Direct Tensile Properties and Stress–Strain Model of UHP-ECC

Ke-Quan Yu; Zhou-Dao Lu; Jian-Guo Dai; Surendra P. Shah

doi:10.1061/(ASCE)MT.1943-5533.0002975

Direct Tensile Properties and Stress–Strain Model of UHP-ECC

Ke-Quan Yu
, Zhou-Dao Lu
, Jian-Guo Dai^*
, Surendra P. Shah

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

152 Citations (Scopus)

Abstract

This research developed an ultra-high-performance engineered cementitious composite (UHP-ECC), which combines the properties of strain-hardening, multiple cracking, and high mechanical strength. The compressive strength of the UHP-ECC reached 150 MPa at 28 days under standard curing conditions, whereas the tensile strength and strain capacity of the UHP-ECC were 18 MPa and 8%, respectively. Different fiber volumetric ratios and geometries (fiber length and diameter) were used to investigate the influences of fiber-reinforcement parameters on the mechanical and crack-pattern properties of UHP-ECC, including the tensile strength, strain capacity, strain energy, crack number, and crack spacing. It was found that the fiber reinforcement parameters significantly influence both the mechanical properties and crack-patterns of UHP-ECC. Based on the test results, a bilinear tensile stress-strain model was proposed for UHP-ECC and its accuracy was demonstrated through comparisons with the test results. © 2019 American Society of Civil Engineers.

Original language	English
Article number	04019334
Journal	Journal of Materials in Civil Engineering
Volume	32
Issue number	1
Online published	31 Oct 2019
DOIs	https://doi.org/10.1061/(ASCE)MT.1943-5533.0002975
Publication status	Published - Jan 2020
Externally published	Yes

Funding

Acknowledgments The authors appreciate the financial support from the National Natural Science Foundation of China (51478406 and 51278441), the Research Grants Council of the Hong Kong SAR (Project Code: 152145/17E), and the Research Institute for Sustainable Urban Development, Hong Kong Polytechnic University through Project 1-BBWE

Research Keywords

Crack-pattern
Fiber reinforcement
Stress-strain model
Tensile property
Ultrahigh-performance engineered cementitious composite (UHP-ECC)

RGC Funding Information

RGC-funded

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10.1061/(ASCE)MT.1943-5533.0002975

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title = "Direct Tensile Properties and Stress–Strain Model of UHP-ECC",

abstract = "This research developed an ultra-high-performance engineered cementitious composite (UHP-ECC), which combines the properties of strain-hardening, multiple cracking, and high mechanical strength. The compressive strength of the UHP-ECC reached 150 MPa at 28 days under standard curing conditions, whereas the tensile strength and strain capacity of the UHP-ECC were 18 MPa and 8\%, respectively. Different fiber volumetric ratios and geometries (fiber length and diameter) were used to investigate the influences of fiber-reinforcement parameters on the mechanical and crack-pattern properties of UHP-ECC, including the tensile strength, strain capacity, strain energy, crack number, and crack spacing. It was found that the fiber reinforcement parameters significantly influence both the mechanical properties and crack-patterns of UHP-ECC. Based on the test results, a bilinear tensile stress-strain model was proposed for UHP-ECC and its accuracy was demonstrated through comparisons with the test results. {\textcopyright} 2019 American Society of Civil Engineers.",

keywords = "Crack-pattern, Fiber reinforcement, Stress-strain model, Tensile property, Ultrahigh-performance engineered cementitious composite (UHP-ECC)",

author = "Ke-Quan Yu and Zhou-Dao Lu and Jian-Guo Dai and Shah, \{Surendra P.\}",

year = "2020",

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AU - Yu, Ke-Quan

AU - Lu, Zhou-Dao

AU - Dai, Jian-Guo

AU - Shah, Surendra P.

PY - 2020/1

Y1 - 2020/1

N2 - This research developed an ultra-high-performance engineered cementitious composite (UHP-ECC), which combines the properties of strain-hardening, multiple cracking, and high mechanical strength. The compressive strength of the UHP-ECC reached 150 MPa at 28 days under standard curing conditions, whereas the tensile strength and strain capacity of the UHP-ECC were 18 MPa and 8%, respectively. Different fiber volumetric ratios and geometries (fiber length and diameter) were used to investigate the influences of fiber-reinforcement parameters on the mechanical and crack-pattern properties of UHP-ECC, including the tensile strength, strain capacity, strain energy, crack number, and crack spacing. It was found that the fiber reinforcement parameters significantly influence both the mechanical properties and crack-patterns of UHP-ECC. Based on the test results, a bilinear tensile stress-strain model was proposed for UHP-ECC and its accuracy was demonstrated through comparisons with the test results. © 2019 American Society of Civil Engineers.

AB - This research developed an ultra-high-performance engineered cementitious composite (UHP-ECC), which combines the properties of strain-hardening, multiple cracking, and high mechanical strength. The compressive strength of the UHP-ECC reached 150 MPa at 28 days under standard curing conditions, whereas the tensile strength and strain capacity of the UHP-ECC were 18 MPa and 8%, respectively. Different fiber volumetric ratios and geometries (fiber length and diameter) were used to investigate the influences of fiber-reinforcement parameters on the mechanical and crack-pattern properties of UHP-ECC, including the tensile strength, strain capacity, strain energy, crack number, and crack spacing. It was found that the fiber reinforcement parameters significantly influence both the mechanical properties and crack-patterns of UHP-ECC. Based on the test results, a bilinear tensile stress-strain model was proposed for UHP-ECC and its accuracy was demonstrated through comparisons with the test results. © 2019 American Society of Civil Engineers.

KW - Crack-pattern

KW - Fiber reinforcement

KW - Stress-strain model

KW - Tensile property

KW - Ultrahigh-performance engineered cementitious composite (UHP-ECC)

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DO - 10.1061/(ASCE)MT.1943-5533.0002975

M3 - RGC 21 - Publication in refereed journal

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SN - 0899-1561

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JO - Journal of Materials in Civil Engineering

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ER -

Direct Tensile Properties and Stress–Strain Model of UHP-ECC

Abstract

Funding

Research Keywords

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