This study examined the factors affecting the bubble generation of a motor driven bubble generator to develop a heating unit using hydrodynamic cavitation. This study also investigated the heat production and thermal efficiency by changing operating conditions. Bubble generation using the 25 ℓ-capacity motor is driven bubble generator was confirmed visually in various experimental conditions: three levels of motor powers(1, 3, 5 HP), two levels of revolutions(1800, 3200 rpm), and two levels of internal pressures of the bubble generator(the atmospheric pressure, pressurized air). After constructing the heating unit, heat production, and thermal efficiency were measured in the following experimental conditions: two levels of motor powers(3, 5 HP) and three levels of water quantities(102, 152, 230 kg). And then specifically temperature increasing rate and specific consumed energy required for the heating unit design were calculated. Bubbles were generated stably at 1,800 rpm and pressure from 0~0.8 bar. When heating water around 30℃, specific temperature increasing rate was maximized at 0.247℃/min and 0.002422℃/min-kg. Thermal efficiencies were 121% with only motor driving power as input energy and 98% with both motors driving power and water circulating pump driving power as input energy. This showed that the heating unit using hydrodynamic cavitation had higher thermal efficiency than the existing combustion boiler. Maximum specific consumed energy was 0.0270 KJ/min-kg-℃. This study confirmed that water can be heated with the heat caused by the explosion of the bubbles generated by hydrodynamic cavitation. And the results of this study could be utilized for commercial use because it showed much higher thermal efficiency than the existing combustion boiler.

본 연구는 히트펌프와 잉여 태양에너지를 이용한 온실의 난방효과를 검토하고, 난방을 위한 FCU(Fan Coil Unit)의 적정 소요대수를 검토하였다. 실험기간 동안 최저 및 평균 외기온은 각각 26.2℃, –11.5℃ 및 4.4℃정도이었고, 수평면 일사량은 0.75~20.54 MJ·m-2 정도의 범위에 있다. 이 기간 동안 온실로 부터 회수된 총 잉여 태양에너지는 1,579,884.9kcal 정도로 나타나 이상화탄소 배출량을 약 470.3 kgCO2정도 절감시킬 수 있을 것으로 나타났다. 그리고 히트펌프 작동에 의해 축열탱크에 축열된 총 열 량은 26,556,903.6kcal로 이산화탄소의 발생량을 8,366.2 kgCO2정도 절감시킬 수 있는 것으로 나타났 다. 히트펌프에 의해 축열된 총 열량 중에 잉여 태양에너지에서 얻은 열량의 비율은 최소 0.0%, 최대 20.9%, 평균 6.1%정도로서 기상상태나 히트펌프 작동상태 등에 따라 큰 차이가 있었다. 히트펌프 시스 템의 성능계수와 히트펌프의 효율은 각각 약 2.64정도 및 약 86.6%전후인 것으로 나타났다. 또한 총 난방에너지는 23,554,744.7kcal으로서 실제 히트펌프에 의해 축열탱크에 축열된 량의 약 88.7%정도를 이용하는 것으로 나타났다. 시간당 전체 난방에너지는 10,993.1~18,786.9kcal·h-1범위였고, 평균 14,381.3kcal·h-1이로서 대부분 난방부하보다 많은 것으로 나타났다. FCU는 대당 1,597.9 kcal·h-1 전후의 값이나 5.0~6.0m2당 1대 정도로 설계하면 큰 문제가 없을 것으로 추정되었다.

Experimental hot-water heating system was consisted of power supply equipment, a hot water storage tank, circulating pump, fan coil unit and a plastic flexible hose. This heating system was manufactured by an electric heater of a power capacity 6kw/h and light-oil hot air heater in control the heating capacity was 5,000kcal/h. As the result, temperature difference due to hot-water heating system and hot air heater in greenhouse showed that air temperature at experimental greenhouse, and comparison greenhouse were 14.8℃, 13.4℃ respectively. It was found that root-zone temperature of experimental plot and control were 22℃, 15℃. Root-zone temperature in the experimental plot was 7℃ higher than that in control. The inlet-outlet water temperature difference of 2℃ and 3℃ corresponded to the difference of the heat exchange of about 3,132kcal/h, 4,916kcal/h, the heat exchange effciency ranged from 54~88% generally. Under the experimental condition, equation heat change(Y) and correlation could be represented as follows : Y = -282.92ｘ2 + 2963.9ｘ -1688.6, R2 = 0.9081. it is suggested to applicate energy of root-zone warming system where energy from the groundwater is extracted and transferred to the water

본 연구는 길이 15 m, 폭 5.6 m, 동고 2.9 m인 단동 비닐 온실 2동을 대상으로 실험구와 대조구로 나누어 실시하였다. 시스템은 전기히터를 이용한 온수가온기로서 온수저장조와 순환펌프, 팬코일유닛으로 구성하였다. 폐회로시스템의 온수배관을 통하여 온수가 순환되도록 하였으며 팬코일유닛을 통해 온실내부를 난방 하도록 하였다. 연구결과를 요약하면 다음과 같다. 실험기간 동안 순환유량은 26L/min 정도의 범위에 있었고, 평균유속은 2.0m/s 정도였다. 유출입수의 평균 온도차는 60±2℃ 이었다. 근권부 온도를 측정한 결과 처리구에는 22℃, 대조구에서는 15℃로 나타나 처리구 근권부 온도가 약 7℃ 높게 유지되었다. 입출구 온도차에 따른 열교환량은 온도차가 2℃일 경우 시간당 열교환량은 3,132kcal이고, 3.4℃일 경우 4,916kcal로서 열교환방정식은 y=-282.92X2+2963.9X-1688.6, R2=0.9081로 상관관계가 매우 높은 것으로 나타났으며 열교환효율은 54~88%로 온도차가 클수록 열교환효율은 높게 나타났다.

This study is nutrient heating effect to apply the surplus heat recovery in greenhouse using fan coil unit. Especially, this study was carried out to utilize a surplus heat in greenhouse. This fan coil unit system was composed of a water tank, a fan coil unit, a circulating pump and a water-water heat exchanger. As the result, Temperature difference duing to fan coil unit in greenhouse showed that air temperature at experimental greenhouse on fan , comparison greenhouse were 28.3℃, 33.9℃, respectively. heat ratio showed that exchanged energy quantity in fan coil unit was 19,900∼28,880kcal/h, respectively. It was found that difference of nutrient temperature due to surplus heat recovery, water tank temperature were 19.2∼21.5℃ and 16.2∼18.3℃, The temperature variation of nutrient temperature was about 3℃ and higher . Economic analysis of fan coil unit system was increased gross income cost by 804,787 won.

This study aims to identify participating resident awareness of the improvements to forest carbon cycle villages created by the Korea Forest Service by introducing a system for district heating basedon forest biomass in mountainous areas. Hwacheon Forest Carbon Circulation village was established in Paroho-neureup village in Yuchon-ri, Hwacheon-gun between 2011 and 2013. However, its operation has not been smooth due to the increasing number of households rapidly leaving the district heating system. This study surveyed 76 households that participated in the district heating system using forest biomass in the early stages of the project. This includes households participating in the district heating system(participating households) and households not currently participating in the district heating system(withdrawal households) from September 2019. Surveys focused on the process of participating in forest carbon cycle village projects, and satisfaction in local heating and policy requirements. Of the 67 households, excepting those not allowed to participate in the survey due to death or having moved elsewhere, 36 households participated and 31 households the were in the process of leaving the village were also included. As a result, there was a significant difference between participating and exiting households in the motivation and satisfaction level of district heating. The results of this study are expects to reflect the importance of awareness of residents in the operation of the forest carbon cycle village. This will be utilized as an important dataset for improvement as a means to promote the re-entry if outgoing households. It will also help set the direction of the forest town revitalization project, utilizing forest biomass in the future.