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Locally Produced Structural Elements for Fast Rebuilding. Dr. Gary S. Prinz Steel Structures Laboratory (ICOM) Ecole Polytechnique Federale de Lausanne (EPFL). Introduction. Natural Disasters/ Conflicts:. - Displace large numbers of people.
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Locally Produced Structural Elements for Fast Rebuilding Dr. Gary S. Prinz Steel Structures Laboratory (ICOM) EcolePolytechniqueFederale de Lausanne (EPFL)
Introduction Natural Disasters/ Conflicts: - Displace large numbers of people - Require massive-rebuilding effort, in short timeframe. INDONESIA (2004) 9.1Mw earthquake/tsunami displaces 500,000 people 2 HAITI (2010) 7.0Mw earthquake displaces 1.2M people 1 Current Conflicts Example Natural Disasters [1] Margesson, R., and Taft-Morales, M. (2010). “Haiti earthquake: crisis and response” Congressional Research Service, Library of Congress, Washington, D.C. [2] Meisl, C.S., Safaie, S., Elwood, K.J., Gupta, R., and Kowsari, R. (2006). “Housing reconstruction in Northern Sumatra after the December 2004 Great Sumatra Earthquake and Tsunami.” Earthquake Spectra, 22(S3), S777-S802.
Introduction Typical Shelter Construction: 1) Steel frames with light cladding - Specialized steel elements - Multiple fasteners and skilled labor often required - Elements must be stored in preparation for use/or manufactured post disaster. 2) Timber frames with heavy-light cladding - Timber elements require an abundance of natural resources Time Consuming Space Consuming Skilled/trained construction (to withstand future events) Ecological impacts (deforestation) Can degrade over time (water, insects, etc.)
Introduction Typical Shelter Construction (Cont.): 3) Adobe/Cementitious Material Shelters - Requires large quantities of materials (difficult to transport) - Difficult to dismantle and move to permanent location - Heavy, and vulnerable to aftershocks/future earthquake events if unreinforced. Shelter Needs: - Cheap, locally fabricated structural elements - Mountable and dismountable by small group of unskilled labor Following 2004 Indonesia quake, residents chose temporary tents over ‘transitional shelters’ due to fear of not relocating back to villages.2 - Resistant to future disaster events - Ecologically efficient [2] Meisl, C.S., Safaie, S., Elwood, K.J., Gupta, R., and Kowsari, R. (2006). “Housing reconstruction in Northern Sumatra after the December 2004 Great Sumatra Earthquake and Tsunami.” Earthquake Spectra, 22(S3), S777-S802.
Multi-Purpose Elements Idea: Use existing materials/elements who’s use can be modified during extreme circumstances to create shelter structures. - Existing fabrication technology on large scale (modified purpose) - Fast response - No storage (minimal storage) of specialized structural elements - Can be re-used for original purpose when/if no longer needed as shelter! Shelter Fabrication Storage Exportation (Small connectors) (Local production) Storage Exportation Assembly Assembly
Multi-Purpose Elements 1) Steel-Coil Tubes: - Easily manufactured from thin galvanized steel coils - Used as ventilation ducts in industrial buildings, with existing fabrication technology available almost anywhere in world! - Good structural properties (high flexural stiffness, etc.) - Durable 2) Rain Gutters: 3) Door Frames: - Have structural properties 4) Guard Rails: - Mass production already exists in many parts of the world - Can be used for primary purpose if no longer needed
Inter-Connecting Tubular Structures Example Multi-purpose element use: - Use tube elements to form structural frames - Easily store end connectors Rigid end-connecting elements Special end-connecting elements - Divert production of tubes following disaster
Inter-Connecting Tubular Structures Steel Log-Cabin (SLC) Concept: (0.10 m3 steel) 0.46 m 0.46 m 0.46 m - Steel tubes form primary structure and function as façade - Interlocking joints allow speed and ease in assembly - Easily dismounted and relocated - No need for fasteners/skilled labor - Formed entirely from thin galvanized steel coils
Tube Connectors Crimped Connector -Attached using crimping machine -Fabricated from steel plates (same as tubes) -Can stored flat, and folded on site to facilitate large quantities.
Experimental Testing of SLC Concept Shelter Must Withstand Future Natural Events: - Aftershocks from devastating earthquakes - Recurring hurricanes/ wind storms
Testing of SLC System System-Level Lateral Resistance Tests: No intermediate shear connectors Crimped end connectors Intermediate shear connectors
Testing of SLC Concept Tested to 2kN S E N W East Wall: - Various West Wall: - Tube shear connectors - Door opening
Testing of SLC Concept S E N W North and South Wall: - Tube shear connectors - 1 cycle to 2kN - Pushover to failure
Testing of SLC Concept North Wall
Development of Tube Connectors Crimped Connector Proposed Semi-Rigid Connector -Less Material -More material -Low rotational stiffness -Possibly higher rotational stiffness -Requires crimping machine on-site -Restrained in tube by friction (no special machines required) - No mechanical fasteners!
Testing of Tube Connectors Crimped Connector Static, monotonic loading to failure Semi-Rigid Connector
Testing of Tube Connectors Crimped Connector
Testing of Tube Connectors Semi-Rigid Connector 3x increase in strength 4x increase in stiffness
Summary - High demand for shelters exists following major natural disasters - Quick response time is required to preserve both life and livelihood - Need for easily assembled locally fabricated shelters - Typical 3 stage rebuilding process (emergency shelter, transitional shelter, permanent shelter) takes too long. - Use of multi-purpose elements offer fast rebuilding solution - Possible to use existing elements for modified purpose (i.e. ventilation ducts) to create light, adaptable, durable, and locally fabricated shelter solutions. - Multiple configurations available (example SLC concept, frames, etc.) - Reduces required storage - Special connectors required - Pushover testing of SLC shelter indicates connecting elements are crucial to shelter performance, and must be developed thoroughly for good performance.
Questions? / Discussion References: [1] Margesson, R., and Taft-Morales, M. (2010). “Haiti earthquake: crisis and response” Congressional Research Service, Library of Congress, Washington, D.C. [2] Meisl, C.S., Safaie, S., Elwood, K.J., Gupta, R., and Kowsari, R. (2006). “Housing reconstruction in Northern Sumatra after the December 2004 Great Sumatra Earthquake and Tsunami.” Earthquake Spectra, 22(S3), S777-S802.