• 제목/요약/키워드: Greenhouse Horticulture

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적색과 청색광 수지를 첨가한 플라스틱온실 피복재의 광특성 및 토마토, 고추의 생육과 수량 반응 (Optical Properties, Growth and Yield of Tomato and Pepper under Greenhouse Covering Films with Different Red and Blue Resins)

  • 권준국;최영하;강남준;이재한;정호정;박진면
    • 한국생물환경조절학회:학술대회논문집
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    • 한국생물환경조절학회 2005년도 세계의 친환경 시설원예 기술동향 및 추계 국제학술대회 발표논문집
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    • pp.89-94
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    • 2005
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시설원예용 지열 및 태양열 이용 하이브리드 히트펌프 시스템의 난방성능에 관한 연구 (Study on Heating Performance of Hybrid Heat Pump System Using Geothermal Source and Solar Heat for Protected Horticulture)

  • 전종길;이동건;백이;김형권
    • 한국태양에너지학회 논문집
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    • 제35권5호
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    • pp.49-56
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    • 2015
  • In this study a hybrid heating system based on geothermal source and solar heat was developed in order to save energy for greenhouse heating and its field performance was evaluated. Developed system are composed of following parts: water tank, heat exchanger, heat pump, fan coil unit and heat storage unit. The working performance test was carried out in a greenhouse cultivating oriental orchids being managed by $23^{\circ}C$. Field performance test results showed that average heating coefficient of performance ($COP_h$) was 3.4 for the period from mid-January to mid-March 2013. Heating coefficient of performance ($COP_h$) of developed hybrid heat pump system was more sensitive to water tank temperature than outside air temperature. This study showed that developed hybrid heat pump system has a potential to save the heating costs up to 91% compared to conventional agricultural oil heaters.

Development of Semi-basement Type Greenhouse Model for Energy Saving

  • Kim, Seoung Hee;Joen, Jong Gil;Kwon, Jin Kyeong;Kim, Hyung Kweon
    • Journal of Biosystems Engineering
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    • 제41권4호
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    • pp.328-336
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    • 2016
  • Purpose: The heat culture areas of greenhouses have been continuously increasing. In the face of international oil price fluctuations, development of energy saving technologies is becoming essential. To save energy, auxiliary heat source and thermal insulation technologies are being developed, but they lack cost-efficiency. The present study was conducted to save energy by developing a conceptually new semi-basement type greenhouse. Methods: A semi-basement type greenhouse, was designed and constructed in the form of a three quarter greenhouse as a basic structure, which is an advantageous structure to inflow sunlight. To evaluate the performance of the developed greenhouse, a similar structured general greenhouse was installed as a control plot, and heating tests were conducted under the same crop growth conditions. Results: Although shadows appeared during the winter in the semi-basement type greenhouse due to the underground drop, the results of crop growth tests indicated that there were no differences in crop growth and development between the semi-basement type greenhouse and the control greenhouse, indicating that the shadows did not affect the crop up to the height of the crop growing point. The amount of fuel used for heating from January to March was almost the same between the two greenhouses for tests. The heating load coefficients of the experimental greenhouses were calculated as $3.1kcal/m^2{\cdot}^{\circ}C{\cdot}h$ for the semi-basement type greenhouse and $2.9kcal/m^2{\cdot}^{\circ}C{\cdot}h$ for the control greenhouse. Since the value is lower than the double layer PE (polyethylene) film greenhouse value of $3.5kcal/m^2{\cdot}^{\circ}C{\cdot}h$ from a previous study, Tthe semi-basement type greenhouse seemed to have energy saving effects. Conclusions: The semi-basement type greenhouse could be operated with the same fuel consumption as general greenhouses, even though its underground portion resulted in a larger volume, indicating positive effects on energy saving and space utilization. It was identified that the heat losses could be reduced by installing a thermal curtain of multi-layered materials for heat insulation inside the greenhouse for the cultivation of horticultural products by installing thermal curtain of multi-layered materials for heat insulation inside the greenhouse, it was identified that the heat losses could be reduced.

간척지에 플라스틱 온실 설치 시의 문제점 분석 및 개선방안 (An analysis of problems and countermeasures in the installation of plastic greenhouse on reclaimed lands)

  • 유인호;구양규;조명환;류희룡;문두경
    • 농업과학연구
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    • 제41권4호
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    • pp.473-480
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    • 2014
  • Upon setting up a dedicated plastic greenhouse for tomato cultivation developed by the Rural Development Administration on the Gyehwa reclaimed land, this study was aimed at analyzing the problems can be occurred in the installation of plastic greenhouse on reclaimed lands as well as finding out solutions for improvement. A relatively cheaper wooden pile was used in the installation in order to supplement the soft ground conditions. Based on the results of ground investigation of the installation site, both the allowable bearing capacity and pulling resistance of the wooden pile with a diameter of 150 mm and a length of 10 m were computed and came out to be 30.645 kN. It was determined that the values were enough to withstand the maximum compressive force (17.206 kN) and the pullout force (20.435 kN) that are generally applied to the greenhouse footing. There are three problems aroused in the process of greenhouse installation, and the corresponding countermeasures are as follow. First, due to the slightly bent shape of the wooden pile, there were phenomenon such as deviation, torsion, and fracture when driving the pile. This could be prevented by the use of the backhoe (0.2) rotating tongs, which are holding the pile, to drive the pile while pushing to the direction of the driving and fixing it until 5 m below ground and applying a soft vibrating pressure until the first 2 m. Second, there exists a concrete independent footing between the column of the greenhouse and the wooden pile driven to the underground water level. Since it is difficult to accurately drive the pile on this independent footing, the problem of footing baseplate used to fix the column being off the independent footing was occurred. In order to handle with this matter, the diameter of the independent footing was changed from 200 mm to 300 mm. Last, after films were covered in the condition that the reinforcing frame and bracing are not installed, there was a phenomenon of columns being pushed away by the strong wind to the maximum of $11m{\cdot}s^{-1}$. It is encouraged to avoid constructions in winter, and the film covering jobs always to be done after the frame construction is completely over. The height of the independent footing was measured for 9 months after the completion of the greenhouse installation, and it was found to be within the margin of error meaning that there was no subsidence. The extent to the framework distortion and the value of inclinometers as well showed not much alteration. In other words, the wooden pile was designed to have a sufficient bearing capacity.

플라스틱하우스의 보온피복 재료 및 방법이 보온력과 토마토의 생육 및 수량에 미치는 영향 (Effects of Covering Materials and Methods on Heat Insulation of a Plastic Greenhouse and Growth and Yield of Tomato)

  • 권준국;이재한;강남준;강경희;최영하
    • 생물환경조절학회지
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    • 제13권4호
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    • pp.251-257
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    • 2004
  • 본 연구는 몇가지 보온피복 재료 및 방법이 플라스틱하우스의 보온력과 토마토의 생육과 수량에 미치는 영향을 구명하고자 수행하였다. 다겹보온덮개(카시미론 8온스 1겹+폴리폼(1 mm) 4겹 +부직포 2겹+폴리프로필렌 1겹+흑색네트차광망 1겹)를 이중하우스 구조의 외면에 피복한 것이 이중하우스 구조의 내부에 피복한 것에 비해 하우스내 야간의 기온과 지온은 약 $ 낮았으나 광투과율이 높아서 토마토 상품수량이 약 $2\%$ 증가하였다. 그리고 다곁보온덮개를 피복하지 않고 이중하우스 구조의 내부에 EVA커튼을 설치한 것에 비해서는 하우스내 야간기온이 $3^{\circ}C$ 높게 유지되어 수확기가 약 1일 빨라지고 토마토 과실도$ 19\%$ 증수하였다. 한편 이중하우스 외면에 다겹보온덮개를 피복하고 내부에 보온커튼(알미늄+직물)을 설치한 것은 다겹보온 덮개를 피복하고 보온커튼을 설치하지 않은 것과 이중하우스에 다겹보온덮개를 피복하지 않고 EVA커튼만 설치한 것에 비해 하우스내 기온이 각각 $2.2^{\circ}C$$4.5^{\circ}C$ 높게 유지되었으며 이러한 보온효과에 의해 토마토 과실수량도 각각 $18\%$$37\%$ 가되었다. 따라서 본 연구결과는 남부지역에서 저온기에 다겹보온덮개를 이중 플라스틱하우스 구조의 외면에 피복하고 내부에 보온성이 높은 커튼자재를 사용하면 가온을 하지 않거나 최소한의 난방비로 토마토를 재배할 수 있음을 시사해 주었다.