Please click on the title to download the presentation.
| 1.3 NZEB | 2.3 Smart Grids | 3.3 Industry | 4.3 Sorption Technologies |
| K.1.3.1 Application of GSHP system in nearly zero energy building (NZEB) Prof. Wei Xu, Chairman, China Committee of Heating Ventilation & Air Conditioning (CCHVAC) |
K.2.3.1 Next Generation Heat Pump Systems with Enhanced Smart Grid Response Capability for the United States Market Dr. Ammi Amarnath, Electric Power Research Institute |
K.3.3.1 Flexible heat supply and sustainability Jan Grift, Senior Energy Analyst, Energy Matters |
K.4.3.1 Adsorption Heat Pumps and Chillers – Recent Developments for Materials and Components Dr. Walter Mittelbach, SorTech AG |
| O.1.3.1 Field Monitoring of a Nearly Zero Energy Building Prof. Carsten Wemhoener, HSR Hochschule für Technik Rapperswil |
O.2.3.1 Market driven vs. grid supporting heat pump operation in low voltage distribution grids with high heat pump penetration – an Austrian case study Mr. Matthias Stifter, AIT Austrian Institute of Technology |
O.3.3.1 Off-design of high temperature hybrid heat pump Miss. Karoline Kvalsvik, SINTEF |
O.4.3.1 Optimization of solar cooling system in Greek hotel including cooling production and rejection heat recovery Mr. Michal Bejček, CTU in Prague |
| O.1.3.2 Developing synergies for automated optimal control of residential heat pumps Mr. Hussain Kazmi, Enervalis and KU Leuven |
O.2.3.2 Flexibility of heat pump pools: The use of SG-Ready from an aggregators perspective Mr. David Fischer, Fraunhofer – Institute for Solar Energy Systems (ISE) |
O.3.3.2 Theoretical and Experimental Study on High-Temperature Heat Pumps Using a Low GWP Refrigerant Dr. Choyu Watanabe, Chubu Electric Power Co., Inc. |
O.4.3.2 Analysis and testing of a novel double-stage adsorption-compression chiller for industrial application Dr. Salvatore Vasta, CNR – Istituto di Tecnologie Avanzate per l |
| O.1.3.3 Investigations of Different Control Strategies for Heat Pump Systems in a Residential nZEB in the Nordic Climate Mr. John Clauß, Norwegian University of Science and Technology |
O.2.3.3 Thermal storage improves flexibility of residential heating systems for smart grids Dr. Philipp Schütz, Lucerne University of Applied Sciences and Arts |
O.3.3.3 Thermodynamic Analysis on High Temperature Heat Pump cycles using Low-GWP refrigerants for Heat recovery Dr. Sho Fukuda, Kyushu University |
O.4.3.3 Residential and Commercial Capacity Absorption Heat Pumps for Space and Domestic Water Heating Applications Mr. Michael Garrabrant, Stone Mountain Technologies, Inc |
| O.1.3.4 The impact of EU nearly-zero energy building (NZEB) regulations on heating choices in buildings Mr. Lukas Bergmann, Delta Energy & Environment |
O.2.3.4 Flexibility offered by residential floor heating in a smart grid context: the role of heat pumps and renewable energy sources in optimization towards different objectives Ms. Annelies Vandermeulen, KULeuven |
O.3.3.4 Novel Working Fluid, HFO-1336mzz(E), for Use in Waste Heat Recovery Applications Mr. Jason Juhasz, Chemours Comapny |
O.4.3.4 Analysis of a compression-assisted absorption heat transformer Prof. Baolong Wang, Tsinghua University |
| 1.4 NZEB | 2.4 Smart Grids | 3.4 Industry | 4.4 Sorption Technologies |
| O.1.4.1 Prototype Air-Source Integrated Heat Pump Field Evaluation Results Mr. Jeff Munk, Oak Ridge National Laboratory |
O.2.4.1 Model predictive HP- and Building control to maximize PV-power on-site use Mr. Rene Rieberer, Graz University of Technology |
O.3.4.1 Development of centrifugal chiller and heat pump using low GWP refrigerant Mr. Ryosuke Suemitsu, Mitsubishi Heavy Industries, LTD. |
O.4.4.1 Performance Evaluation of Double-Lift Absorption Heat Transformer for Generation of Steam at 180 °C Mr. Ryousuke Moriwaki, Waseda University |
| O.1.4.2 PV and heat pump system with a seasonal storage for NZEB house Mr. Jan Sedlar, Czech Technical University in Prague |
O.2.4.2 Heat pump system control: the potential improvement based on perfect prediction of weather forecast and user occupancy Dr. Hatef Madani, KTH Royal Institute of Technology |
O.3.4.2 Measured performance of a novel high temperature heat pump with HFO-1336mzz(Z) as the working fluid Mr. Mattias Nilsson, Viking Heat Engines AS |
O.4.4.2 Experimental results of an absorption heat transformer Mr. José Corrales Ciganda, TU Berlin |
| O.1.4.3 Comfortable and high-efficient desiccant-enhanced direct expansion heat pump Mr. Yaodong Tu, Shanghai Jiaotong University |
O.2.4.3 Home Energy Management Using Retrofit Control Platform Mr. Edward Vineyard, Oak Ridge National Laboratory |
O.3.4.3 Refrigerant Selection and Cycle Development for a High Temperature Vapor Compression Heat Pump Mr. Heinz Moisi, Graz University of Technology |
O.4.4.3 Hybrid Membrane-based Ionic Liquid Absorption Cycle for Water Heating, Dehumidification, and Cooling Prof. Dr. Saeed Moghaddam, University of Florida |
| O.1.4.4 Experimental EMS of an ASHP using Load Shifting based on Time-of-Use Pricing in Ontario, Canada Mr. Aidan Brookson, Ryerson University |
O.2.4.4 A fully operational virtual energy storage network providing flexibility for the power system Dr. Martin Geidl, Swisscom Energy Solutions Ltd |
O.3.4.4 Performance analysis of a high-temperature heat pump with ejector based on butane as the refrigerant Dr. Mirza Popovac, Austrian Institute of Technology |
O.4.4.4 Heat recovery in milk powder drying by using a liquid sorption process Dr. Michel van der Pal, Energieonderzoek Centrum Nederland (ECN) |
| O.1.4.5 High efficiency heat pumps for low temperature lift applications Prof. Dr. Beat Wellig, Lucerne University of Applied Sciences and Arts – Engineering and Architecture |
O.2.4.5 Business Models using the Flexibility of Heat Pumps – A Discourse Mr. David Fischer, Fraunhofer – Institute for Solar Energy Systems (ISE) |
O.3.4.5 Techno-economic feasibility study of a system for the transfer of refrigeration capacity from LNG regasification plants to industrial assets Dr. Carlos Infante Ferreira, Delft University of Technology |
O.4.4.5 Advanced heat driven hybrid refrigeration and heat pump systems Dr. Zacharie Tamainot-Telto, University of Warwick |
| Dutch Innovation Award by Eneco
Nominees: |
|||
| 1.5 Heat pumps in Residential Buildings | 2.5 Combination | 3.5 Industry | 4.5 Sorption Technologies |
| K.1.5.1 10 years of heat pumps monitoring in Germany. Outcomes of several monitoring campaigns. From low-energy houses to un-retrofitted single-family dwellings. Dr. Marek Miara, Fraunhofer – Institute for Solar Energy Systems (ISE) |
K.2.5.1 Residential PV replacements offer an opportunity that heat pumps should not miss Krystyna Dawson, BSRIA Ltd |
K.3.5.1 Rethink Energy in Industrial Heat Pumps NOW!! Alexander Cohr Pachai, Johnson Controls, UNEP |
K.4.5.1 Sustainable data centers and energy conversion technologies Dr. Bruno Michel, Zürich Research Laboratory, IBM-Research |
| O.1.5.1 A micro-heat pump combined with mechanical ventilation including heat recovery – simulation and in situ monitoring Mr. Georgios Dermentzis, University of Innsbruck |
O.2.5.1 Smart Building heating, cooling and power generation with solar geothermal combined heat pump system Prof. Dr. Euy-Joon Lee, Korea Institute of Energy Research |
O.3.5.1 Rotation Heat Pump (RHP) Mr. Franz Rindler, ecop Technologies GmbH |
O.4.5.1 Part load performance of gas fired absorption heat pumps Mr. Paul Schmitt-Gehrke, TU Berlin |
| O.1.5.2 Inverter Drive Control and Seasonal Performance Analysis of a Single Speed Unitary Air-Source Split-System Heat Pump Mr. Nicholas Salts, Purdue University |
O.2.5.2 Eligibility of a Heat Pump Based on the Primary Energy Factor Dr. Primož Poredoš, University of Ljubljana, Faculty of mechanical engineering |
O.3.5.2 Absorption of CO2-NH3-H2O mixture in mini-channel heat exchangers Ms. Vilborg Gudjonsdottir, Delft University of Technology |
O.4.5.2 Opportunity and challenge of developing a hydrophobic membrane-based compact absorption system Mr. Sung Joo Hong, The University of Tokyo |
| O.1.5.3 Low carbon solution for heating and cooling in Multi Family Buildings Mr. Martin Betz, Glen Dimplex |
O.2.5.3 Activated building surfaces for space heating and cooling Prof. Carsten Wemhoener, HSR Hochschule für Technik Rapperswil |
O.3.5.3 Test results R600 pilot heat pump Mr. Anton Wemmers, Energy Research Center of The Nederlands (ECN) |
O.4.5.3 Development of highly performing water-adsorption chiller using new aluminophosphate as water adsorbent Dr. Kanghee Cho, Korea Institute of Energy Research |
| O.1.5.4 Comparison of energy performance of simulated and measured hp systems in existing multi-family buildings Mr. Tuomo Niemelä, Granlund Consulting Oy / Aalto University |
O.2.5.4 Performance analysis of a PV driven heat pump system during a heating season in high latitude countries Prof. Dr. Dorota Chwieduk, Institute of Heat Engineering, Faculty of Power and Aeronautical Engineering, Warsaw University of Technology |
O.3.5.4 Turbo-compressors: Prototype tests of mechanical vapour re-compression for steam driers Dr. Michael Bantle, SINTEF Energy Research |
O.4.5.4 Dynamic modelling of an air-cooled LiBr-H2O absorption chiller based on heat and mass transfer empirical correlations Mr. Joan Farnós, Universitat Polit |
| 1.6 Cold Climates | 2.6 District Heating | 3.6 Daikin Best Student Award | 4.6 Sorption Technologies |
| O.1.6.1 Turbocompressors for Domestic Heat Pumps – A Critical Review Prof. Dr. Jürg Schiffmann, Ecole Polytechnique Fédérale de Lausanne |
O.2.6.1 BIG Solar Graz – Results of a techno-economic feasibility study Mr. Patrick Reiter, S.O.L.I.D., Gesellschaft für Solarinstallation und Design mbH |
O.3.6.1 ORC Driven Heat Pump Running on Gas Bearings for Domestic Applications: Proof of Concept and Thermo-Economic Improvement Potential Ms. Violette Mounier, EPFL |
O.4.6.1 Non-intrusive characterization of thermally driven heat pumps Mr. Oliver Buchin, Technische Universit |
| O.1.6.2 Study on the Frosting Phenomena between Concavity and Convexity Plate under Forced Convection -Detailed Observation and Analysis of Frost Layer Grouth- Mr. Kenzo Yasui, Waseda University |
O.2.6.2 Practical experience on tendering and contracting heat pumps for district heating Mr. Bjarke Paaske, PlanEnergi |
O.3.6.2 Comfortable and high-efficient desiccant-enhanced direct expansion heat pump Mr. Yaodong Tu, Shanghai Jiaotong University |
O.4.6.2 Liquid Desiccant System Component Models in the Sorption System Simulation Program (SorpSim) Dr. Kyle Gluesenkamp, Oak Ridge National Laboratory |
| O.1.6.3 A new method for preventing air-source heat pump and refrigerator from frosting Dr. Li Zhang, Central Research Institute of Electric Power Industry, Japan |
O.2.6.3 Novel district heating and cooling energy network using CO2 as a heat and mass transfer fluid Prof. Dr. Daniel Favrat, Ecole Polytechnique f |
O.3.6.3 Different ethyl alcohol secondary fluids used for GSHP in Europe Miss. Monika Ignatowicz, KTH Royal Institute of Technology |
O.4.6.3 Molecular Simulation of NH3/Ionic Liquid Mixtures for Absorption Heat Pump Cycles Mr. Meng Wang, TU Delft |
| O.1.6.4 Performance Testing of Cold Climate Air Source Heat Pumps Mr. Daniel Giguère, Natural Resources Canada, CanmetENERGY |
O.2.6.4 Pricing strategies for neutral-temperature district heating and cooling networks based on heat pumps Dr. Marco Cozzini, EURAC |
O.3.6.4 High Temperature Heat Pump Integration using Zeotropic Working Fluids for Spray Drying Facilities Mr. Benjamin Zühlsdorf, Technical University of Denmark |
O.4.6.4 Cycle Simulation and Prototyping of Single-Effect Double-Lift Absorption Chiller Mr. Tatsuo Fujii, Hitachi, Ltd. |
| O.3.6.5 Comparison of energy performance of simulated and measured heat pump systems in existing multi-family residential buildings Mr. Tuomo Niemelä, Granlund Consulting Oy / Aalto University |
|||