Response surface methodology approach for optimized compressive strength of some mix design concrete aggregates from waste cockle shells and glass powder

Sugito, S.; Alisjahbana, S.; Riyanto, H.

Growing Science » Engineering Solid Mechanics » Response surface methodology approach for optimized compressive strength of some mix design concrete aggregates from waste cockle shells and glass powder

Journals

ESM Volumes

Volume 1 (16)
- Issue 1 (4)
- Issue 2 (4)
- Issue 3 (4)
- Issue 4 (4)

Volume 2 (32)
- Issue 1 (6)
- Issue 2 (8)
- Issue 3 (10)
- Issue 4 (8)

Volume 3 (27)
- Issue 1 (7)
- Issue 2 (7)
- Issue 3 (6)
- Issue 4 (7)

Volume 4 (25)
- Issue 1 (5)
- Issue 2 (7)
- Issue 3 (7)
- Issue 4 (6)

Volume 5 (25)
- Issue 1 (7)
- Issue 2 (6)
- Issue 3 (6)
- Issue 4 (6)

Volume 6 (32)
- Issue 1 (8)
- Issue 2 (8)
- Issue 3 (8)
- Issue 4 (8)

Volume 7 (28)
- Issue 1 (7)
- Issue 2 (6)
- Issue 3 (7)
- Issue 4 (8)

Volume 8 (36)
- Issue 1 (8)
- Issue 2 (10)
- Issue 3 (9)
- Issue 4 (9)

Volume 9 (36)
- Issue 1 (9)
- Issue 2 (9)
- Issue 3 (9)
- Issue 4 (9)

Volume 10 (35)
- Issue 1 (9)
- Issue 2 (8)
- Issue 3 (10)
- Issue 4 (8)

Volume 11 (39)
- Issue 1 (10)
- Issue 2 (10)
- Issue 3 (9)
- Issue 4 (10)

Volume 12 (41)
- Issue 1 (10)
- Issue 2 (9)
- Issue 3 (12)
- Issue 4 (10)

Keywords

Authors

Countries

Engineering Solid Mechanics

ISSN 2291-8752 (Online) - ISSN 2291-8744 (Print) Quarterly Publication Volume 10 Issue 2 pp. 101-112 , 2022

Response surface methodology approach for optimized compressive strength of some mix design concrete aggregates from waste cockle shells and glass powder Pages 101-112 Download PDF

Authors: Sugito Sugito, Sofia W. Alisjahbana, Hery Riyanto

DOI: 10.5267/j.esm.2022.2.005

Keywords: Cockle shells powder, Compressive strength, Concrete, Epoxy resin, Glass powder, Waste

Abstract: Nowadays, with increased demand for aggregates for concrete and an awareness of the need of protecting natural resources, experts are becoming increasingly interested in waste material as a building material substitute. However, the compressive strength is influenced by the composition of concrete. In this study, the compressive strength of concrete under substitution using waste from cockle shells and glass was investigated using Response Surface Methodology (RSM). Central Composite Design (CCD) based on RSM was used to assess the influence of epoxy resin, cockle shells powder, and glass powder on compressive strength responses. RSM developed first-order and second-order mathematical models with findings from experimental design. Analysis of variance was used to determine the correctness of CCD's mathematical models. Desirability analysis was then employed to optimize epoxy resin, cockle shells powder, and glass powder yielding maximum compressive strength. The RSM analysis revealed that the empirical results fit well into linear and quadratic models of concrete compressive strength. The mixing components will produce cement with compressive strength in each formulation of 54.71 MPa (4.88% epoxy resin and 4.0% cockle shells powder), 47.82 MPa (6.85% epoxy resin and 8.0% glass powder), 147.0 MPa, (4% cockle shells powder and 8% glass powder), and 56.08 MPa (4.4% epoxy resin, 4.0% cockle shells powder, and 8.0% glass powder). The results confirmed that a reasonable compressive strength of concrete could be achieved using epoxy resin, cockle shells powder, and glass powder.

How to cite this paper

 Sugito, S., Alisjahbana, S & Riyanto, H. (2022). Response surface methodology approach for optimized compressive strength of some mix design concrete aggregates from waste cockle shells and glass powder.Engineering Solid Mechanics, 10(2), 101-112.

Refrences

Basri, H., Mannan, M., & Zain, M. F. M. (1999). Concrete using waste oil palm shells as aggregate. Cement and concrete Research, 29(4), 619-622.
Ede, A. N., Gideon, P. O., Akpabot, A. I., Oyebisi, S. O., Olofinnade, O. M., & Nduka, D. O. (2021). Review of the Properties of Lightweight Aggregate Concrete Produced from Recycled Plastic Waste and Periwinkle Shells. Paper presented at the Key Engineering Materials.
Gupta, A., Gupta, N., Shukla, A., Goyal, R., & Kumar, S. (2020). Utilization of recycled aggregate, plastic, glass waste and coconut shells in concrete-A review. Paper presented at the IOP Conference Series: Materials Science and Engineering.
Habibi, A., Ramezanianpour, A. M., Mahdikhani, M., & Bamshad, O. (2021). RSM-based evaluation of mechanical and durability properties of recycled aggregate concrete containing GGBFS and silica fume. Construction and Building Materials, 270, 121431.
Hammoudi, A., Moussaceb, K., Belebchouche, C., & Dahmoune, F. (2019). Comparison of artificial neural network (ANN) and response surface methodology (RSM) prediction in compressive strength of recycled concrete aggregates. Construction and Building Materials, 209, 425-436.
Hamouda, H. I., Nassar, H. N., Madian, H. R., Amr, S. S. A., & El-Gendy, N. S. (2015). Response surface optimization of bioethanol production from sugarcane molasses by Pichia veronae strain HSC-22. Biotechnology research international, 2015.
Hilal, N. N., Sahab, M. F., & Ali, T. K. M. (2021). Fresh and hardened properties of lightweight self-compacting concrete containing walnut shells as coarse aggregate. Journal of King Saud University-Engineering Sciences, 33(5), 364-372.
Jayanti, D. S., Amrida, N., Sitorus, A., & Thamren, D. S. (2021). Potential Hydroelectric Power Plant for a Remote Area Utilizing Subwatershed Lawe-Simpali. Mathematical Modelling of Engineering Problems, 8(5), 715-720. doi:10.18280/mmep.080505
Karri, R. R., Ravindran, G., & Paramasivan, B. (2021). Predictive capability evaluation and optimization of sustainable biodiesel production from oleaginous biomass grown on pulp and paper industrial wastewater. Renewable Energy, 168, 204-215.
Mohamad, N., Muthusamy, K., & Ismail, M. A. K. E. G. (2021). Cockle Shell as Mixing Ingredient in Concrete: A Review. CONSTRUCTION, 1(2), 9-20.
Murugan, S., Natarajan, M., Karthik, V., & Johnpaul, V. (2020). Utilization of cockle shell aggregates in the production of eco-concrete. Materials Today: Proceedings.
Nematzadeh, M., Shahmansouri, A. A., & Fakoor, M. (2020). Post-fire compressive strength of recycled PET aggregate concrete reinforced with steel fibers: Optimization and prediction via RSM and GEP. Construction and Building Materials, 252, 119057.
Raseela, M., & George, B. M. S. (2019). Experimental investigation on use of cockle shell as partial coarse aggregate replacement in concrete. Concrete, International, 4(2), 504-510.
Ren, B., Chen, C., Li, C., Fu, X., You, L., & Liu, R. H. (2017). Optimization of microwave-assisted extraction of Sargassum thunbergii polysaccharides and its antioxidant and hypoglycemic activities. Carbohydrate Polymers, 173, 192-201.
Salarian, A.-A., Hami, Z., Mirzaei, N., Mohseni, S. M., Asadi, A., Bahrami, H., Vosoughi, M., Alinejad, A., & Zare, M.-R. (2016). N-doped TiO2 nanosheets for photocatalytic degradation and mineralization of diazinon under simulated solar irradiation: Optimization and modeling using a response surface methodology. Journal of Molecular Liquids, 220, 183-191.
Sinkhonde, D., Onchiri, R. O., Oyawa, W. O., & Mwero, J. N. (2021). Response surface methodology-based optimisation of cost and compressive strength of rubberised concrete incorporating burnt clay brick powder. Heliyon, 7(12), e08565. doi:https://doi.org/10.1016/j.heliyon.2021.e08565
Sitorus, A., Fauzi, A., Ramadhan, G., Hasan, A. R., & Karyadi, A. (2018). Conceptual Design of Harvesters Knife for Chinese Spinach (Ipomoea Reptans Poir.): CAD Approach. Paper presented at the 2018 International Conference on Computing, Engineering, and Design (ICCED).
Yirgu, Z., Leta, S., Hussen, A., Khan, M. M., & Aragaw, T. (2021). Optimization of microwave-assisted carbohydrate extraction from indigenous Scenedesmus sp. grown in brewery effluent using response surface methodology. Heliyon, 7(5), e07115. doi:https://doi.org/10.1016/j.heliyon.2021.e07115