NEHRP Clearinghouse
displaying 1 - 8 results in total 8
O'Rourke, M. J.; Solla, E.
Seismic Risk Analysis of Latham Water District, Albany, New York. (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Applied Science and Research Applications., June 1977, 65 p.
Keywords: Earthquake resistant structures; Water pipes; Buried pipelines; Risk analysis; Seismic risk; Subsurface structures; Structural design; Albany County (New York); Sewer pipes; Earthquake engineering; New York; Latham Water District; Pipelines; Earthquakes; Dynamic structural analysisO'Rourke, M. J.; Wang, L. R. L.
Earthquake Response of Buried Pipelines. (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Applied Science and Research Applications., March 1978, 17 p.
Keywords: Seismic design; Earthquake resistant structures; Water pipes; Seismic waves; Buried pipelines; Subsurface structures; Earth movements; Sewer pipes; Ground motion; Earthquake engineering; Pipelines; Earthquakes; Dynamic structural analysisWang, L. R. L.; Cheng, K. M.
Seismic Response Behavior of Buried Pipelines. (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Applied Science and Research Applications., June 1978, 16 p.
Keywords: Earthquake resistant structures; Water pipes; Seismic waves; Buried pipelines; Subsurface structures; Earth movements; Dynamic response; Ground motion; Earthquake engineering; Sewer pipes; Pipelines; EarthquakesPikul, R. R.; Wang, L. R. L.; O'Rourke, M. J.
Seismic Vulnerability of the Latham Water Distribution System. A Case Study (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Applied Science and Research Applications., September 1978, 42 p.
Keywords: Earthquake resistant structures; Water pipes; Buried pipelines; Subsurface structures; Seismic risk; Structural design; Albany County (New York); Sewer pipes; Earthquake engineering; New York; Latham Water District; Pipelines; Earthquakes; Dynamic structural analysisWang, L. R. L.; Fung, R. C. Y.
Seismic Design Criteria for Buried Pipelines. (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Applied Science and Research Applications., September 1978, 23 p.
Keywords: Seismic design; Earthquake resistant structures; Water pipes; Seismic waves; Buried pipelines; Subsurface structures; Biaxial stresses; Sewer pipes; Earthquake engineering; Earthquakes; Pipelines; Design criteriaWang, L. R. L.; O'Rourke, M. J.; Pikul, R. R.
Seismic Vulnerability, Behavior and Design of Buried Pipelines, Final Report of Phase I Study. (Seismic Vulnerability, Behavior and Design of Underground Piping Systems).
National Science Foundation, Washington, DC. Engineering and Applied Science., March 1979, 148 p.
Keywords: Pipe joints; Seismic waves; California; Buried pipelines; Risk analysis; Seismic risk; Albany (New York); Subsurface structures; Earth movements; Ground motion; Earthquake engineering; San Fernando earthquake; New York; Piping systems; Pipelines; Earthquakes; Dynamic structural analysisParnes, R.; Weidlinger, P.
Dynamic Response of an Embedded Pipe Subjected to Periodically Spaced Longitudinal Forces.
National Science Foundation, Washington, DC. Engineering and Applied Science., August 1979, 34 p.
Keywords: Earthquake resistant structures; Buried pipelines; Subsurface structures; Dynamic response; Ground motion; Earthquake engineering; Soil structure interactions; Pipelines; Earthquakes; Dynamic structural analysisParnes, R.
Static Analysis of an Embedded Pipe Subjected to Periodically Spaced Longitudinal Forces.
National Science Foundation, Washington, DC. Engineering and Applied Science., August 1979, 23 p.
Keywords: Earthquake resistant structures; Static loads; Buried pipelines; Subsurface structures; Dynamic response; Ground motion; Earthquake engineering; Soil structure interactions; Static structural analysis; Pipelines; Earthquakes; Dynamic structural analysis