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PEER Van Nuys Testbed

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Designed in 1965 & Constructed in 1966. Seven Stories, 65' ... Non-Ductile Exterior Concrete Frame. Interior Slab-Column Frames. Masonry infill in four bays ... – PowerPoint PPT presentation

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Title: PEER Van Nuys Testbed


1
FEMA 356 Evaluation
  • PEER Van Nuys Testbed
  • May 23, 2002
  • by Jon Heintz, S.E. Robert Pekelnicky

2
Van Nuys Holiday Inn
3
Van Nuys Holiday Inn
  • Designed in 1965 Constructed in 1966
  • Seven Stories, 65 Height
  • 150 x 61 Approximate Plan
  • Non-Ductile Exterior Concrete Frame
  • Interior Slab-Column Frames
  • Masonry infill in four bays
  • Building Instrumented

4
Typical Floor Plan
5
Exterior Frame Elevation
North Elevation
South Elevation
6
Evaluation Methodology
  • Perform ASCE 31 (FEMA 310) Tier 1 screening.
  • Create 3-D linear dynamic model.
  • Determine Modes Periods
  • Evaluate Torsion
  • Perform 2-D nonlinear pushover of longitudinal
    exterior and interior frame.

7
Tier 1 Deficiencies
  • Soft First Story (44 of 2nd story)
  • Quick Check Column Shear gtgt Capacity
  • Members Shear Controlled
  • Weak Column / Strong Beam (Mc0.8Mb)
  • Inadequate Lap Splices
  • Minimal confinement reinforcement
  • Stirrups Ties w/o seismic hooks

8
3-D Model
9
Elastic Model Assumptions
  • Concrete strength fce 150 of specified
  • Frame beams modeled with ACI effective slab
    widths
  • Interior flat slabs modeled as effective beams
    (Luo et. al. 1994, Pecknold 1975)
  • Effective stiffnesses used
  • Columns 50 of Gross (FEMA 356)
  • Beams 50 of Gross (FEMA 356)
  • Slabs 33 of Gross (Vanderbilt 1983)
  • Beam-Column Joints partially rigid
  • Columns fixed at pile cap

10
Transverse Fundamental Mode
T 1.27 sec. PMR 85
11
Longitudinal Fundamental Mode
W/O Infill T 1.20 sec. PMR 89 W/ Infill T
1.12 sec. PMR 77
12
Plan Torsion Fundamental Mode
W/O Infill T 1.03 sec. PMR 0 W/ Infill T
1.00 sec. PMR 8
13
Comparison with Recorded Periods (longitudinal)
  • Pre-1971 T0.52 sec
  • San Fernando
  • early T0.7 sec
  • peak response T1.5 sec
  • Northridge
  • early T1.5 sec
  • Elastic model
  • FEMA 356 empirical equation T0.73 sec
  • T1.2 sec w/o infill

14
Plan Torsional Irregularity
  • Torsion triggers amplified target disp.
  • Infill has 1 expansion gap between frame.
  • Two models used one with infill panels and one
    without infill panels.
  • Models compared to determine whether presence of
    infill has dramatic effect.
  • 3-D model results did not trigger ?
  • 3-D model results did not show significant
    response modification for higher modes

15
2-D Nonlinear Pushover
  • Model longitudinal direction as critical
  • Include both exterior and interior frames.
  • 2 exterior frames 40 of stiffness
  • 2 interior frames 60 of stiffness

16
2-D Nonlinear Pushover
  • Place hinges at all member ends
  • Use criteria in FEMA 356 for hinge properties
  • Flexural hinges limited by
  • flexural strength
  • shear strength
  • lap splice strength
  • embedment (development)
  • Include two load patterns
  • Uniform based on floor mass
  • Modal based on CQC combination of Modes

17
Pushover Curves
Target dt 29 inches (10/50) Target dt 7
inches (50/50)
18
Hinge locations
  • Flexural hinges at base of columns (lap-splice
    controlled)
  • Flexural hinges below 2nd floor beams
  • Shear controlled hinges in 1st, 2nd, 3rd floor
    beams
  • Still need to check
  • shear in columns
  • shear in joints
  • local hinge rotation limits
  • slab punching shear on interior frames

19
Response Spectra
20
Roof Displacement
  • Peak displacement during Northridge
  • 9.2 inches
  • Calculated displacement capacity is significantly
    less. Why?
  • Conservative hinge assumptions? (actual elements
    can go farther)
  • Conservative limitations on lap splice
    capacities?
  • Conservative accounting for degradation (C3)
  • Higher Mode Effects? (not a factor based on our
    linear model results)
  • Plastic hinge not a reliable EDP?

21
Summary
  • ASCE 31 Tier 1 does a good job of predicting
    possible deficiencies
  • FEMA 356 does reasonable job of predicting
    cracked stiffness, in lieu of more detail
  • FEMA 356 NSP yields very conservative results for
    this building
  • Can PEER Methodology more accurately predict
    recorded response?
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