IGS Group (IGS BIM Solutions)’s Post

Whilst high-quality #manufacturer-based BIM content provides efficiency and workflow benefits to designers, it's important to acknowledge poorly created content doesn't end in a 'neutral' outcome, but a detrimental one for both the manufacturer and designer.

Understanding Revit File Positioning Options 🔗 Linking Revit Models: Mastering Positioning Options for Seamless Coordination Linking models in Revit is a powerful feature that enhances collaboration across different disciplines and project teams. However, the success of this process often hinges on how you position these linked models. Understanding and selecting the right positioning option can make a world of difference in your project coordination. Here’s a detailed look at the primary positioning options available in Revit: 1. Auto – Center to Center This option centers the linked model's geometry relative to the host model's geometry. It’s particularly useful when you want to quickly align the overall geometry without worrying about the absolute origins or specific coordinates. The primary benefit here is simplicity and speed, but be cautious, as it might not always offer the precision needed for complex projects. Ideal for initial design and when precise origin alignment isn’t critical. 2. Auto – Origin to Origin By aligning the origin (0,0,0 point) of the linked model with the origin of the host model, this option ensures that both models share the same origin point. This method is beneficial when both models are set up with the same or known origin points. It’s a precise way to maintain consistency across different models, avoid misalignments, and ensure that every element aligns perfectly in both horizontal and vertical axes. 3. Auto – By Shared Coordinates Using shared coordinates is the go-to method for projects that require advanced coordination. This option positions models based on a common coordination point that has been established beforehand. This is particularly useful for large and complex projects where multiple teams work on different parts of the same project. By setting shared coordinates, every linked model aligns accurately within the larger site or building context, ensuring seamless integration across various project components. 🔑 Key Takeaways: Auto – Center to Center: Quick geometry-centric alignment, but limited precision. Auto – Origin to Origin: Precise origin point alignment, ideal for detailed coordination. Auto – By Shared Coordinates: Advanced coordination using a common point, perfect for large-scale projects. Choosing the right positioning method is essential for efficient project management and successful collaboration. Each option caters to different needs and project complexities, ensuring that your linked models integrate smoothly, maintain alignment, and avoid costly errors. Stay tuned for more insights on effective Revit practices and feel free to share your own experiences with these features! #Revit #BIM #ConstructionManagement #ArchitecturalDesign #Engineering #BuildingDesign Feel free to connect with me for more discussions on optimizing your Revit workflows and achieving seamless project coordination! 😊

Revit training (6) New Revit family creation simple method overview: 1. Start with a Template: Revit provides templates for different types of families such as doors, windows, furniture, etc. You can start with a template closest to the type of family you want to create. 2. Basic Family Types: Revit provides three basic family types: * Model-In-Place: Allows you to model a family directly within the project environment. * Component: These are standalone families like doors, windows, furniture, etc. * Detail Component: Used for annotations and details. 3. Create Family: In Revit, you can start a new family by going to the "File" menu and selecting "New" > "Family". This opens the Family Editor environment where you can start creating your family. 4. Building Geometry: Use tools like lines, arcs, circles, and shapes to build the geometry of your family. Revit provides powerful parametric tools that allow you to create flexible and dynamic geometry. 5. Add Parameters: Parameters control the behavior of your family. You can add dimensions, constraints, and other parameters to make your family flexible and adaptable. 6. Create Solid Forms: Once you have the basic geometry, you can use tools to create solid forms such as extrusions, blends, sweeps, and revolves. 7. Apply Materials: You can apply materials to your family to make it visually realistic. Revit comes with a library of materials, and you can also create custom materials. 8. Add Detailing: Depending on the type of family, you may need to add additional detailing such as dimensions, text, symbols, etc. 9. Test and Refine: It's essential to test your family within a project environment to ensure that it behaves as expected. You may need to refine the geometry, parameters, or materials based on testing. 10. Save and Load: Once your family is complete, you can save it and load it into your project. You can also share your family with others by saving it as a separate file. 11. Documentation: It's good practice to document your family with descriptions, parameters, and usage instructions to make it easier for others to use. Note: * Creating families in Revit involves several methods depending on the complexity and specificity of the family you want to create. * Remember, creating families in Revit requires a combination of design skills, parametric modeling knowledge, and familiarity with Revit's tools and environment. #BIM #LOD #Revit #Autodesk #Ditigaltwin #AutoCAD #Architecture #Civil #Mechanical #Electrical #Plumbing #MEP

I am thrilled to announce that I achieved the top rank at the first half of my recent diploma, an accomplishment that has further fueled my passion for sharing expertise in BIM, Revit, and Electrical Systems. ⚡*𝘿𝙞𝙥𝙡𝙤𝙢𝙖 𝙊𝙫𝙚𝙧𝙫𝙞𝙚𝙬:* 1. *𝙄𝙣𝙩𝙧𝙤𝙙𝙪𝙘𝙩𝙞𝙤𝙣:* - *BIM and Revit Fundamentals:* Gain a solid foundation in Building Information Modeling (BIM) and Autodesk Revit, including the key benefits and applications of these tools. - *Revit Extensions:* Explore various extensions and their functionalities to maximize your productivity. - *Local and Central Files:* Learn how to effectively manage local and central files to ensure seamless collaboration. 2. *𝙎𝙢𝙖𝙡𝙡 𝙎𝙤𝙘𝙠𝙚𝙩𝙨:* - *Views and Manage Links:* Understand how to create and manage views, and handle linked models. - *Distribution and Worksets:* Dive into the distribution of small sockets and manage worksets for effective project organization. - *Wiring, Power, Panels, Annotations:* Master the intricacies of wiring, power distribution, panel design, and creating detailed annotations. 3. *𝙑𝙞𝙚𝙬 𝙏𝙚𝙢𝙥𝙡𝙖𝙩𝙚𝙨 & 𝙑𝙞𝙨𝙞𝙗𝙞𝙡𝙞𝙩𝙮 𝙖𝙣𝙙 𝙂𝙧𝙖𝙥𝙝𝙞𝙘𝙨:* - *View Templates:* Learn to create and manage view templates to maintain consistency across your project. - *Visibility and Graphics:* Customize visibility settings and graphic representations to enhance project clarity. - *Power Loads:* Analyze and manage power loads for mechanical system. 4. *𝙇𝙞𝙜𝙝𝙩𝙞𝙣𝙜 𝙎𝙮𝙨𝙩𝙚𝙢:* - *Integration from Revit to Dialux:* Discover how to integrate Revit with Dialux for comprehensive lighting design. - *Families and Lighting Distribution:* Understand lighting families and their distribution to achieve optimal illumination. - *Revit Parameters, Wiring, Power, Panels, Annotations, Filters:* Delve into Revit parameters and manage all aspects of the lighting system. 5. *𝙋𝙖𝙣𝙚𝙡𝙨 𝙎𝙘𝙝𝙚𝙙𝙪𝙡𝙚𝙨 𝙖𝙣𝙙 𝘾𝙖𝙗𝙡𝙚 𝙏𝙧𝙖𝙮𝙨:* - *Panel Schedules:* Learn to create and manage panel schedules. - *Cable Trays:* Design and implement cable tray systems to support your electrical infrastructure. 6. *𝙌𝙪𝙖𝙣𝙩𝙞𝙩𝙞𝙚𝙨, 𝘾𝙤𝙣𝙙𝙪𝙞𝙩𝙨, 𝙁𝙞𝙣𝙖𝙡𝙞𝙯𝙞𝙣𝙜 𝙖𝙣𝙙 𝙎𝙝𝙚𝙚𝙩𝙨:* - *Quantities and Conduits:* Calculate quantities and design conduit systems efficiently. - *Finalizing and Sheets:* Finalize your project and prepare detailed sheets for presentation and construction. 7. *𝙑𝙞𝙚𝙬 𝙍𝙖𝙣𝙜𝙚 :* - *View Range:* Understand and manage view range settings to ensure accurate representations. This diploma aims to equip you with the skills and knowledge necessary to excel in BIM and electrical systems design, offering practical, real-world insights that you can apply immediately. 𝙎𝙥𝙚𝙘𝙞𝙖𝙡 𝙩𝙝𝙖𝙣𝙠𝙨 𝙩𝙤 :- Eng. Mohamed Emam Eng. Omar Hamdi

Moving a wall in architectural design can have similar and different effects in AutoCAD and Revit due to the fundamental differences in how these software platforms operate. In AutoCAD: 1. Manual Adjustments: Moving a wall in AutoCAD typically involves selecting the wall entity and physically moving it using commands like "Move" or by dragging it with the mouse. This process requires manual adjustments and can be time-consuming, especially if the design is complex. 2. 2D-centric: AutoCAD is primarily a 2D drafting tool, so while it can simulate 3D environments, its core functionality revolves around 2D drafting. Therefore, moving a wall may not automatically update associated elements like dimensions or 3D models, which may require additional manual adjustments. 3. Limited Parametric Capabilities: AutoCAD lacks robust parametric capabilities compared to Revit. Changes made to one part of the design may not propagate throughout the drawing unless manually adjusted, leading to potential errors or inconsistencies. In Revit: 1. BIM (Building Information Modeling): Revit is built around the BIM methodology, where elements in the model are inherently intelligent and interconnected. When you move a wall in Revit, the software automatically updates all associated elements, such as dimensions, schedules, and 3D views. 2. Parametric Design: Revit allows you to define relationships and constraints between elements, making it easier to maintain design integrity. Moving a wall in Revit can trigger automatic adjustments in connected elements, ensuring that the entire model remains coordinated. 3. Real-time Visualization: Revit provides real-time visualization capabilities, allowing you to instantly see how moving a wall affects the overall design. This helps architects and designers make informed decisions quickly. 4. Data-rich Modeling: Revit models contain a wealth of information beyond just geometry. Moving a wall in Revit not only updates the geometry but also maintains data such as material properties, construction details, and cost estimates, ensuring accuracy throughout the design process. In summary, while both AutoCAD and Revit can facilitate the movement of walls in architectural design, Revit offers more advanced capabilities for maintaining design coherence, thanks to its BIM-based approach and parametric design features. Revit's ability to automatically update associated elements and provide real-time visualization significantly streamlines the design process compared to AutoCAD. #architecture #architectdaily

Enhance your Revit productivity with these free add-ons: • PyRevit: Optimize repetitive tasks and check models for errors. • Dynamo: Visual programming for workflow optimization. • Nonica Tab: Run Dynamo scripts faster with a customizable toolbar. • Colour Splasher: Visualize model info with color coding. • DiRootsOne: A suite of eight productivity-enhancing plugins. • EF-Tools: Over 50 tools to boost Revit productivity. • COINS Auto-Section Box: Create focused 3D views for better analysis. • Design Review: View, print, and annotate 2D/3D files. • Engipedia Layers Manager: Analyze layered structures. • Align: Organize elements along an axis. • Master Purger: Remove unused elements from your model. • Isolate Warnings: Highlight elements with warnings in 3D views. • Revit Lookup: Access raw database info. • Clash Preventor: Automatically detect and resolve clashes. • Tiny Tools: Streamline tasks like view alignment and renaming. • ElementRenumbering: Sequentially renumber elements. • Microdesk Accelerator: Automate MEP design tasks. • OnboxApp: Optimize performance for various tasks. • Room Finishing: Generate room finishes automatically. • Family Editor Interface: Improve Family Content editing. • ToolBox: Tools for MEP and structural designs. • BIMprove: Practical tools for enhanced productivity. • ProSheets: Bulk export views and sheets with smart • Master Purger: Remove unused elements from your model. • Isolate Warnings: Highlight elements with warnings in 3D views. • Revit Lookup: Access raw database info. • Clash Preventor: Automatically detect and resolve clashes. • Tiny Tools: Streamline tasks like view alignment and renaming. • ElementRenumbering: Sequentially renumber elements. • Microdesk Accelerator: Automate MEP design tasks. • OnboxApp: Optimize performance for various tasks. • Room Finishing: Generate room finishes automatically. • Family Editor Interface: Improve Family Content editing. • ToolBox: Tools for MEP and structural designs. • BIMprove: Practical tools for enhanced productivity. • ProSheets: Bulk export views and sheets with smart features. These tools can make your Revit workflow more efficient. Share your favorites in the comments! Credit goes to RD Studio for creating such a helpful and comprehensive article. You can find the https://lnkd.in/dk5WsmpG to understand more about the add-ons. #Revit #BIM #AEC #Construction #Architecture #Engineering #Productivity #AddOns #Dynamo #PyRevit

Acquiring coordinates: Revit is essential for ensuring that your project models share a consistent coordinate system, especially when collaborating with other models or disciplines. Here’s a step-by-step guide on how to acquire coordinates from a linked model in Revit: Step-by-Step Guide to Acquiring Coordinates in Revit Step 1:  1️⃣ Open the Host Model 2️⃣ Open the Revit model (the "host" model) in which you want to acquire the coordinates from another model. Step 2:  1️⃣ Link the Revit Model 2️⃣ If the model from which you want to acquire coordinates isn’t already linked: 3️⃣ Go to the Insert tab in the Revit ribbon. 4️⃣ Click on Link Revit. 5️⃣ Select the Revit model that contains the desired coordinates and click Open. 6️⃣ Position the linked model appropriately if it’s not already positioned correctly. Step 3:  1️⃣ Position the Linked Model (If needed) 2️⃣ If the linked model is not in the correct position: 3️⃣ Use the Move, Rotate, or Align tools to correctly position the linked model about the host model. Step 4:  1️⃣ Acquire Coordinates With the linked model in the correct position, follow these steps: 2️⃣ Select the linked model in your host model. 3️⃣ Go to the Manage tab in the Revit ribbon. 4️⃣ Click on Coordinates under the Project Location panel. 5️⃣ Choose Acquire Coordinates from the dropdown menu. 6️⃣ Click on the linked model. Revit will acquire the coordinate system from the linked model and apply it to your host model. Step 5:  1️⃣ Verify the Acquired Coordinates 2️⃣ To verify that the coordinates have been acquired correctly: Go to Manage > Project Location > Coordinates > Specify Coordinates at Point. 3️⃣ Click on a known point in your model to check its coordinates. The coordinates should now match those from the linked model. Step 6: 1️⃣ Save the Host Model After acquiring the coordinates, it’s important to save your host model to preserve the changes. Key Points to Remember: 1️⃣ Ensure that the models are correctly aligned before acquiring coordinates. 2️⃣ Communicate with your team about the coordinate changes to avoid discrepancies. 3️⃣ Back-up your files before making significant changes, such as acquiring coordinates. By following these steps, you will successfully acquire and apply the coordinate system from a linked Revit model to your host model, ensuring alignment and consistency across your project. #BIM #Revit #Coordinate

Day 9/30 of Bim basics!!! Basic Modify tools & Commands!! In Autodesk Revit, modification tools are essential for altering and refining your building model. These tools can be found on the Modify tab of the ribbon when an element is selected in Revit. 1.    Temporary Dimensions (Shortcut: TD): -Temporary Dimensions appear when you select an element. They allow you to quickly adjust dimensions without opening the Properties palette. -Use them to modify element sizes directly in the view. 2.Thin Lines (Shortcut: TL): -Revit follows a “What You See Is What You Get” approach, meaning what you see on your screen will be printed exactly as shown. -Thin Lines (TL) allow you to work with thinner lines, making it easier to see closely spaced elements without affecting the final print output. 3.Join geometry When you join geometry in the Family Editor, you create a union between different shapes. In a project, however, one of the joined elements actually cuts the other according to the following scheme: ·       Walls cut columns. ·       Structural elements cut host elements (walls, roofs, ceilings, and floors). ·       Floors, ceilings, and roofs cut walls. ·       Gutters, Fascias, and slab edges cut other host elements. Cornices do not cut any elements. Note: When you use the Join Geometry command, the material of the first picked object is applied to both objects. -Modify tab > Geometry panel > Join > Join geometry -If you want to join the first selected geometry instance to several other instances, select Multiple Join on the Options Bar. -If you do not select this option, you must make a first and second selection each time. -Select the first geometry to join (for example, a wall face). -Select the second geometry to join to the first (for example, an edge of a floor). - If you selected Multiple Join, continue selecting other geometry to join to the first. -To exit the tool, click Modify or press Esc  

Not only is this an OCTA Group (CMS - Crippa - SMI) conduit bender loaded in Autodesk Revit, but this is Allied BIM's new Allied Assistant launching this week with our Revit 2025 toolbar! We're pretty proud of it, and we think you will be too. Give it a try in the new release launching sometime this week! What are the best tools to use for bending conduit with Fabrication Tools? Fabrication Tools for Revit offers several tools for bending conduit, each with its own advantages: 1. MEP Expand: * This is the most versatile tool for bending conduit, offering various options for different types of bends. * Kick 90: Creates a 90-degree bend between two conduits at different elevations. * Stub 90: Extends a conduit at a 90-degree angle for a fixed length. * Offset: Adjusts the position or elevation of a conduit. * 4 Point Saddle: Creates a complex bend with four points for routing around obstacles. * 3 Point Saddle: Creates a bend with three points for connecting conduits. 2. Add Couplings: * This tool helps ensure secure and precise connections between conduits by inserting couplings where they intersect. 3. Align Couplings: * This tool aligns couplings based on their centroids, ensuring accurate connections between conduits. 4. Unsplit Conduit: * This tool reverses the splitting of a conduit, restoring it to a continuous state. Choosing the Best Tool: The best tool for bending conduit will depend on the specific requirements of your project. Here are some factors to consider: * Type of Bend: Kick 90, Stub 90, Offset, 4 Point Saddle, and 3 Point Saddle all create different types of bends. * Complexity: For simple bends, Kick 90 and Stub 90 may be sufficient. For more complex bends, you may need to use 4 Point Saddle or 3 Point Saddle. * Precision: Align Couplings and Add Couplings can help ensure accurate connections. Additional Tips: * Use the Preview Feature: Most of these tools have a preview feature that allows you to visualize the bend before applying it. * Experiment: Don't be afraid to experiment with different tools to find the one that works best for you. By utilizing Fabrication Tools' conduit bending tools effectively, you can streamline your MEP workflows and create precise and accurate conduit designs in Revit. #markit #cutit #bendit #alliedassistant #ai #gamechanging #help #revit #2025 #autodeskpartner

Very useful information about how to Acquire Coordinates in Revit...