SURE - Novel Productivity Enhancement Concept for a Sustainable Utilization of a Geothermal Resource

Project: The SURE Project - Novel Productivity Enhancement Concept for a Sustainable Utilization of a Geothermal Resource

Project partners: GFZ - Helmholtz Zentrum Potsdam, Deutsches Geoforschungszentrum; TU DELFT - Delft University of Technology; GZB - Geothermiezentrum Bochum; ISOR - Iceland Geosurvey; TNO - The Netherlands Organisation for Applied Scientific Research; Well Services Group; Imperial College London - Department of Earth Science and Engineering; JSC Geoterma; Nature Research Centre

Industry partners: Norduroka; RARIK; ON Power; Californie Wijnen Geothermie BV; Aardwarmtecluster 1 KKP BV

Duration: 01/2016 until 12/2018

Website: http://www.sure-h2020.eu/ Icon externer Link

Within the EC funded Horizon 2020 project SURE (Novel Productivity Enhancement Concept for a Sustainable Utilization of a Geothermal Resource) the radial water jet drilling (RJD) technology will be investigated and tested as a method to increase inflow into insufficiently producing geothermal wells. Radial water jet drilling uses the power of a focused jet of fluids, applied to a rock through a coil inserted in an existing well. This technology is likely to provide much better control of the enhanced flow paths around a geothermal well and does not involve the amount of fluid as conventional hydraulic fracturing, reducing the risk of induced seismicity considerably. RJD shall be applied to access and connect high permeable zones within geothermal reservoirs to the main well with a higher degree of control compared to conventional stimulation technologies.

SURE will investigate the RJD technology for deep geothermal reservoir rocks at different geological settings such as deep sedimentary basins and magmatic regions at the micro-, meso- and macro-scale. Laboratory tests will include the determination of parameters such as elastic constants, permeability and cohesion of the rocks as well as jetting experiments into large samples at ambient as well as simulated reservoir conditions. Samples will be investigated in 3D with micro CT scanners and with standard microscopy approaches. In addition, advanced modelling will help understand the actual mechanism leading to the rock destruction at the tip of the water jet. Last but not least, experimental and modelling results will be validated by controlled experiments in a quarry (mesoscale) which allows precise monitoring of the process, and in two different geothermal wells. Here, we outline the concept of the project.

Zusätzliche Information

Contact

Dipl.-Ing. Volker Wittig M.Sc. 

R&D Manager Advanced Drilling Technologies

Room: G1 1-003
Phone: +49 (0)234 32-10768

Volker Wittig

Simon Hahn, M. Sc. Maschinenbau

PhD student

Department: Advanced Drilling Technologies

Room: G1 1-002

Tel: +49 (0)234 32-10767

Simon Hahn