Become An Electrical Bim Modeler What Is The Procedure

Becoming a Revit modeler requires a combination of technical skills, software proficiency, and industry knowledge. Here’s a guide on what you need to know and steps you can take to become a proficient Revit modeler:

Essential Skills and Knowledge:

  1. Understanding of Building Information Modeling (BIM):
    • Grasp the fundamentals of BIM and how it differs from traditional CAD.
  2. Proficiency in Revit:
    • Learn to navigate the Revit interface, including views, toolbars, and properties.
    • Understand the use of families, components, and parameters.
    • Master creating and editing models, including architectural, structural, and MEP (Mechanical, Electrical, Plumbing) elements.
  3. Technical Drawing and Drafting:
    • Know how to read and create architectural drawings and blueprints.
    • Understand drafting standards and conventions.
  4. Construction and Building Codes:
    • Familiarize yourself with local and international building codes and standards.
  5. Project Coordination and Collaboration:
    • Learn to work within a collaborative environment, sharing and coordinating models with other team members.
  6. Attention to Detail:
    • Develop a keen eye for detail to ensure accuracy in your models.
  7. Problem-Solving Skills:
    • Be able to troubleshoot issues that arise during modeling.

Steps to Becoming a Revit Modeler:

  1. Education and Training:
    • Obtain a degree or diploma in architecture, engineering, construction management, or a related field.
    • Take specific courses in Revit and BIM. Many community colleges, technical schools, and online platforms offer Revit training.
  2. Gain Experience:
    • Start with internships or entry-level positions that involve drafting or modeling. Hands-on experience is invaluable.
    • Work on small projects to build your portfolio.
  3. Get Certified:
    • Consider obtaining Autodesk Revit certification. This can enhance your resume and demonstrate your proficiency.
  4. Stay Updated:
    • Revit and BIM technologies are constantly evolving. Stay current with the latest updates and industry trends through continuous learning and professional development.
  5. Join Professional Networks:
    • Become a member of professional organizations such as the American Institute of Architects (AIA) or BIM forums. Networking can provide learning opportunities and career advancement.
  6. Develop Soft Skills:
    • Good communication and teamwork skills are essential, as you’ll often work closely with architects, engineers, and other professionals.

Recommended Resources:

  1. Online Courses and Tutorials:
    • Autodesk University
    • LinkedIn Learning
    • Udemy
    • Coursera
  2. Books:
    • “Mastering Autodesk Revit” by various authors
    • “BIM Handbook: A Guide to Building Information Modeling” by Chuck Eastman, et al.
  3. Forums and Communities:
    • Autodesk Revit Forum
    • RevitCity
    • Reddit’s r/Revit

By gaining the necessary skills, obtaining relevant education, and continuously improving your knowledge, you can build a successful career as a Revit modeler.


To become an Electrical BIM (Building Information Modeling) Modeler, you need a combination of specialized knowledge in electrical systems, proficiency in BIM software (particularly Revit), and a good understanding of industry standards and practices. Here’s a step-by-step guide to help you get started:

1. Educational Background

  • Degree: Obtain a degree or diploma in electrical engineering, electrical technology, or a related field.
  • Certifications: Consider certifications specific to electrical systems or BIM, such as Autodesk Revit certification.

2. Understand Electrical Systems and Standards

  • Basic Electrical Knowledge: Familiarize yourself with electrical principles, circuitry, and systems design.
  • Electrical Codes and Standards: Learn local and international electrical codes (e.g., NEC – National Electrical Code, IEC – International Electrotechnical Commission standards).

3. Learn BIM and Revit

  • BIM Fundamentals: Understand the principles of Building Information Modeling (BIM) and its application in construction and engineering.
  • Revit for Electrical Design: Gain proficiency in Autodesk Revit, focusing on its electrical modeling tools. Learn to create and manage electrical systems within Revit, including lighting, power, and communications systems.

4. Develop Technical Skills

  • Drafting and Design: Improve your drafting skills, ensuring you can read and create detailed electrical drawings and schematics.
  • Modeling Techniques: Learn to create 3D models of electrical systems, including conduit, cable trays, panels, and fixtures.

5. Get Hands-on Experience

  • Internships and Entry-Level Positions: Look for internships or entry-level positions that offer exposure to electrical modeling and BIM.
  • Work on Projects: Participate in projects where you can apply your skills in a real-world setting. This could be through work, school projects, or independent practice.

6. Use Relevant Software

  • Revit: As mentioned, Revit is crucial for BIM modeling. Learn to use Revit’s tools for creating electrical layouts and detailed models.
  • Navisworks: Useful for clash detection and coordination among various building systems.
  • AutoCAD: While BIM is increasingly popular, proficiency in AutoCAD is still valuable.

7. Continuous Learning and Certification

  • Stay Updated: BIM technology and standards are continually evolving. Keep your skills up-to-date with ongoing education and training.
  • Certifications: Obtain certifications to validate your expertise, such as the Autodesk Certified Professional in Revit for Electrical Design.

8. Join Professional Networks

  • Professional Organizations: Join organizations such as the Institute of Electrical and Electronics Engineers (IEEE) or BIM-specific groups.
  • Networking: Attend industry conferences, webinars, and workshops to network with professionals and learn about the latest trends.

9. Soft Skills Development

  • Communication: Develop good communication skills to effectively collaborate with architects, engineers, and other stakeholders.
  • Problem-Solving: Enhance your problem-solving abilities to address challenges that arise during the modeling process.

Recommended Resources:

  1. Online Courses and Tutorials:
    • Autodesk University: Offers a variety of courses on Revit and BIM.
    • LinkedIn Learning: Provides courses on Revit for electrical design.
    • Udemy and Coursera: Offer courses on BIM and electrical systems.
  2. Books:
    • “Mastering Autodesk Revit” series.
    • “Electrical Systems Design” by M.K. Giridharan.
    • “BIM Handbook” by Chuck Eastman et al.
  3. Forums and Communities:
    • Revit Forum: A place to discuss Revit-related queries.
    • RevitCity: Community for Revit users.
    • Reddit: Subreddits like r/Revit and r/BIM for discussions and resources.

By following these steps and continually improving your skills, you can build a successful career as an Electrical BIM Modeler.


Design and shop drawings are critical components in the construction and engineering fields. Here’s an overview of what you need to know about each:

Design Drawings

Purpose: Design drawings are conceptual and schematic representations that outline the overall design of a project. They communicate the architect’s or engineer’s vision and are used in the early stages of a project.

Key Characteristics:

  • Conceptual: Focus on the layout, aesthetics, and functionality of a project.
  • Schematic: Include basic plans, elevations, sections, and sometimes 3D views.
  • Detail Level: Generally lower than shop drawings. They provide enough detail to convey the design intent but not for actual construction.
  • Audience: Primarily intended for clients, project stakeholders, and regulatory agencies for approvals and permits.

Types of Design Drawings:

  • Architectural Drawings: Floor plans, elevations, sections, and 3D renderings.
  • Structural Drawings: Basic layout of structural elements like beams, columns, and foundations.
  • MEP (Mechanical, Electrical, Plumbing) Drawings: Schematics showing the general layout of MEP systems.

Shop Drawings

Purpose: Shop drawings are detailed and precise drawings used by contractors, fabricators, and installers to guide the actual construction and assembly of components.

Key Characteristics:

  • Detailed: Provide comprehensive details, dimensions, and specifications for construction.
  • Precision: Include exact measurements, materials, and fabrication details.
  • Construction Focused: Used directly on-site or in fabrication shops to ensure accurate construction.
  • Audience: Intended for contractors, fabricators, and construction workers.

Types of Shop Drawings:

  • Structural Shop Drawings: Detailed drawings of steel or concrete components, such as beams, columns, trusses, and connections.
  • Architectural Shop Drawings: Detailed drawings of interior and exterior finishes, windows, doors, and custom millwork.
  • MEP Shop Drawings: Detailed layouts and specifications for mechanical, electrical, and plumbing systems, including ductwork, piping, and wiring.

Process for Creating Design and Shop Drawings

  1. Design Drawings:
    • Conceptual Phase: Develop initial concepts and layouts.
    • Schematic Design: Create schematic drawings that outline the basic structure and systems.
    • Design Development: Refine the drawings with more details, addressing the client’s feedback and regulatory requirements.
    • Construction Documents: Finalize the design drawings to provide a complete set of documents for bidding and regulatory approval.
  2. Shop Drawings:
    • Review Design Drawings: Start with the approved design drawings to understand the overall intent and requirements.
    • Detailing: Develop detailed drawings for specific components, ensuring all dimensions and specifications are accurate.
    • Coordination: Coordinate with other trades (e.g., architectural, structural, MEP) to ensure compatibility and avoid conflicts.
    • Approval: Submit shop drawings for approval by architects, engineers, and clients. Address any comments or revisions.
    • Fabrication and Installation: Use the approved shop drawings to guide the fabrication and installation of components.

Software Tools

  • Design Drawings: Often created using CAD software like AutoCAD, Revit (for BIM), and SketchUp.
  • Shop Drawings: Created using specialized CAD software like AutoCAD, Revit, Tekla Structures (for structural components), and other fabrication-specific tools.

Importance of Accuracy and Coordination

  • Accuracy: Both design and shop drawings must be accurate to ensure the final construction meets the intended design and functions correctly.
  • Coordination: Effective communication and coordination between design and construction teams are essential to avoid errors and ensure a smooth construction process.

By understanding these aspects and honing your skills in creating and interpreting both design and shop drawings, you can play a crucial role in the successful execution of construction projects.

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