The Climate chamber system is an essential facility for aerodynamic performance development of commercial vehicles to investigate air flow field characteristics in different climatic conditions. In particular, the analysis of airflow fields within the chamber system is an essential consideration for optimal design. In this study, the pressure characteristics and velocity uniformity in the test section area were predicted with blower impeller rotational speed using CFD. The velocity uniformity is affected by the distance from the blower nozzle outlet, reaching up to 72.7% at 695 RPM. The pressure differential between 300 RPM and 740 RPM shows an approximate difference of 2651 Pa, with a high-pressure distribution observed along the right side wall of the blower. These results are expected to be used as design data applicable for improving the performance of environmental chamber systems.

Effects of substrate bed interior environments on mushroom qualities were investigated in oyster mushroom cultivation facilities in which either Reversible Air-Circulation Fans (RACF) blowing air in two directions (upwards and downwards) or customary Convection Fans (CF) with air blowing only upwards were operated throughout the cultivation period. Two days before harvest, the deviation ranges of the bed interior temperature and relative humidity in the facility using RACF were in the ranges of 1.0-1.3oC and 7.8-9.0% in the first growing cycle, and within 0.7-1.1oC and 10.0-11.4% in the second cycle. In the facility using CF, the ranges of variation in the indoor environment parameters (5.8-6.4oC and 21.3-23.1% in the first growing cycle, and 3.4-5.7oC and 14.6-18.3% in the second growing cycle) were much enlarged compared to those associated with RACF. These results strongly indicate that RACF significantly enhances air uniformity. Some mushroom qualities differed between growing cycles. For instance RACF in the first cycle gave somewhat better qualities than CF, but some qualities, like pileus diameter and stipe length, were slightly lower than those described for CF in the second cycle when the cultivation substrate weakened. The observation that some qualities worsened under RACF conditions, despite better air uniformity during the growing cycle, revealed the possibility that downward wind may exert a non-negligible negative effect on mushroom growth. Therefore in the future, making wind measurements on the interior and exterior of substrate beds is necessary to obtain insights into their influences on mushroom qualities. The RACF operation manual needs to be edited to convey this necessity.

느타리버섯은 재배사 내부환경에 크게 영향을 받으며 강제 공기순환팬에 의해 공기를 교반하여 내부환경의 균일도를 향상시키고 있다. 본 연구는 느타리버섯 일부 시범 농가에서의 대류팬 작동방법 등 이용 실태를 조사하고, FCU를 가동하지 않은 버섯의 수확이 끝날 무렵이고 폐상 직전인 7.1－10까지 10일 간 느타리 균상재배사에 상향과 하향 등 양방향으로 번 갈아 바람을 토출하는 정역 제어 대류팬과 단일 방향인 상향으로만 바람을 토출하는 관행 방식의 유동팬을 설치하여 재배 사 내부환경의 균일도를 평가하고자 수행하였다. 조사 농가의 대류팬 작동방법(작동시간과 멈춤시간의 조합 방법)은 대부분 5－15분 작동 후 5－30분 멈춤을 반복적으로 적용하고 있는 것으로 조사되었으며 냉방장치를 가동하지 않은 폐상 무렵의 느타리 균상재배사에 정역 제어 대류팬을 설치하여 내부 환경 균일도를 평가한 결과, 최대 기온 편차는 1.4－1.8°C, 최대 상대습도 편차는 7.8－8.7%로 나타나 최대 기온 편차 3.2 －3.7°C, 최대 상대습도 편차 14.0－15.4%를 보인 관행 방식의 유동팬에 비해 내부환경 균일도가 향상된 것으로 나타났 다. 20가지의 정역 제어 대류팬 작동방법 중에서는 10－15분 간 상향으로 바람을 토출한 후 5－10분 간 멈추고 바람의 방 향을 바꾸어 하향으로 10－15분 간 바람을 토출하는 경우가 가장 적은 기온 편차(1.4－1.5°C)를 보였으나 센서의 오차범위 수준에 있어 설정별 차이를 보인다고는 판단할 수 없었다. 향후 버섯의 호흡이 온전히 고려되고 냉방장치가 가동되는 실제 재배기간 중 정역 제어 대류팬이 공기 균일도와 느타리버섯 품질에 미치는 영향을 평가할 필요가 있을 것으로 판단되었으며 재배사 내 공기교반 정도를 확인하기 위한 유동 가시화 연구가 필요할 것으로 판단되었다.

In this experiment, the engine (i30 FD) was fabricated and installed in front of the intake manifold of the gasoline engine of the 2010 1,600cc MPI(Multi Point Injection) 4-cylinder 16-valve DOHC(Double Over Head Camshaft) electronic control fuel injection system, and the plenum chamber was 150cc, 300cc, 4. The engine rotation speed was increased from 1000rpm to 3000rpm by 500rpm, and the pressure change and engine volume efficiency change of the air intake manifold runner were analyzed. In this study, the volume of air flowing into the cylinder was maximized through the stabilization of pressure vibration in the intake manifold runner part due to the engine operation condition and the volume change of the intake manifold plenum chamber, and the uniform distribution rate of the intake air was confirmed by minimizing the interference between the cylinders. It has in the purpose to analyze the flow characteristic at the intake manifold inside. It can apply to obtain the optimal design factor.