NEHRP Clearinghouse
displaying 1 - 10 results in
total 19
Eberhard, M. O.; Sozen, M. A.
Experiments and Analyses to Study the Seismic Response of Reinforced Concrete Frame-Wall Structures with Yielding Columns.
National Science Foundation, Washington, DC., September 1989, 440 p.
Identifying Number(s): UILU-ENG-89-2007
Keywords: Dynamic response; Earthquake engineering; Dynamic tests; Loads (Forces); Graphs (Charts); Framed structure; Structural design; Mechanical properties; Reinforced concrete; Walls; Displacement; Columns (Supports); Structural analysis; Shear strengthBenjamin, J. R.; Webster, F. A.
Optimal Reliability of Lifeline Levee Systems Under Multiple Natural Hazards.
National Science Foundation, Washington, DC., August 1, 1984, 138 p.
Identifying Number(s): JBA-109-030-H-01
Keywords: ; Failure; Hazards; Water flow; Graphs (Charts); Earthquakes; Levels; Probability theory; Subsidence; Bursting; Landslides; Stability; Flooding; Mathematical models; Flood control; Shear strength; Drawdown; DisastersTena-Colunga, A.; Abrams, D. P.
Response of an Instrumented Masonry Shear Wall Building with Flexible Diaphragms during the Loma Prieta Earthquake.
National Science Foundation, Washington, DC., December 1992, 112 p.
Identifying Number(s): UILU-ENG-92-2025
Keywords: Dynamic response; Loma Prieta earthquake; Earthquake engineering; Masonry; Walls; Office buildings; Palo Alto (California); Diaphragms (Mechanics); Shear strengthFattal, S. G.
Research Plan for Masonry Shear Walls.
June 1993, 36 p.
Identifying Number(s): NISTIR-5117
Keywords: ; Research management; Building codes; Earthquake engineering; Loads (Forces); Masonry; Seismic design; Walls; Construction; Design standards; Shear strength; Compressive strengthKariotis, J. C.; Waqfi, O. M.
Recommended Procedure for Calculation of the Balanced Reinforcement Ratio.
National Science Foundation, Washington, DC., February 1992, 74 p.
Identifying Number(s): REPT-2.3-7
Keywords: ; Earthquake engineering; Reinforcing steels; Masonry; Seismic design; Flexural strength; Reinforced concrete; Walls; Mathematical models; Shear strength; Compressive strengthPhan, L. T.; Todd, D. R.; Lew, H. S.
Strengthening Methodology for Lightly Reinforced Concrete Frames-II. Recommended Calculation Techniques for the Design of Infill Walls.
May 1994, 35 p.
Identifying Number(s): NISTIR-5421
Keywords: Dynamic response; Reinforcement (Structures); Earthquake engineering; Loads (Forces); Frames; Reinforced concrete; Infilled walls; Displacement; Concrete structures; Shear strength; Dynamic structural analysisMattock, A. H.
Shear Transfer Under Cyclically Reversing Loading Across an Interface Between Concretes Cast at Different Times.
National Science Foundation, Washington, D.C., June 1977, 100 p.
Identifying Number(s): SM77-1
Keywords: Shear transfer; Earthquake engineering; Shear properties; Concrete construction; Precast concrete; Cracks; Construction joints; Cyclic loads; Shear strengthPark, Y. J.; Reinhorn, A. M.; Kunnath, S. K.
IDARC: Inelastic Damage Analysis of Reinforced Concrete Frame - Shear-Wall Structures.
National Science Foundation, Washington, DC., July 20, 1987, 195 p.
Identifying Number(s): NCEER-87-0008
Keywords: Computer programs; Earthquake resistant structures; IDARC (Inelastic Damage Analysis of Reinforced Concrete Frame Shear Wall Structures); Reinforced concrete; Computer applications; Static structural analysis; Seismology; Shear strength; Dynamic structural analysisGulec, C. K.; Whittaker, A. S.
Performance-Based Assessment and Design of Squat Reinforced Concrete Shear Walls.
National Science Foundation, Arlington, VA. Earthquake Engineering Research Centers Program., September 15, 2009, 664 p.
Identifying Number(s): MCEER-09-0010
Keywords: Boundary elements; Elevation; Finite elements; Earthquakes; Reinforced concrete; Loading (Structural); Walls; Ibarra-Krawinkler pinching model; Fatigue (Tests); Stiffness degradation; Shear strengthScott, G. A.
Dynamic Response of Jointed Rock Masses.
National Science Foundation, Washington, DC., January 1982, 124 p.
Keywords: Dynamic response; Rocks; Theses; Static loads; Earthquake engineering; Computer programs; Earthquakes; Rock properties; Water pressure; Shear strength