“Propene”的意思、由来-开放百科全书

Propene is a byproduct of oil refining and natural gas processing. During oil refining, ethylene, propene, and other compounds are produced as a result of cracking larger hydrocarbons. A major source of propene is naphtha cracking intended to produce ethylene, but it also results from refinery cracking producing other products.^[3] Propene can be separated by fractional distillation from hydrocarbon mixtures obtained from cracking and other refining processes; refinery-grade propene is about 50 to 70%.^[3]

A shift to lighter steam cracker feedstocks with relatively lower propene yields and reduced motor gasoline demand in certain areas has reduced propene supply.

Olefin conversion technology

In the Phillips Triolefin and the Olefin conversion technology interconverts propylene is interconverted with ethylene and 2-butenes. Rhenium and molybdenum catalysts are used:^[4]

The technology is founded on an olefin metathesis reaction discovered at Phillips Petroleum Company.^[5]^[6] Propene yields of about 90 wt% are achieved.

Related is the Methanol-to-Olefins/Methanol-to-Propene converts synthesis gas (syngas) to methanol, and then converts the methanol to ethylene and/or propene. The process produces water as by-product. Synthesis gas is produced from the reformation of natural gas or by the steam-induced reformation of petroleum products such as naphtha, or by gasification of coal.

Dehydrogenation

Fluid catalytic cracking

High severity fluid catalytic cracking (FCC) uses traditional FCC technology under severe conditions (higher catalyst-to-oil ratios, higher steam injection rates, higher temperatures, etc.) in order to maximize the amount of propene and other light products. A high severity FCC unit is usually fed with gas oils (paraffins) and residues, and produces about 20–25 m% propene on feedstock together with greater volumes of motor gasoline and distillate byproducts.

Market and research

Several companies have explored biomanufacturing using engineered enzymes.^[10] The starting materials for the fermentation could be either sugars or petrochemicals.

Propene production has remained static at around 35 million tonnes (Europe and North America only) from 2000 to 2008, but it has been increasing in East Asia, most notably Singapore and China.^[11] Total world production of propene is currently about half that of ethylene.

Uses

Propene is the second most important starting product in the petrochemical industry after ethylene. It is the raw material for a wide variety of products. Manufacturers of the plastic polypropylene account for nearly two thirds of all demand.^[13] Polypropylene end uses include films, fibers, containers, packaging, and caps and closures. Propene is also used for the production of important chemicals such as propylene oxide, acrylonitrile, cumene, butyraldehyde, and acrylic acid. In the year 2013 about 85 million tonnes of propene were processed worldwide.^[12]

Propene is also used to produce isopropanol (propan-2-ol), acrylonitrile, propylene oxide, and epichlorohydrin.^[13]

The industrial production of acrylic acid involves the catalytic partial oxidation of propene.^[14] Propene is also an intermediate in the one-step propane selective oxidation to acrylic acid.^[15]^[16]^[17]^[18]

In industry and workshops, propene is used as an alternative fuel to acetylene in Oxy-fuel welding and cutting, brazing and heating of metal for the purpose of bending. It has become a standard in BernzOmatic products and others in MAPP substitutes,^[19] now that true MAPP gas is no longer available.

Reactions

Propene resembles other alkenes in that it undergoes addition reactions relatively easily at room temperature. The relative weakness of its double bond explains its tendency to react with substances that can achieve this transformation. Alkene reactions include: 1) polymerization, 2) oxidation, 3) halogenation and hydrohalogenation, 4) alkylation, 5) hydration, 6) oligomerization, and 7) hydroformylation.

Combustion

Propene undergoes combustion reactions in a similar fashion to other alkenes. In the presence of sufficient or excess oxygen, propene burns to form water and carbon dioxide.

When insufficient oxygen is present for complete combustion, incomplete combustion occurs allowing carbon monoxide and/or soot (carbon) to be formed as well.

Environmental safety

Propene is a product of combustion from forest fires, cigarette smoke, and motor vehicle and aircraft exhaust. It is an impurity in some heating gases. Observed concentrations have been in the range of 0.1-4.8 parts per billion (ppb) in rural air, 4-10.5 ppb in urban air, and 7-260 ppb in industrial air samples.^[3]

In the United States and some European countries a threshold limit value of 500 parts per million (ppm) was established for occupational (8-hour time-weighted average) exposure. It is considered a volatile organic compound (VOC) and emissions are regulated by many governments, but it is not listed by the U.S. Environmental Protection Agency (EPA) as a hazardous air pollutant under the Clean Air Act. With a relatively short half-life, it is not expected to bioaccumulate.^[3]

Propene has low acute toxicity from inhalation. Inhalation of the gas can cause anesthetic effects and at very high concentrations, unconsciousness. However, the asphyxiation limit for humans is about 10 times higher (23%) than the lower flammability level.^[3]

Storage and handling

Since propene is volatile and flammable, precautions must be taken to avoid fire hazards in the handling of the gas. If propene is loaded to any equipment capable of causing ignition, such equipment should be shut down while loading, unloading, connecting or disconnecting.

Propene is usually stored as liquid under pressure, although it is also possible to store it safely as gas at ambient temperature in approved containers.^[20]

Pharmacology

Propene acts as a central nervous system depressant via allosteric agonism of the GABA_A receptor. Excessive exposure may result in sedation and amnesia, progressing to coma and death in a mechanism equivalent to benzodiazepine overdose. Intentional inhalation may also result in death via asphyxiation (sudden inhalant death).

Occurrence in nature

On September 30, 2013, NASA announced that the Cassini orbiter spacecraft, part of the Cassini-Huygens mission, had discovered small amounts of naturally occurring propene in the atmosphere of Titan using spectroscopy.^[21]^[22]

See also

References

1. ^{{cite book | title = Nomenclature of Organic Chemistry : IUPAC Recommendations and Preferred Names 2013 (Blue Book) | publisher = The Royal Society of Chemistry | date = 2014 | location = Cambridge | page = 31 | doi = 10.1039/9781849733069-FP001 | isbn = 978-0-85404-182-4| chapter = Front Matter }}
2. ^https://pubchem.ncbi.nlm.nih.gov/compound/Propene#section=Top
3. ^¹²³⁴{{cite web |url=http://www.dow.com/productsafety/finder/pro.htm |title=Product Safety Assessment(PSA): Propylene |publisher= Dow Chemical Co.}}
4. ^{{cite journal|last1=Ghashghaee|first1=Mohammad|title=Heterogeneous catalysts for gas-phase conversion of ethylene to higher olefins|journal=Rev. Chem. Eng.|volume=34|issue=5|pages=595–655|doi=10.1515/revce-2017-0003|year=2018}}
5. ^{{cite journal | last1 = Banks | first1 = R. L. | last2 = Bailey | first2 = G. C. | title = Olefin Disproportionation. A New Catalytic Process | journal = Industrial & Engineering Chemistry Product Research and Development | volume = 3 |issue=3| pages = 170–173 | year = 1964 | doi = 10.1021/i360011a002}}
6. ^{{cite encyclopedia|chapter=Metathesis|encyclopedia=Kirk-Othmer Encyclopedia of Chemical Technology|authors=Lionel Delaude, Alfred F. Noels|year=2005| doi=10.1002/0471238961.metanoel.a01|place=Weinheim|publisher=Wiley-VCH|isbn=978-0471238966}}
7. ^Ashford’s Dictionary of Industrial Chemicals, Third edition, 2011, {{ISBN|978-0-9522674-3-0}}, pages 7766-9
8. ^{{cite web|author=Giovanni Maggini |url=http://www.slideshare.net/intratec/propylene-production-via-propane-dehydrogenation |title=Technology Economics: Propylene via Propane Dehydrogenation |publisher=Slideshare.net |date=2012-06-28 |accessdate=2013-11-12}}
9. ^{{cite web|author=Giovanni Maggini |url=http://www.slideshare.net/intratec/technology-economics-propylene-via-propane-dehydrogenation-part-3 |title=Technology Economics: Propylene via Propane Dehydrogenation, Part 3 |publisher=Slideshare.net |date=2013-04-17 |accessdate=2013-11-12}}
10. ^{{cite web |url= https://greenchemicalsblog.com/2012/10/12/global-bioenergies-in-bio-propylene |website= Green Chemicals Blog |title= Global Bioenergies in bio-propylene |first= Doris |last= de Guzman |date= October 12, 2012 }}
11. ^Organic Chemistry 6th edition, McMurry,J., Brooks/Cole Publishing, Pacific Grove USA (2005)
12. ^¹{{cite web|url=http://www.ceresana.com/en/market-studies/chemicals/propylene/|title=Market Study: Propylene (2nd edition), Ceresana, December 2014|publisher=ceresana.com|accessdate=2015-02-03}}
13. ^{{Cite book| contribution = 8034. Propylene | year = 1996 | title = The Merck Index, Twelfth Edition | editor-last = Budavari | editor-first = Susan | volume = | pages = 1348–1349 | place = New Jersey | publisher = Merck & Co. | id =| postscript = {{inconsistent citations}} }}
14. ^{{cite book|last1=J.G.L.|first1=Fierro (Ed.)|title=Metal Oxides, Chemistry and Applications|date=2006|publisher=CRC Press|pages=414–455}}
15. ^{{cite journal|title=The reaction network in propane oxidation over phase-pure MoVTeNb M1 oxide catalysts|journal=Journal of Catalysis|date=March 2014|volume=311|pages=369–385|doi=10.1016/j.jcat.2013.12.008|hdl=11858/00-001M-0000-0014-F434-5|last1=Naumann d'Alnoncourt|first1=Raoul|last2=Csepei|first2=Lénárd-István|last3=Hävecker|first3=Michael|last4=Girgsdies|first4=Frank|last5=Schuster|first5=Manfred E.|last6=Schlögl|first6=Robert|last7=Trunschke|first7=Annette}}
16. ^{{cite journal|title=Multifunctionality of Crystalline MoV(TeNb) M1 Oxide Catalysts in Selective Oxidation of Propane and Benzyl Alcohol|journal=ACS Catalysis|date=7 June 2013|volume=3|issue=6|pages=1103–1113|doi=10.1021/cs400010q|hdl=11858/00-001M-0000-000E-FA39-1|last1=Amakawa|first1=Kazuhiko|last2=Kolen'Ko|first2=Yury V.|last3=Villa|first3=Alberto|last4=Schuster|first4=Manfred E/|last5=Csepei|first5=Lénárd-István|last6=Weinberg|first6=Gisela|last7=Wrabetz|first7=Sabine|last8=Naumann d'Alnoncourt|first8=Raoul|last9=Girgsdies|first9=Frank|last10=Prati|first10=Laura|last11=Schlögl|first11=Robert|last12=Trunschke|first12=Annette}}
17. ^{{cite journal|title=Surface chemistry of phase-pure M1 MoVTeNb oxide during operation in selective oxidation of propane to acrylic acid|journal=Journal of Catalysis|date=January 2012|volume=285|issue=1|pages=48–60|doi=10.1016/j.jcat.2011.09.012|hdl=11858/00-001M-0000-0012-1BEB-F|last1=Hävecker|first1=Michael|last2=Wrabetz|first2=Sabine|last3=Kröhnert|first3=Jutta|last4=Csepei|first4=Lenard-Istvan|last5=Naumann d'Alnoncourt|first5=Raoul|last6=Kolen'Ko|first6=Yury V.|last7=Girgsdies|first7=Frank|last8=Schlögl|first8=Robert|last9=Trunschke|first9=Annette}}
18. ^{{cite book|title=Kinetic studies of propane oxidation on Mo and V based mixed oxide catalysts|pages=3–24, 93|doi=10.14279/depositonce-2972|year=2011|last1=Csepei|first1=Lénárd-István}}
19. ^For example, "MAPP-Pro"
20. ^Encyclopedia of Chemical Technology, Fourth edition, 1996, {{ISBN|0471-52689-4}} (v.20), page 261
21. ^{{cite web|url=http://www.upi.com/Science_News/2013/09/30/Cassini-finds-ingredient-of-household-plastic-on-Saturn-moon/UPI-42881380571911/ |title=Spacecraft finds propylene on Saturn moon, Titan |publisher=UPI.com |date=2013-09-30 |accessdate=2013-11-12}}
22. ^{{cite web|url=http://www.spacedaily.com/reports/Cassini_finds_ingredient_of_household_plastic_on_Saturn_moon_999.html |title=Cassini finds ingredient of household plastic on Saturn moon |publisher=Spacedaily.com |date= |accessdate=2013-11-12}}

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