Microcrack Detection in High-Performance Cementitious Materials

1. Microcrack Detectionin High-Performance Cementitious Materials Pietro Lura, Ye Guang, Kyoji Tanaka, and Ole Mejlhede Jensen

2. Early-age cracking Tokyo Institute of Technology, Yokohama, Japan

3. Microcracking (Bisschop & van Mier 2002)

4. Chemical shrinkage Autogenous shrinkage Definitions (Jensen & Hansen 2001) solid water air

5. Autogenous shrinkage in HPC • Less water • More cement • Silica fume

6. Internal microcracking • Does autogenous shrinkage lead to internal cracks? • How to detect them?

7. Superabsorbent polymers (SAP)

8. Autogenous relative humidity Paste C (w/c 0.30 + 20% SF +0.6% SAP) Paste A (w/c 0.35) Paste B (w/c 0.30 + 20% SF)

9. Autogenous strain Paste C (w/c 0.30 + 20% SF +0.6% SAP) Paste A (w/c 0.35) Paste B (w/c 0.30 + 20% SF)

10. Samples for crack detection - 3 cement pastes • 1.5, 3, and 6-mm rods • sealed at 32C

11. 10 1.2 µm ] 1 m µ [ r e t e m a i d e 0.1 r o P 0.01 1.6 MPa 0.1 1 10 100 Intrusion pressure [MPa] Properties of Gallium - melting point 29.8 C • does not wet cement paste • nontoxic

12. Gallium intrusion

13. Sample preparation • epoxy resin • grinding • polishing • crack examination: - optical microscope - BSE - EPMA

14. Crack detection (1)

15. Crack detection (2)

16. Conclusions • Cracks before intrusion can be distinguished • High shrinkage, big rod  Cracks

17. Further research • EPMA • Acoustic Emission • FE calculations