Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites
abstract: As the demand of sustainable construction materials increases, use of fibers and textiles as partial or full reinforcement in concrete members present a tremendous opportunity. Proper characterization techniques and design guides for hybrid materials are therefore needed. This dissertation...
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ndltd-asu.edu-item-403522018-06-22T03:07:52Z Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites abstract: As the demand of sustainable construction materials increases, use of fibers and textiles as partial or full reinforcement in concrete members present a tremendous opportunity. Proper characterization techniques and design guides for hybrid materials are therefore needed. This dissertation presents a comprehensive study on serviceability-based design of strain softening and strain hardening materials. Multiple experimental procedures are developed to document the nature of single crack localization and multiple cracking mechanisms in various fiber and fabric reinforced cement-based composites. In addition, strain rate effects on the mechanical properties are examined using a high speed servo-hydraulic tension test equipment. Significant hardening and degradation parameters such as stiffness, crack spacing, crack width, localized zone size are obtained from tensile tests using digital image correlation (DIC) technique. A tension stiffening model is used to simulate the tensile response that addresses the cracking and localization mechanisms. The model is also modified to simulate the sequential cracking in joint-free slabs on grade reinforced by steel fibers, where the lateral stiffness of slab and grade interface and stress-crack width response are the most important model parameters. Parametric tensile and compressive material models are used to formulate generalized analytical solutions for flexural behaviors of hybrid reinforced concrete (HRC) that contains both rebars and fibers. Design recommendations on moment capacity, minimum reinforcement ratio etc. are obtained using analytical equations. The role of fiber in reducing the amount of conventional reinforcement is revealed. The approach is extended to T-sections and used to model Ultra High Performance Concrete (UHPC) beams and girders. The analytical models are extended to structural members subjected to combined axial and bending actions. Analytical equations to address the P-M diagrams are derived. Closed-form equations that generate the interaction diagram of HRC section are presented which may be used in the design of multiple types of applications. The theoretical models are verified by independent experimental results from literature. Reliability analysis using Monte Carlo simulation (MCS) is conducted for few design problems on ultimate state design. The proposed methodologies enable one to simulate the experiments to obtain material parameters and design structural members using generalized formulations. Dissertation/Thesis Yao, Yiming (Author) Mobasher, Barzin (Advisor) Underwood, Benjamin (Committee member) Neithalath, Narayanan (Committee member) Rajan, Subramaniam D (Committee member) Liu, Yongming (Committee member) Arizona State University (Publisher) Engineering analytical model design distributed cracking fiber reinforced cocnrete strain hardening strain rate eng 328 pages Doctoral Dissertation Civil and Environmental Engineering 2016 Doctoral Dissertation http://hdl.handle.net/2286/R.I.40352 http://rightsstatements.org/vocab/InC/1.0/ All Rights Reserved 2016 |
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NDLTD |
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English |
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Doctoral Thesis |
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Engineering analytical model design distributed cracking fiber reinforced cocnrete strain hardening strain rate |
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Engineering analytical model design distributed cracking fiber reinforced cocnrete strain hardening strain rate Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
description |
abstract: As the demand of sustainable construction materials increases, use of fibers and textiles as partial or full reinforcement in concrete members present a tremendous opportunity. Proper characterization techniques and design guides for hybrid materials are therefore needed. This dissertation presents a comprehensive study on serviceability-based design of strain softening and strain hardening materials. Multiple experimental procedures are developed to document the nature of single crack localization and multiple cracking mechanisms in various fiber and fabric reinforced cement-based composites. In addition, strain rate effects on the mechanical properties are examined using a high speed servo-hydraulic tension test equipment.
Significant hardening and degradation parameters such as stiffness, crack spacing, crack width, localized zone size are obtained from tensile tests using digital image correlation (DIC) technique. A tension stiffening model is used to simulate the tensile response that addresses the cracking and localization mechanisms. The model is also modified to simulate the sequential cracking in joint-free slabs on grade reinforced by steel fibers, where the lateral stiffness of slab and grade interface and stress-crack width response are the most important model parameters.
Parametric tensile and compressive material models are used to formulate generalized analytical solutions for flexural behaviors of hybrid reinforced concrete (HRC) that contains both rebars and fibers. Design recommendations on moment capacity, minimum reinforcement ratio etc. are obtained using analytical equations. The role of fiber in reducing the amount of conventional reinforcement is revealed. The approach is extended to T-sections and used to model Ultra High Performance Concrete (UHPC) beams and girders.
The analytical models are extended to structural members subjected to combined axial and bending actions. Analytical equations to address the P-M diagrams are derived. Closed-form equations that generate the interaction diagram of HRC section are presented which may be used in the design of multiple types of applications.
The theoretical models are verified by independent experimental results from literature. Reliability analysis using Monte Carlo simulation (MCS) is conducted for few design problems on ultimate state design. The proposed methodologies enable one to simulate the experiments to obtain material parameters and design structural members using generalized formulations. === Dissertation/Thesis === Doctoral Dissertation Civil and Environmental Engineering 2016 |
author2 |
Yao, Yiming (Author) |
author_facet |
Yao, Yiming (Author) |
title |
Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
title_short |
Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
title_full |
Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
title_fullStr |
Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
title_full_unstemmed |
Characteristics of Distributed Cracking for Analysis and Design of Strain Hardening Cement Based Composites |
title_sort |
characteristics of distributed cracking for analysis and design of strain hardening cement based composites |
publishDate |
2016 |
url |
http://hdl.handle.net/2286/R.I.40352 |
_version_ |
1718701268518567936 |