Study on the preparation and characterization of high-dispersibility nanosilica

Yu, Guo; Wang, Yanqing; Wang, Zhongming; Shen, Chengjin

doi:10.1515/secm-2014-0010

Cited by 10 publications

(2 citation statements)

References 4 publications

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“…e hydration reaction of ultrafine cement with high resistance to HPC is a physical and chemical process that includes the dissolution of minerals, the precipitation of ions, the crystallization of new minerals, the precipitation of products, the bonding, and the nucleation. e approximate expression of hydration reaction of ultrafine cement minerals with high resistance to HPC is [14][15][16]…”

Section: Preparation Of Full-length Anchoring Materialsmentioning

confidence: 99%

Research and Performance Test of New Full‐Length Anchorage Material

Huang

Meng

Zhao

et al. 2021

Advances in Materials Science and Engineering

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It is difficult to support roadway with anchor cable in view of impact tendency in impinging liability roadway; a new material of inorganic and high-performance full-length anchoring material for anchoring cable is developed by adding several modifiers with ultrafine cement as the main material. The purpose is to improve the mechanical properties and durability of cement-based materials, improve the coordination of anchor cable support system, and ensure the stability of surrounding rock of mining roadway. The new full-length anchoring material is developed by optimizing the proportion of different components of the material, and the mechanical properties of the new material were studied. The anchoring force of resin anchoring agent, ordinary Portland cement, blank ultrafine cement, and new full-length anchoring material are tested. Based on SEM microscopic characterization, the fracture types and failure characteristics of resin anchoring agent and full-length anchoring material are researched. The results show that the optimal content of each component of the new inorganic high-performance full-length anchorage material is as follows: the content of component A is 15%, the content of component B is 3%, the content of component C is 0.2%, the content of component D is 1%, and the content of component E is 1%; the tensile test shows that the full-length anchoring material has good bonding property, high anchoring strength, strong stability, and good rock coupling. SEM microstructure and morphology analysis have showed that the new anchorage materials can fully hydrate each other, resulting in a relatively dense stone body. The new full-length anchoring material can effectively improve the anchoring force and improve the stability of the anchor cable and has significant performance advantages and good engineering applicability, and it has the advantages of lower cost and safer to use. The new material is a very good supporting material for roadway.

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Section: Preparation Of Full-length Anchoring Materialsmentioning

confidence: 99%

Research and Performance Test of New Full‐Length Anchorage Material

Huang

Meng

Zhao

et al. 2021

Advances in Materials Science and Engineering

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“…One is application and development of mesomechanics [2][3][4], and the other one is the proposed property study of interface phase structure [5][6][7]. The fiber-matrix interface phase behavior plays an important role in determining the mechanical properties of GFRP composites such as elastic modulus, tensile strength, and fracture toughness, and it has received considerable attention and extensive investigations.…”

Section: Introductionmentioning

confidence: 99%

Numerical Research on the Pullout Failure of GFRP Bolt

Wang

et al. 2017

Advances in Materials Science and Engineering

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The fiber pullout is a main failure after the fiber is broken in the tension of glass fiber reinforced polymer (GFRP) bolt. In this paper, the numerical analysis is done on the distribution of both fiber normal force and interface shear stress. The results show that, on the ideal interface, the fiber pullout occurs from the lower end to the upper end of the matrix gradually, and both the normal stress of the fiber and the shear stress of the ideal interface gradually increase from the lower end to the upper end. With the increase of the interface layer thickness, the shear stress concentration area on the interface is enlarged while the stress applied is reduced, and the displacement of GFRP deformation is increasing sharply. This means that the capacity of GFRP deformation is enhanced. As a soft elastic body, the interface layer with a smaller elastic modulus can make the fiber stress and the interface shear stress sharply small and well dispersed. In addition, the load can be effectively transferred to the reinforced phase fibers in a bigger interfacial layer elastic modulus with a certain strength.

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Enhance interface thermal conductivity by forming the cladding structure between grafting BN and phase change material

Wu,

Jia

2024

Appl. Phys. A

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Study on the preparation and characterization of high-dispersibility nanosilica

Cited by 10 publications

References 4 publications

Research and Performance Test of New Full‐Length Anchorage Material

Research and Performance Test of New Full‐Length Anchorage Material

Numerical Research on the Pullout Failure of GFRP Bolt

Enhance interface thermal conductivity by forming the cladding structure between grafting BN and phase change material

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