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The use of high-performance concretes, ultra highperformance concretes, and additive manufacturing technology in increasing the ballistic protection level of field fortifications

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Języki publikacji
EN
Abstrakty
EN
High-Performance Concretes (HPC) and Ultra High-Performance Concretes (UHPC) allow for the production of extremely durable construction elements when compared to those same elements made of C35/45 concrete. Increased compressive- and flexural strength markedly contribute to ballistic resistance reducing the area and depth of the “crater” which results from a potential impact of a projectile or a fragment. Additionally, the presence of dispersed fibres in these mixtures eliminates the need of using reinforcement bars, which, in turn, reduces the time expenditure and labour. The article compares the results of various ballistic tests of elements made of high-performance concrete mixtures to determine the viability of applying such elements in the defence sector. Furthermore, the authors present the possibility of adapting additive technologies for the performance of field fortification tasks by the military, as part of which the HPCs and UHPCs are used as working mixtures. The authors also show the possibility of fabricating construction elements without the use of formworks, as well as printing construction elements directly at the site of future operation of the buildings.
Czasopismo
Rocznik
Tom
Opis fizyczny
Bibliogr. 40 poz., rys.
Twórcy
  • Wojskowy Instytut Techniki Inżynieryjnej, Wrocław, Polska
  • Wojskowy Instytut Techniki Inżynieryjnej, Wrocław, Polska
  • Politechnika Wrocławska, Wrocław, Polska
Bibliografia
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  • Anton, A., Reiter, L., Wangler, T., Frangež, V., Flatt, R.J., & Dillenburger, B. (2021). A 3D concrete printing prefabrication platform for bespoke columns. Automation in Construction, 122, 103467.
  • Bhattacherjee, S., Basavaraj, A.S., Rahul, A.V., Santhanam, M., Gettu, R., Panda, B.N., Schlangen, E., Chen, Y., Çopuroğlu, O., Ma, G., Wang, L., Beigh, M.A., & Mechtcherine, V. (2021). Sustainable materials for 3D concrete printing. Cement & Concrete Composites, 122, 104156.
  • Bos, FP Freek, et al. “Additive Manufacturing of Concrete in Construction: Potentials and Challenges of 3D Concrete Printing.” Virtual and Physical Prototyping, vol. 11, no. 3, 2016, pp. 209–225.
  • Buswell R, Soar RC, Gibb A, Thorpe T (2007) Freeform construction: mega-scale rapid manufacturing for construction. Autom Constr 16:224–231
  • Buswell, Richard A., et al. “3D Printing Using Concrete Extrusion: A Roadmap for Research.” Cement and Concrete Research, vol. 112, 2018, pp. 37–49.
  • Dancygier, A.N. (2017). High-performance concrete engineered for protective barriers. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 375.
  • Dapper, P.R., Ehrendring, H.Z., Pacheco, F., Christ, R., Menegussi, G.C., Oliveira, M.F., & Tutikian, B.F. (2021). Ballistic Impact Resistance of UHPC Plates Made with Hybrid Fibers and Low Binder Content. Sustainability.
  • Dapper, P.R., Ehrendring, H.Z., Pacheco, F., Christ, R., Menegussi, G.C., Oliveira, M.F., & Tutikian, B.F. (2021). Ballistic Impact Resistance of UHPC Plates Made with Hybrid Fibers and Low Binder Content. Sustainability.
  • Drdlová, M., & Šperl, M. (2021). The comparison of projectile impact resistance of ultra-high-performance fibre-reinforced concrete with various aggregates. EPJ Web of Conferences.
  • Du, J., Meng, W., Khayat, K.H., Bao, Y., Guo, P., Lyu, Z., Abu-obeidah, A., Nassif, H., & Wang, H. (2021). New development of ultra-high-performance concrete (UHPC). Composites Part B: Engineering.
  • Fornůsek, J., Mára, M., & Lovichová, R. (2018). The Influence of Different Fibres Ratio in the Cementitious Composite on Ballistic Resistance. Key Engineering Materials, 760, 114 - 118.
  • Freek Bos, Rob Wolfs, Zeeshan Ahmed & Theo Salet (2016) Additive manufacturing of concrete in construction: potentials and challenges of 3D concrete printing, Virtual and Physical Prototyping, 11:3, 209-225, DOI: 10.1080/17452759.2016.1209867
  • Granger, S., Loukili, A., Pijaudier-Cabot, G., & Chanvillard, G. (2007). Experimental characterization of the self-healing of cracks in an ultra high performance cementitious material: Mechanical tests and acoustic emission analysis. Cement and Concrete Research, 37, 519-527.
  • Hongya, X. (2014). Ballistic Resistance of Metal Corrugated Sandwich Plates Filled with High Performance Concrete. Journal of the Chinese Ceramic Society.
  • Jin, X., Jin, T., Su, B., Wang, Z., Ning, J., & Shu, X. (2017). Ballistic resistance and energy absorption of honeycomb structures filled with reactive powder concrete prisms. Journal of Sandwich Structures & Materials, 19, 544 - 571.
  • Klyuev, S., Khezhev, T., Pukharenko, Y., & Klyuev, A. (2019). Fiber Concrete for Industrial and Civil Construction. Materials Science Forum, 945, 120 - 124.
  • Krauthammer, T. (2014). Foreword: Challenges for advancing the performance of military concrete. Magazine of Concrete Research, 66, 3-5.
  • Kristoffersen, M.M., Toreskås, O.L., Dey, S., & Børvik, T. (2021). Ballistic impact on concrete slabs: An experimental and numerical study. EPJ Web of Conferences.
  • Kristoffersen, M.M., Toreskås, O.L., Dey, S., & Børvik, T. (2021). Ballistic perforation resistance of thin concrete slabs impacted by ogive-nose steel projectiles. International Journal of Impact Engineering, 156, 103957.
  • Li, J., Wu, Z., Shi, C., Yuan, Q., & Zhang, Z. (2020). Durability of ultra-high performance concrete – A review. Construction and Building Materials, 255, 119296.
  • Lowke, D., Stengel, T., Schießl, P., & Gehlen, C. (2012). Control of Rheology, Strength and Fibre Bond of UHPC with Additions - Effect of Packing Density and Addition Type.
  • Mára, M., Kheml, P., Carrera, K., Fornůsek, J., & Sovják, R. (2021). Effect of Corundum and Basalt Aggregates on the Ballistic Resistance of UHP-SFRC. Crystals.
  • Mára, M., Sovják, R., & Fornůsek, J. (2020). USING TEXTILE ARAMID FABRICS TO INCREASE THE BALLISTIC RESISTANCE OF ULTRA-HIGH-PERFORMANCE STEEL-FIBRE REINFORCED CONCRETE. Acta Polytechnica.
  • Maras, M.M. (2021). Tensile and flexural strength cracking behavior of geopolymer composite reinforced with hybrid fibers. Arabian Journal of Geosciences, 14.
  • Othman, H.I., & Marzouk, H. (2018). Applicability of damage plasticity constitutive model for ultra-high performance fibre-reinforced concrete under impact loads. International Journal of Impact Engineering, 114, 20-31.
  • Oucif, C., Mauludin, L.M., & Abed, F.H. (2020). Ballistic behavior of plain and reinforced concrete slabs under high velocity impact. Frontiers of Structural and Civil Engineering, 14, 299-310.
  • Richard, P., & Cheyrezy, M. (1994). Reactive Powder Concretes With High Ductility and 200 - 800 Mpa Compressive Strength.
  • Richard, P., & Cheyrezy, M. (1995). Composition of reactive powder concretes. Cement and Concrete Research, 25, 1501-1511.
  • Shaikh, F. (2013). Review of mechanical properties of short fibre reinforced geopolymer composites. Construction and Building Materials, 43, 37-49.
  • Štoller, J., & Dvořák, P. (2016). Field Tests of Cementitious Composites Suitable for Protective Structures and Critical Infrastructure. Key Engineering Materials, 722, 11 - 3.
  • Suiker, A.S., Wolfs, R., Lucas, S., & Salet, T.A. (2020). Elastic buckling and plastic collapse during 3D concrete printing. Cement and Concrete Research, 135, 106016.
  • Sun, J., Huang, Y., Aslani, F., Wang, X., & Ma, G. (2021). Mechanical enhancement for EMW-absorbing cementitious material using 3D concrete printing. Journal of building engineering, 41, 102763.
  • Wang, C., Yang, C., Liu, F., Wan, C., & Pu, X.C. (2012). Preparation of Ultra-High Performance Concrete with common technology and materials. Cement & Concrete Composites, 34, 538-544.
  • Wang, D., Ju, Y.Z., Shen, H., & Xu, L. (2019). Mechanical properties of high performance concrete reinforced with basalt fiber and polypropylene fiber. Construction and Building Materials.
  • Wang, D., Ju, Y.Z., Shen, H.Z., & Xu, L. (2019). Mechanical properties of high performance concrete reinforced with basalt fiber and polypropylene fiber. Construction and Building Materials.
  • Weerheijm, J., Roebroeks, G., Krabbenborg, D., & Ozbek, A.S. (2015). THE POTENTIALS OF POROUS CONCRETE FOR BALLISTIC PROTECTION.
  • Wille, K., Naaman, A.E., & Parra-Montesinos, G.J. (2011). Ultra-High Performance Concrete with Compressive Strength Exceeding 150 MPa (22 ksi): A Simpler Way. Aci Materials Journal, 108, 46-54.
  • Yu, R., Spiesz, P.P., & Brouwers, H.J. (2014). Mix design and properties assessment of Ultra-High-Performance Fibre Reinforced Concrete (UHPFRC). Cement and Concrete Research, 56, 29-39.
  • STANAG 2280 - MC ENGR (Edition 1) (Ratification draft 1) – Design Threat Levels and Handover Procedures for Temporary Protective Structures. NATO Standardization Agency, June 2007.
  • Standard Practice for Fabricating and Testing Specimens of Ultra-High Performance Concrete ASTM C1856/C1856M-17
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ddcb0ddc-9919-44e7-b828-205f0ca7d303
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