Naturally cured foamed concrete with improved thermal insulation properties

Nikolay Mashkin,Rustam Mansurov,Ekaterina Bartenjeva,N.O Kopanitsa,V.S Plevkov,P.A Radchenko,T.Y Ovsyannikova,A.A Klopotov,L.A Teplyakova

doi:10.1051/matecconf/201814302005

Nikolay Mashkin, Rustam Mansurov + Show 7 more

Open Access

https://doi.org/10.1051/matecconf/201814302005

Copy DOI

Abstract

The paper is dedicated to investigation on improvement of thermal insulation properties of non-autoclaved concrete by increasing aggregate stability of foamed concrete mixture. The study demonstrates influence of mineral admixtures on the foam stability index in the mortar mixture and on decrease of foamed concrete density and thermal conductivity. The effect of mineral admixtures on thermal conductivity properties of non-autoclaved concrete was assessed through different ways of their addition: to the foam and to the mortar mixture. The admixtures were milled up to the specific surface area of 300 and 600 m2/kg using an AГO-9 centrifugal attrition mill with continuous operation mode (Institute of Solid State Chemistry and Mechanochemistry, Siberian Branch of the Russian Academy of Sciences, Novosibirsk). Laboratory turbulent foam concrete mixer was used to prepare foamed concrete. Thermal conductivity coefficient was defined by a quick method using “ИTП-MГ 4 “Zond” thermal conductivity meter in accordance with the regulatory documents. The impact of modifiers on the foam structure stability was defined using the foam stability index for the mortar mixture. The research demonstrated the increase in stability of porous structure of non-autoclaved concrete when adding wollastonite and diopside. Improvement of thermal and physical properties was demonstrated, the decrease of thermal conductivity coefficient reaches 0.069 W/(m×°C)

Highlights

The growth of interest in cellular concrete investigation is connected with the change of requirements to thermal protection of buildings and structures, those located in harsh climate conditions
There are some research dedicated to mineral content control in hardened cement paste [5], the result of which define the decrease of thermal conductivity coefficient of interpore partitions in foamed concrete by 6.5-24 % with the maximum allowable content of calcium aluminate (C3A) and calcium alumoferrite (C4AF) in Portland cement and with the minimum allowable content of alite (C3S)
Experimental research was performed using samples of naturally cured foamed concrete produced according to the traditional technology with the use of turbulent foam concrete mixer

Summary

Introduction

The growth of interest in cellular concrete investigation is connected with the change of requirements to thermal protection of buildings and structures, those located in harsh climate conditions. There are some research dedicated to mineral content control in hardened cement paste [5], the result of which define the decrease of thermal conductivity coefficient of interpore partitions in foamed concrete by 6.5-24 % with the maximum allowable content of calcium aluminate (C3A) and calcium alumoferrite (C4AF) in Portland cement and with the minimum allowable content of alite (C3S). Use of components with lower thermal conductivity and high density like ash, slag, peat, expanded perlite, vermiculite, allows improving thermal insulation properties [10,11,12,13,14,15]. Use of fine montmorillonite clay enables to obtain ultralight foamed concrete with the density of 200 kg/m3 due to high adsorption capacity [10]

Objectives

Methods

Conclusion