TY - GEN
T1 - Bio-cementation of Demolition Wastes and Recycled Aggregates for Sustainable Production of Paving Blocks
AU - Muhanna, H. N.
AU - Niras, R. K.M.
AU - Prasadini, U. N.C.
AU - Gowthaman, S.
AU - Nawarathna, T. H.K.
AU - Chen, M.
AU - Kawasaki, S.
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.
PY - 2024
Y1 - 2024
N2 - Concrete block pavements have recently become an attractive engineering system, increasingly used in parking areas, pedestrian walks, traffic intersections, container yards, and low-volume roads. However, the production of paving blocks is in high demand for Portland Cement and natural aggregates. The exhaustive use of such resources has become a serious threat, resulting in a scarcity of resources and negative environmental impacts. To alleviate these traits, the authorities heightened laws to restrict the construction practices that heavily contribute to carbon footprint. This study proposes the bio-cementation of demolition wastes and recycled aggregates as a new sustainable alternative for producing paving blocks. The method harnesses the bacteria containing active urease to biochemically induce the cementation. The feasibility and efficiency of using five different types of demolition wastes were investigated. Recycled concrete coarse aggregates (R-CCA), recycled concrete fine aggregates (R-CFA), recycled concrete aggregate dust (R-CAD), recycled concrete mortar dust (R-CMD), and recycled brick aggregates (R-BA) were derived by crushing the building demolition wastes and prepared in standard molds. The bacteria used herein were Sporosarcina pasteurii. During the batches of treatment, the bacteria culture was percolated into the specimens along with aqueous urea and calcium chloride. The evaluation program consisted of unconfined compressive strength (UCS) tests, scanning electron microscopy (SEM) analysis, and the measurements of precipitation content. The SEM results revealed that the bio-cement treatment could induce the formation of calcium carbonate within the pores and facilitate the binding of aggregates in all the categories. However, the achieved UCS on R-CFA was the highest (~2 MPa), that on R-CCA was the next (~1.48 MPa), while that on R-CAD and R-BA were the worst. R-CMD achieved a moderate UCS (~0.6 MPa). The gradation and the nature of the waste material were found to determine the efficiency of strengthening and uniformity in the cementation profile.
AB - Concrete block pavements have recently become an attractive engineering system, increasingly used in parking areas, pedestrian walks, traffic intersections, container yards, and low-volume roads. However, the production of paving blocks is in high demand for Portland Cement and natural aggregates. The exhaustive use of such resources has become a serious threat, resulting in a scarcity of resources and negative environmental impacts. To alleviate these traits, the authorities heightened laws to restrict the construction practices that heavily contribute to carbon footprint. This study proposes the bio-cementation of demolition wastes and recycled aggregates as a new sustainable alternative for producing paving blocks. The method harnesses the bacteria containing active urease to biochemically induce the cementation. The feasibility and efficiency of using five different types of demolition wastes were investigated. Recycled concrete coarse aggregates (R-CCA), recycled concrete fine aggregates (R-CFA), recycled concrete aggregate dust (R-CAD), recycled concrete mortar dust (R-CMD), and recycled brick aggregates (R-BA) were derived by crushing the building demolition wastes and prepared in standard molds. The bacteria used herein were Sporosarcina pasteurii. During the batches of treatment, the bacteria culture was percolated into the specimens along with aqueous urea and calcium chloride. The evaluation program consisted of unconfined compressive strength (UCS) tests, scanning electron microscopy (SEM) analysis, and the measurements of precipitation content. The SEM results revealed that the bio-cement treatment could induce the formation of calcium carbonate within the pores and facilitate the binding of aggregates in all the categories. However, the achieved UCS on R-CFA was the highest (~2 MPa), that on R-CCA was the next (~1.48 MPa), while that on R-CAD and R-BA were the worst. R-CMD achieved a moderate UCS (~0.6 MPa). The gradation and the nature of the waste material were found to determine the efficiency of strengthening and uniformity in the cementation profile.
KW - Bio-cementation
KW - Demolition waste
KW - Paving blocks
KW - Recycled aggregates
KW - Sustainability
KW - Ureolytic bacteria
UR - http://www.scopus.com/inward/record.url?scp=85203145341&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=85203145341&partnerID=8YFLogxK
U2 - 10.1007/978-981-97-3737-6_4
DO - 10.1007/978-981-97-3737-6_4
M3 - Conference contribution
AN - SCOPUS:85203145341
SN - 9789819737369
T3 - Lecture Notes in Civil Engineering
SP - 47
EP - 58
BT - Proceedings of the 14 International Conference on Sustainable Built Environment - ICSBE 2023
A2 - Dissanayake, Ranjith
A2 - Mendis, Priyan
A2 - De Silva, Sudhira
A2 - Fernando, Shiromal
A2 - Konthesingha, Chaminda
A2 - Attanayake, Upul
A2 - Gajanayake, Pradeep
PB - Springer Science and Business Media Deutschland GmbH
T2 - 14th International Conference on Sustainable Built Environment, ICSBE 2023
Y2 - 15 December 2023 through 17 December 2023
ER -