Strength and Durability of High Performance Concrete Doped New Low Clinker Cementing Material

Shuai Huang; Yue Jun Lyu; Yan Ju Peng; Li Fang Zhang

doi:10.4028/www.scientific.net/KEM.765.370

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 765Strength and Durability of High Performance...

Strength and Durability of High Performance Concrete Doped New Low Clinker Cementing Material

Abstract:

A new low clinker cementing material applying to different concrete strength is developed in this paper. The experiential results show that standard consistency water consumption of the new material is less than the ordinary material; and the particle size is better than the ordinary material. And the cracking performance of the concrete made by the new material is far better than the performance of the concrete made by the ordinary material. Furthermore, the shrinkage of the concrete made by new material is less; and the resistance ability to carbonation is higher. Especially, our proposed new material could make the gel body dense and become six components of concrete into four, which simplifies the production process of concrete mixing station. At the same time, the prepared concrete made by the new material has better construction performance, volume stability and high durability. Unfortunately, the initial and final setting time of the new material are slightly longer. However, the initial and final setting time are still able to meet the national requirements. And most of all the new material meets the requirements of green high performance concrete.

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Periodical:

Key Engineering Materials (Volume 765)

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370-376

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.765.370

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Online since:

March 2018

Authors:

Shuai Huang*, Yue Jun Lyu, Yan Ju Peng, Li Fang Zhang

Keywords:

Concrete, Durability, New Low Clinker Cementing Material, Strength

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References

[1] JI Escalante , LY Gómez , KK Johal , G Mendoza , H Mancha, et al. Reactivity of blast-furnace slag in portland cement blends hydrated under different conditions, Cement & Concrete Research, 31 (2001) 1403-1409.

DOI: 10.1016/s0008-8846(01)00587-7

Google Scholar

[2] J. Davidovits. Ancient and modern concretes: what is the real difference. Concrete International, 12 (1987) 23-28.

Google Scholar

[3] S. A. Podmasova, SH. T. Babev and YU. S. Volkov, New low water demand binders for high-strength concretes. Proceedings of International Conference on High-Strength Concrete, Norway (1993).

Google Scholar

[4] J.E. Jonasson and V. Ronin. Energrtically modified cement (EMC). Proceedings of International Conference on High-Strength Concrete, Norway (1993).

Google Scholar

[5] Sun M B. A new method for the mix design of medium strength flowing concrete with low cement content. Cement and Concrete Composites, 25 (2003) 215-222.

DOI: 10.1016/s0958-9465(02)00013-6

Google Scholar

[6] Heikal M, Didamony H E and Morsy M S. Limestone-filler pozzolanic cement, Cement and Concrete Research, 30(2000) 1827-1834.

DOI: 10.1016/s0008-8846(00)00402-6

Google Scholar

[7] Jin-keun Kim and Chil-Sung Lee. Moisture diffusion of concrete considering self-desiccation at early ages, CCR, 29 (1999) 1921-(1927).

DOI: 10.1016/s0008-8846(99)00192-1

Google Scholar

[8] Powers T C: Freezing effects in concrete Durability of concrete, Special Publication SP-47(ACI), (1975).

Google Scholar

[9] Detwiler R.J and Tennis P.D. The use of limestone in portland cement: a state of the art review, Skokie, IL: Portland Cement Association (1996).

Google Scholar

[10] TAYLOR H F M. Cement chemistry. London: Thomas Telford (1990) 293- 295.

Google Scholar

[11] O Gencel, C Ozel, W Brostow and G Martínez-Barrera. Effect of metallic aggregate and cement content on abrasion resistance behaviour of concrete, Materials Research Innovations,15 ( 2011), 116-123.

DOI: 10.1179/143307511x12998222918877

Google Scholar

[12] H. Z. Cui, T. Y. Lo and F. Xing. Properties of self-compacting lightweight concrete. Materials Research Innovations, 14 (2010) 392-396.

DOI: 10.1179/143307510x12820854748953

Google Scholar