Complete course for the mechanical, electrical, and plumbing (MEP) disciplines for the building design and construction
What you will learn
Correctly configure Revit projects for electrical systems
Model typical elements of plumbing systems
Create mechanical systems within Revit
Create piping system for mechanical installations
Carry out energy analysis based on building data
Work collaboratively on multidisciplinary projects
Description
Revit MEP Electromechanical Specialization Course is the perfect way for professionals to learn the fundamentals of BIM design and become specialized in Revit. This course provides an in-depth learning experience that covers everything from basic principles to advanced techniques. It covers topics such as drafting, modeling, and visualization, as well as the use of tools such as Autodesk Revit.
#AulaGEO
Through this specialization course, learners will be able to become proficient in using Revit MEP for projects such asย electrical systems, plumbing systems & HVAC systems. With a comprehensive curriculum that covers topics such as 3D modeling, visualization techniques, and project coordination, this course arms students with the skills needed to excel in your career path.
CONTENT
PART I – Electrical
During the development of the course we will pay attention to the necessary configuration within a Revit project to be able to execute electrical calculations. We will show you how to work with circuits, boards, voltage types and electrical distribution systems. You will learn how to extract data from circuits and create dashboard views that balance design loads.
Finally, we will show you how to create detailed reports of parts, conductors and electrical pipes.
Introduction
Lecture 1: Introduction
Lecture 2: Electricity templates
Lecture 3: Link external models
Lighting
Lecture 4: Efficient lighting design
Lecture 5: Spaces and lighting
Lecture 6: Reflected ceiling view
Lecture 7: Lighting analysis
Lecture 8: Lighting fixtures
Lecture 9: Light switches
Lecture 10: Annotation symbols
Power
Lecture 11: Create circuits
Lecture 12: Electric Conectors
Lecture 13: Transformers and boards
Lecture 14: Power distribution systems
Lecture 15: Conduits and cable trays
Lecture 16: Configuration of electrical pipes
Lecture 17: Placing conduits on a model
Lecture 18: Place cable trays on model
Lecture 19: Electrical configurations
Lecture 20: Wiring configuration
Lecture 21: Voltage configuration and distribution systems
Lecture 22: Set up load calculation and dashboard view
Lecture 23: Create circuits and wiring
Lecture 24: Manual cable creation
Lecture 25: Circuit Properties
Lecture 26: Board Properties
Lecture 27: Circuit tables
Conclusion
Lecture 28: Farewell
PART II – Plumbing
For plumbing, we will focus on how to properly configure our projects to work with plumbing installations. And we will do it taking into account the collaborative work necessary for multi-disciplinary projects. You will learn to model, design and report models of sanitary facilities under the BIM environment. In the final section, we will pay attention to creating logical duct and pipe systems, creating those elements, and using the Revit engine to design sizes and verify performance.
Introduction
Lecture 1: Introduction
Lecture 2: Templates for plumbing systems
Lecture 3: Link architecture
Plumbing Model Creation
Lecture 4: Place pieces
Lecture 5: Pieces per monitor copy
Lecture 6: Pipe connectors
Lecture 7: Place teams
Lecture 8: Plumbing setup
Lecture 9: Piping systems
Lecture 10: Pipe routing
Lecture 11: Manual laying of pipes
Lecture 12: Pendiente de tuberรญas
Lecture 13: Valves and other accessories
Inspection, design and reporting
Lecture 14: Systems inspection
Lecture 15: Piping design
Lecture 16: Pressure loss reports
Lecture 17: Sanitary Parts Tables
Conclusion
Lecture 18: Farewell
PART III – HVAC
In this part we will concentrate on the use of Revit tools that assist us in performing energy analysis of buildings. We will see how to enter energy information in our model and how to export this information for treatment outside of Revit. In the final section, we will pay attention to creating logical duct and pipe systems, creating those elements, and using the Revit engine to design sizes and verify performance.
Introduction
Lecture 1: Introduction
Lecture 2: Templates with mechanical configurations
Lecture 3: Links for collaborative work
Energy Design
Lecture 4: Create spaces
Lecture 5: Place spaces
Lecture 6: Create space tables
Lecture 7: Modify space properties
Lecture 8: Create zones
Lecture 9: Modify construction options
Lecture 10: Thermal load analysis
Lecture 11: Load analysis
Lecture 12: Climate data
Lecture 13: Sliver spaces
Lecture 14: Level of detail of the report
Lecture 15: Load analysis details
Lecture 16: Thermal load reports
Lecture 17: Export gbXML to simulation software
Design of mechanical installations
Lecture 18: Systems Explorer
Lecture 19: Mechanical configurations
Lecture 20: Duct connectors
Lecture 21: Create mechanical systems
Lecture 22: Mechanical piping configuration
Lecture 23: Pipe connectors
Lecture 24: Piping systems
Lecture 25: Place terminals
Lecture 26: Place mechanical equipment
Lecture 27: Create routing scheme
Lecture 28: Manual routing
Lecture 29: Duct sizes
Lecture 30: Mechanical piping equipment
Lecture 31: Mechanical pipe routing
Lecture 32: Manual pipe editing
Lecture 33: Mechanical pipe size
Lecture 34: Loss reports
Conclusion
Lecture 35: Farewell
The AulaGeo team worked hard on this course. It was developed in Spanish by Enzo, voiced by Gabriella for English speaking students.
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