The United Nations Convention on the Law of the Sea (UNCLOS) has been ratified by 168 countries. Among these countries, Indonesia is one of the most notable states concerning compliance with the provisions of the UNCLOS. However, the aggressive actions exhibited by countries seeking to become world hegemonies have resulted in the violation of the Convention. Therefore, this research aims to critically analyse the problems associated with any violations of sovereignty and sovereign rights by foreign research vessels which are conducting commercial and military navigation in Indonesian waters (territorial sea with the archipelagic waters and the inland waters). This research shows that the spirit of the Djuanda Declaration constituting the main principle of the Indonesian Republic is a legal ground for defending the national interest of Indonesia as an archipelagic state. This is the key to maintaining the integrity of sovereignty and national interest.
전 세계 해상 선박사고 건수는 감소하고 있지만, 국내 해상 사고 건수는 증가하고 있다. 이러한 이유에서 국내 선박의 해양 사 고를 줄이기 위한 한 가지 방법으로 사고 건수가 가장 많은 어선과 낚시어선을 대상으로 하는 어선복원성기준에 관한 연구를 수행한다. 국제해사기구(IMO)와 국내 그리고 일본, 중국, 캐나다 해외 3개국의 어선복원성기준을 각각 조사하고, 상호 비교 분석한 결과외국의 기준 들 대비 국내 기준이 가장 완화된 기준임을 알 수 있었다. 비교 분석 결과를 토대로 국내 어선복원성 기준을 보완하기 위한 어선복원성기 준 개정(안)을 5가지 평가항목에 대해서 제안했다.
The research vessel NARA equipped with an azimuth thruster system was built in 2015. There are few vessels with this propulsion system in Korea. This vessel has two modes such as the normal for maneuvering and the power for investigation, and the other two modes as one axis and two axes on the operating. This type of vessels does not seem to have a clear grasp of the maneuvering character in comparison with the vessel with a conventional propulsion system. So the authors carried out the sea test for the turning, the zigzag and the inclination, and the results are as follows. In turning test, the case of using the two axes mode is much better than the case of using the one axis mode for the elements of turning, such as advance, transfer, tactical diameter and final diameter, but turning hard over the rudder in full speed is very vulnerable to capsize in both modes. In zigzag test, the yaw quicking responsibility index, is very large excessively, which means a bad counter maneuvering ability, so an operator has to keep in mind that in turning operation. If necessary to avoid collision at head on situation, it may be a more effective method to use the crash astern stop than the turning according to the conditions and circumstances for the shortest stopping distance is very short.
This study is intended to provide navigator with specific information necessary to assist in the avoidance of collision and in operation of ships to evaluate the maneuverability of research vessel Jera. Authors carried out full-scale sea trials for turning test, zig-zag test, and spiral test at actual sea-going condition, which were performed on starboard and port sides with 10-20 rudder angle at service speed of 10 knots. The turning circle was much different at both of the turning of port and starboard which was longer at the starboard than at the port. In the zig-zag test results, the port and starboard was 10˚ the first and second overshoot angles were 6.0˚ , 5.8˚ and 6.3˚ , 7.1˚ respectively and the first overshoot angles were 16.4˚ , 17.6˚ when using 20˚ . Her maneuverability index T and K can be easily determined by using an analogue computer with the data obtained from the zig-zag tests where K is a constant representing the turning ability and T is a constant representing her quick response. In the zig-zag tests under 10˚ or 20˚ at rudder angle, the value K is 0.149. 0.123 sec- and T is 11.853 and 6.193 sec and angular velocity is 0.937˚ /sec and 1.636˚ /sec. In the spiral test, the loop width was unstable at +0.51˚ and -1.19˚ around the midship of rudder, but the tangent line at 0˚ was close to vertical. From the sea trial results, we found that she did comply with the present criterion in the standards of maneuverability of IMO.
지구 온난화로 인해 북극해에 얼음이 빠르게 해빙되어 상업적 운항이 진행되고 있다. 극한의 조건에서도 북극해 항로를 개척하는 이유는 기존 항로보다 운항거리 단축되어 경제적으로 이익을 가지고 오기 때문이다. 이에 국제해사기구(IMO)에서는 북극해 항로를 안전하게 운항하기 위해 극지운항선박 안전기준(Polar Code)이 제정하였다. 본 연구에서는 북극해 안전 운항을 위해 항해사가 반드시 알아야 하는 얼음의 종류 및 극지운항선박 안전기준에 대해 설명하였다. 그리고 북극해를 운항하는 통항선의 안전 운항에 대한 이론적 지식을 시뮬레이션을 통해 검증하였다. 그 결과 안전 운항을 위해서 통항선들은 얼음 진입 전 감속을 통해 얼음을 분석하고 얼음을 안전하고 효율적으로 쇄빙하기 위해 직각으로 진입해야 함을 알 수 있었다. 또한, 얼음에 진입 후 항로(lead)운항에 대하여 시뮬레이션을 실시한 결과 변침이 곤란하여 전방의 통항선에 대한 긴급상황 대처 훈련이 필요한 것으로 판단된다. 향후 다양한 조건의 시나리오를 통해 면밀한 분석이 필요할 것으로 본다.
The aim of this study is to research attributes of fishermen's occupational accidents for investigating the measure of risk control on situational condition in the Korean offshore and coastal fishing vessel. Using data of fishermen's occupational accidents are from National federation of fisheries cooperatives for 2013. The results were as belows; Occupational accident occurrence rate was 29.5‰, slips & trips and struck by object and contact with gear were shown severe occurrence pattern. Occupational accident occurrence rate of offshore fisheries was 130.2‰, coastal was 16.9‰, specially the risk rates were severely high in several type of danish seine, stow net and offshore trap. Death rate by accidents was 10.6‰ and by fall into the water in occurrence pattern was 5.5‰.
In vibration analysis of ships, the principle aim is to determine the natural frequencies and excitation frequencies, and use this information to avoid resonances and vibration damage. The simplest method is to prevent resonance conditions, which is effective as long as the natural frequencies and excitation frequencies can be regarded as independent from environmental conditions. For ships that use electric propulsion systems, the sources of vibration are reduced compared with those caused by a diesel engine or other combustion-based propulsion systems. However, the frequency spectrum of these vibrations may be different; therefore, to understand the characteristics of the electric propulsion, we also should investigate how the ship responds to these vibrations. We focused on a 1,000-ton deadweight (DWT) ocean-research vessel using an electric propulsion system and analyzed the response to vibration.
This study was intended to determine the maneuverability of the vessel CHARMBADA. When the rudder angle was at 10˚, 20˚ and 30˚, the maximum advance by slow, half and full ahead were varied in the range of 523.6-131.3m, 528.8-177.2m and 530.6-219.7m, respectively. The maximum transfer was 799.9-181.3m, 792.1-232.8m and 807.7-316.9m, respectively. The turning circle ability was better during starboard turning. When the rudder angle was 10˚, 20˚ and 30˚, variation in the maximum advances was 392.0m, 245.0m and 153.0m. The maximum transfer was 528.0m, 339.0m and 218.0m, respectively based on the regression equations. As the rudder angle became bigger, the maximum advance or maximum transfer became smaller by the exponential function. The advance inertia took 127sec, 145sec, 181sec each until the vessel speed was 7.0konts, 12.0konts, 17.0konts. The static inertia took 245sec, 269sec, 300sec each until the vessel speed was under 2.0konts and the advance distance was 114.4m, 181.2m, 197.0m each. Accordingly, the static inertia was inclined to increase to scale according to the increase in vessel speed. For the CHARMBADA, the smaller the rudder angle was, the much bigger the turning circle became due to adhesion to the skeg, thereby lowering the vessel's turning ability.