Heat transfer in tubing-casing annulus during production process of geothermal systems

Fuzong Zhou; Xiuhua Zheng

doi:10.1007/s12583-015-0511-5

Journal of Earth Science ›› 2015, Vol. 26 ›› Issue (1) : 116 -123. DOI: 10.1007/s12583-015-0511-5

Special Issue on Geohtermal Energy

Heat transfer in tubing-casing annulus during production process of geothermal systems

Fuzong Zhou ¹^,^a
, Xiuhua Zheng ²

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Abstract

In geothermal systems, the temperature distribution of heat flow in the wellbore is dependent on the well structure and the geological conditions of the surrounding formation. Understanding of heat transfer in the tubing-casing annulus can reduce the heat losses of wellbore fluid during the production process. The present study discusses the possible means of heat transfer in the annulus, and develops a piecewise equation for estimating the convective heat transfer coefficient with a wider valid condition of 0<Ra<7.17×10⁸. By converting the radiation and natural convection into equivalent thermal conduction, their sum is defined as a total thermal conductivity to describe the heat transfer in the annulus. The results indicate that the annulus filled with gas can be utilized as a good thermal barrier for the fluid in the wellbore. Additionally, the contribution of radiation will increase to occupy a majority proportion in the total thermal conductivity when the annular size increases and the materials have high emissivity. Otherwise, thermal radiation is just the second factor.

Keywords

heat transfer / tubing-casing annulus / Rayleigh number / natural convection / geothermal system / thermal conductivity / radiation

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Fuzong Zhou, Xiuhua Zheng. Heat transfer in tubing-casing annulus during production process of geothermal systems. Journal of Earth Science, 2015, 26(1): 116-123 DOI:10.1007/s12583-015-0511-5

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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]	Deguen R. Thermal Convection in a Spherical Shell with Melting/Freezing at either or both of Its Boundaries. Journal of Earth Science, 2013, 24(5): 669-682.

[3]	Dropkin D, Somercales E. Heat Transfer by Natural Convection in Liquids Confined by Two Parallel Plates Which are Inclined at Various Angles with Respect to Horizontal. Journal of Heat Transfer, 1965, 87 77

[4]	Durucan E, Olcenoglu K. Geothermal Drilling and Preliminary Test Operations at Kizildere, Turkey. Geothermics, 1970, 2: 1463-1466.

[5]	Fishenden M, Saunders O A. An Introduction to Heat Transfer, 1950, 1st Ed. London: Oxford University Press, 103.

[6]	Gabolde G, Nguyen J P. Drilling Data Handbook, 1991 Paris: Technip

[7]	Gallup D L. Production Engineering in Geothermal Technology: A Review. Geothermics, 2009, 38: 326-334.

[8]	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.

[9]	Grant M A, Bixley P F. Geothermal Reservoir Engineering, 2011, (2nd Ed.) Oxford: Elservier

[10]	Hasan A R, Kabir C S. Fluid Flow and Heat Transfer in Wellbores, 2002 Texas: Society of Petroleum Engineers, 64-73.

[11]	Holman J P. Heat Transfer, 1981, (5th Ed.) New York: McGraw-Hill

[12]	Incropera F P, DeWitt D P, Bergman T L, . Fundamentals of Heat and Mass Transfer, 2001, 5th Ed. Hoboken: John Wiley & Sons

[13]	Kanev K, Ikeuchi J, Kimura S, . Heat Loss to the Surrounding Rock Formation from a Geothermal Wellbore. Geothermics, 1997, 26: 329-349.

[14]	Kays W M, Leung E Y. Heat Transfer in Annular Passages-Hydrodynamically Developed Turbulent Flow with Arbitrarily Prescribed Heat Flux. International Journal of Heat and Mass Transfer, 1963, 6: 537-557.

[15]	Miyauchi A, Kameyama M, Ichikawa H. Linear Stability Analysis on the Influences of the Spatial Variations in Thermal Conductivity and Expansivity on the Flow Patterns of Thermal Convection with Strongly Temperature-Dependent Viscosity. Journal of Earth Science, 2014, 25(1): 126-139.

[16]	Ramey H J. Wellbore Heat Transmission. Journal of Petroleum Technology, 1962, 14: 427-435.

[17]	Rohsenow W M, Hartnett J P, Cho Y I. Handbook of Heat Transfer, 1998, 3rd Ed. New York: McGraw-Hill

[18]	Schulz S U. Investigations on the Improvement of the Energy Output of a Closed Loop Geothermal System (CLGS), 2008 Berlin: Technische Universität Berlin

[19]	Sheriff N. Experimental Investigation of Natural Convection in Single and Multiple Vertical Annuli with High Pressure Carbon Dioxide. Proceedings of the Third International Heat Transfer Conference, Chicago, Illinois., 1966, 2 132.

[20]	Tang H X, Zhang J B, Wang T Q, . Prediction for Temperature Distribution in Offshore High-Temperature Oilwells. Journal of Daqing Petroleum Institute, 2010, 34(3): 96-100.

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

[22]	Tóth A. Heat Losses in a Planned Hungarian Geothermal Power Plant. Proceedings, Thirsty-First Workshop on Geothermal Reservoir Engineering, 2006 Stanford: Stanford University

[23]	Tóth A, Bobok E. Limits of Heat Transfer Extraction from Dry Hole. Proceedings, Thirty-Third Workshop on Geothermal Reservoir Engineering, 2008 Stanford: Stanford University

[24]	Willhite G P. Overall Heat Transfer Coefficients in Steam and Hot Water Injection Wells. Journal of Petroleum Technology, 1967, 19: 607-615.

[25]	Willhite G P, Wilson J H, Martin W L. Use of an Insulating Fluid for Casing Protection during Steam Injection. Journal of Petroleum Technology, 1967, 19: 1453-1456.

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

[27]	Yang S M, Tao W Q. Heat Transfer, 1998, (3rd Ed.) Beijing: Higher Education Press

[28]	Yang X W, Fan H H, Zhao L X. A New Way to Predict Borehole Flowing Temperature Distribution. Petroleum Geology & Oilfield Development in Daqing, 2008, 27(4): 76-81.