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tanks and inside the pipes, temperature and humidity sensors, flow sensors and electricity control valves, high-efficiency variable-speed circulating pumps, a heat pump (operating 283 Energies 2022, 15, 1008 database on network attached storage (NAS). Real-time and past data could be accessed 288 meters), actuators controlled by the TESSe2b controller, two-way and three-way electronic mode and temperature set points) and communication protocol converters (CAN/MOD- 284 control valves, high-efficiency variable-speed circulating pumps, a heat pump (operating BUS/M-BUS). The TESSe2b controller communicates with the heat pump, the monitoring 285 mode and temperature set points) and communication protocol converters (CAN/MOD- system and with all sensors and actuators. The measured data and status of each device 286 BUS/M-BUS). The TESSe2b controller communicates with the heat pump, the monitoring in the system were collected by the monitoring system and uploaded inside a structured 287 system and with all sensors and actuators. The measured data and status of each device in the system were collected by the monitoring system and uploaded inside a structured through a password-protected website. As is shown in the hydraulic scheme of Figure 1 289 database on network attached storage (NAS). Real-time and past data could be accessed for the building in Cyprus, the heat pump charges the DHW tank through the buffer tank 290 through a password-protected website. As is shown in the hydraulic scheme of Figure 1 and not directly. The load pump is in constant pressure mode to automatically regulate 291 be accessed through a password-protected website. As is shown in the hydraulic scheme for the building in Cyprus, the heat pump charges the DHW tank through the buffer tank the flow delivered to the house based on the demand. The controller was installed inside 292 of Figure 1 for the building in Cyprus, the heat pump charges the DHW tank through the and not directly. The load pump is in constant pressure mode to automatically regulate the building in the engine room as shown in Figure 7. 293 8 of 16 buffer tank and not directly. The load pump is in constant pressure mode to automatically the flow delivered to the house based on the demand. The controller was installed inside regulate the flow delivered to the house based on the demand. The controller was installed the building in the engine room as shown in Figure 7. inside the building in the engine room as shown in Figure 7. 294 Figure 6. Overview of TESSe2b control and monitoring system implementation. 295 Figure 6. Overview of TESSe2b control and monitoring system implementation. Figure 6. Overview of TESSe2b control and monitoring system implementation. 296 Figure 7. View of the engine room. 297 Figure 7. View of the engine room. 298 Figure 7. View of the engine room. 4. Performance Evaluation of TESSe2b System 4. Performance Evaluation of TESSe2b System 4.1. Methodology 4. Performance Evaluation of TESSe2b System 299 4.1. Methodology Performance evaluation was attempted in various ways. First, we compared the Performance evaluation was attempted in various ways. First, we compared the 4T.1EMSSeeth2obdsoololugytion and a conventional heating and cooling residential system that was used 300 TESSe2b solution and a conventional heating and cooling residential system that was used in Cyprus, consisting of a boiler and burner using heat oil (heating), split units (cooling) Performance evaluation was attempted in various ways. First, we compared the 301 in Cyprus, consisting of a boiler and burner using heat oil (heating), split units (cooling) and solar supported by electric heating element DHW. For the TESSe2b energy calcula- TESSe2b solution and a conventional heating and cooling residential system that was used 302 and solar supported by electric heating element DHW. For the TESSe2b energy calculations, tions, the monitoring results during heating and cooling mode were taken into account. in Cyprus, consisting of a boiler and burner using heat oil (heating), split units (cooling) 303 the monitoring results during heating and cooling mode were taken into account. The The capacity of the conventional system for heating, cooling and DHW as well as the en- capacity of the conventional system for heating, cooling and DHW as well as the energy ergy consumption were estimated by using all technical characteristics of the building consumption were estimated by using all technical characteristics of the building shell, shell, the location of the building (climatic and meteorological data) and the typical use of the location of the building (climatic and meteorological data) and the typical use of the dwellings. A conventional system was simulated through Design Builder (DB) in order to provide all appropriate results for the TESSe2b system evaluation. TESSe2b evaluation was also conducted through different levels of system energy efficiency (symbols CH1, CH2, . . . refer to circulators, and they are shown in Figure 1) [22]: SPF1: efficiency of the system, including the electricity consumption of the GSHP; SPF2: efficiency of the system, including the electricity consumption of the GSHP and the circulator of the BHEs (circulator CH2); SPF3: efficiency of the system, including the electricity consumption of the GSHP and the circulators CH2, CH1 and CL1;PDF Image | Latent Thermal Energy Storage Application
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