A Review of the Use of Corncob Ash as a Supplementary Cementitious Material

Ash Ahmed; John Kamau

doi:10.24018/ejeng.2017.2.8.415

Research Article

Senior Lecturer in Materials Science School of the Built Environment & Engineering Leeds Beckett University Civic Quarter Northern Terrace Leeds LS2 8AG

* Corresponding author

John Kamau

Civil Engineering Group. Leeds Beckett University, Leeds

10.24018/ejeng.2017.2.8.415

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Submitted 2017-07-12
Published 2017-08-15

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Abstract

It has been argued that cement is the most energy intensive and expensive material in concrete. It has also been suggested that energy efficiency could be achieved by using Supplementary Cementitious Materials (SCMs), which require less process heating and emit fewer levels of CO₂. This paper reviewed studies from different authors on the possibility of using Corn Cob Ash (CCA) as a SCM. The review targeted studies that had applied the quantitative method, with validity and reliability based on empirical data from laboratory experiments. The review covered workability, density, compressive and tensile strengths, gain in strength over time, water absorption and chemical resistance of CCA-replaced concrete. From the findings, it can be concluded that CCA could be used as an effective SCM to replace cement in concrete, with the benefit of a reduction in CO₂ emissions that are associated with the production of cement and a mitigation on environmental nuisance that is attributed to the throwing away of corncobs and CCA in landfill, while at the same time improving the properties of wet and hardened concrete.

Keywords: Corncob Ash Maize Cob Ash Pozzolans Supplementary Cementitious Materials Cement Replacements

References

M. Islam and M. Islam, "Strength and durability characteristics of concrete made with fly-ash blended cement," Australian Journal of Structural Engineering, vol. 14, 2013.
Google Scholar

D. Adesanya and A. Raheem, "Development of corn cob ash blended cement," Construction and Building Materials, vol. 23, pp. 347-352, 2008.
Google Scholar

K. J. Rao, M. A. Mujeeb, and M. Sastri, "Behavior of Ternary Blended Concrete with Fly Ash and Silica Fume," IUP Journal of Structural Engineering, vol. 7, p. 25, 2014.
Google Scholar

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Google Scholar

Mineral Products Association, "Fact Sheet 18 [Part 1] Embodied CO2 of UK Cement," Additions and Cementitious Material, p. 8, 2007.
Google Scholar

J. Osunade, "Effect of replacement of lateritic soils with granite fines on the compressive and tensile strengths of laterized concrete," Building and Environment, vol. 37, pp. 491-496, 2002.
Google Scholar

M. L. Gambhir, Concrete Technology 4e. Tata McGraw-Hill Education, ISBN 0070583749: Tata McGraw-Hill Education, 2009.
Google Scholar

J. D. Bapat, Mineral admixtures in cement and concrete: CRC Press, 2012.
Google Scholar

T. C. Holland, Silica fume user's manual: Federal Highway Administration, Silica Fume Association (SFA) Washington, 2005.
Google Scholar

British Standards Institution, "BS EN 197-1:2000. Part 1. Cement composition, specifications and conformity criteria for common cements. British Standards Institution (BSI), London, UK," in BSOL, ed, 2000.
Google Scholar

N. M. Al-Akhras, "Durability of metakaolin concrete to sulfate attack. Cement and concrete research, 36(9), 1727-1734., (Khedr and Idriss, 1995)," 2006.
Google Scholar

American Society for Testing and Materials, "ASTM C618. Standard specification for coal fly ash and raw or calcined naturalpozzolan for use in concrete, American Society for Testing and Materials, ASTM International, West Conshohocken, PA, 2012, DOI: 10.1520/C0618-12,," ed, 2012.
Google Scholar

G. Hannesson, K. Kuder, R. Shogren, and D. Lehman, "The influence of high volume of fly ash and slag on the compressive strength of self-consolidating concrete," Construction and Building Materials, vol. 30, pp. 161-168, 2012.
Google Scholar

C. L. Page and M. M. Page, Durability of concrete and cement composites: Elsevier, Woodhead publishing. ISBN 9781855739406, 2007.
Google Scholar

M. Shetty, Concrete technology: theory and practice: S. Chand. ISBN 8121900034, 2005.
Google Scholar

C. R. Kothari, "Research methodology: Methods and techniques," vol. 2e, 2004.
Google Scholar

A. Price, R. Yeargin, E. Fini, and T. Abu-Lebdeh, "Investigating effects of introduction of corncob ash into portland cements concrete: Mechanical and thermal properties," Am. J. Eng. Applied Sci, vol. 7, pp. 133-144, 2014.
Google Scholar

F. F. Udoeyo and S. A. Abubakar, "Maize-cob ash as filler in concrete," Journal of materials in civil engineering, vol. 15, pp. 205-208, 2003.
Google Scholar

D. Adesanya, "Evaluation of blended cement mortar, concrete and stabilized earth made from ordinary Portland cement and corn cob ash," Construction and Building Materials, vol. 10, pp. 451-456, 1996.
Google Scholar

D. A. Adesanya and A. A. Raheem, "A study of the workability and compressive strength characteristics of corn cob ash blended cement concrete," Construction and Building Materials, vol. 23, pp. 311-317, 2009.
Google Scholar

D. Adesanya and A. Raheem, "A study of the permeability and acid attack of corn cob ash blended cements," Construction and Building Materials, vol. 24, pp. 403-409, 2010.
Google Scholar

J. Kamau, A. Ahmed, P. Hirst, and J. Kangwa, "Suitability of Corncob Ash as a Supplementary Cementitious Material," International Journal of Materials Science and Engineering, vol. 4, pp. 215-228, 2016.
Google Scholar

O. Olafusi and F. Olutoge, "Strength properties of corn cob ash concrete," Journal of Emerging Trends in Engineering and Applied Sciences, vol. 3, pp. 297-301, 2012.
Google Scholar

J. Kamau, A. Ahmed, P. Hirst, and J. Kangwa, "Permeability of corncob ash, anthill soil and rice husk ash replaced concrete," International Journal of Science, Environment and Technology, vol. 6, pp. 1299-1308, 2017.
Google Scholar

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Google Scholar

British Standards Institution, "BS EN 1992-1-1:2000. Eurocode 2: Design of Concrete Structures‚ Part 1-1: General Rules and Rules for Buildings. BSI, London, UK," ed, 2004.
Google Scholar

C. Arya, Design of structural elements: concrete, steelwork, masonry and timber designs to British standards and Eurocodes. Spon Press, LONDON AND NEW YORK: Taylor & Francis, 2009.
Google Scholar

F. A. Oluokun, "Fly ash concrete mix design and the water-cement ratio law," Materials Journal, vol. 91, pp. 362-371, 1994.
Google Scholar

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[1]

2017. A Review of the Use of Corncob Ash as a Supplementary Cementitious Material. European Journal of Engineering and Technology Research. 2, 8 (Aug. 2017), 1–6. DOI:https://doi.org/10.24018/ejeng.2017.2.8.415.

Issue

Vol. 2 No. 8: AUGUST 2017

[1] M. Islam and M. Islam, "Strength and durability characteristics of concrete made with fly-ash blended cement," Australian Journal of Structural Engineering, vol. 14, 2013.
Google Scholar

[2] D. Adesanya and A. Raheem, "Development of corn cob ash blended cement," Construction and Building Materials, vol. 23, pp. 347-352, 2008.
Google Scholar

[3] K. J. Rao, M. A. Mujeeb, and M. Sastri, "Behavior of Ternary Blended Concrete with Fly Ash and Silica Fume," IUP Journal of Structural Engineering, vol. 7, p. 25, 2014.
Google Scholar

[4] M. E. Johnson and A. Gonzalez, "Estimating Cost Savings for Aviation Fuel and CO 2 Emission Reductions Strategies," Collegiate Aviation Review, vol. 31, 2013.
Google Scholar

[5] Mineral Products Association, "Fact Sheet 18 [Part 1] Embodied CO2 of UK Cement," Additions and Cementitious Material, p. 8, 2007.
Google Scholar

[6] J. Osunade, "Effect of replacement of lateritic soils with granite fines on the compressive and tensile strengths of laterized concrete," Building and Environment, vol. 37, pp. 491-496, 2002.
Google Scholar

[7] M. L. Gambhir, Concrete Technology 4e. Tata McGraw-Hill Education, ISBN 0070583749: Tata McGraw-Hill Education, 2009.
Google Scholar

[8] J. D. Bapat, Mineral admixtures in cement and concrete: CRC Press, 2012.
Google Scholar

[9] T. C. Holland, Silica fume user's manual: Federal Highway Administration, Silica Fume Association (SFA) Washington, 2005.
Google Scholar

[10] British Standards Institution, "BS EN 197-1:2000. Part 1. Cement composition, specifications and conformity criteria for common cements. British Standards Institution (BSI), London, UK," in BSOL, ed, 2000.
Google Scholar

[11] N. M. Al-Akhras, "Durability of metakaolin concrete to sulfate attack. Cement and concrete research, 36(9), 1727-1734., (Khedr and Idriss, 1995)," 2006.
Google Scholar

[12] American Society for Testing and Materials, "ASTM C618. Standard specification for coal fly ash and raw or calcined naturalpozzolan for use in concrete, American Society for Testing and Materials, ASTM International, West Conshohocken, PA, 2012, DOI: 10.1520/C0618-12,," ed, 2012.
Google Scholar

[13] G. Hannesson, K. Kuder, R. Shogren, and D. Lehman, "The influence of high volume of fly ash and slag on the compressive strength of self-consolidating concrete," Construction and Building Materials, vol. 30, pp. 161-168, 2012.
Google Scholar

[14] C. L. Page and M. M. Page, Durability of concrete and cement composites: Elsevier, Woodhead publishing. ISBN 9781855739406, 2007.
Google Scholar

[15] M. Shetty, Concrete technology: theory and practice: S. Chand. ISBN 8121900034, 2005.
Google Scholar

[16] C. R. Kothari, "Research methodology: Methods and techniques," vol. 2e, 2004.
Google Scholar

[17] A. Price, R. Yeargin, E. Fini, and T. Abu-Lebdeh, "Investigating effects of introduction of corncob ash into portland cements concrete: Mechanical and thermal properties," Am. J. Eng. Applied Sci, vol. 7, pp. 133-144, 2014.
Google Scholar

[18] F. F. Udoeyo and S. A. Abubakar, "Maize-cob ash as filler in concrete," Journal of materials in civil engineering, vol. 15, pp. 205-208, 2003.
Google Scholar

[19] D. Adesanya, "Evaluation of blended cement mortar, concrete and stabilized earth made from ordinary Portland cement and corn cob ash," Construction and Building Materials, vol. 10, pp. 451-456, 1996.
Google Scholar

[20] D. A. Adesanya and A. A. Raheem, "A study of the workability and compressive strength characteristics of corn cob ash blended cement concrete," Construction and Building Materials, vol. 23, pp. 311-317, 2009.
Google Scholar

[21] D. Adesanya and A. Raheem, "A study of the permeability and acid attack of corn cob ash blended cements," Construction and Building Materials, vol. 24, pp. 403-409, 2010.
Google Scholar

[22] J. Kamau, A. Ahmed, P. Hirst, and J. Kangwa, "Suitability of Corncob Ash as a Supplementary Cementitious Material," International Journal of Materials Science and Engineering, vol. 4, pp. 215-228, 2016.
Google Scholar

[23] O. Olafusi and F. Olutoge, "Strength properties of corn cob ash concrete," Journal of Emerging Trends in Engineering and Applied Sciences, vol. 3, pp. 297-301, 2012.
Google Scholar

[24] J. Kamau, A. Ahmed, P. Hirst, and J. Kangwa, "Permeability of corncob ash, anthill soil and rice husk ash replaced concrete," International Journal of Science, Environment and Technology, vol. 6, pp. 1299-1308, 2017.
Google Scholar

[25] British Standards Institution, "BS EN 206:2013. Concrete-Specification, performance, production and conformity. BSI, London, UK," in BSI Standards Publication, ed, 2013.
Google Scholar

[26] British Standards Institution, "BS EN 1992-1-1:2000. Eurocode 2: Design of Concrete Structures‚ Part 1-1: General Rules and Rules for Buildings. BSI, London, UK," ed, 2004.
Google Scholar

[27] C. Arya, Design of structural elements: concrete, steelwork, masonry and timber designs to British standards and Eurocodes. Spon Press, LONDON AND NEW YORK: Taylor & Francis, 2009.
Google Scholar

[28] F. A. Oluokun, "Fly ash concrete mix design and the water-cement ratio law," Materials Journal, vol. 91, pp. 362-371, 1994.
Google Scholar

A Review of the Use of Corncob Ash as a Supplementary Cementitious Material

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