554-556 Third Avenue NY, New York - PowerPoint PPT Presentation

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554-556 Third Avenue NY, New York

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... reinforcement in concrete ... reinforcement takes full shear load Several columns require additional shear reinforcement at roof level Structural Design Adjusted ... – PowerPoint PPT presentation

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Title: 554-556 Third Avenue NY, New York


1
554-556 Third Avenue NY, New York
  • Michelle L. Mentzer
  • Structural Option

2
Outline
  • Building Information
  • Structural Background
  • Problem Statement
  • Proposal
  • Structural Design
  • Architecture
  • Construction Management
  • Conclusions

3
Design Team
  • Owner
  • Maidman Development
  • Architect
  • H. Thomas OHara Architects
  • Structural Engineer
  • DeSimone Consulting Engineers
  • CM
  • BrawnMade Construction
  • Tishman Staff
  • MEP Engineer
  • MGJ Associates

4
Location
  • Midtown Manhattan
  • 37th Street and Third Avenue

5
Building Information
  • 30 Stories
  • 120,000 sq. ft.
  • 3600 sq. ft. Footprint
  • Residential occupancy
  • Ground floor
  • Retail space
  • Residential lobby
  • Fifth floor
  • Fitness room
  • Living units

Ground Floor
Fifth Floor
6
Building Information
  • Residential occupancy
  • Floors 2-24
  • Marriott ExecuStay Suites
  • Floors 25-30
  • Double height condominiums

Floor 8-24
Floor 25-30
7
Structural Background
  • Gravity System
  • Flat plate concrete construction
  • Floors 6-30 cantilever over buildings on 2 sides
  • Flat plate supports cladding load at cantilevers
  • Column walks shift loads toward building interior
  • Post-tensioning in slabs and columns near walks
  • Mat Foundation

8
Structural Background
  • Column Walk
  • Column 12 on floor 5
  • Column 18 on floor 8
  • Resembles a wall between levels

9
Structural Background
  • Lateral System
  • Wind loads govern for design loads
  • Shear wall core
  • Relatively uniform throughout building
  • Link beams connect walls above door openings
  • Extends above main roof to enclose penthouse

10
Problem Statement
  • Architectural style limited by thin cantilever
    slabs that cannot support heavy cladding
  • ADOSS model proved slabs would fail with heavy
    cladding load
  • Metal panels are the only option

11
Proposal
  • Develop an additional support system capable of
    carrying excess cladding loads
  • Steel trusses at roof level
  • Tension members hanging from trusses carry loads
  • Change façade through architectural precast
    panels and roof trusses
  • Determine impact these changes have on
    construction schedule, site layout and cost

12
Structural Design
  • Truss Design
  • Braced frames replace shear walls above roof
  • System modeled in RISA
  • Applicable load cases considered
  • Continuous top bottom chords
  • Pins at all other locations
  • Fixed supports at columns and shear walls

13
Structural Design
  • Supporting Columns
  • Located wherever a truss joint coincides with a
    column/shear wall
  • Connections not necessarily centered on column

14
Structural Design
  • Truss and Braced Frame Member Sizes
  • Maximum consistency
  • Lightest weight sections where possible
  • All wide flange shapes

W14x90
W21x83
W14x211
15
Structural Design
  • Truss Connections
  • Heavy bracing type connections at truss joints
  • Base plate and anchor bolts connect bottom chord
    to columns or shear walls

16
Structural Design
  • Tension Members
  • W14x22, W14x34, W14x68
  • Largest members at top
  • Reduce size as allowable
  • Hanger connection
  • Tension splices where necessary

17
Structural Design
  • Slabs
  • No gravity load transferred from cladding to
    slabs
  • Cladding directly supported by columns
  • Angles welded to column flanges and bolted to
    panels
  • Lateral ties from panels to slab
  • Transfer wind forces to rigid diaphragm

18
Structural Design
  • Column Walk
  • Added compression in column creates more tension
    in slab near column 18 on level 8
  • Initially gravity load is fully vertical
  • As core reinforcement in column slants, gravity
    force creates horizontal component at slab level
  • Horizontal tension at level 8 is resisted by
    post-tensioning
  • One additional 1 3/8 Dywidag in level 8 slab
  • Original design calls for 5 Dywidags

19
Structural Design
  • Column Capacities
  • Column capacities checked at critical locations
    using PCA Column
  • All support columns checked for gravity loads and
    moments from eccentricity
  • Dimensions and reinforcement increase in some
    areas
  • Exterior columns not supporting truss also
    checked
  • Supporting extra loads directly from cladding
  • Sufficient as designed to carry cladding loads

20
Structural Design
  • Tension in Columns
  • Created by moment from cantilevered truss
  • Resisted by reinforcement in concrete

21
Structural Design
  • Shear in Columns
  • Lateral loads from trusses and braced frames
    transferred directly to columns at roof level
  • Rigid diaphragm redistributes load at floor
    thirty
  • Where columns are in tension, shear reinforcement
    takes full shear load
  • Several columns require additional shear
    reinforcement at roof level

22
Structural Design
  • Adjusted Column Sizes

23
Structural Design
  • Overturning Moments
  • 0.9D1.6W load case critical
  • Overturning caused by combination of wind and
    truss forces
  • Building overturning resisted by self weight and
    foundation
  • Safety factor (critical case)2.5
  • Moments cause tension and compression in opposite
    flanges of shear wall core
  • Spreadsheets used to check reinforcement for
    tension and compression in shear walls
  • Sufficient as designed to resist tension and
    compression loads

24
Architecture
Cladding
  • Precast architectural panels
  • Architectural Precast Association
  • Acid-etched medium with yellow pigment
  • Red and beige tones blend with surroundings
  • Hint of yellow sets it apart and ties in idea of
    light associated with the name Aurora

25
Architecture
  • Truss Design
  • Similar truss idea used in IBM Building,
    Baltimore, MD
  • Shape of trusses emphasizes cantilevers
  • Maximum symmetry possible
  • Add interest and detract from tall slender
    penthouse
  • Visible from street level

26
Architecture
  • Column Dimensions Changes
  • West window shifts
  • No other substantial changes to layout necessary

27
Architecture
Before
After
28
Construction Management
  • Sequencing
  • Finish pouring concrete before erecting steel
  • Enclosures cannot begin until after steel work is
    complete
  • Crane only needed for one task at a time

29
Construction Management
Site Logistics
  • Tower crane capacity 8 tons
  • Maximum member weight 5 tons
  • Maximum panel weight 7.5 tons
  • Street parking behind crane

30
Construction Management
  • Schedule Impact
  • Durations from MC2
  • Steel adds approx. 1.5 months to schedule
  • Panels take about the same amount of time to hang
  • Overall extension of schedule 1.5 months

31
Construction Management
  • Cost
  • Initial overall cost
  • R.S. Means 18.2 million
  • Structural steel
  • MC2 220,000
  • Panels (MC2)
  • Metal panels 960,000
  • Architectural precast panels 2,200,000
  • Proposal adds 1.5 million or 8.6 of initial cost

32
Conclusions
  • Trusses add architectural interest and allow use
    of a heavier cladding system
  • No substantial interruptions to interior layout
  • 1.5 million cost increase
  • 1.5 month schedule increase

33
Conclusions
  • Recommendation
  • Revenue from architectural enhancements will not
    likely offset added costs and schedule delays
  • Use original metal panel cladding system

34
Acknowledgements
  • DeSimone Consulting Engineers
  • Penn State AE Faculty
  • AE Class of 2003
  • My Family

35
Questions
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