| Abstract | Due to climate change, the range of outdoor temperature and relative humidity has expanded with the range of dew-point temperature, thereby increasing the condensation risk in buildings. In this case, if thermoelectric modules that can immediately respond to a wide range of temperature changes are used in the condensation prevention system, the indoor condensation risk can be reduced. The applicability and economic feasibility of thermoelectric technology to prevent condensation that can occur at thermal bridges in buildings was analyzed through steady-state heat transfer analysis using THERM 7.8 and energy consumption analysis using thermoelectric element regression equations. The annual energy was analyzed to be a maximum of 70.17 kWh per household, and when converted to electricity costs, it was calculated to be approximately 8,420 KRW. By
applying thermoelectric technology, which can respond quickly and flexibly in a variety of environments, to the anti-condensation system, excellent effects were achieved in both environmental and economic aspects. |
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