001461636 000__ 06013cam\a22006377a\4500
001461636 001__ 1461636
001461636 003__ OCoLC
001461636 005__ 20230503003403.0
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001461636 007__ cr\un\nnnunnun
001461636 008__ 230325s2023\\\\sz\a\\\\o\\\\\000\0\eng\d
001461636 019__ $$a1373930399
001461636 020__ $$a9783031245244
001461636 020__ $$a3031245245
001461636 020__ $$z3031245237
001461636 020__ $$z9783031245237
001461636 0247_ $$a10.1007/978-3-031-24524-4$$2doi
001461636 035__ $$aSP(OCoLC)1373984491
001461636 040__ $$aEBLCP$$beng$$cEBLCP$$dGW5XE$$dYDX$$dOCLCF
001461636 049__ $$aISEA
001461636 050_4 $$aTH7417.5
001461636 08204 $$a697/.7$$223/eng/20230327
001461636 24500 $$aGeothermal heat pump systems /$$cDavid Borge-Diez, Enrique Rosales-Asensio, editors.
001461636 260__ $$aCham, Switzerland :$$bSpringer,$$c2023.
001461636 300__ $$a1 online resource (vi, 323 pages) :$$billustrations (chiefly color).
001461636 4901_ $$aGreen energy and technology,$$x1865-3537
001461636 500__ $$a1.1 Thermal Resistance Network Within a Borehole
001461636 5050_ $$aIntro -- Contents -- Geoespatial Distribution of the Efficiency and Sustainability of Different Energy Sources for Geothermal Heat Pumps in Europe -- 1 Introduction -- 2 Heat Pumps Technology -- 3 Analysis Description -- 3.1 Heat Pump Selection -- 3.2 Input Energies -- 4 Costs and Emissions Comparative -- 5 Sensitivity Analysis -- 5.1 Sensitivity Related to COP Improvement in EHPs -- 5.2 Sensitivity Related to COP Improvement in GEHPs -- 5.3 Sensitivity Related to Emissions in Electricity Production -- 6 Conclusions -- References -- Low-Enthalpy Geothermal Applications -- 1 Introduction
001461636 5058_ $$a2 Geothermal Olympic-Size Outdoor Swimming Pools -- 2.1 Introduction -- 2.2 The Beatty Park Leisure Centre Outdoor Swimming Pools -- 2.3 Energy Balance -- 2.4 Model Data -- 2.5 Model Analysis -- 3 Conclusions -- 4 Viability of Ground Source Heat Pumps (GSHP) Against Air Source Heat Pumps (ASHP) for Domestic Applications -- 5 Introduction -- 6 Experimental Systems -- 6.1 Common Construction Details of the Houses -- 6.2 GSHP System Description -- 6.3 ASHP System Description -- 7 Instrumentation -- 7.1 Sensor Calibration -- 7.2 Data Collection and Processing -- 8 Analysis
001461636 5058_ $$a8.1 Comparison of Operating Conditions -- 8.2 Heating and Cooling Capacities and COP -- 9 Results and Discussion -- 9.1 Basic Data -- 9.2 Air Entering the FCU -- 9.3 Groundwater Temperature -- 9.4 COPs of GSHP and ASHP Systems -- 10 Conclusions -- 11 Appendix B -- References -- Energy Geostructures -- 1 Introduction -- 2 Energy Pile Fundamentals -- 2.1 Ground Source Heat Pump Systems (GSHPs) -- 2.2 Types of Ground Heat Exchangers (GHEs) -- 2.3 Heat Exchange Operation -- 2.4 Energy Pile Materials and Configurations -- 2.5 Benefits and Limitations -- 2.6 Applications and Developments
001461636 5058_ $$a3 Thermal Behavior of Energy Piles -- 3.1 General Principles -- 3.2 Heat Transfer Within Energy Piles -- 3.3 Thermal Analysis of Energy Piles -- 4 Mechanical Behavior of Energy Piles -- 5 Design of Energy Piles -- 5.1 General Considerations -- 5.2 Current Standards -- 5.3 Thermal Design -- 5.4 Mechanical Performed-Based Design -- 6 Site Investigation for Energy Pile Design -- 6.1 Design Stages -- 6.2 Design Parameters -- 6.3 Determination of Design Parameters -- 7 Construction Recommendations for Energy Piles -- 7.1 Materials -- 7.2 Pipes Features and Bending -- 7.3 Pipes Fixing
001461636 5058_ $$a7.4 Installation -- 7.5 Quality Control -- References -- Multiparametric Evaluation of Electrical, Biogas and Natural Gas Geothermal Source Heat Pumps -- 1 Introduction -- 2 Research Scope -- 3 Practical Procedure -- 3.1 Economic Evaluation -- 3.2 Environmental Footprint -- 4 Discussion -- 4.1 Overall Process Economy -- 4.2 Initial Investment -- 4.3 Environmental Impact -- 4.4 System Availability -- 4.5 Global Discussion -- 5 Conclusions -- References -- Transient Thermal-Resistance-Capacitance Model for U-Tube Ground Heat Exchanger -- 1 Introduction
001461636 506__ $$aAccess limited to authorized users.
001461636 520__ $$aThis book presents an overview of geothermal heating systems using ground source heat pumps in different countries. It evaluates the emissions and energy costs generated by the operation of low enthalpy geothermal systems, with heat pumps fed by different energy sources, and assesses, from an international point of view, those policies whose aim is a sustainable, low-carbon economy. The use of low-impact energy sources is gradually growing with the aim of reducing greenhouse gases emission and air pollution. The alternatives offered by geothermal systems are one of the key solutions for a future renewable development, enabling the electrification of heating systems and the use of biofuels. The book will be of interest to energy professionals and researchers.
001461636 588__ $$aDescription based on print version record.
001461636 650_0 $$aGround source heat pump systems.
001461636 650_0 $$aHeat pumps$$xThermodynamics.
001461636 655_0 $$aElectronic books.
001461636 7001_ $$aBorge Díez, David,$$eeditor.
001461636 7001_ $$aRosales-Asensio, Enrique,$$eeditor.
001461636 77608 $$iPrint version:$$aBorge-Diez, David$$tGeothermal Heat Pump Systems$$dCham : Springer International Publishing AG,c2023$$z9783031245237
001461636 830_0 $$aGreen energy and technology.$$x1865-3537
001461636 852__ $$bebk
001461636 85640 $$3Springer Nature$$uhttps://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-031-24524-4$$zOnline Access$$91397441.1
001461636 909CO $$ooai:library.usi.edu:1461636$$pGLOBAL_SET
001461636 980__ $$aBIB
001461636 980__ $$aEBOOK
001461636 982__ $$aEbook
001461636 983__ $$aOnline
001461636 994__ $$a92$$bISE