Recycling of Cement–Wood Board Production Waste into a Low-Strength Cementitious Binder

Cement is a widely used building material, with more than 4.4 billion metric tons produced in 2021. Unfortunately, the excessive use of cement raises several environmental issues, one of which is the massive amounts of CO2e produced as a by-product. Using recycled materials in the concrete mix is wi...

Full description

Saved in:
Bibliographic Details
Published in:Recycling (Basel) 2022-10, Vol.7 (5), p.76
Main Authors: Argalis, Pauls P., Sinka, Maris, Bajare, Diana
Format: Article
Language:English
Subjects:
Binders (materials)
By-products
Carbon footprint
Cement
Composition
Compressive strength
Concrete mixes
Differential thermal analysis
Dust
Emissions
Energy consumption
Environmental aspects
Filler materials
Greenhouse gases
Grinding
Humidity
Hydration
Latvia
low-strength cementitious binder
Manufacturing
Manufacturing wastes
mechanical treatment
Methods
Natural cement
Planetary mills
Recycled materials
Recycling
Recycling (Waste, etc.)
Rheology
Thermal analysis
Thermogravimetry
Waste management
waste recycling
Waste streams
Wood composites
X-ray diffraction
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Cement is a widely used building material, with more than 4.4 billion metric tons produced in 2021. Unfortunately, the excessive use of cement raises several environmental issues, one of which is the massive amounts of CO2e produced as a by-product. Using recycled materials in the concrete mix is widely employed to solve this problem. A method for minimizing the use of natural cement by substituting it with secondary cementitious material that consists of wood–cement board manufacturing waste has been studied in this paper. The cement in the waste stream was reactivated by a mechanical treatment method—the use of a planetary mill, allowing it to regain its cementitious properties and be used as a binder. Physical and mineralogical analysis of the binder material was performed using X-ray diffraction (XRD), thermogravimetry/differential thermal analysis (TG/DTA) and Brunauer–Emmett–Teller analysis; granulometry and compressive strength tests were also carried out. The results show that the grinding process did not significantly change the mineralogical composition and the specific surface area; it did, however, affect the compressive strength of the samples prepared by using the reactivated binding material; also, the addition of plasticizer to the mix increased compressive strength by 2.5 times. Samples were cured in high-humidity conditions. The optimal water-to-binder (W/B) ratio was found to be 0.7 because of the wood particles that absorb water in their structure. Compressive strength increased as the grinding time increased.
ISSN:2313-4321
2313-4321
DOI:10.3390/recycling7050076