Download presentation
Presentation is loading. Please wait.
1
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 1 Northridge Earthquake - Concrete Structures
2
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 2 Outline Introduction Types of Structures Typical Failure Modes Code Development Conclusions
3
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 3 Types of Structures Parking Garages –Large plan areas – number of lateral systems minimized –Not limited to a specific type of parking garage: Precast Steel components Cast in place concrete – post tensioned Hybrid systems
4
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 4 Types of Structures Parking Garages –Ramps have the effect of shortening and stiffening adjacent columns –Precast elements often difficult to tie together –Performance far worse than other structures –9 parking garages collapsed
5
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 5 Types of Structures Parking Garages –California State University –Moment resisting frame –Cast in place Ductile – lateral –Precast Brittle - gravity
6
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 6 Types of Structures Parking Garages
7
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 7 Types of Structures Office Buildings –Fared better than parking garages –Shear walls performed reasonably well Cracked but did not collapse Most could use epoxy grouting –Non-ductile structures showed brittle failure in columns and piers
8
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 8 Types of Structures Office Buildings
9
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 9 Types of Structures Residential Housing –Apartments –Precast concrete used in basement parking experienced mixed results –Concrete and wood structures above did not fare well –Post-tensioned slab failure
10
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 10 Types of Structures Residential Housing
11
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 11 Typical Failure Modes Column Failure –Tie failure –Tie distribution –Shear failure –Spiral columns Steel to Concrete Connections Tilt-up Buildings
12
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 12 Typical Failure Modes Joints –Beam hinging –Corner joints –Roof joints Beam Alignment Waffle Slab Failure
13
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 13 Column Failure Spalling Vertical Reinforcement Concentrated in Corners Inadequate Cover Older Structures – Non-ductile
14
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 14 Column Failure Tie Failure –Occurred in numerous buildings
15
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 15 Column Failure Tie Distribution
16
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 16 Column Failure Shear Failure –Holiday Inn built in 1966 –Minor damage during 1971 earthquake –Red tagged, temporary shoring installed –Vertical column reinforcement between ties buckled – added confinement not provided by the concrete –Most severe damage between 4 th and 5 th floors
17
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 17 Column Failure Shear Failure
18
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 18 Column Failure Shear Failure
19
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 19 Column Failure Shear Failure –Champaign Tower –15 story building in Santa Monica –Non-ductile moment frames & shear walls –Column spans shortened by balconies –Experienced full length shear cracks –Typical short column behavior –Structure did not collapse
20
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 20 Column Failure Shear Failure
21
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 21 Column Failure Spiral Reinforced Columns –Spiral ties are more effective than rectangular ties –Need about 30% more link steel –Columns in following pictures do not have adequate confinement –Concrete outside of steel is lost
22
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 22 Column Failure Spiral Columns
23
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 23 Steel to Concrete Connections
24
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 24 Tilt-up Building Failure Commonly Used for Industry, Warehouses 300 Structures Damaged Poor Connection Between Roof & Tilt-up Panels Caused Failures 1976 UBC – Minimum Tie Reinforcement –Post 1976 construction fared better Passed Retrofit Ordinance after Northridge –2,100 structures need to be retrofitted
25
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 25 Tilt-up Building Failure
26
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 26 Tilt-up Building Failure
27
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 27 Tilt-up Building Failure
28
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 28 Joint Failure Beam Hinging
29
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 29 Joint Failure Corner Joint –No transverse reinforcement –Insufficient anchorage for hooked bars –Widely spaced ties in members outside of the joint –No intermediate ties in column –Adequate confinement of concrete necessary
30
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 30 Joint Failure Corner Joint
31
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 31 Joints Roof Joint
32
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 32 Beam Alignment Failure Inadequate Connection of Beam to Column Most Cases Experienced Concrete Spalling
33
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 33 Beam Alignment Failure
34
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 34 Beam Alignment Failure
35
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 35 Waffle Slab Failure Few Bars Passing Through Columns Punching Failure Transfer of Moment From Slab to Column No Secondary Resistance Progressive Failure
36
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 36 Code Development Various Code Changes Over Last 40 Years Varying Seismic Resistances 1976 UBC Code Is First Code Similar to Current Codes –Separates “modern” and “older” buildings
37
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 37 1968 - Ductile Detailing in Frames 1971 - Revised Detailing for Tilt-up Structures 1976 - Design Forces Increased (Development of UBC) 1988 - Improved Detailing of Shear Walls 1994 - Shear Wall Design Provisions Introduced Code Development
38
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 38 1997 - New Requirements for Welded & Mechanical Splices for Precast Structures 1997 - Provisions for Seismic Design of Precast Concrete Structures 1997 - Requirements for Frame Members That Are Not Part of LFR System Must Be Detailed for Maximum Inelastic Response Code Development Since Northridge
39
Villanova University Dept. of Civil & Environmental Engineering CEE 8414 – Structural Dynamics Northridge Earthquake 39 Conclusions Ductile Structures Fared Better Parking Garages Suffered the Most Damage Columns Lacked Confinement Shear Failures Prevalent Code Changes Seem to be Working
Similar presentations
