Compressive Strength of Ternary Blended Geopolymer Concrete Composites

IF 0.7 Q4 ENGINEERING, CIVIL

Electronic Journal of Structural Engineering Pub Date : 2021-11-30 DOI:10.56748/ejse.21287

R.Kumutha, K.Vijai, S.K.Vinu

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Abstract

Use of industrial wastes as supplementary concreting materials in the manufacturing of concrete is very vital at present to obtain a sustainable environmental solution. Some of the commonly used pozzolanic materials are Fly ash, Ground Granulated Blast Furnace Slag (GGBS), Silica Fume and Rice Husk Ash (RHA) etc. In the present experimental investigation, the compressive strength property of ternary blended geopolymer concrete has been studied by considering Fly ash, Ground Granulated blast furnace slag (GGBS) and Rice Hush Ash (RHA) in various percentages as source materials for geopolymerisation. The source materials were activated with alkaline activators consisting of a combination of Sodium Hydroxide (NaOH) & Sodium Silicate (Na2SiO3) solutions with the concentration of NaOH being 10 molarity (10M). For various combinations of Fly ash, Rice Husk ash and GGBS the compressive strength for 7 days and 28 days were determined experimentally. From the test results, it has been found that as the GGBS content increases, the compressive strength of the concrete also increases whereas, as the content of RHA increases, the density and compressive strength of the concrete decreases. The optimum combination was found to be F60 G30 R10 and F70 G20 R10 for which the compressive strength of the concrete is 34.67 MPa and 24.87 MPa which can be used in applications where M30 and M20 grades of concrete are required. The density of F60 G30 R10 GPC is 2320 kg/m3 which is lesser than conventional concrete. It is also found that usage of 90% of rice husk ash in geopolymer concrete is not at all effective. The obtained compressive strengths are in the range of 10 MPa to 34.0 MPa which depends on the ratio of GGBS to RHA. Proper consumption of the RHA contributes in solving the environmental pollution and also to improve the environmental friendliness of concrete to make it suitable as a green building material.

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三元共混地聚合物混凝土复合材料的抗压强度

目前，在混凝土生产中使用工业废物作为补充混凝土材料对于获得可持续的环境解决方案至关重要。一些常用的火山灰材料是粉煤灰、磨细高炉矿渣（GGBS）、硅灰和稻壳灰（RHA）等。在本试验研究中，考虑粉煤灰对三元混合地质聚合物混凝土的抗压强度性能进行了研究，磨碎的粒状高炉矿渣（GGBS）和不同百分比的稻壳灰（RHA）作为地质聚合的原料。原料用碱性活化剂活化，碱性活化剂由氢氧化钠（NaOH）和硅酸钠（Na2SiO3）溶液的组合组成，NaOH浓度为10摩尔浓度（10M）。试验测定了粉煤灰、稻壳灰和GGBS的不同组合的7天和28天抗压强度。从试验结果中可以发现，随着GGBS含量的增加，混凝土的抗压强度也会增加，而随着RHA含量的提高，混凝土的密度和抗压强度会降低。最佳组合为F60 G30 R10和F70 G20 R10，其混凝土抗压强度分别为34.67MPa和24.87MPa，可用于需要M30和M20等级混凝土的应用中。F60 G30 R10 GPC的密度为2320 kg/m3，低于传统混凝土。研究还发现，在地聚合物混凝土中使用90%的稻壳灰根本无效。所获得的抗压强度在10MPa至34.0MPa的范围内，这取决于GGBS与RHA的比率。适当使用RHA有助于解决环境污染，也有助于提高混凝土的环境友好性，使其适合作为绿色建筑材料。

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来源期刊

Electronic Journal of Structural Engineering Engineering-Civil and Structural Engineering

CiteScore

1.10

自引率

16.70%

发文量

期刊介绍： The Electronic Journal of Structural Engineering (EJSE) is an international forum for the dissemination and discussion of leading edge research and practical applications in Structural Engineering. It comprises peer-reviewed technical papers, discussions and comments, and also news about conferences, workshops etc. in Structural Engineering. Original papers are invited from individuals involved in the field of structural engineering and construction. The areas of special interests include the following, but are not limited to: Analytical and design methods Bridges and High-rise Buildings Case studies and failure investigation Innovations in design and new technology New Construction Materials Performance of Structures Prefabrication Technology Repairs, Strengthening, and Maintenance Stability and Scaffolding Engineering Soil-structure interaction Standards and Codes of Practice Structural and solid mechanics Structural Safety and Reliability Testing Technologies Vibration, impact and structural dynamics Wind and earthquake engineering. EJSE is seeking original papers (research or state-of the art reviews) of the highest quality for consideration for publication. The papers will be published within 3 to 6 months. The papers are expected to make a significant contribution to the research and development activities of the academic and professional engineering community.