Petrochemicals: Difference between revisions
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{{Image|Complete Teesside petrochemical plant.jpg|right|350px|A complete petrochemical plant site at Teesside, England.}} | |||
'''Petrochemicals''' are [[Chemistry|chemical]] products made from the [[hydrocarbon]]s present in raw [[natural gas]] and [[Petroleum|petroleum crude oil]]. The largest petrochemical manufacturing industries are to be found in the [[United States of America]], [[Europe|Western Europe]], [[Asia]] and the [[Middle East]]. | |||
As of 2007, there were 2,980 operating petrochemical plants in 4,320 locations worldwide.<ref>[http://www.prlog.org/10011624-petrochemical-industry-worldwide.pdf Petrochemical Industry – Worldwide]</ref> The petrochemical end products from those plants include plastics, soaps, detergents, solvents, paints, drugs, fertilizer, pesticides, explosives, synthetic textile fibers and rubbers, flooring and insulating materials and much more. Petrochemicals are found in such common consumer products as aspirin, cars, clothing, compact discs, video tapes, electronic equipment, furniture, and a great many others.<ref>[http://www.npradc.org/docs/ourIndustry/petrochemicalFacts/petrochart.pdf Petrochemicals Chart] From the website of the [[National Petrochemical & Refiners Association]]</ref> | A relatively small number of hydrocarbon feedstocks form the basis of the petrochemical industries, namely [[methane]], [[ethylene]], [[propylene]], [[butane]]s, [[butadiene]], [[benzene]], [[toluene]] and [[xylene]]s.<ref name=Hatch>{{cite book|author=Sami Matar and Lewis F. Hatch|title=Chemistry of Petrochemical Processes|edition=|publisher=Gulf Professional Publishing|year=2001|id=ISBN 0-0-88415-315-0}}</ref><ref name=HP>{{cite journal|author=Staff |year=2001 |month=March|title=Petrochemical Processes 2001 |journal=Hydrocarbon Processing |volume= |issue= |pages=pp. 71-246 |id=ISSN 0887-0284}}</ref> | ||
As of 2007, there were 2,980 operating petrochemical plants in 4,320 locations worldwide.<ref>[http://www.prlog.org/10011624-petrochemical-industry-worldwide.pdf Petrochemical Industry – Worldwide]</ref> The petrochemical end products from those plants include plastics, soaps, detergents, solvents, paints, drugs, fertilizer, pesticides, explosives, synthetic textile fibers and rubbers, flooring and insulating materials and much more. | |||
Petrochemicals are found in such common consumer products as aspirin, cars, clothing, compact discs, video tapes, electronic equipment, furniture, and a great many others.<ref>[http://www.npradc.org/docs/ourIndustry/petrochemicalFacts/petrochart.pdf Petrochemicals Chart] From the website of the [[National Petrochemical & Refiners Association]]</ref> | |||
==Feedstocks sources== | ==Feedstocks sources== | ||
{{Image|Petrochem Feedstocks.png|right|426px|Petrochemical feedstock sources.}} | |||
The adjacent diagram schematically depicts the major hydrocarbon sources used in producing petrochemicals are:<ref name=Hatch/><ref name=HP/><ref name=AMAP>[http://www.tsp2.org/news/Butadiene%20Supply%20AMAP%20Update.pdf SBS Polymer Supply Outlook]</ref><ref>{{cite book|author=Jean-Pierre Favennec (Editor)|title= Petroleum Refining: Refinery Operation and Management|edition=|publisher=Editions Technip|year=2001|id=ISBN 2-7108-0801-3}}</ref> | |||
Methane | :*Methane, [[ethane]], [[propane]] and [[butane]]s: Obtained primarily from [[Natural gas processing|natural gas processing plants]]. | ||
:*[[Petroleum naphtha|Naphtha]] obtained from [[Petroleum refining processes|petroleum refineries]]. | |||
:*Benzene, toluene and xylenes, as a whole referred to as ''[[BTX]]'' and primarily obtained from petroleum refineries by extraction from the reformate produced in [[Catalytic reforming|catalytic reformers]]. | |||
:*[[Gas oil]] obtained from petroleum refineries. | |||
*Ethylene | Methane and BTX are used directly as feedstocks for producing petrochemicals. However, the ethane, propane, butanes, naphtha and gas oil serve as optional feedstocks for steam-assisted [[thermal cracking]] plants referred to as ''[[steam crackers]]'' that produce these intermediate petrochemical feedstocks: | ||
*Propylene | |||
*Butenes and butadiene | :*Ethylene | ||
*Benzene | :*Propylene | ||
:*Butenes and butadiene | |||
:*Benzene | |||
In 2007, the amounts of ethylene and propylene produced in steam crackers were about 115 M[[Tonne|t]] (megatonnes) and 70 Mt, respectively.<ref>{{cite book|author=Hassan E. Alfadala, G.V. Rex Reklaitis and Mahmoud M. El-Halwagi (Editors)|title=Proceedings of the 1st Annual Gas Processing Symposium, Volume 1: January, 2009 - Qatar|edition=1st Edition|publisher=Elsevier Science|pages= pp. 402-414|year=2009|id=ISBN 0-444-53292-7}}</ref> The output ethylene capacity of large steam crackers ranged up to as much as 1.0 – 1.5 Mt per year.<ref>[http://www.petrochemistry.net/crackers-capacities-in-europe.html Crackers capacities] From the website of the [[Association of Petrochemicals Producers in Europe]] (APPE)</ref><ref>[http://www.technip.com/pdf/brochures/Ethylene.pdf Steam Cracking: Ethylene Production] (PDF page 3 of 12 pages)</ref> | In 2007, the amounts of ethylene and propylene produced in steam crackers were about 115 M[[Tonne|t]] (megatonnes) and 70 Mt, respectively.<ref>{{cite book|author=Hassan E. Alfadala, G.V. Rex Reklaitis and Mahmoud M. El-Halwagi (Editors)|title=Proceedings of the 1st Annual Gas Processing Symposium, Volume 1: January, 2009 - Qatar|edition=1st Edition|publisher=Elsevier Science|pages= pp. 402-414|year=2009|id=ISBN 0-444-53292-7}}</ref> The output ethylene capacity of large steam crackers ranged up to as much as 1.0 – 1.5 Mt per year.<ref>[http://www.petrochemistry.net/crackers-capacities-in-europe.html Crackers capacities] From the website of the [[Association of Petrochemicals Producers in Europe]] (APPE)</ref><ref>[http://www.technip.com/pdf/brochures/Ethylene.pdf Steam Cracking: Ethylene Production] (PDF page 3 of 12 pages)</ref> | ||
The | Steam crackers are not to be confused with [[steam reforming]] plants used to produce [[hydrogen]] and [[Ammonia production|ammonia]]. | ||
===Worldwide usage of optional steam cracking feedstock sources=== | |||
As of 2004, the percentage of the worldwide steam cracking plants using each of the optional steam cracking feed sources was:<ref>{{cite book|author=Richard Meyers|title=The Basics of Chemistry|edition=|publisher=Greenwood Press|year=2003|id=ISBN 0-313-31664-3}}</ref> | |||
:*Ethane: 35% | |||
:*Propane: 9% | |||
:*Butanes: 3% | |||
:*Naphtha: 45% | |||
:*Gas oil: 5% | |||
:*Other: 3 % | |||
===The effect of feedstock on the steam cracking yields of intermediate petrochemical products=== | |||
The effect of feedstock selection upon the yields of steam cracking products is summarized in the table below: | |||
{| | |||
| | |||
{| class = "wikitable" align="left" | |||
|+ Steam cracking feedstocks versus yields of intermediate petrochemical products<ref name=HP/> | |||
! ||colspan="5"|Product Yields | |||
|- | |||
! Feedstock<br/>source||Ethylene<br/>weight %||Propylene<br/>weight %||Butadiene<br/>weight %||[[Aromatics]]<sup> (a)</sup><br/>weight%||Other<sup> (b)</sup><br/>weight % | |||
|- align="center" | |||
| Ethane||84.0 ||1.4||1.4||0.4||12.8 | |||
|- align="center" | |||
| Propane||45.0||14.0||2.0||3.5||35.5 | |||
|- align="center" | |||
| Butane||44.0||17.3||3.0||3.4||32.3 | |||
|- align="center" | |||
| Naphtha<sup> (c)</sup>||34.4||14.4||4.9||14.0||32.3 | |||
|- align="center" | |||
| Gas oil<sup> (d)</sup>||25.5 ||13.5||4.9||12.8||43.3 | |||
|- | |||
|colspan="6"|(a) Includes benzene, toluene, xylenes and any other aromatics.<br/> | |||
(b) Includes [[hydrogen]], methane, butenes, non-aromatic portion of [[pyrolysis gasoline]] and [[fuel oil]]. <br/> | |||
(c) Full-range naphtha (as differentiated from [[Petroleum naphtha|light or heavy naphtha]]).<br/> | |||
(d) The portion of [[petroleum|petroleum crude oil]] that has a boiling range of about 250 to 550 °C (480 to 1020 °F).<br/> That encompasses the boiling range of atmospheric gas oil (AGO) produced by the [[Petroleum_refining_processes/Draft#The crude oil distillation unit|atmospheric distillation]]<br/> of petroleum crude oil and the boiling range of vacuum gas oil (VGO) produced by the [[vacuum distillation]]<br/> of petroleum crude oil. | |||
|} | |||
|} | |||
==Feedstocks and example petrochemical products== | ==Feedstocks and example petrochemical products== | ||
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|-align="center" | |-align="center" | ||
|[[formaldehyde]]||[[glycol ether]]s||[[epoxy resin]]s||[[tert-butanol|''tert''-butanol]]||[[nylon]]s|| | |[[formaldehyde]]||[[glycol ether]]s||[[epoxy resin]]s||[[tert-butanol|''tert''-butanol]]||[[nylon]]s|| | ||
|} | |||
The chemicals that can be produced from each of the major petrochemical feedstocks can be depicted as "network diagrams". For example, these are the network diagrams for the chemicals that may be derived from ethylene and from propylene as the petrochemical feedstocks: | |||
{|border="0" cellpadding="0" cellspacing= "0" align="left" | |||
|- | |||
|valign="bottom" |{{Image|Petrochem1.png|right|473px|Petrochemicals that may be produced from ethylene.}} | |||
|valign="bottom" |{{Image|Petrochem3.png|right|435px|Petrochemicals that may be produced from propylene.}} | |||
|} | |||
As another example, this is the network diagram for the chemicals that may be derived from benzene as the petrochemical feedstock: | |||
{|border="0" cellpadding="0" cellspacing= "0" align="center" | |||
|- | |||
|valign="bottom" |{{Image|Petrochem2.png|right|587px|Petrochemicals that may be produced from benzene.}} | |||
|} | |||
As more examples, these are the network diagrams for the chemicals that may be derived from toluene and from xylenes as the petrochemical feedstocks: | |||
{|border="0" cellpadding="0" cellspacing= "0" align="center" | |||
|- | |||
|valign="center" |{{Image|Petrochem4.png|right|353px|Petrochemicals that may be produced from toluene.}} | |||
|valign="bottom" |{{Image|Petrochem5.png|right|400px|Petrochemicals that may be produced from xylenes.}} | |||
|} | |} | ||
==References== | ==References== | ||
{{reflist}} | {{reflist}}[[Category:Suggestion Bot Tag]] |
Latest revision as of 06:01, 3 October 2024
Petrochemicals are chemical products made from the hydrocarbons present in raw natural gas and petroleum crude oil. The largest petrochemical manufacturing industries are to be found in the United States of America, Western Europe, Asia and the Middle East.
A relatively small number of hydrocarbon feedstocks form the basis of the petrochemical industries, namely methane, ethylene, propylene, butanes, butadiene, benzene, toluene and xylenes.[1][2]
As of 2007, there were 2,980 operating petrochemical plants in 4,320 locations worldwide.[3] The petrochemical end products from those plants include plastics, soaps, detergents, solvents, paints, drugs, fertilizer, pesticides, explosives, synthetic textile fibers and rubbers, flooring and insulating materials and much more.
Petrochemicals are found in such common consumer products as aspirin, cars, clothing, compact discs, video tapes, electronic equipment, furniture, and a great many others.[4]
Feedstocks sources
The adjacent diagram schematically depicts the major hydrocarbon sources used in producing petrochemicals are:[1][2][5][6]
- Methane, ethane, propane and butanes: Obtained primarily from natural gas processing plants.
- Naphtha obtained from petroleum refineries.
- Benzene, toluene and xylenes, as a whole referred to as BTX and primarily obtained from petroleum refineries by extraction from the reformate produced in catalytic reformers.
- Gas oil obtained from petroleum refineries.
Methane and BTX are used directly as feedstocks for producing petrochemicals. However, the ethane, propane, butanes, naphtha and gas oil serve as optional feedstocks for steam-assisted thermal cracking plants referred to as steam crackers that produce these intermediate petrochemical feedstocks:
- Ethylene
- Propylene
- Butenes and butadiene
- Benzene
In 2007, the amounts of ethylene and propylene produced in steam crackers were about 115 Mt (megatonnes) and 70 Mt, respectively.[7] The output ethylene capacity of large steam crackers ranged up to as much as 1.0 – 1.5 Mt per year.[8][9]
Steam crackers are not to be confused with steam reforming plants used to produce hydrogen and ammonia.
Worldwide usage of optional steam cracking feedstock sources
As of 2004, the percentage of the worldwide steam cracking plants using each of the optional steam cracking feed sources was:[10]
- Ethane: 35%
- Propane: 9%
- Butanes: 3%
- Naphtha: 45%
- Gas oil: 5%
- Other: 3 %
The effect of feedstock on the steam cracking yields of intermediate petrochemical products
The effect of feedstock selection upon the yields of steam cracking products is summarized in the table below:
|
Feedstocks and example petrochemical products
The table below includes some representative examples of the petrochemical end products produced from the eight hydrocarbon feedstocks – methane, ethylene, propylene, butenes, butadiene, benzene, toluene and xylenes:
methane | ethylene | propylene | butenes and butadienes | benzene | toluene | xylenes |
---|---|---|---|---|---|---|
hydrogen | polyethylene | polypropylene | styrene-butadiene rubber (SBR) | styrene | benzoic acid | phthalic anhydride |
ammonia | ethanol | isopropanol | methyl tert-butyl ether (MTBE) | polystyrene | toluene diisocyanate | polyesters |
methanol | ethylene glycol | propylene glycol | polybutadiene | phenol | polyurethanes | dimethyl terephthalate |
methyl chloride | vinyl acetate | allyl chloride | acrylonitrile-butadiene-styrene (ABS) | cumene | caprolactam | terephthalate acid |
carbon black | perchloroethylene | acrylonitrile | polybutenes | aniline | nylons | polyethylene terephthalate |
acetylene | polyvinyl acetate | acrylic acid | methyl ethyl ketone (MEK) | adipic acid | polyureas | dioctyl phthalate |
formaldehyde | glycol ethers | epoxy resins | tert-butanol | nylons |
The chemicals that can be produced from each of the major petrochemical feedstocks can be depicted as "network diagrams". For example, these are the network diagrams for the chemicals that may be derived from ethylene and from propylene as the petrochemical feedstocks:
As another example, this is the network diagram for the chemicals that may be derived from benzene as the petrochemical feedstock:
As more examples, these are the network diagrams for the chemicals that may be derived from toluene and from xylenes as the petrochemical feedstocks:
References
- ↑ 1.0 1.1 Sami Matar and Lewis F. Hatch (2001). Chemistry of Petrochemical Processes. Gulf Professional Publishing. ISBN 0-0-88415-315-0.
- ↑ 2.0 2.1 2.2 Staff (March 2001). "Petrochemical Processes 2001". Hydrocarbon Processing: pp. 71-246. ISSN 0887-0284.
- ↑ Petrochemical Industry – Worldwide
- ↑ Petrochemicals Chart From the website of the National Petrochemical & Refiners Association
- ↑ SBS Polymer Supply Outlook
- ↑ Jean-Pierre Favennec (Editor) (2001). Petroleum Refining: Refinery Operation and Management. Editions Technip. ISBN 2-7108-0801-3.
- ↑ Hassan E. Alfadala, G.V. Rex Reklaitis and Mahmoud M. El-Halwagi (Editors) (2009). Proceedings of the 1st Annual Gas Processing Symposium, Volume 1: January, 2009 - Qatar, 1st Edition. Elsevier Science, pp. 402-414. ISBN 0-444-53292-7.
- ↑ Crackers capacities From the website of the Association of Petrochemicals Producers in Europe (APPE)
- ↑ Steam Cracking: Ethylene Production (PDF page 3 of 12 pages)
- ↑ Richard Meyers (2003). The Basics of Chemistry. Greenwood Press. ISBN 0-313-31664-3.