Research on Design of Principal Dimension Elements of Hangar in Aircraft Carriers

Abstract

Abstract: Hangar is the biggest cabin for maintaining and safeguarding aircrafts in aircraft carrier and the design of principal dimensions of hangar should satisfy the demands of an efficient cooperation between crafts and the ship. A craft automation layout program was compiled according to the principia of compact layout and convenient for transport of crafts. And a fuzzy modeling technology was also used to handle those subjective constraints and goals in the design process. Meanwhile, a double optimization configuration was presented to solve the problem of design of principal dimensions. Then, the example proves the validity of the model, as well as a more efficient design strategy , so the method can provide a reference for the design of principal dimensions of hangar in our own aircraft carrier.

Key words: aircraft carrier, principal dimensions of hangar, design, fuzzy modeling, double optimization configuration

CLC Number:

U 662.3

HU Yu-Long, HUANG Sheng, HOU Yuan-Hang, WANG Wen-Quan. Research on Design of Principal Dimension Elements of Hangar in Aircraft Carriers[J]. Journal of Shanghai Jiaotong University, 2012, 46(08): 1184-1189.

References

［1］王钱生. 航母适配性的基本设计要求［J］. 飞机设计, 2006(2):3235.
WANG Qiansheng. Fundamental design requirements for adaptation to aircraft carriers［J］. Aircraft Design, 2006(2): 3235.
［2］潘镜芙. 国外航空母舰的发展与展望［J］. 自然杂志, 2007, 29（6）:3239.
PAN Jingfu. The review and prospect of aircraft carriers［J］. Chinese Journal of Nature, 2007, 29(6):3239.
［3］孙诗南. 现代航空母舰［M］. 上海：上海科学普及出版社, 2000:106115.
［4］Zimmermann H J. Fuzzy set theory and its applications［M］. New York: Springer, 2001:32:34.
［5］Singer D J. A hybrid agent approach for setbased conceptual ship design through the use of a Fuzzy Logic agent to facilitate communications and negotiation［D］. Ann Arbor: University of Michigan, 2003.
［6］Gray A W, Daniels A S, Singer D J. Impacts of fuzzy logic modeling for constraints optimization［J］. Naval Engineers Journal, 2010,122(2): 121132.
［7］王钱生. 舰载机总体设计主要关键技术概述［J］. 飞机设计, 2005(2): 612.
WANG Qiansheng. Critical technologies in carrierbased aircraft design and development［J］. Aircraft Design, 2005(2): 612.
［8］朱英富. 水面舰船设计新技术［M］. 哈尔滨：哈尔滨工程大学出版社，2004：5193.
ZHU Yingfu. Advanced technology for surface vessel design［M］. Harbin: Harbin Engineering University Press, 2004: 5193.
［9］The MathWorks, Inc. Fuzzy Logic ToolboxTM 2 User’s Guide［EB/OL］. (2010025) ［2011504］. www.mathworks.com/contact_TS.html.
［10］王志国，仲晨华，杨志清，等. 舰船防火区域划分原则研究［J］. 海军工程大学学报, 2003, 15（1）:5052.
WANG Zhiguo, ZHONG Chenhua, YANG Zhiqing, et al. Principle of division of ship’s fire zone［J］. Journal of Naval University of Engineering, 2003, 15（1）:5052.
［11］Li J, Parsons M. Complete design of fuzzy systems using a realcoded genetic algorithm with imbedded constraints［J］. Journal of Intelligent and Fuzzy Systems,2001, 10(1): 1337.
［12］Deb K. Multiobjective optimization using evolutionary algorithms［M］. New York: Wiley,2001: 2376.

[1]	OUYANG Xuyu, CHANG Haichao, LIU Zuyuan, FENG Baiwei, ZHAN Chengsheng, CHENG Xide. Application of Adaptive Sampling Method in Hull Form Optimization [J]. Journal of Shanghai Jiao Tong University, 2022, 56(7): 937-943.
[2]	QIN Xuesheng (秦雪升), LIU Yuanhe (刘远贺), LI Kebo (黎克波), LIANG Yangang∗ (梁彦刚). Impact Angle/Time Constraint Guidance Design Based on Fast Terminal Error Dynamics [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(6): 823-832.
[3]	XING Lu, HUA Yixiong, ZHANG Zhinan. Conceptual Design of Mechatronics System by Integrating EBD and TRIZ [J]. Journal of Shanghai Jiao Tong University, 2022, 56(5): 576-583.
[4]	WU Li ∗ (武力), HUANG Wei (黄伟), LI Xuetao (李学涛). Personalized Design Method of Bionic Bone Scaffold with Voronoi Spacial Architecture [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(4): 521-527.
[5]	LU Dezhi 1,2‡ (鲁德志), LI Wentao1‡ (李文韬), WANG Xiaowen2 (王孝文), SONG Yan2 (宋艳), ZHANG Pingping2 (张萍萍), FENG Haiyang2 (冯海洋), WU Yuncheng1 (吴云成), XU Yuanjing3 (许苑晶), LI Tao4 (李涛), MA Zhenjiang1∗ (马振江), WANG Jinwu1,2∗ (王金武). Case Study of a Personalized Scoliosis Brace Based on 3D Printing [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(4): 528-534.
[6]	ZOU Ke (邹柯), ZOU Jincheng (邹金成), WANG Yifei (王逸飞), ZHANG Aili ∗ (张爱丽). Design of Real-Time Temperature Monitoring and Control System for Multimodal Ablation [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(4): 535-542.
[7]	LIN Yana∗ (林焰), PEI Feib (裴斐). Experimental Study on Hydrodynamic Response of Semisubmersible Platform-Based Bottom-Hinged Flap Wave Energy Converter [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 307-315.
[8]	HUO Fali∗ (霍发力), YANG Hongkun (杨宏坤), GUO Jianting (郭建廷), JI Chunyan (嵇春艳), NIU Jianjie (牛建杰), WANG Ke (王珂). Design and Overall Strength Analysis of Multi-Functional Elastic Connections Floating Breakwater System [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 326-338.
[9]	DU Jian1∗ (杜剑), ZHAO Xu2 (赵旭), GUO Liming2 (郭力铭), WANG Jun2 (王军). Machine Learning-Based Approach to Liner Shipping Schedule Design [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(3): 411-423.
[10]	LIU Xiaoying* (刘晓颖), YUE Yong(岳勇), WANG Chongning (王宠宁), HUANG Jiazan (黄家赞),HUANG Xianwei(黄贤伟), HAO Yanhua(郝艳华). Topology Optimization Method for Calcaneal Prosthesis [J]. J Shanghai Jiaotong Univ Sci, 2022, 27(2): 240-249.
[11]	ZHANG Hengrui. Demand-Driven Materials Design [J]. Journal of Shanghai Jiao Tong University, 2021, 55(Sup.1): 93-94.
[12]	ZHANG Jinke, MIAO Guangwu, JIN Jiamin, CHEN Yinfei, LU Hanfeng, NING Wensheng, BAI Zhanqi, LIU Wucan. Analysis of Factors and Significances of Adsorption Kinetics R115/NaX System [J]. Journal of Shanghai Jiao Tong University, 2021, 55(9): 1071-1079.
[13]	TAO Wei, LIU Zhao, XU Can, ZHU Ping. Multi-Scale Reliability-Based Design Optimization of Three-Dimensional Orthogonal Woven Composite Fender [J]. Journal of Shanghai Jiao Tong University, 2021, 55(5): 615-623.
[14]	HE Ke, WU Zishuai, WANG Daoai, ZHANG Zhinan. Development of a Triboelectric Performance Test System [J]. Journal of Shanghai Jiao Tong University, 2021, 55(5): 624-630.
[15]	WU Junxiang (吴钧翔), LUO Dinghao(罗丁豪), XIE Kai (谢凯), WANG Lei (王磊), HAO Yongqiang (郝永强). Design and Application of 3D Printing Based Personalised Pelvic Prostheses [J]. J Shanghai Jiaotong Univ Sci, 2021, 26(3): 361-367.