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CHRISTOPHER HIGGINS, Ph.D., P.E.

Development and Application of Titanium Alloy Bars for Shear and Flexural Strengthening Reinforced Concrete Bridges. CHRISTOPHER HIGGINS, Ph.D., P.E. Overview. Background Experimental Test Results ASTM Specification AASHTO-LRFD Design Guide Future Directions.

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CHRISTOPHER HIGGINS, Ph.D., P.E.

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  1. Development and Application of Titanium Alloy Bars for Shear and Flexural Strengthening Reinforced Concrete Bridges CHRISTOPHER HIGGINS, Ph.D., P.E.

  2. Overview • Background • Experimental Test Results • ASTM Specification • AASHTO-LRFD Design Guide • Future Directions

  3. Strengthening Existing Bridges • Post-tensioning • Wrapping/confining • Carbon fiber reinforced polymer (CFRP) laminate • Near-surface mounted (NSM) • Carbon fiber reinforced polymer rod/strip • Glass fiber reinforced polymer (GFRP) rod • Stainless steel bars FRP rods and laminates fail due to bond and anchorage and materials arenonductile Concerns with corrosion at surface for most metals, relatively low strength (stainless reinforcing bars) Flexural girder strengthening with CFRP laminate http://aslanfrp.com/Aslan400/Resources/Aslan400.pdf Strengthening with NSM CFRP strips http://aslanfrp.com/Aslan500/aslan500-pg2.html

  4. Ductile FRP?Environmentally insensitive material with high strength, well defined properties, good surface bonding characteristics along length, and efficient mechanical anchorages

  5. Titanium Alloy Material Properties (Ti-6Al-4V) 1380 1210 1030 860 Stress (MPa) 690 520 340 170 Extensometer Strain (in/in)

  6. Titanium Alloy Material Properties (Ti-6Al-4V) • Aircraft fastener quality (6% Aluminum 4% Vanadium) • Well-defined, high strength, and ductile (limited hardening->protects bond, structural fuse) • High fatigue resistance (CAFL~ 75 ksi), low notch sensitivity • Impervious to chlorides due to stable oxide layer • Coeff. of thermal expansion (8.6me/oC) (8-12 Con. and 12 St.) • Conventional fabrication (shear, cut, and bend) • Relatively lightweightof 281 lb/ft3(steel 1.7x) • Bends facilitate anchorage

  7. Strengthening – Flexure and Diagonal Tension (Shear) 26 full-scale specimens

  8. Fabrication and Installation ACI 440.2R • Groove Spacing • Groove dimensions

  9. Durability High Cycle Fatigue and Freeze-Thaw Combined Largest combined structural-environmental testing chamber Thermocouples at 0.5, 1.5, and 3 in. ensure temperature targets • 1.6 million cycles @ steel stress range >50 years of life.

  10. T Beam Experimental Results – Durability (s=10 in.) TiAB TiAB Env. and Fatigue Base

  11. Field Demonstration: Mosier Bridge Over I84 DL produces M- LL produces M+

  12. Results • Reserve strength of Ti girder substantially exceeds factored demands • Strengthening of failed girder better response than unfailed girder Predicted strength w Ti Reserve Capacity Design • Design strength of Ti girder exceeds factored demands even with conservative assumptions

  13. 30% less expensive than CFRP

  14. Main Committee: Committee B10 – Reactive and Refractory Metals and Alloys Sub-Committee: Committee B10.01 on Titanium ASTM Specification for NSM Titanium

  15. Approved Nov. 2018

  16. ASTM B1009-18 Requirements: • Tensile properties (Class 120 and 130) • Chemical requirements • Bond strength • Cross-Sectional area calculation • Bending requirements

  17. Guide Balloted and Approved by COBS 2019 • “Guide for Design and Construction of Near-Surface Mounted Titanium Alloy Bars for Strengthening Concrete Structures” • AASHTO-LRFD Format • General Conditions • Materials • Construction • Installation • Design • Flexure and Shear (MCFT)

  18. Design Guide • Conventional analysis methods • Design TiABs at yield if conditions are met • Includes environmental durability factor (epoxy) • 3 Limit states for flexure and 1 for shear • Strength • Service (check bond stress at cutoffs and where retrofitted strength above base capacity) • Fatigue (not of TiAB but of reinforcing steel) • Comprehensive design example (shear and flexure)

  19. Development and Application of Titanium Alloy Bars for Shear and Flexural Strengthening Reinforced Concrete Bridges Christopher Higgins, Ph.D., P.E.

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