Autodesk.Inventor.Professional.11简体中文版安装说明

Autodesk Inventor Professional 初级培训课程描述本课程可以使机械设计工程师初步掌握Autodesk 三维机械设计软件inventor 的使用,使用该产品进行设计，实现缩短设计周期、更快速地将高质量的产品投入市场的冃的。

还可 以充分利用设计数据，与延伸设计团队进行有效的协同作业。

培训时间：2天8小时/天课程目标学员通过培训后，可以初步掌握Inventor 三维设计软件，并能运用Inventor 进行机械设 计。

参加人员 基本要求掌握工程制图与机械设计基础知识会使丿 IJ Microsoft® Windows 操作系统 培训内容 一、熟悉 Autodesk Inventor1. 零件建模过程介绍2. 熟悉用八界面3. Autodesk Inventor 设计支持系统介绍 二、 创建草图1. 学习草图命令和环境，然后练习创建草图2. 学习如何约束草图以及应用、查看和删除约束3. 学习草图中的尺寸4. 编辑草图 三、 创建定位特征1. 定位特征介绍2. 创建工作平面3. 创建工作轴4. 创建工作点 四、 创建零件特征1. 创建拉仲和旋转特征2. 创建加强筋3. 创建放样、扫掠特征4. 分割特征 五、 创建部件模型1. 装入零部件2. 创建在位零部件3. 使用装配约朿约朿冬部件 六、 创建工程图技术工程师等 机械设计工程师,1.定义图纸、图框、标题栏2.修改视图、图纸和标题栏的设置3.创建投影视图、斜视图、剖视图、局部视图和打断视图4.用文字和尺寸注释工程图七、创建表达视图Autodesk Inventor 中级培训课程描述木课程可以使机械设计工程师全面掌握Autodesk三维机械设计软件——Inventor,使用该产品进行产品设计，可实现缩短设计周期、更快速地将高质量的产品投入市场的目的。

还可以充分利用设计数据，少延伸设计团队进行有效的协同作业。

培训时间：1天8小时/天课程目标学员通过培训后，可以全面掌握Inventor三维设计软件，并能运用Inventor完成机械设计任务，满足实际工作需要.参加人员机械设计工程师，技术工程师等基本要求掌握工程制图与机械设计基础知识掌握Inventor基本应用技巧会使用Microsoft® Windows操作系统培训内容一、参数的运用1.使用参数和等式表达零件特征，定义装配约束2.将模型中参数值与Microsoft Excel电了表格相关联二、衍丰零部件1.衍生零件的用途2.由零件创建衍生零件3.由部件创建衍生零件4.断开衍住零件与源零部件的链接5.更新衍生零件三、iPart、iAssemblv、iFeature 的仓ij1.创建iPart （零件系列化）2.创建iAssembly （不见系列化）3.创建iFeature四、iMatc的运用五、自适应零件1.学习自适应特征、零件和子部件2.将零件特征设为自适应3.使用参考草图创建自适应零件4.通过添加装配约束，修改部件和子部件屮的自适应零件的人小六、设计视图的创建七、资源中心库的使用与创建八、Inventor Studio（渲染）的运用Autodesk Inventor Professional 高级培训课程描述木课程主要内容针对Autodesk Inventor Professional的用户，包扌舌"设计加速器”"布线设计” “运动仿真” “管路设计”四个模块。

AUTODESK INVENTOR Trial ProjectsDesign AutomationDesign a conveyor assemblyIn Inventor, click the ‘Projects’ icon in the ribbon. Navigate to where you saved the project files and select Assembly Convey-or DA.ipj . Then open Assembly Conveyor DA.iam .Access the ‘Design’ tab in the ribbon and click ‘Bolted Connec-tion’, located in the ‘Fasten’ panel.Select ‘Concentric’ from the drop-down for the ‘Placement’.Select the face shown for the ‘Start Plane’.2.4.1.3.Select a ‘Circular’ reference on the yellow bracket for the loca-tion.Choose the back face of the yellow bracket for the fastener ‘Termination’.Define the ‘Thread ‘using an ‘ANSI Metric M Profile’, and then set the ‘Diameter’ to 5mm.Select ‘Click to add a fastener’ in the dialog to select a‘Standard’ and ‘Category’.6.8.5. 7.Filter to ‘ANSI, Socket Head Bolts’, and select the ‘Forged Socket Head Cap Screw - Metric option’.Select ‘Click to add a fastener’ below the screw you just insert-ed, and then insert the ‘Plain Washer (Metric)’ component.Drag the arrow at the end of the fastener preview to define the correct length. Click ‘OK’ on the dialog to create the bolted connection.Click ‘OK’ again the accept the default ‘File Naming’ for the newsubassembly.10.12.9.11.Right-click on the new bolt subassembly and select ‘Copy’ from the marking menu.Right-click in empty space and select ‘Paste’ to insert another in-stance of the component. Note that it’s listed as a subassembly within the feature tree, and not as an original bolted connection.Selecting ‘Constraint’ from the marking menu, create a ‘Mate’ between the front face of the bracket and this face on the washer.Create another ‘Mate’ constrain between the centerline of thescrew and the centerline of the remaining hole.14.16.13.15.Right-click on the original bolt and select ‘Edit’ using ‘DesignAccelerator’.Click to add a fastener beneath the existing washer listing.Insert an instance of the ‘ASME B 18.21.2M’ lock washer to the stack, and then drag it in between the two existing components in the list.Click ‘OK’ to apply the change, and notice how the copiedsubassembly updates to reflect the change as well. 18.20.17.19.Activate the ‘Pattern’ command from the ‘Assemble’ tab in the ribbon. Select both of the bolt subassemblies for the compo-nents to pattern.From the rectangular pattern tab in the dialog, select an edge along the X axis to define the first pattern direction.Choose ‘Measure’ for the distance option, and then select the faces shown. Click ‘OK’ to apply the pattern.Access the ‘Design’ tab in the ribbon and click‘Bolted Connection’ again.22.24.21.23.Define the ‘Placement’ as ‘By hole’.Select the front face of the blue bracket for the ‘Start Plane’,and then click on one of the holes at the bottom of the bracketfor the location.Select the face on the opposite side of the mount for the ‘Termination’ definition.Select ‘Click to add a fastener’ in the dialog.26.28.25.27.Filter to ‘ANSI, Socket Head Bolts’, and select the‘Forged Socket Head Cap Screw - Metric’ option again.Click to add a fastener below the screw, inserting a ‘Plain Washer (metric)’.Add a third fastener to the list, choosing the ‘ASME B18.21.2M’ lock washer, and then drag it in between the screw and plain washer in the list.Select ‘Click to add a fastener’ below the ‘Selected Hole’ listing,and then choose the ‘Hex Nut Metric’ component within the‘ANSI, Nuts’ category.30.32.29.31.Adjust the cap screw length to 30mm.Check ‘Follow pattern’ in the dialog.Click ‘OK’ twice to place an instance at each hole in the pattern, and to accept the default ‘File Naming’. Save your progress to continue.Continue using ‘Design Automation’ to create a shaft connect-ing the motor and the drive pully.34.36.33.35.Activate the ‘Shaft’ command, located in the ‘Power Transmission’ panel on the ‘Design’ tab.Click the eraser icon at the upper-right of the ‘Shaft Compo-nent Generator’ dialog to reset the calculation data, and then click ‘OK’.Zoom into the drive portion of the motor and select the inner cylindrical face for the first ‘Placement’ definition.Select the back face of the drive motor pully for the shaft’s‘Start plane’ definition.38.40.37.39.Select the outer face of the motor cover for the shaft’s orientation definition.If required, use the flip direction button to ensure the shaft is oriented correctly.Double-click an arrow glyph for the first shaft section to enter a specific value of 8mm.Double-click the listing in the dialog to edit the section length.42.44.41.43.Enter a length of 30mm and click ‘OK’.Define the second edge of the shaft section as having‘No feature’.Double-click the next section in the list to edit it, setting a di-ameter of 10mm and a length of 23mm. Keep the default edge definitions as well.Change the section type for the third listing to ‘Cylinder’ andselect ‘Yes’ to confirm.46.48.45.47.Adjust the third section’s diameter, making it 12mm.Drag the arrow glyph to set the length of this section at 48mm.Define a ‘Chamfer’ for the second edge of the section, using the values shown.For the last shaft section, drag both the diameter and length to10mm.50.52.49.51.Define a ‘Chamfer’ for the second edge of the section, using a ‘Distance of 0.5mm’ and an ‘Angle of 45deg’.Access the section features drop-down for the third shaft sec-tion, and then select ‘Add Wrench’ to add some flat spots for the pully key onto.Define the feature at 26mm long and 11mm deep.Click ‘Add Wrench’ again to define a second feature with the same dimensions.54.56.53.55.Drag the blue arrow in the graphics area to rotate the second feature 90deg about the shaft. Click ‘OK’ twice to create the shaft and accept the default ‘File Naming’.Double-click on the shaft to view it clearly, and to confirm itwas created as intended. Save all of your files to finish. 58.57.Autodesk, Autodesk Inventor, and the Autodesk logo are registered trademarks or trademarks of Autodesk, Inc., and/or its subsidiaries and/or affiliates in the USA and/or other countries. All other brand names, product names, or trademarks belong to their respective holders. Autodesk reserves the right to alter product offerings and specifications at any time without notice, and is not responsible for typographical or graphical errors that may appear in this document.© 2017 Autodesk, Inc. All rights reserved.。

AutodeskInventor机械设计软件使用教程Chapter 1: Introduction to Autodesk Inventor Mechanical Design Software (200 words)Autodesk Inventor is a powerful and widely-used software tool for mechanical design. Designed by Autodesk, this software provides engineers and designers with a comprehensive set of tools for creating, rendering, and simulating 3D models. With its intuitive interface and extensive features, Inventor is a popular choice for professionals in various industries, including manufacturing, automotive, and aerospace.In this tutorial, we will explore the key features and functionalities of Autodesk Inventor. This guide is designed for beginners and will provide step-by-step instructions on how to use the software effectively.Chapter 2: Getting Started with Autodesk Inventor (300 words)Before diving into the intricacies of Autodesk Inventor, it's important to familiarize yourself with the basic layout and tools. Upon launching the software, you will be greeted with an interface consisting of various panels, menus, and a workspace.This chapter will guide you through the process of creating a new project and setting up your workspace. You will also learn how to navigate the interface and customize the layout to suit your preferences. Additionally, you will be introduced to the different file types supported by Inventor and how to save your work.Chapter 3: Creating 3D Models (400 words)One of the core functionalities of Autodesk Inventor is the ability to create 3D models of mechanical components. In this chapter, we will delve into the different techniques and tools available for creating these models.You will learn how to sketch 2D profiles and use the extrude, revolve, and sweep commands to convert these profiles into 3D objects. We will also explore the wide range of construction tools, including fillets, chamfers, and patterns, that allow you to add intricate details to your models.Chapter 4: Assembly and Constraints (300 words)In a real-world mechanical design project, multiple components come together to form an assembly. Autodesk Inventor provides a robust set of tools for creating and managing these assemblies.This chapter will guide you through the assembly process, from inserting components to defining relationships between them using constraints. You will also learn how to manipulate assemblies, hide and show components, and create exploded views for documentation purposes.Chapter 5: Simulating and Analyzing Models (300 words)Autodesk Inventor offers powerful simulation and analysis tools that allow you to test the performance and behavior of your designs before manufacturing or production.In this chapter, you will learn how to apply loads, define material properties, and run simulation studies to determine factors such as stress, displacement, and interference. Additionally, you will explore the motion analysis tools available in Inventor, which enable you to simulate the movement of assembly components.Chapter 6: Documentation and Presentation (300 words)Effective communication of your design ideas is crucial in the engineering field. Autodesk Inventor provides a set of tools for creating technical drawings, dimensioning, and generating documentation.This chapter will cover the creation of 2D drawings, including the placement of views, adding dimensions and annotations, and creating a bill of materials. You will also learn how to render 3D models for realistic visualizations and create interactive presentations.Conclusion: Mastering Autodesk Inventor (200 words)In conclusion, Autodesk Inventor is a powerful software tool that is widely used in the mechanical design industry. With its comprehensive set of features, intuitive interface, and simulation capabilities, it provides engineers and designers with the tools they need to bring their concepts to life.In this tutorial, we have explored the key features of Autodesk Inventor, including creating 3D models, managing assemblies, simulating designs, and creating technical documentation. By following the step-by-step instructions provided, you will be well on your way to mastering this software and becoming proficient in mechanical design. Remember to practice regularly and experiment with different design scenarios to enhance your skills.。