Ground-heat transfer is tightly coupled with soil-moisture transfer. The coupling is threefold: heat is transferred by thermal conduction and by moisture transfer; the thermal properties of soil are strong functions of the moisture content; and moisture phase change includes latent heat effects and changes in thermal and hydraulic properties. A heat and moisture transfer model was developed to study the ground-coupled heat and moisture transfer from buildings. The model also includes detailed considerations of the atmospheric boundary conditions, including precipitation. Solutions for the soil temperature distribution are obtained using a finite element procedure. The model compared well with the seasonal variation of measured ground temperatures.
Skip Nav Destination
Article navigation
February 2002
Technical Papers
Ground-Coupled Heat and Moisture Transfer from Buildings Part 1–Analysis and Modeling*
Michael P. Deru,
Michael P. Deru
National Renewable Energy Laboratory, 1617 Cole Blvd., Golden CO 80401
Search for other works by this author on:
Allan T. Kirkpatrick
Allan T. Kirkpatrick
Mechanical Engineering Department, Colorado State University, Fort Collins CO 80523
Search for other works by this author on:
Michael P. Deru
National Renewable Energy Laboratory, 1617 Cole Blvd., Golden CO 80401
Allan T. Kirkpatrick
Mechanical Engineering Department, Colorado State University, Fort Collins CO 80523
Contributed by the Solar Energy Division of the American Society of Mechanical Engineers for publication in the ASME JOURNAL OF SOLAR ENERGY ENGINEERING. Manuscript received by the ASME Solar Energy Division, Nov. 2000; final revision, May 2001. Associate Editor: V. C. Mei.
J. Sol. Energy Eng. Feb 2002, 124(1): 10-16 (7 pages)
Published Online: May 1, 2001
Article history
Received:
November 1, 2000
Revised:
May 1, 2001
Citation
Deru, M. P., and Kirkpatrick, A. T. (May 1, 2001). "Ground-Coupled Heat and Moisture Transfer from Buildings Part 1–Analysis and Modeling." ASME. J. Sol. Energy Eng. February 2002; 124(1): 10–16. https://doi.org/10.1115/1.1435652
Download citation file:
Get Email Alerts
A Nonintrusive Optical Approach to Characterize Heliostats in Utility-Scale Power Tower Plants: Camera Position Sensitivity Analysis
J. Sol. Energy Eng (December 2024)
A Solar Air Receiver With Porous Ceramic Structures for Process Heat at Above 1000 °C—Heat Transfer Analysis
J. Sol. Energy Eng (April 2025)
View Factors Approach for Bifacial Photovoltaic Array Modeling: Bifacial Gain Sensitivity Analysis
J. Sol. Energy Eng (April 2025)
Resources, Training, and Education Under the Heliostat Consortium: Industry Gap Analysis and Building a Resource Database
J. Sol. Energy Eng (December 2024)
Related Articles
Ground-Coupled Heat and Moisture Transfer from Buildings Part 2–Application
J. Sol. Energy Eng (February,2002)
Analysis of Heat and Moisture Transfer Beneath Freezer Foundations-Part II
J. Sol. Energy Eng (May,2004)
Theoretical Prediction of the Soil Thermal Conductivity at Moderately High Temperatures
J. Heat Transfer (December,2002)
On the Thermal Performance Characteristics of Three-Dimensional Multichip Modules
J. Electron. Packag (September,2004)
Related Proceedings Papers
Related Chapters
Energy Balance for a Swimming Pool
Electromagnetic Waves and Heat Transfer: Sensitivites to Governing Variables in Everyday Life
Experimental Investigation of an Improved Thermal Response Test Equipment for Ground Source Heat Pump Systems
Inaugural US-EU-China Thermophysics Conference-Renewable Energy 2009 (UECTC 2009 Proceedings)
Pool Boiling
Thermal Management of Microelectronic Equipment, Second Edition