Underground Combustion in the Shannon Pool, Wyoming

Parrish, David J.; Rausch, R.W.; Beaver, K.W.; Wood, H.W.

doi:10.2118/141-pa

Cited by 6 publications

(3 citation statements)

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“…The amount of fuel available for in situ combustion can be maximized for a given system by the proper L TO treatment prior to high-temperature combustion. 10. For a given crude oil, the apparent H/C ratio of the fuel burned decreased as combustion temperature increased.…”

Section: Effect Of Air Flux On Fuel Availabilitymentioning

confidence: 93%

Factors Affecting Fuel Availability and Composition During In Situ Combustion

Alexander

Martin

Dew

1962

Journal of Petroleum Technology

149

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1 his paper presents data obtained using a flood-pot technique to determine the fuel available and the corresponding theoretical air requirements for in situ combustion of crude oils. Since the technique is relatively quick and easy, it is a practical and convenient tool for evaluating reservoirs as fireflood prospects. It is also a research tool which facilitates systematic study of the variables affecting fuel availability and corresponding air requirements. The understanding of these variables is of prime importance to those concerned with the technical and economic development of in situ combustion as an oilrecovery process.The experimental results show conclusively that the fuel available for in situ combustion is not a constant but, rather, varies with crude-oil characteristics, porous-medium type, oil saturation, air flux and time-temperature relationships. Thus, the fuel availability for specified field applications should be determined using actual reservoir crude and cofe material and the process conditions expected during in situ combustion in the reservoir.

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Section: Effect Of Air Flux On Fuel Availabilitymentioning

confidence: 93%

Factors Affecting Fuel Availability and Composition During In Situ Combustion

Alexander

Martin

Dew

1962

Journal of Petroleum Technology

149

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“…Table 3 shows the parameters of the design of the THAI ISC process. Several authors have provided procedures for designing the ISC process (Nelson and McNeil, 1961;Parrish et al, 1962;Gates and Ramey, 1980;Fassihi et al, 1981;Sarathi, 1998).…”

Section: Pilot Project For Isc From Toe-to-heel By Air Injection (Thai)mentioning

confidence: 99%

Toe-to-Heel Air Injection in-Situ Combustion Process: Case Study From the Azraq Basin, Jordan

Al-Mahasneh

2020

MGPB

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The exploration and drilling operations for oil in the Wadi Rajil region of the Azraq Basin in northeast Jordan confirmed the existence of quantities of asphalt and heavy oil in several formations of limestone and dolomite within layers of sandstone. The estimated area was 1200 km 2 (120000 hectare) and possibly contained 800 million m 3 (five billion barrels) of original oil. The aim of this study is to obtain in-situ combustion and to suggest the application of the drilling of two wells by an in-situ combustion process called Toe-to-Heel Air Injection In-situ Combustion in the Wadi Rajil-Hamzeh field. This approach proposes a pilot project of drilling two wells. One vertical injection well in the upper production zone and another horizontal production well at the bottom of the reservoir. Through this technique, the productivity will increase, the viscosity of the oil will decrease, and consequently the sweep efficiency will be higher. This pilot project's potential production reaches 212.94 m 3 /d of oil. The total time for the project to be completed is around 450 days. The efficiency of recovery in this study reached around 65 to 69%. This result can lead to the possible expansion of the approach applied in this project throughout the Wadi Rajil-Hamzeh region.

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“…44 High temperatures have been partly combatted by cirdatirig co!d water down the annulus and up the tubing, along with the produced crude oil.cz In the case of light oils, it is more economical to shut the .. . Treatments include hot oil washes,l',23,4' hot oil and surfactant squeezes, and LPG, kerosene, and diesel-oil washes of the wells, each of which has only a temporary effect.…”

Section: Vplmentioning

confidence: 99%

A Current Appraisal of In-Situ Combustion Field Tests

Ali

1972

Journal of Petroleum Technology

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According to these reports on more than two dozen tests, in-situ combustion, when property engineered, can recover 50 percent of oil in place. However, lest you be fired up, in the heat of statistics, to ignite your reservoir, bear in mind that man by nature is disinclined to expose his failures. Introduction In-situ combustion may be said to date back to 1888 when Mendeleev suggested the in-situ conversion of coal into combustible gases. In 1934, Sheinman and Dubrovai, on the basis of earlier laboratory studies, proposed the process of oil recovery by means of a proposed the process of oil recovery by means of a moving underground firefront. Following this, a number of field tests were carried out in Azerbaidjan and other regions from 1934 to 1937. An analysis of the tests showed that the heat losses were so large that injected hot gases reached the formation face with zero thermal energy. Nevertheless. the tests opened the way to more field tests, laboratory research, and theoretical studies, as a result of which in-situ combustion has come to be recognized as a promising method of recovering oil. At the present time there are nearly 300 papers, and close to a dozen books (in Russian) dealing partly or wholly with in-situ combustion. At least nine large-scale field in-situ combustion projects are currently in operation. Listings of field projects are currently in operation. Listings of field tests can be found in a number of publications (for example, Refs. 5, 6, 51, 54, 61, 64, 65). The main purpose of this paper is to present, compare, and contrast the performance of two dozen forward combustion tests that have been reported in detail out of 100 or so that have been cited in the literature. Reverse combustion and various modifications of the basic process will not be considered. Only brief mention will be made of wet combustion tests. Also, the paper is not intended to give criteria for designing a combustion project, nor does it purport to discuss equipment and operational aspects of firefloods, except for the special operational problems encountered in fireflooding. No reference will be made to a great many experimental and mathematical studies conducted principally in the U. S., U.S.S.R., and Holland; however, a few instances will be cited where the experimental and predicted results were compared with the test results. Principle Statistics of Selected Firefloods Principle Statistics of Selected Firefloods Tables 1A and 1B summarize the principal statistics of 24 forward combustion tests. These, and the two cited below. seem to be the only ones for which information is available on oil recovery or air-oil ratio (AOR), or both. In a few cases, certain performance data were estimated from the reported performance data were estimated from the reported data. Such values are indicated by a question mark. It is recognized that the highly complex in-situ combustion process, compounded by reservoir heterogeneities, cannot be expressed in terms of over-all parameters. However, in spite of its limitations the table should be of value in balancing out the most favorable conditions for a fireflood. Notice that the table does not give values of the producing gas-oil ratio (GOR) water-oil ratio (WOR), producing gas-oil ratio (GOR) water-oil ratio (WOR), ignition information, gas recovery, produced gas composition, sweep data, etc. These items are covered in separate sections. The test numbers used in the text refer to the corresponding tests in the tables. To complete the table, two tests should be added. The available information on them is rather meager, but the key data are available. JPT P. 477

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Underground Combustion in the Shannon Pool, Wyoming

Cited by 6 publications

References 0 publications

Factors Affecting Fuel Availability and Composition During In Situ Combustion

Factors Affecting Fuel Availability and Composition During In Situ Combustion

Toe-to-Heel Air Injection in-Situ Combustion Process: Case Study From the Azraq Basin, Jordan

A Current Appraisal of In-Situ Combustion Field Tests

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