Institut Nachhaltigkeit und Energie am Bau
Dauerhafte URI für die Sammlunghttps://irf.fhnw.ch/handle/11654/10
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Ergebnisse nach Hochschule und Institut
Publikation Contributions to system integration of PV and PVT collectors with heat pumps in buildings(2019) Koch, Manuel; Dott, Ralf; Tanabe, Shin-ichi; Zhang, H.; Kurnitski, Jarek; Gameiro da Silva, Manuel; Nastase, Ilinca; Wargocki, Pawel; Cao, Guangyu; Mazzarela, Livio; Inard, ChristianA common approach to improve self-consumption of photovoltaic (PV) generation in buildings with heat pumps (HP) is to overload the thermal storage capacities during times with surplus PV generation (hereinafter referred to as thermal overloading). The impact of battery capacity and domestic hot water (DHW) consumption on the effectiveness of this method in a single-family home (SFH) is evaluated through numerical simulations. Increased battery capacity is shown to decrease the effectiveness of thermal overloading. Regarding DHW consumption, temporal concentration is shown to have a stronger influence on the effectiveness of thermal overloading than total energy. Furthermore, the potential of photovoltaic-thermal collectors (PVT) as heat exchangers for air/brine/water heat pumps (ABWHP) is estimated. The results show that the properties of PVT collectors with high thermal conductivity are in the feasible range for application in a well-insulated SFH in Central European climate.04B - Beitrag KonferenzschriftPublikation CoolShift. Cooling of buildings by chiller-assisted nocturnal radiation and convection(IOP Publishing, 2019) Koch, Manuel; Dott, Ralf; Eismann, RalphA novel approach for cooling an office building is numerically evaluated. PVT collectors are used for nocturnal radiative and convective cooling. A TABS ceiling serves as thermal storage. If the free cooling power of the PVT collectors is too low, it is boosted by a chiller raising the collector temperature. While the energy efficiency improves compared to a conventional daytime chiller cooling system, the room temperature cannot always be kept in the desired band. Furthermore, the PVT collectors stay cooler than comparable PV modules during the day, increasing the electricity generation.01A - Beitrag in wissenschaftlicher ZeitschriftPublikation CoolShift – Cooling of buildings by chiller-assisted nocturnal radiation and convection(IOP Publishing, 04.09.2019) Koch, Manuel; Dott, Ralf; Eismann, Ralph; Scartezzini, Jean-LouisA novel approach for cooling an office building is numerically evaluated. PVT collectors are used for nocturnal radiative and convective cooling. A TABS ceiling serves as thermal storage. If the free cooling power of the PVT collectors is too low, it is boosted by a chiller raising the collector temperature. While the energy efficiency improves compared to a conventional daytime chiller cooling system, the room temperature cannot always be kept in the desired band. Furthermore, the PVT collectors stay cooler than comparable PV modules during the day, increasing the electricity generation.04B - Beitrag KonferenzschriftPublikation Energieflüsse eines Mehrfamilienhauses unter der Lupe(AZ Medien AG, 12.10.2012) Dorusch, Falk; Hall, Monika; Dott, RalfEin detailliertes Monitoring der Energieflüsse ermöglicht Einblicke in die Energiebilanz eines Mehrfamilienhauses mit Elektromobilität in Rupperswil. Dank eines 15-minütigen Messwerterfassungsintervalls können Aussagen zur Gleichzeitigkeit von solarer Energieerzeugung und Stromverbrauch getroffen und Potenziale zur Lastverschiebung aufgezeigt werden.01B - Beitrag in Magazin oder ZeitungPublikation Seasonal Performance of a Combined Solar, Heat Pump and Latent Heat Storage System(Ecole Polytechnique Fédérale de Lausanne (EPFL), 2013) Winteler, Christian; Dott, Ralf; Afjei, Thomas; Scartezzini, Jean-LouisThis paper investigates the seasonal performance of a combined solar, heat pump and latent heat storage system for dwellings. This combination could provide a viable alternative to common brine-water heat pump systems with a borehole heat exchanger (BHX). Since the latent heat storage, or ice storage, is filled with pure water, it can also be used in (but is not limited to) places where a BHX is prohibited, e.g. water protection areas. The aim of this work is to find and evaluate given system configurations for three different annual heat demands that reach seasonal performance factors (SPF) comparable to those of BHX heat pump systems, i.e. SPF ~ 4.0. A simulation study using MATLAB®/SIMULINK® and the CARNOT Blockset is conducted. Technologies considered in the simulation study are a brine-water heat pump, unglazed solar collectors as source for the heat pump and a buried ice storage that serves as alternative source for the heat pump and is regenerated by the collectors. Unglazed collectors use solar irradiation and ambient heat (via convective heat exchange) for heat generation. Additionally, thermal coupling of the ice storage to the surrounding soil which also contributes to the regeneration of the system is considered. The simulation models of this system have been validated with laboratory and field test data. The heat generated by the heat pump is used for space heating and domestic hot water preparation of single family houses with different heat loads which have been defined in the framework of IEA SHC Task 44 / HPP Annex 38 "Solar and heat pump systems". To obtain the desired SPF for each building type the power output of the heat pump with the corresponding size of the collector field is varied. For each building a configuration is found that yields a SPF ~ 4.0. A high SPF can only be reached as long as no backup heating is needed, which means, that the ice storage should never be completely discharged, i.e. completely frozen. This requires significant contributions from the solar collector, especially during the heating period.04B - Beitrag Konferenzschrift