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| Auteurs principaux: | , , , , |
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| Format: | Preprint |
| Publié: |
2025
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| Accès en ligne: | https://arxiv.org/abs/2501.04977 |
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| _version_ | 1866912181885337600 |
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| author | Thakur, Manas Nakka, Nishika Bommiditha, Jyothsnavi Surkanti, Sahasra Sai Padhee, Srikant Sekhar |
| author_facet | Thakur, Manas Nakka, Nishika Bommiditha, Jyothsnavi Surkanti, Sahasra Sai Padhee, Srikant Sekhar |
| contents | With the rising threat of ballistic impacts, it is critical to devise a solution that is both efficient and economical. Recently, Polymer Matrix Sand Composites (PMSCs) have emerged as a viable cost-effective option. This ongoing research focuses on providing stronger protection against diverse ballistic impacts. The study examines the enhancement of ballistic resistance in PMSCs through the graded incorporation of sand. Variable properties are achieved along the thickness by altering the sand particle size and weight fraction in the polymer matrix. The gradation creates a stepwise structure, starting with a dense base impact zone containing abrasive sand particles with a typical size range. This layer is brittle and hard, effectively eroding incoming projectiles. Subsequent layers are less dense, offering tensile strength that reflects stress waves and reduces impact energy while supporting the frontal brittle zone. The minimally dense or neat matrix regions prevent backlash and provide a cushioning effect. The addition of sand particles increases the composite's surface area, enhancing adhesion between inclusions and the matrix. This improved adhesion ensures efficient load transfer, increasing overall hardness. PMSCs were fabricated to analyze the effects of two matrix compositions, and refining manufacturing methods. These composites were subjected to tensile testing, Izod impact testing, Shore-D hardness testing, and other evaluations to assess their mechanical properties. The findings show that varying the sand content significantly impacts mechanical properties up to an optimal weight fraction for a given size range of inclusions. Experimental and simulation studies were employed to extract properties and evaluate material behavior under ballistic threats. The research underscores the potential of PMSCs as affordable and sustainable composites for advanced ballistic protection. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2501_04977 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Sand Inclusion Composite Structures for Enhanced Ballistic Impact Resistance Thakur, Manas Nakka, Nishika Bommiditha, Jyothsnavi Surkanti, Sahasra Sai Padhee, Srikant Sekhar Applied Physics With the rising threat of ballistic impacts, it is critical to devise a solution that is both efficient and economical. Recently, Polymer Matrix Sand Composites (PMSCs) have emerged as a viable cost-effective option. This ongoing research focuses on providing stronger protection against diverse ballistic impacts. The study examines the enhancement of ballistic resistance in PMSCs through the graded incorporation of sand. Variable properties are achieved along the thickness by altering the sand particle size and weight fraction in the polymer matrix. The gradation creates a stepwise structure, starting with a dense base impact zone containing abrasive sand particles with a typical size range. This layer is brittle and hard, effectively eroding incoming projectiles. Subsequent layers are less dense, offering tensile strength that reflects stress waves and reduces impact energy while supporting the frontal brittle zone. The minimally dense or neat matrix regions prevent backlash and provide a cushioning effect. The addition of sand particles increases the composite's surface area, enhancing adhesion between inclusions and the matrix. This improved adhesion ensures efficient load transfer, increasing overall hardness. PMSCs were fabricated to analyze the effects of two matrix compositions, and refining manufacturing methods. These composites were subjected to tensile testing, Izod impact testing, Shore-D hardness testing, and other evaluations to assess their mechanical properties. The findings show that varying the sand content significantly impacts mechanical properties up to an optimal weight fraction for a given size range of inclusions. Experimental and simulation studies were employed to extract properties and evaluate material behavior under ballistic threats. The research underscores the potential of PMSCs as affordable and sustainable composites for advanced ballistic protection. |
| title | Sand Inclusion Composite Structures for Enhanced Ballistic Impact Resistance |
| topic | Applied Physics |
| url | https://arxiv.org/abs/2501.04977 |