Impact Resistance of Ultra-High-Performance Concrete Composite Structures

Ning, Huijun; Ren, Huiqi; Wang, Wei; Nie, Xiaodong

doi:10.3390/ma16237456

Cited by 6 publications

(3 citation statements)

References 29 publications

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“…Ultra-high-performance concrete (UHPC) represents a significant advancement in engineering materials, exhibiting enhanced workability, mechanical properties, and durability compared to conventional concrete [6][7][8][9]. Characterized by its high-density structure, UHPC effectively impedes the penetration of corrosive agents [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Enhancing Sulfate Erosion Resistance in Ultra-High-Performance Concrete through Mix Design Optimization Using the Modified Andreasen and Andersen Method

Wang,

Chen,

Shen

et al. 2024

Coatings

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This study presents an in-depth investigation into optimizing the mix design of ultra-high-performance concrete (UHPC) for enhanced sulfate erosion resistance, utilizing the modified Andreasen and Andersen (MAA) method. By testing the mechanical properties and slump flow of UHPC, it was determined that the optimal W/B = 0.2, and the best volume content of steel fibers is 2%. Through long-term tests lasting 360 days on three groups of UHPC specimens under different curing conditions, their mass loss, compressive strength corrosion resistance coefficient, surface appearance, and erosion layer thickness were tested. The results indicate that under sulfate attack, the mass and compressive strength corrosion resistance coefficients of UHPC specimens showed a trend of first increasing and then decreasing, due to the formation and expansion of ettringite and gypsum. The thickness of the erosion layer increases over time. By 360 days, the internal damage caused by sulfate attack is about twice as severe as it was after 60 days. However, the addition of steel fibers was found to effectively mitigate these effects, reducing mass loss and preserving the structural integrity of UHPC.

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Section: Introductionmentioning

confidence: 99%

Enhancing Sulfate Erosion Resistance in Ultra-High-Performance Concrete through Mix Design Optimization Using the Modified Andreasen and Andersen Method

Wang,

Chen,

Shen

et al. 2024

Coatings

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“…The bonding strength between the GFRP bar and concrete will differ from the bonding performance of GFRP ground bolts, and the actual state of geotechnical anchoring engineering would be inconsistent without considering the influence of grouting on anchoring performance in bonding strength tests between a GFRP bar and concrete. Existing studies have primarily centered on concrete structures [ 16 , 17 ], emphasizing the analysis of bonding strength at interfaces with concrete [ 18 ] or mortar, with a limited exploration of other geological materials such as sandy soil, clay soil, and various weathered rock masses [ 19 ]. Liu et al [ 20 ] conducted experimental studies to investigate the factors influencing the anchoring performance of fully threaded GFRP mortal bolts, using concrete with a strength grade of C60 to simulate rock mass.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Durability and Bond Properties of GFRP Resin Bolts

Lin,

Zhang,

Wang

2024

Materials

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Glass fiber-reinforced polymer (GFRP) anchor bolts are a new type of high-performance nonmetallic anchor with significantly higher tensile strength, a lighter weight, better corrosion resistance, and a lower cost than steel bars. Therefore, exploring the durability and bonding performance of GFRP anchor systems is of great importance for the structural design of protective engineering, especially in coastal environments. However, insufficient research has been conducted on the durability of GFRP resin bolts in seawater conditions, with no universal standard on the pullout testing of GFRP bolts. To study the durability and bonding performance of GFRP resin bolts, durability experiments were conducted in this work using artificial seawater, and the pullout tests were conducted using a large-scale concrete platform with different compressive strengths (21.2, 40.8, and 61.3 MPa). The results of the durability experiments indicated that the strength variations of the GFRP rods and epoxy resin materials in artificial seawater environments were less than 5%. Subsequently, indoor pullout tests using steel tubes filled with epoxy resin were conducted, and the test results indicated a critical anchor length value. Pullout tests of the GFRP resin bolts embedded in large-scale concrete blocks were also conducted with different strengths. According to the test results, all GFRP resin bolts embedded in the three concrete blocks with different compressive strengths exhibited rod fracture failure. The failure mode was not controlled via the compressive strength of the concrete blocks due to the high bonding strength between the resin and the rod, as well as between the resin and the concrete. Therefore, this GFRP resin anchor system could fully utilize the tensile strength of GFRP rods. This research offers significant practical value in verifying the safety and reliability of GFRP resin bolts in corrosive marine service environments, and it contributes to the application and development of GFRP materials in the engineering field, serving as a valuable reference for the structural design and further study of GFRP bolts.

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“…Impact resistance refers to dynamic mechanical tests and is characterized by the destruction of test specimens with a high speed of loading (impact) [1]. When testing impact resistance internal defects, position of the part in relation to the load, notches, etc [2]., are important.…”

Section: Introductionmentioning

confidence: 99%

Designing a Laboratory Stand for Testing Impact Resistance of Plastic Films by Free-Falling Dart Drop According Astm D1709

Sabev,

Chukalov,

Bakardzhiev

2024

ETR

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In this article, the process of designing a laboratory stand for testing impact resistance of plastic films using free-falling dart drop method according to ASTM D1709, type A will be followed. It will be analyzed the all stages of designing-synthesis of project solutions, analysis and optimization, assessment and presentation of tasks. The purpose of the article is to create a designing basis for the variable design of impact resistance stands to be used in the design of non-standardized laboratory equipment.

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Impact Resistance of Ultra-High-Performance Concrete Composite Structures

Cited by 6 publications

References 29 publications

Enhancing Sulfate Erosion Resistance in Ultra-High-Performance Concrete through Mix Design Optimization Using the Modified Andreasen and Andersen Method

Enhancing Sulfate Erosion Resistance in Ultra-High-Performance Concrete through Mix Design Optimization Using the Modified Andreasen and Andersen Method

Experimental Study on Durability and Bond Properties of GFRP Resin Bolts

Designing a Laboratory Stand for Testing Impact Resistance of Plastic Films by Free-Falling Dart Drop According Astm D1709

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