Mechanical Behavior Based on Aggregates Microstructure of Ultra-high Performance Concrete

Qingjun Ding; Changsheng Zhou; Gaozhan Zhang; Hong Guo; Yang Li; Yongyuan Zhang; Kaizheng Guo

doi:10.1007/s11595-024-2925-3

Journal of Wuhan University of Technology Materials Science Edition ›› 2024, Vol. 39 ›› Issue (3) : 673 -681. DOI: 10.1007/s11595-024-2925-3

Cementitious Materials

Mechanical Behavior Based on Aggregates Microstructure of Ultra-high Performance Concrete

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Abstract

We developed ultra-high performance concrete (UHPC) incorporating mullite sand and brown corundum sand (BCS), and the quartz sand UHPC was utilized to prepare for comparison. The properties of compressive strength, elastic modulus, ultrasonic pulse velocity, flexural strength, and toughness were investigated. Scanning electron microscopy and nanoindentation were also conducted to reveal the underlying mechanisms affecting macroscopic performance. Due to the superior interface bonding properties between mullite sand and matrix, the compressive strength and flexural toughness of UHPC have been significantly improved. Mullite sand and BCS aggregates have higher stiffness than quartz sand, contributing to the excellent elastic modulus exhibited by UHPC. The stiffness and volume of aggregates have a more significant impact on the elastic modulus of UHPC than interface performance, and the latter contributes more to the strength of UHPC. This study will provide a reference for developing UHPC with superior elastic modulus for structural engineering.

Keywords

ultra-high performance concrete / mechanical properties / fine aggregates / microstructure / nanoindentation

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Qingjun Ding, Changsheng Zhou, Gaozhan Zhang, Hong Guo, Yang Li, Yongyuan Zhang, Kaizheng Guo. Mechanical Behavior Based on Aggregates Microstructure of Ultra-high Performance Concrete. Journal of Wuhan University of Technology Materials Science Edition, 2024, 39(3): 673-681 DOI:10.1007/s11595-024-2925-3

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References

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[1]	Arora A, Almujaddidi A, Kianmofrad F, et al. Material Design of Economical Ultra-high Performance Concrete (UHPC) and Evaluation of Their Properties[J]. Cem. Concr. Compos., 2019, 104: 103 346.

[2]	Yoo D-Y, Banthia N. Mechanical Properties of Ultra-High Performance Fiber-reinforced Concrete: A Review[J]. Cement and Concrete Composites, 2016, 73: 267-280.

[3]	Chu H, Zhang Y, Wang F, et al. Effect of Graphene Oxide on Mechanical Properties and Durability of Ultra-high-performance Concrete Prepared from Recycled Sand[J]. Nanomaterials, 2020, 10(9): 1 718

[4]	Gu C P, Ye G, Sun W. Ultrahigh Performance Concrete-Properties, Applications and Perspectives[J]. Science China Technological Sciences, 2015, 58: 587-599.

[5]	Graybeal B, Brühwiler E, Kim B S, et al. International Perspective on UHPC in Bridge Engineering[J]. Journal of Bridge Engineering, 2020, 25(11): 04 020 094

[6]	Shi J, Shi C, Ou Y, et al. Compressive Elastic Modulus of UltraY High Performance Concrete: A Review[J]. Material Reports, 2021, 35(3): 3 067-3 075.

[7]	Amin M, Tayeh BA, Agwa IS. Effect of Using Mineral Admixtures and Ceramic Wastes as Coarse Aggregates on Properties of Ultra-High-Performance Concrete[J]. Journal of Cleaner Production, 2020, 273: 123 073.

[8]	Soliman NA, Tagnit-Hamou A. Development of Ultra-High-Performance Concrete using Glass Powder - Towards Ecofriendly Concrete[J]. Construction and Building Materials., 2016, 125: 600-612.

[9]	Yazıcı H, Yardımcı MY, Aydın S, et al. Mechanical Properties of Reactive Powder Concrete Containing Mineral Admixtures under Different Curing Regimes[J]. Construction and Building Materials, 2009, 23(3): 1 223-1 231.

[10]	Li PP, Yu QL, Brouwers HJH. Effect of Coarse Basalt Aggregates on the Properties of Ultra-high Performance Concrete (UHPC)[J]. Construction and Building Materials, 2018, 170: 649-659.

[11]	Kim H, Hadl P, Nguyen V T. A New Mix Design Method for UHPC Based on Stepwise Optimization of Particle Packing Density[C]. International Interactive Symposium on Ultra-High Performance Concrete, Iowa State University Digital Press, 2016

[12]	Huang Z, Li S. Study on Mechanical Properties of Ultra High Performance Concrete with Coarse Aggregate[J]. Journal of Hunan University Natural Sciences, 2018, 45(3): 47-54.

[13]	Zhang L, Liu J, Liu J, et al. Effect of Steel Fiber on Flexural Toughness and Fracture Mechanics Behavior of Ultrahigh-Performance Concrete with Coarse Aggregate[J]. Journal of Materials in Civil Engineering, 2018, 30(12): 04 018 323

[14]	Piasta W, Góra J, Budzyński W. Stress-strain Relationships and Modulus of Elasticity of Rocks and of Ordinary and High Performance Concretes[J]. Construction and Building Materials, 2017, 153: 728-739.

[15]	Huang Weirong YY, Yanjie L, Tong C. Mechanical Properties of Ultra-high Performance Concrete Containing Coarse Aggregate[J]. Journal of the Chinese Ceramic Society, 2020, 48(11): 1 7847-1 755.

[16]	Collepardi S, Luigi C, Troli R. Mechanical Properties of Modified Reactive Powder Concrete[J]. ACI Spec. Pub., 1997, 173: 1-22.

[17]	Ma J, Orgass M, Dehn F, et al. Comparative Investigations on Ultra-high Performance Concrete with and Without Coarse Aggregates[C]. International Symposium on Ultra High Performance Concrete, Kassel, Germany, 2004

[18]	Li H, Li Y, Jin C, et al. Meso-scale Modelling of the Effect of Coarse Aggregate Properties on the Creep of Concrete[J]. Journal of Building Engineering, 2022, 54: 104 660.

[19]	State Bureau of Quality Technical Supervision. Standard for Test Methods of Concrete Physical and Mechanical Properties[S]. GB/T17671-1999, 2019

[20]	General Administration of Quality Supervision. Reactive Powder Concrete[S]. GB/T 31387-2015, 2015

[21]	ASTM Intemational. Standard Test Method for Flexural Performance of Fiber-Reinforced Concrete (Using Beam with Third-Point Loading) [S]. ASTM-C1609, 2012

[22]	China Association for Engineering Construction Standardization. Technical Specification for Detecting Strength of Concrete by Ultrasonic-Rebound Combined Method[S]. CECS 02:2005, 2005

[23]	Sorelli L, Constantinides G, Ulm F-J, et al. The Nano-mechanical Signature of Ultra High Performance Concrete by Statistical Nanoindentation Techniques[J]. Cement and Concrete Research, 2008, 38(12): 1 447-1 456.

[24]	Sherwood E, Bentz E, Collins MP. Effect of Aggregate Size on Beam-Shear Strength of Thick Slabs[J]. ACI Structural Journal, 2007, 104: 180-190.

[25]	Liu J, Han F, Cui G, et al. Combined Effect of Coarse Aggregate and Fiber on Tensile Behavior of Ultra-High Performance Concrete[J]. Construction and Building Materials, 2016, 121: 310-318.

[26]	Hasannejad M, Berenjian J, Pouraminian M, et al. Studying of Microstructure, Interface Transition Zone and Ultrasonic Wave Velocity of High Strength Concrete by Different Aggregates[J]. Journal of Building Pathology and Rehabilitation, 2021, 7(1): 9

[27]	Wang S, Zhu H, Liu F, et al. Effects of Steel Fibers and Concrete Strength on Flexural Toughness of Ultra-High Performance Concrete with Coarse Aggregate[J]. Case Studies in Construction Materials, 2022, 17: e01 170.

[28]	Sahmaran M, Yaman IO. Hybrid Fiber Reinforced Self-Compacting Concrete with a High-Volume Coarse Fly Ash[J]. Construction and Building Materials, 2007, 21(1): 150-156.

[29]	Barnett SJ, Lataste J-F, Parry T, et al. Assessment of Fibre Orientation in Ultra High Performance Fibre Reinforced Concrete and Its Effect on Flexural Strength[J]. Materials and Structures, 2009, 43(7): 1 009-1 023.

[30]	Leutbecher T, Rebling J. Predicting the Postcracking Strength of Ultra-High Performance Fiber Reinforced Concrete by Means of Three-Point Bending Tests According to EN 14651[J]. Structural Concrete, 2019, 20(6): 2 081-2 095.

[31]	Naaman AE, Reinhardt HW. Proposed Classification of HPFRC Composites Based on their Tensile Response[J]. Materials and Structures, 2006, 39(5): 547-555.

[32]	Ganesh B, Ramesh MN, K M V S. Correlation of Dynamic and Static Modulus of Elasticity of UHPC[J]. Indian Concrete Journal, 2020, 94: 56-65.

[33]	Şahin F, Uysal M, Canpolat O, et al. Effect of Basalt Fiber on Metakaolin-based Geopolymer Mortars Containing Rilem, Basalt and Recycled Waste Concrete Aggregates[J]. Construction and Building Materials., 2021, 301: 124 113.

[34]	Salman G. Density and Ultrasonic Pulse Velocity Investigation of Self-compacting Carbon Fiber-Reinforced Concrete[J]. Engineering and Technology Journal, 2018, 36(1): 89-99.

[35]	Mohammed TU, Rahman MN. Effect of Types of Aggregate and Sand-to-Aggregate Volume Ratio on UPV in Voncrete[J]. Construction and Building Materials, 2016, 125: 832-841.

[36]	Mohammed TU, Mahmood AH. Effects of Maximum Aggregate Size on UPV of Brick Aggregate Concrete[J]. Ultrasonics, 2016, 69: 129-136.

[37]	Nematzadeh M, Poorhosein R. Estimating Properties of Reactive Powder Concrete Containing Hybrid Fibers using UPV[J]. Comput. Concrete, 2017, 20(4): 491-502.

[38]	Chu H, Gao L, Qin J, et al. Mechanical Properties and Microstructure of Ultra-High-Performance Concrete with High Elastic Modulus[J]. Construction and Building Materials, 2022, 335: 127 385.

[39]	Dehghanpour H, Subasi S, Guntepe S, et al. Investigation of Fracture Mechanics, Physical and Dynamic Properties of UHPCs Containing PVA, Glass and Steel Fibers[J]. Construction and Building Materials, 2022, 328: 127 079.

[40]	Li S, Jensen OM, Wang Z, et al. Influence of Micromechanical Property on the Rate-dependent Flexural Strength of Ultra-high Performance Concrete Containing Coarse Aggregates (UHPC-CA)[J]. Composites Part B: Engineering, 2021, 227: 109 394.

[41]	Yang J, Ding Q, Zhang G, et al. Effect of Sulfate Attack on the Composition and Micro-mechanical Properties of C-A-S-H Gel in Cement-Slag Paste: A Combined Study of Nanoindentation and SEM-EDS[J]. Construction and Building Materials, 2022, 345: 128 275.

[42]	Liu Y, Wei Y. Abrasion Resistance of Ultra-high Performance Concrete with Coarse Aggregate[J]. Materials and Structures, 2021, 54: 1-18.

[43]	Zhang F, Poh LH, Zhang M-H. Effect of Bauxite Aggregate in Cement Composites on Mechanical Properties and Resistance Against High-velocity Projectile Impact[J]. Cement and Concrete Composites, 2021, 118: 103 915.