Your search keyword '"Zhuoyang Zhang"' showing total 2 results

1. Locking Front Model for pull-out behaviour of PVA microfibre embedded in cementitious matrix

Author

Viktor Mechtcherine, Majid Ranjbarian, Zhuoyang Zhang, Michael Kaliske, Iurie Curosu, and J. Storm

Subjects

Cement, Materials science, business.product_category, 0211 other engineering and technologies, Front (oceanography), 02 engineering and technology, Building and Construction, 021001 nanoscience & nanotechnology, Spall, Matrix (mathematics), 021105 building & construction, Microfiber, General Materials Science, Cementitious, Composite material, 0210 nano-technology, Cementitious matrix, Ductility, business

Abstract

High-performance polymeric microfibres are widely used along with cementitious matrices to produce Strain-Hardening, Cement-based Composites (SHCCs); a specific class of Fibre-Reinforced Cementitious Composites (FRCCs), which show high ductility in the post-cracking stage. As in all composites, the performance of SHCC is determined by the properties of its constituents: fibre, matrix and the interface between them. Above all, the interface plays an important role in the crack-bridging behaviour of fibres. Interface properties are commonly investigated by means of single fibre pull-out tests. The article at hand proposes a physical explanation of the pull-out behaviour of PVA microfibre in the post-debonding stage. It is shown that a particular type of damage with characteristic geometry creates a “locking front” somewhere on the fibre's embedded length, which leads to a rise in force in the post-debonding regime. The evidence supporting the given explanation is provided by microscopic analysis of the embedded parts of the fibres. First, single-sided fibre pull-out tests are performed followed by the spalling of the matrix by a special technique and by micro-mechanical, numerical simulations of the pull-out experiment. The Locking Front Model suggests that the interaction between fibre and matrix is not uniform over the embedded length, but it is rather local. Thus, the locking front of fibre-matrix interaction could be much shorter than the embedded length, indicating that the pull-out behaviour might be not proportionally dependent on embedded length for this type of microfibre.

Published

2019

2. A review on cement-based materials used in steel structures as fireproof coating

Author

Jinlong Pan, Zhuoyang Zhang, Jingming Cai, Jinsheng Han, and Xiaomeng Ma

Subjects

Cement, Materials science, business.industry, Building and Construction, Pozzolan, engineering.material, Thermal conduction, law.invention, Coating, law, Thermal insulation, Fly ash, engineering, General Materials Science, Calcination, Composite material, Porosity, business, Civil and Structural Engineering

Abstract

Cement-based materials used as fireproof coatings exhibit favorable thermal insulation and anti-spalling properties as well as adequate residual mechanical properties after elevated temperature, which are promising on the fields of structural fire-resistance applications and occupy price advantage. Based on these three types of performances, this paper was intended to review various corresponding influencing factors and relevant theories of this type of materials. The effects of various porous fillers on thermal insulation performance were investigated and it is suggested that the porous fillers with pozzolanic reactivity deserve to be utilized. The influences of fibers on spalling resistance performance were analyzed. Also, the effect of fly ash on residual mechanical properties after elevated temperatures was summarized and the analyses showed that other solid wastes produced after calcination have the potential to be added for improving residual mechanical properties. Then, various conduction theories and corresponding analytical models for predicting effective thermal conductivity and different anti-spalling mechanisms of fibers were listed. Based on the analysis, the remaining challenges of development of cement-based fire-resistive coatings were finally discussed.

Published

2022