With the elevator shaft properly configured, we can now proceed to install the elevator system itself. For this demonstration, we'll be using a manufacturer-supplied family file that I've sourced directly from the vendor's technical library and included in our class dataset. This approach mirrors real-world workflows where architects and engineers leverage manufacturer-specific BIM content to ensure accuracy and compliance with industry standards.

Navigate to our class folder where you'll find the elevator family file ready for integration. This manufacturer-provided component includes all the parametric intelligence and geometric detail needed for both design development and construction documentation phases. Click Open to import this family into your current project environment.

Once loaded, access the Architecture tab and select Component to begin placement. The elevator family is designed as a hosted component, meaning it requires a wall element for proper insertion and structural reference.

Notice how the software automatically seeks an appropriate host wall—in this case, it's identifying our front wall where the elevator entrance will be located. Position the elevator against this wall, ensuring proper alignment with your circulation patterns and building code requirements for accessibility.

The rectangular boundary you see represents the hoistway footprint, which must align precisely with your structural and MEP coordination requirements. Positioning it in the corner maximizes efficiency while maintaining clear egress paths. The automatic door opening demonstrates the intelligent relationships built into quality manufacturer families.

Here's where working with manufacturer-supplied content reveals both its power and complexity: these families are engineered for maximum flexibility across diverse project types, not just your specific building requirements. As you can see, our elevator system defaults to approximately 10-11 stories—far exceeding our two-story structure.

This is the reality of leveraging manufacturer BIM libraries in 2026: while the geometric precision and technical specifications are exceptional, the parametric flexibility requires careful adjustment. Select the elevator to access its instance parameters, where you'll find an extensive array of customizable properties.

The challenge with sophisticated manufacturer content lies in parsing through numerous technical parameters. Focus on non-dimensional values that control operational characteristics rather than getting lost in the geometric constraints.

Located within the parameters, you'll find "Number of Stops"—currently set to 10. Adjust this to 2 to match our ground floor and second floor configuration. This single parameter change immediately resolves the vertical extent issue and optimizes the family's performance for our specific application.

To verify our configuration, create a section view that cuts through both the building core and elevator system. This cross-sectional analysis is essential for coordinating floor-to-floor heights and ensuring proper alignment with structural elements.

The section reveals our stop-to-stop spacing of 14 feet, which aligns well with our floor plate organization. You can see the elevator now properly serves level two and terminates at the roof level—exactly what our design requires. The underlying parametric framework still supports multiple stops, but we've successfully customized it for our two-story application.

With these critical parameters properly configured, our elevator system is now ready for further refinement and coordination with other building systems. Save your progress as we continue developing the remaining core elements and mechanical systems integration.