抗侧向荷载的结构体系外文翻译

荷载规范英文版篇一：建筑英语--荷载规范类I Load Code for the Design of Building Structures 建筑结构荷载规范Permanent load 永久荷载Variable load 可变荷载Accidental load 偶然荷载Representative values of a load荷载代表值Design reference period设计基准期Characteristic value \ nominal value 标准值Combination value组合值Frequent value 频预值Quasi-permanent value 准永久值Design value of a load 荷载设计值Load bination荷载组合Fundamental bination基本组合Accidental bination 偶然组合Characteristic \ nominal bination标准组合Frequent binations 频遇组合Quasi-permanent binations 准永久组合Equivalent uniform load等效均布荷载Tributary area 从属面积Dynamic coefficient 动力系数Reference snow pressure 基本雪压Reference window pressure 基本风压Terrain roughness 地面粗燥度II Code for Seismic Design of Building GB 5001-2001 建筑抗震设计规范Earthquake action 地震作用Seismic fortification intensity 抗震设防烈度Seismic fortification criteria 抗震设防标准Design parameters of ground motion 设计地震动参数Design basic acceleration of ground motion设计基本地震加速度Design characteristic period of ground motion 设计特征周期Seismic concept design of building 建筑抗震概念设计Seismic fortification measures抗震措施Details of seismic design抗震构造措施Site 场地IIICode for Design of Steel Structures GB 5001-2003钢结构设计规范Strength 强度Load-carrying capability承载能力Brittle fracture 脆断（指钢结构在拉应力状态下没有出现警示性的塑性变形而突然发生的脆性断裂）Characteristic value of strength强度标准值（钢材屈服点和抗拉强度）Design value of strength强度设计值First order elastic analysis 一阶弹性分析Second order elastic analysis 二阶弹性分析Buckling 屈曲（杆件或板件在轴心压力、弯矩、剪力单独或共同作用下突然发生与原受力状态不符的较大变形而失去稳定）Post-buckling strength of web plate 腹板屈曲后强度（腹板屈曲后尚能保持承受荷载的能力） Normalized web slenderness 通用高后比Overall stability 整体稳定Effective width有效宽度Effective width factor有效宽度系数Effective length有效长度Slenderness ratio 长细比（构件长度与截面的回转半径比）Equivalent Slenderness ratio 换算长细比Nodal bracing force支撑力Unbraced frame无支撑纯框架Frame braced with strong bracing system 强支撑框架Frame braced with weak bracing system 弱支撑框架Leaning column摇摆柱（框架内两端为铰接不能抵抗侧向荷载的柱）Panel zone of column web 柱腹板节点域Spherical steel bearing 球形钢支座Couposite rubber and steel support橡胶支座Chord member 主管Bracing member支管Gap joint 间隙节点Overlap joint 搭接节点Uniplanar joint 平面管节点Multiplanar joint 空间管节点Built-up member 组合构件Composite steel and concrete beam 钢与混泥土组合梁IVDesign Code for Strengthening Concrete StructureGB 50367-2006混泥土结构加固设计规范Strengthening of existing structures 已有结构加固Existing structure member 原构件Important structure member 重要构件General structure member 一般构件Structure member strengthening with reinforced concrete增大截面加固法Structure member strengthening with externally bonded steel frame 外粘型钢加固法Structure member strengthening with externally bonded reinforced materials复合截面加固法Structure member confined by reinforcing wire 绕丝加固法Structure member strengthening with externally applied prestressing 外加预应力加固法 Bonded rebars 植筋（用专用结构胶粘剂将带肋钢筋锚固于基材混泥土中）Structural adhesives结构胶粘剂（可承重，传力）Fiber reinforced polymer（ FRP）纤维复合材Polymer mortar聚合物砂浆Effective cross-section area 有效截面积Design working life for strengthening of existing structure or its member 加固设计使用年限V Technical Code of Cold-formed Thin-wall Steel StructuresGB 50367-2006冷弯薄壁型钢结构技术规范Element 板件（薄壁型钢杆件中相邻两纵边之间的平板部分）Stiffened elements加劲板件（两纵边均与其他板件相连接）Partially Stiffened elements 部分加劲板Unstiffened elements 非加劲板Uniformly pressed elements 均匀受压板件Non- Uniformly pressed elementsSub-elements 子板件Width-to-thickness ratio 宽厚比Effective Width-to-thickness ratio 有效宽厚比Effect of cold forming冷弯效应（因冷弯引起钢材性能改变的现象）Stressed skin action 受力蒙皮作用（与支撑构件可靠连接的压型钢板体系所具有的抵抗板自身平面内剪切变形的能力）Flare groove welds 喇叭形焊缝（连接圆角与圆角或圆角与平板间隙处的焊缝）VI Technical Specification for Application of Architectural Glass JGJ 113-2009建筑玻璃技术规范Architectural Glass 建筑玻璃Strength on centre area of glass 玻璃中部强度（荷载垂直玻璃板面，玻璃中部强度） Strength on border area of glass 玻璃边缘强度Strength on edge of glass 玻璃端面强度Single glass单片玻璃Framed glazing有框玻璃Roof glass 屋面玻璃Floor and stairway glazing地板玻璃Front\ back clearance前部\ 后部余隙Edge clearance 边缘间隙Edge cover潜入深度VIITechnical Specification for Post-installed Fastenings in Concrete StructuresJGJ 145-2004 混泥土结构后锚固技术规范Post-installed fastening 后锚固Anchor锚栓Expansion anchors膨胀型锚栓Undercut anchors 扩孔型锚栓Bonded rebars化学植筋（以化学胶粘剂-----锚固胶将钢筋固定于混泥土基材锚孔） Base material 基材Anchor group 群锚Fixture被连接件（被锚固于混泥土基材上的物件）Anchor plate 锚板Failure mode 破坏模型Anchor failure锚栓破坏Concrete cone failure 混泥土锥体破坏Combination failure 混合型破坏Concrete edge failure 混泥土边缘破坏Pryout failure 剪撬破坏Splitting failure劈裂破坏Pull-out failure 拔出破坏Pull-through failure穿出破坏Steel\ adhesive interface failure 胶筋界面破坏Adhesive\ concrete interface failure 胶混界面破坏Design working life设计使用年限VIIICode of Design on Building Fire Protection and PreventionGB 50016---2006建筑设计防火规范Fire resistance rating耐火极限Non-bustible ponent不燃烧体Difficult-bustible ponent 难燃烧体Combustible ponent 燃烧体Flash point闪点（在规定实验条件下，液体挥发的蒸汽与空气形成的混合物，遇火源能发生闪燃的最低温度）Lower explosion limit爆炸下限Boiling spill oil沸溢性油品Semi-basement半地下室Multi-storied industrial building 多层厂房（仓库）High-rise industrial building 高层厂房（仓库）High racked storage高架仓库Commercial service facilities商业服务网点Important public buildings 重要公共建筑Open flame site 明火地点Sparking site 散发火花地点Safety exit安全出口Enclosed staircase 封闭楼梯间Smoke-proof staircase防烟楼梯间Fire partment 防火分区Fire separation distance防火间距Smoke bay 防烟分区Full water spout 充实水柱（由水枪喷嘴起到射流90%的水柱水量穿过直径380mm圆孔处的一段射流长度）IX Code for Design of Concrete Structure GB 50010---2002混泥土结构设计规范Concrete structure 混泥土结构Plain concrete structure 素混泥土结构Reinforced concrete structure 钢筋混泥土结构Prestressed Concrete structure 预应力混泥土结构Pretensioned prestressed Concrete structure 先张法预应力混泥土结构Post-tensioned prestressed Concrete structure 后张法预应力混泥土结构Cast-in-situ concrete structure 现浇混泥土结构Prefabricated concrete structure装配式混泥土结构Assembled monolithic concrete structure 装配整体式混泥土结构Frame structure框架结构Shearwall structure 剪力墙结构Frame-shearwall structure 框架---剪力墙结构Deep flexural member 深度受弯构件Deep beam深梁Ordinary steel bar 普通钢筋Prestressing tendon 预应力钢筋Degree of reliability 可靠度Safety class安全等级Load effect 荷载效应Load effect bination 荷载效应组合Fundamental bination 基本组合Characteristic bination 标准组合Quasi-permanent bination准永久组合篇二：A list for English version of Chinese Codes and StandardsA list for English version of Chinese Codes and Standards英文版中国标准目录[G:\Public\Engineering\Codes and Standards]1 . GBJ 16-87 Code for design of building fire protection建筑设计防火规范Attachment A Code for design of building fire protection (Revision 97)建筑设计防火规范(97年修订版)2 . GB50160-92 Code for design of petrochemical enterprise fire protection石油化工企业防火设计规范Attachment A Code for design of petrochemical enterprise fire protection(Revision 99)石油化工企业防火设计规范(99年修订版)3 . SHJ9-89 Code for design of petrochemical enterprise for fuel gas system andFlammable gas discharge system石油化工企业燃料气系统和可燃气体排放系统设计规范SHJ9-89 has been replaced by SH3009-20014 . GB50058-92Code for design of electrical installation for explosive and fire hazardousatmospheres爆炸和火灾危险环境电力装置设计规范5 . TJ36-79 Sanitary standard for the design of industrial enterprise工业企业设计卫生标准TJ36-79 has been replaced by GBZ1-20026 . GB16297-1996 Integrated Emission Standard of Air Pollutants大气污染综合排放标准7 . GB8978-1996 Integrated Wastewater Discharge Standard污水综合排放标准8 . GB12348-90Standard for Noise at Boundary of Industrial Enterprises工业企业厂界噪声标准9 . GBJ87-85Code for Noise Control Design of Industrial Enterprises工业企业噪声控制设计规范10 . GB14554-93Emission Standard for Odor Pollutants恶臭污染物排放标准11 . GB50116-1998 Code for Design of Automatic Fire Alarm System火灾自动报警系统设计规范12 . SH3063-1999 Specification for the Design of Combustible Gas and Toxic gas Detection and Alarm for Petrochemical Enterprises石油化工企业可燃气体和有毒气体检测报警设计规范13 . GB9078-1996 Emission Standard of Air Pollutants for Industrial Kiln and Furnace工业炉窑大气污染物排放标准14 . GHZB1-1999 Environmental Quality Standard for Surface WaterGB3838-2002地表水环境质量标准15 . GB3096-93 Standard of Environmental Noise of Urban Area城市区域环境噪声标准16 . SH3024 –95 Design Specification for Environmental Protection in PetrochemicalIndustry石油化工企业环境保护设计规范17 . GB5044-85 Classification of Health Hazard Levels for Occupational Exposureto Toxic Substances职业性接触毒物危害程度分级18 . GB5749-85 Sanitary Standard for Drinking Water生活饮用水卫生标准19 . SH3047-93 Design Specification for Occupational Safety and Hygiene inPetrochemical Industry石油化工企业职业安全卫生设计规范20 . GB/T16157-The Determination of Particulates and Sampling Methods of Gaseous1996 Pollutants Emitted from Gas of Stationary Source固定污染源排气中颗粒物测定与气态污染物采样方法21 . GB11914-89 Water Quality – Determination of the Chemical Oxygen Demand(Dichromate Method )水质化学需氧量的测定重铬酸盐法22 . GB3095-ent Air Quality Standard环境空气质量标准23 . Law of the people’s Republic of China onPrevention and Control of Pollution of the Environment by Solid Wastes固体废物污染环境防治法24 . GB13223-96Emission Standard of Air Pollutants for fossil power plants火电厂大气污染排放标准25. GB150-1998 Steel pressure vessels钢制压力容器26 . GB50033-91 Standard for daylighting design of industrial enterprises27 . GB50034-92 Standard for artificial lighting design of industrial enterprises28 . GB50052-95Code for design of electric power trans29 . GB50053-94Code for design of 10kV and under Electric Substation10kV30 . GB50054-95Code for design of low-voltage Electrical distribution System31 . GB50055-93Code for design ofelectric distribution of general-purpose utilizationequipment32 . GB50056-93Code for design of electrical equipment of electroheat installations33 . GB50057-94Design code for lightning protection of buildings34 . GB50062-92Design Code for Protection Relay and Automatic Device of ElectricPower installation35 . GB50191-93Design Code for Antiseismic of Special Structures36 . SH3007-1999 Code for Design of Tank Farm in Petrochemical Storage andTransportation System37 . SH3038-2000 Code for Electric Power Design in Petrochemical Plants38 . SH3076-96 Code for Design of Building Structures of Petrochemical Enterprises39 . SH3017-1999 Architectural code of petrochemical production design40 . SH3006- for the Design of Control room and Analyzer room forPetrochemical industry41 . GB50151-92 Code of Design for Low expansion foa42 . GB50040-96 Code of Design of Dynamic Machine Foundation43 . GB/T17116.1 Pipe supports and hangerspart 1 : technical specification-199744 . GB/T17116.2 Pipe supports and hangerspart 2 : pipe attachments-199745 . GB/T17116.3 Pipe supports and hangerspart 3 : middle connection attachment and工业企业采光设计标准工业企业照明设计标准 mission and distribution system 供配电系统设计规范以下变电所设计规范低压配电设计规范通用用电设备配电设计规范电热设备电力装置设计规范建筑物防雷设计规范电力装置的继电保护和自动装置设计规范构筑物抗震设计规范石油化工储运系统罐区设计规范石油化工企业生产装置电力设计技术规范石油化工企业建筑物结构设计规范石油化工生产建筑设计规范石油化工控制室和自动分析室设计规范 m Extinguishing System 低倍数泡沫灭火系统设计规范动力机器基础设计规范管道支吊架第1部分: 技术规范管道支吊架第2部分: 管道连接部件-1997 building structure attachments管道支吊架第3部分: 中间连接件和建筑结构连接46 . JGJ94-94 Technical Code for building pile Foundation建筑桩基技术规范47 . SH3004-gn code for heating , ventilation and air conditioning inPetrochemical industry石油化工采暖通风与空气调节设计48 . GBJ19-87Design code for heating , ventilation and air conditioning采暖通风与空气调节设计规范49 . GB12358-90 Gas monitors and alarms for workplace atmosphere general technical requirements作业环境气体检测报警仪通用技术要求50 . GB50217-94 Code for Design of Cables ofElectrical Work电力工程电缆设计规范51 . GB50192-93 Code for design of river port engineering河港工程设计规范52 . GB/T13894-92 Petroleum and liquid petroleum products – Measurement of liquid level intank – Manual method石油和液体石油产品液位测量法(手工法)53 . SH0164-92 Rules for the Packing , Storage , Transportation and Inspection uponDelivery of Petroleum products石油产品包装、贮运及交货验收规则54 . SY5671-93 Petroleum and liquid petroleum Products – Flow Meters Hand OverSYL03-83 Metering Procedure石油及液体石油产品流量计交接计量规程55 . SH3097-2000 Code for the Design of Static Electricity Grounding for PetrochemicalIndustry石油化工静电接地设计规范56 . SHJ43-91 Surface Color and Identification of Equipment and piping inPetrochemical Enterprises石油化工企业设备管道表面色和标志57 . GB/T14549-93 Quality of electric energy supply Harmonics in public supply network电能质量公用电网諧波58 . SINOPECProvisions of Safety valve Settings Made by SINOPEC2001 NO.30中国石化集团公司安全阀设置规定59 . Regulation Regulation on Safety and Technical Supervision of Pressure Vesselsfor PV 压力容器安全技术监察规程60 . GBJ16-87Code for Fire Prevention of Building Design---- Partially Revised Articles and Their Notes建筑防火规范---局部修订条文及其条文说明61 . GBJ9-87 Load Code for the Design of Building Structures建筑结构荷载规范GBJ9-87 has been replaced by GB50009-200162 . JGJ106-2003 Technical code for testing of building foundation Piles建筑基桩检测技术规范63 . JGJ/T93-95 Specification for Low Strain Dynamic Testing of Piles基桩低应变动力检测规程64 . GB/T50269-97 Code for Measurement Method of Dynamic Properties of Subsoil地基动力特性测试规范65 . Fagui 00 A Summary of Laws and Regulation( 12 )规划环保劳动安全卫生消防方面的法规 ( 12 件 )66 . GB/T3840-91Technical Methods for Making Local Emission Standards of Air Pollutants制定地方大气污染物排放标准的技术方法67 . HG20660-91 Classification of Toxicity Hazard and Explosion Risk Extent of ChemicalHGJ43-91 Medium in Pressure Vessels压力容器中化学介质毒性危害和爆炸危险程度分类68 . JTJ237-99 Code for Fire-prevention Design of Oil loading/unloading Terminals装卸油品码头防火设计规范69 . Doc. JSL-65 Decree NO.JSL 65 of the Ministry of Construction ofThe people’s Republic of ChinaManagement Provision on Market of Survey and Design for construction Projects建设部第65号令建设工程勘察设计市场管理规定70 . Doc. JS2000-17Supplementary Notice for Strengthenting the Management of Permit ofEntry into Survey and Design Market建设部建设[2000]17号关于加强勘察设计市场准入管理的补充通知71 . Doc. NJZ98-513 Document of The construction mission of NanjingManagement Measures of Nanjing for permit of Entry into Project Survey and Design Market南京市建委宁建字[98]513号南京市工程勘察设计市场准入管理办法72 . Regulation for SBSteam Boiler Safety Technology Supervisory Regulations蒸汽锅炉安全技术监察规程73 . SH3022-1999 Technical specification for the coating anticorrosion of equipment and piping in petrochemical industry石油化工设备和管道涂料防腐蚀技术规范74 .The Compulsory Provision of Engineering Construction Standards Building工程建设标准强制性条文房屋建筑部分75 .The Compulsory Provision of Engineering Construction Standards Petroleum and Chemical Engineering工程建设标准强制性条文石油和化工建设工程部分76 . SHSG-050-98 Provision for Overall Design of a Large-scale Construction Project in Petrochemical Industry石油化工大型建设项目总体设计內容规定77 . SH3405-96 Series of Steel Pipe Size for Petrochemical Enterprise石油化工企业钢管尺寸系列78 . SH3406-96 Steel Pipe Flanges for Petrochemical Industry石油化工钢制管法兰79 . GB/T8163-less Steel Tubes for Liquid Service输送流体用无缝钢管80 . GB5310-1995 Seamless Steel Tubes and Pipes for High Pressure Boiler高压锅炉用无缝钢管81 . GB/T14976-94 Stainless Steel Seamless Pipes for Fluid Transport流体输送用不锈钢无缝钢管82 . GB/T12771-2000 Welded Stainless Steel Pipes for Liquid Delivery流体输送用不锈钢焊接钢管83 . GWKB2-ution Control Standard for Hazardous Wastes Incineration GB18484-2001 危险废物焚烧污染控制标准84 . GB12337-1998 Steel Spherical Tanks钢制球形储罐85 . GWPB3-sion Standard of Air Pollutants for Coal-burning Oil-burning GB13271-2001 Gas-fired Boiler锅炉大气污染物排放标准 2002-03-1286 . SHS01009-92Maintenance and Service Procedure for Shell and Tube Exchanger 管壳式换热器维护检修规程87 . SHS01018-92Maintenance and Service Procedure for Centrifugal Air Compressor离心式空气压缩机维护检修规程88 . SHS01030-92Maintenance and Service Procedure for Valves阀门维护检修规程89 . SHS03 44 –92 Maintenance and Service Procedure for High-speed Centrifugal Pump 高速离心泵维护检修规程90 . GB/T699-1999 Quality Carbon Structural Steels优质碳素结构钢91 . GB/T711-88 Hot-rolled Quality Carbon Structural Steels Plates and Wide Strips优质碳素结构钢热轧厚钢板和宽钢带92 . GB/T5468-91Measurement Method of Smoke and Dust Emission from Boilers 锅炉烟尘测试方法93 . DL/T5103-1999 Design Code for Unattended Substation of 35kV~110kV35kV~110kV 无人值班变电所设计规程94 . HG/T20586-96Technical Regulations for Lighting Design in Chemical Enterprises 化工企业照明设计技术规定95 . JB4726-on and Low- alloy Steel Forgings for Pressure Vessels压力容器用碳素钢和低合金钢锻件 2002.04.25 96 . SHSG-033-98 Basic Design ( Preliminary Design ) Definition for Petrochemical Plant石油化工装置基础设计 ( 初步设计 ) 内容规定97 . DL5000-2000 Technical Code for Designing Fossil Fuel Power Plants火力发电厂设计技术规程98 . JB4730-94 Nondestructive Testing of Pressure Vessels压力容器无损检测99 . DL408-91 Working Regulation of Power Safety电业安全工作规程 2002-05-10100 . GB4452-1996 General Technical Specification for Hydrant室外消火栓通用技术条件101 . JB4727-2000 Low-alloy steel forgings for low temperature pressure vessels低温压力容器用低合金钢锻件102 . GB252-2000 Light Diesel Fuels轻柴油103 .Hygienic Standard for Industrial Enterprise Noise工业企业噪声卫生标准It has been replaced by GBZ1-2002104 . DL/T620 Overvoltage protection and insulation coordination for AC-1997 electrical installations交流电气装置的过电压保护和绝缘配合 105 . GB50316-2000 Design code for industrial metallic piping工业金属管道设计规范106 . Regulation Regulation on Safety Management and Supervision overfor PP Pressure Pipelines压力管道安全管理与监察规定107 . GB50235-97 Code for construction and acceptance of industrial metallic piping工业金属管道工程施工及验收规范108 . GB50236-98 Cod e for construction and acceptance of field equipment ,industrial pipe welding engineering现场设备、工业管道焊接工程施工及验收规范109 . GB50150-91 Standard for hand-over test of electric equipmentelectric equipment installation engineering电气装置安装工程电气设备交接试验标准110 . GB50168-92 Code for construction and acceptance of cable levels electric equipmentinstallation engineering电气装置安装工程电缆线路施工及验收规范111 . GB50184-93 Standard for quality inspection and assessment of industrial metalpipeline engineering工业金属管道工程质量检验评定标准112 . GBJ126-89Code for construction and acceptance of industrial equipment and pipeline insulation engineering工业设备及管道绝热工程施工及验收规范113 . GBJ211-87Code for construction and acceptance of industrial furnace masoy engineering工业炉砌筑工程施工及验收规范114 . JB4708-ssment of steel pressure vessels welding technology钢制压力容器焊接工艺评定115 . JB/4709-2000 Welding specification for steel pressure vessels篇三：土木工程方面英文规范汇总下载土木工程方面英文规范汇总下载1、/dzcn/viewthread.php?tid=3612&extra=page%3D1英国规范 - 土方工程 Earthworks BS60312、/dzcn/viewthread.php?tid=4526&extra=page%3D1美国结构设计规范合集3、/dzcn/viewthread.php?tid=5982&extra=page%3D1 BS 6399 - Loading for Buildings.part1-34、/dzcn/viewthread.php?tid=3864&extra=page%3D1 BS5400 钢筋混凝土英国规范（全）挡土结构设计规范 [英6、/dzcn/viewthread.php?tid=1373&extra=page%3D1 结构混凝土规范 Structural use of concrete [BS8110]7、/dzcn/viewthread.php?tid=1989&extra=page%3D1 BS 1377 英国BS试验规范8、/dzcn/viewthread.php?tid=629&extra=page%3D1BS8004 英国规范 - 地基基础 Foundations9、/dzcn/viewthread.php?tid=3418&extra=page%3D1英国场地勘察规范最新版 BS5930:199910、/dzcn/viewthread.php?tid=4977&extra=page%3D1美国钢结构焊接规范2006版 AWS D1.1/D1.1M-200611、/dzcn/viewthread.php?tid=6002&extra=page%3D1 ASTMD 6640_01-2005 环境勘察用岩心管样品机获取的土壤的收集和处置的标准实施规程12、/dzcn/viewthread.php?tid=5774&extra=page%3D1美国安全颜色规范 ASME standard Z535.1 Safety Color Code13、/dzcn/viewthread.php?tid=3958&extra=page%3D1挡水性液体混凝土结构设计 BS800714、/dzcn/viewthread.php?tid=4492&extra=page%3D1屋顶施加载荷BS6399-3-1988 Imposed roof loads15、/dzcn/viewthread.php?tid=4312&extra=page%3D1BS2633规范公路BS规范大全目录17、/dzcn/viewthread.php?tid=4066&extra=page%3D1公路施工标准规程 Standard Specifications for Highway Construction - 2007 Edition18、/dzcn/viewthread.php?tid=2516&extra=page%3D1国际建筑物规范 International Building Code 200619、/dzcn/viewthread.php?tid=332&extra=page%3D2英国勘察规范 BS593020、/dzcn/viewthread.php?tid=3115&extra=page%3D2桥梁施工英国规范 BS 5400 Bridge Construction21、/dzcn/viewthread.php?tid=4458&extra=page%3D2澳大利亚混凝土规范AS360022、/dzcn/viewthread.php?tid=3054&extra=page%3D 25个国外铁路相关标准(英文)23、/dzcn/viewthread.php?tid=3019&extra=page%3D2欧洲的风荷载规范24、/dzcn/viewthread.php?tid=1242&extra=page%3D2加强/加筋土和回填规范 - Strengthened/reinforced soils and other fills - BS 800625、/dzcn/viewthread.php?tid=4259&extra=page%3D2可焊接的钢结构 BS4360：1990 Weldable structural steels26、/dzcn/viewthread.php?tid=3852&extra=page%3D2砌体结构规程 Specification for Masoy Structures - ACI 5301文）钢设计 - 英国标准规范BS5950指南28、/dzcn/viewthread.php?tid=2476&extra=page%3D2 ASCE 标准-房屋及其他建筑物最小设计负荷29、/dzcn/viewthread.php?tid=2301&extra=page%3D2美国桩基规范30、/dzcn/viewthread.php?tid=3401&extra=page%3D2 2100个美国材料规范 ASTM Standards31、/dzcn/viewthread.php?tid=3828&extra=page%3D2建筑专业标准规范大全32、/dzcn/viewthread.php?tid=4001&extra=page%3D2中国桩基规范（英文版）33、/dzcn/viewthread.php?tid=4257&extra=page%3D3 BS-EN 方面关于钢结构的标准规范34、/dzcn/viewthread.php?tid=1423&extra=page%3D3建筑结构钢的使用规范 - The Use of Structural Steel in Building BS 449-235、/dzcn/viewthread.php?tid=4118&extra=page%3D3结构混凝土建筑规范要求及注释 ACI-318-9936、/dzcn/viewthread.php?tid=1372&extra=page%3D3低层房屋结构设计规范 Structural Design for Low-rise building [BS 8103]37、/dzcn/viewthread.php?tid=1366&extra=page%3D3地面锚固规范 - Ground Anchorages BS80816399 Loading for Buildings Part 1 Dead and imposed loads 建筑静荷载和施加荷载39、/dzcn/viewthread.php?tid=3132&extra=page%3D3欧洲岩土设计规范（第1部分基本原则）Eurocode 7 Geotechnical Design40、/dzcn/viewthread.php?tid=3917&extra=page%3D3混凝土材料和施工方法&混凝土试验方法和实用标准CSA A23.1-04 & A23.2-0441、/dzcn/viewthread.php?tid=3898&extra=page%3D3土方与爆破工程GBJ 201-83 Earthworks and Explosion Works42、/dzcn/viewthread.php?tid=3682&extra=page%3D3钢结构极限状态设计[加拿大规范]Steel Structures(Canada)43、/dzcn/viewthread.php?tid=3799&extra=page%3D3[解决]求加国CSA A23.3-94 (R2000) Design of Concrete Structures44、/dzcn/viewthread.php?tid=3603&extra=page%3D3BS6164-1990英国隧道工程施工规范45、/dzcn/viewthread.php?tid=343&extra=page%3D3物探规范EM1110-1-180246、/dzcn/viewthread.php?tid=2774&extra=page%3D3[英] 香港2004桩基规范 FoundationCode2004_HK47、/dzcn/viewthread.php?tid=2058&extra=page%3D3 BS 4190 - 螺钉螺母螺帽 - Bolts, Screws and Nuts <!--[if !vml]--><!--[endif]-->48、/dzcn/viewthread.php?tid=1948加固/加筋土和其它回填土 BS 8006 - Strengthened/reinforced soils and other fills。

PASAR结构专业英汉对照一、规范或图集《建筑结构可靠度设计统一标准》：Unified standard for reliability design of building structures《建筑结构荷载规范》：Load code for the design of building structures《钢结构设计规范》：Code for design of steel structures《建筑抗震设计规范》：Code for seismic design of buildings《混凝土结构设计规范》：Code for design of concrete structures《建筑地基基础设计规范》：Code for design of building foundation《门式刚架轻型房屋钢结构技术规程》：Technical specification for steel structure of light-weight Buildings with gabled frames《钢筋混凝土筒仓设计规范》：Code for design of reinforced concrete silos《砌体结构设计规范》：Code for design of masonry structures《高层建筑混凝土结构技术规程》：Technical specification for concrete structures of tall building《高层民用建筑钢结构技术规程》：Technical specification for steel structure of tall buildings《混凝土结构加固设计规范》：Design code for strengthening concrete structure 《钢结构加固技术规范》：Technical specification for strengthening steel structures 《工业建筑防腐蚀设计规范》：Code for Anticorrosion Design of IndustrialConstructionsPermanent load：恒载Live load: 活载Snow load:雪荷载Snow region : 雪压分布区Reference snow pressure:基本雪压Wind load：风荷载Wind region:风压分布区Reference wind pressure:基本风压Terrain roughness:地面粗糙度Crane load:吊车荷载Seismicity 6 points：地震烈度6点（不能简单认为中国规范6度）二、常用语1、混凝土结构Concrete structure :混凝土结构（包括素砼结构、钢筋砼结构、预应力砼结构）Plain concrete structure:素混凝土结构Reinforced Concrete structure :钢筋混凝土结构Prestressed Concrete structure :预应力混凝土结构Cast-in-situ Concrete structure :现浇混凝土结构Structural joint:结构缝（分割混凝土结构间隔的总称）Expansion joint:伸缩缝Deep beam:深梁Steel bar :普通钢筋Reinforcing bar ：钢筋（通常指受力钢筋）Reinforcing rod：钢筋（在钢筋混凝土中使用的各种钢筋）Hoop reinforcement:箍筋（螺旋形箍筋除外）Stirrup:箍筋spacing of stirrups:箍筋间距spiral reinforcements:螺旋筋fabric reinforcements:钢筋网Transverse reinforcement:横向钢筋（垂直纵向受力钢筋的箍筋或间接钢筋）Hot rolled deformed bars :热轧带肋钢筋Hot rolled plain round bars :热轧光圆钢筋Anchorage length:锚固长度Concrete cover：混凝土保护层Topping:面层(也可指砂浆)Bar diameter:钢筋直径Foundation:基础Concrete wall:混凝土墙（泛指用混凝土做的墙体）Frame beams:框架梁Frame columns:框架柱Columns of bent:排架柱Columns supporting structural transfer member:框支柱Shear walls and coupling beams:剪力墙和连梁Cantilever beam:悬臂梁Slab:板（泛指混凝土板及其他板）Slab on ground：地面上的混凝土板Suspended slabs:楼面板Ratio of reinforcement:配筋率Embedded parts:预埋件Lap length：搭接长度Rejointing :勾缝，填缝Fist pour:第一期浇灌Second pour：第二期浇灌Fine aggregate concrete:细石混凝土Concrete with strength level is no lower than C30:混凝土强度等级不低于C30（《建筑地基基础设计规范》描述）The concrete strength grade shall not be less than C30: 混凝土强度等级不低于C30（《混凝土结构设计规范》描述）The stressed steel bars adopt the HRB400,Stirrups adopt HRB300:受力钢筋采用HRB400，箍筋采用HRB300Anchorage of steel reinforcement:钢筋的锚固The impermeability grade of concrete:混凝土抗渗等级2、地基基础Earth work:地基工程Ground(foundation soils):地基Retaining wall：挡（土）墙Gravity Retaining wall：重力式挡墙Pedestals：设备底座Characteristic value of subsoil bearing capacity:地基承载力特征值Ground treatment(ground improvement):地基处理Strip footing under column:柱下条形基础Pile foundation:桩基础End-bearing pile :端承桩50 thick concrete blinding：50厚混凝土基础垫层Concrete blinding C15 : C15混凝土垫层C15 plain concrete:C15 素混凝土Residual soil：原积土Design grade of foundation:基础设计等级Grade A：甲级Anti-floating checking：抗浮验算Rock, gravelly soil, sandy soil, silty soil, cohesive soil, artificial fill:岩石，碎石土，砂土，粉土，黏性土，人工填土Plain fill:素填土Compacted fill:压实填土Miscellaneous fill:杂填土Compacted coefficient:压实系数Embedded depth of foundation:基础埋置深度3、钢结构Steel work:钢结构工程Steel structure:钢结构Pure frames:(无支撑)纯框架Braced frames:有支撑框架Wind column:抗风柱Wind beam:抗风梁或抗风系杆Brackets:牛腿Connector（Connecting pieces）:连接件Supports(bearings):支座Hinged bearing：铰支座，铰支承Composite steel and concrete beam:钢与混凝土组合梁Beam:梁Column:柱Leaning column：摇摆柱（框架内两端为铰接不能抵抗侧向荷载的柱）Purlin :檩条Girt:围梁，也可指墙面檩条Manhole：人孔Eot crane: 电动桥式起重机Underslung crane:悬挂吊车Crane rail:吊车轨道Crane stop :吊车车挡Crane girders(Crane beam &Crane runway):吊车梁Planed and tightly fitted:刨平顶紧Cantrex rail clip:吊车轨道固定夹10 PL. Stiffener: 10厚加劲板PL 10: 10厚钢板6 Gap: 6mm缝隙Column web：柱腹板Web plate:腹板Column flange:柱翼缘板Flange plate:翼缘板Web stiffener:腹板加劲板(Column )cap plate: (柱)顶板(Column) base plate: (柱)底板M20 bolt: M20螺栓4 Holes φ20：4个φ20孔High strength bolt(H.D bolt)：高强螺栓Commercial bolt：普通螺栓4M20 anchor bolts: 4M20 地脚螺栓4M16 Chemical anchors: 4M16化学螺栓Bolt property grade:螺栓的性能等级（8.8级或10.9级）Stud:栓钉Stair tread：楼梯踏步Handrail：扶手栏杆Platform:平台（一般的操作或检修平台）50 Grouting：50厚灌浆层（还指钢平台上铺的混凝土板）32 Grating :32厚钢格栅Corrugated steel plate(Checkered plate)：花纹钢板Vertical brace:竖直支撑（垂直剪刀撑）Horizontal brace:水平支撑Ties:系杆Sag rod:直拉条Angle brace：隅撑The lace on built-up members:组合构件的缀条Shear resistant key(Shear key):抗剪件Cable tray support：电缆槽支架Pipe support:管道支架Stiffener both sides:两边布置加劲板Splice:拼接（钢构件设置的拼接）Plate 10:10厚钢板（PL 10）Filler plate:填板Check nut （locknut）:防松螺母（可指地脚螺栓柱脚钢板上的第二颗螺母）Truss:桁架Truss member:桁架杆件Web member:腹杆Chord :弦杆，也可指拱的跨度End post:（桁架）端部受压杆Weld:焊接Weld tube :焊接管Weld:焊缝Butt weld:对接焊缝Fillet weld:角焊缝Groove:坡口The quality level of welds shall not be lower than class 2:焊缝质量等级不低于2级Full penetration:全熔透Topping coat：外涂层，面漆Finishing coat：面漆Primer:底漆Priming:上底漆Blast cleaning:喷砂清洗，喷砂除锈Dry film :干膜Slip coefficient at friction interface:摩擦面的抗滑移系数Fire protection coating:防火涂料Beam-to-beam connection:梁梁连接节点Beam-to-column connection:梁柱连接节点Rigid connection:刚接Hinged connection：铰接H-section:H型截面box-section:箱型截面The inserted column base:插入式柱脚The encased column base：埋人式柱脚The encasing column base：外包式柱脚Span:跨度Bay:开间Bay spacing:柱距Slope:坡度Roof slope 5°: 屋面坡度5度Eaves:屋檐Eaves gutter(gutter):天沟Canopy:雨棚，挑棚Detailing requirements:构造要求4、改造工程Strengthening work:加固工程Existing：现有的，列如：Existing foundation:现有基础Existing structure member:原构件Strengthening of existing structures:对已有结构加固Structure member strengthening with reinforced concrete:增大截面加固法Structure member strengthening with externally bonded steel frame:外粘型钢加固法Structure member strengthening with externally bonded reinforced materials:复合截面加固法unloading:卸载Hacking:凿毛Bonded rebars:植筋4M16 Chemical anchors: 4M16化学螺栓Structrual adhesives:结构胶Fibre reinforced polymer (FRP):纤维复合材Polymer nirtar:聚合物砂浆polymer mortar：复合砂浆Corrosion inhibitor：阻锈剂Reshoring:临时支撑（原始的支撑拆除后，用于模板或整体结构的临时支撑）the interface of new and existing shall be hacking , and cleaning, then cast in concrete.:新旧砼交接处，应先凿毛、并清洗干净，再浇筑砼。

Structural Systems to resist lateral loadsCommonly Used structural SystemsWith loads measured in tens of thousands kips, there is little room in the design of high-rise buildings for excessively complex thoughts. Indeed, the better high-rise buildings carry the universal traits of simplicity of thought and clarity of expression.It does not follow that there is no room for grand thoughts. Indeed, it is with such grand thoughts that the new family of high-rise buildings has evolved. Perhaps more important, the new concepts of but a few years ago have become commonplace in today’ s technology.Omitting some concepts that are related strictly to the materials of construction, the most commonly used structural systems used in high-rise buildings can be categorized as follows:1.Moment-resisting frames.2.Braced frames, including eccentrically braced frames.3.Shear walls, including steel plate shear walls.4.Tube-in-tube structures.5.Tube-in-tube structures.6.Core-interactive structures.7.Cellular or bundled-tube systems.Particularly with the recent trend toward more complex forms, but in response also to the need for increased stiffness to resist the forces from wind and earthquake, most high-rise buildings have structural systems built up of combinations of frames, braced bents, shear walls, and related systems. Further, for the taller buildings, the majorities are composed of interactive elements in three-dimensional arrays.The method of combining these elements is the very essence of the design process for high-rise buildings. These combinations need evolve in response to environmental, functional, and cost considerations so as to provide efficient structures that provoke the architectural development to new heights. This is not to say that imaginative structural design can create great architecture. To the contrary, many examples of fine architecture have been created with only moderate support from the structural engineer, while only fine structure, not great architecture, can be developed without the genius and the leadership of a talented architect. In any event, the best of both isneeded to formulate a truly extraordinary design of a high-rise building.While comprehensive discussions of these seven systems are generally available in the literature, further discussion is warranted here .The essence of the design process is distributed throughout the discussion.Moment-Resisting FramesPerhaps the most commonly used system in low-to medium-rise buildings, the moment-resisting frame, is characterized by linear horizontal and vertical members connected essentially rigidly at their joints. Such frames are used as a stand-alone system or in combination with other systems so as to provide the needed resistance to horizontal loads. In the taller of high-rise buildings, the system is likely to be found inappropriate for a stand-alone system, this because of the difficulty in mobilizing sufficient stiffness under lateral forces.Analysis can be accomplished by STRESS, STRUDL, or a host of other appropriate computer programs; analysis by the so-called portal method of the cantilever method has no place in today’s technology.Because of the intrinsic flexibility of the column/girder intersection, and because preliminary designs should aim to highlight weaknesses of systems, it is not unusual to use center-to-center dimensions for the frame in the preliminary analysis. Of course, in the latter phases of design, a realistic appraisal in-joint deformation is essential.Braced Frame sThe braced frame, intrinsically stiffer than the moment –resisting frame, finds also greater application to higher-rise buildings. The system is characterized by linear horizontal, vertical, and diagonal members, connected simply or rigidly at their joints. It is used commonly in conjunction with other systems for taller buildings and as a stand-alone system in low-to medium-rise buildings.While the use of structural steel in braced frames is common, concrete frames are more likely to be of the larger-scale variety.Of special interest in areas of high seismicity is the use of the eccentric braced frame.Again, analysis can be by STRESS, STRUDL, or any one of a series of two –or threedimensional analysis computer programs. And again, center-to-center dimensions are used commonly in the preliminary analysis.Shear wallsThe shear wall is yet another step forward along a progression of ever-stiffer structural systems. The system is characterized by relatively thin, generally (but not always) concrete elements that provide both structural strength and separation between building functions.In high-rise buildings, shear wall systems tend to have a relatively high aspect ratio, that is, their height tends to be large compared to their width. Lacking tension in the foundation system, any structural element is limited in its ability to resist overturning moment by the width of the system and by the gravity load supported by the element. Limited to a narrow overturning, One obvious use of the system, which does have the needed width, is in the exterior walls of building, where the requirement for windows is kept small.Structural steel shear walls, generally stiffened against buckling by a concrete overlay, have found application where shear loads are high. The system, intrinsically more economical than steel bracing, is particularly effective in carrying shear loads down through the taller floors in the areas immediately above grade. The sys tem has the further advantage of having high ductility a feature of particular importance in areas of high seismicity.The analysis of shear wall systems is made complex because of the inevitable presence of large openings through these walls. Preliminary analysis can be by truss-analogy, by the finite element method, or by making use of a proprietary computer program designed to consider the interaction, or coupling, of shear walls.Framed or Braced TubesThe concept of the framed or braced or braced tube erupted into the technology with the IBM Building in Pittsburgh, but was followed immediately with the twin 110-story towers of the World Trade Center, New York and a number of other buildings .The system is characterized by three –dimensional frames, braced frames, or shear walls, forming a closed surface more or less cylindrical in nature, but of nearly any plan configuration. Because those columns that resist lateral forces are placed as far as possible from the cancroids of the system, the overall moment ofinertia is increased and stiffness is very high.The analysis of tubular structures is done using three-dimensional concepts, or by two- dimensional analogy, where possible, whichever method is used, it must be capable of accounting for the effects of shear lag.The presence of shear lag, detected first in aircraft structures, is a serious limitation in the stiffness of framed tubes. The concept has limited recent applications of framed tubes to the shear of 60 stories. Designers have developed various techniques for reducing the effects of shear lag, most noticeably the use of belt trusses. This system finds application in buildings perhaps 40stories and higher. However, except for possible aesthetic considerations, belt trusses interfere with nearly every building function associated with the outside wall; the trusses are placed often at mechanical floors, mush to the disapproval of the designers of the mechanical systems. Nevertheless, as a cost-effective structural system, the belt truss works well and will likely find continued approval from designers. Numerous studies have sought to optimize the location of these trusses, with the optimum location very dependent on the number of trusses provided. Experience would indicate, however, that the location of these trusses is provided by the optimization of mechanical systems and by aesthetic considerations, as the economics of the structural system is not highly sensitive to belt truss location.Tube-in-Tube StructuresThe tubular framing system mobilizes every column in the exterior wall in resisting over-turning and shearing forces. The term‘tube-in-tube’is largely self-explanatory in that a second ring of columns, the ring surrounding the central service core of the building, is used as an inner framed or braced tube. The purpose of the second tube is to increase resistance to over turning and to increase lateral stiffness. The tubes need not be of the same character; that is, one tube could be framed, while the other could be braced.In considering this system, is important to understand clearly the difference between the shear and the flexural components of deflection, the terms being taken from beam analogy. In a framed tube, the shear component of deflection is associated with the bending deformation of columns and girders (i.e, the webs of the framed tube) while the flexural component is associated with the axial shortening and lengthening of columns (i.e, the flanges of the framed tube). In a braced tube, the shear component of deflection is associated with the axial deformation ofdiagonals while the flexural component of deflection is associated with the axial shortening and lengthening of columns.Following beam analogy, if plane surfaces remain plane (i.e, the floor slabs),then axial stresses in the columns of the outer tube, being farther form the neutral axis, will be substantially larger than the axial stresses in the inner tube. However, in the tube-in-tube design, when optimized, the axial stresses in the inner ring of columns may be as high, or even higher, than the axial stresses in the outer ring. This seeming anomaly is associated with differences in the shearing component of stiffness between the two systems. This is easiest to under-stand where the inner tube is conceived as a braced (i.e, shear-stiff) tube while the outer tube is conceived as a framed (i.e, shear-flexible) tube.Core Interactive StructuresCore interactive structures are a special case of a tube-in-tube wherein the two tubes are coupled together with some form of three-dimensional space frame. Indeed, the system is used often wherein the shear stiffness of the outer tube is zero. The United States Steel Building, Pittsburgh, illustrates the system very well. Here, the inner tube is a braced frame, the outer tube has no shear stiffness, and the two systems are coupled if they were considered as systems passing in a straight line from the “hat” structure. Note that the exterior columns would be improperly modeled if they were considered as systems passing in a straight line from the “hat” to the foundations; these columns are perhaps 15% stiffer as they follow the elastic curve of the braced core. Note also that the axial forces associated with the lateral forces in the inner columns change from tension to compression over the height of the tube, with the inflection point at about 5/8 of the height of the tube. The outer columns, of course, carry the same axial force under lateral load for the full height of the columns because the columns because the shear stiffness of the system is close to zero.The space structures of outrigger girders or trusses, that connect the inner tube to the outer tube, are located often at several levels in the building. The AT&T headquarters is an example of an astonishing array of interactive elements:1.The structural system is 94 ft (28.6m) wide, 196ft(59.7m) long, and 601ft (183.3m) high.2.Two inner tubes are provided, each 31ft(9.4m) by 40 ft (12.2m), centered 90 ft (27.4m)apart in the long direction of the building.3.The inner tubes are braced in the short direction, but with zero shear stiffness in the longdirection.4. A single outer tube is supplied, which encircles the building perimeter.5.The outer tube is a moment-resisting frame, but with zero shear stiffness for the center50ft(15.2m) of each of the long sides.6. A space-truss hat structure is provided at the top of the building.7. A similar space truss is located near the bottom of the building8.The entire assembly is laterally supported at the base on twin steel-plate tubes, because theshear stiffness of the outer tube goes to zero at the base of the building.Cellular structuresA classic example of a cellular structure is the Sears Tower, Chicago, a bundled tube structure of nine separate tubes. While the Sears Tower contains nine nearly identical tubes, the basic structural system has special application for buildings of irregular shape, as the several tubes need not be similar in plan shape, It is not uncommon that some of the individual tubes one of the strengths and one of the weaknesses of the system.This special weakness of this system, particularly in framed tubes, has to do with the concept of differential column shortening. The shortening of a column under load is given by the expression△=ΣfL/EFor buildings of 12 ft (3.66m) floor-to-floor distances and an average compressive stress of 15 ksi (138MPa), the shortening of a column under load is 15 (12)(12)/29,000 or 0.074in (1.9mm) per story. At 50 stories, the column will have shortened to 3.7 in. (94mm) less than its unstressed length. Where one cell of a bundled tube system is, say, 50stories high and an adjacent cell is, say, 100stories high, those columns near the boundary between .the two systems need to have this differential deflection reconciled.Major structural work has been found to be needed at such locations. In at least one building, the Rialto Project, Melbourne, the structural engineer found it necessary to vertically pre-stress the lower height columns so as to reconcile the differential deflections of columns in closeproximity with the post-tensioning of the shorter column simulating the weight to be added on to adjacent, higher columns.原文翻译：抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

抗侧向荷载的结构体系外文翻译Company number：【WTUT-WT88Y-W8BBGB-BWYTT-19998】外文翻译一.原文：Structural Systems to resist lateral loads Commonly Used structural SystemsWith loads measured in tens of thousands kips, there is little room in the design of high-rise buildings for excessively complex thoughts. Indeed, the better high-rise buildings carry the universal traits of simplicity of thought and clarity of expression.It does not follow that there is no room for grand thoughts. Indeed, it is with such grand thoughts that the new family of high-rise buildings has evolved. Perhaps more important, the new concepts of but a few years ago have become commonplace in today’ s technology.Omitting some concepts that are related strictly to the materials of construction, the most commonly used structural systems used in high-rise buildings can be categorized as follows:1.Moment-resisting frames.2.Braced frames, including eccentrically braced frames.3.Shear walls, including steel plate shear walls.4.Tube-in-tube structures.5.Tube-in-tube structures.6.Core-interactive structures.7.Cellular or bundled-tube systems.Particularly with the recent trend toward more complex forms, but in response also to the need for increased stiffness to resist the forces from wind and earthquake, most high-rise buildings have structural systems built up of combinations of frames,braced bents, shear walls, and related systems. Further, for the taller buildings, the majorities are composed of interactive elements in three-dimensional arrays.The method of combining these elements is the very essence of the design process for high-rise buildings. These combinations need evolve in response to environmental, functional, and cost considerations so as to provide efficient structures that provoke the architectural development to new heights. This is not to say that imaginative structural design can create great architecture. To the contrary, many examples of fine architecture have been created with only moderate support from the structural engineer, while only fine structure, not great architecture, can be developed without the genius and the leadership of a talented architect. In any event, the best of both is needed to formulate a truly extraordinary design of a high-rise building.While comprehensive discussions of these seven systems are generally available in the literature, further discussion is warranted here .The essence of the design process is distributed throughout the discussion.Moment-Resisting FramesPerhaps the most commonly used system in low-to medium-rise buildings, the moment-resisting frame, is characterized by linear horizontal and vertical members connected essentially rigidly at their joints. Such frames are used as a stand-alone system or in combination with other systems so as to provide the needed resistance to horizontal loads. In the taller of high-rise buildings, the system is likely to be found inappropriate for a stand-alone system, this because of the difficulty in mobilizing sufficient stiffness under lateral forces.Analysis can be accomplished by STRESS, STRUDL, or a host of other appropriate computer programs; analysis by the so-called portal method of the cantilever method has no place in today’s technology.Because of the intrinsic flexibility of the column/girder intersection, and because preliminary designs should aim to highlight weaknesses of systems, it is not unusual to use center-to-center dimensions for the frame in the preliminary analysis. Of course, in the latter phases of design, a realistic appraisal in-joint deformation is essential. Braced Frame sThe braced frame, intrinsically stiffer than the moment –resisting frame, finds also greater application to higher-rise buildings. The system is characterized by linear horizontal, vertical, and diagonal members, connected simply or rigidly at their joints. It is used commonly in conjunction with other systems for taller buildings and as a stand-alone system in low-to medium-rise buildings.While the use of structural steel in braced frames is common, concrete frames are more likely to be of the larger-scale variety.Of special interest in areas of high seismicity is the use of the eccentric braced frame.Again, analysis can be by STRESS, STRUDL, or any one of a series of two –or three dimensional analysis computer programs. And again, center-to-center dimensions are used commonly in the preliminary analysis.Shear wallsThe shear wall is yet another step forward along a progression of ever-stiffer structural systems. The system is characterized by relatively thin, generally (but not always) concrete elements that provide both structural strength and separation between building functions.In high-rise buildings, shear wall systems tend to have a relatively high aspect ratio, that is, their height tends to be large compared to their width. Lacking tension in the foundation system, any structural element is limited in its ability to resist overturning moment by the width of the system and by the gravity load supported by the element. Limited to a narrow overturning, One obvious use of the system, which does have the needed width, is in the exterior walls of building, where the requirement for windows is kept small.Structural steel shear walls, generally stiffened against buckling by a concrete overlay, have found application where shear loads are high. The system, intrinsically more economical than steel bracing, is particularly effective in carrying shear loads down through the taller floors in the areas immediately above grade. The sys tem hasthe further advantage of having high ductility a feature of particular importance in areas of high seismicity.The analysis of shear wall systems is made complex because of the inevitable presence of large openings through these walls. Preliminary analysis can be by truss-analogy, by the finite element method, or by making use of a proprietary computer program designed to consider the interaction, or coupling, of shear walls.Framed or Braced TubesThe concept of the framed or braced or braced tube erupted into the technology with the IBM Building in Pittsburgh, but was followed immediately with the twin110-story towers of the World Trade Center, New York and a number of other buildings .The system is characterized by three –dimensional frames, braced frames, or shear walls, forming a closed surface more or less cylindrical in nature, but of nearly any plan configuration. Because those columns that resist lateral forces are placed as far as possible from the cancroids of the system, the overall moment of inertia is increased and stiffness is very high.The analysis of tubular structures is done using three-dimensional concepts, orby two- dimensional analogy, where possible, whichever method is used, it must be capable of accounting for the effects of shear lag.The presence of shear lag, detected first in aircraft structures, is a serious limitation in the stiffness of framed tubes. The concept has limited recent applications of framed tubes to the shear of 60 stories. Designers have developed various techniques for reducing the effects of shear lag, most noticeably the use of belt trusses. This system finds application in buildings perhaps 40stories and higher. However, except for possible aesthetic considerations, belt trusses interfere with nearly every building function associated with the outside wall; the trusses are placed often at mechanical floors, mush to the disapproval of the designers of the mechanical systems. Nevertheless, as a cost-effective structural system, the belt truss works well and will likely find continued approval from designers. Numerous studies have sought tooptimize the location of these trusses, with the optimum location very dependent on the number of trusses provided. Experience would indicate, however, that the location of these trusses is provided by the optimization of mechanical systems and by aesthetic considerations, as the economics of the structural system is not highly sensitive to belt truss location.Tube-in-Tube StructuresThe tubular framing system mobilizes every column in the exterior wall in resisting over-turning and shearing forces. The term‘tube-in-tube’is largely self-explanatory in that a second ring of columns, the ring surrounding the central service core of the building, is used as an inner framed or braced tube. The purpose of the second tube is to increase resistance to over turning and to increase lateral stiffness. The tubes need not be of the same character; that is, one tube could be framed, while the other could be braced.In considering this system, is important to understand clearly the difference between the shear and the flexural components of deflection, the terms being taken from beam analogy. In a framed tube, the shear component of deflection is associated with the bending deformation of columns and girders , the webs of the framed tube) while the flexural component is associated with the axial shortening and lengthening of columns , the flanges of the framed tube). In a braced tube, the shear component of deflection is associated with the axial deformation of diagonals while the flexural component of deflection is associated with the axial shortening and lengthening of columns.Following beam analogy, if plane surfaces remain plane , the floor slabs),then axial stresses in the columns of the outer tube, being farther form the neutral axis, will be substantially larger than the axial stresses in the inner tube. However, in the tube-in-tube design, when optimized, the axial stresses in the inner ring of columns may be as high, or even higher, than the axial stresses in the outer ring. This seeming anomaly is associated with differences in the shearing component of stiffness between the twosystems. This is easiest to under-stand where the inner tube is conceived as a braced , shear-stiff) tube while the outer tube is conceived as a framed , shear-flexible) tube.Core Interactive StructuresCore interactive structures are a special case of a tube-in-tube wherein the two tubes are coupled together with some form of three-dimensional space frame. Indeed, the system is used often wherein the shear stiffness of the outer tube is zero. The United States Steel Building, Pittsburgh, illustrates the system very well. Here, the inner tube is a braced frame, the outer tube has no shear stiffness, and the two systems are coupled if they were considered as systems passing in a straight line from the “hat” structure. Note that the exterior columns would be improperly modeled if they were considered as systems passing in a straight line from the “hat” to the foundations; these columns are perhaps 15% stiffer as they follow the elastic curve of the braced core. Note also that the axial forces associated with the lateral forces in the inner columns change from tension to compression over the height of the tube, with the inflection point at about 5/8 of the height of the tube. The outer columns, of course, carry the same axial force under lateral load for the full height of the columns because the columns because the shear stiffness of the system is close to zero. The space structures of outrigger girders or trusses, that connect the inner tube to the outer tube, are located often at several levels in the building. The AT&T headquarters is an example of an astonishing array of interactive elements:1.The structural system is 94 ft (28.6m) wide, 196ft(59.7m) long, and 601ft(183.3m) high.2.Two inner tubes are provided, each 31ft(9.4m) by 40 ft (12.2m), centered 90 ft(27.4m) apart in the long direction of the building.3.The inner tubes are braced in the short direction, but with zero shear stiffness inthe long direction.4. A single outer tube is supplied, which encircles the building perimeter.5.The outer tube is a moment-resisting frame, but with zero shear stiffness for thecenter50ft (15.2m) of each of the long sides.6. A space-truss hat structure is provided at the top of the building.7. A similar space truss is located near the bottom of the building8.The entire assembly is laterally supported at the base on twin steel-plate tubes,because the shear stiffness of the outer tube goes to zero at the base of thebuilding.Cellular structuresA classic example of a cellular structure is the Sears Tower, Chicago, a bundled tube structure of nine separate tubes. While the Sears Tower contains nine nearly identical tubes, the basic structural system has special application for buildings of irregular shape, as the several tubes need not be similar in plan shape, It is not uncommon that some of the individual tubes one of the strengths and one of the weaknesses of the system.This special weakness of this system, particularly in framed tubes, has to do with the concept of differential column shortening. The shortening of a column under load is given by the expression△=ΣfL/EFor buildings of 12 ft (3.66m) floor-to-floor distances and an average compressive stress of 15 ksi (138MPa), the shortening of a column under load is 15 (12)(12)/29,000 or 0.074in (1.9mm) per story. At 50 stories, the column will have shortened to 3.7 in. (94mm) less than its unstressed length. Where one cell of a bundled tube system is, say, 50stories high and an adjacent cell is, say, 100stories high, those columns near the boundary between .the two systems need to have this differential deflection reconciled.Major structural work has been found to be needed at such locations. In at least one building, the Rialto Project, Melbourne, the structural engineer found it necessary to vertically pre-stress the lower height columns so as to reconcile thedifferential deflections of columns in close proximity with the post-tensioning of the shorter column simulating the weight to be added on to adjacent, higher columns.。

Part IV：Commonly Used Professional Terms of Civil Engineeringdevelopment organization 建设单位design organization 设计单位construction organization 施工单位reinforced concrete 钢筋混凝土pile 桩steel structure 钢结构aluminium alloy 铝合金masonry 砌体（工程）reinforced ~ 配筋砌体load-bearing ~ 承重砌体unreinforced ~非配筋砌体permissible stress (allowable stress) 容许应力plywood 胶合板retaining wall 挡土墙finish 装修finishing material装修材料ventilation 通风natural ~ 自然通风mechanical ~ 机械通风diaphragm wall (continuous concrete wall) 地下连续墙villa 别墅moment of inertia 惯性矩torque 扭矩stress 应力normal ~ 法向应力shear ~ 剪应力strain 应变age hardening 时效硬化air-conditioning system空调系统(air) void ration（土）空隙比albery壁厨，壁龛a l mery壁厨，贮藏室anchorage length锚固长度antiseismic joint 防震缝architectural appearance 建筑外观architectural area 建筑面积architectural design 建筑设计fiashing 泛水workability (placeability) 和易性safety glass安全玻璃tempered glass (reinforced glass) 钢化玻璃foamed glass泡沫玻璃asphalt沥青felt (malthoid) 油毡riveted connection 铆接welding焊接screwed connection 螺栓连接oakum 麻刀，麻丝tee三通管tap存水弯esthetics美学formwork 模板（工程）shoring 支撑batching 配料slipform construction (slipforming) 滑模施工lfit-slab construction 升板法施工mass concrete 大体积混凝土terrazzo水磨石construction joint 施工缝honeycomb蜂窝，空洞，麻面piled foundation桩基deep foundation 深基础shallow foundation浅基础foundation depth基础埋深pad foundation独立基础strip foundation 条形基础raft foundation筏基box foundation箱形基础BSMT=basement 地下室lift 电梯electric elevatorlift well电梯井escalator 自动扶梯Poisson’s ratio 泊松比μYoung’s modulus , modulus of elasticity 杨氏模量，弹性模量Esafety coefficient 安全系数fatigue failure 疲劳破坏bearing capacity of foundations 地基承载力bearing capacity of a pile 单桩承载力two-way-reinforcement 双向配筋reinforced concrete two-way slabs钢筋混凝土双向板single way slab单向板window blind 窗帘sun blindwind load 风荷载curing 养护watertight concrete 防水混凝土white cement白水泥separating of concrete混凝土离折segregation of concretemortar 砂浆~ joint 灰缝pilaster 壁柱fire rating耐火等级fire brick 耐火砖standard brick标准砖terra cotta 琉璃瓦mosaic 马赛克ceramic mosaic陶瓷锦砖，马赛克，ceramic mosaic tileceramic tile 瓷砖rubble wall毛石墙marble 大理石,大理岩granite 花岗石,花岗岩ready-mixed concrete 商品混凝土，预拌混凝土real estate房地产reinforcement bar 钢筋veinforcement meal, reinforcing bar, reinforcing steel reinforcement cover混凝土保护层reinforcement mat 钢筋网, reinforcing mesh reinforcing ratio 配筋率reinforcement percentagereinforcing work钢筋工程residential building居住建筑rigid foundation刚性基础roof 屋顶，屋盖，屋面; roof board 屋面板; roof garden屋顶花园roof live load 屋面活荷载rustic terrazzo粗面水磨石，水刷石sand cushion砂垫层saw-tooth skylight锯齿形天窗scaffold 脚手架sill窗台silty soil粉质土single door单扇门double door双扇门single reinforcemen单筋tsliding door推拉门sliding window水平推拉窗staircase楼梯间stair rail(ing) 楼梯栏杆，楼梯扶手stair step楼梯踏步stair string (er)楼梯梁stair clearance 楼梯净空高度stair headroom steel forms钢模板store room贮藏室structural drawings结构图soft substratum软弱下卧层sun louver 遮阳板supporting block 支座supporting layer持力层tensile reinforcement 受拉钢筋tensile steel, tension reinforcementterrace roof 平屋顶thermal insulation隔热through ventilation穿堂风timber structure 木结构wood structuretoilet 盥洗间，浴室，厕所，便池tracing paper描图纸lawn 草坪treatment of elevation立面处理drawing board 绘图板triaxial compression test 三轴压缩试验tubular steel scaffolding钢管脚手架uniformly distributed load均布荷载unnotched bar 光面钢; threadbar螺纹钢筋urinal 小便池，小便斗，小便槽valley天沟ventilating skylight 通风天窗waterproof barrier 防水层aquatardTerzaghi bearing capacity theory太沙基承载力理论Terzaghi consolidation theory 太沙基固结理论foundation treatment 地基处理foundation pressure 基底压力span 跨度specific gravity比重quicklime生石灰,氧化钙hydrated lime 熟石灰,消石灰hydration 水化作用plaster of Paris熟石膏portland cement 波特兰水泥,硅酸盐水泥,普通水泥portland blastfurnace slag cement矿渣水泥portland fly-ash cement粉煤灰(硅酸盐)水泥portland-pozzolana cement火山灰质硅酸盐水泥gas-foaming admixture发泡剂retarding admixture缓凝剂water-reducing agent减水剂air-entrained agent 加气剂slump坍落度water-cement ratio水灰比w/carchitectural lighting 建筑采光,建筑照明architectural perspective建筑透视图architectural section 建筑剖面图architectural specifications建筑规范architectural working drawing 建筑施工图architecture sketch建筑草图arc welding 电弧焊stress concentration 应力集中multi storied building 多层建筑settlement of foundation 地基沉降tensile strength抗拉强度compressive strength抗压强度bending strength抗弯强度construction material 建筑材料building material continuous beam连续梁tower crane 塔式起重机,塔吊SPT=standard penetration test 标准贯入度试验wall between two windows窗间墙stability稳定性stress-strain curve应力-应变曲线stress-strain diagram应力-应变图damp-proof coating防潮层osmosis渗透osmotic co-efficient渗透系数osmotic pressure渗透压力finite element method 有限单无法finite-difference method有限差分法finite slice method 条分法deformation 变形displacement位移allowable bearing capacity 容许承载力total and differential settlement 总沉降量和沉降差Mohr’s circle of stress 摩尔应力圆snow laod雪(荷)载bent reinforcement bar 弯起钢筋bent steel 弯起钢筋bent-up bar 弯起钢筋bid 投标，标书bid call招标bid opening开标bidding sheet 标价单bid price 出价，投标价格binding reinforcement 绑扎钢筋blocking course檐口墙，女儿墙parapet (wall) bloodwood 红木redwoodbrick lintel 砖砌过梁brick masonry structure 砖石结构BRKT =bracket 牛腿building height 建筑高度building industrialization建筑工业化building-in fitting 预埋件building law 建筑法building line 建筑红线building module 建筑模数building orientation 建筑物朝向building permits for construction建筑施工执照building equipment 建筑设备building physics建筑物理building rubble 建筑垃圾building storm sewer 房屋雨水管built –in cupboard 壁厨cable structure 悬索结构cable-supported construction悬索结构canopy雨篷cast-in-place concrete 现浇混凝土cast-in-situ concrete 现浇混凝土caterpillar crane 履带式起重机cavity brick空心砖cavity wall空心墙ceiling 顶棚，吊顶，天花板cement floor水泥地面cement mortar水泥砂浆center-to-center中心距(中到中间距)chain-pull switch拉线开关cromatics色彩学city planning城市规划civil architecture民用建筑civil building民用建筑civil engineering土木工程clay brick粘土砖clerestory天窗clerestory windows高侧窗closet 盥洗室，厕所，卫生间coated glass 玻璃幕墙glass curtain wall collapsible loess 湿陷性黄土slumping loess collar tie beam 圈梁combination beam 组合梁combination construction 混合结构shear wall 剪力墙shear strength 抗剪强度transom （门上的）亮子bar 棒，条，杆件，（粗）钢筋beam 梁framework 框架truss桁架statically determinate ~ 静定桁架statically indeterminate ~ 超静定桁架elasticity弹性plasticity塑性stiffness刚度fiexibility挠度bending moment弯矩~ diagram 弯矩图~ envelope弯矩包络线influence line 影响线aggregate 骨料coarse ~ 粗骨料fine ~ 细骨料admixture外加剂concrete mixer混凝土搅拌机paint 油漆density密度viscosity粘度，粘滞性geology地质earth pressure 土压力active ~ 主动土压力coarse sand 粗砂; medium sand中砂; fine sand细砂artificial daylight人工采光artificial illumination人工照明art of architecture建筑艺术seismatic design 抗震设计back view 背立面balcony阳台balustrade 栏杆，扶手bamboo scaffolding竹脚手架band iron扁铁，扁钢bar cutter钢筋切断机bar list钢筋表bar spacing钢筋间距base board踢脚板basic module基本模数BC=building code建筑法规beam-and-column construction梁柱结构（框架结构）beam-and-girder construction主次梁梁格结构beam-and-slab construction梁板结构beam with one overhanging end 悬臂梁cantilever beam, overhanging beambeam with simply supported ends 简支梁simple beam, simple-supported beam, simply supported beam beam with fixed ends 固端梁bending stiffness弯曲刚度bending strength抗弯强度bending stress弯曲应力bend bar 弯起钢筋，弯筋commemorative architecture 纪念性建筑commercial buildings商业建筑物,商业房屋compacted fill 压实填土,夯实填土compacted soil压实土compaction by layers分层填土夯实compaction by rolling 碾压compaction by vibration振动压实compartmentation隔断completion acceptance竣工验收completion date 竣工日期compression bar 受压钢筋compression steel受压钢筋concealed work 隐蔽工程conductor 水落管construction administration 施工管理constructional drawing 施工图,构造图construction and installation work 建筑安装工程construction company 建筑公司construction economics建筑经济construction industry建筑(工)业construction in process 在建工程construction management plan 施工组织设计construction period施工工期construction site 施工现场creep 徐变,蠕变cross wall横墙dark room暗室design development phase 技术设计阶段design scheme设计方案detail drawing 详图,大样图,细部图development area 开发区digestion tank 化粪池septic tank, sewage tank distributed load分布荷载distributing bars 分布钢筋distribution reinforcement分布钢筋BL=dead load 恒载,自重dogleg stair 双折楼梯half turndomestic building居住房屋,住宅door window落地窗dormitory宿舍downspout 雨水管,落水管drain spout, fall pipe, leader pipe, rain conductor, rain leader, rain-water leaderdrip line 滴水线dunny厕所,盥洗室earthquake intensity地震烈度earthquake load 地震荷载earthquake resistant design抗震设计earthwork土石方工程earthwork quantity土方工程量eave 屋檐effective depth 有效高度,有效深度,有效厚度enameled tile 琉璃瓦,釉面砖engineering geological prospecting工程地质勘探expanded joint 伸缩缝,温度缝shrinkage joint, temperature jointfactory building厂房figured glass 图案玻璃,压花玻璃patterned glass fixed window固定窗flat skylight平天窗flexible foundation 柔性基础floor load楼面荷载floor plan楼屋平面图floor-to-ceiling height楼面至顶棚高度,室内净高floor-to-floor height楼面至楼面高度story height层高farmed steel 型钢shape(d) steelfoundation beam 基础梁foundation bed 基础垫层gable 出墙~ wallgalvanized iron 镀锌铁皮,白铁皮general arrangement drawing总体布置图,总平面图general layout 总平面图,总体布置glass fiber reinforced plastics玻璃纤维增强塑料,玻璃钢glued board 胶合板gravel 砾石; ~ cobble 卵石pebble gravel, pebble stoneground engineering地基工程ground floor plan底层平面图groundwater surface 地下水位phreatic (water ) surfacegutter明沟,天沟rain-gutter檐沟,天沟hair 麻刀hempmixed sand 混合砂mechanics of materials 材料力学theoretical mechanics 理论力学elastic mechanics弹性力学structural mechanics结构力学architectural mechanics建筑力学fracture mechanics断裂力学soil mechanics土力学rock mechanics岩石力学fluid mechanics流体力学abrasive floor防滑地板accelerated cement 快凝水泥accelerator促凝剂，速凝剂acceptance of hidden subsurface work 隐蔽工程验收acceptance of tender得标acceptance of work subelements分项工程验收access eye 清扫孔，检查孔access hole 检修孔access plate 检修孔盖板accordion shades 折叠式活动隔断，屏风acid 酸alkali碱acoustical insulation 隔声red cray 红粘土adamic earthadhesive bitumen primer冷底子油administration of the construction contract 施工合同管理aerial ledder消防梯non-bearing wall 非承重墙non-load bearing wall norm for detailed estimates 预算定额norm for preliminary estimates 概算定额norm for estimating labor requirements劳动定额norm for estimating material requirements材料定额open ditch 明沟open trenchoutside finish 外装修partion 隔壁, ~ screen 隔断pea shingle 豆砾石，绿豆砂pipeline gas 管道煤气plastic hinge 塑性铰plinth (wall)勒脚pointing (joints)勾缝pointing masonry勾缝砌体,清水墙porch 门廊,走廊pore water 孔隙水post-tensioning method后张法precast concrete lintel 预制混凝土过梁precast reinforced concrete building预制钢筋混凝土房屋monolithic reinforced concrete building整体式钢筋混凝土房屋prestressed concrete 预应力混凝土pretensioning method先张法protecting cap 安全帽protective cap, safety helmet protecting net 安全网public building公共建筑public comfort station 公共厕所public conveniencepump concrete 泵送混凝土pumping concrete halfpace landing楼梯平台landing platform, stair landing, stair platformhallway门厅,过道hemp thread麻丝high-rise hotel高层旅馆,高层饭店hip 屋脊线hoop reinforcement环筋,箍筋hull core structure筒体结构inside finish内装修jalousie window 百叶窗, louver windowjunior beam 次梁secondary beam, secondary girdermain beam 主梁primary beam, primary girder kick strip 踢脚step踏步L & CM=lime and cement mortar石灰水泥砂浆lintol (门窗)过梁lintellongitudinal bar纵向钢筋low-rise building低层建筑LR = living room 起居室,客厅sitting room, parlo(u)rmastic 玛碲脂,树脂,嵌缝料membrane curing薄膜养护metallic tape钢卷尺metal window钢窗mid-span moment跨中弯矩mix(ing) proportion 配合比,混合比mix(ing) ratio mopboard踢脚板mosquito screen 纱窗, screen window。

土木工程抗侧向荷载的结构体系中英文翻译一、科技资料原文：Structural Systems to resist lateral loadsCommonly Used structural SystemsWith loads measured in tens of thousands kips, there is little room in the design of high-rise buildings for excessively complex thoughts. Indeed, the better high-rise buildings carry the universal traits of simplicity of thought and clarity of expression.It does not follow that there is no room for grand thoughts. Indeed, it is with such grand thoughts that the new family of high-rise buildings has evolved. Perhaps more important, the new concepts of but a few years ago have become commonplace in today’ s technology.Omitting some concepts that are related strictly to the materials of construction, the most commonly used structural systems used in high-rise buildings can be categorized as follows:1.Moment-resisting frames.2.Braced frames, including eccentrically braced frames.3.Shear walls, including steel plate shear walls.4.Tube-in-tube structures.5.Tube-in-tube structures.6.Core-interactive structures.7.Cellular or bundled-tube systems.Particularly with the recent trend toward more complex forms, but in response also to the need for increased stiffness to resist the forces from wind and earthquake, most high-rise buildings have structural systems built up of combinations of frames, braced bents, shear walls, and related systems. Further, for the taller buildings, the majorities are composed of interactive elements in three-dimensional arrays.The method of combining these elements is the very essence of the design process for high-rise buildings. These combinations need evolve in response to environmental, functional, and cost considerations so as to provide efficient structuresthat provoke the architectural development to new heights. This is not to say that imaginative structural design can create great architecture. To the contrary, many examples of fine architecture have been created with only moderate support from the structural engineer, while only fine structure, not great architecture, can be developed without the genius and the leadership of a talented architect. In any event, the best of both is needed to formulate a truly extraordinary design of a high-rise building.While comprehensive discussions of these seven systems are generally available in the literature, further discussion is warranted here .The essence of the design process is distributed throughout the discussion.Moment-Resisting FramesPerhaps the most commonly used system in low-to medium-rise buildings, the moment-resisting frame, is characterized by linear horizontal and vertical members connected essentially rigidly at their joints. Such frames are used as a stand-alone system or in combination with other systems so as to provide the needed resistance to horizontal loads. In the taller of high-rise buildings, the system is likely to be found inappropriate for a stand-alone system, this because of the difficulty in mobilizing sufficient stiffness under lateral forces.Analysis can be accomplished by STRESS, STRUDL, or a host of other appropriate computer programs; analysis by the so-called portal method of the cantilever method has no place in today’s technology.Because of the intrinsic flexibility of the column/girder intersection, and because preliminary designs should aim to highlight weaknesses of systems, it is not unusual to use center-to-center dimensions for the frame in the preliminary analysis. Of course, in the latter phases of design, a realistic appraisal in-joint deformation is essential.Braced Frame sThe braced frame, intrinsically stiffer than the moment –resisting frame, finds also greater application to higher-rise buildings. The system is characterized by linear horizontal, vertical, and diagonal members, connected simply or rigidly at their joints.It is used commonly in conjunction with other systems for taller buildings and as a stand-alone system in low-to medium-rise buildings.While the use of structural steel in braced frames is common, concrete frames are more likely to be of the larger-scale variety.Of special interest in areas of high seismicity is the use of the eccentric braced frame.Again, analysis can be by STRESS, STRUDL, or any one of a series of two –or three dimensional analysis computer programs. And again, center-to-center dimensions are used commonly in the preliminary analysis.Shear wallsThe shear wall is yet another step forward along a progression of ever-stiffer structural systems. The system is characterized by relatively thin, generally (but not always) concrete elements that provide both structural strength and separation between building functions.In high-rise buildings, shear wall systems tend to have a relatively high aspect ratio, that is, their height tends to be large compared to their width. Lacking tension in the foundation system, any structural element is limited in its ability to resist overturning moment by the width of the system and by the gravity load supported by the element. Limited to a narrow overturning, One obvious use of the system, which does have the needed width, is in the exterior walls of building, where the requirement for windows is kept small.Structural steel shear walls, generally stiffened against buckling by a concrete overlay, have found application where shear loads are high. The system, intrinsically more economical than steel bracing, is particularly effective in carrying shear loads down through the taller floors in the areas immediately above grade. The sys tem has the further advantage of having high ductility a feature of particular importance in areas of high seismicity.The analysis of shear wall systems is made complex because of the inevitable presence of large openings through these walls. Preliminary analysis can be by truss-analogy, by the finite element method, or by making use of a proprietary computer program designed to consider the interaction, or coupling, of shear walls.Framed or Braced TubesThe concept of the framed or braced or braced tube erupted into the technology with the IBM Building in Pittsburgh, but was followed immediately with the twin110-story towers of the World Trade Center, New York and a number of other buildings .The system is characterized by three –dimensional frames, braced frames, or shear walls, forming a closed surface more or less cylindrical in nature, but of nearly any plan configuration. Because those columns that resist lateral forces are placed as far as possible from the cancroids of the system, the overall moment of inertia is increased and stiffness is very high.The analysis of tubular structures is done using three-dimensional concepts, orby two- dimensional analogy, where possible, whichever method is used, it must be capable of accounting for the effects of shear lag.The presence of shear lag, detected first in aircraft structures, is a serious limitation in the stiffness of framed tubes. The concept has limited recent applications of framed tubes to the shear of 60 stories. Designers have developed various techniques for reducing the effects of shear lag, most noticeably the use of belt trusses. This system finds application in buildings perhaps 40stories and higher. However, except for possible aesthetic considerations, belt trusses interfere with nearly every building function associated with the outside wall; the trusses are placed often at mechanical floors, mush to the disapproval of the designers of the mechanical systems. Nevertheless, as a cost-effective structural system, the belt truss works well and will likely find continued approval from designers. Numerous studies have sought to optimize the location of these trusses, with the optimum location very dependent on the number of trusses provided. Experience would indicate, however, that the location of these trusses is provided by the optimization of mechanical systems and by aesthetic considerations, as the economics of the structural system is not highly sensitive to belt truss location.Tube-in-Tube StructuresThe tubular framing system mobilizes every column in the exterior wall in resisting over-turning and shearing forces. The term‘tube-in-tube’is largely self-explanatory in that a second ring of columns, the ring surrounding the central service core of the building, is used as an inner framed or braced tube. The purpose of the second tube is to increase resistance to over turning and to increase lateral stiffness. The tubes need not be of the same character; that is, one tube could be framed, while the other could be braced.In considering this system, is important to understand clearly the difference between the shear and the flexural components of deflection, the terms being taken from beam analogy. In a framed tube, the shear component of deflection is associated with the bending deformation of columns and girders (i.e, the webs of the framed tube) while the flexural component is associated with the axial shortening and lengthening of columns (i.e, the flanges of the framed tube). In a braced tube, the shear component of deflection is associated with the axial deformation of diagonals while the flexural component of deflection is associated with the axial shortening and lengthening of columns.Following beam analogy, if plane surfaces remain plane (i.e, the floor slabs),then axial stresses in the columns of the outer tube, being farther form the neutral axis, will be substantially larger than the axial stresses in the inner tube. However, in the tube-in-tube design, when optimized, the axial stresses in the inner ring of columns may be as high, or even higher, than the axial stresses in the outer ring. This seeming anomaly is associated with differences in the shearing component of stiffness between the two systems. This is easiest to under-stand where the inner tube is conceived as a braced (i.e, shear-stiff) tube while the outer tube is conceived as a framed (i.e, shear-flexible) tube.Core Interactive StructuresCore interactive structures are a special case of a tube-in-tube wherein the two tubes are coupled together with some form of three-dimensional space frame. Indeed, the system is used often wherein the shear stiffness of the outer tube is zero. The United States Steel Building, Pittsburgh, illustrates the system very well. Here, the inner tube is a braced frame, the outer tube has no shear stiffness, and the two systems are coupled if they were considered as systems passing in a straight line from the “hat” structure. Note that the exterior columns would be improperly modeled if they were considered as systems passing in a straight line from the “hat” to the foundations; these columns are perhaps 15% stiffer as they follow the elastic curve of the braced core. Note also that the axial forces associated with the lateral forces in the inner columns change from tension to compression over the height of the tube, with the inflection point at about 5/8 of the height of the tube. The outer columns, of course, carry the same axial force under lateral load for the full height of the columns because the columns because the shear stiffness of the system is close to zero. The space structures of outrigger girders or trusses, that connect the inner tube to the outer tube, are located often at several levels in the building. The AT&T headquarters is an example of an astonishing array of interactive elements:1.The structural system is 94 ft (28.6m) wide, 196ft(59.7m) long, and 601ft(183.3m) high.2.Two inner tubes are provided, each 31ft(9.4m) by 40 ft (12.2m), centered 90 ft(27.4m) apart in the long direction of the building.3.The inner tubes are braced in the short direction, but with zero shear stiffness inthe long direction.4. A single outer tube is supplied, which encircles the building perimeter.5.The outer tube is a moment-resisting frame, but with zero shear stiffness for thecenter50ft (15.2m) of each of the long sides.6. A space-truss hat structure is provided at the top of the building.7. A similar space truss is located near the bottom of the building8.The entire assembly is laterally supported at the base on twin steel-plate tubes,because the shear stiffness of the outer tube goes to zero at the base of thebuilding.Cellular structuresA classic example of a cellular structure is the Sears Tower, Chicago, a bundled tube structure of nine separate tubes. While the Sears Tower contains nine nearly identical tubes, the basic structural system has special application for buildings of irregular shape, as the several tubes need not be similar in plan shape, It is not uncommon that some of the individual tubes one of the strengths and one of the weaknesses of the system.This special weakness of this system, particularly in framed tubes, has to do with the concept of differential column shortening. The shortening of a column under load is given by the expression△=ΣfL/EFor buildings of 12 ft (3.66m) floor-to-floor distances and an average compressive stress of 15 ksi (138MPa), the shortening of a column under load is 15 (12)(12)/29,000 or 0.074in (1.9mm) per story. At 50 stories, the column will have shortened to 3.7 in. (94mm) less than its unstressed length. Where one cell of a bundled tube system is, say, 50stories high and an adjacent cell is, say, 100stories high, those columns near the boundary between .the two systems need to have this differential deflection reconciled.Major structural work has been found to be needed at such locations. In at least one building, the Rialto Project, Melbourne, the structural engineer found it necessary to vertically pre-stress the lower height columns so as to reconcile the differential deflections of columns in close proximity with the post-tensioning of the shorter column simulating the weight to be added on to adjacent, higher columns.二、原文翻译：抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

原文翻译：抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

确实，较好的高层建筑普遍具有构思简单、表现明晰的特点。

这并不是说没有进行宏观构思的余地。

实际上，正是因为有了这种宏观的构思，新奇的高层建筑体系才得以发展，可能更重要的是：几年以前才出现的一些新概念在今天的技术中已经变得平常了。

如果忽略一些与建筑材料密切相关的概念不谈，高层建筑里最为常用的结构体系便可分为如下几类：1．抗弯矩框架。

2．支撑框架，包括偏心支撑框架。

3．剪力墙，包括钢板剪力墙。

4．筒中框架。

5．筒中筒结构。

6．核心交互结构。

7．框格体系或束筒体系。

特别是由于最近趋向于更复杂的建筑形式，同时也需要增加刚度以抵抗几力和地震力，大多数高层建筑都具有由框架、支撑构架、剪力墙和相关体系相结合而构成的体系。

而且，就较高的建筑物而言，大多数都是由交互式构件组成三维陈列。

将这些构件结合起来的方法正是高层建筑设计方法的本质。

其结合方式需要在考虑环境、功能和费用后再发展，以便提供促使建筑发展达到新高度的有效结构。

这并不是说富于想象力的结构设计就能够创造出伟大建筑。

正相反，有许多例优美的建筑仅得到结构工程师适当的支持就被创造出来了，然而，如果没有天赋甚厚的建筑师的创造力的指导，那么，得以发展的就只能是好的结构，并非是伟大的建筑。

无论如何，要想创造出高层建筑真正非凡的设计，两者都需要最好的。

虽然在文献中通常可以见到有关这七种体系的全面性讨论，但是在这里还值得进一步讨论。

设计方法的本质贯穿于整个讨论。

设计方法的本质贯穿于整个讨论中。

抗弯矩框架抗弯矩框架也许是低，中高度的建筑中常用的体系，它具有线性水平构件和垂直构件在接头处基本刚接之特点。

这种框架用作独立的体系，或者和其他体系结合起来使用，以便提供所需要水平荷载抵抗力。

对于较高的高层建筑，可能会发现该本系不宜作为独立体系，这是因为在侧向力的作用下难以调动足够的刚度。

外文翻译---高层建筑及结构设计High-rise XXX to define。

Generally。

a low-rise building is considered to be een 1 to 2 stories。

while a medium-rise building ranges from 3 or 4 stories up to 10 or 20 stories or more。

While the basic principles of vertical and horizontal subsystem design remain the same for low-。

medium-。

or high-rise buildings。

the vertical subsystems XXX high-XXX requiring larger columns。

walls。

XXX。

XXX.The design of high-rise buildings must take into account the unique XXX by their height and the need to withstand lateral forces such as wind and earthquakes。

One important aspect of high-rise design is the framework shear system。

XXX。

braced frames。

or XXX the appropriate system depends on the specific building characteristics and the seismicity of the n in which it is located.Another key n in high-rise design is the seismic system。

Lesson 4 Tall BuildingAlthough there have been many advancements in building construction technology in general, spectacular achievements have been made in the design and construction of ultrahigh-rise buildings．虽然在建筑施工技术中，总的来说已经有了许多进步，但是在超高层建筑的设计和施工中也取得了惊人的成就。

The early development of high-rise buildings began with structural steel framing．高层建筑的早期发展始于结构的钢框架。

Reinforced concrete and stressed-skin tube systems have since been economically and competitively used in a number of structures for both residential and commercial purposes．从那以后，钢筋混凝土和薄壳筒体体系就被竞相经济地用在了许多民用和商用结构中。

The high-rise buildings ranging from 50 to 110 stories that are being built all over the United States are the result of innovations and development of new structural systems．美国各地正在修建的50～110层的高层建筑是新的结构体系改革和发展的结果。

Greater height entails increased column and beam sizes to make buildings more rigid so that under wind load they will not sway beyond an acceptable limit．更大的高度需要增加柱和梁的尺寸来使建筑物的刚性更大，以便于它们在风荷载作用下不会倾斜到允许的范围之外。

一、科技资料原文：Structural Systems to resist lateral loadsCommonly Used structural SystemsWith loads measured in tens of thousands kips, there is little room in the design of high-rise buildings for excessively complex thoughts. Indeed, the better high-rise buildings carry the universal traits of simplicity of thought and clarity of expression.It does not follow that there is no room for grand thoughts. Indeed, it is with such grand thoughts that the new family of high-rise buildings has evolved. Perhaps more important, the new concepts of but a few years ago have become commonplace in today’ s technology.Omitting some concepts that are related strictly to the materials of construction, the most commonly used structural systems used in high-rise buildings can be categorized as follows:1.Moment-resisting frames.2.Braced frames, including eccentrically braced frames.3.Shear walls, including steel plate shear walls.4.Tube-in-tube structures.5.Tube-in-tube structures.6.Core-interactive structures.7.Cellular or bundled-tube systems.Particularly with the recent trend toward more complex forms, but in response also to the need for increased stiffness to resist the forces from wind and earthquake, most high-rise buildings have structural systems built up of combinations of frames, braced bents, shear walls, and related systems. Further, for the taller buildings, the majorities are composed of interactive elements in three-dimensional arrays.The method of combining these elements is the very essence of the design process for high-rise buildings. These combinations need evolve in response to environmental, functional, and cost considerations so as to provide efficient structures that provoke the architectural development to new heights. This is not to say that imaginative structural design can create great architecture. To the contrary, many examples of fine architecture have been created with only moderate support from the structural engineer, while only fine structure, not great architecture, can be developedwithout the genius and the leadership of a talented architect. In any event, the best of both is needed to formulate a truly extraordinary design of a high-rise building.While comprehensive discussions of these seven systems are generally available in the literature, further discussion is warranted here .The essence of the design process is distributed throughout the discussion.Moment-Resisting FramesPerhaps the most commonly used system in low-to medium-rise buildings, the moment-resisting frame, is characterized by linear horizontal and vertical members connected essentially rigidly at their joints. Such frames are used as a stand-alone system or in combination with other systems so as to provide the needed resistance to horizontal loads. In the taller of high-rise buildings, the system is likely to be found inappropriate for a stand-alone system, this because of the difficulty in mobilizing sufficient stiffness under lateral forces.Analysis can be accomplished by STRESS, STRUDL, or a host of other appropriate computer programs; analysis by the so-called portal method of the cantilever method has no place in today’s technology.Because of the intrinsic flexibility of the column/girder intersection, and because preliminary designs should aim to highlight weaknesses of systems, it is not unusual to use center-to-center dimensions for the frame in the preliminary analysis. Of course, in the latter phases of design, a realistic appraisal in-joint deformation is essential.Braced Frame sThe braced frame, intrinsically stiffer than the moment –resisting frame, finds also greater application to higher-rise buildings. The system is characterized by linear horizontal, vertical, and diagonal members, connected simply or rigidly at their joints. It is used commonly in conjunction with other systems for taller buildings and as a stand-alone system in low-to medium-rise buildings.While the use of structural steel in braced frames is common, concrete frames are more likely to be of the larger-scale variety.Of special interest in areas of high seismicity is the use of the eccentric braced frame.Again, analysis can be by STRESS, STRUDL, or any one of a series of two –or three dimensional analysis computer programs. And again, center-to-center dimensions are used commonly in the preliminary analysis.Shear wallsThe shear wall is yet another step forward along a progression of ever-stiffer structural systems. The system is characterized by relatively thin, generally (but not always) concrete elements that provide both structural strength and separation between building functions.In high-rise buildings, shear wall systems tend to have a relatively high aspect ratio, that is, their height tends to be large compared to their width. Lacking tension in the foundation system, any structural element is limited in its ability to resist overturning moment by the width of the system and by the gravity load supported by the element. Limited to a narrow overturning, One obvious use of the system, which does have the needed width, is in the exterior walls of building, where the requirement for windows is kept small.Structural steel shear walls, generally stiffened against buckling by a concrete overlay, have found application where shear loads are high. The system, intrinsically more economical than steel bracing, is particularly effective in carrying shear loads down through the taller floors in the areas immediately above grade. The sys tem has the further advantage of having high ductility a feature of particular importance in areas of high seismicity.The analysis of shear wall systems is made complex because of the inevitable presence of large openings through these walls. Preliminary analysis can be by truss-analogy, by the finite element method, or by making use of a proprietary computer program designed to consider the interaction, or coupling, of shear walls.Framed or Braced TubesThe concept of the framed or braced or braced tube erupted into the technology with the IBM Building in Pittsburgh, but was followed immediately with the twin 110-story towers of the World Trade Center, New York and a number of other buildings .The system is characterized by three –dimensional frames, braced frames, or shear walls, forming a closed surface more or less cylindrical in nature, but of nearly any plan configuration. Because those columns that resistlateral forces are placed as far as possible from the cancroids of the system, the overall moment of inertia is increased and stiffness is very high.The analysis of tubular structures is done using three-dimensional concepts, or by two- dimensional analogy, where possible, whichever method is used, it must be capable of accounting for the effects of shear lag.The presence of shear lag, detected first in aircraft structures, is a serious limitation in the stiffness of framed tubes. The concept has limited recent applications of framed tubes to the shear of 60 stories. Designers have developed various techniques for reducing the effects of shear lag, most noticeably the use of belt trusses. This system finds application in buildings perhaps 40stories and higher. However, except for possible aesthetic considerations, belt trusses interfere with nearly every building function associated with the outside wall; the trusses are placed often at mechanical floors, mush to the disapproval of the designers of the mechanical systems. Nevertheless, as a cost-effective structural system, the belt truss works well and will likely find continued approval from designers. Numerous studies have sought to optimize the location of these trusses, with the optimum location very dependent on the number of trusses provided. Experience would indicate, however, that the location of these trusses is provided by the optimization of mechanical systems and by aesthetic considerations, as the economics of the structural system is not highly sensitive to belt truss location.Tube-in-Tube StructuresThe tubular framing system mobilizes every column in the exterior wall in resisting over-turning and shearing forces. The term‘tube-in-tube’is largely self-explanatory in that a second ring of columns, the ring surrounding the central service core of the building, is used as an inner framed or braced tube. The purpose of the second tube is to increase resistance to over turning and to increase lateral stiffness. The tubes need not be of the same character; that is, one tube could be framed, while the other could be braced.In considering this system, is important to understand clearly the difference between the shear and the flexural components of deflection, the terms being taken from beam analogy. In a framed tube, the shear component of deflection is associated with the bending deformation of columns and girders (i.e, the webs of the framed tube) while the flexural component is associated with the axial shortening and lengthening of columns (i.e, the flanges of the framed tube). In abraced tube, the shear component of deflection is associated with the axial deformation of diagonals while the flexural component of deflection is associated with the axial shortening and lengthening of columns.Following beam analogy, if plane surfaces remain plane (i.e, the floor slabs),then axial stresses in the columns of the outer tube, being farther form the neutral axis, will be substantially larger than the axial stresses in the inner tube. However, in the tube-in-tube design, when optimized, the axial stresses in the inner ring of columns may be as high, or even higher, than the axial stresses in the outer ring. This seeming anomaly is associated with differences in the shearing component of stiffness between the two systems. This is easiest to under-stand where the inner tube is conceived as a braced (i.e, shear-stiff) tube while the outer tube is conceived as a framed (i.e, shear-flexible) tube.Core Interactive StructuresCore interactive structures are a special case of a tube-in-tube wherein the two tubes are coupled together with some form of three-dimensional space frame. Indeed, the system is used often wherein the shear stiffness of the outer tube is zero. The United States Steel Building, Pittsburgh, illustrates the system very well. Here, the inner tube is a braced frame, the outer tube has no shear stiffness, and the two systems are coupled if they were considered as systems passing in a straight line from the “hat” structure. Note that the exterior columns would be improperly modeled if they were considered as systems passing in a straight line from the “hat” to the foundations; these columns are perhaps 15% stiffer as they follow the elastic curve of the braced core. Note also that the axial forces associated with the lateral forces in the inner columns change from tension to compression over the height of the tube, with the inflection point at about 5/8 of the height of the tube. The outer columns, of course, carry the same axial force under lateral load for the full height of the columns because the columns because the shear stiffness of the system is close to zero.The space structures of outrigger girders or trusses, that connect the inner tube to the outer tube, are located often at several levels in the building. The AT&T headquarters is an example of an astonishing array of interactive elements:1.The structural system is 94 ft (28.6m) wide, 196ft(59.7m) long, and 601ft (183.3m) high.2.Two inner tubes are provided, each 31ft(9.4m) by 40 ft (12.2m), centered 90 ft (27.4m)apart in the long direction of the building.3.The inner tubes are braced in the short direction, but with zero shear stiffness in the longdirection.4. A single outer tube is supplied, which encircles the building perimeter.5.The outer tube is a moment-resisting frame, but with zero shear stiffness for the center50ft(15.2m) of each of the long sides.6. A space-truss hat structure is provided at the top of the building.7. A similar space truss is located near the bottom of the building8.The entire assembly is laterally supported at the base on twin steel-plate tubes, because theshear stiffness of the outer tube goes to zero at the base of the building.Cellular structuresA classic example of a cellular structure is the Sears Tower, Chicago, a bundled tube structure of nine separate tubes. While the Sears Tower contains nine nearly identical tubes, the basic structural system has special application for buildings of irregular shape, as the several tubes need not be similar in plan shape, It is not uncommon that some of the individual tubes one of the strengths and one of the weaknesses of the system.This special weakness of this system, particularly in framed tubes, has to do with the concept of differential column shortening. The shortening of a column under load is given by the expression△=ΣfL/EFor buildings of 12 ft (3.66m) floor-to-floor distances and an average compressive stress of 15 ksi (138MPa), the shortening of a column under load is 15 (12)(12)/29,000 or 0.074in (1.9mm) per story. At 50 stories, the column will have shortened to 3.7 in. (94mm) less than its unstressed length. Where one cell of a bundled tube system is, say, 50stories high and an adjacent cell is, say, 100stories high, those columns near the boundary between .the two systems need to have this differential deflection reconciled.Major structural work has been found to be needed at such locations. In at least one building, the Rialto Project, Melbourne, the structural engineer found it necessary to vertically pre-stressthe lower height columns so as to reconcile the differential deflections of columns in close proximity with the post-tensioning of the shorter column simulating the weight to be added on to adjacent, higher columns.二、原文翻译：抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

Structural Systems to resist lateral loadsCommonly Used structural SystemsWith loads measured in tens of thousands kips,there is little room in the design of high-rise buildings for excessively complex thoughts. Indeed, the better high-rise buildings carry the universal traits of simplicity of thought and clarity of expression.It does not follow that there is no room for grand thoughts. Indeed, it is with such grand thoughts that the new family of high-rise buildings has evolved. Perhaps more important, the new concepts of but a few years ago have become commonplace in today’ s technology.Omitting some concepts that are related strictly to the materials of construction, the most commonly used structural systems used in high-rise buildings can be categorized as follows:1.Moment-resisting frames.2.Braced frames, including eccentrically braced frames.3.Shear walls, including steel plate shear walls.4.Tube-in-tube structures.5.Tube-in-tube structures.6.Core-interactive structures.7.Cellular or bundled-tube systems.Particularly with the recent trend toward more complex forms, but in response also to the need for increased stiffness to resist the forces from wind and earthquake, most high-rise buildings have structural systems built up of combinations of frames, braced bents, shear walls, and related systems. Further, for the taller buildings, the majorities are composed of interactive elements in three-dimensional arrays.The method of combining these elements is the very essence of the design process for high-rise buildings. These combinations need evolve in response to environmental, functional, and cost considerations so as to provide efficient structures that provoke the architectural development to new heights. This is not to say that imaginative structural design can create great architecture. To the contrary, manyexamples of fine architecture have been created with only moderate support from the structural engineer, while only fine structure, not great architecture, can be developed without the genius and the leadership of a talented architect. In any event, the best of both is needed to formulate a truly extraordinary design of a high-rise building.While comprehensive discussions of these seven systems are generally available in the literature, further discussion is warranted here .The essence of the design process is distributed throughout the discussion.Moment-Resisting FramesPerhaps the most commonly used system in low-to medium-rise buildings, the moment-resisting frame, is characterized by linear horizontal and vertical members connected essentially rigidly at their joints. Such frames are used as a stand-alone system or in combination with other systems so as to provide the needed resistance to horizontal loads. In the taller of high-rise buildings, the system is likely to be found inappropriate for a stand-alone system, this because of the difficulty in mobilizing sufficient stiffness under lateral forces.Analysis can be accomplished by STRESS, STRUDL, or a host of other appropriate computer programs; analysis by the so-called portal method of the cantilever method has no place in today’s technology.Because of the intrinsic flexibility of the column/girder intersection, and because preliminary designs should aim to highlight weaknesses of systems, it is not unusual to use center-to-center dimensions for the frame in the preliminary analysis. Of course, in the latter phases of design, a realistic appraisal in-joint deformation is essential.Braced Frame sThe braced frame, intrinsically stiffer than the moment –resisting frame, finds also greater application to higher-rise buildings. The system is characterized by linear horizontal, vertical, and diagonal members, connected simply or rigidly at their joints. It is used commonly in conjunction with other systems for taller buildings and as a stand-alone system in low-to medium-rise buildings.While the use of structural steel in braced frames is common, concrete frames are more likely to be of the larger-scale variety.Of special interest in areas of high seismicity is the use of the eccentric braced frame.Again, analysis can be by STRESS, STRUDL, or any one of a series of two –or three dimensional analysis computer programs. And again, center-to-center dimensions are used commonly in the preliminary analysis.Shear wallsThe shear wall is yet another step forward along a progression of ever-stiffer structural systems. The system is characterized by relatively thin, generally (but not always) concrete elements that provide both structural strength and separation between building functions.In high-rise buildings, shear wall systems tend to have a relatively high aspect ratio, that is, their height tends to be large compared to their width. Lacking tension in the foundation system, any structural element is limited in its ability to resist overturning moment by the width of the system and by the gravity load supported by the element. Limited to a narrow overturning, One obvious use of the system, which does have the needed width, is in the exterior walls of building, where the requirement for windows is kept small.Structural steel shear walls, generally stiffened against buckling by a concrete overlay, have found application where shear loads are high. The system, intrinsically more economical than steel bracing, is particularly effective in carrying shear loads down through the taller floors in the areas immediately above grade. The sys tem has the further advantage of having high ductility a feature of particular importance in areas of high seismicity.The analysis of shear wall systems is made complex because of the inevitable presence of large openings through these walls. Preliminary analysis can be by truss-analogy, by the finite element method, or by making use of a proprietary computer program designed to consider the interaction, or coupling, of shear walls.Framed or Braced TubesThe concept of the framed or braced or braced tube erupted into the technology with the IBM Building in Pittsburgh, but was followed immediately with the twin 110-story towers of the World Trade Center, New York and a number of other buildings .The system is characterized by three –dimensional frames, braced frames, or shear walls, forming a closed surface more or less cylindrical in nature, but of nearly any plan configuration. Because those columns that resist lateral forces are placed as far as possible from the cancroids of the system, the overall moment of inertia is increased and stiffness is very high.The analysis of tubular structures is done using three-dimensional concepts, or by two- dimensional analogy, where possible, whichever method is used, it must be capable of accounting for the effects of shear lag.The presence of shear lag, detected first in aircraft structures, is a serious limitation in the stiffness of framed tubes. The concept has limited recent applications of framed tubes to the shear of 60 stories. Designers have developed various techniques for reducing the effects of shear lag, most noticeably the use of belt trusses. This system finds application in buildings perhaps 40stories and higher. However, except for possible aesthetic considerations, belt trusses interfere with nearly every building function associated with the outside wall; the trusses are placed often at mechanical floors, mush to the disapproval of the designers of the mechanical systems. Nevertheless, as a cost-effective structural system, the belt truss works well and will likely find continued approval from designers. Numerous studies have sought to optimize the location of these trusses, with the optimum location very dependent on the number of trusses provided. Experience would indicate, however, that the location of these trusses is provided by the optimization of mechanical systems and by aesthetic considerations, as the economics of the structural system is not highly sensitive to belt truss location.Tube-in-Tube StructuresThe tubular framing system mobilizes every column in the exterior wall inresisting over-turning and shearing forces. The term‘tube-in-tube’is largely self-explanatory in that a second ring of columns, the ring surrounding the central service core of the building, is used as an inner framed or braced tube. The purpose of the second tube is to increase resistance to over turning and to increase lateral stiffness. The tubes need not be of the same character; that is, one tube could be framed, while the other could be braced.In considering this system, is important to understand clearly the difference between the shear and the flexural components of deflection, the terms being taken from beam analogy. In a framed tube, the shear component of deflection is associated with the bending deformation of columns and girders (i.e, the webs of the framed tube) while the flexural component is associated with the axial shortening and lengthening of columns (i.e, the flanges of the framed tube). In a braced tube, the shear component of deflection is associated with the axial deformation of diagonals while the flexural component of deflection is associated with the axial shortening and lengthening of columns.Following beam analogy, if plane surfaces remain plane (i.e, the floor slabs),then axial stresses in the columns of the outer tube, being farther form the neutral axis, will be substantially larger than the axial stresses in the inner tube. However, in the tube-in-tube design, when optimized, the axial stresses in the inner ring of columns may be as high, or even higher, than the axial stresses in the outer ring. This seeming anomaly is associated with differences in the shearing component of stiffness between the two systems. This is easiest to under-stand where the inner tube is conceived as a braced (i.e, shear-stiff) tube while the outer tube is conceived as a framed (i.e, shear-flexible) tube.Core Interactive StructuresCore interactive structures are a special case of a tube-in-tube wherein the two tubes are coupled together with some form of three-dimensional space frame. Indeed, the system is used often wherein the shear stiffness of the outer tube is zero. The United States Steel Building, Pittsburgh, illustrates the system very well. Here, theinner tube is a braced frame, the outer tube has no shear stiffness, and the two systems are coupled if they were considered as systems passing in a straight line from the “hat” structure. Note that the exterior columns would be improperly modeled if they were considered as systems passing in a straight line from the “hat” to the foundations; these columns are perhaps 15% stiffer as they follow the elastic curve of the braced core. Note also that the axial forces associated with the lateral forces in the inner columns change from tension to compression over the height of the tube, with the inflection point at about 5/8 of the height of the tube. The outer columns, of course, carry the same axial force under lateral load for the full height of the columns because the columns because the shear stiffness of the system is close to zero.The space structures of outrigger girders or trusses, that connect the inner tube to the outer tube, are located often at several levels in the building. The AT&T headquarters is an example of an astonishing array of interactive elements:1.The structural system is 94 ft (28.6m) wide, 196ft(59.7m) long, and 601ft(183.3m) high.2.Two inner tubes are provided, each 31ft(9.4m) by 40 ft (12.2m), centered 90 ft(27.4m) apart in the long direction of the building.3.The inner tubes are braced in the short direction, but with zero shear stiffness inthe long direction.4. A single outer tube is supplied, which encircles the building perimeter.5.The outer tube is a moment-resisting frame, but with zero shear stiffness for thecenter50ft (15.2m) of each of the long sides.6. A space-truss hat structure is provided at the top of the building.7. A similar space truss is located near the bottom of the building8.The entire assembly is laterally supported at the base on twin steel-plate tubes,because the shear stiffness of the outer tube goes to zero at the base of the building.Cellular structuresA classic example of a cellular structure is the Sears Tower, Chicago, a bundled tube structure of nine separate tubes. While the Sears Tower contains nine nearly identical tubes, the basic structural system has special application for buildings of irregular shape, as the several tubes need not be similar in plan shape, It is not uncommon that some of the individual tubes one of the strengths and one of the weaknesses of the system.This special weakness of this system, particularly in framed tubes, has to do with the concept of differential column shortening. The shortening of a column under load is given by the expression△=ΣfL/EFor buildings of 12 ft (3.66m) floor-to-floor distances and an average compressive stress of 15 ksi (138MPa), the shortening of a column under load is 15 (12)(12)/29,000 or 0.074in (1.9mm) per story. At 50 stories, the column will have shortened to 3.7 in. (94mm) less than its unstressed length. Where one cell of a bundled tube system is, say, 50stories high and an adjacent cell is, say, 100stories high, those columns near the boundary between .the two systems need to have this differential deflection reconciled.Major structural work has been found to be needed at such locations. In at least one building, the Rialto Project, Melbourne, the structural engineer found it necessary to vertically pre-stress the lower height columns so as to reconcile the differential deflections of columns in close proximity with the post-tensioning of the shorter column simulating the weight to be added on to adjacent, higher columns.抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

结构力学结构力学structural mechanics 结构分析structural analysis结构动力学structural dynamics拱Arch三铰拱three-hinged arch抛物线拱parabolic arch圆拱circular arch穹顶Dome空间结构space structure空间桁架space truss雪载［荷］snow load风载［荷］wind load土压力earth pressure地震载荷earthquake loading弹簧支座spring support支座位移support displacement支座沉降support settlement超静定次数degree of indeterminacy机动分析kinematic analysis结点法method of joints截面法method of sections结点力joint forces共轭位移conjugate displacement影响线influence line三弯矩方程three-moment equation单位虚力unit virtual force刚度系数stiffness coefficient柔度系数flexibility coefficient力矩分配moment distribution力矩分配法moment distribution method力矩再分配moment redistribution分配系数distribution factor矩阵位移法matri displacement method单元刚度矩阵element stiffness matrix单元应变矩阵element strain matrix总体坐标global coordinates贝蒂定理Betti theorem高斯--若尔当消去法Gauss-Jordan elimination Method屈曲模态buckling mode复合材料力学mechanics of composites复合材料composite material纤维复合材料fibrous composite单向复合材料unidirectional composite泡沫复合材料foamed composite颗粒复合材料particulate composite层板Laminate夹层板sandwich panel正交层板cross-ply laminate斜交层板angle-ply laminate层片Ply多胞固体cellular solid膨胀Expansion 压实Debulk 劣化Degradation 脱层Delamination脱粘Debond 纤维应力fiber stress 层应力ply stress 层应变plystrain 层间应力interlaminar stress 比强度specific strength 强度折减系数strength reduction factor 强度应力比strength -stress ratio 横向剪切模量transverse shear modulus 横观各向同性transverse isotropy 正交各向异Orthotropy 剪滞分析shear lag analysis 短纤维chopped fiber 长纤维continuous fiber 纤维方向fiber direction 纤维断裂fiber break 纤维拔脱fiber pull-out纤维增强fiber reinforcement 致密化Densification最小重量设计optimum weight design 网格分析法netting analysis混合律rule of mixture失效准则failure criterion蔡--吴失效准则Tsai-W u failure criterion达格代尔模型Dugdale model断裂力学fracture mechanics概率断裂力学probabilistic fracture Mechanics格里菲思理论Griffith theory线弹性断裂力学linear elastic fracture mechanics, LEFM弹塑性断裂力学elastic-plastic fracture mecha-nics, EPFM断裂Fracture脆性断裂brittle fracture解理断裂cleavage fracture蠕变断裂creep fracture延性断裂ductile fracture晶间断裂inter-granular fracture准解理断裂quasi-cleavage fracture穿晶断裂trans-granular fracture裂纹Crack裂缝Flaw缺陷Defect割缝Slit微裂纹Microcrack折裂Kink椭圆裂纹elliptical crack深埋裂纹embedded crack［钱］币状裂纹penny-shape crack预制裂纹Precrack短裂纹short crack表面裂纹surface crack裂纹钝化crack blunting裂纹分叉crack branching裂纹闭合crack closure裂纹前缘crack front裂纹嘴crack mouth裂纹张开角crack opening angle,COA裂纹张开位移crack opening displacement, COD裂纹阻力crack resistance裂纹面crack surface裂纹尖端crack tip裂尖张角crack tip opening angle, CTOA裂尖张开位移crack tip opening displacement, CTOD 裂尖奇异场crack tip singularity Field裂纹扩展速率crack growth rate稳定裂纹扩展stable crack growth定常裂纹扩展steady crack growth亚临界裂纹扩展subcritical crack growth 裂纹［扩展］减速crack retardation止裂crack arrest止裂韧度arrest toughness断裂类型fracture mode滑开型sliding mode张开型opening mode撕开型tearing mode复合型mixed mode撕裂Tearing撕裂模量tearing modulus断裂准则fracture criterionJ 积分J-integralJ 阻力曲线J-resistance curve断裂韧度fracture toughness应力强度因子stress intensity factor HRR 场Hutchinson-Rice-Rosengren Field 守恒积分conservation integral有效应力张量effective stress tensor应变能密度strain energy density能量释放率energy release rate内聚区cohesive zone塑性区plastic zone张拉区stretched zone热影响区heat affected zone, HAZ延脆转变温度brittle-ductile transition temperature固体力学弹性力学elasticity弹性理论theory of elasticity均匀应力状态homogeneous state of stress应力不变量stress invariant应变不变量strain invariant应变椭球strain ellipsoid均匀应变状态homogeneous state of strain应变协调方程equation of strain compatibility拉梅常量Lame constants各向同性弹性isotropic elasticity旋转圆盘rotating circular disk楔wedge开尔文问题Kelvin problem布西内斯克问题Boussinesq problem艾里应力函数Airy stress function克罗索夫--穆斯赫利什维利法Kolosoff-Muskhelishvili method 基尔霍夫假设Kirchhoff hypothesis板Plate矩形板Rectangular plate圆板Circular plate环板Annular plate波纹板Corrugated plate加劲板Stiffened plate,reinforced Plate中厚板Plate of moderate thickness弯［曲］应力函数Stress function of bending 壳Shell扁壳Shallow shell旋转壳Revolutionary shell球壳Spherical shell［圆］柱壳Cylindrical shell锥壳Conical shell环壳Toroidal shell封闭壳Closed shell波纹壳Corrugated shell扭［转］应力函数Stress function of torsion 翘曲函数Warping function半逆解法semi-inverse method瑞利--里茨法Rayleigh-Ritz method松弛法Relaxation method莱维法Levy method松弛Relaxation量纲分析Dimensional analysis自相似［性］self-similarity影响面Influence surface接触应力Contact stress赫兹理论Hertz theory协调接触Conforming contact滑动接触Sliding contact滚动接触Rolling contact压入Indentation各向异性弹性Anisotropic elasticity颗粒材料Granular material散体力学Mechanics of granular media 热弹性Thermoelasticity超弹性Hyperelasticity粘弹性Viscoelasticity对应原理Correspondence principle褶皱Wrinkle塑性全量理论Total theory of plasticity 滑动Sliding微滑Microslip粗糙度Roughness非线性弹性Nonlinear elasticity大挠度Large deflection突弹跳变snap-through有限变形Finite deformation格林应变Green strain阿尔曼西应变Almansi strain弹性动力学Dynamic elasticity运动方程Equation of motion准静态的Quasi-static气动弹性Aeroelasticity水弹性Hydroelasticity颤振Flutter弹性波Elastic wave简单波Simple wave柱面波Cylindrical wave水平剪切波Horizontal shear wave竖直剪切波Vertical shear wave体波body wave无旋波Irrotational wave畸变波Distortion wave膨胀波Dilatation wave瑞利波Rayleigh wave等容波Equivoluminal wave勒夫波Love wave界面波Interfacial wave边缘效应edge effect塑性力学Plasticity可成形性Formability金属成形Metal forming耐撞性Crashworthiness结构抗撞毁性Structural crashworthiness 拉拔Drawing破坏机构Collapse mechanism回弹Springback挤压Extrusion冲压Stamping穿透Perforation层裂Spalling塑性理论Theory of plasticity安定［性］理论Shake-down theory运动安定定理kinematic shake-down theorem 静力安定定理Static shake-down theorem率相关理论rate dependent theorem载荷因子load factor加载准则Loading criterion加载函数Loading function加载面Loading surface塑性加载Plastic loading塑性加载波Plastic loading wave简单加载Simple loading比例加载Proportional loading卸载Unloading卸载波Unloading wave冲击载荷Impulsive load阶跃载荷step load脉冲载荷pulse load极限载荷limit load中性变载nentral loading拉抻失稳instability in tension加速度波acceleration wave本构方程constitutive equation完全解complete solution名义应力nominal stress过应力over-stress真应力true stress等效应力equivalent stress流动应力flow stress应力间断stress discontinuity应力空间stress space主应力空间principal stress space静水应力状态hydrostatic state of stress对数应变logarithmic strain工程应变engineering strain等效应变equivalent strain应变局部化strain localization应变率strain rate应变率敏感性strain rate sensitivity应变空间strain space有限应变finite strain塑性应变增量plastic strain increment累积塑性应变accumulated plastic strain永久变形permanent deformation内变量internal variable应变软化strain-softening理想刚塑性材料rigid-perfectly plastic Material 刚塑性材料rigid-plastic material理想塑性材料perfectl plastic material材料稳定性stability of material应变偏张量deviatoric tensor of strain应力偏张量deviatori tensor of stress应变球张量spherical tensor of strain应力球张量spherical tensor of stress路径相关性path-dependency线性强化linear strain-hardening应变强化strain-hardening随动强化kinematic hardening各向同性强化isotropic hardening强化模量strain-hardening modulus幂强化power hardening塑性极限弯矩plastic limit bending Moment塑性极限扭矩plastic limit torque弹塑性弯曲elastic-plastic bending弹塑性交界面elastic-plastic interface弹塑性扭转elastic-plastic torsion粘塑性Viscoplasticity非弹性Inelasticity理想弹塑性材料elastic-perfectly plastic Material 极限分析limit analysis极限设计limit design极限面limit surface上限定理upper bound theorem上屈服点upper yield point下限定理lower bound theorem下屈服点lower yield point界限定理bound theorem初始屈服面initial yield surface后继屈服面subsequent yield surface屈服面［的］外凸性convexity of yield surface 截面形状因子shape factor of cross-section沙堆比拟sand heap analogy屈月艮Yield屈服条件yield condition屈服准则yield criterion屈服函数yield function屈服面yield surface塑性势plastic potential能量吸收装置energy absorbing device能量耗散率energy absorbing device塑性动力学dynamic plasticity塑性动力屈曲dynamic plastic buckling塑性动力响应dynamic plastic response塑性波plastic wave运动容许场kinematically admissible Field静力容许场statically admissible Field流动法则flow rule速度间断velocity discontinuity滑移线slip-lines滑移线场slip-lines field移行塑性铰travelling plastic hinge塑性增量理论incremental theory of Plasticity 米泽斯屈服准则Mises yield criterion普朗特--罗伊斯关系prandtl- Reuss relation特雷斯卡屈服准则Tresca yield criterion洛德应力参数Lode stress parameter莱维--米泽斯关系Levy-Mises relation亨基应力方程Hencky stress equation赫艾--韦斯特加德应力空间Haigh-Westergaard stress space 洛德应变参数Lode strain parameter德鲁克公设Drucker postulate盖林格速度方程Geiringer velocity Equation连续过程continuous process碰撞截面collision cross section通用气体常数conventional gas constant燃烧不稳定性combustion instability稀释度dilution完全离解complete dissociation火焰传播flame propagation组份constituent碰撞反应速率collision reaction rate燃烧理论combustion theory浓度梯度concentration gradient阴极腐蚀cathodic corrosion火焰速度flame speed火焰驻定flame stabilization火焰结构flame structure着火ignition湍流火焰turbulent flame层流火焰laminar flame燃烧带burning zone渗流flow in porous media, seepage达西定律Darcy law赫尔-肖流Hele-Shaw flow毛［细］管流capillary flow过滤filtration爪进fingering不互溶驱替immiscible displacement不互溶流体immiscible fluid互溶驱替miscible displacement互溶流体miscible fluid迁移率mobility流度比mobility ratio渗透率permeability孑匕隙度porosity多孔介质porous medium比面specific surface迂曲度tortuosity空隙void空隙分数void fraction注水water flooding可湿性wettability地球物理流体动力学geophysical fluid dynamics 物理海洋学physical oceanography大气环流atmospheric circulation海洋环流ocean circulation海洋流ocean current旋转流rotating flow平流advection埃克曼流Ekman flow埃克曼边界层Ekman boundary layer大气边界层atmospheric boundary layer大气-海洋相互作用atmosphere-ocean interaction 埃克曼数Ekman number罗斯贝数Rossby unmber罗斯贝波Rossby wave斜压性baroclinicity正压性barotropy内磨擦internal friction海洋波ocean wave盐度salinity环境流体力学environmental fluid mechanics斯托克斯流Stokes flow羽流plume理查森数Richardson number污染源pollutant source污染物扩散pollutant diffusion噪声noise噪声级noise level噪声污染noise pollution排放物effulent工业流体力学industrical fluid mechanics流控技术fluidics轴向流axial flow并向流co-current flow对向流counter current flow横向流cross flow螺旋流spiral flow旋拧流swirling flow滞后流after flow混合层mixing layer抖振buffeting风压wind pressure附壁效应wall attachment effect, Coanda effect简约频率reduced frequency爆炸力学mechanics of explosion终点弹道学terminal ballistics动态超高压技术dynamic ultrahigh pressure technique 流体弹塑性体hydro-elastoplastic medium热塑不稳定性thermoplastic instability空中爆炸explosion in air地下爆炸underground explosion水下爆炸underwater explosion电爆炸discharge-induced explosion激光爆炸laser-induced explosion核爆炸nuclear explosion点爆炸point-source explosion殉爆sympathatic detonation强爆炸intense explosion粒子束爆炸explosion by beam radiation 聚爆implosion起爆initiation of explosion爆破blasting霍普金森杆Hopkinson bar电炮electric gun电磁炮electromagnetic gun爆炸洞explosion chamber轻气炮light gas gun马赫反射Mach reflection基浪base surge成坑cratering能量沉积energy deposition爆心explosion center爆炸当量explosion equivalent火球fire ball爆高height of burst蘑菇云mushroom侵彻penetration规则反射regular reflection崩落spallation应变率史strain rate history流变学rheology聚合物减阻drag reduction by polymers 挤出［物］胀大extrusion swell, die swell 无管虹吸tubeless siphon剪胀效应dilatancy effect孑L压［误差］效应hole-pressure［error］effect 剪切致稠shear thickening剪切致稀shear thinning触变性thixotropy反触变性anti-thixotropy超塑性superplasticity粘弹塑性材料viscoelasto-plastic material滞弹性材料anelastic material本构关系constitutive relation麦克斯韦模型Maxwell model沃伊特-开尔文模型Voigt-Kelvin model宾厄姆模型Bingham model奥伊洛特模型Oldroyd model幂律模型power law model应力松驰stress relaxation应变史strain history应力史stress history记忆函数memory function衰退记忆fading memory应力增长stress growing粘度函数voscosity function相对粘度relative viscosity复态粘度complex viscosity拉伸粘度elongational viscosity拉伸流动elongational flow第一法向应力差first normal-stress difference第二法向应力差second normal-stress difference 德博拉数Deborah number魏森贝格数Weissenberg number动态模量dynamic modulus振荡剪切流oscillatory shear flow宇宙气体动力学cosmic gas dynamics等离［子］体动力学plasma dynamics电离气体ionized gas彳亍星边界层planetary boundary layer阿尔文波Alfven wave泊肃叶-哈特曼流］Poiseuille-Hartman flow哈特曼数Hartman number生物流变学biorheology生物流体biofluid生物屈服点bioyield point生物屈服应力bioyield stress电气体力学electro-gas dynamics铁流体力学ferro-hydrodynamics血液流变学hemorheology, blood rheology血液动力学hemodynamics磁流体力学magneto fluid mechanics磁流体动力学magnetohydrodynamics, MHD磁流体动力波magnetohydrodynamic wave磁流体流magnetohydrodynamic flow磁流体动力稳定性magnetohydrodynamic stability生物力学biomechanics生物流体力学biological fluid mechanics生物固体力学biological solid mechanics宾厄姆塑性流Bingham plastic flow开尔文体Kelvin body沃伊特体Voigt body可贴变形applicable deformation可贴曲面applicable surface边界润滑boundary lubrication液膜润滑fluid film lubrication向心收缩功concentric work离心收缩功eccentric work关节反作用力joint reaction force微循环力学microcyclic mechanics微纤维microfibril渗透性permeability生理横截面积physiological cross-sectional area 农业生物力学agrobiomechanics纤维度fibrousness硬皮度rustiness胶粘度gumminess粘稠度stickiness嫩度tenderness渗透流osmotic flow易位流translocation flow蒸腾流transpirational flow过滤阻力filtration resistance压扁wafering风雪流snow-driving wind停滞堆积accretion遇阻堆积encroachment沙漠地面desert floor流沙固定fixation of shifting sand流动阈值fluid threshold通类名词力学mechanics牛顿力学Newtonian mechanics经典力学classical mechanics静力学statics运动学kinematics动力学dynamics动理学kinetics宏观力学 macroscopic mechanics,macromechanics 细观力学mesomechanics微观力学 microscopic mechanics,micromechanics 一般力学general mechanics固体力学solid mechanics流体力学fluid mechanics理论力学theoretical mechanics应用力学applied mechanics工程力学engineering mechanics实验力学experimental mechanics计算力学computational mechanics理性力学rational mechanics物理力学physical mechanics地球动力学geodynamics力force作用点point of action作用线line of action力系system of forces力系的简化reduction of force system 等效力系equivalent force system刚体rigid body力的可传性transmissibility of force 平行四边形定则parallelogram rule力三角形force triangle力多边形force polygon零力系null-force system平衡equilibrium力的平衡equilibrium of forces平衡条件equilibrium condition平衡位置equilibrium position平衡态equilibrium state分析力学analytical mechanics拉格朗日乘子Lagrange multiplier拉格朗日［量］Lagrangian拉格朗日括号Lagrange bracket循环坐标cyclic coordinate循环积分cyclic integral哈密顿［量］Hamiltonian哈密顿函数Hamiltonian function正则方程canonical equation正则摄动canonical perturbation正则变换canonical transformation正则变量canonical variable哈密顿原理Hamilton principle作用量积分action integral哈密顿--雅可比方程Hamilton-Jacobi equation 作用--角度变量action-angle variables 阿佩尔方程Appell equation 劳斯方程Routh equation拉格朗日函数Lagrangian function 诺特定理Noether theorem 泊松括号poisson bracket边界积分法boundary integral method 并矢dyad运动稳定性stability of motion 轨道稳定性orbital stability 李雅普诺夫函数Lyapunov function 渐近稳定性asymptotic stability 结构稳定性structural stability 久期不稳定性secular instability 弗洛凯定理Floquet theorem 倾覆力矩capsizing moment 自由振动free vibration 固有振动natural vibration 暂态transient state环境振动ambient vibration 反共振anti-resonance 衰减attenuation库仑阻尼Coulomb damping 同相分量in-phase component 非同相分量out-of -phase component 超调量overshoot参量［激励］振动parametric vibration模糊振动fuzzy vibration临界转速critical speed of rotation阻尼器damper半峰宽度half-peak width集总参量系统lumped parameter system相平面法phase plane method相轨迹phase trajectory等倾线法isocline method跳跃现象jump phenomenon负阻尼negative damping达芬方程Duffing equation希尔方程Hill equationKBM 方法KBM method, Krylov-Bogoliu-bov-Mitropol'skii method 马蒂厄方程Mathieu equation平均法averaging method组合音调combination tone解谐detuning耗散函数dissipative function硬激励hard excitation硬弹簧hard spring, hardening spring谐波平衡法harmonic balance method久期项secular term自激振动self-excited vibration分界线separatrix亚谐波subharmonic软弹簧soft spring ,softening spring软激励soft excitation邓克利公式Dunkerley formula瑞利定理Rayleigh theorem分布参量系统distributed parameter system优势频率dominant frequency模态分析modal analysis固有模态natural mode of vibration同步synchronization超谐波ultraharmonic范德波尔方程van der pol equation频谱frequency spectrum基频fundamental frequencyWKB 方法WKB method, Wentzel-Kramers-Brillouin method 缓冲器buffer风激振动aeolian vibration嗡鸣buzz倒谱cepstrum颤动chatter蛇行hunting阻抗匹配impedance matching机械导纳mechanical admittance机械效率mechanical efficiency机械阻抗mechanical impedance随机振动stochastic vibration, random vibration隔振vibration isolation减振vibration reduction应力过冲stress overshoot喘振surge摆振shimmy起伏运动phugoid motion起伏振荡phugoid oscillation驰振galloping陀螺动力学gyrodynamics陀螺摆gyropendulum陀螺平台gyroplatform陀螺力矩gyroscoopic torque陀螺稳定器gyrostabilizer陀螺体gyrostat惯性导航inertial guidance姿态角attitude angle方位角azimuthal angle舒勒周期Schuler period机器人动力学robot dynamics多体系统multibody system多刚体系统multi-rigid-body system机动性maneuverability凯恩方法Kane method转子［系统］动力学rotor dynamics转子［一支承一基础］系统rotor-support-foundation system 静平衡static balancing动平衡dynamic balancing静不平衡static unbalance动不平衡dynamic unbalance现场平衡field balancing不平衡unbalance不平衡量unbalance互耦力cross force挠性转子flexible rotor分频进动fractional frequency precession 半频进动half frequency precession油膜振荡oil whip转子临界转速rotor critical speed自动定心self-alignment亚临界转速subcritical speed涡动whirl。

结构术语中英对照（建议收藏）强度strength承载能力load-carrying capacity脆断brittle fracture强度标准值characteristic value of strength强度设计值design value of strength一阶弹性分析first order elastic analysis阶弹性分析second order elastic analysis屈曲buckling腹板屈曲后强度post-buckling strength of web plate 通用高厚normalizde web slenderness整体稳定overall stability有效宽度。

effective width有效宽度系数effective width factor长细比 slenderness ratio换算长细比equivalent slenderness ratio支撑力 nodal bracing force无支撑纯框架unbraced frame强支撑框架frame braced with strong bracing system 弱支撑框架frame braced with weak bracing system 摇摆柱leaning column柱腹板节点域panel zone of column web球形钢支座spherical steel bearing橡胶支座couposite rubber and steel support主管chord member支管bracing member隙节点 gap joint搭接节点 overlap joint平面管节点 uniplanar joint空间管节点multiplanar joint组合构件built-up member钢与混凝土组合梁 composite steel and concrete beamAacceptable quality 合格质量acceptance lot 验收批量aciera 钢材against slip coefficient between frictionsurface of high-strength bolted connection高强度螺栓摩擦面抗滑移系数allowable ratio of height to sectionalthickness of masonry wall or column砌体墙、柱容许高厚比allowable slenderness ratio of steel member 钢构件容许长细比allowable slenderness ratio of timbercompression member 受压木构件容许长细比allowable stress range of fatigue 疲劳容许应力幅allowable ultimate tensile strain ofreinforcement 钢筋拉应变限值allowable value of crack width 裂缝宽度容许值allowable value of deflection of structuralmember 构件挠度容许值allowable value of deflection of timberbending member 受弯木构件挠度容许值allowable value of deformation of steelmember 钢构件变形容许值allowable value of deformation of structuralmember 构件变形容许值allowable value of drift angle of earthquakeresistant structure抗震结构层间位移角限值amplified coefficient of eccentricity 偏心距增大系数anchorage 锚具anchorage length of steel bar 钢筋锚固长度approval analysis during construction stage 施工阶段验算arch 拱arch with tie rod 拉捍拱arch-shaped roof truss 拱形屋架area of shear plane 剪面面积area of transformed section 换算截面面积aseismic design 建筑抗震设计assembled monolithic concrete structure 装配整体式混凝土结构automatic welding 自动焊接auxiliary steel bar 架立钢筋Bbackfilling plate 垫板balanced depth of compression zone 界限受压区高度balanced eccentricity 界限偏心距bar splice 钢筋接头bark pocket 夹皮batten plate 缀板beam 次梁bearing plate 支承板bearing stiffener 支承加劲肋bent-up steel bar 弯起钢筋board 板材bolt 螺栓bolted connection 钢结构螺栓连接bolted joint 木结构螺栓连接bolted steel structure 螺栓连接钢结构bonded prestressed concrete structure 有粘结预应力混凝土结构bow 顺弯breadth of wall between windows 窗间墙宽度building structural materials 建筑结构材料building structural unit 建筑结构单元building structure 建筑结构built-up steel column 格构式钢柱bundled tube structure 成束筒结构burn-through 烧穿butt connection 对接butt joint 对接butt weld 对接焊缝Ccalculating area of compression member 受压构件计算面积calculating overturning point 计算倾覆点calculation of load-carrying capacity ofmember 构件承载能力计算camber of structural member 结构构件起拱cantilever beam 挑梁cavitation 孔洞characteriseic value of live load on floor orroof 楼面、屋面活荷载标准值characteristi cvalue o fwindload 风荷载标准值characteristic value of concrete compressivestrength 混凝土轴心抗压强度标准值characteristic value of concrete tensilestrength 混凝土轴心抗拉标准值characteristic value of cubic concretecompressive strength 混凝土立方体抗压强度标准值characteristic value of earthquake action 地震作用标准值characteristic value of horizontal crane load吊车水平荷载标准值characteristic value of masonry strength 砌体强度标准值characteristic value of permanent action 永久作用标准值characteristic value of snowload 雪荷载标准值characteristic value of strength of steel 钢材强度标准值characteristic value of strength of steel bar钢筋强度标准值characteristic value of uniformly distributedlive load 均布活标载标准值characteristic value of variable action 可变作用标准值characteristic value of vertical crane load 吊车竖向荷载标准值charaeteristic value of material strength 材料强度标准值chimney 烟囱circular double-layer suspended cable 圆形双层悬索circular single-layer suspended cable 圆形单层悬索circumferential weld 环形焊缝clear height 净高cold bend inspection of steelbar 冷弯试验cold drawn bar 冷拉钢筋cold drawn wire 冷拉钢丝cold-formed thin-walled sectionsteel 冷弯薄壁型钢cold-formed thin-walled steel structure 冷弯薄壁型钢结构cold-rolled deformed bar 冷轧带肋钢筋column bracing 柱间支撑combination value of live load on floor orroof 楼面、屋面活荷载组合值compaction 密实度compliance control 合格控制composite floor system 组合楼盖composite floor with profiled steel sheet 压型钢板楼板composite roof truss 组合屋架compostle member 组合构件compound stirrup 复合箍筋compression member with large eccentricity 大偏心受压构件compression member with small eccentricity 小偏心受压构件compressive strength at an angle with slopeof grain 斜纹承压强度compressive strength perpendicular to grain 横纹承压强度concentration of plastic deformation 塑性变形集中conceptual earthquake-resistant design 建筑抗震概念设计connecting plate 连接板connection 连接connections of steel structure 钢结构连接connections of timber structure 木结构连接consistency of mortar 砂浆稠度constant cross-section column 等截面柱construction and examination concentratedload 施工和检修集中荷载continuous weld 连续焊缝core area of section 截面核芯面积core tube supported structure 核心筒悬挂结构corrosion of steel bar 钢筋锈蚀coupled wall 连肢墙coupler 连接器coupling wall-beam 连梁coupling wall-column... 墙肢coursing degree of mortar 砂浆分层度cover plate 盖板covered electrode 焊条crack 裂缝crack resistance 抗裂度crack width 裂缝宽度crane girder 吊车梁crane load 吊车荷载creep of concrete 混凝土徐变crook 横弯cross beam 井字梁cup 翘弯curved support 弧形支座Ddeformation analysis 变形验算degree of gravity vertical for structure orstructural member 结构构件垂直度degree of gravity vertical forwall surface 墙面垂直度degree of plainness for structural memer 构件平整度degree of plainness for wall surface 墙面平整度depth of compression zone 受压区高度depth of neutral axis 中和轴高度design of building structures 建筑结构设计design value of earthquake-resistant strengthof materials 材料抗震强度设计值design value of load-carrying capacity ofmembers 构件承载能力设计值designations 0f steel 钢材牌号designvalue of material strength 材料强度设计值destructive test 破损试验detailing reintorcement 构造配筋detailing requirements 构造要求diamonding 菱形变形diaphragm 横隔板dimensional errors 尺寸偏差distribution factor of snow pressure 屋面积雪分布系数double component concrete column 双肢柱dowelled joint 销连接down-stayed composite beam 下撑式组合粱ductile frame 延性框架dynamic design 动态设计Eearthquake-resistant design 抗震设计earthquake-resistant detailing requirements 抗震构造要求effective area of fillet weld 角焊缝有效面积effective depth of section 截面有效高度effective diameter of bolt or high-strength bolt 螺栓或高强度螺栓有效直径effective height 计算高度effective length 计算长度effective length of fillet weld 角焊缝有效计算长度effective length of nail 钉有效长度effective span 计算跨度effective supporting length at end of beam 梁端有效支承长度effective thickness of fillet weld 角焊缝有效厚度elastic analysis scheme 弹性方案elastic foundation beam 弹性地基梁elastic foundation plate 弹性地基板elastically supported continuous girder 弹性支座连续梁elasticity modulus of materials 材料弹性模量elongation rate 伸长率embeded parts 预埋件enhanced coefficient of local bearingstrength of materials 局部抗压强度提高系数equivalent slenderness ratio 换算长细比equivalent uniformly distributed live load 等效均布活荷载etlectlve cross-section area of high-strengthbolt 高强度螺栓的有效截面积ettectlve cross-section area of bolt 螺栓有效截面面积euler's critical load 欧拉临界力euler's critical stress 欧拉临界应力Ffiller plate 填板门fillet weld 角焊缝finger joint 指接fish eye 白点fish-belly beam 角腹式梁fissure 裂缝flexible connection 柔性连接flexural rigidity of section 截面弯曲刚度flexural stiffness of member 构件抗弯刚度floor plate 楼板floor system 楼盖four sides(edgessupported plate 四边支承板frame structure 框架结构frame tube structure 单框筒结构frame tube structure 框架-简体结构frame with sidesway 有侧移框架frame without sidesway 无侧移框架frange plate 翼缘板friction coefficient of masonry 砌体摩擦系数full degree of mortar at bed joint 砂浆饱满度function of acceptance 验收函数Ggang nail plate joint 钉板连接grider 主梁grip 夹具grith weld 环形焊缝groove 坡口gusset plate 节点板Hhanger 吊环hanging steel bar 吊筋heat tempering bar 热处理钢筋height variation factor of wind pressure 风压高度变化系数heliral weld 螺旋形僻缝high-strength bolt 高强度螺栓high-strength bolt with large hexagon bea 大六角头高强度螺栓high-strength bolted bearing type join 承压型高强度螺栓连接，high-strength bolted connection 高强度螺栓连接high-strength bolted friction-type joint 摩擦型高强度螺栓连接high-strength holted steel slsteel structure 高强螺栓连接钢结构hinge support 铰轴支座hinged connection 铰接hlngeless arch 无铰拱hollow brick 空心砖hollow ratio of masonry unit 块体空心率honeycomb 蜂窝hook 弯钩hoop 箍筋hot-rolled deformed bar 热轧带肋钢筋hot-rolled plain bar 热轧光圆钢筋hot-rolled section steel 热轧型钢hunched beam 加腋梁Iimpact toughness 冲击韧性impermeability 抗渗性inclined section 斜截面inclined stirrup 斜向箍筋incomplete penetration 未焊透incomplete tusion 未溶合incompletely filled groove 未焊满indented wire 刻痕钢丝influence coefficient for load-bearingcapacity of compressionmember 受压构件承载能力影响系数influence coefficient for spacial action 空间性能影响系数initial control 初步控制inspection for properties of glue used instructural member 结构用胶性能检验inspection for properties of steelbar 钢筋性能检验integral prefabricated prestressed concreteslab-column structure整体预应力板柱结构intermediate stiffener 中间加劲肋intermittent weld 断续焊缝Jjoint of reinforcement 钢筋接头Kkey joint 键连接kinetic design 动态设计knot 节子(木节)Llaced of battened compression member 格构式钢柱lacing and batten elements 缀材(缀件)lacing bar 缀条lamellar tearing 层状撕裂lap connectlon 叠接(搭接)lapped length of steel bar 钢筋搭接长度large pannel concrete structure 混凝土大板结构large-form cocrete structure 大模板结构lateral bending 侧向弯曲lateral displacement stiffness of storey 楼层侧移刚度lateral displacement stiffness of structure 结构侧移刚度lateral force resistant wallstructure 抗侧力墙体结构leg size of fillet weld 角焊缝焊脚尺寸length of shear plane 剪面长度lift-slab structure 升板结构limiting value for sectional dimension 截面尺寸限值limiting value for supporting length 支承长度限值limiting value for total height of masonrystructure 砌体结构总高度限值linear expansion coeffcient 线膨胀系数lintel 过梁load bearing wall 承重墙load-carrying capacity per bolt 单个普通螺栓承载能力load-carrying capacity per high-strength holt单个高强螺桂承载能力load-carrying capacity per rivet 单个铆钉承载能力long term rigidity of member 构件长期刚度longitude horizontal bracing 纵向水平支撑longitudinal steel bar 纵向钢筋longitudinal stiffener 纵向加劲肋longitudinal weld 纵向焊缝losses of prestress 预应力损失lump material 块体Mmain axis 强轴main beam 主梁major axis 强轴manual welding 手工焊接manufacture control 生产控制mechanical properties of materials 材料力学性能melt-thru 烧穿method of sampling 抽样方法minor axls 弱轴modified coefficient for allowable ratio ofheight to sectionalthickness of masonry wall 砌体墙容许高厚比修正系数modulus of elasticity of concrete 混凝土弹性模量modulus of elasticity parellel to grain 顺纹弹性模量moisture content 含水率moment modified factor 弯矩调幅系数monitor frame 天窗架mortar 砂浆multi-defence system of earthquake-resistantbuilding 多道设防抗震建筑multi-tube supported suspended structure 多筒悬挂结构Nnailed joint 钉连接net height 净高net span 净跨度non-destructive inspection of weld 焊缝无损检验non-destructive test 非破损检验non-load-bearingwall 非承重墙non-uniform cross-section beam 变截面粱non-uniformly distributed strain coefficientof longitudinal tensile reinforcement纵向受拉钢筋应变不均匀系数normal concrete 普通混凝土normal section 正截面notch and tooth joint 齿连接number of sampling 抽样数量Oobligue section 斜截面oblique-angle fillet weld 斜角角焊缝one-way reinforced(or prestressedconcreteslab 单向板open web roof truss 空腹屋架ordinary concrete 普通混凝土ordinary steel bar 普通钢筋orthogonal fillet weld 直角角焊缝outstanding width of flange 翼缘板外伸宽度outstanding width of stiffener 加劲肋外伸宽度over-all stability reduction coefficient ofsteel beam 钢梁整体稳定系数overturning or slip resistance analysis 抗倾覆、滑移验算Ppadding plate 垫板partial penetrated butt weld 不焊透对接焊缝partition 非承重墙penetrated butt weld 透焊对接焊缝percentage of reinforcement 配筋率pilastered wall 带壁柱墙pit 凹坑pith 髓心plain concrete structure 素混凝土结构plane hypothesis 平截面假定plane structure 平面结构plane trussed lattice grids 平面桁架系网架plank 板材plastic adaption coefficient of cross-section截面塑性发展系数plastic design of steel structure 钢结构塑性设计plastic hinge 塑性铰plastlcity coefficient of reinforced concretemember in tensilezone受拉区混凝土塑性影响系数plate-like space frame 干板型网架plate-like space truss 平板型网架plug weld 塞焊缝plywood 胶合板pockmark 麻面polygonal top-chord roof truss 多边形屋架post-tensioned prestressed concrete structure后张法预应力混凝土结构precast reinforced concrete member 预制混凝土构件prefabricated concrete structure 装配式混凝土结构presetting time 初凝时间prestressed concrete structure 预应力混凝土结构prestressed steel structure 预应力钢结构prestressed tendon 预应力筋pre-tensioned prestressed concrete structure 先张法预应力混凝土结构primary control 初步控制production control 生产控制properties of fresh concrete 可塑混凝土性能properties of hardened concrete 硬化混凝土性能property of building structural materials 建筑结构材料性能purlin 檩条Qquality grade of weld 焊缝质量级别quality inspection of bolted connection 螺栓连接质量检验quality inspection of riveted connection 铆钉连接质量检验quasi-permanent value of live load on flooror roof 楼面、屋面活荷载准永久值Rradial check 辐裂ratio of axial compressive force to axialcompressive ultimate capacity of section轴压比ratio of height to sectional thickness ofwall or column 砌体墙柱高、厚比ratio of reinforcement 配筋率ratio of shear span to effective depth ofsection 剪跨比redistribution of internal force 内力重分布reducing coefficient of compressive strengthin sloping grain for bolted connection螺栓连接斜纹承压强度降低系数reducing coefficient of liveload 活荷载折减系数reducing coefficient of shearing strength fornotch and tooth connection齿连接抗剪强度降低系数regular earthquake-resistant building 规则抗震建筑reinforcement ratio 配筋率reinforcement ratio per unit volume 体积配筋率relaxation of prestressed tendon 预应筋松弛representative value of gravity load 重力荷载代表值resistance to abrasion 耐磨性resistance to freezing and thawing 抗冻融性resistance to water penetration 抗渗性reveal of reinforcement 露筋right-angle filletweld 直角角焊缝rigid analysis scheme 刚性方案rigid connection 刚接rigid transverse wall 刚性横墙rigid zone 刚域rigid-elastic analysis scheme 刚弹性方案rigidity of section 截面刚度rigidly supported continous girder 刚性支座连续梁ring beam 圈梁rivet 铆钉riveted connecction 铆钉连接riveted steel beam 铆接钢梁riveted steel girder 铆接钢梁riveted steel structure 铆接钢结构rolle rsupport 滚轴支座rolled steel beam 轧制型钢梁roof board 屋面板roof bracing system 屋架支撑系统roof girder 屋面梁roof plate 屋面板roof slab 屋面板roof system 屋盖roof truss 屋架round wire 光圆钢丝Ssafety classes of building structures 建筑结构安全等级safetybolt 保险螺栓saw-tooth joint failure 齿缝破坏scarf joint 斜搭接seamless steel pipe 无缝钢管seamless steel tube 无缝钢管second moment of area of tranformed section 换算截面惯性矩second order effect due to displacement 挠曲二阶效应secondary axis 弱轴secondary beam 次粱section modulus of transformed section 换算截面模量section steel 型钢semi-automatic welding 半自动焊接separated steel column 分离式钢柱setting time 凝结时间shake 环裂shaped steel 型钢shapefactorofwindload 风荷载体型系数shear plane 剪面shearing rigidity of section 截面剪变刚度shearing stiffness of member 构件抗剪刚度short stiffener 短加劲肋short term rigidity of member 构件短期刚度shrinkage 干缩shrinkage of concrete 混凝干收缩silos 贮仓skylight truss 天窗架slab 楼板slab-column structure 板柱结构slag inclusion 夹渣sloping grain 斜纹slump 坍落度snow reference pressure 基本雪压solid-web steel column 实腹式钢柱space structure 空间结构space suspended cable 悬索spacing of bars 钢筋间距spacing of rigid transverse wall 刚性横墙间距spacing of stirrup legs 箍筋肢距spacing of stirrups 箍筋间距specified concrete 特种混凝上spiral stirrup 螺旋箍筋spiral weld 螺旋形焊缝split ringjoint 裂环连接square pyramid space grids 四角锥体网架stability calculation 稳定计算stability reduction coefficient of axiallyloaded compression 轴心受压构件稳定系数stair 楼梯static analysis scheme of building 房屋静力汁算方案static design 房屋静力汁算方案statically determinate structure 静定结构statically indeterminate structure 超静定结构sted 钢材steel bar 钢筋steel column component 钢柱分肢steel columnbase 钢柱脚steel fiber reinforced concrete structure 钢纤维混凝土结构steel hanger 吊筋steel mesh reinforced brick masonry member 方格网配筋砖砌体构件steel pipe 钢管steel plate 钢板steel plateelement 钢板件steel strip 钢带steel support 钢支座steel tie 拉结钢筋steel tie bar for masonry 砌体拉结钢筋steel tube 钢管steel tubular structure 钢管结构steel wire 钢丝stepped column 阶形柱stiffener 加劲肋stiffness of structural member 构件刚度stiffness of transverse wall 横墙刚度stirrup 箍筋storev height 层高straight-line joint failure 通缝破坏straightness of structural member 构件乎直度strand 钢绞线strength classes of masonry units 块体强度等级strength classes of mortar 砂浆强度等级strength classes of structural steel 钢材强度等级strength classes(grades of prestressed tendon预应力筋强度等级strength classes(grades of steel bar 普通钢筋强度等级strength of structural timber parallel tograin 木材顺纹强度strongaxis 强轴structural system composed of bar 杆系结构structural system composed of plate 板系结构structural wall 结构墙superposed reinforced concrete flexuralmember 叠合式混凝土受弯构件suspended crossed cable net 双向正交索网结构suspended structure 悬挂结构swirl grain 涡纹Ttensile(compressive) rigidity of section 截面拉伸(压缩刚度)tensile(compressive) stiffness of member 构件抗拉(抗压刚度) tensile(ultimate) strength of steel 钢材抗拉(极限强度)test for properties of concrete structuralmembers 构件性能检验thickness of concrete cover 混凝土保护层厚度thickness of mortarat bed joint 水平灰缝厚度thin shell 薄壳three hinged arch 三铰拱tie bar 拉结钢筋tie beam 系梁tie tod 系杆tied framework 绑扎骨架tor-shear type high-strength bolt 扭剪型高强度螺栓torsional rigidity of section 截面扭转刚度torsional stiffness of member 构件抗扭刚度total breadth of structure 结构总宽度total height of structure 结构总高度total length of structure 结构总长度transmission length of prestress 预应力传递长度transverse horizontal bracing 横向水平支撑transverse stiffener 横向加劲肋transverse weld 横向焊缝transversely distributed steelbar 横向分布钢筋trapezoid roof truss 梯形屋架triangular pyramid space grids 三角锥体网架triangular roof truss 三角形屋架trussed arch 椽架trussed rafter 桁架拱tube in tube structure 筒中筒结构tube structure 简体结构twist 扭弯two hing。

淮阴工学院毕业设计外文资料翻译系（院）：建筑工程学院专业：土木工程房建方向姓名：学号：1091407202外文出处：成都理工大学Chengdu University of Technology (用外文写)附件： 1.外文资料翻译译文；2.外文原文。

附件1：原文翻译抗侧向荷载的结构体系常用的结构体系如果已经测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少其他复杂的构思余地了。

确实，较好的高层建筑普遍具有构思简单、表现明晰的特点。

这并不是说没有进行宏观构思的余地。

实际上，正是因为有了这种宏观的构思，新奇的高层建筑体系才得以发展，可能更重要的是：前几年才出现的一些新概念在今天的技术中已经变的一般了。

如果忽略一些与建筑材料密切相关的概念不谈，高层建筑里最为常用的结构体系可以分为如下几类：抗弯矩框架。

支撑框架，包括偏心支撑框架。

剪力墙，包括钢板剪力墙。

筒中框架。

筒中筒结构。

核心交互结构。

框架体系或束筒体系。

特别是由于现在需要采用更复杂的建筑形式，同时也需要增加刚度以抵抗风力和地震力，大多数高层建筑都具有由框架、支撑构架、剪力墙和相关体系相结合而构成的体系。

而且，对于那些较高的建筑物来说，大多数都是由交互式构件组成三维陈列。

将这些构件结合起来的方法正是高层建筑设计方法的本质。

其结合方式需要在考虑环境、功能和费用后再进行具体组合，以便提供促使建筑发展达到新高度的有效结构。

这并不是说富于想象力的结构设计就能够创造出伟大建筑。

正相反，有许多优美的建筑仅得到结构工程师适当的支持就被创造出来了，然而，如果没有天赋甚厚的建筑师的创造力的指导，那么，就只有好的结构才能得以发展，并非是伟大的建筑。

无论如何，要想创造出高层建筑真正非凡的设计，两者都需要最好的。

虽然在许多文献中可以见到有关这七种体系的全面性讨论，但是在这里还值得进一步讨论。

设计方法的本质贯穿于整个讨论中。

抗弯矩框架抗弯矩框架也许是低，中高度的建筑物中常用的体系，它具有线性水平构件和垂直构件的特点。

原文翻译：抗侧向荷载的结构体系常用的结构体系若已测出荷载量达数千万磅重，那么在高层建筑设计中就没有多少可以进行极其复杂的构思余地了。

确实，较好的高层建筑普遍具有构思简单、表现明晰的特点。

这并不是说没有进行宏观构思的余地。

实际上，正是因为有了这种宏观的构思，新奇的高层建筑体系才得以发展，可能更重要的是：几年以前才出现的一些新概念在今天的技术中已经变得平常了。

如果忽略一些与建筑材料密切相关的概念不谈，高层建筑里最为常用的结构体系便可分为如下几类：1．抗弯矩框架。

2．支撑框架，包括偏心支撑框架。

3．剪力墙，包括钢板剪力墙。

4．筒中框架。

5．筒中筒结构。

6．核心交互结构。

7．框格体系或束筒体系。

特别是由于最近趋向于更复杂的建筑形式，同时也需要增加刚度以抵抗几力和地震力，大多数高层建筑都具有由框架、支撑构架、剪力墙和相关体系相结合而构成的体系。

而且，就较高的建筑物而言，大多数都是由交互式构件组成三维陈列。

将这些构件结合起来的方法正是高层建筑设计方法的本质。

其结合方式需要在考虑环境、功能和费用后再发展，以便提供促使建筑发展达到新高度的有效结构。

这并不是说富于想象力的结构设计就能够创造出伟大建筑。

正相反，有许多例优美的建筑仅得到结构工程师适当的支持就被创造出来了，然而，如果没有天赋甚厚的建筑师的创造力的指导，那么，得以发展的就只能是好的结构，并非是伟大的建筑。

无论如何，要想创造出高层建筑真正非凡的设计，两者都需要最好的。

虽然在文献中通常可以见到有关这七种体系的全面性讨论，但是在这里还值得进一步讨论。

设计方法的本质贯穿于整个讨论。

设计方法的本质贯穿于整个讨论中。

抗弯矩框架抗弯矩框架也许是低，中高度的建筑中常用的体系，它具有线性水平构件和垂直构件在接头处基本刚接之特点。

这种框架用作独立的体系，或者和其他体系结合起来使用，以便提供所需要水平荷载抵抗力。

对于较高的高层建筑，可能会发现该本系不宜作为独立体系，这是因为在侧向力的作用下难以调动足够的刚度。

I Load Code for the Design of Building Structures 建筑结构荷载规范Permanent load 永久荷载Variable load 可变荷载Accidental load 偶然荷载Representative values of a load 荷载代表值Design reference period 设计基准期Characteristic value \ nominal value 标准值Combination value 组合值Frequent value 频预值Quasi-permanent value 准永久值Design value of a load 荷载设计值Load combination 荷载组合Fundamental combination 基本组合Accidental combination 偶然组合Characteristic \ nominal combination 标准组合Frequent combinations 频遇组合Quasi-permanent combinations 准永久组合Equivalent uniform load 等效均布荷载Tributary area 从属面积Dynamic coefficient 动力系数Reference snow pressure 基本雪压Reference window pressure 基本风压Terrain roughness 地面粗燥度II Code for Seismic Design of Building GB 5001-2001 建筑抗震设计规范Earthquake action 地震作用Seismic fortification intensity 抗震设防烈度Seismic fortification criteria 抗震设防标准Design parameters of ground motion 设计地震动参数Design basic acceleration of ground motion 设计基本地震加速度Design characteristic period of ground motion 设计特征周期Seismic concept design of building 建筑抗震概念设计Seismic fortification measures 抗震措施Details of seismic design 抗震构造措施Site 场地III Code for Design of Steel Structures GB 5001-2003 钢结构设计规范Strength 强度Load-carrying capability 承载能力Brittle fracture 脆断（指钢结构在拉应力状态下没有出现警示性的塑性变形而突然发生的脆性断裂）Characteristic value of strength 强度标准值（钢材屈服点和抗拉强度）Design value of strength 强度设计值First order elastic analysis 一阶弹性分析Second order elastic analysis 二阶弹性分析Buckling 屈曲（杆件或板件在轴心压力、弯矩、剪力单独或共同作用下突然发生与原受力状态不符的较大变形而失去稳定）Post-buckling strength of web plate腹板屈曲后强度（腹板屈曲后尚能保持承受荷载的能力）Normalized web slenderness 通用高后比Overall stability 整体稳定Effective width 有效宽度Effective width factor 有效宽度系数Effective length 有效长度Slenderness ratio 长细比（构件长度与截面的回转半径比）Equivalent Slenderness ratio 换算长细比Nodal bracing force 支撑力Unbraced frame 无支撑纯框架Frame braced with strong bracing system 强支撑框架Frame braced with weak bracing system 弱支撑框架Leaning column 摇摆柱（框架内两端为铰接不能抵抗侧向荷载的柱）Panel zone of column web 柱腹板节点域Spherical steel bearing 球形钢支座Couposite rubber and steel support 橡胶支座Chord member 主管Bracing member 支管Gap joint 间隙节点Overlap joint 搭接节点Uniplanar joint 平面管节点Multiplanar joint 空间管节点Built-up member 组合构件Composite steel and concrete beam 钢与混泥土组合梁IV Design Code for Strengthening Concrete Structure GB 50367-2006混泥土结构加固设计规范Strengthening of existing structures 已有结构加固Existing structure member 原构件Important structure member 重要构件General structure member 一般构件Structure member strengthening with reinforced concrete 增大截面加固法Structure member strengthening with externally bonded steel frame 外粘型钢加固法Structure member strengthening with externally bonded reinforced materials 复合截面加固法Structure member confined by reinforcing wire 绕丝加固法Structure member strengthening with externally applied prestressing 外加预应力加固法Bonded rebars 植筋（用专用结构胶粘剂将带肋钢筋锚固于基材混泥土中）Structural adhesives 结构胶粘剂（可承重，传力）Fiber reinforced polymer（FRP）纤维复合材Polymer mortar 聚合物砂浆Effective cross-section area 有效截面积Design working life for strengthening of existing structure or its member 加固设计使用年限V Technical Code of Cold-formed Thin-wall Steel Structures GB 50367-2006冷弯薄壁型钢结构技术规范Element 板件（薄壁型钢杆件中相邻两纵边之间的平板部分）Stiffened elements 加劲板件（两纵边均与其他板件相连接）Partially Stiffened elements 部分加劲板Unstiffened elements 非加劲板Uniformly compressed elements 均匀受压板件Non- Uniformly compressed elementsSub-elements 子板件Width-to-thickness ratio 宽厚比Effective Width-to-thickness ratio 有效宽厚比Effect of cold forming 冷弯效应（因冷弯引起钢材性能改变的现象）Stressed skin action 受力蒙皮作用（与支撑构件可靠连接的压型钢板体系所具有的抵抗板自身平面内剪切变形的能力）Flare groove welds 喇叭形焊缝（连接圆角与圆角或圆角与平板间隙处的焊缝）VI Technical Specification for Application of Architectural Glass JGJ 113-2009建筑玻璃技术规范Architectural Glass 建筑玻璃Strength on centre area of glass 玻璃中部强度（荷载垂直玻璃板面，玻璃中部强度）Strength on border area of glass 玻璃边缘强度Strength on edge of glass 玻璃端面强度Single glass 单片玻璃Framed glazing 有框玻璃Roof glass 屋面玻璃Floor and stairway glazing 地板玻璃Front\ back clearance 前部\ 后部余隙Edge clearance 边缘间隙Edge cover 潜入深度VII Technical Specification for Post-installed Fastenings in Concrete Structures JGJ 145-2004 混泥土结构后锚固技术规范Post-installed fastening 后锚固Anchor 锚栓Expansion anchors 膨胀型锚栓Undercut anchors 扩孔型锚栓Bonded rebars 化学植筋（以化学胶粘剂-----锚固胶将钢筋固定于混泥土基材锚孔）Base material 基材Anchor group 群锚Fixture 被连接件（被锚固于混泥土基材上的物件）Anchor plate 锚板Failure mode 破坏模型Anchor failure 锚栓破坏Concrete cone failure 混泥土锥体破坏Combination failure 混合型破坏Concrete edge failure 混泥土边缘破坏Pryout failure 剪撬破坏Splitting failure 劈裂破坏Pull-out failure 拔出破坏Pull-through failure 穿出破坏Steel\ adhesive interface failure 胶筋界面破坏Adhesive\ concrete interface failure 胶混界面破坏Design working life 设计使用年限VIII Code of Design on Building Fire Protection and Prevention GB 50016---2006建筑设计防火规范Fire resistance rating 耐火极限Non-combustible component 不燃烧体Difficult-combustible component 难燃烧体Combustible component 燃烧体Flash point 闪点（在规定实验条件下，液体挥发的蒸汽与空气形成的混合物，遇火源能发生闪燃的最低温度）Lower explosion limit 爆炸下限Boiling spill oil 沸溢性油品Semi-basement 半地下室Multi-storied industrial building 多层厂房（仓库）High-rise industrial building 高层厂房（仓库）High racked storage 高架仓库Commercial service facilities 商业服务网点Important public buildings 重要公共建筑Open flame site 明火地点Sparking site 散发火花地点Safety exit 安全出口Enclosed staircase 封闭楼梯间Smoke-proof staircase 防烟楼梯间Fire compartment 防火分区Fire separation distance防火间距Smoke bay 防烟分区Full water spout 充实水柱（由水枪喷嘴起到射流90%的水柱水量穿过直径380mm圆孔处的一段射流长度）IX Code for Design of Concrete Structure GB 50010---2002 混泥土结构设计规范Concrete structure 混泥土结构Plain concrete structure 素混泥土结构Reinforced concrete structure 钢筋混泥土结构Prestressed Concrete structure 预应力混泥土结构Pretensioned prestressed Concrete structure 先张法预应力混泥土结构Post-tensioned prestressed Concrete structure 后张法预应力混泥土结构Cast-in-situ concrete structure 现浇混泥土结构Prefabricated concrete structure 装配式混泥土结构Assembled monolithic concrete structure 装配整体式混泥土结构Frame structure 框架结构Shearwall structure 剪力墙结构Frame-shearwall structure 框架---剪力墙结构Deep flexural member 深度受弯构件Deep beam 深梁Ordinary steel bar 普通钢筋Prestressing tendon 预应力钢筋Degree of reliability 可靠度Safety class 安全等级Load effect 荷载效应Load effect combination 荷载效应组合Fundamental combination 基本组合Characteristic combination 标准组合Quasi-permanent combination 准永久组合。