140 likes | 157 Views
Learn about the importance of monitoring structural responses to earthquakes, the instrumentation used, lessons from past earthquakes, retrofit solutions, wireless connections, and more civil engineering applications.
E N D
Monitoring Structural Response to Earthquakes using Wireless Sensor Networks Judith Mitrani June 18, 2002
Why is Structural Health Monitoring Important? • Measure changes to applied loads • Evaluate health due to accumulated damage • (weather, age, ambient vibrations, natural • disasters, “unnatural” disasters) • Evaluate structure after major event • (earthquakes, hurricanes, industrial accidents, • terrorist attacks) • Use measurements to actively or passively • control structure
Instrumentation for Monitoring • Accelerometers (acceleration) • GPS (displacement) • Rate Gyroscopes (dynamic strain) • Magnetometer (sensor bearings) • Barometer (pressure) • Thermistor (temperature)
Lessons Learned from 1994 Northridge Earthquake • Apartment buildings built with tuck-under parking in the 1960’s and the 1970’s • Configuration creates a soft-story in the ground floor and torsional modes of vibration • Important welded connections failed in hundreds of buildings • Severe damage and even collapse
CUREE Wood-Frame Test at Richmond Field Station • Build large-scale model of a typical late 1960’s apartment building with tuck-under parking, using 1964 Uniform Building Code (UBC) • Run series of scaled 1994 Northridge and 1999 Izmit Earthquakes • Asses the effect of finish materials on structure (exterior stucco, interior gypsum boards, etc.) • Test effectiveness of most common retrofit • Detect damage to structure using dense array of wireless sensors
Retrofit for Soft-Stories Close-up of Retrofit: Steel Moment Resisting Frame (mechanism for resisting lateral forces induced by earthquakes) 3-Story Wood Frame Apartment Building with Finish Materials
Why Wireless Motes? • Easy to Install • Cheap • Store Data Onboard • Expandable Sensor-Board Platform/Flexible Software • Message Hopping Capabilities • Remote Communication
Structural Testing in a Controlled Environment • Footprint of building is 16’W 32’L 27’T • Longitudinal side completely open on one side for parking • Shaking table (20’ 20’) produces 3 translational components of motion • Wireless and conventional sensors used • Software for sensors by Crossbow Technology, Inc. • 25 Motes on Glulam Beam • 25 Motes on First Story Wall
Scaled 1994 Northridge Earthquake on Wood-Frame of Apartment Building
More Civil Engineering Applications:Liquefaction Experiment in Japan
Potential Applications • Instrument Golden Gate Bridge • Prompt Post-Event Tagging of Structures • FEMA Urban Search & Rescue Team • On-line Health Monitoring (update dynamic model of structure) • Enabling Technology for Self-Repairing Structures (active control)
Mote Challenges • Storage • Communication • Numerical Computation Capability • Power • Reliability (in Japan, 50% of the motes thought they were there for “security” reasons) • Time Synchronization