• 한국작물학회지
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• 제36권1호
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• pp.65-69
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• 1991

과맥에서 종자활력의 저하요인을 구명하고자 과맥 2계통(피, 과 isogenic line포함) 및 피맥 1품종의 종자의 수발아를 유도하여 손과 기계탈곡(700 rpm ) 한 종자를 이용하였다. 1. 수발아된 종자를 손 탈곡하여 배부분의 손상이 없어서 발아세, 발아율, TTC치은 수발아 정도에 따른 차이가 적었으나, 출아력은 수발아가 클수록 감소되었다. 2. 수발아된 종자는 기계탈곡시 배의 부분적인 손상이 관찰되었으며, 손 탈곡에 비해서 종자활력에 관계된 형질들이 고도로 유의적인 감소를 가져왔고 효소활력은 크게 증가되었다. 3 손 탈곡구에서 수발아 정도는 효소활력 ( r =0.9 31＊＊, 0.951＊＊) 및 발아력 ( r=0.46＊)과 정상관이 있었다.

• Journal of Biosystems Engineering
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• 제30권3호
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• pp.141-146
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• 2005

Worldwide consumption of vegetable soybean has been increasing recently, but, in the process of vegetable soybean production threshing and seperation work accounts for about $80\%$ of overall labor. Therefore, developing of the vegetable soybean thresher is necessary to reduce the cost of labor. The main objective of this study is to develop the vegetable soybean thresher which is suitable for domestic circumstances. The threshing and separating performance, operating cost, and field capacity of developed vegetable soybean thresher are investigated and analysed. The results are as follows. The effective field capacity of the developed vegetable soybean thresher was shown as 4.8hr/10a, and reduced as much as 11.7 times compared with human labor. The ratio of unthreshed soybean-pod to stem after threshing work was shown as $1.5\%$ and the damaged pod ratio of detached soybean was shown as $1.8\%$. The cost of human labor was shown as 2,560,000 won/ha, but the operating of the developed vegetable soybean thresher was shown as 503,000won/ha. If the vegetable soybean thresher would be used in our farm, the minimum cultivation area appeard to be 22.7a for the cost effective management.

• 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.

• Journal of Biosystems Engineering
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• 제35권6호
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• pp.380-386
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• 2010

This study was carried out to develop soybean thresher which is able to reduce the soybean threshing damage in comparison to the conventional thresher. A threshing cylinder with different diameter of 480 and 384 mm at each end and with one quarter disc pegs of 60 mm radius was developed and attached to the prototype thresher. A conventional thresher which has a threshing cylinder with $\wedge$ type threshing pegs and same diameter of 480 mm at each end was used for comparative test. A series of comparative performance test was conducted using sun-yu and chung-ja soybean. For sun-yu bean, which is white and usually used for soybean paste and soy sauce, the ratio of damaged beans of prototype ranged 2-3% for 330-360 rpm which is recommended cylinder speed by manufacturer. The ratio of damaged beans of conventional thresher was 3-4% for the same range of cylinder speed. chung-ja beans with black color usually shows high damaged ratio compared with white beans, thus cylinder speed of 250-300 rpm is recommended by manufacturer to reduce the damaged ratio. For this range of cylinder speed, the damaged ratio of prototype was 1.3-1.4% and it was 2.7-6.1% for the conventional thresher. Thus prototype is able to reduce the damaged ratio 1.5-5.0% compared with conventional thresher. Prototype shows 0.4% of unthreshed soybean ratio for sun-yu bean in the optimum range of cylinder speed and it was 0.87% for the conventional thresher. For chung-ja bean, the ratio of unthreshed soybean was almost same for both prototype and conventional thresher with the value of 4.0%. The reason of high unthreshed soybean ratio for chung-ja bean compared sun-yu bean is due to the high seed moisture content of 29.11% which is much higher than that of the recommended.

• 농업과학연구
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• 제8권2호
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• pp.224-230
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• 1981

충남농촌진흥원(忠南農村振興院) 포장(圃場)에서 표준시비법(標準施肥法)으로 재배(栽培)한 Japonica형(型) 품종(品種) 이이(裡里)348호(號), 이이(裡里)345호(號) 및 밀양(密陽)15호(號) 3개斗(個)와 Indica ${\times}$ Japonica hybrid형(型) 품종(品種) 밀양(密陽)23호(號), 이이(裡里)342호(號), 수원(水原)294호(號)의 4개(個), 계(計) 7 개(個) 품종(品種)에 대해 적정수확기간(適定收穫期間)을 중심(中心)으로 9월(月)28일(日)부터 10월(月)20일(日)까지 2일간격(日間隔)으로 3축방향(軸方向)에 대(對)하여 탈립저항력(脫粒低抗力)을 측정(測定)하였다. 10월(月)1일(日) 채취(採取)된 시료(試料)를 실험실(實驗室)에서 자연건조(自然乾燥)시키면서 함수율별(含水率別) 탈립증항력(脫粒拯抗力)을 측정(測定)하였다. 본(本) 연구(硏究)의 결과(結果)는 다음과 같다. 1. 외력(外力)이 지경(枝梗)과 평행방향(平行方向)으로 작용(作用)될 경우 Japonica형(型) 품종(品種)의 탈립저항력(脫粒低航力) 평균(平均) 113grdljTEk. 2. 외력(外力)이 지경(枝梗)과 $90^{\circ}$ 측방향(側方向)으로 작용(作用)될 경우의 탈립증항력(脫粒拯抗力)은 평행방향(平行方向)과 비교(比較)하여 Japonica형(型) 품종(品種)은 33~50%인 59.8~115.0gr이었고, Indica ${\times}$ Japonica hybrid형(型) 품종(品種)은 7~21%인 9.8~28.2gr으로 현저(顯著)히 작았다. 3. 기온(氣溫)이 영하(零下)로 강하(降下)하지 않은 본실험기간중(本實驗期間中) 예취일(刈取日)에 따른 탈립심지항력(脫粒甚至抗力)의 변화(變化)는 크게 없었다. 4. 예취후(刈取後) 자연건조(自然乾燥)에 따른 탈립심지항력(脫粒甚至抗力)은 함수율(含水率)의 감소(減少)와 함께 감소(減少)하였다. 5. 이삭 부위별(部位別) 탈립서항력(脫粒鼠抗力)은 상부측(上部側)에 비(比)해 하부측(下部側)에서 약간 큰값을 나타냈다.

• Journal of Biosystems Engineering
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• 제16권2호
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• pp.148-158
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• 1991

This study was undertaken to develop the feed rate control system for the head feed thresher by making use of the microprocessor and to evaluate the response of the system to a various threshing conditions. It was verified the performance of the control system through experiments. Control conditions were determined based on the simulation results of control system. The control system set at RH=500rpm, RL=480rpm for the bundle feed was considered optimum to give a high threshing capability and still to stabilize the feeding seed regardless of the bundle size. The control system for the continuous spread feed set at the range of LH=15mm, and LL=12mm gave a high control performance for the feeding mass of 1.1Kg/m and lower tested. In addition, the feed rate proportionality constant should be set lower than one in order to keep the rotational speed of threshing cylinder within the range of 500~520rpm.

• Journal of Biosystems Engineering
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• 제39권4호
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• pp.299-303
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• 2014

Purpose: This study set out to develop a machine for separating shatter-resistant sesame after threshing. Methods: Three grades of sieve and different blower speeds were tested for a separation system that had been designed specifically for shatter-resistant sesame. Performance tests were run to evaluate the sieve and blower systems in terms of the sesame separation and loss ratios. Results: Tests of the first separation stage using the sieve system revealed the optimum sieve perforation size to be 5 mm. Tests of the second separation stage using the blower system identified the optimum blower speed as being 220 rpm. The optimum separation and loss ratios, of 96.5% and 3.5%, respectively, were obtained at a blower speed of 220 rpm. Conclusions: These results will be useful for the design, construction, and operation of threshing harvesters. For shatter-resistant sesame, an optimum blower speed of 220 rpm was identified.

• Current Research on Agriculture and Life Sciences
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• 제21권
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• pp.23-29
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• 2003

Worldwide consumption of vegetable soybean bas been increasing recently, hence it is necessary to produce good quality of soybean in our farms. In the process of vegetable soybean production threshing and seperation work accounts for about 80% of overall labor. Therefore, developing of the vegetable soybean thresher is necessary to reduce the cost of labor. The purpose of this study is to acquire the basic informations to design of the vegetable soybeans-thresher. We make the experimental system which measure the physical properties and investigate the detachment forces. Also, We calculated the minimum speed of threshing cylinder. The result are as follows; 1. The average length of soybean stem is 68.2cm. 2. The length of soybean pods are seen as 61.3mm for 3 grain, 52.6mm fer 2 grains and 41.0mm fer 1 grain 3. The widths of soybean pods are seen as 14.1mm fer 3 grain, 13.8mm fer 2 grains and 13.4mm fer 1 grain. 4. The weights of soybean pods are seen as 4.1grams for 3 grains, 2.7grams for 2 grains and 1.4grams for 1 grain. 5. The average detachment forces of pods are seen as 1.5kgf for 3 grains, 1.2kgf for 2 grains and 0.8kgf for 1 grain respectively For 1 grain, the detachment force of pods ranges from 0.2kgf to 1.4kgf. For 2 grains, the minimum detachment force of pods is seen as 0.6kgf and the maximum one is seen as 2.5kgf. For 3 grains, the minimum detachment force of pods is seen as 0.7kgf and the maximum one is seen as 2.7kgf. 6. The minimum speed of threshing cylinder is shown 6.83m/s.

• 공연문화연구
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• 제38호
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• pp.111-142
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• 2019

새터가을굿놀이는 밀양시 초동면 신호리(일명 새터)에서 가을걷이를 할 때 부른 민요를 놀이와 결부시킨 것으로, 가을타작이 끝날 무렵 당산제를 지내고 풍년잔치를 벌인 것에서 유래한다. 새터가을굿놀이는 크게 세 마당으로 구성된다. 첫째마당은 도입부에 해당되는 1)입장굿, 둘째마당은 2)성황고사마당, 3)공상타작소리, 4)가을작마당, 5)뿍대기타작, 6)목메놀이 등의 놀이마당, 셋째마당은 7)판굿인 대동화합마당으로 구성된다. 밀양은 상원(上元)놀이와 중원(中元)놀이가 각각 무형문화재로 지정되어 있을 정도로, 농경의식이 발달하였다. 특히 하원놀이의 전승이 전국적으로 미약하다는 점에서 새터가을굿놀이의 전승적 가치는 매우 높다. 새터가을굿놀이의 전반적인 소리는 모두 메나리토리가 근간을 이루고 있으며, 경상도 민요의 특징을 잘 지니고 있다.

• Journal of Biosystems Engineering
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• 제5권1호
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• pp.1-14
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• 1980

Threshing operation may be one of the most important processes in the paddy post-production system as far as the grain loss and labor requirement are concerned . head-feeding type threshers commercially available now in Korea originally were developed for threshing dry paddy in the range of 15 to 17 % in wet basis. However, threshing wet-paddy with the grain moisture content above 20 % has been strongly recommended, especially for new high-yielding Indica -type varieties ; (1) to reduce high grain loss incurred due to the handling operations, and (2) to prevent the quantitative and qualitative loss of milled -rice when unthreshed grains are rewetted due to the rainfall. The objective of this study were to investigate the adaptability of both a head-feeding type thresher and a throw-in type thresher to wet-paddy , and to find out the possiblilities of improving the components of these threshers threshing. Four varieties, Suweon 264 and Milyang 24 as Tongil sister line varieties, minehikari and Jinhueng as Japonica-type varieties, were used at the different levels of the moisture content of grains. Both the feed rate and the cylinder speed were varied for each material and each machine. The thresher output quality , composition of tailing return, and separating loss were analyzed from the sampels taken at each treatment. A separate experiment for measurement opf the power requirement of the head-feeding type thresher was also performed. The results are summarized as follows : 1. There was a difference in the thresher output quality between rice varieties. In case of wet-paddy threshing at 550 rpm , grains with branchlet and torn heads for the Suweon 264 were 12 % and 7 % of the total output in weight, respectively, and for the Minehikari 4.5 % and 2 % respectively. In case of dry paddy threshing , those for the Suweon 264 were 8 % and 5% , and for the Minehikari 4% and 1% respectively. However, those for the Milyang 23 , which is highly susceptable to shattering, were much lower with 1 % and 0.5% respectively, regardless of the moisture content of the paddy. Therefore, it is desirable to breed rice varieties of the same physical properties as well as to improve a thresher adaptable to all the varieties. Torn heads, which increased with the moisture content of rall the varieties except the Milyang 23 , decreased as the cylinder speed increased, but grains with branchlet didnt decrease. The damaged kernels increased with the cylinder speed. 3. The thresher output quality was not affected much by the feed rate. But grains with branchlet and torn heads increased slightly with the feed rate for the head-feeding type thresher since higher resistance lowered at the cylinder speed. 4. In order to reduce grains with branchlet and torn heads in wet-paddy threshing , it is desirable to improve the head-feeding type thresher by developing a new type of cylinder which to not give excess impact on kernels or a concave which has differenct sizes of holes at different locations along the cylinder. 5. For the head-feeding type thresher, there was a difference in separating loss between the varieties. At the cylinder speed of 600 rpm the separating losses for the Minehikari and the Suweon 264 were 1.2% and 0.6% respectively. The separating loss of the head-feeding type thresher was not affected by the moisture content of paddy while that of the Mini-aged thresher increased with the moisture content. 6. From the analysis of the tailings return , to appeared that the tailings return mechanism didn't function properly because lots of single grains and rubbishes were unnecessarily returned. 7. Adding a vibrating sieve to the head-feeding type thresher could increase the efficiency of separation. Consequently , the tailing return mechanism would function properly since unnecessary return could be educed greatly. 8. The power required for the head-feeding type thresher was not affected by the moisture content of paddy, but the average power increased linearly with the feed rate. The power also increased with the cylinder speed.