Hollow Concrete Block Based on High-Strength Concrete as a Tool for Reducing the Carbon Footprint in Construction

The production and servicing of cement-based building materials is a source of large amounts of carbon dioxide emissions globally. One of the ways to reduce its negative impact, is to reduce concrete consumption per cubic meter of building structure through the introduction of hollow concrete produc...

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Published in:Journal of composites science 2024-09, Vol.8 (9), p.358
Main Authors: Elistratkin, Mikhail, Salnikova, Alena, Alfimova, Nataliya, Kozhukhova, Natalia, Pospelova, Elena
Format: Article
Language:English
Subjects:
3D printing
Bearing capacity
Building materials
Carbon dioxide
Carbon footprint
Cement
Concrete
Concrete blocks
Concrete construction
Configuration management
Consumption
Efficiency
Emissions
Formwork
High strength concretes
high-strength self-compacting fine-grained concrete
improving the efficiency of cement use
Lightweight concretes
Load bearing elements
Plant layout
Portland cements
printing formwork for concreting using the FDM method
R&D
reduction in CO2 emissions
Research & development
Sand & gravel
Thermal insulation
thin-walled hollow concrete block
Three dimensional printing
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container_end_page
container_issue 9
container_start_page 358
container_title Journal of composites science
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creator Elistratkin, Mikhail
Salnikova, Alena
Alfimova, Nataliya
Kozhukhova, Natalia
Pospelova, Elena
description The production and servicing of cement-based building materials is a source of large amounts of carbon dioxide emissions globally. One of the ways to reduce its negative impact, is to reduce concrete consumption per cubic meter of building structure through the introduction of hollow concrete products. At the same time, to maintain the load-bearing capacity of the building structure, it is necessary to significantly increase the strength of the concrete used. However, an increase in strength should be achieved not by increasing cement consumption, but by increasing the efficiency of its use. This research is focused on the development of technology for the production of thin-walled hollow concrete blocks based on high-strength, self-compacting, dispersed, micro-reinforced, fine-grained concrete. The use of this concrete provides 2–2.5 times higher strength in the amount of Portland cement consumed in comparison with ordinary concrete. The formation of external contours and partitions of thin-walled hollow blocks is ensured through the use of disposable formwork or cores used as void formers obtained by FDM 3D printing. This design solution makes it possible to obtain products based on high-strength concrete with higher structural and thermal insulation properties compared to now existing lightweight concrete-based blocks. Another area of application of this technology could be the production of wall structures of free configuration and cross-section due to their division, at the digital modeling stage, into individual element-blocks, manufactured in a factory environment.
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subjects 3D printing
Bearing capacity
Building materials
Carbon dioxide
Carbon footprint
Cement
Concrete
Concrete blocks
Concrete construction
Configuration management
Consumption
Efficiency
Emissions
Formwork
High strength concretes
high-strength self-compacting fine-grained concrete
improving the efficiency of cement use
Lightweight concretes
Load bearing elements
Plant layout
Portland cements
printing formwork for concreting using the FDM method
R&D
reduction in CO2 emissions
Research & development
Sand & gravel
Thermal insulation
thin-walled hollow concrete block
Three dimensional printing
title Hollow Concrete Block Based on High-Strength Concrete as a Tool for Reducing the Carbon Footprint in Construction
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