PROVIDENCE RIVER PEDESTRIAN BRIDGE

1. PROVIDENCE RIVER PEDESTRIAN BRIDGE FINAL CAPSTONE PRESENTATION CIVIL ENGINEERING CLASS OF 2014 | APRIL 29, 2014

2. BEVERLY XU (PROJECT MANAGER) – SUSTAINABILITY AND COST ESTIMATION MAX VINHATEIRO – PIER ANALYSIS AND ABUTMENT DESIGN THOMAS SCHIEFER – BRIDGE DECK DESIGN PARTNER JENN THOMAS – BRIDGE DECK DESIGN PARTNER RACHEL CONNOR (PROJECT DRAFTER) – PIER DECK DESIGN KA LING WU – CANOPY DESIGN

3. HISTORICAL CONTEXTINTRODUCTION • I-195 Redevelopment Parcels • June 2007 - RIDOT Feasibility Study • Pedestrian Bridge Design Competition

4. HISTORICAL CONTEXTI-195 REDEVELOPMENT PARCEL

5. HISTORICAL CONTEXTFEASIBILITY STUDY

6. HISTORICAL CONTEXTFEASIBILITY STUDY

8. PIER DECK BRIDGE DECK CANOPY

9. GEOTECHNICALEXISTING PIERS • Five piers span the river • 76 feet span between • 141’x6’ • Concrete encased in 1.5’ granite blocks • Deep concrete T-beam

10. GEOTECHNICALEXISTING PIERS GEOTECHNICAL • Shear reinforcement • Flexural reinforcement

11. GEOTECHNICALEXISTING PIERS - ANALYSIS Flipped problem upside-down Solve for continuous load

12. GEOTECHNICALEXISTING PIERS - RESULTS • Allowable distributed load of 305.9 k/ft • Multiply by entire length of pier: 141 ft. • Divide into total area feeding into single pier: ~ 4,780 ft2 • Area load on bridge deck: 9.07 k/ft2

13. GEOTECHNICALFOUNDATION DESIGN – SOIL CONDITIONS • Mixture of compacted sand, gravel, fill, some silt • Thick layers of silt • Previous bridge loads transferred to bedrock • Largely undisturbed soil

14. GEOTECHNICALFOUNDATION DESIGN – SOIL CONDITIONS West bank

15. GEOTECHNICALFOUNDATION DESIGN – SOIL CONDITIONS East bank

16. GEOTECHNICALFOUNDATION DESIGN – BEARING CAPACITY • 2 methods considered: • Terzaghi: • qult=cNc+qNq+0.5γBNγ Model based on theory of plasticity applied to soil Requires values of shear angle, density, cohesion

17. GEOTECHNICALFOUNDATION DESIGN – BEARING CAPACITY • Meyerhof: • qallow=N/4Kd Empirical formula, uses only boring log data, simple design assumptions

18. GEOTECHNICALFOUNDATION DESIGN – BEARING CAPACITY West bank bearing capacity: 5.87 k/ft2 East bank bearing capacity: 3.91 k/ft2 Use to calculate area required to deliver loads to soil Assign length of combined footings: 26’ 6” E1: 3’ 7”. W2: 3’ 4” W1: 4’ 1”

19. GEOTECHNICALFOUNDATION DESIGN – SHEAR 1-Way shear: ϕVc=ϕ2f'cbwd≥Vu 2-Way shear:

20. GEOTECHNICALFOUNDATION DESIGN – FLEXURAL REINFORCEMENT Concrete is weak in tension Steel rebar added to take tensile loads from moments Area of steel calculated from ultimate moment: As=Mu/(ϕfyjd )

21. GEOTECHNICALFOUNDATION DESIGN – FLEXURAL REINFORCEMENT E1 W1 W2

22. GEOTECHNICALFOUNDATION DESIGN – SETTLEMENT Settlement occurs in silt layers Increasing depth -> increased area of applied load

23. GEOTECHNICALFOUNDATION DESIGN – SETTLEMENT s = Cc/(1+e0)*Hlog((σ’v0+∆σ)/σ’v0)

25. BRIDGE DECKDESIGN • 30° northwest • Upward slopes of 1:20 and 1:15 • 4 girders • No joist system • Two columns per pier • +/- 75 foot spans

26. BRIDGE DECKSAP MODEL: DESIGN • With original orientation • Added joist system • Changed average span length

27. 1 2 3 4 5 6 7 BRIDGE DECKSAP MODEL: DESIGN - SPANS

28. BRIDGE DECKSAP MODEL: JOINTS • Bottom of columns completely restrained • All other joints have no restraints or constraints • All joints welded

29. BRIDGE DECKSAP MODEL: AREA LOADS • LOADS: • Dead • Snow • Deck • Live • Wind • Earthquake

30. BRIDGE DECKSAP MODEL: MEMBER ASSIGNMENTS I BEAM/W FLANGE HSS/BOX BEAM WT SECTION

31. BRIDGE DECKSAP MODEL: MEMBER ASSIGNMENTS GIRDER JOIST COLUMN GIRDER: HSS28x6x1/2 JOIST: W8x40 COLUMN: W12x96

32. BRIDGE DECKSAP MODEL: ANALYSIS DEFLECTIONS MOMENT DIAGRAM SHEAR DIAGRAM

33. BRIDGE DECKSAP MODEL: ANALYSIS

34. BRIDGE DECKMOVING FORWARD • Thermal Loads • Seismic Conditions • Wind Uplift

35. BRIDGE DECKGRAVITY LOAD DETERMINATIONS Dead Load -Member Loads -HSS28x6x1/2 Girder Weight: 112.4 plf -W8x40 Joist Weight: 40 plf -W12x96 Column Weight: 96 plf -Total Weight: 296.351 kips -Decking Loads: 30 psf Live Load -International Building Code (IBC) and Additional Factor of Safety -100 psf Snow Load -American Society of Civil Engineering (ASCE) Code 7-10 -30psf

36. BRIDGE DECKLATERAL LOAD DETERMINATIONS Wind Load -ASCE 7-10 Standard Chapter 26 -Net Wind Pressure: 19.42 psf Seismic Load -ASCE 7-10 Standard Chapter 12 -Seismic Data Taken from United States Geological Survey (USGS) Maps -Lateral Seismic Load: 44.84 Kips Load and Resistance Factor Design (LRFD) Combinations -7 Equation Combinations -Use Maximum (Most Conservative) Combination -Treat Lateral Load and Gravity Loads Separately

37. BRIDGE DECKTRIBUTARY AREA Tributary Area of Girder Tributary Width of Girder Tributary Area of Column

38. BRIDGE DECKHSS28x6x1/2 GIRDER ANALYSIS • Moment Analysis • -Both Exterior and Interior Girders were Analyzed • -Tested for Moment Strength • -Calculated Maximum Allowable Moment for Custom Beams Using Method in American Institute of Steel Construction (AISC) Manual • -Analyzed as Simply Supported Beam

39. BRIDGE DECKW8x40 JOIST ANALYSIS • Moment Analysis • -Tested for Joist Above Columns (Takes Larger Load) • -Tested for Moment Strength • -Values for Maximum Allowable Moment Available in AISC Steel Manual • -Analyzed as Simply Supported Beam with Girder Weights as Point Loads

40. BRIDGE DECKW12x96COLUMN ANALYSIS Axial Loading -Gravity Loads are Applied Axially to Columns -Columns are not “Slender” Enough to be Analyzed for Elastic or Inelastic Buckling -Analyzed for Shear Yielding Instead -Results for 10.5 ft Column Lateral Loading -Seismic Load Treated as Point Load Acting at Top of Column -Column Tested for Maximum Allowable Moment -Not Necessary to Test for Interaction of Loads

41. BRIDGE DECKRESULTS COMPARISON Difference in Applied Moments -Moments from Hand Calculations are Larger -Example: 162.82 Kip-ft (SAP) versus 483.12 Kip-ft -Loading Cases are the Same Reasons for the Discrepancy -Difference in Member Length -Difference in Joint Connections -Greater Capacity in SAP

42. BRIDGE DECKVIBRATIONS Why Test Vibrations? -All Structures Vibrate -Pedestrian Walking Can Cause Resonance -Millennium Bridge in London How to Test Vibrations? -Find vibrational frequencies of all members and of whole system -Solve for Acceleration Limit, -Bridge Considered Safe if is less than 5.00%

43. BRIDGE DECKSOFTWARE MODELING Modeled in RAM Structural Software -Only One Panel of the Bridge will be Analyzed -RAM Structural Software only tests for one type of vibration Modeling Challenges -RAM does not allow custom beams -Only performs vibrational analysis for steel-composite decking

44. BRIDGE DECKHAND CALCULATIONS FOR VIBRATIONS Steel Design Guide #11 “Floor Vibrations Due to Human Activity” -Use Same Values as in RAM Model -Treatment of Joists and Girders -Conditions for interior bream Point Force, is 92lbs Damping Ratio, , is 0.01 -Need to find Panel Weight, W and Frequency, for both members and system -Acceration Limit is solved by:

45. BRIDGE DECKRESULTS COMPARISON Result Summary Comparisons -Produced Similar Values -Both Show the Bridge Satisfies Design Criterion

46. PIER DECKDESIGN CONSIDERATIONS • Collaboration with bridge deck • Tapered Beams • Cantilevered spans

47. 40’ 20’ 40’ 40’ 40’ PIER DECKBASIC LAYOUT

48. PIER DECKBASIC LAYOUT

49. PIER DECKTAPERED BEAMS

50. PIER DECKDEFLECTIONS • Maximum deflection of cantilever: • (L/360)*2 = 2.667 in. • Largest deflection: 1.9593 in.