The apiculture not only provided a huge amount of production, but more importantly, the bees played as the pollinators of nearly 90% of the economic crops. After 2006, large-scale loss of bees happened abruptly, resulting in serious economic losses in the agricultural industry. The statistical data in recent years showed that the scale of winter loss was far beyond the past, so the winter loss had become a very important issue for scientists. According to previous studies, if the rearing temperature is too low in the capped stage, negative effects such as the incomplete development of the nervous system, the decline of resistance to pesticides and Varroa infestation could occur more easily. Therefore, this study intends to develop a heating system to try to maintain the suitable temperature of the colony's growth by external forces in a low-temperature environment so as to increase the ability of the colony to overwinter. A PCB-based heating system were developed in this study. The material changed from glass-fiber into aluminum which have higher heat transfer coefficient. The try-and-error strategy of wire distribution decreased the temperature difference on the heating plate to lower than 0.5°C, which was better than even distribution, resulting in 1.2°C, and was a suitable device to maintain the temperature of brood. This study put the heating system in a real beehive, and found that colonies, which had the similar size, added with heating system were more resistant to the cold winter. The colonies without the heating systems collapsed soon during the cold spell, or they collapsed in few days. In addition, the emergence rate of both control groups and experiment group were between 67% to 69%, and the pattern of decrease of the numbers of capped were similar. Thus, it could be seen that heating system did not affect the parenting behavior. Shuttling down the heating system immediately could have strongly effect on the colonies. The mortality of the colony in the experiment was 0.23 before the heating system was turned off, while the mortality increased 0.50 after the heating system was turned off, indicating that massive loss happened and colony collapse eventually. This study will test the feasibility of the embedded heating system in the future, and at the same time study the way of temperature regulation in the beehive to conform to the law of nature. This study confirms that adding a heating system could successfully increase the survival rate of bee colonies. It is expected that the heating system can be applied to the actual industry to reduce the economic losses of the beekeepers due to winter loss, and increase the value of the apiculture.