Dafalla, 2008 - Google Patents
Improvement of thermal resistivity of desert sand for use in high voltage cable beddings and foundation in arid zonesDafalla, 2008
View PDF- Document ID
- 9157455576624907051
- Author
- Dafalla M
- Publication year
External Links
Snippet
The soil thermal resistivity is of a great importance for the design of high voltage cables. Underground cables generate heat as a result of power losses when transmitting current. This heat must be dissipated in a form that will not affect the performance of the cables. The …
- 239000004576 sand 0 title abstract description 121
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Fillion et al. | Thermal radiation and conduction properties of materials ranging from sand to rock-fill | |
| Zhang et al. | Thermal conductivity of quartz sands by thermo-time domain reflectometry probe and model prediction | |
| Farouki | Thermal properties of soils | |
| Brandon et al. | Factors influencing thermal resistivity of sands | |
| Xiao et al. | Thermal conductivity of sand–tire shred mixtures | |
| Abuel-Naga et al. | Thermal conductivity of soft Bangkok clay from laboratory and field measurements | |
| Xiao et al. | Gradation-dependent thermal conductivity of sands | |
| McCartney et al. | Field-monitoring system for suction and temperature profiles under pavements | |
| Vo et al. | Simulation of snow melting pavement performance using measured thermal properties of graphite-modified asphalt mixture | |
| Chen et al. | Thermal performances of asphalt mixtures using recycled tyre rubber as mineral filler | |
| Liu et al. | Assessment of soil thermal conductivity based on BPNN optimized by genetic algorithm | |
| Liu et al. | Potential applications of phase change materials to extend the winter construction time of earth-rock dam in cold regions | |
| Sun et al. | The relationship between thermal conductivity and electrical resistivity of silty clay soil in the temperature range− 20 C to 10 C | |
| Sivaprasad et al. | Comparative assessment of transient-and steady-state soil thermal conductivity using a specially designed consolidometer | |
| Lyu et al. | A predictive model for the thermal conductivity of silty clay soil based on soil porosity and saturation | |
| Sivaprasad et al. | Influence of stress history on thermal conductivity of saturated fine-grained soils | |
| Oladunjoye et al. | In situ determination of thermal resistivity of soil: case study of Olorunsogo power plant, southwestern Nigeria | |
| Obando et al. | Thermal properties of asphalt pavements modified with a lightweight silica-based composite | |
| Kolawole et al. | Evaluating soil thermal conductivity for buried infrastructure: Impact of water salinity, mineral composition, and moisture content on heat transfer | |
| Dafalla | Improvement of thermal resistivity of desert sand for use in high voltage cable beddings and foundation in arid zones | |
| Tang et al. | Research on the thermal conductivity and moisture migration characteristics of Shanghai mucky clay. I: Experimental modeling | |
| Al-Ajmai et al. | Effect of type of ground cover on the ground cooling potential for buildings in extreme desert climate | |
| Mitchell et al. | Field testing of cable backfill systems | |
| Al-Zyoud | Thermo-physical and mechanical properties of al hashimiyya basaltic rocks, Jordan | |
| Liu et al. | Study on frost heaving characteristics of gravel soil pavement structures of airports in Alpine regions |