Sage Journals: Discover world-class research

Abstract

In this work lightweight and fire-resistant sandwich structures were fabricated and their mechanical, thermal, and fire behavior were investigated. The non-woven mat consisting of jute and polyester fibers at a ratio of 60:40 was used to manufacture Hybrid fiber reinforced Sodium silicate Composites (HSC) to be used as the core of the sandwich structure. The concentration of sodium silicate solution was varied (i.e., 80%, 90%, and 100%) to manufacture HSCs. The woven Jute fiber mat reinforced Epoxy Composites (JEC) were prepared using hand layup followed by light compression method to be used as the skins of the sandwich structures. The tensile and flexural test results revealed that HSC with 100% sodium silicate concentration showed increased strength and modulus. The thermal conductivity was not significantly affected by the sodium silicate solution concentration to prepare HSC and the thermal conductivity of the sandwiches are significantly lower than many existing jute-fiber based composites. However, the fire spread, and damage propagation during fire exposure test were significantly affected by the sodium silicate solution concentration. Sandwich with 100% sodium silicate solution concentration is found to have minimum damage due to fire exposure for 30 minutes. These findings provide a comprehensive understanding of the fabrication processes and design of the sandwich structures using HSC and JEC for applications where high strength, insulation, and fire resistance are required together.

Keywords

Non-woven hybrid fiber mat sodium silicate solution mechanical properties thermal exposure fire exposure

Get full access to this article

View all access options for this article.

References

Bhong

Khan

Devade

, et al. Review of composite materials and applications. Mater Today Proc 2023. doi:10.1016/j.matpr.2023.10.026.

Vijay

Rajkumara

Bhattacharjee

. Assessment of composite waste disposal in aerospace industries. Procedia Environ Sci 2016; 35: 563–570.

Chandramohan

Sathish

Dinesh Kumar

, et al. Mechanical and thermal properties of jute/aloevera hybrid natural fiber reinforced composites. In: AIP Conference Proceedings. New York: AIP Publishing, 2020.

Naik

Kumar

Kaup

. A review on natural fiber composite material in automotive applications. Eng Sci 2021; 18: 1–10.

Khatri

Dua

Naveen

, et al. Potential of natural fiber based polymeric composites for cleaner automotive component production-a comprehensive review. Journal of Materials Research and Technology 2023; 25: 1086–1104.

Shakir

Singh

. Mechanical properties, surface treatments, and applications of jute fiber reinforced composites—a review. Polym Adv Technol 2024; 35(1): e6268.

Etale

Onyianta

Turner

, et al. Cellulose: a review of water interactions, applications in composites, and water treatment. Chem Rev 2023; 123(5): 2016–2048.

Verma

Jain

Mishra

. Applications and drawbacks of epoxy/natural fiber composites. In: Handbook of epoxy/fiber composites. Berlin: Springer, 2022, pp. 1–15.

Kumar

. Jute fibers, their composites and applications. In: Plant fibers, their composites, and applications. Amsterdam: Elsevier, 2022, pp. 253–282.

10.

Kabir

Islam

Wang

. Mechanical and thermal properties of jute fibre reinforced composites. Journal of Multifunctional Composites 2013; 1(1): 71–76.

11.

Bisaria

Gupta

Shandilya

, et al. Effect of fibre length on mechanical properties of randomly oriented short jute fibre reinforced epoxy composite. Mater Today Proc 2015; 2(4-5): 1193–1199.

12.

Wang

Zhou

, et al. Effect of fiber surface modification on the interfacial adhesion and thermo-mechanical performance of unidirectional epoxy-based composites reinforced with bamboo fibers. Molecules 2019; 24(15): 2682.

13.

Rajole

Ravishankar

Kulkarni

. Performance study of jute-epoxy composites/sandwiches under normal ballistic impact. Def Technol 2020; 16(4): 947–955.

14.

Elbadry

Aly-Hassan

Hamada

. Mechanical properties of natural jute fabric/jute mat fiber reinforced polymer matrix hybrid composites. Adv Mech Eng 2012; 4: 354547.

15.

Fajrin

Zhuge

Bullen

, et al. Flexural behaviour of hybrid sandwich panel with natural fiber composites as the intermediate layer. J Mech Eng Sci 2016; 10(2): 1968–1983.

16.

Manfredi

Rodríguez

Wladyka-Przybylak

, et al. Thermal properties and fire resistance of jute-reinforced composites. Compos Interfaces 2010; 17(5-7): 663–675.

17.

Singh

. Thermal properties of jute fiber reinforced chemically functionalized high density polyethylene (JF/CFHDPE) composites developed by palsule process. Polym Compos 2014; 2(2): 97–108.

18.

Boopalan

Niranjanaa

Umapathy

. Study on the mechanical properties and thermal properties of jute and banana fiber reinforced epoxy hybrid composites. Compos B Eng 2013; 51: 54–57.

19.

Majumder

Stochino

Frattolillo

, et al. Jute fiber-reinforced mortars: mechanical response and thermal performance. J Build Eng 2023; 66: 105888.

20.

Zakriya

Ramakrishnan

Palani Rajan

, et al. Study of thermal properties of jute and hollow conjugated polyester fibre reinforced non-woven composite. J Ind Textil 2017; 46(6): 1393–1411.

21.

Duran

. A research on thermal insulation properties of nonwovens produced with recycled jute and wool fibres. Textile and Apparel 2016; 26(1): 22–30.

22.

Bhuiyan

MAR

Ali

Akter

, et al. Flame resistance and heat barrier performance of sustainable plain-woven jute composite panels for thermal insulation in buildings. Appl Energy 2023; 345: 121317.

23.

Balan

Balasundaram

Chellamuthu

, et al. Flame resistance characteristics of woven jute fiber reinforced fly ash filled polymer composite. J Nanomater 2022; 2022(1): 9704980.

24.

S-Q

Tang

R-C

C-B

. Flame retardant treatment of jute fabric with chitosan and sodium alginate. Polym Degrad Stabil 2022; 196: 109826.

25.

Sankar

Stynoski

Al‐Chaar

, et al. Sodium silicate activated slag‐fly ash binders: Part I–Processing, microstructure, and mechanical properties. J Am Ceram Soc 2018; 101(6): 2228–2244.

26.

Chen

S-N

Hsieh

, et al. Enhancements on flame resistance by inorganic silicate-based intumescent coating materials. Materials 2021; 14(21): 6628.

27.

Saba

Jawaid

. Epoxy resin based hybrid polymer composites. Hybrid polymer composite materials 2017; 2017: 57–82.

28.

Al Mahmud

Chowdhury

Rayhan

, et al. Epoxy resin composites reinforced with upcycled fabrics: mechanical, thermal, and morphological analysis. SPE Polymers 2024; 5(4): 624–636.

29.

Ahammad

Arifuzzaman

Islam

. Effect of micro-perlite powder content on thermo-mechanical properties of epoxy resin. Polym Compos 2025; 34: 09540083221092147.

30.

Marx

Rabiei

. Tensile properties of composite metal foam and composite metal foam core sandwich panels. J Sandw Struct Mater 2021; 23(8): 3773–3793.

31.

Bhuiyan

MAR

Darda

Ali

, et al. Heat insulating jute-reinforced recycled polyethylene and polypropylene bio-composites for energy conservation in buildings. Mater Today Commun 2023; 37: 106948.

32.

Jawaid

Saba

Alothman

, et al. Thermal conductivity behavior of oil palm/jute fibre-reinforced hybrid composites. In: AIP conference proceedings. New York: AIP Publishing, 2017.

33.

Pujari

Ramakrishna

Balaram Padal

. Investigations on thermal conductivities of jute and banana fiber reinforced epoxy composites. J Inst Eng India Ser D 2017; 98: 79–83.

The role of sodium silicate treated randomly distributed jute fiber core on the mechanical,thermal and fire behavior of novel sandwich structures

Abstract

Keywords

Get full access to this article

References