5.philosophy of structural design

建筑设计词汇analysis of position 区位分析analysis of existing circumstance 现状分析analysis of function 功能分析sectorization 功能分区analysis of traffic/circulation/streamline 交通/流线分析 analysis of sunshine 日照分析analysis of landscape 景观分析landscape sight /view /vision景观视线analysis of space sequence 空间序列分析philosophy of design 设计理念bubble diagram 气泡图architectural conception 建筑构思architectural creation 建筑创作architectural Sketch 建筑草图layout 建筑布局presentation drawing /perspective 效果图hand drawing 手绘效果图a bird‘s-eye view 鸟瞰图Legend 图例Cover 封面Content 内容Design explanation 设计说明general layout / master plan / site plan 总平面图first floor plan 一层平面图ground floor plan 基础平面图typical floor plan 标准层平面图basement plan 地下室平面图（B1）first basement floor （G1）garage负一层roof plan 屋顶平面图elevation 立面图section 剖面图licensed architect 注册建筑师electrical engineer 电气工程师licensed structural engineer 注册结构工程师plant engineer 设备工程师mechanical engineer 机械工程师landscape architect 景观建筑师licensed planner 注册规划师plot plan engineer 总图工程师project budget 工程预算air-conditioning system 空调系统heating and ventilation 供暖与通风water supply and drainage 给水与排水structure design 结构设计acoustic design 声学设计lighting / illumination design 照明设计Indoor environment design 室内热环境设计Full-size drawing / Details drawing 详图Building code 建筑规范working drawings and the specifications 施工图与施工说明书construction site 建筑地基boundary line of roads 道路红线boundary line of land / property line 用地红线building line 建筑控制线building density / building coverage ratio 建筑密度plot ratio / floor area ratio 容积率greening rate绿地率eclecticism 折衷主义functionalism 功能主义post-modernism 后现代主义minimalism 极简主义deconstruction / deconstructivism 解构主义Italian Renaissance 意大利文艺复兴green building 绿色建筑Doric order 多立克柱式Ionic order 爱奥尼柱式Corinthian order 科林斯柱式Gothic Revival哥特复兴Greek temple 希腊神庙Triumphal arch 凯旋门URBAN PLANNING⏹town and country planning (urban and rural planning)城乡规划⏹city and regional planning 城市与区域规划⏹urban planning law of PRC 中华人民共和国城市规划法⏹城市发展战略层面：comprehensive planning / master plan 城市总体规划landuse planning 土地利用总体规划建筑控制引导层面：detailed plan 详细规划regulatory plan 控制性详细规划site plan 修建性详细规划☐R residential land 居住用地黄色☐ C public facilities 公共设施用地红色commercial ☐M industrial land 工业用地熟褐色manufacture ☐W warehouse land 仓储用地紫色☐T intercity transportation land 对外交通用地中灰色☐S roads and squares 道路广场用地留白☐U municipal utilities 市政公用设施用地蓝灰色☐G green space 绿地中草绿色☐ D specially-designed land 特殊用地深草地色☐ E waters and miscellaneous 水域和其它⏹城市分区规划city district planning⏹城市规模city size⏹城市发展模式urban development pattern⏹城市用地评价urban landuse evaluation⏹城市用地平衡urban landuse balance⏹研究切入点：⏹functional district 城市功能分区⏹urban structure 城市结构⏹urban morphology 城市形态⏹industrial district 工业区⏹residential district 居住区⏹commercial district 商业区⏹institutes and colleges district 文教区⏹Central business district 中央商务区（CBD）⏹warehouse district 仓储区⏹mixed-use district 综合区⏹scenic zone 风景区⏹civic center 市中心⏹sub-civic center 副中心⏹utility distribution 公共设施分布⏹城市给水系统water supply system⏹城市排水系统sewerage system⏹城市供电系统power supply system⏹城市供暖系统district heating system⏹城市燃气系统gas supply system⏹城市通信系统communication system⏹城市绿地系统urban green space system⏹城市道路系统urban road system⏹green belt 绿带⏹green buffer 防护绿地⏹express way 快速路⏹pedestrian street 步行街⏹city ecosystem 城市生态系统⏹balance of city ecosystem 城市生态平衡⏹city environmental quality 城市环境质量⏹city environmental assessment 城市环境评价⏹sustainable development 可持续发展⏹sustainable equilibrium 持久的平衡⏹conservation plan of historic cities 历史文化名城保护规划⏹urban renewal 城市更新⏹urban redevelopment 城市改造⏹urban revitalization 城市复苏⏹urban sprawl 城市扩张⏹urban expansion城市膨胀⏹urban flood control 城市防洪⏹earthquake hazard protection 城市防震⏹urban fire control 城市消防⏹urban air defence 城市防空⏹city (urban)planning commission城市规划委员会⏹city planning and administration bureau城市规划管理局⏹urban facilities城市设施⏹urban planning and development control城市规划建设管理⏹Integrated design for utilities pipeline城市工程管线综合⏹city style and features城市风貌⏹cityscape（city appearance）城市景观⏹city （town）refuse城市垃圾⏹city noise城市噪声⏹city skyline城市天际线住宅专业词汇总结•Villa（house、villahouse 、detached house）独栋别墅•Semi-detached house双拼别墅•Row houses 连排别墅•Townhouse城区住宅•High-grade residential高档住宅•duplex apartment跃层住宅•tall building of apartment单元式高层住宅•apartment of towerbuilding塔式高层住宅•gallery tall building of apartment通廊式高层住宅•housing cluster / group 住宅组团•residential community居住区•residential density居住密度•low-rise medium-density cluster housing低层中密度住宅群•business-living building商住楼•multiple-use （multi-use）high-rise building多功能高层建筑•dwelling size 套型•habitable space居住空间•bedroom卧室•living room 起居室•family room家庭活动室•kitchen厨房•bathroom卫生间•balcony阳台•terrace平台、露台•passage过道•ramp坡道•gallery （corridor gallery）走廊•overhanging corridor挑廊•eaves gallery檐廊•cloister回廊•bridge way架空走廊•semi-basement半地下室•empty space（open floor）架空层•refuge storey避难层•mechanical floor设备层•cabinet壁柜•wall-hung cupboard吊柜•view room眺望间•overhang骑楼•arcade过街楼•stair step 楼梯踏步•stairwell楼梯井•stair landing楼梯平台•stair railing楼梯栏杆•envelop enclosure围护结构•enclosing curtain wall围护性幕墙•decorative faced curtain wall装饰性幕墙•French windows落地橱窗•dormer window天窗•bay window凸窗/飘窗•sash-window上下推拉窗•louver window百叶窗•eaves and gable屋檐与山墙•parapet矮墙•plinth勒脚•canopy雨篷•masonry structure砖石结构/砖混结构•frame structure框架结构•steel-frame structure钢框架结构•frame-shearwall structure框剪结构•magastructure巨型结构•bearing wall承重墙•bearing strength承载力•concrete beam混凝土梁•concrete shell混凝土薄壳•reinforced concrete slab钢筋混凝土楼板•reinforced concrete column钢筋混凝土柱子•deformation joint变形缝•duration of fire resistance耐火极限•safety exit安全出口•hang wall挡烟垂壁•suspended ceiling吊顶•pipe shaft管道井•smoke uptake/flue烟道•air relief shaft通风道•motor repair shop修车库•parking area停车场•under ground garage地下汽车库•high-rise garage高层汽车库•mechanical and stereoscopic garage机械式立体汽车库•compound garage复式汽车库•Minimum turn radius of car汽车最小转弯半径。

素描Sketch画法几何Descriptive Geometry建筑设计初步Introduction of Architecture Design英语English高等数学A Advanced Mathematics A毛泽东思想概论Introduction of Mao Zedong's Thought试唱与练声Audition and Singing建筑设计Architecture Design法律基础Legal Basis邓小平理论概论Introduction of Deng Xiaoping’s theory建筑力学Engineering Mechanics室内设计Interior Design广告学Advertisement建筑结构选型Building Structure Selection城市规划原理Principles of Urban Planning中国古典园林Chinese Traditional Garden专业外语Professional English建筑节能Building Energy Saving建筑物理Architectural physics建筑施工技术经济管理Architectural Economics城市空间结构组织Spatial Structure of Urban Space建筑构造Architectural Construction工程测量Engineering Surveying中国古代建筑装饰Decorating Art of Traditional Chinese Architecture 室内设计发展史History of Interior Design高层建筑设计原理Principles of High Rising Buildings体育Physical Education思想品德修养Ideology and Morality of Accomplishment计算机基础Computer Basic马克思主义哲学原理Philosophy of Marxism阴影透视Shade Shadow Perspective形势与政策Situation and Policy马克思主义政治经济学原理Principles of Marxism Political Economics FORTRAN语言FORTRAN Language色彩Gouache Painting建筑材料Civil Engineering Materials建筑设计原理Principles of Building Design军训Military Training西方经济学概论Introduction of Western Economics中国建筑史History of Chinese Architecture美术史History of Art计算机辅助设计Computer Aided Design建筑结构Building Structure建筑构图原理Principles of Architectural Composition外国建筑史History of Foreign Architecture建筑美学Esthetics of Architecture建筑防火Building Fire Protection大学生心理卫生Students' Psychological Health建筑施工Civil Engineering Construction城市园林绿地规划Planning of Urban Garden and Park 建筑设备Building Equipment洁净建筑设计原理Renovation of Architecture Elevation 宗教建筑发展史History of Sacred Buildings室内空间设计方法Design method of Interior space近现代建筑人物与介绍Introduction of Modern Architects 城市经济Urban Economy。

1．专业名词Architectural engineering 建筑工程学Soil mechanics土力学Mechanics of materials材料力学Structure mechanics结构力学engineering mechanics工程力学Rock mass mechanics岩土力学Civil engineering 土木工程学Environmental engineering 环境工程Material science and dngingeering 材料科学与工程Professional Engineering 注册土木工程师Building engineering 房屋工程Bridge engineering 桥梁工程Geotechnical engineering岩土工程Hydraulic engineering水利工程geodetic sutveying 大地测量学topographic 地形学2.工程结构，工具，名词column 柱cable缆arch拱beam girder梁tower pylon塔frame框架timber 木材t—beam T梁rigid frame 刚架action 各种荷载的统称moment弯矩shear剪力axial force轴力torque扭矩formwork模板，支膜tracery格窗viaduct高架subgrade 路基crushed 碎石falsework 脚手架contour 等高线resistance抗力borehole 钻孔fracture脆断fatigue疲劳larder食品室，储藏室3．专业短语(1)applied stresses 作用应力yield criterion屈服准则yield point屈服点prestressing force预应力dead load 恒载live load 活载expansion joint伸缩缝safety factot 安全系数brittle fracture脆断load effect荷载效应shear strength 抗剪强度load-be tensile strength 抗拉强度aring structure 承重结构restraining pier约束墩pile foundations 桩基础suspension bridge悬索桥cable-stayed bridge斜拉桥plain concrete素混凝土prestressed concrete预应力混凝土structure of composite material复合材料结构structure analysis 结构分析design specifications设计规范safety servceability economy beautification,harmony with envitonment 安全适用经济美观industrial (civil) buliding 工业民用建筑allowable stress approach容许应力法ultimate load method极限荷载法limit state method极限状态法IncrementalLaunching( Push-out )Method顶推（或推顶）法cast in situ 现浇swell膨胀(2)geodetic大地测量学location party 勘测队preliminary location 初步定线subsoil 地基下层土soil investigation 土质勘测intact sample 原状样settltment 沉陷，沉降descend 下降，落下longitudinal profile (section)纵剖面（图）incipient failure 初期破坏gouge断层泥strike走向topographic relief地形起伏standared mesh 标准筛poisson’s ratio 泊松比pore water pressure 孔隙水压力geoiogical genetic地质成因cut slope路堑边坡trial pits 试验坑layered system层状体系e water table 地下水位ngingeering graduate 工科毕业生feasibility study 可行性研究construction phase施工阶段supervision管理，监控layout 布局、格式，平面图natural lighting 自然采光pretensioning (posttensioning)concrete先（后）张法service (live dead) load使用（活、静）荷载philosophy of structure design结构设计原理4．句子(1) 悬臂施工的优点是取消了脚手架the principal of advantage of theContilever tonstraction is the saving infalsework(2)在每个阶段,都要仔细计算和观测结构应力和徐变,以确保结构安全Structural stresses and deformationineach constration stage must beedudatee and inspection to ensure thesafety of the structure(3)目前,通常采用电子计算机进行应力松弛和混凝土徐变计算At ptessent ,computer usualy used forthe calouception of concrete creep andothers relasion(4)混凝土的长期收缩和徐变对预应力的损失产生很在的影响The effect of the shrinkage amd creepof concrete on the loss of prestress is alot(5)内力包括轴力,剪力,弯矩,扭矩等Intera forces consist of thrustshears ,bearing monmentand torque(6)不均匀沉降会导致结构产生更大的破坏Uneven settlement can causeprogressive structural damgage(7)土壤的物理性质与其本身的粒径有着密切的联系The physical properties of soils deeplyassociation with their particle size(8)在各种桥梁中悬索桥的跨度最大Among all bridges the span ofsuspension bridge is the biggest(9)需要强调数学力学，计算技术在土木工程应用中的重要性It is nessary to stress the important ofmathematics,mechanics,and computertechnique in the applcation of soilengineering(10)在许多情况下,可能会指派土木工程师参与其它工程项目的工作In other case ,civil engineers areassigned to work on a project in otherfields .(11)总工程师负责项目的构思与规划The general engineer is in charge of theplots and plans of the project(12)目前,正在试图生产出强度更高,耐久性更好且重量更轻的混凝土At pressent ,attempts are being made toproduce concrete with more strengh anddurability ,and with a lighter weight(13)桥梁上部结构由支座,支座面以上的构件组成The superstructures of a bridge consistsof bearing and elements alove them1．专业名词Architectural engineering 建筑工程学Soil mechanics土力学Mechanics of materials材料力学Structure mechanics结构力学engineering mechanics工程力学Rock mass mechanics岩土力学Civil engineering 土木工程学Environmental engineering 环境工程Material science and dngingeering 材料科学与工程Professional Engineering 注册土木工程师Building engineering 房屋工程Bridge engineering 桥梁工程Geotechnical engineering岩土工程Hydraulic engineering水利工程geodetic sutveying 大地测量学topographic 地形学2.工程结构，工具，名词column 柱cable缆arch拱beam girder梁tower pylon塔frame框架timber 木材t—beam T梁rigid frame 刚架action 各种荷载的统称moment弯矩shear剪力axial force轴力torque扭矩formwork模板，支膜tracery格窗viaduct高架subgrade 路基crushed 碎石falsework 脚手架contour 等高线resistance抗力borehole 钻孔fracture脆断fatigue疲劳larder食品室，储藏室3．专业短语(1)applied stresses 作用应力yield criterion屈服准则yield point屈服点prestressing force预应力dead load 恒载live load 活载expansion joint伸缩缝safety factot 安全系数brittle fracture脆断load effect荷载效应shear strength 抗剪强度load-be tensile strength 抗拉强度aring structure 承重结构restraining pier约束墩pile foundations 桩基础suspension bridge悬索桥cable-stayed bridge斜拉桥plain concrete素混凝土prestressed concrete预应力混凝土structure of composite material复合材料结构structure analysis 结构分析design specifications设计规范safety servceability economybeautification,harmony withenvitonment 安全适用经济美观industrial (civil) buliding 工业民用建筑allowable stress approach容许应力法ultimate load method极限荷载法limit state method极限状态法IncrementalLaunching( Push-out )Method顶推（或推顶）法cast in situ 现浇swell膨胀(2)geodetic大地测量学location party 勘测队preliminary location 初步定线subsoil 地基下层土soil investigation 土质勘测intact sample 原状样settltment 沉陷，沉降descend 下降，落下longitudinal profile (section)纵剖面（图）incipient failure 初期破坏gouge断层泥strike走向topographic relief地形起伏standared mesh 标准筛poisson’s ratio 泊松比pore water pressure 孔隙水压力geoiogical genetic地质成因cut slope路堑边坡trial pits 试验坑layered system层状体系e water table 地下水位ngingeering graduate 工科毕业生feasibility study 可行性研究construction phase施工阶段supervision管理，监控layout 布局、格式，平面图natural lighting 自然采光pretensioning (posttensioning)concrete先（后）张法service (live dead) load使用（活、静）荷载philosophy of structure design结构设计原理4．句子(1) 悬臂施工的优点是取消了脚手架the principal of advantage of theContilever tonstraction is the saving infalsework(2)在每个阶段,都要仔细计算和观测结构应力和徐变,以确保结构安全Structural stresses and deformationineach constration stage must beedudatee and inspection to ensure thesafety of the structure(3)目前,通常采用电子计算机进行应力松弛和混凝土徐变计算At ptessent ,computer usualy used forthe calouception of concrete creep andothers relasion(4)混凝土的长期收缩和徐变对预应力的损失产生很在的影响The effect of the shrinkage amd creepof concrete on the loss of prestress is alot(5)内力包括轴力,剪力,弯矩,扭矩等Intera forces consist of thrustshears ,bearing monmentand torque(6)不均匀沉降会导致结构产生更大的破坏Uneven settlement can causeprogressive structural damgage(7)土壤的物理性质与其本身的粒径有着密切的联系The physical properties of soils deeplyassociation with their particle size(8)在各种桥梁中悬索桥的跨度最大Among all bridges the span ofsuspension bridge is the biggest(9)需要强调数学力学，计算技术在土木工程应用中的重要性It is nessary to stress the important ofmathematics,mechanics,and computertechnique in the applcation of soilengineering(10)在许多情况下,可能会指派土木工程师参与其它工程项目的工作In other case ,civil engineers areassigned to work on a project in otherfields .(11)总工程师负责项目的构思与规划The general engineer is in charge of theplots and plans of the project(12)目前,正在试图生产出强度更高,耐久性更好且重量更轻的混凝土At pressent ,attempts are being made toproduce concrete with more strengh anddurability ,and with a lighter weight(13)桥梁上部结构由支座,支座面以上的构件组成The superstructures of a bridge consistsof bearing and elements alove them。

哲学专业的英文名词
1. Metaphysics（形上学）：研究存在、实体和本质的学科，探讨现实的本质和不可见的现象。

2. Epistemology（认识论）：研究知识的起源、性质、限度和验证方法的学问。

3. Ethics（伦理学）：研究道德原则和价值观的学科，探讨如何判断行为的对错以及如何做出道德决策。

4. Logic（逻辑学）：研究与推理和论证相关的规则和原则的学科，帮助我们理性思考和辨别谬误。

5. Aesthetics（美学）：研究艺术、美和审美经验的学问，探讨美的本质和艺术的功能。

6. Philosophy of Mind（心灵哲学）：研究意识、心灵和思维的学科，涉及到意识的起源、本质和关系。

7. Philosophy of Science（科学哲学）：研究科学方法和科学知识的起源和本质的学科。

8. Political Philosophy（政治哲学）：研究政治权力、公正和社会秩序的学问。

这些是哲学专业中的一些常见英文名词，涵盖了不同领域的研究。

对于想要深入了解哲学的人来说，理解这些名词是很重要的。

在学术研究和讨论中，使用正确的英文术语可以提高交流的准确性和清晰度。

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哲学 Philosophy马克思主义哲学 Philosophy ofMarxism中国哲学 Chinese Philosophy外国哲学 Foreign Philosophies逻辑学 Logic伦理学 Ethics美学 Aesthetics宗教学 Science of Religion科学技术哲学 Philosophy of Scienceand Technology经济学 Economics理论经济学 Theoretical Economics 政治经济学 Political Economy 经济思想史 History of Economic Thought 经济史 History of Economic 西方经济学 Western Economics 世界经济 World Economics人口、资源与环境经济学 Population, Resources and Environmental Economics 应用经济学 Applied Economics 国民经济学 National Economics 区域经济学 Regional Economics 财政学（含税收学） Public Finance (including Taxation)金融学（含保险学） Finance (including Insurance)产业经济学 Industrial Economics 国际贸易学 International Trade 劳动经济学 Labor Economics 统计学 Statistics 数量经济学 Quantitative Economics 中文学科、专业名称 英文学科、专业名称国防经济学 National DefenseEconomics法学 Law法学 Science of Law法学理论 Jurisprudence法律史 Legal History宪法学与行政法学 Constitutional Law and Administrative Law刑法学 Criminal Jurisprudence民商法学(含劳动法学、社会保障法学) Civil Law and Commercial Law (including Science of Labour Law and Science of Social Security Law )诉讼法学 Science of Procedure Laws 经济法学 Science of Economic Law 环境与资源保护法学 Science of Environment and Natural Resources Protection Law 国际法学(含国际公法学、国际私法学、国际经济法学、) International law(including International Public law, International Private Law and International Economic Law)军事法学 Science of Military Law 政治学 Political Science 政治学理论 Political Theory 中外政治制度 Chinese and Foreign Political Institution 科学社会主义与国际共产主义运动 Scientific Socialism and InternationalCommunist Movement中共党史(含党的学说与党的建设)History of the Communist Party ofChina (including the Doctrine of China Party and Party Building)马克思主义理论与思想政治教育 Education of Marxist Theory and Education in Ideology and Politics国际政治学 International Politics 国际关系学 International Relations 外交学 Diplomacy 社会学 Sociology 社会学 Sociology 人口学 Demography 人类学 Anthropology民俗学(含中国民间文学) Folklore (including Chinese Folk Literature)民族学 Ethnology 民族学 Ethnology 马克思主义民族理论与政策 Marxist Ethnic Theory and Policy 中国少数民族经济 Chinese Ethnic Economics中国少数民族史 Chinese Ethnic History中国少数民族艺术 Chinese 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Engineering油气井工程Oil-Gas Well Engineering油气田开发工程Oil-Gas FieldDevelopment Engineering油气储运工程Oil-Gas Storage andTransportation Engineering纺织科学与工程Textile Science andEngineering纺织工程Textile Engineering纺织材料与纺织品设计TextileMaterial and Textiles Design纺织化学与染整工程TextileChemistry and Dyeing and FinishingEngineering服装设计与工程Clothing Design andEngineering轻工技术与工程The Light IndustryTechnology and Engineering制浆造纸工程Pulp and PaperEngineering制糖工程Sugar Engineering发酵工程Fermentation Engineering皮革化学与工程Leather Chemistryand Engineering交通运输工程Communication andTransportation Engineering道路与铁道工程Highway andRailway Engineering交通信息工程及控制TrafficInformation Engineering & Control交通运输规划与管理TransportationPlanning and Management载运工具运用工程Vehicle OperationEngineering船舶与海洋工程Naval Architectureand Ocean Engineering船舶与海洋结构物设计制造Designand Construction of NavalArchitecture and Ocean Structure轮机工程Marine Engine Engineering水声工程Underwater AcousticsEngineering航空宇航科学与技术Aeronauticaland Astronautical Science andTechnology飞行器设计Flight Vehicle Design航空宇航推进理论与工程AerospacePropulsion Theory and Engineering航空宇航器制造工程ManufacturingEngineering of Aerospace Vehicle人机与环境工程Man-Machine andEnvironmental Engineering兵器科学与技术Armament Scienceand Technology武器系统与运用工程WeaponSystems and Utilization Engineering兵器发射理论与技术ArmamentLaunch Theory and Technology火炮、自动武器与弹药工程Artillery,Automatic Gun and AmmunitionEngineering军事化学与烟火技术MilitaryChemistry and Pyrotechnics核科学与技术Nuclear Science andTechnology核能科学与工程Nuclear EnergyScience and Engineering核燃料循环与材料Nuclear Fuel Cycle and Materials核技术及应用Nuclear Technology and Applications辐射防护及环境保护Radiation and Environmental Protection农业工程Agricultural Engineering农业机械化工程Agricultural Mechanization Engineering农业水土工程Agricultural Water-Soil Engineering农业生物环境与能源工程Agricultural Biological Environmental and Energy Engineering农业电气化与自动化Agricultural Electrification and Automation林业工程Forestry Engineering森林工程Forest Engineering木材科学与技术Wood Science and Technology林产化学加工工程Chemical Processing Engineering of Forest Products环境科学与工程Environmental 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中文1717字附录Philosophy of Structural DesignA structural engineering project can be divided into three phases: planning, design, and construction.Structural design involves determining the most suitable proportions of a structure and dimensioning the structural elements and details of which it is composed. This is the most highly technical and mathematical phase of a structural engineering project, but it cannot-and certainly should not-be conducted without being fully coordinated with the planning and construction phases of the project. The successful designer is at all times fully conscious of the various considerations that were involved in the preliminary planning for the structure and, likewise, of the various problems that may later be encountered in its construction.Specially, the structural design of any structure first involves the establishment of the loading and other design conditions that must be resisted by the structure and therefore must be considered in its design. Then comes the analysis (or computation ) of the internal gross forces (thrust, shears, bending moments, and twisting moments), stress intensities, strains, deflections, and reactions produced by the loads, temperature, shrinkage, creep, or other design conditions. Finally comes the proportioning and selection of materials of the members and connections so as to resist adequately the effects produced by the design conditions. The criteria used to judge whether particular proportions will result in the desired behavior reflect accumulated knowledge (theory, field and model tests, and practical experience), intuition, and judgment. For most common civil engineering structures such as bridges and buildings, the usual practice in the past has been to design on the basis of a comparison of allowable stress intensities with those produced by the service loadings and other design conditions. This traditional basis for design is called elastic design because the allowable stress intensities are chosen in accordance with the concept that the stress or strain corresponding to the yield point of the material should not be exceeded at the most highly stressed points of the structure. Of course, the selection of the allowable stresses may also be modified by a consideration of the permissible deflections of the structure.Depending on the type of structure and the conditions involved, the stress intensities computed in the analytical model of the actual structure for the assumed design conditions may or may not be in close agreement with the stress intensities produced in the actual structure by the actual conditions to which it is exposed. The degree of correspondence is not important, provided that the computed stress intensities can be interpreted in terms of previous experience. The selection of the service conditions and the allowable stress intensities provides a margin of safety against failure. The selection of the magnitude of this margin depends on the degree of uncertainty regarding loading, analysis, design, materials, and construction and onthe consequences of failure. For example, if an allowable tensile stress of 20000 psi is selected for structural steel with a yield stress of 33000 psi, the margin of safety (or factor of safety) provided against tensile yielding is 33000/20000, or 1.65.The allowable-stress approach has an important disadvantage in that it does not provide a uniform overload capacity for all parts and all types of structures. As a result, there is today a rapidly growing tendency to base the design on the ultimate strength and serviceability of the structure, with the older allowable-stress approach serving as an alternative basis for design. The newer approach currently goes under the name of strength design in reinforce-concrete design literature and plastic design in steel-design literature. When proportioning is done on the strength basis, the anticipated service loading is first multiplied by a suitable load factor (greater than 1), the magnitude of which depends upon the uncertainty of the loading, the possibility of its changing during the life of the structure, and, for a combination of loadings, the likelihood, frequency, and duration of the particular combination. In this approach for reinforced-concrete design, the theoretical capacity of a structural element is reduced by a capacity-reduction factor to provide for small adverse variations in material strengths, workmanship, and dimensions. The structure is then proportioned so that, depending on the governing conditions, the increased load would (1) cause a fatigue or a buckling or a brittle-fracture failure or (2) just produce yielding at one internal section (or simultaneous yielding at several sections) or (3) cause elastic-plastic displacement of the structure or (4) cause the entire structure to be on the point of collapse.Proponents of this latter approach argue that it results in a more realistic design with a more accurately provided margin of strength over the anticipated service conditions. These improvements result from the fact that nonelastic and nonlinear effects that become significant in the vicinity of ultimate behavior of the structure can be accounted for.In recent decades, there has been a growing concern among many prominent engineers that not only is the term “factor of safety”improper and unrealistic, but worse still a structural design philosophy based on this concept leads in most cases to an unduly conservative and therefore uneconomical design, and in some cases to an unconservative design with too high a probability of failure. They argue that there is no such thing as certainty, either of failure or of safety of a structure but only a probability of failure or a probability of safety. They feel, therefore, that the variations of the load effects and the variations of the structural resistance should be studied in a statistical manner and the probability of survival or the probability of serviceability of a structure estimated. It may not yet be practical to apply this approach to the design of each individual structure. However, it is believed to be practical to do so in framing design rules and regulations. It is highly desirable that building codes and specifications plainly state the factors and corresponding probabilities that they imply.If a good alignment requires a curved bridge-over a part or the total length thenall external longitudinal lines or edges of the structure should be parallel to the curved axis, thereby following again the guideline of good order.The transverse axis of piers or groups of columns should be rectangular (radial) to the curved axis, unless skew crossings over roads or rivers enforce other directions.The requirements of traffic design result occasionally in very acute angles or in level branching which cause difficulties for the bridge engineer to find pleasing solutions for the bridges.结构设计原理一个结构设计工程可以被分为三个阶段：计划、设计、施工。

Structural Analysis and Design Structural analysis and design play a crucial role in the construction and engineering industry. It involves the study of the behavior and performance of structures, ensuring their safety, reliability, and sustainability. This field encompasses a wide range of elements, including materials, loads, forces, and environmental considerations. In this discussion, we will delve into the significance of structural analysis and design from various perspectives,exploring its technical, practical, and ethical dimensions. From a technical standpoint, structural analysis and design involve the application of engineering principles to create safe and efficient structures. Engineers use sophisticated software and mathematical models to simulate the behavior of different materials and structural components under various conditions. By analyzing these simulations, they can optimize the design to ensure that the structure can withstand the expected loads and environmental factors. This process is essential for preventing structural failures, which can have catastrophic consequences in terms of human safety and economic losses. Moreover, structural analysis and design also play a pivotal role in ensuring the sustainability and environmental impact of structures. With growing concerns about climate change and resource depletion, engineers are increasingly focusing on creating eco-friendly and energy-efficient designs. This involves using sustainable materials, optimizing the use of resources, and minimizing the carbon footprint of structures. By integrating these considerations into the design process, engineers can contribute to a more sustainable built environment, aligning with global efforts to combat climate change. Beyond the technical aspects, the practical implications of structural analysis and designare equally significant. Well-designed structures not only ensure safety but also contribute to the overall functionality and aesthetics of the built environment. Whether it's a bridge, a skyscraper, or a residential building, the design of structures has a profound impact on the lives of people. Aesthetically pleasingand well-designed structures can enhance the quality of urban landscapes, instilla sense of pride in communities, and contribute to the overall well-being of society. Furthermore, ethical considerations are paramount in structural analysis and design. Engineers have a responsibility to uphold ethical standards andprioritize the safety and welfare of the public. This involves adhering tobuilding codes and regulations, conducting thorough risk assessments, and being transparent about the limitations of a design. Additionally, ethical engineering practices also encompass considerations for social equity and accessibility. Engineers should strive to create inclusive designs that accommodate the needs of all individuals, including those with disabilities, and contribute to the overall welfare of society. In conclusion, structural analysis and design are integral components of the construction and engineering industry, with far-reaching implications for safety, sustainability, functionality, and ethical responsibility. By approaching this field from a multidimensional perspective, we can appreciateits profound impact on the built environment and society as a whole. As wecontinue to advance technologically and face evolving challenges, the role of structural analysis and design will remain pivotal in shaping a safer, more sustainable, and ethically responsible built environment.。

设计理念的英文名称是Title: Form Follows Function: The Essence of Design Philosophy。

Design philosophy is the foundation of any creative process, guiding the way we conceptualize, develop, and execute our ideas. One of the most fundamental principles in design philosophy is the concept of "form follows function," which emphasizes the importance of functionality and purpose in shaping the form of an object or a space.This design principle, often attributed to American architect Louis Sullivan, highlights the idea that the form of a design should be directly influenced by its intended function. In other words, the aesthetic and structural elements of a design should be a direct result of its intended use, rather than being purely ornamental or arbitrary.The essence of the "form follows function" philosophy lies in the belief that good design should prioritize utility and practicality, ensuring that the end product serves its intended purpose effectively. This principle is especially relevant in fields such as architecture, industrial design, and graphic design, where the functionality of a product or space is paramount.In architecture, for example, the design of a building should be informed by its intended use and the needs of its occupants. A well-designed space should not only be visually appealing but also provide comfort, accessibility, and efficiency. Similarly, in industrial design, the form of a product should be driven by its function, ensuring that it is ergonomic, user-friendly, and fit for its intended purpose.The "form follows function" philosophy also extends to graphic design, where the visual elements of a design should be tailored to effectively communicate its message or function. Whether it's a logo, a website, or a printed advertisement, the design should be intuitive and purposeful, guiding the viewer's attention and conveying information clearly and efficiently.Ultimately, the "form follows function" design philosophy reminds us that good design is not just about aesthetics, but about creating solutions that are practical, efficient,and meaningful. By prioritizing function over form, designers can create products and spaces that not only look good but also work well, enhancing the lives of those who interact with them. In this way, the essence of design philosophy is not just about creating beautiful objects, but about making a positive impact on the world around us.。

常见的建筑术语的英文翻译集之一以下是一些常见的建筑术语的英文翻译集合之一：1. 建筑设计- Architectural Design2. 建筑结构- Building Structure3. 建筑材料- Building Materials4. 建筑施工- Building Construction5. 建筑成本- Construction Cost6. 建筑风格- Architectural Style7. 建筑师- Architect8. 建筑规划- Building Planning9. 建筑模型- Architectural Model10. 建筑面积- Building Area11. 建筑高度- Building Height12. 建筑容积率- Plot Ratio13. 建筑法规- Building Codes and Regulations14. 建筑节能- Energy Efficiency in Buildings15. 建筑智能化- Intelligent Buildings16. 绿色建筑- Green Buildings17. 可持续建筑- Sustainable Buildings18. 建筑声学- Architectural Acoustics19. 建筑光学- Architectural Optics20. 室内设计- Interior Design21. 景观设计- Landscape Design22. 结构设计- Structural Design23. 给排水设计- Water Supply and Drainage Design24. 暖通空调设计- HVAC Design25. 电气设计- Electrical Design26. 消防设计- Fire Protection Design27. 智能化系统设计- Intelligent System Design28. 施工组织设计- Construction Organization Design29. 施工图设计- Construction Drawing Design30. 装饰装修设计- Decoration and Finishing Design31. 建筑声学设计- Architectural Acoustics Design32. 建筑光学设计- Architectural Optics Design33. 建筑热工设计- Architectural Thermal Design34. 建筑美学设计- Architectural Aesthetic Design35. 建筑环境设计- Architectural Environment Design36. 建筑风水学- Feng Shui37. 建筑日照分析- Solar Analysis for Buildings38. 建筑通风分析- Ventilation Analysis for Buildings39. 建筑声环境分析- Acoustic Environment Analysis for Buildings40. 建筑光环境分析- Daylighting Environment Analysis for Buildings41. 建筑热环境分析- Thermal Environment Analysis for Buildings42. 建筑面积计算- Building Area Calculation43. 建筑楼层高度- Storey Height44. 建筑消防设计- Fire Protection Design for Buildings45. 建筑结构安全评估- Structural Safety Evaluation for Buildings46. 建筑抗震设计- Seismic Design for Buildings47. 建筑防洪设计- Flood-resistant Design for Buildings48. 建筑工程招标- Building Engineering Tendering49. 建筑工程施工许可- Construction Permission for Building Projects50. 建筑工程造价咨询- Engineering Cost Consulting for Building Projects51. 建筑工程监理- Project Supervision for Building Projects52. 建筑工程验收- Acceptance of Building Projects53. 建筑工程质量检测- Quality Detection of Building Projects54. 建筑工程质量评估- Quality Evaluation of Building Projects55. 建筑工程质量保修- Quality Guarantee of Building Projects56. 建筑工程档案- Construction Project Archives57. 建筑工程安全- Construction Safety58. 建筑工程管理- Construction Project Management59. 建筑工程合同- Construction Contract60. 建筑工程保险- Construction Insurance61. 建筑工程材料- Construction Materials62. 建筑工程机械- Construction Machinery63. 建筑工程劳务- Construction Labor64. 建筑工程施工组织设计- Construction Organization Design for Building Projects65. 建筑工程施工图设计- Construction Drawing Design for Building Projects66. 建筑工程施工进度计划- Construction Progress Plan for Building Projects67. 建筑工程施工质量控制- Construction Quality Control for Building Projects68. 建筑工程施工安全管理- Construction Safety Management for Building Projects69. 建筑工程施工现场管理- Construction Site Management for Building Projects70. 建筑工程施工成本管理- Construction Cost Management for Building Projects71. 建筑工程施工环境保护- Environmental Protection in Building Construction72. 建筑工程施工节能管理- Energy-saving Management in Building Construction73. 建筑工程施工水土保持- Soil and Water Conservation in Building Construction74. 建筑工程施工质量控制要点- Key Points of Construction Quality Control for Building Projects75. 建筑工程施工安全控制要点- Key Points of Construction Safety Control for Building Projects76. 建筑工程施工质量验收规范- Acceptance Specification for Construction Quality ofBuilding Projects77. 建筑立面设计- Façade Design78. 建筑剖面设计- Section Design79. 建筑立面分析图- Façade Analysis Diagram80. 建筑剖面分析图- Section Analysis Diagram81. 建筑结构分析图- Structural Analysis Diagram82. 建筑平面图- Floor Plan83. 建筑立面图- Façade Drawing84. 建筑剖面图- Section Drawing85. 建筑轴测图- Axonometric Drawing86. 建筑渲染图- Architectural Rendering87. 建筑模型制作- Model Making88. 建筑绘画- Architectural Drawing89. 建筑表现图- Architectural Representation90. 建筑动画- Architectural Animation91. 建筑摄影- Architectural Photography92. 建筑信息模型- Building Information Modeling (BIM)93. 建筑环境评估- Building Environmental Assessment94. 建筑节能评估- Building Energy Efficiency Assessment95. 建筑可持续性评估- Building Sustainability Assessment96. 建筑健康评估- Building Health Assessment97. 建筑设备系统设计- Building Equipment System Design98. 建筑电气系统设计- Electrical System Design for Buildings99. 建筑给排水系统设计- Water Supply and Drainage System Design for Buildings 100. 建筑暖通空调系统设计- HVAC System Design for Buildings一般建筑术语英文翻译之二101. 建筑燃气系统设计- Gas System Design for Buildings102. 建筑消防报警系统设计- Fire Alarm System Design for Buildings103. 建筑智能化系统集成设计- Intelligent System Integration Design for Buildings 104. 建筑幕墙设计- Curtain Wall Design105. 建筑石材幕墙设计- Stone Curtain Wall Design106. 建筑玻璃幕墙设计- Glass Curtain Wall Design107. 建筑绿化设计- Greening Design for Buildings108. 建筑景观设计- Landscape Design for Buildings109. 建筑室内环境设计- Indoor Environmental Design for Buildings110. 建筑声学装修设计- Acoustic Decoration Design for Buildings111. 建筑光学装修设计- Optical Decoration Design for Buildings112. 建筑材料装修设计- Decorative Materials Design for Buildings113. 建筑历史与理论- Architectural History and Theory114. 建筑美学史- History of Architectural Aesthetics115. 现代建筑设计- Modern Architectural Design116. 后现代建筑设计- Postmodern Architectural Design117. 当代建筑设计- Contemporary Architectural Design118. 解构主义建筑设计- Deconstructivist Architectural Design119. 装饰艺术建筑设计- Art Deco Architectural Design120. 功能主义建筑设计- Functionalist Architectural Design121. 结构主义建筑设计- Structuralist Architectural Design122. 新古典主义建筑设计- Neoclassical Architectural Design123. 折衷主义建筑设计- Eclectic Architectural Design124. 绿色建筑设计- Green Architectural Design125. 人文主义建筑设计- Humanist Architectural Design126. 新地域主义建筑设计- New Regionalist Architectural Design127. 参数化建筑设计- Parametric Architectural Design128. 数字建筑设计- Digital Architectural Design129. 未来主义建筑设计- Futurist Architectural Design130. 智能化建筑设计- Intelligent Building Design131. 生态建筑设计- Ecological Architectural Design132. 城市设计- Urban Design133. 景观设计- Landscape Design134. 城市规划- Urban Planning135. 城市更新- Urban Renewal136. 城市改造- Urban Transformation137. 城市意象- Urban Image138. 城市设计理论- Urban Design Theory139. 城市生态设计- Urban Ecological Design140. 城市交通设计- Urban Transportation Design141. 城市基础设施设计- Urban Infrastructure Design142. 城市天际线设计- Urban Skyline Design143. 城市夜景设计- Urban Nightscape Design144. 城市滨水区设计- Urban Waterfront Design145. 城市开放空间设计- Urban Open Space Design146. 城市街道景观设计- Urban Streetscape Design147. 城市公园设计- Urban Park Design148. 城市居住区设计- Urban Residential District Design149. 城市商业区设计- Urban Commercial District Design150. 城市文化区设计- Urban Cultural District Design151. 城市行政中心设计- Urban Governmental District Design152. 城市会展中心设计- Urban Exhibition and Convention Center Design 153. 城市体育馆设计- Urban Stadium Design154. 城市图书馆设计- Urban Library Design155. 城市博物馆设计- Urban Museum Design156. 城市大剧院设计- Urban Theater Design157. 城市机场设计- Urban Airport Design158. 城市火车站设计- Urban Train Station Design159. 城市地铁站设计- Urban Subway Station Design160. 城市公交车站设计- Urban Bus Stop Design161. 城市景观照明设计- Urban Landscape Lighting Design162. 城市标识系统设计- Urban Signage System Design163. 城市公共艺术装置设计- Public Art Installation Design164. 城市家具设计- Urban Furniture Design165. 城市花坛设计- Urban Flower Bed Design166. 城市儿童游乐设施设计- Urban Playground Design167. 城市植栽设计- Urban Planting Design168. 城市排水系统设计- Urban Drainage System Design169. 城市防洪系统设计- Urban Flood Control System Design170. 城市消防系统设计- Urban Fire Protection System Design171. 城市应急救援系统设计- Urban Emergency Rescue System Design172. 城市废弃物处理系统设计- Urban Waste Management System Design 173. 城市给水系统设计- Urban Water Supply System Design174. 城市污水处理系统设计- Urban Wastewater Treatment System Design 175. 城市雨水排放系统设计- Urban Stormwater Management System Design 176. 城市空调系统设计- Urban Air Conditioning System Design177. 城市供暖系统设计- Urban Heating System Design178. 城市燃气供应系统设计- Urban Gas Supply System Design179. 城市电力供应系统设计- Urban Electrical Power Supply System Design180. 城市智能化管理系统设计- Urban Intelligent Management System Design 181. 城市绿色建筑认证体系- Green Building Certification Systems182. 城市绿色建筑评价体系- Green Building Evaluation Systems183. 可持续城市发展理论- Sustainable Urban Development Theory 184. 生态城市理论- Eco-city Theory185. 低碳城市理论- Low-carbon City Theory186. 紧凑城市理论- Compact City Theory187. 智慧城市理论- Smart City Theory188. 韧性城市理论- Resilient City Theory189. 多规合一城市规划体系- Integrated Urban Planning System 190. 城市设计哲学- Urban Design Philosophy191. 城市设计心理学- Urban Design Psychology192. 城市设计社会学- Urban Design Sociology193. 城市设计地理学- Urban Design Geography194. 城市设计经济学- Urban Design Economics195. 城市设计生态学- Urban Design Ecology196. 城市设计符号学- Urban Design Semiotics197. 城市设计现象学- Urban Design Phenomenology198. 城市设计未来学- Urban Design Futures Studies199. 城市设计艺术史- Urban Design Art History200. 城市设计与公共政策- Urban Design and Public Policy。

建筑英语翻译篇一：建筑类英文及翻译外文原文出处：Geotechnical, Geological, and Earthquake Engineering, 1, Volume 10, Seismic Risk Assessment and Retrofitting, Pages 329-342补充垂直支撑对建筑物抗震加固摘要：大量的钢筋混凝土建筑物在整个世界地震活跃地区有共同的缺陷。

弱柱，在一个或多个事故中，由于横向变形而失去垂直承载力。

这篇文章提出一个策略关于补充安装垂直支撑来防止房子的倒塌。

这个策略是使用在一个风险的角度上来研究最近实际可行的性能。

混凝土柱、动力失稳的影响、多样循环冗余的影响降低了建筑系统和组件的强度。

比如用建筑物来说明这个策略的可行性。

1、背景的介绍：建筑受地震震动，有可能达到一定程度上的动力失稳，因为从理论上说侧面上有无限的位移。

许多建筑物，然而，在较低的震动强度下就失去竖向荷载的支撑，这就是横向力不稳定的原因(见图16.1)。

提出了这策略的目的是为了确定建筑物很可能马上在竖向荷载作用下而倒塌，通过补充一些垂直支撑来提高建筑物的安全。

维护竖向荷载支撑的能力，来改变水平力稳定临界失稳的机理，重视可能出现微小的侧向位移(见图16.2)。

在过去的经验表明，世界各地的地震最容易受到破坏的是一些无筋的混凝土框架结构建筑物。

这经常是由于一些无关紧要的漏洞，引起的全部或一大块地方发生破坏，比如整根梁、柱子和板。

去填实上表面来抑制框架的内力，易受影响的底层去吸收大部分的内力和冲力。

这有几种过去被用过的方法可供选择来实施:1、加密上层结构，可以拆卸和更换一些硬度不够强的材料。

2、加密上层结构，可以隔离一些安装接头上的裂缝，从而阻止对框架结构的影响。

3、底楼，或者地板，可以增加结构新墙。

这些措施(项目1、2和3)能有效降低自重，这韧性能满足于一层或多层。

然而，所有这些都有困难和干扰。

在美国，这些不寻常的代价换来的是超过一半更有价值的建筑。

这段英文语速清晰自然地道The workflow of the electronic packaging department mainly involves design, production planning, material processing and manufacturing, quality inspection, as well as organizing, sorting, and storage.The responsibilities of the electronic packaging department are to ensure the safe transportation of products and their intact appearance, which requires staff to be attentive and patient. During the packaging process, each product must be carefully inspected to ensure its proper functioning, and the staff needs to proficiently handle various packaging materials and tools to guarantee the stability and safety of the packaging. Maintaining good communication and collaboration with other departments is also crucial to ensure timely delivery of products and the smooth operation of the warehouse.Specifically, the work content of the electronic packaging department mainly includes market research, overall planning and positioning, packaging design innovation, selection and design of packaging materials, shape and structural design, visual communication design, additional item design, and application of protective technology.1.Market Research: Understand the current market situation and development trends to provide objective and accurate references for corporate decision-makers.2.Overall Planning and Positioning: Determine the general direction of packaging and production processes.3.Packaging Design Innovation: Carry out innovative positioning and conception to meet market demands.4.Selection and Design of Packaging Materials: Choose appropriate pressure-resistant, shockproof, waterproof, and anti-static materials based on the characteristics of electronic products.5.Shape and Structural Design: Design packaging shapes and structures that fit the product features and brand philosophy.6.Visual Communication Design: Create a visual effect for the packaging that attracts consumers.7.Additional Item Design: Such as manuals, warranty cards, etc., inside the packaging.8.Application of Protective Technology: Ensure the safety of products during transportation and storage.In summary, the work of the electronic packaging department focuses not only on the functionality of thepackaging, such as protecting the product from damage, but also emphasizes the aesthetic appeal and market attractiveness of the packaging. A successful packaging design should adhere to the brand philosophy, highlight product features, and stimulate consumers' desire to purchase.。

外文翻译--组合作用的基础及抗剪连接毕业设计（论文）外文参考资料及译文译文题目：学生姓名：学号：专业：所在学院：指导教师：职称：年月日Fundamentals of Composite Action and Shear ConnectionThe evolution of satisfactory design methods for composite beams has been a slow process, requiring much theoretical and experimental work in order' to provide economic and, at the same time, safe design criteria. The purpose of this Chapter is to describe in some detail the more important fundamentals which have to be taken into account in the design of composite structures.Historically the first analysis of a composite section was based on the conventional assumptions of the elastic theory which limit the stresses in the component 'materials to a certain proportion of their 'failure stresses (yield in the case of steel, crushing in the case of concrete). The assumptions inherent in the elastic method are similar to those for ordinary reinforced concrete. In recent' years the concepts of the ultimate load design philosophy have been applied to composite action and a body of experimental evidence has shown it to be a safe, economical basis on which to proportion composite sections. Although at the present time ultimate load design methods are directly applicable only to buildings and not to bridges there seems no reason to doubt that in time the restriction will disappear.Before dealing in detail with the two design approaches (elastic and ultimate load) basic points require consideration.A clear understanding of the way in which the component materials, steel concrete and shear connection react to applied load is an essential preliminary to full analysis of the composite section. Of primary importance are the stress strains relationships, which must of necessity be the product of carefully controlled experiment. These experimental results are not generally suited to direct application and so simplifications and idealisations are adopted in practice. The use of computers has made it possible to reduce the amount of idealisation required with the result that computer `experiments' can now be performed using material stress-strain relationships of considerable complexity.Composite action between steel and concrete implies some interconnectionbetween the two materials which will transfer shear between them. In reinforced concrete members the natural bond of concrete to steel is often sufficient to do this, although cases do arise in which additional anchorage is required. The fully encased filler joist also has a large embedded area which is adequate for full shear transfer. However, the situation is quite different with the common type of composite beam in which the concrete slab rests on, or at best encloses, the top flange of the steel beam. It is true that there will initially be shear transfer by bond and friction at the beam-slab contact surface. There is ,however, a tendency for the slab to separate vertically from the beam and, should this occur, horizontal shear transfer will cease. m A single overload or the fatigue effect of pulsating loading may destroy the natural bond, which once destroyed cannot be reconstituted. The imponderable nature of such shear connection is clearly undesirable; some form of deliberate connection between beam and slab is required with the two objects of transferring horizontal shear and preventing vertical separation. A, natural bond will exist in the presence of shear connection but it is neither desirable to count on its existence nor possible in all cases to calculate its value. Thus shear connection must be provided to transfer all the horizontal shear force.It has. been pointed out that the paradoxical situation exists that if shear connection is provided it may in fact not come into operation because the natural bond takes all the is provided it may in fact not come into operation because the natural bond takes all the shear force, and so `if sufficient shear connectors are provided then they are unnecessary'.The evolution of shear connection devices has been slow and has necessitated a large volume of experimental work on the static and fatigue properties of a wide range of mainly mechanical connectors.It soon appeared clear to early research workers that some form of connector fixed to the top flange of the beam and anchored into the slab was necessary. Caughey and Scott in 1929 proposed using, amongst other things, projecting bolt ends. Since then a wide variety of types of mechanical connectorhas been used in experiment and practice. To some extent the proliferation of types has been .the result of steel fabricators using sections which came easily to hand, since initially a purpose-made shear connector was not available.In any mechanical connection system it is possible to identify parts which transfer horizontal shear and parts which tie the slab down to the beam. Generally, horizontal shear resistance is the ruling criterion of shear connector action and with this in mind mechanical connectors may be classified into three main groups-rigid, flexible and bond.Limit State Design of BrickworkThe basic aim of structural design is to ensure that a structure should fulfill its intended function throughout its lifetime without excessive deflection, cracking or collapse, and this aim must of course be met with due regard to econom y.The designer is assisted in his task by the availability of a code of practice which is based on accumulated experience and research. Up to the present time, such codes have sought to ensure the safety and serviceability of masonry structures by specifying permissible stresses for various types and combinations of materials. Thus codes generally give basic compressive stresses for a range of brick-mortar combinations; the basic stress in a particular case has then to be adjusted for the slenderness ratio of the element and the eccentricity of the loading. The basic stresses are derived from tests on walls or piers , the ultimate stresses having been divided by an arbitrary factor of safety sufficiently large to avoid cracking at working load s. Thus, to this extent, brickwork design has always been related to ultimate strength and to a serviceability limit state.In recent years a more rational procedure has been evolved for dealing with structural safety and serviceability through consideration of the relevant "limit states“ . A structure, or part of a structure, reaches a limit state when it becomes incapable of fulfilling its function or when it no longer satisfies the conditions forwhich it was designed. Two categories of limit state normally have to be considered, namely , ultimate limit states corresponding to failure or collapse and serviceability limit states at which deflections or cracking become excessive. The general method of applying the limit states approach to the design of structures is outlined in a publication of the International Organization for Standardization in which the criterion for a satisfactory design is expressed in terms of design loading effects (S * )and design strengths (R * )as follows **S R ≥ (1) Design loading effects are determined from the characteristic actions from the relationshipS * = effects of (k f Q γ） (2) w here γf is a multiplier (or partial safety factor) and k Q is a characteristic load which, if defined in statistical terms , is given by）（δk 1m k +=Q Q where m Q is the value of the most unfavourable load with a 50 per cent probability of its being exceeded once in the expected life of the structure δ is the standard deviation of the distribution of the .maximum loading k is a coefficient depefldin8 on a selected probability of maximum loadings being greater than k Q It is usual to take the characteristic load as that which will have a 5 per cent probability of being exceeded during the lifetime of the structure.④In many situations, however,statistical data are not available and the characteristic loads have to be based on nominal values given in codes of practice or other regulations.The fac torγf is a function of severalpartial coefficients.1f γ which takes account of the possibility of unfavourable deviation of the loads from the characteristic external loads ,thus allowing for abnormal or unforeseen actions2f γ which takes account of the reduced probability that various loads acting together will a11 be simultaneously at their characteristic values. 3f γ which is intended to allow for possible modification of the load effects due to incorrect design assumptions (for example, introduction of simplified support conditions, hinges, neglect of thermal and other effects which are difficult to assess) and constructional discrepancies such as dimensions of cross-section, deviation of columns from the vertical and accidental eccentricities.Similarly , design strengths of materials, R* , are defined byR * ﹦m kR γwhere k R -- R m -ks is the characteristic strength of the materialR m is the arithmetic mean of test resultss is the standard deviationk is a coefficient depending on the probability of obtaining results less than k RThe characteristic strength of a material is usually taken as the 95 per cent confidence limit of the material strength in a relevant test series. The reduction coefficient γm isa function of two coefficients1m γ which is intended to cover possible reductions in the strength of the materials in the structure as whole as compared to the characteristic value deduced from the control test specimen2m γ which is intended to cover possible weakness of the structure arising from any cause other than the reduction in the strength of the materials allowed for by coefficient γm1, including manufacturing tolerances.Additionally , ISO 2394 allows for the introduction of a further coefficientγwhich may be applied either to the design values of loadings or material cstrengths. This coefficient is in turn a function of two partial coefficientsγwhich is intended to take account of the nature of the structure and its 1cbehaviour , for example, structures or parts of structures in which partial or complete collapse can occur without warning, where redistribution of internal forces is not possible, or where failure of a single element can lead to overall collapseγwhich is intended to take account of the seriousness of attaining a limit 2cstate from other points of view, for example economic consequences,danger to the community , etc.Usually γc is incorporated into either γf or γm and therefore does not appear explicitly In design calculations.The advantage of the limit state approach is that permits a more rational and flexible assessment of structural safety and serviceability; the various relevant factors are identified and up to a point can be expressed in numerical terms. ⑤Ideally ，loading and strengths should be available in statistical terms but this is seldom possible ，so that characteristic values have to be determined on the basis of available evidence .In the case of loads ，the evidence generally results from surveys of buildings in service .Characteristic strengths of materials ，on the other hand，are derived from laboratory tests，the results of which can sometimes provide a statistical basis for characteristic strength .In the absence of such statistical data ，characteristic strengths have to be based on nominal values proved by experience .组合作用的基础及抗剪连接寻求组合梁的满意设计方法是一个缓慢的过程。

第一部分自学指导第1章：土木工程的基本知识一．主要内容1．土木工程中的职业2．现代建筑和结构材料3．公路测量4．预应力混凝土5. 结构设计原理6. 土木工程合同二．重点1．土木工程中的职业（Careers in Civil Engineering）2．现代建筑和结构材料(Modern Buildings and Structural Materials) 3．公路测量(Highway Survey)4．预应力混凝土(Prestressed Concrete)5. 结构设计原理（Philosophy of Structural Design）6. 土木工程合同(Civil Engineering Contracts)三．难点1．课文翻译。

2．单词记忆。

第2章：公路与交通工程一．主要内容1．交通运输系统2．公路定线3．线形设计4．立交与互通式立交5. 路面6. 沥青面层7. 公路排水8. 高速公路9. 公路施工二．重点1．交通运输系统(Transportation System)2．公路定线(Highway Location)3．线形设计(Design of the Alignment)4．立交与互通式立交(Grade separations and Interchanges)5. 路面(Pavement)6. 沥青面层(Bituminous Surface Courses)7. 公路排水(Highway Drainage)8. 高速公路（Freeways）9. 公路施工(Highway Construction)三．难点1．课文翻译。

2．单词记忆。

第二部分复习思考题一．单选题：1. Computers are ________ unless they are given clear and accurate instructions and information.A. usedB. uselessC. usefulD. uselessly2. Active ____ __ for engineers often begins before the student’s last year in the university.A. employB. recruitingC. hireD. firing3. For the student who is preparing to become a ________ engineer, these specialized courses maydeal with such subjects as geodetic surveying, soil mechanics.A. computerB. socialC. civilD. chemical4. The civil engineer may work in research, design, construction, ________, maintenance, oreven in sales.A. analysisB. supervisionC. planD. fee5. Civil engineers work on many different kinds of .A. buildingsB. projectsC. structuresD. roads6. In designing buildings, civil engineers often work as ________ to architectural or constructionfirms.A. workersB. consultantsC. employeesD. students7. Dams, bridges and other large projects ordinarily employ several engineers whose work iscoordinated by a ________ engineer who is in charge of the entire project.A. mainB. chiefC. masterD. systems8. Construction is a ________ process on almost all engineering projects.A. simpleB. complicatedC. easyD. likely9. In compression, the material is ________ together.A. stretchedB. apartC. pushedD. tense10. When a saw cuts easily through a piece of wood, the wood is .A. in tensionB. in compressionC. in pressD. in push11. We defined ________ as the tendency of a material to fracture along the lines of stress.A. tensionB. compressionC. pushD. shear12. The principal construction materials of earlier times were wood and ________,stone, or tile, and similar materials.A. steelB. aluminumC. masonry brickD. plastic13. Modern cement is a mixture of .A. bricksB. limestone and clayC. wood and ashD. plastic14. Concrete is very .A. constantB. the sameC. definiteD. versatile15. Steel has great tensile strength while concrete has great compressive strength, thus, the twosubstances ________ each other.A. counteractB. offsetC. complementD. nullify16. One system that helps ________ concrete weight to some extent uses polymers.A. cutB. accelerateC. addD. keep17. The retention money serves to insure ________ against any defects that may arise in thework.A. the managerB. the contractorC. the carrierD. the employer18. The civil engineering work must be completed to the satisfaction of the employer, or his .A. wifeB. friendC. lawyerD. representative19. For moderate and longer hauls, self-loading scrapers pulled by rubber-tired hauling units andpush-loaded by tractors offer ________ cost.A. higherB. lowerC. the sameD. different20. Highway maintenance activities can be grouped and classified according ________thepurpose of the treatment.A. withB. forC. forwardD. to21. Engineering is a profession, which means that an engineer must have a specialized______ education.A. elementary school B．high school C．middle school D．university22. In most cases, the tender may be ______ at any time until it has been accepted. A．confirmed B．withdrawn C．admitted D. continued23. Current trend is to require students to take courses in the ______ science and the languagearts.A．computer B．chemical C．social D．biology24. The law relating to contracts imposes on each party to a contract ______ to perform.A. an irksome taskB. an easy experimentC. a good planD. a legal obligation25. Indeed, the civil engineer’s choice is ______ and varied.A. smallB. fineC. largeD. tiny26. Roadbeds ______ highway pavement structures and the ballast and track on which trainsmove.A. lie aboveB. underlieC. lie leftD. lie right27. Construction can be very .A. dangerousB. safeC. easyD. secure28. Where material is moved less than about 60m or steeply downhill, drifting with a track orwheel type bulldozer is .A. cheapestB. expensiveC. unknownD. the same29. Thrust is the pressure exerted by each part of a structure on .A. its other partB. itselfC. the wallD. the ground30. The weight of all the people, cars, furniture, and machines and so on that the structure will support when it is in use is .A. dead loadB. live loadC. impactD. safety factor31. In tension, the material is .A. pressedB. pulled apartC. pushedD. compressed32. In fills constructed by end dumping or by placing in thick layers, material, density, andmoisture content could ______ greatly from one spot to another.A. be the sameB. be alikeC. varyD. be equal33. Both ______, the two most important construction materials of modern times, wereintroduced in the nineteenth century.A. steel and cementB. wood and brickC. stone and tileD. ash and plastic34. The total station is used to measure angles in both vertical and horizontal planes, and the level to measure .A. distancesB. central anglesC. elevation differenceD. length35. The ______ vehicle is a creator of accidents.A. advantageB. defectiveC. meritD. failure36. Prestressed concrete is an ______ form of reinforcement.A. originalB. improvedC. sameD. low37.A simple contract consists of an agreement entered into by .A. engineersB. one partyC. companyD. two or more parties38.______ change would result in differential settlement or swell between adjacent areas.A. WeightB. V olumeC. AreaD. No39. There are two basic procedures for controlling the embankment density: ‘manner andmethod’ and ‘’.A. resultB. combinationC. layer thicknessD. moisture control40.A main source of accidents, the problem of ______ driving is the most serious of all.A. drinkB. drinkingC. drunkenD. drank41. Computer programming is now included in almost all engineering ______.A. coursesB. curriculaC. lessonsD. areas42. The relationship between engineering and society is getting ________.A. higherB. fartherC. closerD. lower43. Types of contracts are virtually classified by their ______ system: (1) price-based and (2)cost-based.A. constructionB. designC. tenderD. payment44. Computers can’t solve complicated problems unless they are given ______.A. a good air-conditionB. a young civil engineerC. a good computer engineerD. a good program45. In recent years, rippers have been used successfully to ______ loose or fractured rock.A. break downB. break evenC. break upD. break away46. Civil engineering projects are almost always ______.A. distinctiveB. the similarC. alikeD. the same47. Usually there are ______ easy answers on equipment selection.A. someB. manyC. noD. much48. ______ force acts up and down.A. VerticalB. HorizontalC. Rotating motionD. Turning motion49. Layered construction also produced greater uniformity in the material ______ and in its density and moisture content.A. himselfB. myselfC. themselvesD. itself50. The actual cost of any single highway traffic accident is extremely ______ to determine.A. easyB. liableC. difficultD. apt51. Basically, causes of automobile accidents can be categorized ______ four major groups.A. inB. toC. onD. into52. Electronic distance measuring (EDM) not only can measure the distance between objects but also determine .A. the directionB. the sizeC. the frequencyD. the width53.______ the recent improvement in visibility are wraparound windshields and narrowed roof support pillars.A. Two ofB. Of twoC. TwoD. Two, of54. There is a great deal that the actual highway designer can ______ prevent accident.A. doB. to doC. do toD. to55. To avoid the driving after drinking, one of the methods is .A. law studyB. breath testC. take an examD. driving study56. It is suitable for remote sensing technique to be used for highway location in .A. tropical rain forestB. areas between tall buildingsC. mountainous country without forestD. plains with uniform shade57. The information on the aerial photographs can be converted into maps with the help of stereoscopes which is able to see objects in .A. one dimensionB. two dimensionsC. three dimensionsD. all directions58. The normal steel does not exert any force of its own on the member, ______ to the action of prestressing steel.A. similarB. contraryC. comparableD. likely59. The extensive use of prestressed structures has been due in ______ small measures to the advances in the technology.A. noB. soC. suchD. some60.The employer selects the contractor for the project by .A. tenderB. advertisementC. governmentD. bidding61. Many different and government agencies have competed for the services of engineers in recent years.A. corporationsB. institutesC. unitsD. offices62. Civil engineers may prefer to work with one of the government agencies that with water resources.A. doesB. dealsC. livesD. argues63. It is normal practice for engineer to specialize in just one kind.A. oneB. aC. anD. the64. Construction involves the work and utilizing the equipment and the materials so that costs arekept as as possible.A. highB. preciousC. lowD. expensive65. For example, are often built in wild river valleys or gorges.A. buildingsB. damsC. bridgesD. tunnels66. Electrical and mechanical engineers work on the of the powerhouse and its equipment.A. designB. buildingC. structureD. power67. In Rome, most of the people lived in , great tenement blocks that were often ten storieshigh.A. outdoorB. insulseC. the seaD. the ground68. The prospective civil engineer should be aware of the physical that will be made on him orher.A. conditionsB. testC. courseD. demands69. Much of the work of civil engineering is carried on .A. indoorsB. in the skyC. outdoorsD. underground70. In addition, the building of skyscrapers, bridges and tunnels must also progress under all kinds of conditions.A. designB. economicC. weatherD. water71. The Romans also used a natural cement called pozzolana, made from , that became as hardas stone under water.A. steelB. volcanic ashC. aluminumD. plastic72. Different proportions of the ingredients produce concrete with strength and weight.A. differentB. the sameC. similarD. unknown73. concrete has made it possible to develop buildings with unusual shapes.A. PrestressedB. ReinforcementC. MixtureD. Steel74. The modern engineer must also understand the stresses to which the materials in a structureare subject.A. alikeB. similarC. differentD. the same75. Today, scientific data permit the engineer to make careful calculations .A. inaccuratelyB. in no trendC. lateD. in advance76. The force which the live load will be exerted on the structure is .A. dead loadB. live loadC. impactD. safety factor77. When a saw begins to bind, the wood is because the fibers in it are being pushed together.A. in compressionB. in tensionC. in pull apartD. in stretching78. rods are bent into the shapes to give them the necessary degree of tensile strength.A. ConcreteB. BrickC. PlasticD. Steel79. Many great buildings built in earlier ages are massive structures with .A. aluminum wallsB. thick stone wallsC. steel wallsD. plastic walls80. We all enter into contracts almost every day for the supply f goods, etc.A .educationB transportation C. friendship D. wedding81. Some contracts must be made in a particular to be enforceable.A. fileB. shapeC. patternD. form82. Once a person has signed a document he is assumed to have its contents.A. likedB. approvedC. opposedD. hated83. By setting down the terms of a contract in writing one secures avoiding .A. disputesB. troublesC. scufflesD. sufferings84. In an entire contract, where agrees to pay a certain sum in return for civil engineering work..A. the managerB. the contractorC. the carrierD. the employer85. is not entitled to any payment if he abandons the work prior to completion.A. The managerB. The contractorC. The carrierD. The employer86. The contractor is not entitled to receive payment in until the work is satisfactorilycompleted.A. fullB. partC. 1\3D. 1\487. A tender is normally required to be a definite .A. orderB. billC. offerD. license88. Generally, civil engineering contracts provide for the issue of at various stages of theworks.A. progress chartB. interim certificatesC. progress reportD. interim report89. It does not give the employer the right to demand an high standard of quality throughoutthe works.A. unusuallyB. usuallyC. ordinarilyD. unchangeable90. The employer does not usually bind himself to accept the lowest or indeed any tender and this isoften stated in the .A. bookB. referenceC. advertisementD. novel91. A contract has been defined as an agreement which directly creates and contemplates .A. a demandB. a gameC. an obligationD. an engagement92. When we enter into contracts we are willing to for the service we receive.A. enjoyB. haveC. payD. appreciate93. If there is no written agreement and arises in respect of the contract.A. amendmentB. an appointmentC. a disputeD. a quarrel94. The rubber-tired tractor units have difficulty in operating on , slippery roadbeds.A. looseB. dryC. driedD. wet95. There are variables in earthmoving.A. manyB. less C, different D. no96. The term describes the fill added above the low points along the roadway to raise thelevel to the bottom of the pavement structure.A. site clearingB. excavationC. earthmovingD. embankment97. Material for commonly comes from roadway cuts or designated borrow areas.A. excavationB. embankmentC. earthmovingD. site clearing98. control is largely a matter of conducting the specified procedure.A. TechniquesB. DevicesC. FieldD. Moisture99. Modern practice requires that embankment construction be executed and controlled.A. carefullyB. urgentlyC. easilyD. hardly100. Construction of pavement over high fills often was for a year or more after completion of the fill to allow the settlement to occur.A ahead B. deferred C. advanced D. the same time101. Nearly vegetable matter should be removed from the original ground and fill material.A. noB. allC. not allD. some 102. A track or wheel type bulldozer is to earthmoving of considerably long hauls.A. usedB. suitableC. adaptedD. not suitable 103. Loose rock is handled by units as is done with ‘common’ excavation.A. tractor-scraperB. push-loaded scraperC. power shovelD. roller104. The highway can require mental and response.A. physicalB. chemicalC. socialD. phonological 105. The needs generated by the great increase vehicle numbers and kilometers of road have given rise to major research programs in traffic planning.A. onB. atC. underD. in106. Terminology concerned highway preservation varies considerably from country to country.A. inB. withC. withoutD. through107. Highway improvement is also a key factor preventing accidents.A. offB. inC. onD. at 108. The actual degree of safety one experiences on a given highway is determined by decisions made on levels.A. sameB. differentC. distinguishedD. undistinguished109. Public agencies typically dictate the major constraints within which these design decisions are made.A. to beB. beenC. be toD. being110. Finally, individual motorists make decisions regarding their own safety they select speed, route for their cars.A. atB. toC. asD. in111. Safe highways are and it appears that the driving public does not want safe highways. A. inexpensive B. cheap C. expensive D. cost112. People do not want to pay the costs and suffer the restrictions necessary to produce in traffic.A. safetyB. dangerousC. urgentD. safe113. It is often to determine the true condition of a vehicle after a crash.A. impossibleB. easyC. possibleD. apt114. No figures available to justify it.A. isB. areC. amD. was115. For the driver’s vision, in the body of the automobile, both side and rear windows have been greatly in area.A. shortenedB. lackedC. smallD. enlarged116. Another improvement in driver visibility is the introduction of the remote-controlled rearview mirror.A. insideB. outsideC. undergroundD. top117. The safe performance of the brake system high temperatures has been ensured.A. inB. atC. underD. on118. Relocation and reduction in the height of the brake pedal has meant that the brake can be applied rapidly.A. muchB. moreC. lotD. rather119. The use of uniform traffic control devices will reduce driver reaction time confusion.A. as well asB. as good asC. as much asD. as long as120. Removal, relocation and redesign of fixed obstructions, can provide a clear area for vehicles out of control.A. safeB. hazardousC. recoveryD. dangerous121. Vehicular safety design usually centers protecting the driver and his passengers.A. inB. uponC. underD. up122. The highway construction may also cause impacts on the surroundings.A. helpfulB. favorableC. profitableD. adverse123. The designed highway alignment must meet the technical of the highway engineering. A. strategy B. standard C. philosophy D. policy124. is a gap graded material with less coarse aggregate.A. Hot rolled asphaltB. Porous asphaltC. Asphaltic concreteD. Dense bitumen macadam 125. In this case, layer thickness, moisture control, and the number of passes by a roller of specified type and weight are .A. predeterminedB. not determinedC. unknownD. postdetermined126. is the conventional location technique for highway.A. Remote sensingB. Ground surveyC. Total stationD. Photogrammetry127. A is only used for measuring the vertical heights of objects.A. levelB. total stationC. transitD. tape128. If Party A commissions Party B to execute the construction work, then Party B is referred to as .A. the employerB. the contractorC. the tendererD. the carrier129. The force-account work should be checked and approved daily by .A. the employerB. the contractorC. the carrierD. both A and B130. is not advantage of highway transportation.A. Fast speedB. FlexibilityC. Providing door-to-door serviceD. Carrying a variety of parcel sizes二．填空题：131. Engineers often work as to architectural or construction firms.132. Young engineers may choose to go into or sanitary engineering.133. It is sufficient in order to create a legally , if the parties express their agreement and intention to enter into such a contract.134. One party to the contract is for breach of contract if he fails to perform his part of the agreement.135. the site precedes all grading and most other construction operations.136. Loose rock includes materials such as rock, or earth mixed with boulders.137. No attempt was made to control content or to secure compaction.138. The of windshield wipers, fresh air ventilating systems, had result in greater vehicle safety.139. The safe performance of the brake system has been ensured by the use of brake fluid. 140. Relocation and reduction in height of the brake has meant that the driver’s total reaction time has been reduced.141. Areas of research connected with civil engineering include soil mechanics and ______ techniques.142. Modern cement, called ______, was invented in 1824.143. Material for embankment commonly comes from roadway cuts or designated ______. 144. Causes of automobile accidents can be categorized into four major groups: the vehicles, the road, the driver, the ______ .145. Another improvement in driver visibility is the introduction of the remote-controlled outside ______ mirror.146. Rock nearly always must be drilled and blasted, then loaded with a front-end loader or ______ into trucks or other hauling units.147. The three forces that can act on a structure are , horizontal force, and those that actupon it with a rotating or turning motion.148. Highway pavements are divided into two main categories: ______ and flexible.149. Flexible pavements are further divided into three subgroups: high type, ______, and low type.150. The constructing steps of the transportation system are to plan, design, build, operate and _____.151. The unit price contract is adapted to highway engineering, because usually it is not possible to determine exact quantities of some items of work ______ construction is completed.152. The word ‘contract’ is derived from the Latin ‘contractum’, meaning ______together.153. As a structural material, the enormous advantage of steel is its ______.154. ______ is the dominant transportation mode in passenger travel.155. The Portland cement concrete commonly used for rigid pavements consists of Portland cement, coarse aggregate, ______, water.156. Rigid highway pavement can be divided into three general types: plain concrete pavements, simply reinforced concrete and ______pavements.157. The simplest and generally least costly form of interchange is the ______.158. If distances are great and time is at a premium, ______ transportation will be selected. 159. Signing for freeways should be planned concurrently with the ______ design.160. Major drainage structures are usually large bridges and multi-span ______.161. The weight of the structure itself is known as .162. concrete is an improved form of reinforcement.163. A simple contract consists of an entered into by two or more parties.164. This sum is known as ‘money’ and serves to insure the employer against any defects that may arise in the work.165. Thus, training can be acquired to translate theory into practice to the supervisors. 166. Large projects ordinarily employ several engineers whose work is coordinated by a . 167. Traffic loads are transferred by the wearing surface to the underlying supporting materialsthrough the interlocking of aggregates, the frictional effect of , and cohesion of the fine materials.168. Excavation is the process of loosening and removing earth or rock and transporting it to a fill or to a .169. When planning a structure, an engineer must take into account four factors: dead load, , impact and safety factor.170. The new design standards require rails and other structures to lessen a vehicle’s impact. 171. People select to carry important goods when time is at a premium.172. The benefit-cost ratio method is used for evaluating the and environmental feasibility of the alternative routes.173. A unique bridge site or a mountain pass also mat become a primary .174. The radius of a tangent is , and that of a curve is finite.ing collector-distributor roads can overcome weaving movement of the interchange.三．阅读理解题：Passage OneResearch is one of the most important aspects of scientific and engineering practice. A researcher usually works as a member of a team with other scientists and engineers. He or she is often employed in a laboratory that is financed by government or industry. Areas of research connected with civil engineering include soil mechanics and soil stabilization techniques, and also the development and the testing of new structural materials.176. Research is one of ______ aspects of scientific and engineering practice.A. the most uselessB. the most importantC. the most unnecessary177. A researcher is often employed .A. on a farmB. in a libraryC. in a laboratory178. A researcher usually works as a member of a team with .A. farmers and scientistsB. engineers and farmersC. scientists and engineers179. Which of the following is true?A. Civil engineering research doesn’t include only soil mechanics and soil stabilization, butalso the development of new structural materialsB. Civil engineering research doesn’t include soil mechanics and soil stabilizationC. Civil engineering research doesn’t include the development of new structural materialsPassage TwoThe current tendency is to develop lighter materials. Aluminum, for example, weighs much less than steel but has many of the same properties. Aluminum beams have already been used for bridge construction and for the framework of a few buildings.Attempts are also being made to produce concrete with more strength and durability, and with a lighter weight. One system that helps cut concrete weight to some extent uses polymers, which are long chainlike compounds used in plastics, as part of the mixture.180. The current trend of structural materials is .A. to develop heavier materialsB. to develop lighter materialsC. to develop less materials181. Aluminum weighs .A. much less than steelB. the same as steelC. much heavier than steel182. Aluminum has .A. no properties of steelB. few properties of steelC. many of the same properties of steel183. Which of the following is true?A. Aluminum beams can’t be used for bridge constructionB. Aluminum beams can be used for not only bridge construction but also the framework ofa few buildingsC. Aluminum beams can’t be used for the framework of a few buildingsPassage ThreeSteel and concrete also complement each other in another way: they have almost the same rate of contraction and expansion. They therefore can work together in situations where both compression and tension are factors. Steel rods are embedded in concrete to make reinforced concrete in concrete beams or structures where tension will develop. Concrete and steel also form such a strong bonds—the force that unites them—that the steel cannot slip within the concrete. Still another advantage is that steel does not rust in concrete. Acid corrodes steel, whereas concrete has an alkaline chemical reaction, the opposite of acid.184. Steel and concrete have .A. different rate of contractionB. different rate of expansionC. almost the same rate of contraction and expansion185. Reinforced concrete is .A. steel rods which are embedded in concrete beamsB. concrete which is embedded in steel rodsC. steel rods which react with concrete186. Which of the following is true?。

逻辑构造：(英logical construction)英国罗素用语。

认为为了达到知识的确定性，应尽可能用已知实体的结构替换对于未知实体的推论。

这就是要找出陈述中那些在逻辑上和认识论上最基本的原子陈述。

如果能够把某个包含有x这个语词的陈述改变为一个不包含有x而又不改变命题意义的陈述，那就可以说x是一个逻辑构造。

例如，可以把一个包含有“桌子”这个概念的陈述，改变为一个不提及“桌子”而仅仅提及“长度”、“宽度”、“硬度”、“颜色”等等感觉材料的陈述，从而表明“桌子”概念是一个逻辑构造。

在一般场合下，任何超验的或抽象的实体都是从比较具体的、从感性经验中得知的实体中得出逻辑构造的。

不完全符号：(英incomplete symbol)英国罗素用语。

指摹状词短语。

认为像“亚历山大大帝的老师”等等这样的“不完全符号”,因为它不直接指称某个特定的个体，它没有给它所指示的事实成分命名，因而它不具有独立的意义，只有在上下文中才能确定其独立的意义，即确定其所代表的对象。

与专名不同，摹状词短语或不完全符号不是一个指称某个特定对象的简单符号，而是一个用以描述对象的特征的复合符号，即一个具有内部结构的符号，它的各个组成部分本身具有字面意义，描述了对象的某些特征。

例如，“亚历山大大帝的老师”这个不完全符号不直接指称某个特定的个体，不具有独立意义，但它描述了某个个体的某种特征。

可信度：(英degree of credibility)英国罗素用语。

指一个有理性的人对某一事物可以给予的相信的程度。

凡是我们愿意相信的事物都具有一种“可信度”或“可疑度”。

对于每个有理性的人来说，存在着一个表示不同程度的怀疑的尺度，它的一端是简单的逻辑命题、算术命题以及知觉判断，另一端是一些荒谬的命题。

换言之，任何一个我们具有合理根据而对之具有某种程度的相信或不相信的命题，在理论上都可以排列在一个以必然真理和必然荒谬为两端的尺度之上。

可信度与数学上的概率有某种联系，即如果一个命题对于有关证据来说具有某种数学上的概率，那就能确定它的可信度的大小。