fractionation aims to produce useful products including natural gas suitable for piping to industrial and domestic consumers; liquefied petroleum gases (Propane and Butane) for sale; and gasoline feedstock for liquid fuel blending.[29] The recovered NGL stream is processed through a fractionation train consisting of up to five distillation towers in series: a demethanizer, a deethanizer, a depropanizer, a debutanizer and a butane splitter. The fractionation train typically uses a cryogenic low temperature distillation process involving expansion of the recovered NGL through a turbo-expander followed by distillation in a demethanizing fractionating column.[30][31] Some gas processing plants use lean oil absorption process[27] rather than the cryogenic turbo-expander process.

The gaseous feed to the NGL fractionation plant is typically compressed to about 60 barg and 37 °C.[32] The feed is cooled to -22 °C, by exchange with the demethanizer overhead product and by a refrigeration system and is split into three streams:

  • condensed liquid passes through a Joule-Thomson valve reducing the pressure to 20 bar and enters the demethanizzer as the lower feed at -44.7 °C.
  • some of the vapour is routed through a turbo-expander and enters the demethanizer as the upper feed at -64 °C.
  • the remaining vapor is chilled by the demethanizer overhead product and Joule-Thomson cooling (through a valve) and enters the column as reflux at -96 °C.[32]

The overhead product is mainly methane at 20 bar and -98 °C. This is heated and compressed to yield a sales gas at 20 bar and 40 °C. The bottom product is NGL at 20 barg which is fed to the deethanizer.  

The overhead product from the deethanizer is ethane and the bottoms are fed to the depropanizer. The overhead product from the depropanizer is propane and the bottoms are fed to the debutanizer. The overhead product from the debutanizer is a mixture of normal and iso-butane, and the bottoms product is a C5+ gasoline mixture.

The operating conditions of the vessels in the NGL fractionation train are typically as follows.[29][33][34]

NGL column operating conditions
Demethanizer Deethanizer Depropanizer Debutanizer Butane Splitter
Feed pressure 60 barg 30 barg
Feed temperature 37 °C 25 °C 37 °C 125 °C 59 °C
Column operating pressure 20 barg 26-30 barg 10-16.2 barg 3.8-17 barg 4.9-7 barg
Overhead product temperature -98°C 50 °C 59 °C 49 °C
Bottom product temperature 12 °C 37 °C 125 °C 118 °C 67 °C
Overhead product Methane (natural gas) Ethane Propane Butane Isobutane
Bottom product Natural gas liquids (Depropanizer feed) (Debutanizer feed) Gasoline Normal Butane

A typical composition of the feed and product is as follows.[32]

Stream composition, % volume
Component Feed NGL Ethane Propane Isobutane n-Butane Gasoline
Methane 89.4 0.5 1.36
Ethane 4.9 37.0 95.14 7.32
Propane 2.2 26.0 3.5 90.18 2.0
Isobutane 1.3 7.2 2.5 96.0 4.5
n-Butane 2.2 14.8 2.0 95.0 3.0
Isopentane 5.0 33.13
n-Pentane 3.5 0.5 23.52
n-Hexane 4.0 26.9
n-Heptane 2.0 13.45
Total 100 100 100 100 100 100 100

Sweetening Units Edit

The recovered streams of propane, butanes and C5+ may be "sweetened" in a Merox process unit to convert undesirable mercaptans into disulfides and, along with the recovered ethane, are the final NGL by-products from the gas processing plant. Currently, most cryogenic plants do not include fractionation for economic reasons, and the NGL stream is instead transported as a mixed product to standalone fractionation complexes located near refineries or chemical plants that use the components for feedstock. In case laying pipeline is not possible for geographical reason, or the distance between source and consumer exceed 3000 km, natural gas is then transported by ship as LNG (liquefied natural gas) and again converted into its gaseous state in the vicinity of the consumer.

Products Edit

The residue gas from the NGL recovery section is the final, purified sales gas which is pipelined to the end-user markets. Rules and agreements are made between buyer and seller regarding the quality of the gas. These usually specify the maximum allowable concentration of CO2, H2S and H2O as well as requiring the gas to be commercially free from objectionable odours and materials, and dust or other solid or liquid matter, waxes, gums and gum forming constituents, which might damage or adversely affect operation of the buyers equipment. When an upset occurs on the treatment plant buyers can usually refuse to accept the gas, lower the flow rate or re-negotiate the price.

 

Helium recovery Edit

If the gas has significant helium content, the helium may be recovered by fractional distillation. Natural gas may contain as much as 7% helium, and is the commercial source of the noble gas.[35] For instance, the Hugoton Gas Field in Kansas and Oklahoma in the United States contains concentrations of helium from 0.3% to 1.9%, which is separated out as a valuable byproduct.[36]

See also Edit

References Edit

  1. ^ "PHMSA: Stakeholder Communications - NG Processing Plants". primis.phmsa.dot.gov. Retrieved 9 April 2018.
  2. ^ a b Speight, James G. (2015). Handbook of Petroleum Product Analysis, Second Edition. Hoboken, NJ: John Wiley & Sons. p. 71. ISBN 978-1-118-36926-5.
  3. ^ (PDF). Archived from the original (PDF) on 2016-03-05. Retrieved 2014-09-21.{{cite web}}: CS1 maint: archived copy as title (link)
  4. ^ Kidnay, Arthur J.; Parrish, William R.; McCartney, Daniel G. (2019). Fundamentals of Natural Gas Processing, Third Edition. Boca Raton, FL: CRC Press. p. 165. ISBN 978-0-429-87715-5.
  5. ^ Agency, United States Central Intelligence (1977). Natural Gas. Washington, D.C.: U.S. Central Intelligence Agency. p. 25.
  6. ^ a b U.S. Crude Oil Production Forecast- Analysis of Crude Types (PDF), Washington, DC: U.S. Energy Information Administration, 29 May 2014, p. 7, A final point to consider involves the distinction between the very light grades of lease condensate (which are included in EIA's oil production data) and hydrocarbon gas liquids (HGL) that are produced from the wellhead as gas but are converted to liquids when separated from methane at a natural gas processing plant. These hydrocarbons include ethane, propane, butanes, and hydrocarbons with five or more carbon atoms – referred to as pentanes plus, naptha, or plant condensate. Plant condensate can also be blended with crude oil, which would change both the distribution and total volume of oil received by refineries.
  7. ^ a b c (PDF). UOP LLC. Archived from the original (PDF) on 2011-01-01.
  8. ^ "Radium in Piping".
  9. ^ a b c d "Gas Safety (Management) Regulations 1996". legislation.co.uk. 1996. Retrieved 13 June 2020.
  10. ^ Institute of Petroleum (1978). A guide to North Sea oil and gas technology. London: Heyden & Son. p. 133. ISBN 0855013168.
  11. ^ Dehydration of Natural Gas 2007-02-24 at the Wayback Machine by Prof. Jon Steiner Gudmundsson, Norwegian University of Science and Technology
  12. ^ a b Glycol Dehydration 2009-09-12 at the Wayback Machine (includes a flow diagram)
  13. ^ Desulfurization of and Mercury Removal From Natural Gas 2008-03-03 at the Wayback Machine by Bourke, M.J. and Mazzoni, A.F., Laurance Reid Gas Conditioning Conference, Norman, Oklahoma, March 1989.
  14. ^ Using Gas Geochemistry to Assess Mercury Risk 2015-08-28 at the Wayback Machine, OilTracers, 2006
  15. ^ Natural Gas Processing: The Crucial Link Between Natural Gas Production and Its Transportation to Market 2011-03-04 at the Wayback Machine
  16. ^ Example Gas Plant 2010-12-01 at the Wayback Machine
  17. ^ From Purification to Liquefaction Gas Processing 2010-01-15 at the Wayback Machine
  18. ^ "Feed-Gas Treatment Design for the Pearl GTL Project" (PDF). spe.org. Retrieved 9 April 2018.
  19. ^ Benefits of integrating NGL extraction and LNG liquefaction 2013-06-26 at the Wayback Machine
  20. ^ "MSDS: Natural gas liquids" (PDF). ConocoPhillips.
  21. ^ "What are natural gas liquids and how are they used?". United States Energy Information Administration. April 20, 2012.
  22. ^ "Guide to Understanding Natural Gas and Natural Gas Liquids". STI Group. 2014-02-19.
  23. ^ "Liquid / Gas Separation Technology - Oil & Gas | Pall Corporation". www.pall.com. Retrieved 2023-04-22.
  24. ^ Baker, R. W. "Future Directions of Membrane Gas Separation Technology" Ind. Eng. Chem. Res. 2002, volume 41, pages 1393-1411. doi:10.1021/ie0108088
  25. ^ Molecular Sieves 2011-01-01 at the Wayback Machine (includes a flow diagram of a PSA unit)
  26. ^ Gas Processes 2002, Hydrocarbon Processing, pages 84–86, May 2002 (schematic flow diagrams and descriptions of the Nitrogen Rejection and Nitrogen Removal processes)
  27. ^ a b Market-Driven Evolution of Gas Processing Technologies for NGLs Advanced Extraction Technology Inc. website page
  28. ^ AET Process Nitrogen Rejection Unit Advanced Extraction Technology Inc. website page
  29. ^ a b Manley, D. B. (1998). "Thermodynamically efficient distillation: NGL Fractionation". Latin American Applied Research.
  30. ^ Cryogenic Turbo-Expander Process Advanced Extraction Technology Inc. website page
  31. ^ Gas Processes 2002, Hydrocarbon Processing, pages 83–84, May 2002 (schematic flow diagrams and descriptions of the NGL-Pro and NGL Recovery processes)
  32. ^ a b c Muneeb Nawaz ‘Synthesis and Design of Demethaniser Flowsheets for Low Temperature Separation Processes,' University of Manchester,unpublished PhD thesis, 2011, pp. 137, 138, 154
  33. ^ Luyben, W. L. (2013). "Control of a Train of Distillation Columns for the Separation of natural gas". Industrial and Engineering Chemistry Research. 52: 5710741–10753. doi:10.1021/ie400869v.
  34. ^ ElBadawy, K. M.; Teamah, M. A.; Shehata, A. I.; Hanfy, A. A. (2017). "Simulation of LPG Production from Natural Gas using Fractionation Towers". International Journal of Advanced Scientific and Technical Research. 6 (7).
  35. ^ Winter, Mark (2008). "Helium: the essentials". University of Sheffield. Retrieved 2008-07-14.
  36. ^ Dwight E. Ward and Arthur P. Pierce (1973) "Helium" in United States Mineral Resources, US Geological Survey, Professional Paper 820, p.285-290.

External links Edit

  • Natural Gas Processing Principles and Technology (an extensive and detailed course text by Dr. A.H. Younger, University of Calgary, Alberta, Canada).
  • , Website of the Natural Gas Supply Association (NGSA).
  • Natural Gas Processing (part of the US EPA's AP-42 publication)
  • Natural Gas Processing Plants (a US Department of Transportation website)
  • Gas Processors Association, Website of the Gas Processors Association (GPA) headquartered in Tulsa, Oklahoma, United States.
  • Gas Processing Journal (Publisher: College of Engineering, University of Isfahan, Iran.)
  • Increasing Efficiency of Gas Processing Plants
  • [1]

Further reading Edit

  • Haring, H.W. (2008). Industrial Gases Processing. Weinheim, Germany: WILEY-VCH Verlag Gmbh & CO. KGaA
  • Kohl, A., & Nielsen, R. (1997). Gas Purification. 5TH Edition. Houston, Texas: Gulf Publishing Company

October 15, 2023
natural, processing, range, industrial, processes, designed, purify, natural, removing, contaminants, such, solids, water, carbon, dioxide, hydrogen, sulfide, mercury, higher, molecular, mass, hydrocarbons, condensate, produce, pipeline, quality, natural, pipe. Natural gas processing is a range of industrial processes designed to purify raw natural gas by removing contaminants such as solids water carbon dioxide CO2 hydrogen sulfide H2S mercury and higher molecular mass hydrocarbons condensate to produce pipeline quality dry natural gas 1 for pipeline distribution and final use 2 Some of the substances which contaminate natural gas have economic value and are further processed or sold Hydrocarbons that are liquid at ambient conditions temperature and pressure i e pentane and heavier are called natural gas condensate sometimes also called natural gasoline or simply condensate A natural gas processing plant in Aderklaa AustriaRaw natural gas comes primarily from three types of wells crude oil wells gas wells and condensate wells Crude oil and natural gas are often found together in the same reservoir Natural gas produced in wells with crude oil is generally classified as associated dissolved gas as the gas had been associated with or dissolved in crude oil Natural gas production not associated with crude oil is classified as non associated In 2009 89 percent of U S wellhead production of natural gas was non associated 3 Non associated gas wells producing a dry gas in terms of condensate and water can send the dry gas directly to a pipeline or gas plant without undergoing any separation processIng allowing immediate use 4 Natural gas processing begins underground or at the well head In a crude oil well natural gas processing begins as the fluid loses pressure and flows through the reservoir rocks until it reaches the well tubing 5 In other wells processing begins at the wellhead which extracts the composition of natural gas according to the type depth and location of the underground deposit and the geology of the area 2 Natural gas when relatively free of hydrogen sulfide is called sweet gas natural gas that contains elevated hydrogen sulfide levels is called sour gas natural gas or any other gas mixture containing significant quantities of hydrogen sulfide or carbon dioxide or similar acidic gases is called acid gas Contents 1 Types of raw natural gas wells 2 Contaminants in raw natural gas 3 Natural gas quality standards 4 Description of a natural gas processing plant 4 1 NGL fractionation train 4 2 Sweetening Units 4 3 Products 4 4 Helium recovery 5 See also 6 References 7 External links 8 Further readingTypes of raw natural gas wells EditCrude oil wells Natural gas that comes from crude oil wells is typically called associated gas This gas could exist as a separate gas cap above the crude oil in the underground reservoir or could be dissolved in the crude oil ultimately coming out of solution as the pressure is reduced during production Condensate produced from oil wells is often referred to as lease condensate 6 Dry gas wells These wells typically produce only raw natural gas that contains no condensate with little to no crude oil and are called non associated gas Condensate from dry gas is extracted at gas processing plants and is often called plant condensate 6 Condensate wells These wells typically produce raw natural gas along with natural gas liquid with little to no crude oil and are called non associated gas Such raw natural gas is often referred to as wet gas Coal seam wells These wells typically produce raw natural gas from methane deposits in the pores of coal seams often existing underground in a more concentrated state of adsorption onto the surface of the coal itself Such gas is referred to as coalbed gas or coalbed methane coal seam gas in Australia Coalbed gas has become an important source of energy in recent decades Contaminants in raw natural gas EditSee also Natural gas condensate Raw natural gas typically consists primarily of methane CH4 and ethane C2H6 the shortest and lightest hydrocarbon molecules It often also contains varying amounts of Heavier gaseous hydrocarbons propane C3H8 normal butane n C4H10 isobutane i C4H10 and pentanes All of these are collectively referred to as Natural Gas Liquids or NGL and can be processed into finished by products Liquid hydrocarbons also referred to as casinghead gasoline or natural gasoline and or crude oil Acid gases carbon dioxide CO2 hydrogen sulfide H2S and mercaptans such as methanethiol CH3SH and ethanethiol C2H5SH Other gases nitrogen N2 and helium He Water water vapor and liquid water Also dissolved salts and dissolved gases acids Mercury minute amounts of mercury primarily in elemental form but chlorides and other species are possibly present 7 Naturally occurring radioactive material NORM natural gas may contain radon and the produced water may contain dissolved traces of radium which can accumulate within piping and processing equipment rendering piping and equipment radioactive over time 8 Natural gas quality standards EditRaw natural gas must be purified to meet the quality standards specified by the major pipeline transmission and distribution companies Those quality standards vary from pipeline to pipeline and are usually a function of a pipeline system s design and the markets that it serves In general the standards specify that the natural gas Be within a specific range of heating value caloric value For example in the United States it should be about 1035 5 BTU per cubic foot of gas at 1 atmosphere and 60 F 41 MJ 5 per cubic metre of gas at 1 atmosphere and 15 6 C In the United Kingdom the gross calorific value must be in the range 37 0 44 5 MJ m3 for entry into the National Transmission System NTS 9 Be delivered at or above a specified hydrocarbon dew point temperature below which some of the hydrocarbons in the gas might condense at pipeline pressure forming liquid slugs that could damage the pipeline Hydrocarbon dew point adjustment reduces the concentration of heavy hydrocarbons so no condensation occurs during the ensuing transport in the pipelines In the UK the hydrocarbon dew point is defined as lt 2 C for entry into the NTS 9 The hydrocarbon dewpoint changes with the prevailing ambient temperature the seasonal variation is 10 Seasonal variation of hydrocarbon dewpoint Hydrocarbon dewpoint 30 F 1 1 C 35 F 1 7 C 40 F 4 4 C 45 F 7 2 C 50 F 10 C Months December JanuaryFebruaryMarch April November May October June September July AugustThe natural gas should Be free of particulate solids and liquid water to prevent erosion corrosion or other damage to the pipeline Be dehydrated of water vapor sufficiently to prevent the formation of methane hydrates within the gas processing plant or subsequently within the sales gas transmission pipeline A typical water content specification in the U S is that gas must contain no more than seven pounds of water per million standard cubic feet of gas 11 12 In the UK this is defined as lt 10 C 85barg for entry into the NTS 9 Contain no more than trace amounts of components such as hydrogen sulfide carbon dioxide mercaptans and nitrogen The most common specification for hydrogen sulfide content is 0 25 grain H2S per 100 cubic feet of gas or approximately 4 ppm Specifications for CO2 typically limit the content to no more than two or three percent In the UK hydrogen sulfide is specified 5 mg m3 and total sulfur as 50 mg m3 carbon dioxide as 2 0 molar and nitrogen as 5 0 molar for entry into the NTS 9 Maintain mercury at less than detectable limits approximately 0 001 ppb by volume primarily to avoid damaging equipment in the gas processing plant or the pipeline transmission system from mercury amalgamation and embrittlement of aluminum and other metals 7 13 14 Description of a natural gas processing plant EditThere are a variety of ways in which to configure the various unit processes used in the treatment of raw natural gas The block flow diagram below is a generalized typical configuration for the processing of raw natural gas from non associated gas wells showing how raw natural gas is processed into sales gas piped to the end user markets 15 16 17 18 19 and various byproducts Natural gas condensate Sulfur Ethane Natural gas liquids NGL propane butanes and C5 which is the commonly used term for pentanes plus higher molecular weight hydrocarbons 20 21 22 Raw natural gas is commonly collected from a group of adjacent wells and is first processed in a separator vessels at that collection point for removal of free liquid water and natural gas condensate 23 The condensate is usually then transported to an oil refinery and the water is treated and disposed of as wastewater The raw gas is then piped to a gas processing plant where the initial purification is usually the removal of acid gases hydrogen sulfide and carbon dioxide There are several processes available for that purpose as shown in the flow diagram but amine treating is the process that was historically used However due to a range of performance and environmental constraints of the amine process a newer technology based on the use of polymeric membranes to separate the carbon dioxide and hydrogen sulfide from the natural gas stream has gained increasing acceptance Membranes are attractive since no reagents are consumed 24 The acid gases if present are removed by membrane or amine treating and can then be routed into a sulfur recovery unit which converts the hydrogen sulfide in the acid gas into either elemental sulfur or sulfuric acid Of the processes available for these conversions the Claus process is by far the most well known for recovering elemental sulfur whereas the conventional Contact process and the WSA Wet sulfuric acid process are the most used technologies for recovering sulfuric acid Smaller quantities of acid gas may be disposed of by flaring The residual gas from the Claus process is commonly called tail gas and that gas is then processed in a tail gas treating unit TGTU to recover and recycle residual sulfur containing compounds back into the Claus unit Again as shown in the flow diagram there are a number of processes available for treating the Claus unit tail gas and for that purpose a WSA process is also very suitable since it can work autothermally on tail gases The next step in the gas processing plant is to remove water vapor from the gas using either the regenerable absorption in liquid triethylene glycol TEG 12 commonly referred to as glycol dehydration deliquescent chloride desiccants and or a Pressure Swing Adsorption PSA unit which is regenerable adsorption using a solid adsorbent 25 Other newer processes like membranes may also be considered Mercury is then removed by using adsorption processes as shown in the flow diagram such as activated carbon or regenerable molecular sieves 7 Although not common nitrogen is sometimes removed and rejected using one of the three processes indicated on the flow diagram Cryogenic process Nitrogen Rejection Unit 26 using low temperature distillation This process can be modified to also recover helium if desired see also industrial gas Absorption process 27 using lean oil or a special solvent 28 as the absorbent Adsorption process using activated carbon or molecular sieves as the adsorbent This process may have limited applicability because it is said to incur the loss of butanes and heavier hydrocarbons NGL fractionation train Edit The NGL fractionation process treats offgas from the separators at an oil terminal or the overhead fraction from a crude distillation column in a refinery Fractionation aims to produce useful products including natural gas suitable for piping to industrial and domestic consumers liquefied petroleum gases Propane and Butane for sale and gasoline feedstock for liquid fuel blending 29 The recovered NGL stream is processed through a fractionation train consisting of up to five distillation towers in series a demethanizer a deethanizer a depropanizer a debutanizer and a butane splitter The fractionation train typically uses a cryogenic low temperature distillation process involving expansion of the recovered NGL through a turbo expander followed by distillation in a demethanizing fractionating column 30 31 Some gas processing plants use lean oil absorption process 27 rather than the cryogenic turbo expander process The gaseous feed to the NGL fractionation plant is typically compressed to about 60 barg and 37 C 32 The feed is cooled to 22 C by exchange with the demethanizer overhead product and by a refrigeration system and is split into three streams condensed liquid passes through a Joule Thomson valve reducing the pressure to 20 bar and enters the demethanizzer as the lower feed at 44 7 C some of the vapour is routed through a turbo expander and enters the demethanizer as the upper feed at 64 C the remaining vapor is chilled by the demethanizer overhead product and Joule Thomson cooling through a valve and enters the column as reflux at 96 C 32 The overhead product is mainly methane at 20 bar and 98 C This is heated and compressed to yield a sales gas at 20 bar and 40 C The bottom product is NGL at 20 barg which is fed to the deethanizer The overhead product from the deethanizer is ethane and the bottoms are fed to the depropanizer The overhead product from the depropanizer is propane and the bottoms are fed to the debutanizer The overhead product from the debutanizer is a mixture of normal and iso butane and the bottoms product is a C5 gasoline mixture The operating conditions of the vessels in the NGL fractionation train are typically as follows 29 33 34 NGL column operating conditions Demethanizer Deethanizer Depropanizer Debutanizer Butane SplitterFeed pressure 60 barg 30 bargFeed temperature 37 C 25 C 37 C 125 C 59 CColumn operating pressure 20 barg 26 30 barg 10 16 2 barg 3 8 17 barg 4 9 7 bargOverhead product temperature 98 C 50 C 59 C 49 CBottom product temperature 12 C 37 C 125 C 118 C 67 COverhead product Methane natural gas Ethane Propane Butane IsobutaneBottom product Natural gas liquids Depropanizer feed Debutanizer feed Gasoline Normal ButaneA typical composition of the feed and product is as follows 32 Stream composition volume Component Feed NGL Ethane Propane Isobutane n Butane GasolineMethane 89 4 0 5 1 36Ethane 4 9 37 0 95 14 7 32Propane 2 2 26 0 3 5 90 18 2 0Isobutane 1 3 7 2 2 5 96 0 4 5n Butane 2 2 14 8 2 0 95 0 3 0Isopentane 5 0 33 13n Pentane 3 5 0 5 23 52n Hexane 4 0 26 9n Heptane 2 0 13 45Total 100 100 100 100 100 100 100Sweetening Units Edit The recovered streams of propane butanes and C5 may be sweetened in a Merox process unit to convert undesirable mercaptans into disulfides and along with the recovered ethane are the final NGL by products from the gas processing plant Currently most cryogenic plants do not include fractionation for economic reasons and the NGL stream is instead transported as a mixed product to standalone fractionation complexes located near refineries or chemical plants that use the components for feedstock In case laying pipeline is not possible for geographical reason or the distance between source and consumer exceed 3000 km natural gas is then transported by ship as LNG liquefied natural gas and again converted into its gaseous state in the vicinity of the consumer Products Edit The residue gas from the NGL recovery section is the final purified sales gas which is pipelined to the end user markets Rules and agreements are made between buyer and seller regarding the quality of the gas These usually specify the maximum allowable concentration of CO2 H2S and H2O as well as requiring the gas to be commercially free from objectionable odours and materials and dust or other solid or liquid matter waxes gums and gum forming constituents which might damage or adversely affect operation of the buyers equipment When an upset occurs on the treatment plant buyers can usually refuse to accept the gas lower the flow rate or re negotiate the price nbsp Helium recovery Edit If the gas has significant helium content the helium may be recovered by fractional distillation Natural gas may contain as much as 7 helium and is the commercial source of the noble gas 35 For instance the Hugoton Gas Field in Kansas and Oklahoma in the United States contains concentrations of helium from 0 3 to 1 9 which is separated out as a valuable byproduct 36 See also EditNatural gas prices Petroleum extraction Oil refinery List of natural gas and oil production accidents in the United StatesReferences Edit PHMSA Stakeholder Communications NG Processing Plants primis phmsa dot gov Retrieved 9 April 2018 a b Speight James G 2015 Handbook of Petroleum Product Analysis Second Edition Hoboken NJ John Wiley amp Sons p 71 ISBN 978 1 118 36926 5 Archived copy PDF Archived from the original PDF on 2016 03 05 Retrieved 2014 09 21 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Kidnay Arthur J Parrish William R McCartney Daniel G 2019 Fundamentals of Natural Gas Processing Third Edition Boca Raton FL CRC Press p 165 ISBN 978 0 429 87715 5 Agency United States Central Intelligence 1977 Natural Gas Washington D C U S Central Intelligence Agency p 25 a b U S Crude Oil Production Forecast Analysis of Crude Types PDF Washington DC U S Energy Information Administration 29 May 2014 p 7 A final point to consider involves the distinction between the very light grades of lease condensate which are included in EIA s oil production data and hydrocarbon gas liquids HGL that are produced from the wellhead as gas but are converted to liquids when separated from methane at a natural gas processing plant These hydrocarbons include ethane propane butanes and hydrocarbons with five or more carbon atoms referred to as pentanes plus naptha or plant condensate Plant condensate can also be blended with crude oil which would change both the distribution and total volume of oil received by refineries a b c Mercury Removal from Natural Gas and Liquids PDF UOP LLC Archived from the original PDF on 2011 01 01 Radium in Piping a b c d Gas Safety Management Regulations 1996 legislation co uk 1996 Retrieved 13 June 2020 Institute of Petroleum 1978 A guide to North Sea oil and gas technology London Heyden amp Son p 133 ISBN 0855013168 Dehydration of Natural Gas Archived 2007 02 24 at the Wayback Machine by Prof Jon Steiner Gudmundsson Norwegian University of Science and Technology a b Glycol Dehydration Archived 2009 09 12 at the Wayback Machine includes a flow diagram Desulfurization of and Mercury Removal From Natural Gas Archived 2008 03 03 at the Wayback Machine by Bourke M J and Mazzoni A F Laurance Reid Gas Conditioning Conference Norman Oklahoma March 1989 Using Gas Geochemistry to Assess Mercury Risk Archived 2015 08 28 at the Wayback Machine OilTracers 2006 Natural Gas Processing The Crucial Link Between Natural Gas Production and Its Transportation to Market Archived 2011 03 04 at the Wayback Machine Example Gas Plant Archived 2010 12 01 at the Wayback Machine From Purification to Liquefaction Gas Processing Archived 2010 01 15 at the Wayback Machine Feed Gas Treatment Design for the Pearl GTL Project PDF spe org Retrieved 9 April 2018 Benefits of integrating NGL extraction and LNG liquefaction Archived 2013 06 26 at the Wayback Machine MSDS Natural gas liquids PDF ConocoPhillips What are natural gas liquids and how are they used United States Energy Information Administration April 20 2012 Guide to Understanding Natural Gas and Natural Gas Liquids STI Group 2014 02 19 Liquid Gas Separation Technology Oil amp Gas Pall Corporation www pall com Retrieved 2023 04 22 Baker R W Future Directions of Membrane Gas Separation Technology Ind Eng Chem Res 2002 volume 41 pages 1393 1411 doi 10 1021 ie0108088 Molecular Sieves Archived 2011 01 01 at the Wayback Machine includes a flow diagram of a PSA unit Gas Processes 2002 Hydrocarbon Processing pages 84 86 May 2002 schematic flow diagrams and descriptions of the Nitrogen Rejection and Nitrogen Removal processes a b Market Driven Evolution of Gas Processing Technologies for NGLs Advanced Extraction Technology Inc website page AET Process Nitrogen Rejection Unit Advanced Extraction Technology Inc website page a b Manley D B 1998 Thermodynamically efficient distillation NGL Fractionation Latin American Applied Research Cryogenic Turbo Expander Process Advanced Extraction Technology Inc website page Gas Processes 2002 Hydrocarbon Processing pages 83 84 May 2002 schematic flow diagrams and descriptions of the NGL Pro and NGL Recovery processes a b c Muneeb Nawaz Synthesis and Design of Demethaniser Flowsheets for Low Temperature Separation Processes University of Manchester unpublished PhD thesis 2011 pp 137 138 154 Luyben W L 2013 Control of a Train of Distillation Columns for the Separation of natural gas Industrial and Engineering Chemistry Research 52 5710741 10753 doi 10 1021 ie400869v ElBadawy K M Teamah M A Shehata A I Hanfy A A 2017 Simulation of LPG Production from Natural Gas using Fractionation Towers International Journal of Advanced Scientific and Technical Research 6 7 Winter Mark 2008 Helium the essentials University of Sheffield Retrieved 2008 07 14 Dwight E Ward and Arthur P Pierce 1973 Helium in United States Mineral Resources US Geological Survey Professional Paper 820 p 285 290 External links EditSimulate natural gas processing using Aspen HYSYS Natural Gas Processing Principles and Technology an extensive and detailed course text by Dr A H Younger University of Calgary Alberta Canada Processing Natural Gas Website of the Natural Gas Supply Association NGSA Natural Gas Processing part of the US EPA s AP 42 publication Natural Gas Processing Plants a US Department of Transportation website Gas Processors Association Website of the Gas Processors Association GPA headquartered in Tulsa Oklahoma United States Gas Processing Journal Publisher College of Engineering University of Isfahan Iran Increasing Efficiency of Gas Processing Plants 1 Further reading EditHaring H W 2008 Industrial Gases Processing Weinheim Germany WILEY VCH Verlag Gmbh amp CO KGaA Kohl A amp Nielsen R 1997 Gas Purification 5TH Edition Houston Texas Gulf Publishing Company Retrieved from https en wikipedia org w index php title Natural gas processing amp oldid 1170484892, wikipedia, wiki, book, books, library,

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