NEW APPROACH TO MODELLING THE FORMATION OF LARGE-SIZED THERMOSIPHONS THERMAL REGIME FOR USING GEOTHERMAL HEAT

The relevance of the research is caused by the necessity to develop mathematical models of thermophysical processes occurring in thermosiphons. These models are significantly less complex than the known ones, where sophisticated hydrodynamics problems are solved for vapor channel. However, at the same time they provide the possibility of adequate predictive modeling of heat transfer processes in thermosiphons and determining their main characteristics (temperature, heat fluxes, and evaporation rates) which are necessary to create heat supply systems using geothermal and petrothermal energy of the deep layers of the earth when heat transfers by high thermosiphons system. The main aim of the research is the validation of new approach to description of heat transfer in thermosiphons, which are the main elements of the system for extracting heat from the deeper layers of the earth (geothermal and petrothermal energy) by comparing the results of mathematical modeling of temperatures within the framework of the new model at characteristic points of the coolant layer and experimental results. Object: two-phase close thermosiphon Method. The formulated boundary problem of mathematical physics was solved by the finite difference method. Results. Based on the analysis and synthesis of experimental results, the authors have developed a new approach to mathematical modeling of thermal regime formation of high thermosiphons for using geothermal heat. We formulated mathematical modeling describing heat transfer in a coolant layer on the bottom cover of thermosiphon. This model provides to make reliable prediction of evaporation (or boiling) rates of a coolant. The model differs from the known ones by description of conduction, as well as natural convection in the coolant layer. A good agreement was established between the results of numerical calculations of temperature fields in the area of analysis and the experiments. Numerical studies were performed on a spatial grid of 36×101, the time step was varied in the range from 10–3 to 10–6 s. We considered the range of heat fluxes q corresponding to the conditions of intense evaporation on the free surface of the coolant layer. Experimentally and numerically obtained temperatures at a point located on the symmetry axis of a thermosiphon at a distance of 6 mm from the surface of its bottom cover were compared. N-pentane, a low-boiling liquid that can be used in thermosiphons at relatively low temperature (up to 40 °C) of ro