Bond induced concrete splitting failure in textile-reinforced fine-grained concrete: Fid-Bau Portal

Bond induced concrete splitting failure in textile-reinforced fine-grained concrete

Tekle, Biruk Hailu / Messerer, Dennis / Holschemacher, Klaus

Highlights • Compaction improves splitting resistance of vertically cast specimens. • Top-cast specimens have a lower splitting resistance than bottom-cast specimens. • Higher splitting stress is generated orthogonal to the plane of the textile. • The main cause of splitting failure is the fiber strand’s varying cross-section. • Bond distribution depends on the cross-section variation along the fiber strand.

Abstract Textile-reinforced concrete is an innovative combination of high-performance fine-grained concrete and textile reinforcements. This combination allows the production of thin, efficient, and durable structural elements. Impregnation is commonly used to improve the textile's mechanical performance. When stiff impregnation materials are used, a fiber strand with high transverse stiffness is formed. Textile-reinforced concrete structures with such fiber strands are prone to splitting failures. This paper investigates splitting failure in textile reinforced concrete experimentally and numerically. In the experimental part, the effect of concrete compaction, casting method, and position are studied as parameters. Finite element analysis is performed to investigate failure mode, tensile and bond stress distributions, and the effect of the varying cross-section of the fiber strand. Compaction improved the splitting resistance for the vertically cast specimens. The compacted vertically cast specimens showed a higher splitting resistance than their horizontally cast equivalents. The finite element model indicated that the main cause of splitting failure is the textile reinforcement's varying cross-section coupled with its flat elliptical shape. The model also showed that the bond stress distribution depends on the fiber strand's geometric configuration.