Sunardi, Moch. Agus Choiron, Sugiarto, P. Setyarini
{"title":"利用计算机模拟建立极端天气下渔船碰撞模型","authors":"Sunardi, Moch. Agus Choiron, Sugiarto, P. Setyarini","doi":"10.21303/2461-4262.2023.002601","DOIUrl":null,"url":null,"abstract":"The incidence of fishing boat accidents in Indonesia is very worrying, with 342 people dying during 2018–2020. Based on this, it is crucial to investigate the construction strength of fishing vessels against the possibility of a collision. In this study, the fishing boat due to the impact load was investigated in extreme weather conditions using Finite Element Method (FEM) analysis. Traditional fishing boat was constructed by measuring the thickness of the hull, deck, keel, frames, and longitudinal structure of the fishing boat. The collision model is carried out with an impactor in the form of a mooring pole during extreme weather with a wave height of 6 meters and wind speeds 30 knots. Variations in velocity and frame spacing as in actual conditions are modeled to obtain differences in deformation, absorption energy values, and plasticity of boat construction due to collisions. The collision speed of 30 and 20 knots are set on the extreme weather conditions, while the collision speed of 7 knots is set on operating speed. Frame spacing of 0.5 and 0.6 meters is built according to the boat's frame spacing in the field. Computer simulation is carried out using application software ANSYS Research License. The fishing boat material used is mahogany wood with tested by using impact test with a toughness value of 39.1 kJ/m2. Based on the simulations results, the impact velocity has an effect deformation wider crash area and hull stress value. The speed of the ship collision was 7 knots, the collision did not damage the hull, but the construction failed at speeds of 20 and 30 knots. The closer of frame spacing, the higher collision performance of structure to withstand impact are indicated by the higher energy absorption. At a ship collision speed of 30 knots, the absorption energy of the construction at 0.5-meter frame spacing is 49.8 kJ, greater than 0.6-meter frame spacing with a value of 29.6 kJ","PeriodicalId":11804,"journal":{"name":"EUREKA: Physics and Engineering","volume":"112 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-03-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Development of fishing boat collision models in extreme weather using computer simulation\",\"authors\":\"Sunardi, Moch. Agus Choiron, Sugiarto, P. Setyarini\",\"doi\":\"10.21303/2461-4262.2023.002601\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The incidence of fishing boat accidents in Indonesia is very worrying, with 342 people dying during 2018–2020. Based on this, it is crucial to investigate the construction strength of fishing vessels against the possibility of a collision. In this study, the fishing boat due to the impact load was investigated in extreme weather conditions using Finite Element Method (FEM) analysis. Traditional fishing boat was constructed by measuring the thickness of the hull, deck, keel, frames, and longitudinal structure of the fishing boat. The collision model is carried out with an impactor in the form of a mooring pole during extreme weather with a wave height of 6 meters and wind speeds 30 knots. Variations in velocity and frame spacing as in actual conditions are modeled to obtain differences in deformation, absorption energy values, and plasticity of boat construction due to collisions. The collision speed of 30 and 20 knots are set on the extreme weather conditions, while the collision speed of 7 knots is set on operating speed. Frame spacing of 0.5 and 0.6 meters is built according to the boat's frame spacing in the field. Computer simulation is carried out using application software ANSYS Research License. The fishing boat material used is mahogany wood with tested by using impact test with a toughness value of 39.1 kJ/m2. Based on the simulations results, the impact velocity has an effect deformation wider crash area and hull stress value. The speed of the ship collision was 7 knots, the collision did not damage the hull, but the construction failed at speeds of 20 and 30 knots. The closer of frame spacing, the higher collision performance of structure to withstand impact are indicated by the higher energy absorption. 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引用次数: 0
摘要
印度尼西亚的渔船事故发生率非常令人担忧,2018-2020年期间有342人死亡。在此基础上,研究渔船在碰撞可能性下的结构强度是至关重要的。本文采用有限元法对渔船在极端天气条件下的冲击载荷进行了分析。传统的渔船是通过测量船体、甲板、龙骨、框架和渔船纵向结构的厚度来建造的。碰撞模型是在极端天气下,波浪高度为6米,风速为30节,以系泊杆形式的撞击器进行的。对实际条件下速度和框架间距的变化进行建模,得到船体结构在碰撞下的变形、吸收能值和塑性的差异。30节和20节的碰撞速度是在极端天气条件下设定的,7节的碰撞速度是在运行速度下设定的。0.5米和0.6米的车架间距是根据船在野外的车架间距建造的。利用应用软件ANSYS Research License进行计算机仿真。渔船所用材料为红木,采用冲击试验测试,韧性值为39.1 kJ/m2。仿真结果表明,冲击速度对船体变形、碰撞面积和船体应力值有影响。船的碰撞速度为7节,碰撞没有损坏船体,但在20和30节的速度下建造失败。框架间距越小,结构的抗冲击性能越好,其能量吸收越高。船舶碰撞航速为30节时,0.5 m架距处结构的吸收能量为49.8 kJ,大于0.6 m架距处的吸收能量值为29.6 kJ
Development of fishing boat collision models in extreme weather using computer simulation
The incidence of fishing boat accidents in Indonesia is very worrying, with 342 people dying during 2018–2020. Based on this, it is crucial to investigate the construction strength of fishing vessels against the possibility of a collision. In this study, the fishing boat due to the impact load was investigated in extreme weather conditions using Finite Element Method (FEM) analysis. Traditional fishing boat was constructed by measuring the thickness of the hull, deck, keel, frames, and longitudinal structure of the fishing boat. The collision model is carried out with an impactor in the form of a mooring pole during extreme weather with a wave height of 6 meters and wind speeds 30 knots. Variations in velocity and frame spacing as in actual conditions are modeled to obtain differences in deformation, absorption energy values, and plasticity of boat construction due to collisions. The collision speed of 30 and 20 knots are set on the extreme weather conditions, while the collision speed of 7 knots is set on operating speed. Frame spacing of 0.5 and 0.6 meters is built according to the boat's frame spacing in the field. Computer simulation is carried out using application software ANSYS Research License. The fishing boat material used is mahogany wood with tested by using impact test with a toughness value of 39.1 kJ/m2. Based on the simulations results, the impact velocity has an effect deformation wider crash area and hull stress value. The speed of the ship collision was 7 knots, the collision did not damage the hull, but the construction failed at speeds of 20 and 30 knots. The closer of frame spacing, the higher collision performance of structure to withstand impact are indicated by the higher energy absorption. At a ship collision speed of 30 knots, the absorption energy of the construction at 0.5-meter frame spacing is 49.8 kJ, greater than 0.6-meter frame spacing with a value of 29.6 kJ