This work reports the outcome of an experiment carried out on the compressive strength of concrete using cassava peel ash and epoxy resin as partial replacement for cement in concrete. A lot of types of agricultural waste today pollute the environment and occupy great soil surfaces, and cassava peels is not an exception. One way for consuming waste is to use them in obtaining green materials. And polymer concrete such as epoxy resin concrete is a new advanced composite material which is used in construction industry due to its superior properties in comparison with ordinary Portland cement concrete such as higher mechanical strength and chemical resistance. The cassava peel ash was obtained by calcination of cassava peel at 360ËšC temperature. The design of the experiment used 0, 5, 10, 15, 20, and 25% for both cassava peel ash and epoxy resin. The concrete was batched with a ratio of 1:2:4. The cubes produced were allowed to cure for 7, 14, 28 and 56days. The result obtained showed that there was no appreciable change in slump but slight increase by the increase in percentage of concentrations and the result for compressive strength shows that the concrete strength increases with increase in concentrations and curing age. It can be concluded that epoxy resin when used in conjunction with cassava peel ash performs equally as a good binder in concrete without reducing the compressive strength properties of the concrete.

KEYWORDS: Compressive Strength, Epoxy Resin, Cassava Peel Ash, Slump, Agricultural Waste Management.

Aitcin, P. C., (2011). High performance concrete.CRC press

Bharatkumar, B.H., Raghuprasad, B.K., Ramachandramurthy, D.S., Narayanan, R. and Gopolakrishan, S., (2005). Effect of fly ash and slag on the fracture characteristics of high performance concrete, Material and Structures, January-February, volume 38, Issue1, pp63-72

Buyukozturk, O. and Lau, D., (2004). High Performance Concrete: Fundamentals and Application.Department of Civil and Environmental Engineering, Massachusetts Institute of Technology,Cambridge.

Chandran A., (2016). Investigation on Mechanical Properties of Concrete Elements made with Partial Replacement of Cement with Card-Board Sludge. International Journal of Innovations in Engineering and Technology (IJIET) Volume 6 Issue 4, ISSN: 2319-1058

Ferdous, W., Manalo, A., Wong, H. S., Abousnina, R., Ajarmeh, O. S., Zhuge, Y. and Schubel, P., (2020).

“Optimal design for epoxy polymer concrete based on mechanical properties and durability aspects,†Construction and Building Materials, vol. 232, p. 117229

Fernandez-Ruiz, M.A., Gil-Martin, L.M., Carbonell-Marquez, J.F. and Hernandez-Montes, E., (2018). Epoxy resin and ground tyre rubber replacement for cement in concrete: Compressive behaviour and durability properties. Construction and Building Materials 173(2018) 49-57.

Hunchate, S. R., Chandupalle, S., Ghorpode, V.G. and Reddy, T.C.V., (2014). Mix Design of High Performance Concrete Using Silica Fume and Superplasticizer, International Journal of Innovative Research in Science, Engineering and Technology Vol. 3, Issue 3, march, 10735-10743

Ibrahim, A., AL-Jumaily, S., Naji, N. and Kareem, Q., (2015). An Overview on the Influence of Pozzolanic

Materials on Properties of Concrete.International Journal of Enhanced Research in Science Technology & Engineering. 4 (3) 81-92.

Jafari, K., Tabatabaeian, M., Joshghani, A. and Ozbakkaloglu, T., “Optimizing the mixture design of polymer

concrete: An experimental investigation,†Construction and Building Materials, vol. 167, pp. 185-196, 2018.

Kanchana S. and Ebilin Sabu, (2018). Experimental Investigation of Epoxy Polymer Concrete with Partial

Replacement of Cement by Alccofine. International Research Journal of Engineering and Technology (IRJET). Volume 5 Issue 11, e-ISSN:2395-0056, p-ISSN:2395-0072

Kayali, O., (2008). Fly ash lightweight aggragates in high performance concrete Construction Building Material,

Vol. 22, 2393-2399

Khankahje, E. M., Hussin, W. J., Mirza, M., Rafieizonooz, M. R., Salim, H., Siong, C. and Warid, M. N., (2016). “On blended cement and geopolymer concretes containing palm oil fuel ash,†Materials & Design, vol. 89, pp. 385-398, 2016

Lei Wolong, Zhu Han and Liu ang, (2017). The influence of rubber particle content and particle size on mechanical and deformation properties of epoxy resin concrete.[J] .Industrial building 47(3) pp 137- 168

Liu Kefei, LiYuzhi and Peng Xingwang, (2008). Experimental study on shrinkage performance of epoxy resin

concrete.[J]. Chinese and Foreign Road28(1) pp 174-177

Malhotra, V. M. and Mehta, P. K., (1996). Pozzolanic and Cementitious Materials.Advances in concrete

technology.Vol.1.Gordon and Breach Publishers.

Nagaratnam, B. H., Rahman, M. E., Mirasa, A. K., Mannan M. A. and Lame, S. O., (2016). “Workability and

heat of hydration of self-compacting conrete incorporating agro-industrial waste,†Journal of Cleaner Production, vol. 112, no. 1, pp. 882-894.

Nawy, E.G., (2001). Fundamentals of high-performance concrete.John Wiley & Sons.

Ofuyatan O., Ede A., Olofinnade R., Oyebisi S., Alayande T. and Ogundipe J., (2018). Assessment of Strength

Properties of Cassava Peel Ash-Concrete, International Journal of Civil Engineering and Technology, 9(1), pp. 965–974.

Oladipo, I. O., Adams, J. O. and Akinwande, J. T., (2013). Using Cassava Peelings to Reduce Input Cost of

Concrete. A Waste-to-wealth Initiative in Southwestern Nigeria. Universal Journal of Environmental Research and Technology All Rights Reserved Euresian Publication © 2013 eISSN 2249 - 0256 2013 Volume 3, Issue 4: 511-516

Osuide E. E., Ukeme U.,Osuide, M. O., (2021). An Assessment of the Compressive Strength of Concrete made with Cement Partially Replaced with Cassava Peel Ash; P - ISSN: 2536 – 6866 e - ISSN: 2659 – 1529, SAU Sci-Tech. J., 6(1).

Parmar, A. and Patel, D.M., (2013). Experimental Study on High Performance Concrete by Using Alccofine and

Fly Ash-Hard Concrete Properties, International Journal of Engineering Research and Technology Vol 2- Issue 12, 3363-3366

Punmatharith, T., Rachakornkij, M., Imyim, A. and Wecharatana, M., (2010). “Co-processing of grinding sludge as alternative raw material in Portland cement clinker production,†Journal of Applied Sciences, 10 (15): 1525 – 1535.

Raheem, S. B., Arubike, E. D. and Awogboro, O. S., (2015). Effects of Cassava Peel Ash (CPA) as Alternative

Binder in Concrete. International Journal of Constructive Research in Civil Engineering (IJCRCE) Volume 1, Issue 2, pp 27 – 32.

Salau M.A, Ikponwosa E., and Olonade K., (2012). Structural strength characteristics of Cement cassava peel ash Civil and Environmental Research Vol. 2, No.12 (2010)

Tangchirapat, W., Saeting, T., Jaturapitakkul, C., Kiattikomol, K. and Siripanichgorn, A., (2007). “Use of waste ash from palm oil industry in conrete,†Waste Management, vol. 27, no. 1, pp. 81-88.

Ugwuoke, C. U., Monwuba, N., Onu, F.M., Shimave, A.G., Okonkwo, E.N. and Opurum, C.C., (2008). Impact of Agricultural Waste on Sustainable Environment and Health of Rural Women Civil and Environmental Research. 10 (9): 1-9.

Wang, R., Li, J., Zhang, T. and Czarnecki, L., (2016). “Chemical interaction between polymer and cement in

polymer-cement concrete,†Bulletin of the Polish Academy of Sciences. Technical Sciences., vol. 64, no. 4, pp. 785-792