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A platform for research: civil engineering, architecture and urbanism
3D auxetic cementitious-polymeric composite structure with compressive strain-hardening behavior
https://orcid.org/0000-0001-5825-4175
Highlights A novel 3D auxetic composite structure incorporating polymeric shell and cementitious mortar core (3D-ACPC) is created. The 3D-ACPC simultaneously overcome the brittleness of cementitious material and the low strength of 3D printed polymeric shell. The 3D-ACPC shows enhanced energy absorption than conventional cementitious materials and 3D printed polymeric cellular materials. The origin resulting in the anisotropic compressive behavior of the 3D-ACPC induced is clarified.
Abstract A composite can have properties much better than the components it is made of. This work proposes a three-dimensional auxetic cementitious-polymeric composite structure (3D-ACPC) which incorporates 3D printed polymeric shell with cementitious mortar. Uniaxial compression experiments are performed on the 3D-ACPC to study their quasi-static stress-strain response. Experimental results show that the created composite structure can simultaneously overcome the brittleness of conventional cementitious material and the low compressive strength of 3D printed polymeric cellular shell. Therefore, the 3D-ACPC exhibit compressive strain-hardening behavior ensuring high energy absorption ability. In addition, it is found that structural anisotropy and the shell printing direction have significant impact on the stress-strain response of the 3D-ACPC. Moreover, due to the lightweight cellular structure, the 3D-ACPC shows significantly enhanced specific energy absorption compared to conventional cementitious materials and polymeric cellular materials. To this end, the developed 3D-ACPC has great potential to be used in engineering practice, such as protective structures.
3D auxetic cementitious-polymeric composite structure with compressive strain-hardening behavior
https://orcid.org/0000-0001-5825-4175
Highlights A novel 3D auxetic composite structure incorporating polymeric shell and cementitious mortar core (3D-ACPC) is created. The 3D-ACPC simultaneously overcome the brittleness of cementitious material and the low strength of 3D printed polymeric shell. The 3D-ACPC shows enhanced energy absorption than conventional cementitious materials and 3D printed polymeric cellular materials. The origin resulting in the anisotropic compressive behavior of the 3D-ACPC induced is clarified.
Abstract A composite can have properties much better than the components it is made of. This work proposes a three-dimensional auxetic cementitious-polymeric composite structure (3D-ACPC) which incorporates 3D printed polymeric shell with cementitious mortar. Uniaxial compression experiments are performed on the 3D-ACPC to study their quasi-static stress-strain response. Experimental results show that the created composite structure can simultaneously overcome the brittleness of conventional cementitious material and the low compressive strength of 3D printed polymeric cellular shell. Therefore, the 3D-ACPC exhibit compressive strain-hardening behavior ensuring high energy absorption ability. In addition, it is found that structural anisotropy and the shell printing direction have significant impact on the stress-strain response of the 3D-ACPC. Moreover, due to the lightweight cellular structure, the 3D-ACPC shows significantly enhanced specific energy absorption compared to conventional cementitious materials and polymeric cellular materials. To this end, the developed 3D-ACPC has great potential to be used in engineering practice, such as protective structures.
3D auxetic cementitious-polymeric composite structure with compressive strain-hardening behavior
https://orcid.org/0000-0001-5825-4175
Highlights A novel 3D auxetic composite structure incorporating polymeric shell and cementitious mortar core (3D-ACPC) is created. The 3D-ACPC simultaneously overcome the brittleness of cementitious material and the low strength of 3D printed polymeric shell. The 3D-ACPC shows enhanced energy absorption than conventional cementitious materials and 3D printed polymeric cellular materials. The origin resulting in the anisotropic compressive behavior of the 3D-ACPC induced is clarified.
Abstract A composite can have properties much better than the components it is made of. This work proposes a three-dimensional auxetic cementitious-polymeric composite structure (3D-ACPC) which incorporates 3D printed polymeric shell with cementitious mortar. Uniaxial compression experiments are performed on the 3D-ACPC to study their quasi-static stress-strain response. Experimental results show that the created composite structure can simultaneously overcome the brittleness of conventional cementitious material and the low compressive strength of 3D printed polymeric cellular shell. Therefore, the 3D-ACPC exhibit compressive strain-hardening behavior ensuring high energy absorption ability. In addition, it is found that structural anisotropy and the shell printing direction have significant impact on the stress-strain response of the 3D-ACPC. Moreover, due to the lightweight cellular structure, the 3D-ACPC shows significantly enhanced specific energy absorption compared to conventional cementitious materials and polymeric cellular materials. To this end, the developed 3D-ACPC has great potential to be used in engineering practice, such as protective structures.
3D auxetic cementitious-polymeric composite structure with compressive strain-hardening behavior
Xu, Yading (author) / Šavija, Branko (author)
Engineering Structures ; 294
2023-01-01
Article (Journal)
Electronic Resource
English
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