Ergies 2021, 14, x FOR PEER REVIEWFigure 4. four. Average every day dry bulb temperature. Figure
Ergies 2021, 14, x FOR PEER REVIEWFigure four. 4. Typical every day dry bulb temperature. Figure Typical daily dry bulb temperature. 97 ofWind velocity [m/s]7 six five four 3 two 1 0 0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340DayFigure five. Average dailydaily velocity. Figure 5. Average wind wind velocity. 9 8 7 Direct Typical Diffuse Horizontal/m2]1 0Energies 2021, 14,20 40 60 80 one hundred 120 140 160 180 200 220 240 260 280 300 320 340DayFigure 5. Average every day wind velocity. 9 eight 7 Direct Typical Diffuse Horizontal7 ofSolar radiation [kWh/m2]6 5 4 three 2 1 0 0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340DayFigure six. Average each day direct and diffuse solar radiation. Figure six. Typical each day direct and diffuse solar radiation.Laptop or computer simulations Laptop simulations with the Compound 48/80 medchemexpress operation of each systems over a period of a single a single year the operation of both systems more than a period of year using a time step of ten min were performed. using a time step of 10 min were performed. three. Final results and Discussion 3. Benefits and Discussion three.1. Estimation of Energy Production 3.1. Estimation of Power Production The volume of power that may be delivered to the developing because of solar radiation The amount of power that can be delivered towards the constructing as a result of solar radiaconversion plus the price with the heat loss was determined by these calculations. The total tion conversion and the rate in the heat loss was determined by these calculations. The demand for thermal power in the tenement home at the style temperature (-18 C) total demand for thermal energy of your tenement home at the style temperature (-18 ) of the outdoors air is 43.61 kW. The individual elements from the thermal power loss with the outdoors air is 43.61 kW. The person components of the thermal power loss are are shown in Table 3. The following data concern the situation with the constructing soon after its shown ininsulation. following data concern the situation of the building following its interinternal Table 3. The nal insulation.Table three. Components with the thermal power loss in kW. Components Glazing Walls Floors (internal) Roofs Floors (external) External infiltration External ventilation Parameter Value-7.78 -10.91 -1.8 -2.69 -0.03 -2.66 -17.Within the case of thermal solar collectors, the method provided around ESC = 24,097 kWh (469.18 kWh per m2 gross region) of thermal energy per year. The annual energy production by PV panels was a great deal reduced and amounted to EPV = 6860 kWh (136.11 kWh per m2 of active area), assuming 95 inverter efficiency. To establish the Tenidap In stock operational efficiency (Equations (1) and (two)) of solar energy conversion, the total volume of energy incident per m2 of your plane inclined in the identical angle as the collectors was calculated. This value was ESOL = 1061 kWh/m2 for the meteorological conditions of Poznan. SC = PV = ESC 00 ESOL EPV 00 ESOL (1) (2)(Equations (1) and (2)) of solar power conversion, the total amount of power incident per m2 with the plane inclined in the similar angle as the collectors was calculated. This value was ESOL = 1061 kWh/m2 for the meteorological situations of Poznan.Energies 2021, 14,= =100(1) eight of 15 (two)The efficiency of the entire SDHW program was equal for the average worth for this type The efficiency of your complete SDHW method was equal towards the average value for this kind of renewable energy sources and was 44 . The highest value occurred in in August, whilst of renewable power sources and was 44 . The highest value occurred August, while the.