建筑类型和设计-外文翻译

建筑设计中英文对照表目录：Cover封面Content目录Design Explanation设计说明Master Plan总平面Space Sequence Analysis景观空间分析Function Analysis功能分析Landscape Theme Analysis景观景点主题分析图Traffic Analysis交通分析Vertical Plan竖向平面布置图Lighting Furniture Layout灯光平面布置示意图Marker/Background Music/Garbage Bin标识牌/背景音乐/垃圾桶布置图Plan平面图Hand Drawing手绘效果图Section剖面图Detail详图Central Axis中心公共主轴Reference Picture参考图片Planting Reference Picture植物选样材料类：aluminum铝asphalt沥青alpine rock轻质岗石boasted ashlars粗凿ceramic陶瓷、陶瓷制品cobble小圆石、小鹅卵石clay粘土crushed gravel碎砾石crushed stone concrete碎石混凝土crushed stone碎石cement石灰enamel陶瓷、瓷釉frosted glass磨砂玻璃grit stone/sand stone砂岩glazed colored glass/colored glazed glass彩釉玻璃granite花岗石、花岗岩gravel卵石galleting碎石片ground pavement material墙面地砖材料light-gauge steel section/hollow steel section薄壁型钢light slates轻质板岩lime earth灰土masonry砝石结构membrane张拉膜、膜结构membrane waterproofing薄膜防水mosaic马赛克quarry stone masonry/quarrystone bond粗石体plaster灰浆polished plate glass/polished plate磨光平板玻璃panel面板、嵌板rusticated ashlars粗琢方石rough rubble粗毛石reinforcement钢筋设计阶段：existing condition analysis现状分析analyses of existings城市现状分析construction site service施工现场服务conceptual design概念设计circulation analysis交通体系分析construction drawing施工图complete level完成面标高details细部设计、细部大样示意图diagram示意图、表elevation上升、高地、海拔、正面图development design扩初设计façade/elevation正面、立面general development analysis城市总体发展分析general situation survey概况general layout plan/master plan总平面general nature environment总体自然分析grid and landmark analysis城市网格系统及地标性建筑物分析general urban and landscape concept总体城市及景观设计概念general level design总平面竖向设计general section总体剖面图layout plan布置图legend图例lighting plan灯光布置图plan drawing平面图plot plan基地图presentation drawing示意图perspective/render效果图pavement plan铺装示意图reference pictures/imaged picture参考图片reference level参考标高图片site overall arrangement场地布局space sequence relation空间序列specification指定、指明、详细说明书scheme design方案设计sketch手绘草图sectorization功能分区section剖面site planning场地设计reference picture of planting植物配置意向图reference picture of street furniture街道家具布置意向图设计描述：a thick green area密集绿化administration/administrative行政administration zone行政区位function analysis功能分析arc/camber弧形askew歪的、斜的aesthetics美学height高度abstract art抽象派artist艺术家、大师art nouveau新艺术主义acre英亩architect建筑师be integrated with与……结合起来bisect切成两份、对开bend弯曲boundary/border边界operfloor架空层budget预算estimate评估beach海滩building code建筑规范。

building types and designA building is closely bound up with people，for it provides with the necessary space to work and live in .As classified by their use ,buildings are mainly of two types :industrial buildings and civil buildings .industrial buildings are used by various factories or industrial production while civil buildings are those that are used by people fordwelling ,employment ,education and other social activities .Industrial buildings are factory buildings that are available for processing and manufacturing of various kinds ,in such fields as the mining industry ,the metallurgical industry ,machine building ,the chemical industry and the textile industry . factory buildings can be classified into two types single-story ones and multi-story ones .the construction of industrial buildings is the same as that of civil buildings .however ,industrial and civil buildings differ in the materials used and in the way they are used .Civil buildings are divided into two broad categories: residential buildings and public buildings .residential buildings should suit family life .each flat should consist of at least three necessary rooms : a living room ,a kitchen and a toilet .public buildings can be used in politics ,cultural activities ,administration work and other services ,such as schools, office buildings,parks ,hospitals ,shops ,stations ,theatres ,gymnasiums ,hotels ,exhibition halls ,bath pools ,and so on .all of them have different functions ,which in turn require different design types as well.Housing is the living quarters for human beings .the basic function of housing is to provide shelter from the elements ,but people today require much more that of their housing .a family moving into a new neighborhood will to know if the available housing meets its standards of safety ,health ,and comfort .a family will also ask how near the housing is to grain shops ,food markets ,schools ,stores ,the library ,a movie theater ,and the community center .In the mid-1960’s a most important value in housing was sufficient space both inside and out .a majority of families preferred single-family homes on about half an acre of land ,which would provide space for spare-time activities .in highly industrialized countries ,many families preferred to live as far out as possible from the center of a metropolitan area ,even if the wage earners had to travel some distance to theirwork .quite a large number of families preferred country housing to suburban housing because their chief aim was to get far away from noise ,crowding ,and confusion .the accessibility of public transportation had ceased to be a decisive factor in housing because most workers drove their cars to work .people we’re chiefly interested in the arrangement and size of rooms and the number of bedrooms .Before any of the building can begin ,plans have to be drawn to show what the building will be like ,the exact place in which it is to go and how everything is to be done.An important point in building design is the layout of rooms ,which should provide the greatest possible convenience in relation to the purposes for which they are intended .in a dwelling house ,the layout may be considered under three categories : “day”, “night” ,and “services” .attention must be paid to the provision of easy commun ication between these areas .the “day “rooms generally include adining-room ,sitting-room and kitchen ,but other rooms ,such as a study ,may be added ,and there may be a hall .the living-room ,which is generally the largest ,often serves as a dining-room ,too ,or the kitchen may have a dining alcove .the “night “rooms consist of the bedrooms .the “services “comprise thekitchen ,bathrooms ,larder ,and water-closets .the kitchen and larder connect the services with the day rooms .It is also essential to consider the question of outlook from the various rooms ,and those most in use should preferably face south as possible .it is ,however ,often very difficult to meet the optimum requirements ,both on account of the surroundings and the location of the roads .in resolving these complex problems ,it is also necessary to follow the local town-planning regulations which are concerned with public amenities ,density of population ,height of buildings ,proportion of green space to dwellings ,building lines ,the general appearance of new properties in relation to the neighbourhood ,and so on .There is little standardization in industrial buildings although such buildings still need to comply with local town-planning regulations .the modern trend is towardslight ,airy factory buildings .generally of reinforced concrete or metal construction ,a factory can be given a “shed ”type ridge roof ,incorporating windows facing north so as to give evenly distributed natural lighting without sun-glare .翻译：建筑类型和设计建筑物与人们有着紧密的联系，他为人们提供必要的空间，用以工作和生活。

建筑设计中英文对照外文翻译文献On the other hand, there is a significant amount ofliterature in the field of architecture design that is writtenin foreign languages. While it may not be as readily accessible for non-native speakers, there are many benefits to exploring literature in other languages. For example, architects who are fluent in multiple languages can have a broader understanding of different cultural approaches to architecture. By reading literature in foreign languages, architects can gain insights into design concepts and practices that may not be covered in English-language sources. This can lead to a more diverse and innovative approach to design.However, one challenge with accessing literature in foreign languages is the accuracy of translations. Architecture is a technical field with specific terminology, and it is important to ensure that translations accurately convey the intended meaning. In some cases, the translation of technical terms and concepts may not accurately convey their full meaning, which can lead to misunderstandings or confusion. Architects who rely on translated literature should be cautious and ensure they verify the accuracy of the translations with experts in the field.Despite these challenges, it is essential for architects to explore literature in multiple languages to stay informed and to gain a global perspective on architecture design. By consideringboth English and foreign language translated literature, architects can access a wider range of resources and insights. Additionally, architects should consider collaborating with colleagues who are fluent in different languages to ensure accurate translation and interpretation of foreign language sources.In conclusion, architecture design is a field that benefits from accessing literature in multiple languages. English provides a wealth of resources and is the global language of academia. However, architects who can access and read literature in foreign languages can gain new perspectives and insights into different cultural approaches to design. While caution should be taken to verify the accuracy of translations, architects should explore literature in multiple languages to broaden their understanding and enhance their creative problem-solving skills.。

中英文对照外文翻译文献(文档含英文原文和中文翻译)Structure in Design of ArchitectureAnd Structural MaterialWe have and the architects must deal with the spatial aspect of activity, physical, and symbolic needs in such a way that overall performance integrity is assured. Hence, he or she well wants to think of evolving a building environment as a total system of interacting and space forming subsystems. Is represents a complex challenge, and to meet it the architect will need a hierarchic design process that provides at least three levels of feedback thinking: schematic,preliminary, and final.Such a hierarchy is necessary if he or she is to avoid being confused , at conceptual stages of design thinking ,by the myriad detail issues that can distract attention from more basic considerations .In fact , we can say that an architect’s ability to distinguish the more basic form the more detailed issues is essential to his success as a designer .The object of the schematic feed back level is to generate and evaluate overall site-plan, activity-interaction, and building-configuration options .To do so the architect must be able to focus on the interaction of the basic attributes of the site context, the spatial organization, and the symbolism as determinants of physical form. This means that ,in schematic terms ,the architect may first conceive and model a building design as an organizational abstraction of essential performance-space in teractions.Then he or she may explore the overall space-form implications of the abstraction. As an actual building configuration option begins to emerge, it will be modified to include consideration for basic site conditions.At the schematic stage, it would also be helpful if the designer could visualize his or her options for achieving overall structural integrity and consider the constructive feasibility and economic ofhis or her scheme .But this will require that the architect and/or a consultant be able to conceptualize total-system structural options in terms of elemental detail .Such overall thinking can be easily fed back to improve the space-form scheme.At the preliminary level, the architect’s emphasis will shift to the elaboration of his or her more promising schematic design options .Here the architect’s structural needs will shift to approximate design of specific subsystem options. At this stage the total structural scheme is developed to a middle level of specificity by focusing on identification and design of major subsystems to the extent that their key geometric, component, and interactive properties are established .Basic subsystem interaction and design conflicts can thus be identified and resolved in the context of total-system objectives. Consultants can play a significant part in this effort; these preliminary-level decisions may also result in feedback that calls for refinement or even major change in schematic concepts.When the designer and the client are satisfied with the feasibility of a design proposal at the preliminary level, it means that the basic problems of overall design are solved and details are not likely to produce major change .The focus shifts again ,and the design process moves into the final level .At this stage the emphasiswill be on the detailed development of all subsystem specifics . Here the role of specialists from various fields, including structural engineering, is much larger, since all detail of the preliminary design must be worked out. Decisions made at this level may produce feedback into Level II that will result in changes. However, if Levels I and II are handled with insight, the relationship between the overall decisions, made at the schematic and preliminary levels, and the specifics of the final level should be such that gross redesign is not in question, Rather, the entire process should be one of moving in an evolutionary fashion from creation and refinement (or modification) of the more general properties of a total-system design concept, to the fleshing out of requisite elements and details.To summarize: At Level I, the architect must first establish, in conceptual terms, the overall space-form feasibility of basic schematic options. At this stage, collaboration with specialists can be helpful, but only if in the form of overall thinking. At Level II, the architect must be able to identify the major subsystem requirements implied by the scheme and substantial their interactive feasibility by approximating key component properties .That is, the properties of major subsystems need be worked out only in sufficient depth to very the inherent compatibility of their basic form-related and behavioral interaction . This will mean a somewhat more specificform of collaboration with specialists then that in level I .At level III ,the architect and the specific form of collaboration with specialists then that providing for all of the elemental design specifics required to produce biddable construction documents .Of course this success comes from the development of the Structural Material.The principal construction materials of earlier times were wood and masonry brick, stone, or tile, and similar materials. The courses or layers were bound together with mortar or bitumen, a tar like substance, or some other binding agent. The Greeks and Romans sometimes used iron rods or claps to strengthen their building. The columns of the Parthenon in Athens, for example, have holes drilled in them for iron bars that have now rusted away. The Romans also used a natural cement called puzzling, made from volcanic ash, that became as hard as stone under water.Both steel and cement, the two most important construction materials of modern times, were introduced in the nineteenth century. Steel, basically an alloy of iron and a small amount of carbon had been made up to that time by a laborious process that restricted it to such special uses as sword blades. After the invention of the Bessemer process in 1856, steel was available in large quantities at low prices. The enormous advantage of steel is its tensile forcewhich, as we have seen, tends to pull apart many materials. New alloys have further, which is a tendency for it to weaken as a result of continual changes in stress.Modern cement, called Portland cement, was invented in 1824. It is a mixture of limestone and clay, which is heated and then ground into a power. It is mixed at or near the construction site with sand, aggregate small stones, crushed rock, or gravel, and water to make concrete. Different proportions of the ingredients produce concrete with different strength and weight. Concrete is very versatile; it can be poured, pumped, or even sprayed into all kinds of shapes. And whereas steel has great tensile strength, concrete has great strength under compression. Thus, the two substances complement each other.They 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 tensions will develop. Concrete and steel also form such a strong bond─ 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.The adoption of structural steel and reinforced concrete caused major changes in traditional construction practices. It was no longer necessary to use thick walls of stone or brick for multistory buildings, and it became much simpler to build fire-resistant floors. Both these changes served to reduce the cost of construction. It also became possible to erect buildings with greater heights and longer spans.Since the weight of modern structures is carried by the steel or concrete frame, the walls do not support the building. They have become curtain walls, which keep out the weather and let in light. In the earlier steel or concrete frame building, the curtain walls were generally made of masonry; they had the solid look of bearing walls. Today, however, curtain walls are often made of lightweight materials such as glass, aluminum, or plastic, in various combinations.Another advance in steel construction is the method of fastening together the beams. For many years the standard method was riveting.A rivet is a bolt with a head that looks like a blunt screw without threads. It is heated, placed in holes through the pieces of steel, and a second head is formed at the other end by hammering it to hold it in place. Riveting has now largely been replaced by welding, the joining together of pieces of steel by melting a steel materialbetween them under high heat.Priestess’s concrete is an improved form of reinforcement. Steel rods are bent into the shapes to give them the necessary degree of tensile strengths. They are then used to priestess concrete, usually by one of two different methods. The first is to leave channels in a concrete beam that correspond to the shapes of the steel rods. When the rods are run through the channels, they are then bonded to the concrete by filling the channels with grout, a thin mortar or binding agent. In the other (and more common) method, the priestesses steel rods are placed in the lower part of a form that corresponds to the shape of the finished structure, and the concrete is poured around them. Priestess’s concrete uses less steel and less concrete. Because it is a highly desirable material.Progressed concrete has made it possible to develop buildings with unusual shapes, like some of the modern, sports arenas, with large spaces unbroken by any obstructing supports. The uses for this relatively new structural method are constantly being developed.建筑中的结构设计及建筑材料建筑师必须从一种全局的角度出发去处理建筑设计中应该考虑到的实用活动，物质及象征性的需求。

毕业设计（论文）外文参考资料及译文译文题目：建筑类型和设计Building types and designAbstract: As classified by their use ,buildings are mainly of two types :industrial buildings and civil buildings .industrial buildings are used by various factories or industrial production while civil buildings are those that are used by people for dwelling, employment ,education and other social activities .Key words: industrial buildings; civil buildings; social activitiesA building is closely bound up with people，for it provides with the necessary space to work and live in .As classified by their use ,buildings are mainly of two types :industrial buildings and civil buildings .industrial buildings are used by various factories or industrial production while civil buildings are those that are used by people for dwelling ,employment ,education and other social activities .Industrial buildings are factory buildings that are available for processing and manufacturing of various kinds ,in such fields as the mining industry ,themetallurgical industry ,machine building ,the chemical industry and the textile industry . factory buildings can be classified into two types single-story ones and multi-story ones .the construction of industrial buildings is the same as that of civil buildings .however ,industrial and civil buildings differ in the materials used and in the way they are used .Civil buildings are divided into two broad categories: residential buildings and public buildings .residential buildings should suit family life .each flat should consist of at least three necessary rooms : a living room ,a kitchen and a toilet .public buildings can be used in politics ,cultural activities ,administration work and other services,suchasschools,officebuildings,parks ,hospitals ,shops ,stations ,theatres ,gym nasiums ,hotels ,exhibition halls ,bath pools ,and so on .all of them have different functions ,which in turn require different design types as well.Housing is the living quarters for human beings .the basic function of housing is to provide shelter from the elements ,but people today require much more that of their housing .a family moving into a new neighborhood will to know if the available housing meets its standards of safety ,health ,and comfort .a family will also ask how near the housing is to grain shops ,food markets ,schools ,stores ,the library ,a movie theater ,and the community center .In the mid-1960’s a most important value in housing was sufficient space both inside and out .a majority of families preferred single-family homes on about half an acre of land ,which would provide space for spare-time activities .in highly industrialized countries ,many families preferred to live as far out as possible from the center of a metropolitan area ,even if the wage earners had to travel some distance to their work .quite a large number of families preferred country housing to suburban housing because their chief aim was to get far away from noise ,crowding ,and confusion .the accessibility of public transportation had ceased to be a decisive factor in housing because most workers drove their cars to work .people we’re chiefly interested in the arrangement and size of rooms and the number of bedrooms .Before any of the building can begin ,plans have to be drawn to show what the building will be like ,the exact place in which it is to go and how everything is to be done.An important point in building design is the layout of rooms ,which should provide the greatest possible convenience in relation to the purposes for which they are intended .in a dwelling house ,the layout may be considered under three categories : “day”, “night” ,and “services” .attention must be paid to the provision of easy communication between these areas .the “day”rooms generally include a dining-room ,sitting-room and kitchen ,but other rooms ,such as a study ,may be added ,and there may be a hall .the living-room ,which is generally the largest ,often serves as a dining-room ,too ,or the kitchen may have a d ining alcove .the “night” rooms consist the roost.t he “services” comprise the kitchen ,bathrooms ,larder ,and water-closets .the kitchen and larder connect the services with the day rooms .It is also essential to consider the question of outlook from the various rooms ,and those most in use should preferably face south as possible .it is ,however ,often very difficult to meet the optimum requirements ,both on account of the surroundings and the location of the roads .in resolving these complex problems ,it is also necessary to follow the local town-planning regulations which are concerned with public amenities ,density of population ,height of buildings ,proportion of green space to dwellings ,building lines ,the general appearance of new properties in relation to the neighbourhood ,and so on .There is little standardization in industrial buildings although such buildings still need to comply with local town-planning regulations .the modern trend is towards light ,airy factory buildings .generally of reinforced concrete or metal construction ,a factory can be given a “shed ”type ridge roof ,incorporating windows facing north so as to give evenly distributed natural lighting without sun-glare .Architectural design development so far, is no longer content merely to live and businesses use natural resources are becoming scarce in today's society, energy saving, environmentally friendly building construction to become the development trend of the future. Market has been as energy conservation, green building the driving force,the recent century represented a harmonious environment, real estate sellingenergy-saving also proves this point. This also means that ordinary people had alienated the energy saving type of real estate, gradually unfold the mystery, to the public.Water reuse and efficient use of water resources technologyReflections Harmony century urban life, the introduction of green, energy-saving building construction concept, the full use of geographical terrain and climate, natural advantages, according to human comfort requirements and weather conditions for construction planning and design, Kunming bring a “non-green , uncooperative”, the life of the proposal, environmental protection into a harmonious way of life.Deep sense of crisis of water scarcity, water conservation harmony century by water reuse treatment systems. “Water”, also known as “recycled water” or “back water”, water reuse is the main form of eff icient use of water resources. “Harmony Century” water reuse treatment systems throughout the real estate sub-quality implementation of all water emissions, returning after a biological focus, depth filtration UV disinfection treatment process, used for toilet flushing, car washing, cleaning, and to meet the landscape and a huge pool green eco-system needs, efficient use of water resources, water cost savings of more households.Impermeable layer of drainage technique with noise“Harmony Century” the introduction of the same layer emission technologies, to achieve the same floor of the main drainage branch pipe and branch pipes are not across the floor drain in the floor within the same established connection to the main drainage pipe.The traditional approach, there are a number of drainage construction, it is hard to solve the problem: noise can interfere with the drainage upstairs downstairs; floor are many holes, the downstairs when the fire could spread to the upstairs; maintenance, when renovation of damage to the downstairs ceilings; sewage poured into the trap as a result of health problems; leaks, clogged affect the downstairs tenants, disputes.“Harmony Century” using the same drainage system, installed only in the civil riser, interior designers can be free of the bathroom layout, drainage branch pipe inthe renovation by interior design drawings for installation. As a result, not only solved the problem of traditional drainage patterns to achieve the clarity of property rights, each household has a fully independent health space, tenants will not be the upper interference, while still meeting the personalized decoration, personalized decoration . Solar energy saving lamp“Harmony Century” will be back in two years ago, solar lighting in the planning, is the first application of solar lighting in Kunming than real estate, energy-saving environmental protection played a role model.Solar energy street lights, without power because of their influence, without ditching embedding, not consumption of conventional energy, as long as the sunny spot to be installed and so on. Harmony century, the first to use solar lights, charging at night during the day, no external power supply, safety and energy conservation pollution; the process of charging and switching lights from the microcomputer intelligent control, automatic lights dark, dawn, turn off the lights automatically, without manual operation, stable and reliable , long life, full of energy saving; solar power supply systems over ad hoc charge, discharge, anti-reverse and lightning, etc., more secure and reliable operation.Thermal insulation of aerated concrete brick insulation, noise, radiation Aerated concrete is a new type of light porous materials, it is light weight, good insulation properties, high strength, shock resistance, sound insulation performance, high temperature and so on.Since only the weight of aerated concrete brick and sand-lime brick is equivalent to 1 / 3 of ordinary concrete, 1 / 5, greatly reducing the weight of body building, built to improve the seismic performance of buildings.We can see from the structure, the internal structure of aerated concrete, like bread, like a large number of evenly distributed closed pores, so in general do not have the sound-absorbing building materials performance。

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。

中文3220字附录：毕业设计外文翻译院（系）建筑工程学院专业土木工程班级姓名学号导师2011年4月15日英文：High-Rise Buildings and StructuralDesignAbstract：It is difficult to define a high-rise building . One may say that a low-rise building ranges from 1 to 2 stories . A medium-rise building probably ranges between 3 or 4 stories up to 10 or 20 stories or more . Although the basic principles of vertical and horizontal subsystem design remain the same for low- , medium- , or high-rise buildings , when a building gets high the vertical subsystems become a controlling problem for two reasons . Higher vertical loads will require larger columns , walls , and shafts . But , more significantly , the overturning moment and the shear deflections produced by lateral forces are much larger and must be carefully provided for .Key Words：High-Rise Buildings Structural Design Framework Shear Seismic SystemIntroductionThe vertical subsystems in a high-rise building transmit accumulated gravity load from story to story , thus requiring larger column or wall sections to support such loading . In addition these same vertical subsystems must transmit lateral loads , such as wind or seismic loads , to the foundations. However , in contrast to vertical load , lateral load effects on buildings are not linear and increase rapidly with increase in height . For example under wind load , the overturning moment at the base of buildings varies approximately as the square of a buildings may vary as the fourth power of buildings height , other things being equal.Earthquake produces an even more pronounced effect.When the structure for a low-or medium-rise building is designed for dead and live load , it is almost an inherent property that the columns , walls , and stair or elevator shafts can carry most of the horizontal forces . The problem is primarily shear resistance . Moderate addition bracing for rigid frames in“short”buildings can easily be provided by filling certain panels ( or even all panels ) without increasing the sizes of the columns and girders otherwise required for vertical loads.Unfortunately , this is not is for high-rise buildings because the problem is primarily resistance to moment and deflection rather than shear alone . Special structural arrangements will often have to be made and additional structural material is always required for the columns , girders , walls , and slabs in order to made a high-rise buildings sufficiently resistant to much higher lateral deformations .As previously mentioned , the quantity of structural material required per square foot of floor of a high-rise buildings is in excess of that required for low-rise buildings . The vertical components carrying the gravity load , such as walls , columns , and shafts , will need to be strengthened over the full height of the buildings . But quantity of material required for resisting lateral forces is even more significant .With reinforced concrete , the quantity of material also increases as the number of stories increases . But here it should be noted that the increase in the weight of material added for gravity load is much more sizable than steel , whereas for wind load the increase for lateral force resistance is not that much more since the weight of a concrete buildings helps to resist overturn . On the other hand , the problem of design for earthquake forces . Additional mass in the upper floors will give rise to a greater overall lateral force under the of seismic effects .In the case of either concrete or steel design , there are certain basic principles for providing additional resistance to lateral to lateral forces and deflections in high-rise buildings without too much sacrifire ineconomy .1、Increase the effective width of the moment-resisting subsystems . This is very useful because increasing the width will cut down the overturn force directly and will reduce deflection by the third power of the width increase , other things remaining cinstant . However , this does require that vertical components of the widened subsystem be suitably connected to actually gain this benefit.2、Design subsystems such that the components are made to interact in the most efficient manner . For example , use truss systems with chords and diagonals efficiently stressed , place reinforcing for walls at critical locations , and optimize stiffness ratios for rigid frames .3、Increase the material in the most effective resisting components . For example , materials added in the lower floors to the flanges of columns and connecting girders will directly decrease the overall deflection and increase the moment resistance without contributing mass in the upper floors where the earthquake problem is aggravated .4、Arrange to have the greater part of vertical loads be carried directly on the primary moment-resisting components . This will help stabilize the buildings against tensile overturning forces by precompressing the major overturn-resisting components .5、The local shear in each story can be best resisted by strategic placement if solid walls or the use of diagonal members in a vertical subsystem . Resisting these shears solely by vertical members in bending is usually less economical , since achieving sufficient bending resistance in the columns and connecting girders will require more material and construction energy than using walls or diagonal members .6、Sufficient horizontal diaphragm action should be provided floor . This will help to bring the various resisting elements to work together instead of separately .7、Create mega-frames by joining large vertical and horizontal components such as two or more elevator shafts at multistory intervalswith a heavy floor subsystems , or by use of very deep girder trusses .Remember that all high-rise buildings are essentially vertical cantilevers which are supported at the ground . When the above principles are judiciously applied , structurally desirable schemes can be obtained by walls , cores , rigid frames, tubular construction , and other vertical subsystems to achieve horizontal strength and rigidity . Some of these applications will now be described in subsequent sections in the following .Shear-Wall SystemsWhen shear walls are compatible with other functional requirements , they can be economically utilized to resist lateral forces in high-rise buildings . For example , apartment buildings naturally require many separation walls . When some of these are designed to be solid , they can act as shear walls to resist lateral forces and to carry the vertical load as well . For buildings up to some 20storise , the use of shear walls is common . If given sufficient length ,such walls can economically resist lateral forces up to 30 to 40 stories or more .However , shear walls can resist lateral load only the plane of the walls ( i.e.not in a diretion perpendicular to them ) . Therefore ,it is always necessary to provide shear walls in two perpendicular directions can be at least in sufficient orientation so that lateral force in any direction can be resisted . In addition , that wall layout should reflect consideration of any torsional effect .In design progress , two or more shear walls can be connected to from L-shaped or channel-shaped subsystems . Indeed , internal shear walls can be connected to from a rectangular shaft that will resist lateral forces very efficiently . If all external shear walls are continuously connected , then the whole buildings acts as a tube , and is excellent Shear-Wall Systems resisting lateral loads and torsion .Whereas concrete shear walls are generally of solid type withopenings when necessary , steel shear walls are usually made of trusses . These trusses can have single diagonals , “X”diagonals , or“K”arrangements . A trussed wall will have its members act essentially in direct tension or compression under the action of view , and they offer some opportunity and deflection-limitation point of view , and they offer some opportunity for penetration between members . Of course , the inclined members of trusses must be suitable placed so as not to interfere with requirements for windows and for circulation service penetrations though these walls .As stated above , the walls of elevator , staircase ,and utility shafts form natural tubes and are commonly employed to resist both vertical and lateral forces . Since these shafts are normally rectangular or circular in cross-section , they can offer an efficient means for resisting moments and shear in all directions due to tube structural action . But a problem in the design of these shafts is provided sufficient strength around door openings and other penetrations through these elements . For reinforced concrete construction , special steel reinforcements are placed around such opening .In steel construction , heavier and more rigid connections are required to resist racking at the openings .In many high-rise buildings , a combination of walls and shafts can offer excellent resistance to lateral forces when they are suitably located ant connected to one another . It is also desirable that the stiffness offered these subsystems be more-or-less symmertrical in all directions .Rigid-Frame SystemsIn the design of architectural buildings , rigid-frame systems for resisting vertical and lateral loads have long been accepted as an important and standard means for designing building . They are employed for low-and medium means for designing buildings . They are employed for low- and medium up to high-rise building perhaps 70 or 100 stories high . When compared to shear-wall systems , these rigid frames bothwithin and at the outside of a buildings . They also make use of the stiffness in beams and columns that are required for the buildings in any case , but the columns are made stronger when rigidly connected to resist the lateral as well as vertical forces though frame bending .Frequently , rigid frames will not be as stiff as shear-wall construction , and therefore may produce excessive deflections for the more slender high-rise buildings designs . But because of this flexibility , they are often considered as being more ductile and thus less susceptible to catastrophic earthquake failure when compared with ( some ) shear-wall designs . For example , if over stressing occurs at certain portions of a steel rigid frame ( i.e.,near the joint ) , ductility will allow the structure as a whole to deflect a little more , but it will by no means collapse even under a much larger force than expected on the structure . For this reason , rigid-frame construction is considered by some to be a “best”seismic-resisting type for high-rise steel buildings . On the other hand ,it is also unlikely that a well-designed share-wall system would collapse.In the case of concrete rigid frames ,there is a divergence of opinion . It true that if a concrete rigid frame is designed in the conventional manner , without special care to produce higher ductility , it will not be able to withstand a catastrophic earthquake that can produce forces several times lerger than the code design earthquake forces .Therefore , some believe that it may not have additional capacity possessed by steel rigid frames . But modern research and experience has indicated that concrete frames can be designed to be ductile , when sufficient stirrups and joinery reinforcement are designed in to the frame . Modern buildings codes have specifications for the so-called ductile concrete frames . However , at present , these codes often require excessive reinforcement at certain points in the frame so as to cause congestion and result in construction difficulties 。

建筑设计中英对照表●房屋各部分 Parts of house屋面 roof屋脊 ridge坡屋顶 pitched roof单坡屋顶 pent roof, lean-to roof人字屋顶 gable roof四坡顶 hipped roof屋面排水沟 valley卷材防水屋面 membrane roof找平层 screed-coat防水层 damp-proof course泛水 flashing屋顶层 garret阁楼 penthouse, loft, attic天台 roof-deck晒台 drying stage组合烟囱 chimney stack屋檐 eave屋面排水 roofing drainage檐沟，明沟 gutter水落管 down-pipe, downspout雨棚 canopy, awning柱廊 colonnade走廊 corridor中庭 atrium山墙 gable女儿墙 parapet山花 pediment隅石砌 quoins阳台 balcony, veranda阳台栏杆 balustrade阳台栏杆柱 baluster, banister平台 terrace台阶 steps梯子 ladder梯级 step楼梯 staircase(＝step)楼梯踏步平板 tread楼梯踏步竖板 riser楼梯休息平台 landing直角转弯平台quarter-space landing 梯宽 run of stair梯高 rise of stair楼梯扶手 rail, railing回转梯corkscrew staircase，caracole 踏步突沿 nosing窗子 window百叶窗 blinds, louvers旋转窗 balance window平开窗，窗叶 casement窗扇 sash中旋窗 awning window上下推拉窗double-hung window 屋顶通气窗 clerestory门窗亮子 transom窗框 window frame窗台 sill，cill采光顶 sunroof天窗 sunlight老虎窗 dormer-window通风窗 ventlight落地窗 French window墙壁 wall承重墙 bearing wall隔间 partition空心墙 cavity wall防火隔断(分区) compartmentation剪力墙 shear panel墙裙 wainscot窗间墙 pier幕墙 curtain wall电梯 elevator, lift自动扶梯 escalator地板，楼面 floor夹层楼面 entresol，mezzanine楼座 balcony楼板 slab天花板 ceiling壁炉 andiron，fireplace，grate地下室 basement防火 fire-cut防火门 fire door耐热涂料 heat-resisting paints绝热 heat insulation门槛 head-rail, sill柱子 column，post，pillar柱头 column cap, head斜撑 knee brace悬索 catenary梁 beam基础梁 grade beam钢板梁 plate girder工字梁 I-beam过梁 lintel, lintol, head椽子 purlin基础 foundation碎石垫层 hard core混凝土地基 concrete foundation 基座、柱础 pedestal独立基础 isolated footing放大基础 spreading footing条形基础 strip footing筏式基础 mat foundation浮筏基础 floating foundation 沉箱基础 caisson化粪池 cesspool, septic tank 伸缩缝 expansion joint冷桥 thermal bridge散水 wash, apron披水板 weathering-board桁架 truss组合桁架 composite truss框架 framework模板 formwork拱券 arch穹顶 dome平拱 flat arch筒拱 vault, vaulted roof半圆穹顶 concha瓦 shingle, tile砖 brick瓷砖 ceramic tile玻璃砖 glass blocks大理石 marble花岗岩 granite水磨石 terrazzo砌块 masonry混凝土 concrete预制混凝土 pre-cast concrete钢筋混凝土 reinforced concrete钢筋 steel reinforcement水泥 cement抹灰，灰泥 plaster, stucco熟石灰hydrate of lime, slaked-lime 砂浆 mortar抹灰层 floated coat饰面 finish木砖 grounds, timber brick石膏 gypsum石膏板 plaster slab夹胶玻璃 plyglass胶合板 plywood, clip-board脚手架 scaffolding悬臂 cantilever叠涩，牛腿 corbel遮阳 sun shading●制图与构图用语草图 sketch, draft图纸 drawing施工图 working drawings工程 project方案 plan总图 grid总平面 site平面 floor立面 elevation正立面 facade剖面 section详图 detail门厅上部 upper foyer比例尺 scale=透视图，表现图 rendering透视 perspective轴测isometric perspectiveAxonometric projection轴线 axis建筑面积 floor area, architecture area 相对标高 relative elevation/level层高，净空 headroom, headway室内 interior室外 exterior室内装修 interior decoration装饰 ornament广场 square, plaza, public square流线 circulation解构 deconstruction空间 space, spatial比例 proportion统一 unity均衡 balance协调 harmony尺度 scale韵律 rhythm风格 style功能 function关系 relationship●房屋House高层建筑high-rise building社区housing complex家舍house茅舍cottage平房one-story house，bungalow，plain-house二楼two-story house公寓(建筑) apartment house公寓(房间) apartment(flat)(英)别墅villa花园洋房garden house寄宿舍dormitory(美)供膳出租房间board and lodging出租房间room for rent(美)乡村旅舍country inn供膳寄宿舍boardinghouse大厦mansions, edifice大楼building预制装配式房屋 pre-fabricate house 小木屋 shack一个单元 one unit车库 garage报告厅auditorium, lecture hall多功能厅multi-use hall阅览室 browsing room, reading room 茶室refreshment room操作间cab, utility room●居住Dwelling套房 suit主人套房 master suit门厅，前厅 lobby大厅 hall, main hall过厅 gallery起居间 living RM，family RM聚会厅gathering RM，keeping RM休息厅 lounge, sitting RM客厅 parlor衣帽间 cloakroom更衣、衣橱间 walk-in-closet, W.I.C.厨房 kitchen餐厅 dinning room早餐厅 nook, breakfast room食品、餐具间 pantry, butlery浴室，洗手间 bathroom盥洗室 toilet room卫生间 water closet, W.C.前室，门厅 foyer寝室，卧房 bedroom主人房 master bedroom书斋，书房 study, library工作室，画室 studio私室，书斋 den化妆室 boudoir, dressing RM, powder RM 婴儿室 nursery客房 guestroom壁厨 closet, ambry洗衣间 laundry room地窖 cellar储藏室 storage健身房 exercise RM服务入口 service entry换鞋处 mud room游艺室 games room活动室 activities room音乐室 music alcove工人房 maid bedroom台球室 billiards room温室 greenhouse●家具Furniture方桌 square table圆桌 round table长方桌 rectangle table伸缩桌 extension table小桌 side table凳子 stool有肘的椅子 armchair摇椅，安乐椅 rocking chair藤椅 rattan chair塑料椅 plastic chair帆布椅 deck chair折椅 folding chair沙发 sofa长椅 couch桌子，餐桌 table玻璃桌子 glass table塑料桌子 acrylic table木制饭桌 wooden-table●庭院Yard家宅院 messuage门廊 porch, covered porch敞廊 loggia前院 front yard(美)；forecourt 中院(英) court yard后院 back-yard(美)侧院 quiet yard小庭院 garth天井 patio, patios, hypaethral 花园 garden树篱 hedge围场 enclosure花架 arbor bower草坪 lawn花坛 flowerbed灌木 bush, brush撒水器 sprinkler假山 rockery亭子，阁楼 pavillion小径 path车道 driveway游泳池 pool围墙 fence●前门Front door会发谐音钟声的门door chime 警报器 buzzer门铃 doorbell门环 doorknocker窥孔 peephole门把 knob门柱 doorjamb锁眼 keyhole转门 swinging door折门 fold-away (accordion) door●冷暖气Cooling and heating电风扇electric fan煤气暖炉gas heater (stove)石油暖炉kerosene heater(=stove) 电暖炉electric heater(=stove)暖气片panel heating散热器radiator冷气机air cooler空调机air-conditioner中央暖气central heating(system) 局部暖气space heating●几何名词直线 line曲线 curve圆弧 arc圆 circle椭圆 ellipse三角形 triangle正方形 square矩形 rectangle多边形 polygon螺旋线 spiral平行六面体parallelepiped球体 sphere半球 hemisphere●相关专业名称结构structure电气electric work给排水plumbing暖通HVAC,Heating/Ventilation/Air Condition 城市规划city planning●其他GRC玻璃纤维增强复合材料(Glass-fiber Reinforced Composite) PVC聚氯乙烯建构tectonic风格style古典主义Classicalism哥特复兴式Gothic Revival巴洛克风格Baroque洛可可Rococo文艺复兴Renaissance帕拉迪奥风格Palladian新艺术运动Art Nouveau理性主义Rationalism折衷主义Eclecticism粗野主义Brutalism风格主义Mannerism构成主义Constructivism国际主义风格International Style 功能主义Functionalism表现主义Expressionism现代主义Modernism新古典主义Neo-Classicism可持续建筑 Sustainable Architecture。