外墙装饰工程设计总说明

外墙面做法说明一、适用范围适用于一般民用与工业建筑外墙面装修工程中的：1、外墙面抹灰工程2、饰面砖工程3、外墙涂饰工程4、外墙外保温工程二、设计依据1、《民用建筑热工设计规范》GB 50176-932、《公共建筑节能设计标准》DBJ14-036-20063、《居住建筑节能设计标准》DBJ14-037-20064、《既有采暖居住节能改造技术规程》JGJ 129-20005、《外墙外保温工程技术规程》JGJ 144-20046、《建筑装饰装修工程质量验收规范》 GB 50210-20017、《建筑工程施工质量验收统一标准》GB 50300-20018、《外墙饰面砖工程施工及验收规范》JGJ 126-20009、《砌体工程施工及验收规范》GB 50203-200210、《混凝土结构工程施工质量验收规范》GB 50204-2002三、基层墙体1、本图集做法中砖墙包括：煤矸石砖、黄河淤泥砖、烧结多孔砖、灰砂砖、蒸压粉煤灰砖等。

2、本图集做法中加气混凝土砌块墙包括：加气混凝土砌块、加气硅酸盐砌块等。

3、混凝土墙、混凝土小型空心砌块墙。

4、大模板混凝土墙。

其他新型墙体可参照使用，使用时根据不同的基层墙体确定合理的固定方法，对于不宜使用射钉固定的墙体，可改用其他有效的锚固方法（如塑料锚栓锚固、预埋锚筋、锚件等）。

四、设计施工要求1、抹灰工程（1）抹灰工程抹灰总厚度大于等于35ｍｍ时应有加强措施。

（2）抹灰工程不同材料基体交接处应有加强措施。

（3）外墙的抹灰曾与基层之间必须粘结牢固。

2、饰面砖工程（1）外墙外保温饰面砖厚度不宜超过6厚，面砖宜采用柔性砂浆勾缝，且厚度应比面砖厚度薄2～3ｍｍ。

（2）高层建筑外墙外保温体系做面砖饰面时，面砖重量应小于等于20㎏/㎡，且面积小于等于10000㎜2/块。

3，外墙涂饰工程外墙涂饰材料应选用弹性外墙涂料，涂饰前应刷抗碱封闭底漆。

其颜色、品种由设计人员定，并在施工图中说明。

4、外墙外保温材料浅析规则式植物造景和自然式植物造景苏旺指导老师：汪小飞（黄山学院生命与环境科学学院，安徽黄山245041）摘要：本文分析了规则式植物造景和自然式植物造景，和他们各自的造景特色和主要适用在什么场合。

室外工程方案设计说明一、项目背景及概况本项目为某大型商业综合体的室外工程项目，位于城市中心繁华商业区，总建筑面积约80,000平方米，包括商业街区、停车场、休闲广场等多个功能区域。

项目建设将采用现代化工程技术，以提高商业综合体的形象和功能，提升商业区形象，增加城市绿化率和生态环境。

二、设计目标1.美观、实用：根据项目特点和功能需求，设计出持久耐用的室外工程设施，具有现代感、时尚感，同时满足商业综合体的实际运营需求。

2.绿化：在城市商业综合体中，增加绿化面积，提供良好的环境和氛围，营造舒适的购物、游玩环境。

3.安全：室外工程设施应考虑到人员进出、安全疏散、消防通道等因素，确保顾客和员工的安全。

4.可持续发展：在设计过程中，考虑室外工程的可持续性，包括材料的选择、能源利用、节能减排等方面。

三、设计内容1.商业街区设计商业街区是商业综合体的核心区域，主要包括餐饮区、购物区、娱乐区等。

在商业街区的设计中，我们将采用大面积的透明玻璃橱窗和户外露天座椅，以及水景、景观灯等元素，营造出时尚、温馨的购物环境。

同时，在商业街区的地面铺装上，我们将采用防滑、易清洁、易维护的材料，确保顾客的安全和舒适。

2.停车场设计商业综合体的停车场设计将采用现代化的自动化智能系统，提供方便、快捷的停车服务。

同时，我们将在停车场周围设置绿化带和休闲座椅，增加停车场的舒适度和美感。

3.休闲广场设计休闲广场是商业综合体的公共休闲区域，主要包括绿化带、雕塑、喷泉、步行道等。

在设计中，我们将注重绿化带的规划和植物的选择，以及照明和景观水系的设计，打造出一个宜人、宁静的休闲环境。

4.照明设计在室外工程中，照明设计是十分重要的一环。

我们将充分考虑到建筑物外立面和景观照明的设计，通过照明方案营造出室外空间的氛围和美感。

5.周边环境改善在设计过程中，我们还将考虑到商业综合体周边环境的改善，包括道路修复、绿化提升、交通设施升级等。

四、设计原则1.符合城市规划和环保要求在设计过程中，我们将严格遵守城市规划和环保要求，合理合法地规划和建设室外工程设施，保证项目的合法性和环保性。

工程技术说明4.1墙体工程4.1.1 本工程墙体工程设计执行《烧结空心砖和空心砌块》GB/T13545-2014，《烧结多孔砖和多孔砌块》GB13544-2011，《建筑外墙防水工程技术规程》JGJ/T235-2011，《建筑防火封堵应用技术规程》CESC154-2003，《重庆市房屋建筑和市政基础设施工程质量常见问题防治要点（2019年版）》4.1.2 建筑外墙、内隔墙的材料性能指标、构造措施（除图说注明外）详西南18J112。

墙体的基础和钢筋混凝土墙、梁（含门窗过梁）、柱详见结施,与节能有关的外墙及内墙填充墙材料详节能专篇；在施工过程中应做好隐蔽工程的记录与验收；4.1.34.1.4 排，孔洞率≥45%，干密度801~900kg/m³，强度等级≥MU5.0；有锚固要求的外墙外保温工程墙体，和有挂装要求的部位，需选用外壁厚≥25mm的厚壁型烧结页岩空心砖，页岩多孔砖容重{1400kg/m3、导热系数0.58 [W/(m.k)]}。

4.1.5 洞口宽度大于300mm时应采用钢筋混凝土过梁；门窗洞两端固定点一砖范围内墙体（除设有钢筋混凝土构造柱或边框外），应采用砌筑200宽（或同墙厚）烧结实心砖或预制混凝土块补齐；墙垛宽度未特殊注明处,均为100mm宽; 门，窗洞边距框架柱，构造柱或墙小于200mm时，应设置现浇混凝土门、窗垛，且应按设计配置构造钢筋，不低于以下要求：内配 2∅10竖筋,∅6.5@200水平S型拉钩，竖筋锚入上下梁板内,墙体的拉墙筋锚入门窗洞C20细石混凝土，并植筋铆入剪力墙或结构柱中。

电井和水井的门洞下方浇筑300高C20细石混凝土门槛（完成面起算）。

4.1.6 窗洞下口应浇筑宽度与墙厚相同，高度不小于60mm，长度每边伸入墙内不少于200mm的混凝土压项，内配不小于2Φ8主筋和Φ6@250的分布筋，混凝土强度不低于C20，另设置水平S型拉钩。

4.1.7 转角及交接处应同时砌筑，不宜留直槎。

外墙装修工程施工方案一、项目背景外墙装修工程是指对建筑外墙进行装饰和保护处理，以提升建筑物外观美观度和耐久性。

本施工方案针对某项目的外墙装修需求进行详细规划，确保施工质量和进度符合相关标准和要求。

二、施工目标1. 提供外墙装修设计方案，满足建筑外观美观、保护墙体的需求；2. 确保施工过程安全、高效，并达到预期的质量标准；3. 保护施工现场周边环境，最大限度减少施工对周边居民生活的影响。

三、装修材料选用1. 外墙涂料：选用环保型防水、防雨、耐候性强的外墙涂料，确保装饰效果和墙体保护功能；2. 隔热材料：选用导热系数低、隔音性能好、节能效果明显的隔热材料，提高建筑的保温性能；3. 装饰饰面材料：根据设计要求，选用耐候性好、外观效果出色的装饰饰面材料，保证装修效果优良。

四、施工步骤1. 施工准备：(1) 成立专业的施工团队，确保施工人员熟悉相关工艺和操作规范；(2) 准备所需材料和施工设备；(3) 制定详细的施工计划和时间表。

2. 表面处理：(1) 对建筑物外墙进行清洁处理，确保墙面平整、无明显泥浆、灰尘、油污等杂质；(2) 检查墙面是否有裂缝、松动等问题，及时予以修复。

3. 隔热层施工：(1) 根据设计方案，施工隔热层，确保隔热材料覆盖全面、整齐平坦；(2) 做好隔热层的防潮处理，以保证隔热层的使用寿命。

4. 外墙保温处理：(1) 在隔热层上进行保温处理，确保保温材料完整、紧密，无渗漏；(2) 根据设计要求，进行外墙外保温层的涂料及饰面处理。

5. 装饰层施工：(1) 根据设计方案，进行装饰层的处理，包括涂料、贴砖、贴石材等；(2) 确保各种装饰材料的平整、美观。

6. 玻璃、铝塑板施工：(1) 安装玻璃、铝塑板等装饰材料，确保安装牢固、无破损；(2) 做好密封处理，防止渗漏。

五、施工质量控制1. 施工前，通过对墙面进行检测，确定外墙装修的可行性和施工步骤；2. 按照相关标准和规范进行施工，确保每个施工环节的合理性和适用性；3. 进行中间验收，及时发现和修复施工中的问题，保障施工质量；4. 完工后进行最终验收，确保装修效果和质量符合预期和要求。

川海大夏外墙装饰工程施工组织设计日期：2016年12月26日目录第一节编制说明 (1)一、编制依据 0第二节工程概况 (1)一、工程概况 (1)第三节施工准备 (2)一、施工技术准备 (2)二、施工现场准备 (3)三、施工机具、材料准备 (4)四、施工组织和劳动力准备 (5)第四节施工工艺及要求 (5)一、施工前成品保护 (5)二、铝合金门窗、百叶窗施工工艺 (6)三、玻璃幕墙工程施工工艺 (12)四、干挂石材幕墙施工工艺 (17)五、雨篷工程施工工艺 (20)第六节工期及进度保证措施 (25)第七节安全文明施工保证措施 (26)一、安全施工措施 (26)二、文明施工措施 (27)第一节编制说明一、编制依据1、依据国家、地方、行业相关标准规范编制，如当地政府有比本标准更高的要求时，按照当地政府规定执行。

2、施工图中所引用的国家或行业标准一旦有更新时，施工单位有义务了解规范标准的更新和按照相应的标准执行。

甲方提供的“川海大夏节能专项设计说明”、《川海大夏外墙装饰工程施工》、工程技术标准。

3、施工中应严格遵循下列有关规范、规程、规定执行：(1)中华人民共和国颁发的《建筑工程施工质量验收统一标准》；(GB50300-2221)(2)中华人民共和国颁发的《建筑安装工人安全技术操作规程》、《施工现场临时用电安全技术规范》；(JGJ33-2001)（JGJ46-88）(3)铝合金门（GB/T8478-2010)(4)装饰工程施工及验收规范（GB50210-2001）；(5)建筑玻璃应用技术规程（JGPJ113-97）；(6)电气工程施工及验收规范（GB50303-2002）(7)建筑幕墙工程技术规范（JCJ102-2010）(8)铝合金窗（GB/T8479-2010)(9)建筑筑工高处作业安全技术规范（JGJ80)(10)建筑玻璃应用技术规范（JFJ113-97)第二节工程概况一、工程概况建设单位：广西川海房地产开发有限公司工程名称：川海大夏外墙装饰工程计划施工日期：30日历天施工单位：广西德键建筑工程有限公司施工范围：外立面围护门、窗、玻璃幕墙、百叶窗（防火门除外）、外墙面石材、构造线条、窗套、裙楼部位的雨篷、不锈钢门，具体参数、数量、节点大样见施工图。

外墙装饰工程设计总说明一、工程概述1.1、项目名称：1.2、建设单位：1.3、主体结构形式：钢筋混凝剪力墙结构1.4、建筑高度：16.7 M1.5、地面粗糙度类型：c类1.6、建筑物耐火等级：一级1.7、抗震设防烈度： 7度1.8、幕墙安全等级为：二级1.9、幕墙设计使用年限：25年本分包幕墙工程主要包括以下几大项目：1、铝板幕墙； .2、点式玻璃雨蓬3、铝门窗：4、石材幕墙二、设计依据2.1、业主认可的方案设计图纸2.2、设计过程中业主提供的有关其它要求2.3、设计、施工、检测规范：a.建筑设计类：b.结构设计类d.钢材类1、基本风压：0.55 kN/㎡2、场地类别： B 类3、抗震设防烈度：抗震设计按地震设防烈度7度计算地震作用，地震加速度0.16g。

4、耐火等级：一级5、耐久年限：50年以上6、年温度变化：80度7、后置化学锚栓拉拔力最大设计值2.83KN，现场检测拉拔力不小于6KN。

8、本工程均为三级焊缝，焊缝高度不小于较薄母板厚度。

三、主要幕墙的节点构造设计1.石材幕墙本工程大部分幕墙为石材幕墙形式，龙骨采用镀锌钢龙骨支撑体系，石材面板采用上下开短槽形式不锈钢挂件对结构体系，立柱采用60x80x4的镀锌钢方通；横梁采用50x50x5的镀锌角钢；面材采用25mm厚细花岗石，花岗岩板材的弯曲强度应经法定监测机构监测确定，其弯曲强度不应小于8.0Mpa，颜色根据建筑师和业主封样确定；板块间的缝隙宽度为6mm，采用密封性能可靠的现场湿密封系统，密封胶必须为石材专业密封胶。

主要特点：1.立柱与主体结构之间采用螺栓连接，通过三维调整消除主体结构施工误差的不利影响；2.采用镀锌方钢作为立柱，采用镀锌角钢作为横梁，不仅惯性矩大，抗变形能力强，而且采购方便、成本较低，施工也很方便；2. 点式玻璃雨篷系统A、系统形式：点式雨篷系统B、龙骨：变截面工字钢，表面氟碳喷涂C、面材：8(10)+1.52pvb+8mm钢化夹胶玻璃系统设计理念：3.本雨蓬点爪式玻璃采用钢架支撑的点驳接爪系统，坚固耐用，安全美观。

施工设计总说明范文一、设计目标：本施工设计旨在满足工程建设的需要，保证工程施工质量，确保工程安全及工期要求，实现设计师的设计构想，以及满足业主的要求。

同时，本设计着重考虑了施工的可行性，提出了合理的施工方案，确保施工过程中的高效性和经济性。

二、施工工艺：1.基坑开挖：根据地质勘察信息和设计要求，确定开挖深度和坑底标高，采用机械开挖方式进行基坑开挖。

对于土方回填均采用半干法。

2.地基处理：采用加固桩法处理地基，提高地基的承载力。

地基加固中采用的桩基类型为灌注桩，通过与混凝土柱体相连形成整体结构。

3.主体结构施工：主体结构采用钢筋混凝土结构，墙体框架采用剪力墙加配肋压拱形成的强度和刚度较高的体系。

梁柱采用预制构件，通过现场拼装加固。

4.外墙砌筑：外墙砌筑采用烧结砖，采用钢筋砌筑支模，解决了垂直度和墙面表面平整度问题。

外墙砌筑前，先进行墙面防潮层施工。

5.室内装饰：室内装饰以实现舒适、美观、环保、功能合理为设计原则，采用石膏板或装饰板进行墙面和天花板装饰，采用地板砖或地毯进行地面装饰，采用木质材料进行家具和橱柜的制作。

6.排水系统：建筑物排水采用下水道系统，将所有排水通过下水道连接到市政污水处理设施，确保排水的畅通。

7.电气系统：电气系统采用中央供电方式，配备灯具、插座和开关等电气设备。

电线采用火线与零线间距离要符合国家电气安全标准。

三、安全技术措施：1.建立安全责任制度，制定施工安全技术措施，加强对施工作业人员的安全教育和培训，提高安全意识。

2.建立安全监控系统，对施工现场进行24小时全天候监控，实时了解施工现场安全情况，并及时采取措施防止事故发生。

3.使用符合国家标准和产品质量认证的建筑材料，确保施工质量和安全。

4.合理布置施工现场，设立警示标志和安全防护设施，保障工人的人身安全。

5.在施工现场设置消防设施，防止火灾和其他安全事故的发生。

四、工程预算：工程预算根据设计要求和施工工艺确定，包括施工材料费、施工人工费、机械使用费等。

august 2012 MODERN STEEL CONSTRUCTIONSLab EDgE DETaILS whERE the structural frame of the building meets the architectural skin can be cumbersome and complex. But they don’t have to be!The design and detailing of the structural components around the slab edge to support the façade can have a tremen-dous impact on the overall cost of the project, as well as the façade’s functionality. There are many factors to consider when developing a design strategy to accommodate the façade loads, including the type of façade, its location relative to the struc-tural frame, the length of cantilever of the slab past the spandrel beam, the strength of the slab and metal deck and the orienta-tion of the metal deck and adjacent framing.AISC Steel Design Guide 22, Façade Attachments to Steel Framed Structures , available on /epubs , gives the practicing engineer guidelines to address these issues. This article draws from the design guide to provide tips and consid-erations on how to detail slab edges for supporting façade loads in an efficient and economical manner.Loads and Forces Let’s first examine the loads and forces that are involved. The gravity load on the façade generally consists of solely the dead self-weight of the façade panel. Most façades carry no ver-tical live load, but it’s important to recognize when there are flat areas that project from the structure and provide working space for building maintenance and window washers. In these cases, live, rain and/or snow loads must also be considered. The center of gravity of the façade elements is almost always offset some distance from the centerline of the support locations on the steel frame. This eccentricity between the center of gravity of the façade panel and the support loca-tions on the steel frame produces a moment that usually is resolved with a horizontal force couple from the top and bot-tom attachments (as shown in Figure 1). The top attachment may be in tension from the gravity loads due to resolving the eccentricity, and often, negative wind pressures combined with this horizontal force couple will be critical in the design of the façade attachment.Often, the weights of the façade panels are supported on the slab edge. The slab edge details must transmit these forces and moments into the structural frame without exceeding deflec-tion, tolerance and clearance limits. Conceptually, there are two methods to transfer the forces from the slab edge and into the structural frame:Method 1 – The slab and metal deck act as a cantilever to resist the façade loads. In this approach, the strength and stiffness of the slab and metal deck resist the shear and moment, essentially treating it like a cantilevered beam to support the façade loads. This method is economical when the typical slab and metal deck are adequate or can easily be reinforced to take the additional facade loads. (See Figure 2, p. 18, for free body diagrams of the structural components involved in this method.) If, however, the thickness of the slab must be increased to accommodate the façade loads, this may diminish the cost effectiveness of this method.The façade panel loads may be transferred into theslab by direct bearing on theslab or by attachment to steelembedments or bent platesthat also serve as pour stops. If a bent plate pour stop is used, a steel headed stud anchor or deformed bar anchor is often welded to the pour stop at the end of the slab, which engages the concrete reinforcement and transfers the forces into the slab. The stud or bar attachment cannot be shop-welded when it projects over the spandrel beam, as this would violate OSHA requirements that prohibit tripping hazards.DETaILS FROM ThE EDgEBy Jie ZuosteelwiseConsiderations for detailing the slab edge and designing façade attachments.Fig. 1: Horizontal force couple due to eccentricity.➤Resolving the eccentricity of the façade load location and the spandrel beam support with the slab and metal deck as a cantilever eliminates the need to design the spandrel beam for torsion or brace it against twist. However, the façade load induces negative moment in the slab as it passes over the span-drel, which may require additional flexural reinforcement in the top of the slab in that area.Method 2 – A bent plate or other steel assembly is used as a means to transfer the loads to the spandrel. This approach has a load path that bypasses the slab and metal deck; it relies on the strength and stiffness of an attached bent plate, angle or other structural steel assembly to transfer the loads directly into the spandrel (as seen in Figure 3). This method generally is used in cases where the slab and metal deck are inadequate to resist the façade loads. Examples of such scenarios include a long, over-hanging slab that produces a large moment or when there is a slab opening in the back-span that limits its capacity. Due to the eccentricity of the façade load, the spandrel must resist the induced torsion or be braced against it.Concrete Slab and Metal DeckThe concrete slab cantilever can be designed according to ACI 318 and there exist design tables in AISC Steel Design Guide 22 for flexural strength and slab geometries. When the slab and metal deck act as a cantilever to support the façade (Method 1), the façade should transfer its loads to the slab through direct bearing. T o determine the effective slab width, a conservative approach is to take the effective width equal to the width of the concentrated load plus twice the distance to the line of bending in the slab (as shown in Figure 4, p. 20).➤Fig. 2: Design concept of Method 1, where the slab is utilized to resolve eccentricity of façade panel loads.➤Fig. 3: Design concept of Method 2, where the spandrel is used to resolve eccentricity of façade panel loads.MODERN STEEL CONSTRUCTION august 2012MODERN STEEL CONSTRUCTION august 2012The orientation of the flutes of the metal deck also may affect the effective width and effective depth of the slab. When the flutes are oriented parallel to the spandrel beam, the effec-tive depth is taken at the location where the depth is reduced at the flute; the effective width is unaffected. If the flutes are oriented perpendicular, the full slab depth is effective but the effective width must be reduced to account for the area of con-crete not present in the compression zone. The design guide also addresses other forces that slab and deck must also be able to resist, including forces from kickers or roll (back-up) beams, when used, and the horizontal force couple due to eccentricity.Spandrel beam In the case of Method 2, the eccentricity of the façade load induces torsion on the spandrel beam. Wide flange sections make great flexural members, but offer little torsional resis-tance and often require bracing against twist. If the spandrel Fig. 4: effective widthfor concentrated loadsat slab edge.beam is a girder with in-fill beams framing to it, the secondary framing may provide adequate restraint against twist. If there is no secondary framing, however, the spandrel must have suf-ficient torsional strength and stiffness or additional restraint must be provided.One common solution is to add intermittent perpendicu-lar kickers or bracing angles between the bottom flange of the spandrel and the top flange of the first interior beam (as shown in Figure 5). It can also be an anchored connection in the slab. Another common solution is to include additional framing per-pendicular to the spandrel, referred to as “roll beams” (shown in Figure 6, p. 22). The connections on roll beams must bedesigned with enough moment resistance to sustain the tor-sional shear. The presence of a kicker or roll beam results in vertical and horizontal reactions in the spandrel, and the hori-zontal force couple between the top and bottom flanges resolves the twisting force.➤Fig. 5: a kicker brace can be used to resolve the torsion in the spandrel.➤Light-gauge Metal Pour StopOne economical slab edge detail incorporates a light-gauge metal pour stop. T ypically used in Method 1 and made of cold-formed steel of 10- to 20-gauge thickness with a yield strength of 33 ksi, its sole purpose is to form the edge of the slab. It is an item that usually comes with the metal deck procurement package and is welded to the spandrel during erection of the metal deck. The Steel Deck Institute provides a design table for light-gage metal pour stops to support the weight of wet concrete, concrete pore water pressure on the vertical leg and a uniform construction live load of 20 psf; this table is also printed in AISC Steel Design Guide 22.SDI recommends that the designer limit the design flexural stress to 20 ksi for the wet concrete load, temporarily increased by one-third for the construction live load. The table provides designs for an overhang length of up to 12 in. It is also recommended that the horizontal and vertical deflection should be limited to a maxi-mum of 1/4 in. for concrete dead load. (The design approach of the light-gauge metal pour stop is detailed in Figure 7.)These pour stops are generally not strong enough to be expected to carry any of the façade loads. Use of this type of detail is limited to the slab being able to resist all of the superimposed loads, including the façade. Overlap between the spandrel flange and the pour stop is commonly specified as 2 in.Fig. 6: a roll beam can also be used to brace thespandrel against twist.➤Fig. 7: Design considerations for a light-gauge metal pour stop.➤MODERN STEEL CONSTRUCTION august 2012bent PlateInstead of a light-gauge metal pour stop, a bent plate, angle or other steel assembly can be used. Bent plates are stronger and have more versatility than light-gauge metal pour stops. A bent plate can be designed to act as a pour stop, and also as a transfer element to provide a load path between the façade attachment and the slab, or between the façade attachment and the spandrel beam.Designers might choose to use a bent plate in lieu of a light-gauge metal pour stop for several reasons, including:The cantilever slab overhang is too large to be sup-1.ported by a light-gage metal pour stop.T o transmit the façade forces into the slab by attaching2.it to the façade and welding a headed stud on the verti-cal leg (Method 1).The slab and metal deck are inadequate in strength 3.or stiffness to support the façade, so the bent plate isused as a means to transfer the forces into the spandrel(Method 2).Note that as thickness increases, practical lengths of the bent plate get shorter. Hot-rolled angles do not have this length lim-itation and have tighter tolerances, but required thicknesses andleg sizes are not always readily available. Minimum and maxi-mum thicknesses of bent plates are generally x in. and 1/2 in., respectively, limited by the bending equipment capacity. They can be shop- or field-welded or bolted, though shop attachment requires that field adjustment must be provided for in another way. AISC Steel Design Guide 22 contains design tables for bent plates up to an overhang length of 18 in.Steel Design Guide 22 is a good resource when designing and detailing the slab edge to sufficiently transmit the façade loads into the structural frame. There are many solutions, but the keyis to develop one that is economical and efficient. Also, refer tothe MSC SteelWise column in December 2007, titled “Pushingthe Envelope,” and AISC’s webinar on façade attachments at /elearning.steelwiseaugust 2012MODERN STEEL CONSTRUCTION。