Abstract
In the field of the efficiency of very shallow geothermal energy systems, there is still a significant need for research activity. To ensure the proper exploitation of this energy resource, the decisive geophysical parameters of soil must be well-known. Within this study, thermal conductivity, as a fundamental property for evaluating the geothermal potential of very shallow geothermal systems, was analyzed and measured with a TK04 device. A dataset, consisting of various geophysical parameters (thermal conductivity, bulk density, water content, and porosity) determined for a large range of different textural soil classes, was collated. In a new approach, the geophysical properties were visualized covering the complete grain size range. The comparison between the measured and calculated thermal conductivity values enabled an investigation with respect to the validity of the different Kersten equations. In the course of this comparison, the influence of effective bulk density was taken into account. In conclusion, both Kersten formulas should be used as recommended and regular bulk density corresponded better to the reference dataset representing the outcomes of the TK04 laboratory measurement. Another objective was to visualize the relation of thermal conductivities within their corresponding textural classes and the validity of Kersten formulas for various bulk densities, depths, and soils. As a result, the accessibility to information for expedient recommendations about the feasibility of very shallow geothermal systems will be improved. Easy, accessible know-how of the fundamentals is important for a growing renewable energy sector where very shallow geothermal installations can also cover heating and cooling demands.
Highlights
Due to climate change and the consequent societal rethinking about energy policies in favor of renewable energies, geothermal energy has become progressively important for heating and cooling demands
Results nine different grain size classes according to the United States Department of Agriculture (USDA) soil texture classification from various locations were examined in terms of bulk density, porosity, and thermal conductivity
Textural soil classes were derived based on the samples granulometry
Summary
Due to climate change and the consequent societal rethinking about energy policies in favor of renewable energies, geothermal energy has become progressively important for heating and cooling demands. To enable proper and sustainable implementation in today’s energy concepts, research into geothermal systems is fundamental. Compared to solar or wind energy, geothermal systems—as part of the renewable energy sector—are not dependent on diurnal varying climatic conditions. These systems are only affected by seasonal temperature changes until a certain depth [4]. These systems are available at any time and are sustainable if anticipatorily used [5]. Low enthalpy geothermal systems can be installed almost everywhere to enable a decentralized energy supply. In vertical shallow geothermal systems (up to 400 m in depth), Soil Syst. 2018, 2, 50; doi:10.3390/soilsystems2030050 www.mdpi.com/journal/soilsystems
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