Evaluating the Static and Dynamic Impact Properties of LDPE Film: Insights into Mechanical Energy Consumption

1. Barbosa MF, Souza AMCD. Reusing Surlyn® Ionomer Scraps in LDPE Blends: Mechanical and Thermal Properties. Mater Res. 2023; 26 (suppl1): e20230019. DOI:10.1590/1980-5373-mr-2023-0019 Barbosa MF Souza AMCD. Reusing Surlyn® Ionomer Scraps in LDPE Blends: Mechanical and Thermal Properties . Mater Res . 2023 ; 26 (suppl1): e20230019 . DOI:10.1590/1980-5373-mr-2023-0019 Open DOISearch in Google Scholar

2. Kismet Y, Dogan A, Wagner MH. Thermoset powder coating wastes as filler in LDPE – Characterization of mechanical, thermal and morphological properties. Polym Test. 2021 Jan;93:106897. Kismet Y Dogan A Wagner MH. Thermoset powder coating wastes as filler in LDPE – Characterization of mechanical, thermal and morphological properties . Polym Test . 2021 Jan ; 93 : 106897 . Search in Google Scholar

3. Sirin K, Cengel Ö, Canli M. Thermal and mechanical properties of LDPE by the effects of organic peroxides: Mechanical Properties of LDPE. Polym Adv Technol. 2017 Jul;28(7):876–85. Sirin K Cengel Ö Canli M. Thermal and mechanical properties of LDPE by the effects of organic peroxides: Mechanical Properties of LDPE . Polym Adv Technol . 2017 Jul ; 28 ( 7 ): 876 – 85 . Search in Google Scholar

4. Peršić A, Popov N, Kratofil Krehula L, Krehula S. The Influence of Different Hematite (α-Fe2O3) Particles on the Thermal, Optical, Mechanical, and Barrier Properties of LDPE/Hematite Composites. Materials. 2023 Jan 11;16(2):706 Peršić A Popov N Kratofil Krehula L Krehula S. The Influence of Different Hematite (α-Fe2O3) Particles on the Thermal, Optical, Mechanical, and Barrier Properties of LDPE/Hematite Composites . Materials . 2023 Jan 11 ; 16 ( 2 ): 706 Search in Google Scholar

5. Dwivedi UK, Hashmi SAR, Naik A, Joshi R, Chand N. Development and physico‐mechanical behavior of LDPE–sisal prepreg‐based composites. Polym Compos. 2013 May;34(5):650–5. Dwivedi UK Hashmi SAR Naik A Joshi R Chand N. Development and physico‐mechanical behavior of LDPE–sisal prepreg‐based composites . Polym Compos . 2013 May ; 34 ( 5 ): 650 – 5 . Search in Google Scholar

6. Čech Barabaszová K, Holešová S, Hundáková M, Kalendová A. Tribo-Mechanical Properties of the Antimicrobial Low-Density Polyethylene (LDPE) Nanocomposite with Hybrid ZnO–Vermiculite–Chlorhexidine Nanofillers. Polymers. 2020 Nov 27;12(12):2811. Čech Barabaszová K Holešová S Hundáková M Kalendová A. Tribo-Mechanical Properties of the Antimicrobial Low-Density Polyethylene (LDPE) Nanocomposite with Hybrid ZnO–Vermiculite–Chlorhexidine Nanofillers . Polymers . 2020 Nov 27 ; 12 ( 12 ): 2811 . Search in Google Scholar

7. Janik J. Właściwości mieszanin polimerów termoplastycznych PBT/LDPE. Przetw Tworzyw. 2015;21(6 (168):451–5. Janik J. Właściwości mieszanin polimerów termoplastycznych PBT/LDPE . Przetw Tworzyw . 2015 ; 21 ( 6 (168 ): 451 – 5 . Search in Google Scholar

8. Czarnecka-Komorowska D, Wiszumirska K, Garbacz T. FILMS LDPE/LLDPE MADE FROM POST - CONSUMER PLASTICS: PROCESSING, STRUCTURE, MECHANICAL PROPERTIES. Adv Sci Technol Res J. 2018 Sep 1;12(3):134–42. Czarnecka-Komorowska D Wiszumirska K Garbacz T. FILMS LDPE/LLDPE MADE FROM POST - CONSUMER PLASTICS: PROCESSING, STRUCTURE, MECHANICAL PROPERTIES . Adv Sci Technol Res J . 2018 Sep 1 ; 12 ( 3 ): 134 – 42 . Search in Google Scholar

9. Ono K, Yamaguchi M. Thermal and mechanical modification of LDPE in single‐screw extruder. J Appl Polym Sci. 2009 Aug 5;113(3): 1462–70. Ono K Yamaguchi M. Thermal and mechanical modification of LDPE in single‐screw extruder . J Appl Polym Sci . 2009 Aug 5 ; 113 ( 3 ): 1462 – 70 . Search in Google Scholar

10. Sailaja RRN, Seetharamu S. Mechanical and thermal properties of LDPE‐cellulose acetate phthalate blends—Effect of maleic anhydride‐ grafted LDPE compatibilizer. J Appl Polym Sci. 2009 Apr 15;112(2):649–59. Sailaja RRN Seetharamu S. Mechanical and thermal properties of LDPE‐cellulose acetate phthalate blends—Effect of maleic anhydride‐ grafted LDPE compatibilizer . J Appl Polym Sci . 2009 Apr 15 ; 112 ( 2 ): 649 – 59 . Search in Google Scholar

11. Yao Z, Heng JYY, Lanceros-Méndez S, Pegoretti A, Xia M, Tang J, et al. Surface free energy and mechanical performance of LDPE/CBF composites containing toxic-metal free filler. Int J Adhes Adhes. 2017 Sep;77:58–62. Yao Z Heng JYY Lanceros-Méndez S Pegoretti A Xia M Tang J Surface free energy and mechanical performance of LDPE/CBF composites containing toxic-metal free filler . Int J Adhes Adhes . 2017 Sep ; 77 : 58 – 62 . Search in Google Scholar

12. Koffi A, Koffi D, Toubal L. Mechanical properties and drop-weight impact performance of injection-molded HDPE/birch fiber composites. Polym Test. 2021 Jan;93:106956. Koffi A Koffi D Toubal L. Mechanical properties and drop-weight impact performance of injection-molded HDPE/birch fiber composites . Polym Test . 2021 Jan ; 93 : 106956 . Search in Google Scholar

13. Karthikeyan K, Russell BP, Fleck NA, O’Masta M, Wadley HNG, Deshpande VS. The soft impact response of composite laminate beams. Int J Impact Eng. 2013 Oct;60:24–36. Karthikeyan K Russell BP Fleck NA O’Masta M Wadley HNG Deshpande VS. The soft impact response of composite laminate beams . Int J Impact Eng . 2013 Oct ; 60 : 24 – 36 . Search in Google Scholar

14. Rana AK, Mandal A, Banerjee AN. Jute sliver-LDPE composites: Effect of aqueous consolidation on mechanical and dynamic properties. J Appl Polym Sci. 2000 May 2;76(5):684–9. Rana AK Mandal A Banerjee AN. Jute sliver-LDPE composites: Effect of aqueous consolidation on mechanical and dynamic properties . J Appl Polym Sci . 2000 May 2 ; 76 ( 5 ): 684 – 9 . Search in Google Scholar

15. Yazdani H, Ghasemi H, Wallace C, Hatami K. Mechanical properties of carbon nanotube‐filled polyethylene composites: A molecular dynamics simulation study. Polym Compos [Internet]. 2019 Mar [cited 2024 Oct 24];40(S2). Available from: https://4spepublications.onlineli-brary.wiley.com/doi/10.1002/pc.25175 Yazdani H Ghasemi H Wallace C Hatami K. Mechanical properties of carbon nanotube‐filled polyethylene composites: A molecular dynamics simulation study . Polym Compos [Internet] . 2019 Mar [cited 2024 Oct 24]; 40 ( S2 ). Available from: https://4spepublications.onlineli-brary.wiley.com/doi/10.1002/pc.25175 Search in Google Scholar

16. Sahraeian R, Esfandeh M, Hashemi SA. Rheological, Thermal and Dynamic Mechanical Studies of the Ldpe/Perlite Nanocomposites. Polym Polym Compos. 2013 May;21(4):243–50. Sahraeian R Esfandeh M Hashemi SA. Rheological, Thermal and Dynamic Mechanical Studies of the Ldpe/Perlite Nanocomposites . Polym Polym Compos . 2013 May ; 21 ( 4 ): 243 – 50 . Search in Google Scholar

17. Xu M ming, Huang G yan, Feng S shan, McShane G, Stronge W. Static and Dynamic Properties of Semi-Crystalline Polyethylene. Polymers. 2016 Mar 28;8(4):77. Xu M ming Huang G yan Feng S shan McShane G Stronge W. Static and Dynamic Properties of Semi-Crystalline Polyethylene . Polymers . 2016 Mar 28 ; 8 ( 4 ): 77 . Search in Google Scholar

18. Zhu T, Li X, Zhao X, Zhang X, Lu Y, Zhang L. Stress-strain behavior and corresponding crystalline structures of four types of polyethylene under a wide range of strain rates. Polym Test. 2022 Feb;106:107460. Zhu T Li X Zhao X Zhang X Lu Y Zhang L. Stress-strain behavior and corresponding crystalline structures of four types of polyethylene under a wide range of strain rates . Polym Test . 2022 Feb ; 106 : 107460 . Search in Google Scholar

19. Mohagheghian I, McShane GJ, Stronge WJ. Impact perforation of monolithic polyethylene plates: Projectile nose shape dependence. Int J Impact Eng. 2015 Jun;80:162–76. Mohagheghian I McShane GJ Stronge WJ. Impact perforation of monolithic polyethylene plates: Projectile nose shape dependence . Int J Impact Eng . 2015 Jun ; 80 : 162 – 76 . Search in Google Scholar

20. Sandeep J, Murali V. Low Density Polyethylene/Polymeric Microballon Syntactic Foam: Strain Rate Dependent Compressive Response. J Polym Mater. 2017;34(2). Sandeep J Murali V. Low Density Polyethylene/Polymeric Microballon Syntactic Foam: Strain Rate Dependent Compressive Response . J Polym Mater . 2017 ; 34 ( 2 ). Search in Google Scholar

21. Obst M, Kurpisz D, Jakubowski M. Experimental and Analytical Approaches on Air Spring Absorbers Made of LDPE Polymer. Acta Mech Autom. 2024 Jun 1;18(2):314–22. Obst M Kurpisz D Jakubowski M. Experimental and Analytical Approaches on Air Spring Absorbers Made of LDPE Polymer . Acta Mech Autom . 2024 Jun 1 ; 18 ( 2 ): 314 – 22 . Search in Google Scholar

22. Drane P, De Jesus-Vega M, Inalpolat M, Sherwood J, Orbey N. Inductive quantification of energy absorption of high-density polyethylene foam for repeated blunt impact. Proc Inst Mech Eng Part J Mater Des Appl. 2020 Mar;234(3):531–45. Drane P De Jesus-Vega M Inalpolat M Sherwood J Orbey N. Inductive quantification of energy absorption of high-density polyethylene foam for repeated blunt impact . Proc Inst Mech Eng Part J Mater Des Appl . 2020 Mar ; 234 ( 3 ): 531 – 45 . Search in Google Scholar

23. Sahu DP, Mohanty SC. Static and dynamic analysis of polyethylene terephthalate foam core and different natural fiber-reinforced laminated composite-based sandwich plates through experimental and numerical simulation. Mechanics of Advanced Materials and Structures. 2024 Aug 8;1–20. Sahu DP Mohanty SC. Static and dynamic analysis of polyethylene terephthalate foam core and different natural fiber-reinforced laminated composite-based sandwich plates through experimental and numerical simulation . Mechanics of Advanced Materials and Structures . 2024 Aug 8 ; 1 – 20 . Search in Google Scholar

24. Sahu DP, Das R, Prusty JK, Mohanty SC. Frequency analysis of skew sandwich plates with polyethylene terephthalate foam-core and car-bon/basalt fiber-reinforced hybrid face layers using ANFIS model and experimental validation. Mechanics of Advanced Materials and Structures. 2024 Dec 11;1–23. Sahu DP Das R Prusty JK Mohanty SC. Frequency analysis of skew sandwich plates with polyethylene terephthalate foam-core and car-bon/basalt fiber-reinforced hybrid face layers using ANFIS model and experimental validation . Mechanics of Advanced Materials and Structures . 2024 Dec 11 ; 1 – 23 . Search in Google Scholar

25. Sahu DP, Das R, Prusty JK, Mohanty SC. Flexural and dynamic characterization of carbon/basalt hybrid laminated composite sandwich plates with PET foam core: A numerical and experimental approach. Structures. 2025 Feb;72:108204. Sahu DP Das R Prusty JK Mohanty SC. Flexural and dynamic characterization of carbon/basalt hybrid laminated composite sandwich plates with PET foam core: A numerical and experimental approach . Structures . 2025 Feb ; 72 : 108204 . Search in Google Scholar

26. Antony Vincent V, Kailasanathan C, Ramesh G, Maridurai T, Arun Prakash VR. Fabrication and Characterization of Hybrid Natural Fibre-Reinforced Sandwich Composite Radar Wave Absorbing Structure for Stealth Radomes. Trans Electr Electron Mater. 2021 Dec;22(6):794– 802. Antony Vincent V Kailasanathan C Ramesh G Maridurai T Arun Prakash VR. Fabrication and Characterization of Hybrid Natural Fibre-Reinforced Sandwich Composite Radar Wave Absorbing Structure for Stealth Radomes . Trans Electr Electron Mater . 2021 Dec ; 22 ( 6 ): 794 – 802 . Search in Google Scholar

27. Das R, Sahu DP, Bisoyi DK. Silane‐treated kapok fiber/epoxy composites for aerospace cabin interiors: Synthesis and characterization. Polymer Composites. 2024 Dec 6;pc.29359. Das R Sahu DP Bisoyi DK. Silane‐treated kapok fiber/epoxy composites for aerospace cabin interiors: Synthesis and characterization . Polymer Composites . 2024 Dec 6 ;pc. 29359 . Search in Google Scholar

28. Sahu DP, Das R, Mohanty SC. Multiwalled carbon nanotubes filled pineapple/kenaf hybrid laminated composites structures for electromagnetic interface shielding applications. Polymer Composites. 2024 Dec 26;pc.29428. Sahu DP Das R Mohanty SC. Multiwalled carbon nanotubes filled pineapple/kenaf hybrid laminated composites structures for electromagnetic interface shielding applications . Polymer Composites . 2024 Dec 26 ;pc. 29428 . Search in Google Scholar