Indoor thermal quality is one of the main research topics in the field of sustainable construction. The HCRI-BIPV smart window was developed for indoor environmental control of the quality of life of the building. This paper describes the 0.75 kWp capacity of a grid-connected photovoltaic energy system controlled by the indoor thermal environment. The size of the monitoring study was office hours, and data were recorded between 8 a.m. and 5 p.m. When the indoor temperature reaches 26°C or higher, the windows are opened and cooled by fresh air to bring the indoor temperature below 10°C and above. The Smart Window System had 130.01 wKh in the 6-month study. Taking into account each evaluation factor, the HCRI-BIPV Smart Window not only provides a passive energy profile for its power load, but also improves the indoor thermal environment with natural ventilation. The study provides a very interesting data for the development of BIPV smart windows between BIPV applications and building energy design in Taiwan.
summary
Smart grid is one of the main energy management concepts in the sustainable development of smart buildings. Net zero energy, zero energy and inactive energy are the trends of the international roadmap process for energy conservation policies. The BIPV case study uses a window system design to integrate the HCRI-BIPV system with human life, so that human behavior is closed to the health and comfortable quality of life. The concept of renewable energy design enables versatility with the availability of building materials. In addition, in the physical design of the building, through environmental control, the climatic characteristics of the BIPV environment need to be considered, especially in the humid subtropical region, Taiwan.
The HCRI-BIPV Smart Window is a successful study of a passive energy system that provides electricity to its own drivers, and the excess energy will feed 128.50 kWh into the public grid. The HCRI-BIPV window system can provide its own power to drive the window controller, which is cooled by natural ventilation. Since there is not enough energy to cool the indoor thermal environment, the multi-functionality of solar technology is the research direction of indoor thermal comfort research. Compiled by Chen Jiaoyun
Finally, the BIPV case study uses three aspects: renewable energy use, ventilation systems, and thermal controllers. It became a HCRI-BIPV smart window to study PV power performance with indoor thermal comfort research Taiwan, but its power quality value is weak to provide power for air load use projects. This paper provides a sample of renewable energy and environmental control data for renewable energy planners and building designers who are interested in the application of BIPV renewable energy. The study can then provide people with a sample of data who will obtain the thermal design of a sustainable building through the HCRI-BIPV smart window study.
