Fushun process

Fushun process
Process type	Chemical
Industrial sector(s)	Chemical industry ; oil industry
Feedstock	oil shale
Product(s)	shale oil
Leading companies	Fushun Mining Group
Main facilities	Fushun Shale Oil Plant

Last updated March 03, 2023

The Fushun process is an above-ground retorting technology for shale oil extraction. It is named after the main production site of Fushun, Liaoning province in northeastern China.

History

The Fushun process was developed and utilized for the extraction of shale oil in China during the mid-1920s.^[1] The commercial-scale utilization of the process began in 1930 with the construction of "Refinery No. 1".^[2]^[3] After World War II, the shale oil production was ceased, but 100 Fushun-type oil shale retorts were restored in 1949.^[4] In 1950, total 266 retorts were in operation, each with the capacity of 100–200 tons of shale oil per day.^[2]

With the discovery of Daqing oil field in the 1960s, the shale oil production declined and Sinopec, an operator of shale oil production these times, shut down its oil shale operations in the beginning of the 1990s.^[4] At the same time, the Fushun Oil Shale Retorting Plant, using Fushun process technology, was established as a part of the Fushun Mining Group. It started production in 1992.^[3] In 2005, China became the largest shale oil producer in the world.^[2]

In 1985–86, Sinopec used the Fushun process for a test processing of Jordan's oil shale from the El Lajjun deposit. Although the process was technically viable, the cooperation was halted due to high operation costs.^[5]^[6]

Technology

The Fushun process is classified as an internal combustion technology but also includes external gas heating.^[7] It uses a vertical cylindrical type shaft retort, with outside steel plate lined with inner fire bricks. The retort has height over 10 metres (33 ft) and its inner diameter is about 3 metres (9.8 ft). Raw oil shale particles with the size of 10 to 75 millimetres (0.4 to 3.0 in) are fed from the top of the retort. At the upper section of the retort oil shale is dried and heated by the ascending hot gases, which pass upward through the descending oil shale causing decomposition of the rock. The pyrolysis takes place at about 500 °C (930 °F).^[1] The produced oil vapor and gases exit from the top of the retort; hot gases and oil vapors move from the bottom to the top directly, and not diagonally like in Kiviter process.^[8] During the pyrolysis process, oil shale is decomposed to shale coke (char), which together with the ascending air-steam is burnt in the lower part of the retort to heat gases necessary for pyrolysis. These gases are recirculated; after leaving retort, they are cooled in a condensation system, where shale oil is condensed, and re-heated in a heating furnace about 500 °C (930 °F) to 700 °C (1,290 °F) before reinserting into the retort. The shale ash exits from a rotating water dish that acts as a seal and cooler at the bottom of the retort.^[1]

Retorts are operated in sets and have a heat carrier preparation unit and rotating water seals designed for the whole set instead of a single retort as in case of the Kiviter retort. Regenerative furnaces are located next to the retorts and they are operating in two cycles – the combustion cycle and the gas heating cycle. During the combustion cycle, a furnace is heated up to 1,000 °C (1,830 °F) by combustion gases. After the combustion cycle, retort gases from the condensation system is inserted into a furnace for their heating.^[8] By alternating furnaces, one furnace is always available for heating retort gas. Twenty retorts typically share one condensation system and a set of heating furnaces.^[1]

Advantages of the Fushun process include small investment and stable operation.^[9] The process is characterized by the high thermal efficiency, but due to the addition of air into the retort, the nitrogen dilutes the pyrolysis gas. In addition, the excess oxygen in retort burns out a part of produced shale oil, which reduce the shale oil yield. The oil yield of the Fushun retort accounts for about 65% of Fischer Assay.^[1] Disadvantage of this process is a high water consumption amounting to 6–7 barrels of water per barrel of produced shale-oil, and great quantities of waste shale. It is not suitable of ores with small size and oil content lower than 5%.^[9]

As the capacity of single retort is limited, Fushun process is suitable for small-scale retorting plants, and for processing lean oil shale with low gas yield.^[1]

Commercial use

Fushun process is used only in China. The Fushun Mining Group operates the largest by capacity shale oil plant in the world (Fushun Shale Oil Plant) consisting of 180 Fushun retorts.^[6]^[8] Each retort processes about 4 tonnes of oil shale per hour.^[6]^[8]

Related Research Articles

<span class="mw-page-title-main">Oil shale</span> Organic-rich fine-grained sedimentary rock containing kerogen

Oil shale is an organic-rich fine-grained sedimentary rock containing kerogen from which liquid hydrocarbons can be produced. In addition to kerogen, general composition of oil shales constitutes inorganic substance and bitumens. Based on their deposition environment, oil shales are classified as marine, lacustrine and terrestrial oil shales. Oil shales differ from oil-bearing shales, shale deposits that contain petroleum that is sometimes produced from drilled wells. Examples of oil-bearing shales are the Bakken Formation, Pierre Shale, Niobrara Formation, and Eagle Ford Formation. Accordingly, shale oil produced from oil shale should not be confused with tight oil, which is also frequently called shale oil.

Shale oil is an unconventional oil produced from oil shale rock fragments by pyrolysis, hydrogenation, or thermal dissolution. These processes convert the organic matter within the rock (kerogen) into synthetic oil and gas. The resulting oil can be used immediately as a fuel or upgraded to meet refinery feedstock specifications by adding hydrogen and removing impurities such as sulfur and nitrogen. The refined products can be used for the same purposes as those derived from crude oil.

Petrosix is the world's largest surface oil shale pyrolysis retort with an 11 metres (36 ft) diameter vertical shaft kiln, operational since 1992. It is located in São Mateus do Sul, Brazil, and it is owned and operated by the Brazil energy company Petrobras. Petrosix means also the Petrosix process, an externally generated hot gas technology of shale oil extraction. The technology is tailored to Irati oil shale formation, a Permian formation of the Paraná Basin.

The oil shale industry is an industry of mining and processing of oil shale—a fine-grained sedimentary rock, containing significant amounts of kerogen, from which liquid hydrocarbons can be manufactured. The industry has developed in Brazil, China, Estonia and to some extent in Germany and Russia. Several other countries are currently conducting research on their oil shale reserves and production methods to improve efficiency and recovery. Estonia accounted for about 70% of the world's oil shale production in a study published in 2005.

Shale oil extraction is an industrial process for unconventional oil production. This process converts kerogen in oil shale into shale oil by pyrolysis, hydrogenation, or thermal dissolution. The resultant shale oil is used as fuel oil or upgraded to meet refinery feedstock specifications by adding hydrogen and removing sulfur and nitrogen impurities.

The history of the oil shale industry started in ancient times. The modern industrial use of oil shale for oil extraction dates to the mid-19th century and started growing just before World War I because of the mass production of automobiles and trucks and the supposed shortage of gasoline for transportation needs. Between the World Wars oil shale projects were begun in several countries.

Oil shale gas is a synthetic non-condensable gas mixture (syngas) produced by oil shale thermal processing (pyrolysis). Although often referred to as shale gas, it differs from the natural gas produced from shale, which is also known as shale gas.

Oil shale in China is an important source of unconventional oil. A total Chinese oil shale resource amounts of 720 billion tonnes, located in 80 deposits of 47 oil shale basins. This is equal to 48 billion tonnes of shale oil. At the same time there are speculations that the actual resource may even exceed the oil shale resource of the United States.

The Kiviter process is an above ground retorting technology for shale oil extraction.

The Galoter process is a shale oil extraction technology for a production of shale oil, a type of synthetic crude oil. In this process, the oil shale is decomposed into shale oil, oil shale gas, and spent residue. A decomposition is caused by mixing raw oil shale with a hot oil shale ash, generated by combustion of carbonaceous residue (semi-coke) in the spent residue. The process was developed in 1950s and it is used commercially for the shale oil production in Estonia. There are projects for further development of this technology and for expansion of its usage, e.g. in Jordan and USA.

The Alberta Taciuk process is an above-ground dry thermal retorting technology for extracting oil from oil sands, oil shale and other organics-bearing materials, including oil contaminated soils, sludges and wastes. The technology is named after its inventor William Taciuk and the Alberta Oil Sands Technology and Research Authority.

The Paraho process is an above ground retorting technology for shale oil extraction. The name "Paraho" is delivered from the words "para homem", which means in Portuguese "for mankind".

The Lurgi–Ruhrgas process is an above-ground coal liquefaction and shale oil extraction technology. It is classified as a hot recycled solids technology.

The gas combustion retort process was an above-ground retorting technology for shale oil extraction. It was a predecessor of the Paraho and Petrosix processes, and modern directly heated oil shale retorting technologies in general.

The Nevada–Texas–Utah retort process was an above-ground shale oil extraction technology to produce shale oil, a type of synthetic crude oil. It heated oil shale in a sealed vessel (retort) causing its decomposition into shale oil, oil shale gas and spent residue. The process was developed in the 1920s and used for shale oil production in the United States and in Australia. The process was simple to operate; however, it was ceased from the operation because of a small capacity and labor extensiveness.

The Superior multimineral process is an above ground shale oil extraction technology designed for production of shale oil, a type of synthetic crude oil. The process heats oil shale in a sealed horizontal segmented vessel (retort) causing its decomposition into shale oil, oil shale gas and spent residue. The particularities of this process is a recovery of saline minerals from the oil shale, and a doughnut-shape of the retort. The process is suitable for processing of mineral-rich oil shales, such as in the Piceance Basin. It has a relatively high reliability and high oil yield. The technology was developed by the American oil company Superior Oil.

The Union process was an above ground shale oil extraction technology for production of shale oil, a type of synthetic crude oil. The process used a vertical retort where heating causes decomposition of oil shale into shale oil, oil shale gas and spent residue. The particularity of this process is that oil shale in the retort moves from the bottom upward to the top, countercurrent to the descending hot gases, by a mechanism known as a rock pump. The process technology was invented by the American oil company Unocal Corporation in late 1940s and was developed through several decades. The largest oil shale retort ever built was the Union B type retort.

The Chevron STB process is an above-ground shale oil extraction technology. It is classified as a hot recycled solids technology.

LLNL HRS process is an above-ground shale oil extraction technology. It is classified as a hot recycled solids technology.

KENTORT II is an above-ground shale oil extraction process developed by the Center for Applied Energy Research of the University of Kentucky. It is a hot recycled solids fluidized bed retorting process developed since 1982 for processing the eastern United States Devonian oil shales. The concept of this process was initiated in 1986 in the test unit.

References

1 2 3 4 5 6 Qian, Jialin; Wang, Jianqiu (2006-11-07). World oil shale retorting technologies (PDF). Amman, Jordan: International Oil Shale Conference. Archived from the original (PDF) on 2008-05-27. Retrieved 2009-02-14.
1 2 3 "Shale oil: Perspective with China focus" (PDF). Intelligence Dynamics. 2007-03-07. Archived from the original (PDF) on July 7, 2011. Retrieved 2009-02-14.
1 2 Dyni, John R. (2006). "Geology and resources of some world oil-shale deposits. Scientific Investigations Report 2005–5294" (PDF). U.S. Department of the Interior. U.S. Geological Survey. Retrieved 2009-02-14.
1 2 Qian, Jialin; Wang, Jianqiu; Li, Shuyuan (2006). Oil Shale Activity in China (PDF). 26th Oil Shale Symposium. Colorado School of Mines. Archived from the original (PDF) on 2011-07-25. Retrieved 2009-02-14.
↑ Alali, Jamal; Abu Salah, Abdelfattah; Yasin, Suha M.; Al Omari, Wasfi (2006). "Oil Shale in Jordan" (PDF). Natural Resources Authority of Jordan. Retrieved 2009-02-17.^{[ permanent dead link ]}
1 2 3 Yin, Liang (2006-11-07). "Current status of oil shale industry in Fushun, China" (PDF). Amman, Jordan: International Oil Shale Conference. Archived from the original (PDF) on 2007-09-28. Retrieved 2009-02-14.
↑ Burnham, Alan K.; McConaghy, James R. (2006-10-16). "Comparison of the acceptability of various oil shale processes" (PDF). Golden: 26th Oil shale symposium. UCRL-CONF-226717. Archived from the original (PDF) on 2016-02-13. Retrieved 2009-01-04.
1 2 3 4 Purga, Jaanus (2004). "Today's rainbow ends in Fushun" (PDF). Oil Shale. A Scientific-Technical Journal. Estonian Academy Publishers. 21 (4): 269–272. ISSN 0208-189X . Retrieved 2009-02-14.
1 2 "Present development status of oil shale". China Chemical Reporter. 2008-11-26. Retrieved 2009-02-17.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[qian-1] 1 2 3 4 5 6 Qian, Jialin; Wang, Jianqiu (2006-11-07). World oil shale retorting technologies (PDF). Amman, Jordan: International Oil Shale Conference. Archived from the original (PDF) on 2008-05-27. Retrieved 2009-02-14.

[id-2] 1 2 3 "Shale oil: Perspective with China focus" (PDF). Intelligence Dynamics. 2007-03-07. Archived from the original (PDF) on July 7, 2011. Retrieved 2009-02-14.

[dyni-3] 1 2 Dyni, John R. (2006). "Geology and resources of some world oil-shale deposits. Scientific Investigations Report 2005–5294" (PDF). U.S. Department of the Interior. U.S. Geological Survey. Retrieved 2009-02-14.

[qian2-4] 1 2 Qian, Jialin; Wang, Jianqiu; Li, Shuyuan (2006). Oil Shale Activity in China (PDF). 26th Oil Shale Symposium. Colorado School of Mines. Archived from the original (PDF) on 2011-07-25. Retrieved 2009-02-14.

[jordan2-5] Alali, Jamal; Abu Salah, Abdelfattah; Yasin, Suha M.; Al Omari, Wasfi (2006). "Oil Shale in Jordan" (PDF). Natural Resources Authority of Jordan. Retrieved 2009-02-17.^{[ permanent dead link ]}

[fushun2-6] 1 2 3 Yin, Liang (2006-11-07). "Current status of oil shale industry in Fushun, China" (PDF). Amman, Jordan: International Oil Shale Conference. Archived from the original (PDF) on 2007-09-28. Retrieved 2009-02-14.

[AICHE-7] Burnham, Alan K.; McConaghy, James R. (2006-10-16). "Comparison of the acceptability of various oil shale processes" (PDF). Golden: 26th Oil shale symposium. UCRL-CONF-226717. Archived from the original (PDF) on 2016-02-13. Retrieved 2009-01-04.

[fushun-8] 1 2 3 4 Purga, Jaanus (2004). "Today's rainbow ends in Fushun" (PDF). Oil Shale. A Scientific-Technical Journal. Estonian Academy Publishers. 21 (4): 269–272. ISSN 0208-189X . Retrieved 2009-02-14.

[chemical-9] 1 2 "Present development status of oil shale". China Chemical Reporter. 2008-11-26. Retrieved 2009-02-17.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]