• 한국작물학회지
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• 제43권1호
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• pp.54-58
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• 1998

Four introduced forage rape cultivars 'Akela', 'Ramon', 'Sparta', and 'Velox' and a leading rapeseed cultivar Hall-ayuchae were seeded on 1 October 1994 on 20-cm rows at seeding rates of 3, 5, 7, 10, 13, and IS kg/ha to select the best adapted forage rape cultivars and to determine the optimum seeding rate in the Cheju area. Days to flowering of each cultivar was not significantly affected by seeding rate. Average plant height increased from 151 to 164 cm as seeding rate increased from 3 to 10 kg/ha and then decreased to 156 cm at 15 kg/ha. Stem diameter linearly decreased with increasing seeding rate. The optimum seeding rate for the greatest dry matter and protein yields of five cultivars ranged from 10.7 to 11.8 and 10.8 to 14.4 kg/ha, respectively. Dry matter yields of five cultivars ranged from 7.72 and 22.01 Mg/ha. Sparta produced the greatest dry matter yield, followed by Akela, Ramon, Hallayuchae, and Velox. Crude protein yields of five cultivars ranged from 0.29 to 1.08 Mg/ha. Sparta produced the greatest crude protein yield, followed by Akela, Ramon, Velox, and Hallayuchae. As seeding rate increased, crude protein content linearly increased but crude fiber content linearly decreased. The forage cultivars had higher crude protein and lower crude fiber than the oilseed cultivar Hallayuchae. Our results demonstrate that Sparta was the best adapted cultivar to Cheju area and the optimum seeding rate for Sparta was about 10 kg/ha.

• 한국작물학회지
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• 제55권3호
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• pp.195-199
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• 2010

This experiment was conducted to develop optimum sesame cultivation practices as succeeding cropping system of watermelon in the greenhouse condition. We also compared major components in sesame seed cultivated in the greenhouse and open field condition. The adaptable varieties under the greenhouse condition were white sesame 'Pyoungan' and black sesame 'Jinki' which showed higher yield and disease resistance. We also conducted several experiments to determine optimum sowing date, planting density and pinching time. Grain yields were statistically different according to the several sowing dates. In general, sesame sowing on June 30th showed higher grain yields than July 10th, July 20th and July 30th in the greenhouse. We also found out sesame cultivation practice with the row spacing of 40 cm and interplant spacing of 30 cm (a few branch type) or 40 cm (many branch type) showed higher yield than other treatments. Optimum pinching time was 25 days after first flowering in main stem when thousand seed weight and grain yield were highest. In the comparison of major components of sesame at the different cultivation conditions, sesame seeds cultivated in the greenhouse contained 4% much more oil content than open field condition. The lignan compounds, sesamin and sesamolin were also higher by 6% in the greenhouse than open field condition. It was concluded that sesame cultivation practices as succeeding cropping system of watermelon in the greenhouse condition guaranteed higher grain yield with less labor input which is now emerging alternative farming practice system in present aging rural society and will also give sesame cultivation farmers to increase net income in Korea.

• 한국약용작물학회지
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• 제14권1호
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• pp.41-44
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• 2006

강활의 재배면적 136 ha 중에서 재배면적이 70%에 달하는 북강활의 노두번식 재배시 묘종의 정식적기를 구명하기 위하여 정식기를 3월 20일부터 10일 간격으로 5월 1일까지 정식하여 생육 및 수량을 조사한 결과는 다음과 같다. 1. 시험전 토양의 화학성은 비옥도가 중간정도인 보통밭이었다. 2. 재배 기간중의 3년간 평균기온은 3월 하순을 제외하고 평년에 비해 낮은 편이었으나 4월 중순 이후의 강우량은 많았다. 3. 정식시기가 빠를수록 출현율, 추대율이 높았으며 초장과 경장이 길고, 분지수가 많았으며 생육도 양호하였으나 경직경은 일정한 경향이 없었다. 4. 수량구성 요소들은 4월 1일 정식한 구에서 가장 좋았으며 수량도 251 kg/10g으로 3월 20일 정식한 구보다 13% 증수되어 정식적기는 4월 1일 전후가 적당할 것으로 생각된다.

• Journal of Biosystems Engineering
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• 제3권2호
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• pp.88-99
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• 1978

In this study, rice harvesting systems suitable to Korean situations and the optimum timing of these systems were determined, respectively, based on experimentally determined factors such as filed yield and the milling quantity and quality measured at various levels of the grain moisture content at harvest. Rice varieties used for the experiment were the AKIBARE (Japonica-type) and the SUWEON 251 (high yielding TONGIL sister-line variety), The harvesting systems studied by the experimental work of this study were traditional system with both the wet material and dry-material threshing system by use of binder with both the dry-material and wet-material threshings, and system by use of combine. Grain samples were taken from final products of the paddy rice harvested from the experiment a fields for each system to measure the recovery rates of the milled rice. The results may be summarized as follows; 1. The milling recovery rate of the AKIBARE variety had highest value within the range of the grain moisture at harvest, showing from 21 to 26 percent. The head-rice recovery for the same variety was a little greater in the wet-material threshing than in the dry-material threshing , higher values of which , were 20 to 25 percent , seen within the range of grain moisture at harvest regardless of the harvesting systems tested. 2. The milling recovery of the SUWEON 251 , when tested for different harvesting systems and harvesting grain moisture, did not show a statistically significant different. In contrast , head-rice recovery for the systems operated by the wet-material threshing was much greater than that by the -material threshing. The difference of the recoveries between these systems range from 2.6 to 4.7 percent. 3. An assessment of the optimum period of -harvest timing for each of the harve\ulcornersting systems tested were made bJ.sed on (a) the maximum total milled-rise yield and (b) the percentage reduction in the total milled-rice yield due to untimely harvest operations. The optimum period determined are: 23-19% for the ATD, AC, STD, SBW, STW systems, 25-21% for the ATW ani ABW systems, and 27-18% for the ABD, SBD, and SC systems, respectively.

• 약학회지
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• 제46권5호
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• pp.364-368
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• 2002

Optimal synthetic conditions of barium sulfate were investigated from the viewpoint of yield and bulkiness according to a randomized complete block design proposed by Box and Wilson. Barium chloride and Sodium sulfate were utilized as reactants in order to prepare barium sulfate in this study. The optimum Synthesis conditions of barium sulfate obtained from this study are as follows; Reactant temperature; 60~75$^{\circ}C$ (viewpoint of yield) and 60~71$^{\circ}C$ (viewpoint of bulkiness). Concentration of two reactants; 12.7~14.4％ (viewpoint of yield) and 5~10.5％ (viewpoint of bulkiness). Mole ratio of two reactants, [BaCl$_2$]/[Na$_2$SO$_4$]; 1.62~1.96 (viewpoint of yield) and 2.0 (viewpoint of bulkiness). Reacting time; 13~15 minutes (viewpoint of yield) and 12~14 minutes (viewpoint of bulkiness). Drying temperature of product; 86~10$0^{\circ}C$ (viewpoint of yield) and 6$0^{\circ}C$ (viewpoint of bulkiness).

• KSBB Journal
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• 제14권6호
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• pp.639-642
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• 1999

키토산 올리고당을 보다 효율적으로 생산하고자 효소와 기질간의 특성을 조사한 다음, 이를 바탕으로 기질을 단계별로 첨가하여 생산 효율을 높일 수 있었다. 본 실험에 사용된 효소의 안정성을 조사한 결과 pH 5.0에서 6일 후에도 약 90% 이상의 효소활성을 유지하였다. 기질이 초기 농도에 따른 겉보기 수율은 0.5~2% 키토산 용액은 약 90% 이상이었으며, 그이상의 농도일 경우 감소하였다. 그래서, 수율을 증가시키기 위해 초기 반응 속도 및 겉보기 수율이 높은 기실 농도에 기질을 단계 별로 첨가한 결과, 분해 반응에 있어 겉보기 수율은 64.6%에서 83.2%로 증가하였고, 이에 따라 키토산 올리고당의 생산량은 10.52 mg/mL에서 12.26 mg/mL로 증가하였다. TLC분석 결과 Batch type과 기질을 단계별로 첨가하였을 경우의 올리고당 조성은 주로 3-5당이었다. 키토산 올리고당 생산을 위한 최적의 반응 조건은 pH 5.0, 40$^{\circ}C$에서 초기 반응 속도 및 수율이 높은 기질 농도인 2% 키토산 용액에 기질을 3시간마다 첨가할 때였다. 반응 시간에 따른 기질의 양과 효소를 보다 더 최적화하여 키토산 올리고당의 최종 농도와 겉보기 수율을 증가시킬 수 있었다.

• 한국자원식물학회지
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• 제10권4호
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• pp.382-385
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• 1997

미역취의 재배기술 확립을 위하여 육묘일수에 따른 생육특성, 추대율 및 수량성을 시험하여 얻어진 결과를 요약하면 다음과 같다. 1. 육묘일수에 따른 생육은 재배년수와는 무관하게 60일 육묘와 70일 육묘에서 초장, 분기수가 40일 육묘와 50일 육묘보다 양호하였다. 2. 육묘일수별 추대반응은 1년차의 경우 40일 육묘와 50일 육묘에서 추대율이 각각 14.5%, 13.5%로 나타난 반면 60일 육묘와 70일 육묘에서는 추대주가 없었다. 3. 육묘일수별 생엽수량은 육묘일수에 따라 다소 수량차이는 있었지만 전반적으로 60일 육묘가 가장 높은 수량성을 보였다. 4. 재배년수에 따른 추대율은 2년차 재배보다 평균적으로 3년차 재배에서 낮아졌으며 생엽 수량은 38% 증가되었다. 5. 미역취의 추대에 따른 적정 수량확보를 위한 적정 육묘일수는 60일정도 육묘하여 재배하는 것이 유리한 것으로 판단되었다.

• Journal of Biosystems Engineering
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• 제3권1호
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• pp.20-36
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• 1978

The effect of binder kicking forces on the shattering losses of paddy rice, which has been widely understood as an outstanding loss factor in harvesting with a binder, were experimentally assessed in this thesis.Through the field tests the optimum time of harvest, in terms of grain moisture contents, was found by considering harvesting losses for two rice varieties, harvested by two different binders, at four or five grain moisture levels.A device was designed and manufactured to apply various kicking forces to the bundles and was used in the bundle kicking tests. It was intended to find out the optimum range of kicking force to minimize the kicking losses. Based on the study, modification of the existing binder kicking mechanism was suggested. The following is a summary of the results of this thesis. 1. In Suweon 258 variety, as the grain moisture content is reduced, so the cutting loss and the kicking loss increase. The grain losses range from 0.77 to 0.82 percent of total field yield for the cutting loss, from 1.83 to 2.01 percent for the kicking loss, and from 2.60 to 2.83 percent for the field loss, when the moisture content is about 22 percent. 2. In Jinheung variety , the field losses increased as the grain moisture content decreased . When the moisture content was 20 percent, the field loss, cutting loss and kicking loss was 0.42-0.49 % , 0.30-0.35, and 0.12 -0.14% of the total field yield, respectively. 3. The difference in the field loss , cutting loss, and kicking loss for the two binders was 0.23% , 0.05% and 0.18% respectively in Suweon 258 variety, and 0.07% , 0.02% and 0.05% respectively ini Jinheung variety. The grain losses for binder B were slightly higher than those for binder A. 4. In the statistical analysis of each variety , the kicking force and the moisture content of the grain, and its interaction were all highly significant at 1% level by T test .The optimum kicking force was found to be in the 3.0-0.4kg range. This does not interrupt the binder operation, while ioses are kept to an acceptale level. 5. To reduce the kicking force of the eXlstmg binder mechanism, the speed of rotation of the kicking arm needs to be redued by increasing the number of driving sprocket teeth, and the position and gear ratio of the knotter-bill and driving bevelgear have to be change to give a !motter-bill speed of 1110 rpm. It is also desirable to attach a belt conveyor which smoothly carries the bundle to the ground. 6. The optimum harvesting time cased on maximum field yield was found to be at a grain moisture content of around 22 percent for Suweon 258 variety, and 20 percent for Jinheung variety. Tota] field yield and field yield at the time amounted to 9, 812.5 kg/ha, 9, 302. 5kg/ha respectively for the Suweon 258, and 7, 819.5 kg/ ha, 7, 158.7 kg/ha respectively for the Jinheung variety.

• 한국토양비료학회지
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• 제18권2호
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• pp.208-214
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• 1985

수원지방(水原地方)의 농가포장(農家圃場)에서 1978년(年)~83년(年) (6개년(個年)) 식양토(埴壤土)인 보통답(普通畓)에서 수도품종별(水稻品種別) 질소(窒素) 시비반응(施肥反應) 및 질소(窒素) 생산효율(生産效率) 등(等)을 검토(檢討)하였는바 그 결과(結果)를 요약(要約)하면 다음과 같다. 1. 2차회귀식(次回歸式)을 적용(適用), 최다수량(最多收量)을 생산(生産)하기 위(爲)한 질소시비(窒素施肥) 최적량(最適量)은 13.9g~28.0kg/10a 범위(範圍)로 품종(品種)에 따라 차이(差異)가 크므로 질소내비성(窒素耐肥性)을 고려(考慮)하여 품종(品種)을 선정(選定), 재배(栽培)함이 필요(必要)하였다. 2. 질소(窒素) 시비최적량(施肥最適量)이 높았던 품종(品種)에서는 수확기(收穫期) 질소함량(窒素含量)(경엽(莖葉)) 및 총질소(總窒素) 흡수량(吸收量)(경엽(莖葉)+곡실(穀實))이 증가(增加)하였으나 최적량(最適量) 시용시(施用時) 시비(施肥) 및 흡수질소(吸收窒素)의 생산효율(生産效率)과 질소이용율(窒素利用率)은 오히려 감소(減少)하였다 3. 품종별(品種別) 무질소구(無窒素區) 정조수량(正租收量)에 대(對)한 질소(窒素) 최적량(最適量) 시용시(施用時) 정조수량(正租收量)의 증수효과(增收效果)를 증수율(增收率)로서 볼 때 29~121%의 범위(範圍)로서 품종간(品種間) 질소응수(窒素應酬)의 차이(差異)가 현저(顯著)하였다. 4. 질소(窒素) 최적량(最適量) 시용시(施用時) 질소응수(窒素應酬)가 큰 품종(品種)은 수확기(收穫期) 총질소(總窒素) 흡수량(吸收量), 시비(施肥) 및 흡수질소(吸收窒素)의 생산효율(生産效率)과 질소이용률(窒素利用率)이 높았다.

• 대한화학회지
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• 제56권2호
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• pp.257-263
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• 2012

The selection of suitable delignification conditions and optimization of process variables is crucial to the successful operation of chemical pulping processes. Soda pulping of Carpolobia lutea was investigated, as an alternative raw material for pulp and paper production. The process was optimized under the influence of three operational variables, namely, temperature, time and concentration of cooking liquor. Equations derived using a second - order polynomial design predicted the pulp yield and lignin dissolution with errors less than 8% and 11% respectively. The maximum variations in the pulp yield using a second order factorial design was caused by changes in both time and alkali concentration. Optimum pulp yield of 43.87% was obtained at low values of the process variables. The selectivity of lignin dissolution was independent of the working conditions, allowing quantitative estimations to be established between the pulp yield and residual lignin content within the range studied.