Predicting initial formation temperature for deep well engineering with a new method

Fuzong Zhou , Yucheng Xiong , Ming Tian

Journal of Earth Science ›› 2015, Vol. 26 ›› Issue (1) : 108 -115.

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Journal of Earth Science ›› 2015, Vol. 26 ›› Issue (1) : 108 -115. DOI: 10.1007/s12583-015-0512-4
Special Issue on Geohtermal Energy

Predicting initial formation temperature for deep well engineering with a new method

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Abstract

With the progress of science and technology, human beings explore the energy underground with thousands of meters. As a thermophysical parameter, initial formation temperature (IFT) plays an essential role in deep well engineering. However, it is not easy to predict the IFT accurately before drilling. This work uses a new method to analyze the effect factors of the underground temperature field, and assumes an artificial surface to eliminate the disturbance of the human errors and equipment errors on the surface temperature and thermal conductivity. Considering different distributions of the formation thermal conductivity and the rock radiogenic heat production, an optimized model was established. With this model, the paper predicted the bottom temperature of the main hole of the Chinese Continental Scientific Drilling (CCSD) as 132.80 °C at 4 725 m depth with 0.5% error. When the thermal conduction is dominant in the formation, this simple method can predict the IFT distribution effectively for deep well in the exploration stage. However, it is almost impossible to avoid aquifers in the formation of drilling deep well, an existing drillhole including groundwater is needed to predict for testing the model’s accuracy.

Keywords

initial formation temperature / deep well / thermal conductivity / radiogenic heat production

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Fuzong Zhou, Yucheng Xiong, Ming Tian. Predicting initial formation temperature for deep well engineering with a new method. Journal of Earth Science, 2015, 26(1): 108-115 DOI:10.1007/s12583-015-0512-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Akpan A E. Estimation of Subsurface Temperatures in the Tattapani Geothermal Field, Central India, from Limited Volume of Magnetotelluric Data and Borehole Thermograms Using a Constructive Back-Propagation Neural Network. Earth Interactions, 2014, 18: 1-26.

[2]

Andaverde J, Verma S P, Santoyo E. Uncertainty Estimates of Static Formation Temperature in Borehole and Evaluation of Regression Models. Geophys. J. Int., 2005, 160: 1112-1122.

[3]

Ascencio F, Garcia A, Rivera J, . Estimation of Undisturbed Formation Temperatures under Spherical-Radial Heat Flow Conditions. Geothermics, 1994, 23: 317-326.

[4]

Bassam A, Santoyo E, Andaverde J, . Estimation of Static Formation Temperatures in Geothermal Wells by Using an Artificial Neural Network Approach. Comput. Geosci-UK, 2010, 36: 1191-1199.

[5]

Brennand A W. A New Method for the Analysis of Static Formation Temperature Test. Proceedings of the 6th New Zealand Geothermal Workshop, Auckland, 1984
[6]

Carslaw H S, Jaeger J C. Conduction of Heat in Solids, 1959 London: Oxford University Press
[7]

Čermák V, Bodri L. Two-Dimensional Temperature Modelling along Five East-European Geotraverses. J. Geodyn., 1986, 5: 133-163.

[8]

Chugunov V, Fomin S, Hashida T. Heat Flow Rate at a Bore-Face and Temperature in the Multi-Layer Media Surrounding a Borehole. Int. J. Heat Mass Tran., 2003, 46: 4769-4778.

[9]

Clauser C, Giese P, Huenges E, . The Thermal Regime of the Crystalline Continental Crust: Implications from the KTB. J. Geophys. Res., 1997, 102: 18417-18441.

[10]

Cong B, Zhai M, Carswell D A, . Peotrgenesis of Ultrahigh-Pressure Rocks and Their Contry Rocks at Shuanghe in Dabieshan, Central China. Eur. J. Mineral., 1995, 7: 119-138.

[11]

Dowdle W L, Cobb W M. Static Formation Temperature from Well Logs—An Empirical Method. J. Petrol. Tech., 1975, 27: 1326-1330.

[12]

Espinosa-Paredes G, Garcia-Gutierrez A. Estimation of Static Formation Temperatures in Geothermal Wells. Energ. Convers. Manage., 2003, 44: 1343-1355.

[13]

Furlong K, Chapman D S. Thermal State of the Lithosphere. Rev. Geophys., 1987, 25: 1255-1264.

[14]

Ge S. Estimation of Groundwater Velocity in Fracture Zones from Well Temperature Profiles. J. Volcanol. Geoth. Res., 1998, 84: 93-101.

[15]

Gorman J M, Abraham J P, Sparrow E M. A Novel, Comprehensive Numerical Simulation for Predicting Temperatures within Boreholes and the Adjoining Rock Bed. Geothermics, 2014, 50: 213-219.

[16]

Hasan A R, Kabir C S. Modeling Two-Phase Fluid and Heat Flows in Geothermal Wells. J. Petrol. Sci. Eng., 2010, 71: 77-86.

[17]

He L J, Hu S B, Yang W C, . Temperature Measurement in the Main Hole of the Chinese Continental Scientific Drilling. Chinese J. Geophys., 2006, 49(3): 745-752.
[18]

Ketcham R A. Distribution of Heat Producing Elements in the Upper and Middle Crust of Southern and West Central Arizona: Evidence from the Core Complexes. J. Geophys. Res., 1996, 101: 13611-13632.

[19]

Kutasov I M, Eppelbaum L V. Determination of Formation Temperature from Bottom-Hole Temperature Logs—A Generalized Horner Method. J. Geophys. Eng., 2005, 2: 90-96.

[20]

Leblanc Y, Pascoe L J, Jones F W. The Temperature Stabilization of a Borehole. Geophysics, 1981, 46: 1301-1303.

[21]

Liou J G, Wang Q C, Zhai M G, . Ultrahigh-P Metamorphic Rocks and Their Associated Lithologies from the Dabie Mountains, Central China: A Field Trip Guide to the 3rd International Eclogite Field Symposium. Chinese Sci. Bull., 1995, 40: 1-71.
[22]

Lu N, Ge S. Effect of Horizontal Heat and Fluid Flow on the Vertical Temperature Distribution in the Semi-Confining Layer. Water Resour. Res., 1996, 32: 1449-1454.

[23]

Manetti G. Attainment of Temperature Equilibrium in Holes during Drilling. Geothermics, 1973, 2: 94-100.

[24]

Morita K, Tago M. Development of the Down-Hole Coaxial Heat Exchanger System: Potential for Fully Utilizing Geothermal Resources. GRC Bull., 1995, 24: 83-92.
[25]

Somerton W H. Thermal Properties and Temperature-Related Behavior of Rock/Fluid Systems, 1992 New York: Eisevier
[26]

Tekin S, Akin S. Estimation of the Formation Temperature from the Inlet and Outlet Mud Temperatures while Drilling Geothermal Formations. Proceedings of 36th Workshop on Geothermal Reservoir Engineering. Stanford University, Stanford, 2011
[27]

Wang J Y, Hu S B, Cheng B H, . Predication of the Deep Temperature in the Target Area of the Chinese Continential Scientific Drilling. Chinese J. Geophys., 2001, 44(6): 774-782.
[28]

Wu B, Zhang X, Jeffrey R G. A Model for Downhole Fluid and Rock Temperature Prediction during Circulation. Geothermics, 2014, 50: 202-212.

[29]

Xu Z Q, Zhang Z M, Liu F L, . Exhumation Structure and Mechanism of the Sulu Ultrahigh-Pressure Metamorphic Belt, Central China. Acta Geologica Sinica, 2003, 77: 433-450.
[30]

Zhou F, Zhang X. Assessment of Heat Transfer in an Aquifer Utilizing Fractal Theory. Appl. Therm. Eng., 2013, 59(1–2): 445-453.

[31]

Zhou N, Li Z Z, Jia Z X. Statistical Regression Analysis of Geothermal Gradient. Drilling Technology, 1997, 20(5): 5-9.
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