차광도포제 처리는 시설하우스 내부의 고온 제어를 위한 유용한 관리 방법 중 하나로 이용되고 있다. 우리나 라 포도과원에 설치된 비가림 시설은 강우를 방지하여 병 발생을 예방하는 독특한 시설로 여름철 고온 피해를 받을 가능성이 높다. 본 시험에서는 포도 비가림 시설 아래의 과도한 고온을 회피하기 위해 차광도포제의 농도를 달리하여 비가림 비닐 외부에 처리하였다. 그 결과 35% 차광도포제 처리는 비가림 비닐 아래의 PPFD (광합성 광양자 자속 밀도)의 45%를 감소시켰다. 또한 35% 차광도포제 처리는 무처리 대비 과방부위 온도를 2oC를 낮추는 결과를 나타냈다. 차광도포제 처리는 포도 비가림 시설에서 유의하게 온도를 낮추는 효과가 확인되었지만 주변 온도보다 낮은 온도로 제어 할 수는 없었다. 자연적으로 제거되는 35% 차광도포제 처리는 우리 나라의 포도 비가림 시설내의 여름철 과도한 열 손상과 과일 품질 저하를 방지하는 방법으로 활용할 수 있다.
노지 포도재배는 강우에 직접 노출되어 열과와 병 발생이 많아진다. 그래서 도입된 것이 간이 비가림 재배이지만, 이것 역시 열과와 병 발생을 예방하는데는 한계가 있다. 따라서 간이비가림 시설의 문제점을 보완하기 위해서 완전하게 강우를 차단하면서 자연적인 환기가 가능한 비가림 시설을 개발하여 적설하중과 풍하중을 내재해 규격에 맞추었다. 개선된 비가림 시설의 특성을 검증 하기 위해서 100m2 규모의 시설을 설치한 다음 관행 비 가림 시설과 시설 내외부 온도 분포와 그에 따른 포도 캠벨얼리의 품질, 갈반병 발생 및 열과율 등을 조사하여 비교하였다. 관행 비가림 시설과 개선된 비가림 시설의 온도 조사 결과 외기온이 34oC 이상일 경우 시설 내부온도가 관행 최대 40.7oC, 개선 시설은 37.4oC로 측정되어 개선 시설이 3정도 낮았고, 32oC 이하에서는 관행과 개선 시설 간에 온도 차이가 없었다. 과실 품질은 개선된 비가림 시설이 관행 비가림 시설보다 당도와 상품과율이 높았다. 개선된 비가림 시설이 관행에 비해 열과율과 갈반병 발병율이 현저히 낮았다.
본 연구는 참다래 비가림 시설재배에서 인공수분이 착과 및 과실품질에 미치는 영향과 안정적인 착과를 위한 유효수분기간을 확인하고자 수행하였다. 또한 최근 참다래 재배농가들에서 많이 수행되고 있는 현탁액을 이용한 인공수분의 효과를 확인하고자 하였다. 인공수분은 비가림 시설재배에서뿐 아니라 노지재배에서도 참다래의 착과량이 개선되었으며 중량증가와 당도향상의 과실품질 개선효과가 확인되었다. 유효수분기간 확인을 위하여 만 개 후부터 매일 7일간 인공수분이 수행되었다. 과실의 착과율, 과실당 종자수, 그리고 과실생장량은 만개 후 4 일까지 차이가 나타나지 않았으나 만개 후 5일부터는 분명하게 감소하였다. 결과적으로 참다래 비가림 시설재 배에서 유효수분기간은 만개 후 4일 이내로 나타났다. 또한, 현탁액을 이용한 인공수분은 석송자를 이용한 것과 착과량과 과실품질의 차이를 나타내지 않았다. 따라서, 화분 현탁액을 이용한 인공수분은 참다래 재배에서 노동력을 절감할 수 있는 매우 효율적인 수분방법이 될 수 있을 것이다.
본 연구는 나리 인편자구 포장정식 시 재배시설에 따른 바이 러스 감염률 등을 조사하여 포장 구근생산체계를 확립하고자 하 였다. 맹아률은 비가림하우스 및 망실하우스에서 높았으며, 품종 별로는 ‘Yelloween’이 ‘Star Gazer’보다 높았고 ‘Yelloween’ 의 망실하우스에서 맹아률은 90.3%였다. 총생체중 및 구근특성 도 ‘Yelloween’이 ‘Star Gazer’보다 높았으며 ‘Yelloween’ 노 지 정식구에서 총생체중은 15.8g이었으며 구중은 10.7g으로 가장 양호하였다. 진딧물 비래의 최성기는 5월이었고 노지 38마리 에 비해 비가림 및 망실에서 8마리, 2마리로 월등히 낮았으며, 바이러스 이병률은 CMV가 LSV보다 높았으며 노지에서 CMV 이병률은 17.8%로 비가림 및 망실보다 4배 이상 높았다. Pyrethroid처리는 250mg • L-1이상에서 바이러스 방제효과가 있 었다.
본 연구는 표준 개방한우사 설계도에서 제시된 처마의 길이보다 짧게 개방한우사의 처마가 시설되었을 때 지붕의 기울기와 동일하게 처마를 연장하는 것과 기둥 위치에서 수직으로 비가림시설을 하는 경우, 어느 우사가 우의 더위 스트레스 경감, 우방 바닥 건조, 비 들이침 및 환기효율에 더 유리한지를 규명하기 위하여 표준길이의 처마와 3종의 비가림 시설을 대상으로 computational fluid dynamics (CFD) 시뮬레이션기법을 이용하여 수행하였다. 여름철의 평균 풍속인 1.2 m/s에 근거하여 시뮬레이션을 한 결과, 여러 형태로 수직 비가림시설을 설치하는 것보다 표준 처마길이로 시공하는 것이 환기 및 풍속분포가 양호하였다. 따라서 수직으로 비가림시설을 하는 것보다는 축사 표준설계도에 제시된 처마 길이 정도까지 지붕의 기울기와 같게 처마를 연장하는 것이 유리하다.
1. 시설형태별 온도분포는 Type 1의 경우 지붕의 환기구가 없기 때문에 중력환기는 거의 일어나지 않고, 풍력환기에만 의존하게 되므로 풍속이 약한 경우는 온도가 상승하였다. Type 2 및 Type 3는 지붕의 환기구를 통하여 중력환기가 일어나기 때문에 대체로 온도 분포도 균일한 편으로 나타났다. 2. 시설형태별 평면 광분포는 Type 1가 가장 높고 Type 2, Type 3순으로 나타났다. 즉 일사투과율에 의한 지면 일사 도달율과 직접적으로 관련되기 때문에 Type 1, Type 2, Type 3순으로 지면온도 상승에 영향을 주었다. 3. 환기모델과 열수지 모델을 도입하여 환기량 및 실내온도 변화를 구한 결과, 시설형태별 풍속의 변화에 따른 내외기온차 변화는 Type 1이 가장 크고 Type 2, Type 3순이었다. Type 1의 경우 다른 형태에 비하여 풍속이 1 ㎧로 증가하면 급격히 내외기온차가 감소하였다. 4. 실측치를 사용하여 모델에 의한 풍속변화에 따른 환기량의 변화를 추정한 결과, Type 3 및 Type 2가 상대적으로 Type 1보다 낮은 경향을 나타냈다. 5. 전체적으로 개량형인 Type 2 및 Type 3은 관행형인 Type 1보다 효율적이라고 판단된다. 특히, 성력화의 차원에서 보면 Type 3이 Type 2보다 월등히 우수하기 때문에 자연적인 강우차단 능력이 보장된다면 Type 3이 Type 2보다 효율적이라고 사료된다.
Background : The use of the rain shelter facility gets more prevalent in the Ginseng cultivation area these days. This study is designed to establish a technique for the stable cultivation of Ginseng in the rain shelter facilities in high temperature (above 30 ℃) without the damage from high temperature Methods and Results : This study was carried out on 3-year Ginseng roots in 2016 in order to find out how to stably cultivate Ginseng in high temperature without suffering the high temperature damage during the cultivation of Ginseng under rain shelter facilities. The rain shading materials were coated with scattering film (scattering film + black shading net 90%), bluish white double-sided film (shading 85%) and PE film (PE film + black shading net 90%). The damage reduction by high temperature was made to the scattering film and bluish-white double-ended film only. An aluminum screen (shading rate: 40%) was installed when the high temperature (above 30℃) was reached while the isoprene (solution of 2000 times) was sprayed 4 times every 7 days from the full development stage. The light transmittance was 12.6 - 13.4% for the scattering film, 10.5 - 10.8% for the bluish-white double sided film and 7.1% for the PE film in the first coating while it was 7.3% for the scattering film and 7.1% for the bluish-white double-sided film when the aluminum screen was installed in high temperature. The high, average and low values in the relative humidity were higher inside the facility than in the outside during the survey period. The area of leaf was the largest under the scattering film. The area of leaf was the largest for the scattered film under the aluminum shade of 40% shading followed by that of spraying of isoprene 4 times, and that of the no-treatment. As for the growth under ground, the growth of underground shoots increased by 40% in aluminum screen, 53.7% in shading and 26.1% in the spraying of isoprene 4 times than non-shading while there was no difference among other rain shelter materials. Conclusion : The result of the research showed that when the scattering film is selected as the rain shelter material film for the cultivation of Ginseng, it is necessary to shade the sunlight as much as 40% by using the aluminum screen or the shading net to reduce the high temperature damage.
Background : Ginseng rain cover farming is expanding around Jinan county and Jangsu country of North Jeolla Province. Some farmers doing ginseng rain cover farming have suffered from difficulties due to hot weather damages. However, it is a situation that the study on mitigation techniques for high temperature damage do not exist with ginseng rain cover farming. Methods and Results : The test covering work was firstly done on April 28th for heat block film+90% black light blocking net, blue double sided film, and PE film+75% black light blocking net and when it comes to second treatment, 30% and 40% shading were implemented for heat block film group and blue double sided film group respectively and 75% black light blocking net was installed on PE film+75% shading group. When it comes to micro-climate measurement in rain cover facility, temperature, humidity and light intensity were measured during the growing period of ginseng. The results are as follows. Regarding the light transmittance (per PAR, 10 am in clear day) in facility with 1st covering, light block film covered group (LBF), blue double sided film group (BDF) and PE film group have 12.9±1.8%, has 11.6±1.0% and 27.1±1.1% respectively and after 2nd covering, in LBF groups, 30% blocking, 40% blcoking and no blocking have 10.6±1.3%, 8.2±0.9% and 12.9±1.8% and in BDF groups, 30% blocking, 40% blcoking and no blocking have 9.4±0.8%, 7.9±0.7% and 11.6±1.0 respectively and PE film group has 10.6±0.7%. Relative humidity also showed the same trend as temperature. The average monthly amount of light and maximum light intensity were lower in 30% and 40% light blocking groups of LBF and BDF and a little higher in no light blocking group compared to PE film group. The degree of high temperature damage was 1 in no LBF of BDF, but no LBF of LBF was so bad like 3. However, there was no high temperature damage in the test groups of blocking films or BDF with 30% and 40% light blocked light screens. Regarding root weight, all secondly treated groups of LBF group and BDF group were lighter compared to 4.36g of PE film group and especially, prism sheetof no light blocking group has 2.5g and BDF of of no light blocking group has 3.21g. 30 % and 40% light blocking groups of LBF group and BDF group were light with 3.20~4.07g. Conclusion : Regarding the analysis result on micro-climate in facility with different cover materials for 2 years old ginseng in ginseng rain cover farming of Gyeonggi Province, the covering method suitable for high temperature damage mitigation in ginseng rain cover farming was that 1st covering was done by PE film+75% black light blocking net and then 75% black light blocking net is additionally covered at a time when outside temperatures reaches 30℃.
Background : The production of healthy ginseng seedling is a critical part of growing 5-6-year-old fresh ginseng. Recently, for the problem of replant failure, it becomes more and more difficult to find first planted field for ginseng seedling cultivation. In this situation, This study was conducted to examine the possibility of seedling production practices of ginseng by utilizing the multi-beds cultivation system as a way to produce ginseng seedling stably. Methods and Results : This experiment was conducted by installing a 3-layed cultivation beds using 50㎜ sandwich panels. As the 1st and 2nd beds get insufficient amount of light, fluorescent lights were installed in 2 rows to further lighten up. And the 3rd bed used natural light. The bed soil used was formulated by mixing saprolite, yakto and peat moss. The control was cultivated under natural light on 1-layed bed with commercial bed soil for ginseng seedling. The commercial bed soil had pH 7.24, higher than the standard of permission, 6.5; and its calcium and sodium contents were 10.7, and 0.85 cmol+/㎏, respectively, higher than the standard. The available phosphate concentration was 34.0㎎/㎏, lower than the appropriate level of 100 ㎎/㎏. The mixing bed soil also had pH 7.69, higher than the standard but its nitrate and phosphate were within the appropriate range. The intra-facility light quantities of the 1st and 2nd beds were constant at around 100 μmol during days. But the light quantity of the 3rd bed was 51.4 μmol in average daily value. The roots of the 1st-3rd beds were found to weigh 0.58 – 0.73 g while those of the control group, about 0.47g to show heavier root weight of the multi-beds cultivation ginseng than that of the control. As for the yield, the control showed 145 ㎏/10a whereas the 1st-3rd beds showed higher levels between 183 – 228 ㎏/10a. Conclusion : In the multi-beds cultivation of ginseng seedling, fluorescent lamps seem to have provided sufficient light as an artificial light source. The soil for ginseng seedling production is different from ginseng cultivation field soil, additional study will be also necessary to set up the physiochemical range of bed soil for ginseng seedling.
Growth of 6-year old ‘Niitaka’ pear (Pyrus pyrifolia Nakai) trees and control of insect and disease occurrences were compared between fermented soybean extracts and rain-shelter system for two years. Foliar application of fermented soybean extracts was applied at 6 times as a pre-experiment in the open-field in 2013, with a rain-shelter system in 2014. Fermented soybean extract treatment increased foliar concentrations of approximately 0.46% T-N, 0.17% K, 0.19% Ca, and 0.06% Mg in 2013 compared to the control, with similar macro-nutrients between the control and soybean extract treatment observed in 2014. Rain-shelter system increased foliar concentrations of T-N, Ca, and Mg compared to the open-field. There were no significantly different between the control and soybean extract treatment for number of leaves per fruit, leaf dry weight, phytotoxicity, and completed shoot growth on August during the two years. Rain-shelter system increased leaf dry weight and did not affect phytotoxicity in the leaves. Fruit quality parameters were mostly similar to control and soybean extract treatment for two years, with higher fruit firmness observed for soybean extract treatment. Rain-shelter system advanced 4 days of harvest dates, and increased approximately 7.0 ton fruit yield per ha, 20 g mean fruit weight, and fruit soluble solid contents compared to open-field in 2014. Soybean extract treatment little suppressed occurrence of disease and insect on the leaves and fruits in both years. Rain-shelter system increased occurrence of Venturia nashicola on the leaves and to 63.8% of Gymnosporangium asiaticum on the fruits in 2014. Strong winds and storms in May elevated relative humidity in the rain-shelter system and caused high infection of the disease occurrence, requiring for an additional green control method. Soybean extract treatment little affected tree growth and would have initiated for a long-term study to evaluate tree physiological characteristics. Rain-shelter system improved fruit productivity and advanced harvest dates, which could have been more effective facility at a Thanks Giving Day between middle and end of September.
Background: The purpose of this study was to evaluate methods to reduce seeding expenses, thereby increasing farm income. This study investigated the effects of rain shelter controlled cultivation and adapted seeding times on the stable seed production of Scutellaria baicalensis Georgi. Methods and Results: Seed germination was conducted under 10 condition compose to control, water washing, cold storage at 4℃ for 15 days, seed sterilization with a benomyl pesticides, hormone treated seed by submerging in 100 ppm GA3 with the cold storage at 20℃ and 25℃, darkness in a covered petridish and illuminated with a 1,500 Lux lamp. There were three cultivation type, open cultivation with non-woven fabric mulching, cultivation with a vinyl covering and rain sheltered in a plastic greenhouse. Sowing dates were April 27, May 18, June 7 and June 28, 2013. Plants were spaced 10 ㎝ apart in rows 30 ㎝ apart. Mixed oil cake fertilizer, N-P2O5-K2O (12-10-10) was applied at 600 ㎏• 10 a−1. Conclusions: Optimum germination occured in darkness at 25℃ and cold storage after submerging in GA3. The highest seed yields (4.5 ㎏• 10 a−1) occurred in the plastic greenhouse for the April 25 sowing. The highest root yield (17%) was found on April 1, under greenhouse conditions.