PDF Publication Title:
Text from PDF Page: 013
Energies 2022, 15, 6385 13 of 13 References Informed Consent Statement: All authors have been informed and agreed to publish. Data Availability Statement: All data, models, and codes generated or used during the study appear in the article. Conflicts of Interest: All the authors have no conflict of interest. 1. Luo, T.; Pei, P.; Chen, Y.; Hao, D.; Wang, C. Improvements in the Water Retention Characteristics and Thermophysical Parameters of Backfill Material in Ground Source Heat Pumps by a Molecular Sieve. Energies 2022, 15, 1801. [CrossRef] 2. Zou, H.; Pei, P.; Zhang, J. Impacts of hydrogeological characters of fractured rock on thermodynamic performance of ground- coupled heat pump. PLoS ONE 2021, 16, e0252056. [CrossRef] [PubMed] 3. Luo, J.; Wang, H.; Zhang, H.; Yan, Z. A geospatial assessment of the installation potential of shallow geothermal systems in a graben basin. Renew. Energy 2021, 165, 553–564. [CrossRef] 4. Zhou, W.; Pei, P.; Hao, D.; Wang, C. A Numerical Study on the Performance of Ground Heat Exchanger Buried in Fractured Rock Bodies. Energies 2020, 13, 1647. [CrossRef] 5. Zhang, H.; Han, Z.; Li, X.; Ji, M.; Zhang, X.; Li, G.; Yang, L. Study on the influence of borehole spacing considering groundwater flow and freezing factors on the annual performance of the ground source heat pump. Appl. Therm. Eng. 2020, 182, 116042. [CrossRef] 6. Pastore, N.; Cherubini, C.; Giasi, C.I. Analysis of gravel back-filled borehole heat exchanger in karst fractured limestone aquifer at local scale. Geothermics 2020, 89, 101971. [CrossRef] 7. Zhao, Z.; Lin, Y.-F.; Stumpf, A.; Wang, X. Assessing impacts of groundwater on geothermal heat exchangers: A review of methodology and modeling. Renew. Energy 2022, 190, 121–147. [CrossRef] 8. He, W.; Xiang, X.; Li, Y.; Li, C. Application and research on buried ground-source heat pump technology in karst area of Guizhou. Drill. Eng. 2014, 41, 62–65. 9. You, T.; Li, X.; Cao, S.; Yang, H. Soil thermal imbalance of ground source heat pump systems with spiral-coil energy pile groups under seepage conditions and various influential factors. Energy Convers. Manag. 2018, 178, 123–136. [CrossRef] 10. Zhou, W.; Pei, P.; Mao, R.; Qian, H.; Hu, Y.; Zhang, J. Selection and techno-economic analysis of hybrid ground source heat pumps used in karst regions. Sci. Prog. 2020, 103, 0036850420921682. [CrossRef] [PubMed] 11. You, T.; Wu, W.; Shi, W.; Wang, B.; Li, X. An overview of the problems and solutions of soil thermal imbalance of ground-coupled heat pumps in cold regions. Appl. Energy 2016, 177, 515–536. [CrossRef] 12. Zeng, Z.; Xu, Y.; Zhao, Y.; Liu, H.; Tang, S. Development of experimental platform on soil heat and moisture migration of ground source heat pump system in karst region. J. Guangxi Univ. (Nat. Sci. Ed.) 2016, 41, 178–186. [CrossRef] 13. Li, Y.; Du, Z.; Xiao, B. Study of characteristics of soil temperature recover under intermittent operation of ground-source heat pump. Acta Energ. Sol. Sin. 2017, 38, 1268–1274. 14. Dacquay, C.; Fujii, H.; Lohrenz, E.; Holländer, H.M. Feasibility of thermal load control from electrochromic windows for ground coupled heat pump optimization. J. Build. Eng. 2021, 40, 102339. [CrossRef] 15. Chung, E.; Ting, K.K.; Aljaaidi, O. Karst modeling of a miocene carbonate build-up in central luconia SE Asia. In Challenges in Seismic Characterization and Geological Model Building; International Petroleum Technology Conference: Bangkok, Thailand, 2011. 16. John, H.A. Engineering Rock Mechanics; Pergamon: London, UK, 1997. 17. Su, C. Advanced Engineering Thermodynamics; Higher Education Press: Beijing, China, 1987. 18. Ma, Z.; Li, Y. Design and Application of Ground Source Heat Pump System; Machinery Industry Press: Beijing, China, 2007. 19. Snow, D.T. Anisotropic permeability of fractured media. Water Resour. Res. 1969, 5, 1273–1289. [CrossRef] 20. Yang, S.; Tao, W. Heat Transfer, 4th ed.; Higher Education Press: Beijing, China, 2006.PDF Image | Research on the Application of Fracture Water
PDF Search Title:
Research on the Application of Fracture WaterOriginal File Name Searched:
energies-15-06385.pdfDIY PDF Search: Google It | Yahoo | Bing
Turbine and System Plans CAD CAM: Special for this month, any plans are $10,000 for complete Cad/Cam blueprints. License is for one build. Try before you buy a production license. More Info
Waste Heat Power Technology: Organic Rankine Cycle uses waste heat to make electricity, shaft horsepower and cooling. More Info
All Turbine and System Products: Infinity Turbine ORD systems, turbine generator sets, build plans and more to use your waste heat from 30C to 100C. More Info
CO2 Phase Change Demonstrator: CO2 goes supercritical at 30 C. This is a experimental platform which you can use to demonstrate phase change with low heat. Includes integration area for small CO2 turbine, static generator, and more. This can also be used for a GTL Gas to Liquids experimental platform. More Info
Introducing the Infinity Turbine Products Infinity Turbine develops and builds systems for making power from waste heat. It also is working on innovative strategies for storing, making, and deploying energy. More Info
Need Strategy? Use our Consulting and analyst services Infinity Turbine LLC is pleased to announce its consulting and analyst services. We have worked in the renewable energy industry as a researcher, developing sales and markets, along with may inventions and innovations. More Info
Made in USA with Global Energy Millennial Web Engine These pages were made with the Global Energy Web PDF Engine using Filemaker (Claris) software.
Sand Battery Sand and Paraffin for TES Thermo Energy Storage More Info
CONTACT TEL: 608-238-6001 Email: greg@infinityturbine.com (Standard Web Page)