Thermal stresses analysis of casing string used in enhanced geothermal systems wells

ZHANG Pei-feng

Volume 4 Issue 4

Dec. 2016

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ZHANG Pei-feng. 2016: Thermal stresses analysis of casing string used in enhanced geothermal systems wells. Journal of Groundwater Science and Engineering, 4(4): 293-300.

Citation:

ZHANG Pei-feng. 2016: Thermal stresses analysis of casing string used in enhanced geothermal systems wells. Journal of Groundwater Science and Engineering, 4(4): 293-300.

Citation:

ZHANG Pei-feng. 2016: Thermal stresses analysis of casing string used in enhanced geothermal systems wells. Journal of Groundwater Science and Engineering, 4(4): 293-300.

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Thermal stresses analysis of casing string used in enhanced geothermal systems wells

ZHANG Pei-feng

1Beijing Institute of Exploration Engineering, Beijing 100083, China.

Publish Date: 2016-12-28

Abstract

Abstract

In the enhanced geothermal systems wells, casing temperature variation produces casing thermal stresses, resulting in casing uplift or bucking. When the induced thermal stresses exceed casing material’s yield strength, the casing deforms and collapses. The traditional casing design standard only considers the influence of temperature variation on casing material’s yield strength. Actually, for commonly used grades of steel pipe, casing’s material properties-such as yield strength, coefficient of thermal expansion, and modulus of elasticity change with temperature variation. In this paper, the modified thermal stress equation is given. Examples show that the allowable temperature of the material grade N80’s casing is only 164 ℃, which is much lower than that of the traditional design standard. The effective method to improve the casing pipe’s allowable temperature is pre-stressed cementing technology. Pre-stressed cementing includes pre-tension stress cementing and pre-pressure stress cementing. This paper focuses on the design method of full casing pre-tension stress cementing and the ground anchor full casing string pre-tension cementing construction process.
- Casing thermal stress,
- EGS wells,
- Casing deformation and collapse,
- Pre-tension stress cementing,
- Well completion design,
- Pre-stressed cementing

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References(13)

References

ZHAI Ya-feng, ZHANG Xin-wen, et al. 2010. Cementing and completion technology of heavy oil thermal recovery well in Xinjiang oilfield. Xinjiang Oil & Gas, 6(3): 86-91 .

Levey S S. 2010. Subsurface geology of the fenton hill hot dry rock geothermal energy site. Los Alamos: Los Alamos National Laboratory .

Carden R S. 1983. Unique aspects of drilling and completing hot dry geothermal wells. New Orleans: IADC/SPE 1983 Drilling Conference, 123-140 .

YANG Xiu-juan, YANG Heng-lin, et al. 2004. Analysis of the prestress design of casing. Oil Field Equipment, 33(1): 1-5 .

LIU Kun-fang, ZHANG Zhao-yin, et al. 1994. Analyses of steam-injected well casing thermal stress and casing string strength design. Petroleum Drilling Techniques, 22(4): 36-40 .

Garnish J. 2002. European activities in Hot Dry Rock research. In: Open Meeting on Enhanced Geothermal Systems. Reno: U.S. Department of Energy, 8-9 .

LI Zi-feng, YANG Xin-jun, et al. 2008. Casing cementing with internal pre-pressurization for thermal recovery wells. Engineering Mechanics, 25(6): 219-224 .

MIT. 2006. The future of geothermal energy-Impact of Enhanced Geothermal Systems (EGS) on the United States in the 21st century. Massachusetts: MIT .

Teodoriu C, Falcone G. 2009. Comparing completion design in hydrocarbon and geothermal wells: The need to evaluate the integrity of casing connections subject to thermal stresses. Geothermics, 2009, 38(2): 238-246 .

Rybach L. 2010. Status and prospects of geothermal energy. Bali: Proceedings of World Geothermal Congress .

Karner S L. 2005. Stimulation techniques used in enhanced geothermal systems: perspectives from geomechanics and rock physics. In: Thirtieth workshop on geothermal reservoir engineering Stanford University. Stanford: The 30th Stanford Geothermal Workshop .

LIU Xiao-gang, TAO Lin, et al. 2011. Optimal design of casing of high temperature and high pressure well in Bohai Oilfield. Fault-Block Oil & Gas Field, 18(6): 787-789 .

Allen D M, Ghomshei M M, et al. 2000. The current status of geothermal exploration and development in Canada. Kyushu-Tohoku: 2000 World Geothermal Congress, 55-58 .

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