• 수산해양기술연구
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• 제22권3호
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• pp.23-28
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• 1986

This paper describes on the measurement of the deck vibration produced by the main engine vibration of stern trawler MjS SAE-BA-DA (2,275GT, 3,600PS) while the ship is cruising and drifting. The obtained results are as follows; 1. The deck vibration level was the highest point at vertical line which pass main engine and the lowest point at vertical line which pass top bridge while the crusing. 2. The vibration source level of the main engine, screw shaft and screw propeller were respectively 110, 90 and 80% while the crusing. 3. The main deck vibration pressure level at the check points 2, 20, 30, 40, 60, 70, 80, 86m from the bow to stern was respectively 9, 8, 7, 10, 22, 45, 18, 23%. 4. The frequency distributions of the rr.ain engine, screw shaft, screw propeller vibration were from 3 Hz to 10 KHz, predominant frequency was 1 KHz, each vibration accelration the highest level were respectively 1. 3, 0.8, 0.5 $mm/s^2.$ 5. The predominant frequency distributions of the main deck, second deck, bridge deck and top bridge deck-s vibration were from 10 to 30 Hz, and each vibration accelration level were respectively 0.7, 0.05, 0.07, 0.04 $mm/s^2.$

• 어선
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• 제29권
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• pp.15-20
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• 1986

This paper describes on the measurement of the deck vibration produced by the main engine vibration of stern trawler MIS SAE-BA-DA (2,275GT, 3,600PS) while the ship is cruising and drifting. The obtained results are as follows; 1. The deck vibration level was the highest point at vertical line which pass main engine and the lowest point at vertical line which pass top bridge while the crusing. 2. The vibration source level of the main engine, screw shaft and screw propeller were respectively 110, 90 and 80% while the crusing. 3. The main deck vibration pressure level at the check points 2, 20, 30, 40, 60, 70, 80, 86m from the bow to stern was respectively 9, 8, 7, 10, 22, 45, 18, 23%. 4. The frequency distributions of the main engine, screw shaft, screw propeller vibration were from 3Hz to 10KHz, predominant frequency was 1KHz, each vibration accelration the highest level were respectively 1.3, 0.8, 0.5mm/$S^2$. 5. The predominant frequency distributions of the main deck, second deck, bridge deck and top bridge deck's vibration were from 10 to 30Hz, and each vibration accelration level were respe¬ctively 0.7, 0.05, 0.07, 0.04mm/$S^2$.

• 한국해양공학회지
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• 제12권1호
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• pp.135-142
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• 1998

In this study, the frequency transfer function of motions are predicted from the result of a full-scale seakeeping trials. Because the real sea has the characteristics of multi-directional waves,we compare the results in the one directional waves with ones in the directional waves. For calculation of the frequency transfer function in the directional waves, Takezawa's inverse estimation method was introduced and the frequency ranges were divided into three parts in order to consider following seas. The full-scale seakeeping trials was executed in the south sea of Korea using the stern trawler. Those results show that analysis method of the multi-directional waves is more reliable than that of one directional waves, and confirm the possibility of applying this method to the full-scale seakeeping trials.

• 수산해양기술연구
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• 제33권3호
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• pp.189-193
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• 1997

We make an ultrasonic system as a trial to measure the distance between trawl doors, and carried out a water tank ($24{\times} 24$m, water depth 1 m) experiment for confirming the practical use of the system in October 1996. This system calculates the distance between the pinger (50 kHz) and the transponder (50 kHz/70 kHz) attached each one on the trawl door by measuring the time-difference of receiving with two channels receiver on the trawler. This paper assums that both the length of the warp from the stern to the trawl door is same. At results the system shows a good relation between the distance and the time-difference of receiving while the location of the pinger is moved in variously in the water tank, and it was found that the method of measuring techniques on the prototype system could be applied to the measurement of the trawl door opening in the field experiment.

• 수산해양기술연구
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• 제46권4호
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• pp.476-486
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• 2010

Fishing efficiency of a trawl vessel can be enhanced by increasing the swept area per unit time, which can be attained either by increasing the mouth size of the net, or by increasing the towing speed. To improve fishing and fuel efficiency of trawl vessels targeting fishes of greater mobility, in which the towing speed is more critical in determining fishing efficiency, we conducted a series of model tests to evaluate the performance of the newly-designed nozzle propeller before installing it in a trawl vessel to verify its towing speed and fuel efficiency in the sea. By conducting further model tests in the experimental basin, we redesigned the propeller of stern trawler to improve the resistance and propulsion performance. Through actual fishing operations, we evaluated the improvement in fuel and fishing efficiency by installing the new nozzle propeller. The trawling speed increased by 0.6kts at the same engine power (RPM), while the engine margin increased by more than 20%. The increased towing speed by installing the redesigned propeller is expected to enhance fishing performance through increasing the number of hauling- and casting operations per unit times, while shortening the towing duration. Analysis of the Catch-Per-Unit-Effort (CPUE) data indicated that the mean CPUE of trawl fishery increased from 3.04kg/m in year 2007 to 6.15kg/m in year 2008, confirming enhanced fishing efficiency by adopting the redesigned propeller.

• 수산해양기술연구
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• 제25권2호
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• pp.70-74
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• 1989

실험선 제주 402호의 조종성능을 전속전진중 최대타각으로 전타한 때의 선회권측정과 $10^{\circ}$, 20$^{\circ}$, 30$^{\circ}$Z시험에서 산출된 조종성지수를 분석, 검토한 결과를 요약하면 다음과 같다. 1. 선회종거는 우현선회시가 79.1m로 배의 길이의 약 2.6배였으며, 좌현선회시는 81.4m로서 배의 길이의 약 2.7배였다. 또, 선회경은 배의 길이의 약 2.6배로서 우현선회시가 78.3m로서 좌현선회시 80.4m보다 작았다. 2. 선회권시험시 속력저감율은 0.49였으며, 평균선회각속도는 우현선회시가 4.3$^{\circ}$/sec, 좌현선회시는 4$^{\circ}$/sec이었다. 3. Z시험 결과 over shot angle은 우현전타시가 좌현전타시보다 더 컸으며, 좌우타전타시의 평균값은 $10^{\circ}$Z시험시가 10.5$^{\circ}$, 20$^{\circ}$Z시험시가 20.5$^{\circ}$, 30$^{\circ}$Z시험시가 29.5$^{\circ}$로 다소 큰 편이었다. 4. $10^{\circ}$, 20$^{\circ}$, 30$^{\circ}$Z시험에서 K' 및 T'의 값은 각각 0.755, 0.566, 0.481 및 3.468, 1.621, 1.547로서 대체적으로 선회성은 대각도 전타 일수록 나쁘거나, 추종성은 대각도 전타 일 수 록 좋았다.

• 수산해양기술연구
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• 제49권3호
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• pp.301-310
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• 2013

To suggest a standard concerning with the arrangement of bridge equipment, the authors conducted the video observations with 3CCD (charge coupled device) cameras installed on the ceil of the bridge for monitoring the working activities of two bridge teams (the skipper/mate1 and the skipper/mate2) in a Korean coastal large trawler(gross tonnage: 139) for five days from July 30th. 2010 and analyzed of the data. Work elements coded by the work activities were input on the sheet of work analysis by the time unit of 1 sec according to the time occurred. A single work element among the work activities for every 5 minutes was denoted as the number of occurrence. The frequency of equipment usage was limited only in the usage of the equipment. In the case of the navigation and the towing net two ranks were integrated and analyzed. On the other hand, in the case of the casting net and the hauling net, two processes were integrated to as one and then analyzed separately as two ranks. As the results, 15 elements of work was carried out between two bridge teams for the observation; lookout, radar, GPS plotter, fish finder, net monitor, fishing deck, RPM indicator, rudder angle indicator, compass card, for maneuver; steering, ship speed control, trawl winch operation and external communications, paper works and others. It was found that the work load of the skipper per 5 minutes accordance with the navigation, the casting net, the towing net and the hauling net are 20.5 times, 11.9 times, 38.0 times and 9.5 times respectively, the mates are 65.2 times, 66.5 times, 85.7 times and 59.1 times respectively. The radar was shown the highest frequency of the equipment usage and the next was the fish finder, the GPS plotter and the external communications in the case of the navigation. In the case of the towing net the frequency of usage was high the ranking as the radar, the net monitor, the fish finder, the GPS plotter, the steering system and the external communications. In the case of the integrated process both of the casting and hauling net the trawl winch was shown the highest frequency to the skipper and the next was the GPS plotter and the radar, and the steering system was shown the highest frequency to the mate and the next was the radar, the ship speed control system, the GPS plotter, the net monitor and the fish finder.

• 수산해양기술연구
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• 제16권2호
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• pp.69-76
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• 1980

This paper describes the measurement of the underwater noises produced by the engine vibration around the engine room of stern trawler MIS Sae-Ba-Da(2275GT, 3,600 PS) and pole kner M/S Kwan-Ak-San (243 GT, 1000 PS) while the ship is stopping. The underwater noise pressure level was measured with the underwater level meter of which measuring range is 100 to 200 dB(re bLPa). A and B denotes the maximum pressure level measured at right beneath the bottom of the engine room, while the main engine of the Sae-Ba-Da revoluted at 750 and 500 rpm, respectively. C denotes that of the main engine of the Kwan-Ak-San revoluted at 350 rpm, and D that of the generator of the Sae-Ba-Da revoluted at 720 rpm. Thus A, B, C and D were set for the standard sound source for the experiment. The results obtained are as follows: 1. The noise Pressure level at A, B, C and D were 170.5,165,153 and 158dB, respectively. 2. When the check points distanted vertically 1, 10, 20, 30, 40, 50m from the sound source, the underwater noise presure levels were 170.5, 155, 148, 144 and 138 dB and the directional angle was 116\ulcorner in case of A. 3. The sound level attenuated at the rate of 20dB per 10" meters of the horizontal distance from the sound sources. 4. The frequency distribution of the noise was 100Hz to 10KHz and predominant frequency was 700 to 800Hzminant frequency was 700 to 800Hz

• 수산해양기술연구
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• 제25권2호
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• pp.75-81
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• 1989

현재 보편적으로 사용하고 있는 안강망어패의 흠함을 보완하기 위하여 새로 설계된 어구의 모형실험을 실시하고, 그 결과를 토대로 하여 실물 크기의 시험어구를 제작하여, 그 전개성능에 관한 해상시험을 실시함과 아울러 선미식 조업방법의 가능성과 문제점에 관해서도 검토하였다. 1. 어구의 전개성능 시험어구가 현용 어구와 다른 점은 그물의 등판.밑판의 아궁이 쪽을 만곡되게 사단하여 성형율이 25%정도 되게 뜸줄과 발줄을 붙이고, 양옆판의 아궁이쪽의 뻗힌 폭을 20%정도 줄이는 대신에 옆구리의 폭을 10%정도 크게한 점, 전개장치의 높이를 현용어구보다 17%정도 작게 한 점, 전개장치의 상단에 붙이는 부력을 16%정도 크게 한 점, 또 각판의 그물감을 서로 잇대는 네모서리에는 적당한 성형율을 주면서 힘줄을 붙인 점, 네갈랫줄의 길이를 맨 아랫것부터 차례로 75m, 77m, 80m, 78m로 다르게 한 점등이다. 어구의 전개성능은 어군탐지기를 써서 측정하였는데, 그 결과, 망구의 전개높이는 시험어구가 유속이 비교적 느릴 때는 현용어구보다 3m 정도 낮으나, 다소 빠를 때는 오히려 1m 정도 더 높고, 망구의 전개간격은 시험어구가 현용어구의 1.4배 정도이며, 망구의 전개면적은 1.3~1.6배여서 시험용어구가 현용어구에 비하여 어획성능이 상당히 클 것으로 기대된다. 2. 선미식 조업방법 선미식조업은 시험선의 선수를 조류에 향하게 해 놓고, 그물은 선미 슬립웨이에서 투양망하며, 전개장치는 선미갤로우스의 양현쪽에 있는 톱로울러를 통한 돋움줄에 의하여 오르내리게 하였다. 이와 같이 선미식 조업방법으로 개량하면 기계화로 성역화의 효과를 기대할 수 있으나, 조류와 바람의 방향이 일치하지 않을 때는 전개장치와 그물이 서로 얽힐 우려가 있으므로 이 점을 충분히 검토할 필요가 있다.

• 수산해양기술연구
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• 제40권4호
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• pp.311-318
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• 2004

실해상 실험을 통하여 해상의 조건이 동일할 때, 예망과 항해중일 때의 만남파에 대한 소형 트롤어선의 종동요와 횡동요의 응답특성을 통계적 방법과 이론적인 방법을 이용하여 분석하였다. 그 결과를 요약하면 다음과 같다. (1) 종동요의 응답 크기를 예망중과 항해중에 따라 비교하면 큰 차이가 없으나, 선수쪽에서 파를 받을 경우에는 항해중의 응답이 예망중 보다 양각 커지는 경향이 있다. (2) 횡동요의 응답은 예망중과 항해중 모두 종동요에 비해 매우 크다. 그러한 경향은 모든파향에서 현저하지만, 횡파를 받을 경우에는 양자의 응답 차이는 줄어든다. (3) 예망중과 항해중 모두 종동요에서 응답스펙트럼의 peak가 나타나는 주기는 파향에 관계없이 거의 일정하다. (4) 선미쪽에서 파를 받고 예망할 때, 양현에 균등하게 warp의 힘이 작용한다면, 어구의 저항은 동요를 감쇄시키는 상당한 효과가 있다.