深海载人潜水器的蛋形耐压壳研究(全英文)=RESEARCH ON EGG-SHAPED PRESSURE HULLS OF DEEP MANNED SUBMERSIBLES
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九品
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作者张建;吴文伟;唐文献;王纬波
出版社上海科学技术出版社
出版时间2020-12
版次1
装帧精装
上书时间2024-09-08
商品详情
- 品相描述:九品
图书标准信息
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作者
张建;吴文伟;唐文献;王纬波
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出版社
上海科学技术出版社
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出版时间
2020-12
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版次
1
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ISBN
9787547847657
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定价
190.00元
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装帧
精装
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开本
16开
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纸张
胶版纸
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页数
228页
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字数
280千字
- 【内容简介】
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本专著面向深海科技发展急需、重大专项和技术领先方向,紧密围绕深海耐压壳装备设计理论与应用技术这个核心主题,针对现有球形结构存在缺陷敏感性高、水动力学特性差、壳内空间利用率低等问题,提出一种新型结构—蛋形耐压壳替代球形耐压壳,从生物学、应用力学、海洋工程学和仿生学角度,全面阐述了深海蛋形耐压壳、蛋形仿生封头、多蛋交接耐压壳研究的*成果。专著内容系统完整,理论创新性明显,技术实用性强,可以直接指导生产实践。专著的出版对全面提升我国深海工程装备自主研发能力具有重要实践意义,也为中国深海耐压装备产业创新发展提供参考和支撑。
- 【作者简介】
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张建,双博士,副教授,江苏省优青,江苏省“333工程”第三层次,江苏省“六大人才高峰”人选,江苏省“双创计划”人才,江苏省科协青年人才托举对象,镇江市有突出贡献的中青年专家,中国船舶科学研究中心博士后。获江苏大学车辆工程博士学位、日本埼玉工业大学机械工程博士学位。
主要从事深海工程装备基础理论研究及复杂机电产品数字化开发。第一或通讯发表SCI收录论文 20篇(ESI高被引1篇)。第一发明人获发明专利39件(美国2件、俄罗斯1件)。作为项目主要完成人获江苏省科技进步二等奖1项(排名3)、三等奖2项(排名3),教育部科技进步二等奖2项(排名3、5),江苏省发明专利优秀奖1项(排名2)。指导研究生获江苏省优秀硕士论文1部。
- 【目录】
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Chapter 1Introduction1
1.1Background and significance1
1.2Overview of research status4
1.2.1Externally pressurized spherical shells4
1.2.2Externally pressurized untypical shells5
1.2.3Externally pressurized domed heads5
1.2.4Shell buckling research approaches6
1.2.5Externally pressurized multisegment shells7
1.3Problems and solution8
1.4Structure of the monograph10
References12
Chapter 2Buckling of deep sea spherical pressure hulls18
2.1Buckling analysis of geometrically perfect and imperfect hulls19
2.1.1Geometry and material19
2.1.2Buckling of geometrically perfect hulls20
2.1.3Buckling of geometrically imperfect hulls23
2.2Effect of yield strength on the buckling of hulls26
2.2.1Perfect geometry analysis27
2.2.2Imperfect geometry analysis28
2.3Experimental methodology of spherical shells34
2.3.1Shell manufacturing and testing34
2.3.2Material properties38
2.4Buckling analysis of spherical shells39
2.4.1Experimental and analytical results 40
2.4.2Comparison between experimental and numerical results42
2.4.3Effect of constitutive models45
2.4.4Effect of geometrical imperfections46
2.5Summary49
References51
Chapter 3Bionic design of eggshape pressure hulls54
3.1Geometric properties of goose eggshells55
3.1.1Size of goose eggshells56
3.1.2Surface area and volume of goose eggshells58
3.1.3Symmetry of goose eggshells59
3.1.4Shape function of goose eggshells61
3.1.5Thickness of goose eggshells62
3.2Load carrying capacities of goose eggshells63
3.2.1Experimental results of goose eggshells67
3.2.2Numerical results of goose eggshells71
3.2.3Comparison between experimental and numerical data73
3.3Configuration and size eggshaped pressure hulls75
3.4Strength, stability, and buoyancy of eggshaped pressure hull77
3.4.1Strength and stability of eggshaped pressure hull77
3.4.2Uniform wall thickness analysis of eggshaped pressure
hulls78
3.4.3Nonuniform wall thickness analysis of eggshaped pressure
hulls80
3.4.4Spherical pressure hulls analysis81
3.5Analytical results of eggshaped and spherical pressure hulls82
3.6Numerical results of eggshaped and spherical pressure hulls85
3.7Evaluation and comparison of main properties for pressure hulls92
3.8Summary93
References95Chapter 4Effect of geometrical parameters on buckling of eggshaped pressure
hulls97
4.1Effect of shape index on buckling of eggshaped pressure hulls98
4.1.1Geometry of eggshaped pressure hulls98
4.1.2Capacity and mass of eggshaped pressure hull100
4.1.3Numerical modeling of eggshaped pressure hulls101
4.1.4Linear buckling of eggshaped pressure hulls102
4.1.5Nonlinear buckling of eggshaped pressure hulls104
4.2Effect of wall thickness on buckling of eggshaped pressure
hulls107
4.2.1Buckling of geometrically perfect eggshaped pressure
hulls107
4.2.2Buckling of geometrically imperfect eggshaped pressure
hulls111
4.2.3Comparison between eggshaped and spherical pressure
hulls113
4.3Buckling experimentation using CNCmachined eggshaped
shells116
4.3.1Experimental buckling of CNCmachined eggshaped
shells116
4.3.2Numerical buckling of CNCmachined eggshaped shells120
4.4Buckling experimentation using rapid prototyping eggshaped
shells 124
4.4.1Experimental buckling of rapid prototyping eggshaped
shells124
4.4.2Numerical buckling of rapid prototyping eggshaped
shells130
4.4.3Effects of imperfection shape and size on buckling of
eggshaped shells133
4.5Summary134
References136
Chapter 5Enhancement of eggshaped pressure hulls using nonuniform wall
thickness139
5.1Design and fabrication of eggshaped pressure hulls140
5.1.1Geometrical design140
5.1.2Sample fabrication141
5.2Measurement and test142
5.2.1Shape scanning of samples142
5.2.2Hydrostatic test of samples144
5.2.3Tensile tests of material147
5.3Experimental analysis of eggshaped pressure hulls148
5.4Numerical analysis of eggshaped pressure hulls150
5.5Summary153
References154
Chapter 6Collapse modes and ultimate strengths of eggshaped shells with
corrosion thinning157
6.1Problem definition158
6.2Numerical analysis of eggshaped shells with corrosion thinning160
6.2.1Collapse mechanism analysis162
6.2.2Ultimate strength analysis163
6.3Experimental analysis of eggshaped shells with corrosion
thinning165
6.3.1Fabrication and measurement of samples166
6.3.2Externally hydrostatic test of samples169
6.3.3Numerical analysis of fabricated eggshaped shells172
6.4Summary174
References175
Chapter 7Buckling of prolate eggshaped domes under external pressure179
7.1Geometrical and physical properties of eggshaped domes180
7.1.1Geometry of eggshaped domes180
7.1.2Capacity and mass of eggshaped domes182
7.2Manufacture, measurement and test of eggshaped domes183
7.2.1Overview of the manufacturing process183
7.2.2Pretest measurements183
7.2.3Collapse tests185
7.2.4Parent material properties186
7.3Experimental analysis of experimental eggshaped domes187
7.4Numerical analysis and verification of manufactured eggshaped
domes187
7.5Buckling of a perfect eggshaped dome190
7.6Summary194
References195
Chapter 8Buckling of multisegment eggshaped pressure hulls197
8.1Geometry of the multisegment eggshaped pressure hull198
8.2Design of rib rings199
8.2.1Analytical prebuckling analysis of the eggshaped pressure
hull200
8.2.2Inner radii of rib rings201
8.3Numerical result and discussions202
8.3.1Prebuckling state203
8.3.2Buckling state205
8.3.3Postbuckling state207
8.3.4Verification of numerical approach211
8.4Summary214
References215
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