Shear testing of prestressed concrete girders

1. Challenge the future Delft University of Technology Shear Testing of Prestressed Concrete Bridge Girders Eva Lantsoght , Gabriela Zarate, Fengqiao Zhang, Minkook Park, Yuguang Yang

2. 2Shear Testing of Prestressed Concrete Girder Bridges Outline • Introduction • Experiments • Results • Recommendations for practice • Summary and conclusions Failure of HPZ03, north side

3. 3Shear Testing of Prestressed Concrete Girder Bridges Introduction: Assessment of PC girder bridges (1) • Prestressed concrete girder bridges in the Netherlands (+- 70) • Prestressed girders • Slab cast in between girders, transverse prestressing • Diaphragm beams • First research: capacity of slabs • Compressive membrane action • Fatigue capacity • Sufficient capacity based on experiments • Then: PC girders UC > 1 for shear-tension

4. 4Shear Testing of Prestressed Concrete Girder Bridges Introduction: Assessment of PC girder bridges (2) Slab-between-girder bridge during construction, 1965

5. 5Shear Testing of Prestressed Concrete Girder Bridges Introduction: Assessment of PC girder bridges (3) Amir, S., Van der Veen , C., Walraven, J. C., & de Boer, A. (2016). Experiments on Punching Shear Behavior of Prestressed Concrete Bridge Decks. Aci Structural Journal, 113(3), 627-636.

6. 6Shear Testing of Prestressed Concrete Girder Bridges Introduction: Helperzoom girders (1) • Taken from demolished slab-between- girder bridge • Tendon profile • Anchor end and tapered part • Beams sawn in half for handling in lab • 1.11 m height • 10.51 m – 12.88 m length • Single concentrated load • a = 2.903 m & a = 4.4 m • 4 experiments / 4 girders

7. 7Shear Testing of Prestressed Concrete Girder Bridges Introduction: Helperzoom girders (2)

8. 8Shear Testing of Prestressed Concrete Girder Bridges Introduction: Helperzoom girders (3) Cross-section A-Aʹ Cross-section B-Bʹ (C.L)

9. 9Shear Testing of Prestressed Concrete Girder Bridges Introduction: Goal of experiments • Goal of research: • Shear-tension capacity (UCs insufficient) • Validate NLFEA • Failure mode • Effect of non-code-compliant stirrups?

10. 10Shear Testing of Prestressed Concrete Girder Bridges Experiments: Test setup (1)

13. 13Shear Testing of Prestressed Concrete Girder Bridges Experiments: Instrumentation (1) • LVDT measurements • Laser distance finders • Acoustic emission sensors • Smart aggregates • Digital image correlation

14. 14Shear Testing of Prestressed Concrete Girder Bridges Experiments: Instrumentation (2) Sensor plan for HPZ03

15. 15Shear Testing of Prestressed Concrete Girder Bridges Results: Material parameters • Concrete: core testing => C55/67 • Prestressing steel tested in lab • Mild steel tested in lab: QR40, 454 MPa • Mild steel = plain bars y = 4086.8x + 1605.6 0 400 800 1200 1600 2000 2400 0 0.02 0.04 0.06 0.08 Stress(MPa) Strain (-)

16. 16Shear Testing of Prestressed Concrete Girder Bridges Results: prestressing level • 3 methods: • cracking moment • full sectional analysis (R2K & layered model) • Measurements • cutting through tendon • Drilling cores test strain (με) stress (MPa) % 1 3107 575 66 2 5606 1037 119 3 561 1039 120 4 5684 1052 121 Average 107 Cutting HPZ03

17. 17Shear Testing of Prestressed Concrete Girder Bridges Results: Loading protocol Loading protocol of HPZ03

18. 18Shear Testing of Prestressed Concrete Girder Bridges Results: Capacities and failure modes HPZ01 HPZ02 HPZ03 HPZ04 Date 27/06/2019 12/09/2019 14/11/2019 16-17/12/2019 lgirder 10.51 m 11.1 m 12.28m 12.88 m lspan 9.6 m 9.6 m 9.6 m 9.6 m a 2903 mm 2903 mm 4400 mm 4400 mm a/d 3.6 3.6 4.9 4.9 Fcrack 965 kN 1001 kN 1050 kN 1100 kN Fshearcrack 1344 kN 1299 kN 1250 kN 1450 kN FShear-tension crack 1480 kN 1350 kN 1600 kN 1750 kN Fmax 1892.7 kN 1849 kN 1990 kN 2380 kN δfail 51.5 mm 39.66 mm 60.91 mm 68.6 mm Failure mode SC/FS SC/FS SC/CC SC/CC

19. 19Shear Testing of Prestressed Concrete Girder Bridges HPZ04 test

20. 20Shear Testing of Prestressed Concrete Girder Bridges Results: DIC measurements HPZ02

21. 21Shear Testing of Prestressed Concrete Girder Bridges Global strain distribution with 20 mm lens Local strain distribution with 90 mm lens Crack opening (w) in x-direction Crack sliding (∆) in y-direction HPZ02 DIC analysis

22. 22Shear Testing of Prestressed Concrete Girder Bridges Results: AE monitoring 1st bending crack Shear cracks

23. 23Shear Testing of Prestressed Concrete Girder Bridges Results: Comparison to predicted capacity

24. 24Shear Testing of Prestressed Concrete Girder Bridges Results: Influence of prestressing level

25. 25Shear Testing of Prestressed Concrete Girder Bridges Results: Influence of prestressing level

26. 26Shear Testing of Prestressed Concrete Girder Bridges Results: Influence of position of load • Failure mode: • For a = 2903 mm: Shear cracking, then shear-compression failure • For a = 4400 mm: Shear cracking, then local crushing of concrete zone or crushing of compression field 0 500 1000 1500 2000 2500 3000 0 10 20 30 40 50 60 70 80 Laod(kN) Deflection at loading point (mm) HPZ01 HPZ02 HPZ03 HPZ04

27. 27Shear Testing of Prestressed Concrete Girder Bridges Results: evaluation of angle of compression field HPZ03

28. 28Shear Testing of Prestressed Concrete Girder Bridges Recommendations for practice: Measurement techniques • AE measurements can capture cracking early • DIC: analysis of aggregate interlock • LVDT and DIC: analysis of angle of compression field • Lasers: need sufficient range for displacement under load Rotating angle for HPZ03

29. 29Shear Testing of Prestressed Concrete Girder Bridges Recommendations for practice: Load testing of PC girder bridges • Ongoing research on load testing of bridges • Collapse test of Vecht Bridge in 2016 • Relate insights from research to collapse test => Future work Collapse test of Vecht Bridge, 2016

30. 30Shear Testing of Prestressed Concrete Girder Bridges Recommendations for practice: Assessment of PC girder bridges • Ongoing research • System behavior and transverse flexural distribution • Best option: NLFEA (RTD 1016:2017) • For sectional analysis: promising results with draft new Eurocode and Response-2000 Response 2000 vs experiments Migalski, J. (2020). Analytical, Numerical and Experimental Analysis of Helperzoom Post-Tensioned TGirders. Delft University of Technology,

31. 31Shear Testing of Prestressed Concrete Girder Bridges Next steps • Finalize analysis of test results • Assessment of these girder types • Use insights from monitoring techniques • (short-term) field tests / load testing • long-term monitoring

32. 32Shear Testing of Prestressed Concrete Girder Bridges Summary and Conclusions • 4 experiments on PC girders failing in shear • Failure modes related to concrete crushing • Increase in shear capacity past inclined cracking load • Non-code-compliant stirrups • Use of AE, SA, DIC + traditional measurement techniques • Future work: assessment of PC girder bridges + recommendations for field testing

33. 33Shear Testing of Prestressed Concrete Girder Bridges Contact: Eva Lantsoght E.O.L.Lantsoght@tudelft.nl elantsoght@usfq.edu.ec

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