Density and Water Absorption Coefficient of Sandcrete Blocks Produced with Waste Paper ash as Partial Replacement of Cement

1. N.E. Ekpenyong, G.P. Umoren, I.E. Udo, O.J. Yawo (2022): Assessment of Thermophysical and Mechanical Properties of Composite Panels Fabricated from Untreated and Treated Coconut Husk Particles for Structural Application, Brilliant Engineering, 2; 1-5, https://doi.org/10.36937/ben.2022.454710.36937/ben.2022.4547 Search in Google Scholar

2. B.M. Kejela (2020): Waste Paper Ash as partial replacement of cement in concrete, American Journal of Construction and Building Materials, 4(1); 8–13. https://doi.org/10.11648/j.ajcbm.2020401.12 Search in Google Scholar

3. U.W. Robert, S.E. Etuk, G.P. Umoren, O.E. Agbasi (2019): Assessment of thermal and mechanical properties of composite board produced from coconut (Cocos nucifera) husks, waste newspapers, and cassava starch, International Journal of Thermophysics, 40(9):1 - 12, https://doi.org/10.1007/s10765-019-2547-810.1007/s10765-019-2547-8 Search in Google Scholar

4. E.U. Nathaniel, U.W. Robert, M.E.Asuquo (2020): Evaluation of Properties of Composite Panels Fabricated from Waste Newspaper and Wood Dust for Structural Application, Journal of Energy Research and Reviews, 5(1): 8-15, https://doi.org/10.9734/JENRR/2020/v5i13013810.9734/jenrr/2020/v5i130138 Search in Google Scholar

5. U.W. Robert, S.E. Etuk, U.A. Iboh, G.P. Umoren, O.E. Agbasi, Z.T. Abdulrazzaq (2020): Thermal and mechanical properties of fabricated plaster of paris filled with groundnut seed coat and waste newspaper materials for structural application, Építôanyag-Journal of Silicate Based and Composite Materials, 72(2); 72 – 78,https://doi.org/10.14382/epĩtõanyag-jsbcm.2020.12 Search in Google Scholar

6. B.A. Solahuddin, F.M. Yahaya (2021): Effect of Shredded Waste Paper on Properties of Concrete, 4th National Conference on Wind & Earthquake Engineering, IOP Conf. Series: Earth and Environmental Science, 682; 012006, https://doi.org/10.1088/1755-1315/682/1/01200610.1088/1755-1315/682/1/012006 Search in Google Scholar

7. B. A. Solahuddin, F. M. Yahaya (2021): Inclusion of Waste Paper on Concrete Properties: A Review, Civil Engineering, 7; 94 – 113, https://dx.doi.org/10.28991/CEJ-SP2021-07-0710.28991/CEJ-SP2021-07-07 Search in Google Scholar

8. B.B. Mitikie, D.T. Waldtsadik (2022): Partial Replacement of Cement by Waste Paper Pulp Ash and Its Effect on Concrete Properties, Advances in Civil Engineering, 8880196, https://doi.org/10.1155/2022/888019610.1155/2022/8880196 Search in Google Scholar

9. S. Subanndi, F. Agustina, V. Vebrian, R. Azzahra (2020): Waste Paper Ash as Additives for High Strength Concrete Mix 45 MPa, Annales de Chimie Science des Matériaux, 44(2); 91 – 96, https://doi.org/10.18280/acsm.44020310.18280/acsm.440203 Search in Google Scholar

10. B. Meko, J. Ighalo (2021): Utilization of waste paper ash as supplementary cementitious material in C-25 concrete: Evaluation of fresh and hardened properties, Cogent Engineering, 8:1, 1938366, https://doi.org/10.1080/23311916.2021.193836610.1080/23311916.2021.1938366 Search in Google Scholar

11. J.P. Azar, M. Najarchi, B. Sanaati et al (2019): The experimental assessment of the effect of paper waste ash and silica fume on improvement of concrete behavior, KSCE Journal of Civil Engineering., 23; 4503 – 4515, https://doi.org/10.1007/s12205-019-0678-x10.1007/s12205-019-0678-x Search in Google Scholar

12. U.W. Robert, S.E. Etuk, O.E. Agbasi, G.P. Umoren, S.S. Akpan, L.A. Nnanna (2021): Hydrothermally-calcined waste paper ash nanomaterial as an alternative to cement for clay soil modification for building purposes, Acta Polytechnica, 61(6); 749–761, https://doi.org/10.14311/AP.2021.61.074910.14311/AP.2021.61.0749 Search in Google Scholar

13. M. O’mara, How much paper is used in one day? Record Nations, March 26, 2021, www.recordnations.com Search in Google Scholar

14. R.W.J. McKinney (1995): Technology of paper recycling, Blackie Academic and Professional, Chapman and Hall, New York, London, pp. 7 – 15 Search in Google Scholar

15. L. Simäo, D. Hotza, F. Raupp-Pereira, J.A. Labrincha, O.R.K. Montedo (2018): Wastes from pulp and paper mills – a review of generation and recycling alternatives, Cerāmica, 64 (371), https://doi.org/10.1590/0366-6913 Search in Google Scholar

16. U.W. Robert, S.E. Etuk, J.B. Emah, O.E. Agbasi, U.A.Iboh (2022): Thermophysical and Mechanical Properties of Clay-Based Composites developed with Hydrothermally Calcined Waste Paper Ash Nanomaterial for Building Purposes, International Journal of Thermophysics, 43(5); 1 - 20, https://doi.org/10.1007/s10765-022-02995-110.1007/s10765-022-02995-1 Search in Google Scholar

17. A.E. Adeniran, A. Nubi, A. Adelopo (2017): Solid waste generation and characterisation in the University of Lagos for a sustainable waste management, Waste Management, 67;3 – 10,https://doi.org/10.1016/j.wasman.2017.05.00210.1016/j.wasman.2017.05.00228532622 Search in Google Scholar

18. U.W. Robert, S.E. Etuk, O.E. Agbasi, U.S. Okorie, A. Lashin (2021): Hygrothermal properties of sandcrete blocks produced with raw and hydrothermally-treated sawdust as partial substitution materials for sand, Journal of King Saud University – Engineering Sciences, https://doi.org/10.1016/j.jksues.2021.10.00510.1016/j.jksues.2021.10.005 Search in Google Scholar

19. U.W. Robert, S.E. Etuk, O.E. Agbasi, S.A. Ekong (2020): Properties of sandcrete block produced with coconut husk as partial replacement of sand, Journal of Building Materials and Structures, 7(1); 95 – 104, https://doi.org/10.5281/zenodo.3993274 Search in Google Scholar

20. G.L. Oyekan, O.M. Kamiyo (2011): A case study on the engineering properties of sandcrete blocks produced with rice husk ash blended cement, Journal of Engineering and Technology Research, 3(2); 88 – 98, https://doi.org/www.academicjournals.org/JETR Search in Google Scholar

21. W. Khan, M. Fahim, S. Zaman, S.W. Khan, Y.I. Badrashi, F. Khan (2021): Use of rice husk ash as partial replacement of cement in sandcrete block, Advances in Science and Technology. Research Journal, 15(2); 101 – 107, https://doi.org/10.12913/22998624/13347010.12913/22998624/133470 Search in Google Scholar

22. M.I. Aho, J.T, Utsev (2008): Compressive strength of hollow sandcrete blocks made with rice husk ash as a partial replacement to cement, Nigerian Journal of Technology, 27(2) Search in Google Scholar

23. T. Alkamu, I. Emmanuel, E.P. Datok, D.D. Jambol (2018): Guinea corn husk ash as partial replacement of cement in hollow sandcrete block production, International Journal of Modern Trends in Engineering and Research, 5(6); 13 – 19, https://doi.org/10.21884/ijmter.2018.5163.xljyk10.21884/IJMTER.2018.5163.XLJYK Search in Google Scholar

24. H. Mahmoud, Z.A. Belel, C. Nwakaire (2012): Groundnut shell ash as a partial replacement of cement in sandcrete blocks production, International Journal of Development and Sustainability, 1(3); 1026 - 1032 Search in Google Scholar

25. IC. Christopher, O.I. Ndubuisi, N.D. Chimobi, O.V. Arinze, J.N. Ezema (2018): Partial replacement of cement with coconut shell ash in sandcrete block, Research Journal of Applied Sciences, Engineering and Technology, 15(6); 206–211, https://doi.org/10.19026/rjaset.15.585910.19026/rjaset.15.5859 Search in Google Scholar

26. U.W. Robert, S.E. Etuk, O.E. Agbasi, G.P. Umoren, N.J. Inyang (2021): Investigation of thermophysical and mechanical properties of board produced from coconut (Cocos nucifera) leaflet. Environmental Technology & Innovation, 24(1), 101869, https://doi.org/10.1016/j.eti.2021/101869 Search in Google Scholar

27. M. Bediako, E.O. Amankwah (2015): Analysis of chemical composition of cement in Ghana: A key to understand the behaviour of cement, Advances in Materials Science and Engineering, 349401, 1–5. https://doi.org/10.1155/2015/34940110.1155/2015/349401 Search in Google Scholar

28. U.W. Robert, S.E. Etuk, O.E. Agbasi, U.S. Okorie, Z.T. Abdulrazzaq, A.U. Anonaba, O.T. Ojo (2021): On the hygrothermal properties of sandcrete blocks produced with sawdust as partial replacement of sand, Journal of the Mechanical Behavior of Materials, 30(1); 144–155, https://doi.org/10.1515/jmbm-2021-001510.1515/jmbm-2021-0015 Search in Google Scholar

29. BS 2028 (1975): British Standard Institute, Precast concrete blocks, London Search in Google Scholar

30. ASTM C150 (2020): Standard Specification for Portland Cement, ASTM International, West Conshohocken, PA Search in Google Scholar

31. U.W. Robert, S.E. Etuk, O.E. Agbasi, S.A. Ekong, Z.T. Abdulrazzaq, A.U. Anonaba (2021): Investigation of Thermal and Strength Properties of Composite Panels Fabricated with Plaster of Paris for Insulation in Buildings, International Journal of Thermophysics, 42(2), 1-18, https://doi.org/10.1007/s10765-020-02780-y10.1007/s10765-020-02780-y Search in Google Scholar

32. S.E. Etuk, O.E. Agbasi, S.S. Ekpo, U.W. Robert, (2020): Gamma Radiation determination of absorption coefficients of cement sand block, Cumhuriyet Science Journal, 41(1), 38 – 42; https://dx.doi.org/10.177776/csj.624318 Search in Google Scholar

33. S.E. Etuk, O.E. Agbasi, Z.T. Abdulrazzaq, U.W. Robert (2018): Investigation of thermophysical properties of Alates (swarmers) termites wing as potential raw material for insulation, International Journal of Scientific World, 6(1), 1 – 7, https://doi.org/10.14419/ijsw.v6i1.852910.14419/ijsw.v6i1.8529 Search in Google Scholar

34. U.W. Robert, S.E. Etuk, O.E. Agbasi, G.P. Umoren (2020): Comparison of clay soils of different colors existing under same conditions in a location, Imam Journal of Applied Sciences, 5(2); 68 – 73, https://doi.org/10.4103/ijas_35_19 Search in Google Scholar

35. USP (2007): Powder Flow. In: The United States Pharmacopeia 30-National Formulary 25 Convention, Rockville. Search in Google Scholar

36. H. Lu, X. Guo, Y. Liu, X. Gong (2015): Effects of particle size on flow mode and flow characteristics of pulverized coal, Kona Powder Part I, 32; 143–153. https://doi.org/10.14356/kona.201500210.14356/kona.2015002 Search in Google Scholar

37. ASTM C618 (2019): Standard Specification for Coal Fly Ash and Raw or Calcined Natural Pozzolan for use in concrete, ASTM International, West Conshohocken. Search in Google Scholar

38. B.M. Alssoun, S. Hwang, K.H. Khayat (2015): Influence of aggregate characteristics on workability of superworkable concrete, Materials and Structures, 49(1), https://doi.org/10.1617/s11527-015-0522-910.1617/s11527-015-0522-9 Search in Google Scholar

39. M. Kang, L. Weibin (2018): Effect of the recycled aggregate concrete, Advances in Materials Science and Engineering, 2428576, https://doi.org/10.1155/2018/242857610.1155/2018/2428576 Search in Google Scholar

40. B. Nagy, D. Szagri (2016): Hygrothermal properties of steel fiber reinforced concretes, Applied Mechanics and Materials, 824; 579–588, https://doi.org/10.4028/www.scientific.net/AMM.824.57910.4028/www.scientific.net/AMM.824.579 Search in Google Scholar

41. C. Egenti, J. M. Khatib, D. Oloke (2013): Analysis of expansion and water absorption of composite compressed earth block, Conference Paper, https://www.researchgate.net/publication Search in Google Scholar

42. B.K. Baiden, M.M. Tuuli (2004): Impact of Quality Control Practices in Sandcrete Blocks Production, Journal of Architectural Engineering, 10(2), 53–6010.1061/(ASCE)1076-0431(2004)10:2(53) Search in Google Scholar

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