Mechanical strengths, drying shrinkage and pore structure of cement mortars with hydroxyethyl methyl cellulose

•Tensile bond strength keeps increasing with 0–3% HEMC.•Incorporating HEMC brings a significant increase in drying shrinkage.•Incorporating HEMC brings more macro and large capillary pores, and decreases interconnected pores.•Low flexural and compressive strengths may be attributed to more macro and...

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Published inConstruction & building materials Vol. 314; p. 125683
Main Authors Wang, Shunxiang, Wang, Zhaojia, Huang, Tianyong, Wang, Peiming, Zhang, Guofang
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 03.01.2022
Subjects
Cement mortars
Drying shrinkage
Hydration process
Hydroxyethyl methyl cellulose
Mechanical strengths
Pore structure
Hydration process
Cement mortars
Mechanical strengths
Hydroxyethyl methyl cellulose
Drying shrinkage
Pore structure
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Abstract •Tensile bond strength keeps increasing with 0–3% HEMC.•Incorporating HEMC brings a significant increase in drying shrinkage.•Incorporating HEMC brings more macro and large capillary pores, and decreases interconnected pores.•Low flexural and compressive strengths may be attributed to more macro and large capillary pores. This paper aims at investigating the long-term mechanical strengths and drying shrinkage, as well as pore structure of cement mortars with hydroxyethyl methyl cellulose (HEMC). The results show that the 3-d flexural strength and compressive strength of cement mortars tend to decrease with the HEMC content increasing. At 28 d to 360 d, the strengths keep decreasing with the HEMC content increasing at 0–1%, and then increase from the minimum value with the HEMC content increasing at 1–3%, still being much lower than those of the control (0% HEMC). Throughout the curing age, both the tensile bond strength and the drying shrinkage value gradually increase with the HEMC content, to be nearly twice at 3% HEMC than those of the control. HEMC significantly delays the 3-d hydration of cement pastes, but has negligible retardation effect on the hydration after 28 d, to bring the similar late hydration degree of cement pastes with HEMC or not. With the HEMC content increasing in the range of 0–1%, incorporating HEMC brings the sharp increase of macro pores, large capillary pores and porosity, and decreases the interconnected pores to bring many more closed pores. Further increasing the HEMC content to 3%, macro pores and porosity decrease, large capillary pores slightly increase and interconnected pores have a negligible change. Obviously, the understanding on the performance development of cement mortars with HEMC is conducive to the better application of HEMC in dry-mix mortars to meet different requirements.
AbstractList •Tensile bond strength keeps increasing with 0–3% HEMC.•Incorporating HEMC brings a significant increase in drying shrinkage.•Incorporating HEMC brings more macro and large capillary pores, and decreases interconnected pores.•Low flexural and compressive strengths may be attributed to more macro and large capillary pores. This paper aims at investigating the long-term mechanical strengths and drying shrinkage, as well as pore structure of cement mortars with hydroxyethyl methyl cellulose (HEMC). The results show that the 3-d flexural strength and compressive strength of cement mortars tend to decrease with the HEMC content increasing. At 28 d to 360 d, the strengths keep decreasing with the HEMC content increasing at 0–1%, and then increase from the minimum value with the HEMC content increasing at 1–3%, still being much lower than those of the control (0% HEMC). Throughout the curing age, both the tensile bond strength and the drying shrinkage value gradually increase with the HEMC content, to be nearly twice at 3% HEMC than those of the control. HEMC significantly delays the 3-d hydration of cement pastes, but has negligible retardation effect on the hydration after 28 d, to bring the similar late hydration degree of cement pastes with HEMC or not. With the HEMC content increasing in the range of 0–1%, incorporating HEMC brings the sharp increase of macro pores, large capillary pores and porosity, and decreases the interconnected pores to bring many more closed pores. Further increasing the HEMC content to 3%, macro pores and porosity decrease, large capillary pores slightly increase and interconnected pores have a negligible change. Obviously, the understanding on the performance development of cement mortars with HEMC is conducive to the better application of HEMC in dry-mix mortars to meet different requirements.
ArticleNumber 125683
Author Wang, Zhaojia
Wang, Peiming
Wang, Shunxiang
Huang, Tianyong
Zhang, Guofang
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  givenname: Zhaojia
  surname: Wang
  fullname: Wang, Zhaojia
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  givenname: Tianyong
  surname: Huang
  fullname: Huang, Tianyong
  organization: Beijing Building Materials Academy of Sciences Research, Beijing 100041, China
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  givenname: Peiming
  surname: Wang
  fullname: Wang, Peiming
  organization: Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, Tongji University, Shanghai 201804, China
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  givenname: Guofang
  surname: Zhang
  fullname: Zhang, Guofang
  email: zgftj@sina.com
  organization: Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, Tongji University, Shanghai 201804, China
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Keywords Hydration process
Cement mortars
Mechanical strengths
Hydroxyethyl methyl cellulose
Drying shrinkage
Pore structure
Language English
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Snippet •Tensile bond strength keeps increasing with 0–3% HEMC.•Incorporating HEMC brings a significant increase in drying shrinkage.•Incorporating HEMC brings more...
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StartPage 125683
SubjectTerms Cement mortars
Drying shrinkage
Hydration process
Hydroxyethyl methyl cellulose
Mechanical strengths
Pore structure
Title Mechanical strengths, drying shrinkage and pore structure of cement mortars with hydroxyethyl methyl cellulose
URI https://dx.doi.org/10.1016/j.conbuildmat.2021.125683
Volume 314
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