BRYAN DARRIN SENIOR THESIS PRESENTATION MILLENNIUM HALL DREXEL CAMPUS PHILADELPHIA, PA

1. BRYAN DARRIN SENIOR THESIS PRESENTATION MILLENNIUM HALL DREXEL CAMPUS PHILADELPHIA, PA

2. Millennium Hall 34th Street and Race Street, Philadelphia, PA 19104 Drexel University Educational Residence Hall 153,000 Gross S.F. 17 Stories Total + Introduction - General Building Information - Existing Structural System - Thesis Objective - Structural Depth - Architectural Breadth - CM Breadth - Final Summary/Conclusions General Building Information Façade of glass and aluminum screen curtain wall Offset of each floor as a rotation about the central core creates spiral affect. [Note: For this entire thesis project, the spiral affect has been removed. This includes all data referred to as existing design.]

3. + Introduction - General Building Information - Existing Structural System - Thesis Objective - Structural Depth - Architectural Breadth - CM Breadth - Final Summary/Conclusions Cast-in-place concrete Flat plate Concrete moment frame with concrete shear walls • 110 feet wide • feet deep • 15 foot cantilever

4. - Introduction + Thesis Objective - Problem Statement/Solution - Thesis Goals - Structural Depth - Architectural Breadth - CM Breadth - Final Summary/Conclusions Thesis Redesign Goals Depth - Structural 1. Reduce the weight of the overall building by replacing the gravity system 2. Minimize drift with a lateral force resisting system in coordination with the gravity system 3. Verify the impact on the foundation system Existing Building Problems Heavy weight due to concrete Thick floor slabs due to large cantilever Redesign Solution Design as steel moment frame Use composite deck to reduce thickness Move column line to exterior Add braced frames for lateral resistance

5. - Introduction + Thesis Objective -Problem Statement/Solution - Thesis Goals - Structural Depth - Architectural Breadth - CM Breadth - Final Summary/Conclusions Thesis Redesign Goals Breadth #2 – Construction Management 5. Determine the impact that the redesign has on the construction schedule and cost of the building Thesis Redesign Goals Breadth #1 - Architectural 4. Determine the impact on the architectural design including floor plan layout

6. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions SDL = 20 psf + 15 psf = 35 psf LL = 100 psf 1.2 SDL + 1.6 LL

7. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions L = 35 + 100 = 135 psf > 147 psf ok Wu = [1.2(44+5+35) + 1.6(100)](12)/1000 = 3.13 klf Mu = 452 ft-kips Use W16x45 with 32 studs spaced at 12 inches

8. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions Ram Model Used to verify hand calculations and determine column sizes Full composite construction was assumed Same loading was used Results #1 RAM member sizes were found to be close to the hand calculated but generally smaller. Results #2 Preliminary column sizes were found W10x33 Typ. As large as W10x100 at interior line

9. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions Design Limits (IBC,2006) (Allowable Building Drift) Δwind = H/400 = 180*12/400 = 5.4 inches Design Loads Wind controls in the North/South direction: 398 kips (Allowable Story Drift) Δseismic = 0.015Hsx = 0.015*10*12 = 1.8 inches Seismic controls in the East/West direction: 327 kips

10. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions ETABS Design Process Model was built in ETABS Member sizes from Gravity system were used Columns were aligned with local beam axis All connections were assigned as moment connection Diaphragm was assigned to each floor Loading patterns for seismic and wind were placed as individual story forces First Evaluation Total Drift > 30 inches Larger member sizes were not making much improvement

11. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions Second Evaluation North/South Wind Braced frames added to resist North/South drift Maximum drift = 5.33 inches < 5.4 inches

12. - Introduction - Thesis Objective + Structural Depth - Gravity Redesign - Lateral Redesign - Foundation Check - Architectural Breadth - CM Breadth - Final Summary/Conclusions East/West Seismic Foundation Check 20 caissons Assume equal distribution 920 kips / caisson 32 caissons Assume interior 10 caissons take half 680 kips / caisson Maximum story drift = 1.22 inches < 1.8 inches

13. - Introduction - Thesis Objective - Structural Depth + Architectural Breadth - CM Breadth - Final Summary/Conclusions Connected directly to column Connection points every 12 feet Continuously up building

14. - Introduction - Thesis Objective - Structural Depth - Architectural Breadth + CM Breadth - Final Summary/Conclusions Existing Cost/Schedule Includes structural concrete, reinforcement, and framing Estimated structural cost of $1.7 million Estimated timeline of 330 days Cost/Schedule Comparison Cost has been increased by $600,000 or by 35% Schedule has been reduced by 200 days or by40% New Cost/Schedule Includes steel framing, steel decking, metal studs to develop composite strength, concrete, reinforcement, and fire proofing Estimated structural cost of $2.3 million Estimated timeline of 130 days

15. - Introduction - Thesis Objective - Structural Depth - Architectural Breadth - CM Breadth + Final Summary/Conclusions Goals Re-evaluated Summary 1. Reduce the weight of the overall building by replacing the gravity system Steel frame and composite deck provide lightweight system 2. Minimize drift with a lateral force resisting system in coordination with the gravity system Steel braced frames partnered with steel moment frame reduce drifts to allowable values 3. Verify the impact on the foundation system Existing caissons have adequate strength for all columns, most could be reduced in size 4. Determine the impact on the architectural design including floor plan layout Minimal façade connection changes and layout adjustments have little impact on floor plan 5. Determine the impact that the redesign has on the construction schedule and cost of the building Structural cost has gone up but entire building schedule time has been reduced

16. - Introduction - Thesis Objective - Structural Depth - Architectural Breadth - CM Breadth + Final Summary/Conclusions Summary Acknowledgements I would like to thank: The Harman Group for a unique building idea Drexel University for allowing me to analyze the Millennium Hall building The entire AE faculty, especially my Thesis Advisor Dr. Hanagan Met project goals Structural design is feasible option QUESTIONS?