S. Homuth scite author profile

Abstract. The Upper Jurassic carbonates of the southern German Molasse Basin are the target of numerous geothermal combined heat and power production projects since the year 2000. A production-orientated reservoir characterization is therefore of high economic interest. Outcrop analogue studies enable reservoir property prediction by determination and correlation of lithofacies-related thermo-and petrophysical parameters. A thermofacies classification of the carbonate formations serves to identify heterogeneities and production zones. The hydraulic conductivity is mainly controlled by tectonic structures and karstification, whilst the type and grade of karstification is facies related. The rock permeability has only a minor effect on the reservoir's sustainability. Physical parameters determined on oven-dried samples have to be corrected, applying reservoir transfer models to water-saturated reservoir conditions. To validate these calculated parameters, a Thermo-Triaxial-Cell simulating the temperature and pressure conditions of the reservoir is used and calorimetric and thermal conductivity measurements under elevated temperature conditions are performed. Additionally, core and cutting material from a 1600 m deep research drilling and a 4850 m (total vertical depth, measured depth: 6020 m) deep well is used to validate the reservoir property predictions. Under reservoir conditions a decrease in permeability of 2-3 magnitudes is observed due to the thermal expansion of the rock matrix. For tight carbonates the matrix permeability is temperature-controlled; the thermophysical matrix parameters are density-controlled. Density increases typically with depth and especially with higher dolomite content. Therefore, thermal conductivity increases; however the dominant factor temperature also decreases the thermal conductivity. Specific heat capacity typically increases with increasing depth and temperature. The lithofacies-related characterization and prediction of reservoir properties based on outcrop and drilling data demonstrates that this approach is a powerful tool for exploration and operation of geothermal reservoirs.

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Thermal effect of a borehole thermal energy store on the subsurface

Mielke

Bauer

Homuth

et al. 2014

Geotherm Energy

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Seasonal High Temperature Heat Storage with Medium Deep Borehole Heat Exchangers

et al. 2015

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Upscaling thermal conductivities of sedimentary formations for geothermal exploration

et al. 2015

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Lithofacies and depth dependency of thermo- and petrophysical rock parameters of the Upper Jurassic geothermal carbonate reservoirs of the Molasse Basin

Homuth

Götz

Sass

2014

zdgg

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In the early stages of hydrothermal reservoir exploration, the thermo-physical characterization of the reservoir is accomplished by evaluating drilling data and seismic surveys. Especially in carbonate reservoirs the distinction of different facies zones and heterogeneities in general is very complex. For economic reasons a sufficiently high flow rate toward the production well and an according high fluid temperature is necessary. For reservoir predictions and modelling, geothermal parameters such as permeability, thermal conductivity/diffusivity, and specific heat capacity have to be quantified. The thermo-physical parameters are facies related. The application of a thermofacies classification to Upper Jurassic limestones serves to understand the heterogeneities and to identify production zones. Outcrop analogue studies enable the determination and correlation of facies related thermo-physical parameters and structural geology data and thus the geothermal exploration concept becomes more precise and quantitative. The analogue outcrops of the Swabian and Franconian Alb represent the target formations of Upper Jurassic carbonate reservoirs in the adjacent Molasse Basin. These limestone formations contain the main flow paths through fractures, faults, and characteristic of limestone formations also through karstification. The type and grade of karstification is also facies related. In general the matrix permeability has only a minor effect on the reservoir's sustainability except for some grainstones and dolomitized zones with higher porosities and permeabilities. Permeabilities range from 10-18 to 10-13 m² (0.001 mD to 100 mD). The permeability range of mudand wackestones is about the same. A high variation of thermo-physical parameters is recognized within individual facies zones or stratigraphic units. Mud-and wackestones show thermal conductivities around 2 W/(mK), while mudstones have lower thermal conductivities than wackestones. The thermal conductivities of massive reefal limestones show values of 1.8 to 3.9 W/(mK). Secondarily silicified reefal limestones and dolomites show the highest values of thermal conductivity. These parameters determined on oven dried samples have to be corrected for water saturated rocks under the according temperature and pressure conditions using transfer models. A comparison of calculated reservoir properties with measurements from deep drill cores confirms a good correlation. Based on the investigation of the matrix parameters in combination with reservoir transfer models, the reservoir prognosis and numerical simulation can be improved. The facies related characterization and prediction of reservoir formations is a powerful tool for the exploration, operation, extension and quality management of geothermal reservoirs in the Molasse Basin. Kurzfassung In der Planungsphase einer hydrothermalen Reservoirerkundung erfolgt die thermophysikalische Charakterisierung des Reservoirs durch die Auswertung von Bohrungsdaten und seismischen Erkundungen. Im Falle von Karbonatreservoiren ist...

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S. Homuth

Reservoir characterization of the Upper Jurassic geothermal target formations (Molasse Basin, Germany): role of thermofacies as exploration tool

Thermal effect of a borehole thermal energy store on the subsurface

Seasonal High Temperature Heat Storage with Medium Deep Borehole Heat Exchangers

Upscaling thermal conductivities of sedimentary formations for geothermal exploration

Lithofacies and depth dependency of thermo- and petrophysical rock parameters of the Upper Jurassic geothermal carbonate reservoirs of the Molasse Basin

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