Abstract

Textile-reinforced concrete (TRC) is a promising composite material with enormous potential in structural applications because it offers the possibility to construct slender, lightweight, and robust elements. However, despite the good heat resistance of the inorganic matrices and the well-established knowledge on the high-temperature performance of the commonly used fibrous reinforcements, their application in TRC elements with very small thicknesses makes their effectiveness against thermal loads questionable. This paper presents a state-of-the-art review on the thermomechanical behavior of TRC, focusing on its mechanical performance both during and after exposure to high temperatures. The available knowledge from experimental investigations where TRC has been tested in thermomechanical conditions as a standalone material is compiled, and the results are compared. This comparative study identifies the key parameters that determine the mechanical response of TRC to increased temperatures, being the surface treatment of the textiles and the combination of thermal and mechanical loads. It is concluded that the uncoated carbon fibers are the most promising solution for a fire-safe TRC application. However, the knowledge gaps are still large, mainly due to the inconsistency of the testing methods and the stochastic behavior of phenomena related to heat treatment (such as spalling).

Highlights

  • Embedding reinforcing textiles into inorganic matrices is an innovative technique which offers the possibility to manufacture thin, slender, and lightweight but robust structural elements

  • This review focuses on the behavior of Textile-reinforced concrete (TRC) as a standalone material under thermal loading

  • In the study of Antons et al [49], flexure tests were performed on TRC specimens heated while bearing a constant load, and the discussion focused on the strain evolution with increasing temperature as a function of the load level

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Summary

Introduction

Embedding reinforcing textiles into inorganic matrices is an innovative technique which offers the possibility to manufacture thin, slender, and lightweight but robust structural elements. Apart from variations in the specimen geometry, the clamping method, the loading rate, etc., the performed tests found in the literature vary in the heating rate, the method and the position of the temperature measurements, and the exposure time. Most importantly, they vary in the combination of the heating and mechanical loading conditions. The performance of TRM/TRC systems under elevated temperatures and fire conditions has been discussed in the review study of [28], which emphasized the behavior of strengthening schemes. Conclusions, should be drawn with caution, because the available experimental data are limited, and the testing procedures vary significantly

Performance of the Textile-to-Matrix Bond
Tensile
Loading at Increased Temperatures or after Cooling Down
Initial Stage
Flexural Performance of the Composite
Findings
Conclusions and Knowledge Gaps

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