Super-Elastic Copper-Based and Iron-Based Shape Memory Alloys and Engineered Cementitious Composites for Extreme Events Resiliency
Displacement capacity and energy dissipation in conventional RC columns comes at the cost of severe damage to concrete and steel and permanent displacement of the bridges and other structures including marine structures during extreme events such as earthquake, ice load, collision by vessels and vehicles, tsunamis, check floods, and blasts. The resiliency of these structures can be significantly increased if these problems can be eliminated using shape memory alloy (SMA) and engineered cementitious composite (ECC). Comparison of residual displacement in laboratory testing of column models demonstrated that residual displacement was 86% lower than that the columns with conventional materials. The Washington State Department of transportation (WSDOT) implemented SMA/ECC in the columns of the SR-99 on-ramp bridge in downtown Seattle. With the price of Nickel-Titanium SMA (NiTi) being 90 times the mild steel cost, bridge owners may be reluctant to adopt the material. To offset SMA material costs, a new generation of Copper-Aluminum-Manganese (CAM) SMA bar that is approximately 80-90% less expensive than NiTi is emerging. The alloy is composed of 72% Copper, 17% Aluminum, and 11% Manganese. No. 10 CAM bars have been developed and were recently tested along with Headed Reinforcement Corp’s (HRC) couplers at University of Nevada – Reno (UNR) with good results, i.e. large-diameter bars for use in actual bridges have already proven to be feasible. CAM bars are connected to steel bars that extend into the column and footings or cap beams. No CAM-reinforced columns incorporating the (HRC) splice has yet been studied, however, an exploratory study was conducted by shake table testing of a column model incorporating threaded CAM bars. These bars had to be machined to a dog bone shape to avoid fracture at the threaded ends. Engineered Cementitious Composite (ECC) was used in the plastic hinge region. ECC is a fiber-reinforced cement-based concrete which has high tensile ductility and high compressive and tensile strengths.. The column performed very well in limiting residual displacement while eliminating plastic hinge damage. Another SMA type, the low-cost iron-based SMA is also emerging, although its performance under extreme loads is yet to be studied. The advantage of Fe-SMA over CAM, should it prove successful, is having material characteristics that are similar to those of conventional steel that is readily used in bridge construction while being at a low cost. The objective of this research project is to: (1) evaluate and test several innovative columns which have self-centering feature to provide minimum residual displacement after earthquake. (2) improve column serviceability after earthquake by decreasing damage and spalling of concrete within column plastic hinge region; and (3) provide cost comparison among columns having different engineered materials; and (4) develop self-centering column design specifications. Particularly, in this proposed research, the low-cycle fatigue characteristics, corrosion resistance, machinability and coupling mechanisms with traditional steel rebar, and cost of CAM and Fe-SMA super-elastic alloy (SEA) bars will be studied. Direct comparisons will be made with Nickel-Titanium (NiTi) SEAs (and traditional steel reinforcing bars as applicable) to illustrate the advantages/disadvantages of each material. If successfully demonstrated for their suitable characteristics, the CAM and Fe-SMA SEA bars could replace their NiTi counterparts at a significantly lower (up to ten times) cost and accelerate their applications in bridges. Therefore, the outcomes of this project are directly relevant to state departments of transportation and bridge and structural engineers and designers. This proposed project will build on the success of previously implemented WSDOT’s application of shape memory alloy/engineered cementitious composite (SMA/ECC) in the columns of the SR-99 on-ramp bridge in downtown Seattle while making a direct impact on advancing and securing the national transportation network.
- Record URL:
Language
- English
Project
- Status: Programmed
- Funding: $430000
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Contract Numbers:
TPF-5(491)
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Sponsor Organizations:
Alaska Department of Transportation and Public Facilities
Research Development & Technology Transfer
3132 Channel Dr
Juneau, AK United StatesNevada Department of Transportation
1263 South Stewart Street
Carson City, NV United States 89712Federal Highway Administration
1200 New Jersey Avenue, SE
Washington, DC United States 20590Washington State Department of Transportation
Transportation Building
Olympia, WA United States 98504California Department of Transportation
1227 O Street
Sacramento, CA United States 95814 -
Managing Organizations:
Washington State Department of Transportation
Transportation Building
Olympia, WA United States 98504 -
Project Managers:
Mohamedali, Mustafa
- Start Date: 20240806
- Expected Completion Date: 0
- Actual Completion Date: 0
Subject/Index Terms
- TRT Terms: Cement; Columns; Composite materials; Copper alloys; Disaster resilience; Earthquake resistant design; Earthquake resistant structures; Elasticity (Mechanics); Iron alloys; Reinforced concrete
- Subject Areas: Bridges and other structures; Design; Highways; Materials; Security and Emergencies;
Filing Info
- Accession Number: 01832549
- Record Type: Research project
- Source Agency: Federal Highway Administration
- Contract Numbers: TPF-5(491)
- Files: RIP, USDOT, STATEDOT
- Created Date: Jan 13 2022 5:36PM