• 한국토양비료학회지
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• 제47권1호
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• pp.23-27
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• 2014

Nutrient accumulation in surface soil has become a serious problem for cucumber production in greenhouse. However, still in many cases, soil management practices are only focused on maintaining crop yield, regardless of sustainability related with soil chemical properties. This study was conducted to propose a sustainable soil management practice by investigating the impact of cover crop species and nitrogen rate of fertigated solution on cucumber yield and soil chemical properties in greenhouse condition. Rye and hairy vetch were tested as a fallow cover crop, and each amount of urea (1/2, 3/4, 1 times of N fertilizer recommendations), determined by soil testing result, was supplied in fertigation plots as an additional nitrogen source. The result showed that the yield of cucumber was higher in rye treatment than control and hairy vetch treatment. In addition, rye effectively reduced EC and accumulated nutrients from the soil. Meanwhile, N concentration of fertigated solution showed no significant effect on the growth and yield of cucumber. Consequently, these results suggest that it is desirable to choose rye as a fallow catch crop for sustainable cucumber production in greenhouse.

• 한국응용곤충학회지
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• 제53권4호
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• pp.479-483
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• 2014

1990년대 초반 이후 국내 시설 원예작물 재배면적은 급격히 증가하였지만 농가당 재배면적은 협소하여 생산성 증대를 위한 생력관리기술개발이 절실히 요구되고 있다. 하지만 시설하우스에서는 해충들이 다발생하고 방제가 어려워 많은 양의 살충제를 사용하고 있어 생력재배를 어렵게 하고 있다. 또한 과도하고 부적절한 살충제의 사용은 저항성 해충의 출현과 농약중독이라는 문제를 야기하였다. 본 연구에서는 시설 재배 온실에서 무인 연무방제기를 이용한 목화진딧물(Aphis gossypii)과 복숭아혹진딧물(Myzus persicae)의 효율적 방제 가능성을 조사하였다. 무인 연무방제기를 가동시키는 동안 시설 내 측창과 출입구가 완전히 폐쇄된 조건하에서는 시설 내 상대습도가 높게 유지되었고(>95%) 관행방제 약제처리구와 유사한 방제 효과를 보였다(방제가 61.0~94.1%). 반면 무인 연무방제기 가동 시간 동안 측창과 출입구를 50% 정도 개방한 조건에서는 시설 내 상대습도가 상대적으로 낮았고(<95%) 측창과 출입구가 모두 폐쇄된 온실 조건보다 방제 효율이 낮았다(방제가 36.0~54.4%).

• 농업과학연구
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• 제40권4호
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• pp.317-323
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• 2013

This research was conducted to obtain the basic information for establishment of standard guidelines in the design and installation of roof ventilation system in single-span plastic greenhouse. To achieve this, the greenhouse structure & characteristics, cultivation status, and ventilation system were investigated for single-span greenhouse with roof ventilation system cultivating the Cucurbitaceae vegetables, watermelon, cucumber, and oriental melon. Most of single-span watermelon greenhouse in Haman and Buyeo area were a hoop-style and the ventilation system in those greenhouses mostly consisted of two different types of 'roof vent (circular or chimney type) + side vent (hole) + fan' and 'roof vent (circular type) + side vent (hole or roll-up type)'. The diameter of circular and chimney-type vent was mostly 60cm and the average number of vents was 10.5 per a bay with vent spacing of average 6.75m. The ratio of roof vent area to floor area and side vent area in the single-span watermelon greenhouse with ventilation fan were 0.46% and 7.6%, respectively. The single-span cucumber greenhouse in Haman and Changnyeong area were a gable roof type, such as even span, half span, three quarter and the 70.6% of total investigated single-span greenhouses was equipped with a roof ventilation fan while 58.8% had a circulation fan inside the greenhouse. The ratios of roof vent area to floor area in the single-span cucumber greenhouse ranged from 0.61 to 0.96% and in the case of the square roof vent, were higher than that of the circular type vent. On average, the roof ventilation fan in single-span cucumber greenhouse was equipped with the power input of 210W and maximum air volume of $85.0m^3/min$, and the number of fans was 9.75 per a bay. The number of roof vent of single-span oriental melon greenhouse with only roll-up type side vent ranged from 8 to 21 (average 14.8), which was higher than that of other Cucurbitaceae vegetables while the vent number of the greenhouse with a roof ventilation fan was average 7 per a bay.

• 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.

• 생물환경조절학회지
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• 제15권3호
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• pp.211-216
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• 2006

지열을 이용한 열펌프 시스템이 온실의 냉방과 과채류의 묘소질에 미치는 영향을 구명하였다. 온실 내 기온은 주간에는 차광구에 비해서 포그+차광구가 $3{\sim}4^{\circ}C$ 낮았고, 야간에는 지열-펌프+차광구가 차광 및 포그+차광구에 비해 $5{\sim}7^{\circ}C$ 낮았다. 오이, 고추 및 토마토 묘의 초장은 차광이나 차광+포그구에 비해 지열-열펌프+차광구가 가장 짧았고, 엽면적과 건물중은 지열-열펌프+차광구가 다른 처리에 비해 약간 작았다. 결과적으로 건묘지수는 지열을 이용하여 냉방을 한 지열+차광구는 포그+차광구 및 차광구에 비해 모두 높게 나타났다.

• 원예과학기술지
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• 제32권5호
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• pp.614-622
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• 2014

Melons (Cucumis melo L.) are generally grafted onto Cucurbita rootstocks to manage soilborne pathogens such as Monosporascus root rot and v ine decline (MRR/VD) and Fusarium wilt. However, g rafting onto Cucurbita rootstocks reportedly results in the reduction of fruit quality. In this study, the resistance to MRR/VD, yield, and fruit quality of melons grafted onto melon rootstocks were evaluated under greenhouse conditions. Eight melon rootstocks (R1 to R8) were used and the inodorus melon 'Homerunstar' was used as scion. Melon rootstocks R1 to R6 were selected based on resistance to MRR/VD under greenhouse conditions. Non-grafted 'Homerunstar' and plants grafted onto squash interspecific hybrid 'Shintozwa' rootstock (Cucurbita maxima D. ${\times}$ C. moschata D.) served as controls. Grafted melons were cultivated in the greenhouse infested with Monosporascus cannonballus during two growing seasons (summer and autumn). The responses to MRR/VD, yield, and fruit quality differed depending on the rootstocks and growing season. The melons grafted onto 'Shintozwa' exhibited less severe disease symptoms and higher survival rates than non-grafted melons in both seasons. While the melon rootstocks in the summer cultivation did not increase the survival rate compared to non-grafted melons, the melon rootstocks R1 and R2 in the autumn cultivation led to higher survival rates. The melon rootstocks resistant to MRR/VD increased the percentage of marketable fruits and marketable yields. Grafting onto the melon rootstocks caused little or no reduction of fruit quality such as low calcium content, fruit softening, and vitrescence, especially in lower-temperature autumn season. Accordingly, these results suggest that grafting onto the melon rootstocks may increase the tolerance to MRR/VD and the marketable yield without a reduction of fruit quality.

• 한국농공학회논문집
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• 제52권2호
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• pp.67-73
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• 2010

Unlike Urban building, horticultural facilities has a lot of heat loss through plastic or glass covering material which could be much influential to growing plant and consuming energy for heating greenhouse. In many cases, heat loss from a break of cover, a gap of joint sealing, the entrance to greenhouse and windows for ventilation are the main factors considered in calculating the heating load for horticultural facilities. however the normal observation through human eye and digital camera could not recognize where the heat loss occurred. but the infrared thermal image camera with detecting thermal difference could be very effective for noticing heat loss by analyzing infrared thermal image. In this study, greenhouse structure, covering material, internal and external provisions for Horticultural facilities were surveyed in different sites and Infrared thermal camera shooting and image analysis were performed for auditing heat loss from cultivation facilities The results from this study were that unexpected heat loss had been noticed in 7 representative cases of greenhouse such as side wall covered with single or double plastic, and the joint of horizontal thermal curtain, roof without horizontal thermal curtain, entrance to greenhouse, windows for ventilation. the most important factors for keeping heat energy were whether the horizontal thermal curtain with multifold thermal material was installed or not. The internal or external covering using multifold thermal curtain proved to be the most effective ways to keep heat energy from losing through heat transmission, heat radiation. from inside to outside the horticultural facilities.

• 식물병연구
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• 제20권4호
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• pp.264-269
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• 2014

시설오이와 상추 재배지에서 녹비작물의 종류에 따른 M. incognita의 생물학적 방제효과를 조사하였다. 시설오이 재배지에서 수단그라스 재배는 fosthiazate GR의 화학적 처리 효과와 유사한 88.6%의 살선충 효과를 보였다. 상추재배지에서 수단그라스의 재배는 토양중 93.5%의 M. incognita 밀도 감소를 보였다. 또한 수단그라스는 다른 녹비작물보다 매우 우수한 생육을 보였기 때문에 시설 재배지에서 M. incognita를 관리하는데 수단그라스가 적당한 것으로 생각된다.

• 생물환경조절학회지
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• 제12권4호
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• pp.195-199
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• 2003

계면활성제(SF316+FB0800)가 처리된 폴리에틸렌 필름 시설에서 직경 9cm 원안의 필름 표면에 부착된 수적량은 무처리구에서 1.21 mL, 1% 처리구에서 0.15mL, 2% 처리구에서 0.07 mL가 측정되었다. 그러나 육안으로는 1%와 2% 처리구 사이에 차이를 관찰하기가 어려웠다. 수적량은 하루 중 오전 10시에 가장 많았고, 기온의 상승된 오후 2시에 적었다. 무처리구에 비하여 계면활성제 1%와 2% 처리구 사이에 차이를 관찰하기가 어려웠다. 수적량은 하루 중 오전 10시에 가장 많았고, 기온이 상승된 오후 2시에 적었다. 무처리구에 비하여 계면활성제 1%와 2% 처리구에서 투광율은 각각 9.3%, 12.9% 높았다. 기온과 습도는 계면활성제가 처리된 비닐하우스와 머처리 비닐하우스 사이에 뚜렸한 차이를 나타내지 않았다. 오전의 기온은 계면활성제 처리 비닐하우스에서 1~2$^{\circ}C$ 정도 높았으며, 지온의 경우는 계면활성제 처리시설에서 3~4$^{\circ}C$ 정도 높은 경향을 나타냈다. 겨울철 상추의 생육은 계면활성제가 처리된 필름으로 피복된 비닐하우스에서 빨랐다. 그러나 계면활성제농도 1%와 2% 처리구 사이에는 뚜렸한 차이를 보이지 않았다.

• 한국태양에너지학회 논문집
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• 제32권6호
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• pp.60-67
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• 2012

Government Geothermal Cooling-Heating Projects has made efforts to reduce GHG(Greenhouse Gas) emissions and to manage cost of greenhouse farm households. This study evaluated the economic benefits of heating load rate of change by comparing Geothermal Cooling-Heating System with the existing system(greenhouse diesel heating) in the Government Geothermal Cooling-Heating Projects. Economic analysis results shows that, 1) When installing the Cooling-Heating system according to the ratio of 70% heating load in policy standards, the geothermal cooling-heating system has economic efficiency with greenhouse type or scale independent because the investment cost is recovered within 7 years. And It was more economic efficiency the ratio of 50% heating load than70% heating load. 2) When installing the Cooling-Heating system according to the glass greenhouse of the ratio of 90% heating load, pay period of investment cost is recovered within 5 years. Therefore it is necessary to apply flexible heating sharing according to greenhouse type or scale.