Low-Cycle Fatigue Criteria for the Seismic Design of Concrete Structures with High Strength Reinforcing Steel

Low-Cycle Fatigue Criteria for the Seismic Design of Concrete Structures with High Strength Reinforcing Steel

This project will help establish cyclic deformation (strain) demands and acceptance criteria for low-cycle fatigue resistance of steel reinforcement in concrete structures subjected to earthquakes. Together with supporting data and information from other research involving testing of reinforced concrete components, the data on cyclic loading demands and reliability- based acceptance criteria that are developed through this project will facilitate the safe use of HS reinforcement in seismic force resisting systems.

The key objectives of this project are to (1) develop a reliability-based methodology for determining the minimum required low-cycle fatigue resistance of steel reinforcement in the seismic design of concrete structures, (2) apply the methodology to assess the cyclic strain/deformation demands in concrete components for a series of archetype concrete shear wall and frame building structures subjected to earthquakes, and (3) develop acceptance criteria for steel reinforcement in concrete structures, which are consistent with the seismic reliability criteria for buildings in ASCE 7 and related building code standards.

• Grant Details

  Project

  Low-Cycle Fatigue Criteria for the Seismic Design of Concrete Structures with High Strength Reinforcing Steel

  Grantee

  Stanford University

  Category

  Concrete

  Subcategory

  High-Strength Rebar

  Grant #

  02-16

  Award Amount

  $165,000

  Grant Period

  May 2016 - March 2018

  Grant Status

  Complete

  Principal Investigators

  Gregory G. Deierlein, J.A. Blume Professor of Engineering

  Industry Champions

  Dominic Kelly, Simpson Gumpertz and Heger, Inc., Boston; Andrew Taylor, KPFF, Seattle, David Fields, Magnusson Klemencic Associates, Seattle; Ronald Hamburger, Simpson Gumpertz and Heger, Inc., San Francisco

  CPF Allies

  American Concrete Institute Foundation (ACIF), Concrete Reinforcing Steel Institute (CRSI)

• Resources / Downloads

  • Low Cycle Fatigue Effects on the Seismic Performance of Concrete Frame and Wall Systems with High Strength Reinforcing Steel, 2019

• Related Research

  • 02-19 Normal- and High-Strength Continuously Wound Ties
  • 01-19 Foundation Mats with High Strength Steel Reinforcement
  • 05-18 Development of Large High-Strength Headed Reinforcing Bars
  • 03-17 Reinforced Concrete Coupling Beams with High-Strength Steel Bars
  • 02-17 Development and Splice Lengths for High-Strength Reinforcement
  • 03-16 Acceptable Elongations and Low-Cycle Fatigue Performance for High-Strength Reinforcing Bars
  • 01-15 Setting Bar-Bending Requirements for High-Strength Steel Bars
  • 06-14 High-Strength Steel Bars in Reinforced Concrete Walls: Influence of Mechanical Properties of Steel on Deformation Capacity
  • 04-14 Performance Characterization of Beams with High-Strength Reinforcement
  • 04-13 Assessment of Yield Stress Measurement Methods for Reinforcing Bars
  • 03-14 Development of Tentative Specification for High-Strength Steel Reinforcing Bar
  • 05-13 The Development Of A Roadmap On The Use Of High- Strength Reinforcement In Reinforced Concrete Design
  • 01-13 The Impact of High-Strength Reinforcing Steel on Current Design Practice
  • 08-11 Anchorage of High-Strength Reinforcing Bars