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Abstract

In the environment where glove material is exposed to harmful chemicals, hazards related to faster penetration of dangerous substances into the glove interior may cause microdamage. One of the solutions to overcome this problem is to use the self-healing polymeric materials that can minimize economic loss and accidents in the workplace.

The current work aims to present the impact of different types of textile reinforcement on the effectiveness and efficiency of the self-healing process of methyl vinyl silicone rubber containing hybrid molecules with an inorganic silsesquioxane intended for use on all-rubber gloves. Three knitted fabrics with a similar structure and differentiated raw material composition were selected: polyamide, cotton–polyamide, and cotton.

Evaluation of the self-healing process of the elastomeric composite to personal protective equipment was performed. For this purpose the assessment of the surface morphology of materials has been performed before and after the self-healing process.

The implementation of knitted fabric into the polymeric composite in the tested samples allowed us to obtain the best results in all tests. The studied composite samples exhibited an increased resistance to three types of damage: penetration, abrasion and puncture. The samples also underwent the self-healing processes and regeneration after a proper conditioning period. Thus, the obtained results confirmed the possibility of using tested elastomeric composites in the construction of protective gloves and showed an effectivity of the self-healing process for the long-term usage of that protective equipment.

Keywords

chemical modification chemistry coatings composites encapsulation fabrication materials processing surface modification

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References

Chemical Abstracts Service, A Division of the American Chemical Society. CAS REGISTRY(SM), https://www.cas.org/support/documentation/chemical-substances (2019, accessed 28 January 2020).

Wulfhorst

Bock

Skudlik

, et al.Prevention of hand eczema: gloves, barrier creams and workers’ education. In: Johansen

Frosch

Lepoittevin

(eds). Contact dermatitis, 5th ed. Berlin: Springer-Verlag, 2011, pp. 985–1016.

Ogden

. Managing dermal risk: moving on from gloves. Ann Occup Hyg 2010; 54: 131–133.

Packham

. Gloves as chemical protection—can they really work? Ann Occup Hyg 2006; 50: 545–548.

Boeniger

Klingner

. In-use testing and interpretation of chemical-resistant glove performance. Appl Occup Environ Hyg 2002; 17: 368–378.

Majchrzycka

Pościk

. Dobór środków ochrony indywidualnej (Selection of personal protective equipment), Warsaw: CIOP-PIB, 2007.

Åkerfeldt

Lund

Walkenström

. Textile sensing glove with piezoelectric PVDF fibers and printed electrodes of PEDOT:PSS. Text Res J 2015; 85: 1789–1799.

EN 374-1:2016. Chemical glove requirements..

Irzmańska

Dyńska-Kukulska

Jurczyk-Kowalska

. Characteristics of microstructural phenomena occurring on the surface of protective gloves by the action of mechanical and chemical factors. Polimery 2014; 59: 136–146.

10.

Irzmańska

Stefko

Dyńska-Kukulska

. Factors influencing the end of the service life of protective gloves used in car repair shop: a preliminary report. Arch Environ Occup H 2015; 70: 81–90.

11.

Irzmańska

Stefko

. Simulation method for assessing the end of service life of gloves used by workers exposed to mineral oils and mechanical factors. Int J Ind Ergonom 2015; 47: 61–71.

12.

Xue

Bai

Jia

. Robust, self-healing superhydrophobic fabrics prepared by one-step coating of PDMS and octadecylamine. Sci Rep 2016; 6: 1–11.

13.

Plaisted

Amirkhizi

Arbelaez

, et al. Self-healing structural composites with electromagnetic functionality. Proc SPIE 2003; 5054: 372–381.

14.

Williams

Boydston

Bielawski

. Towards electrically conductive, self-healing materials. J R Soc Interface 2007; 4: 359–362.

15.

Zhang

Pan

, et al. Self-healing mechanisms in smart protective coatings: a review. Corros Sci 2018; 144: 74–88.

16.

Zaborski M, Stracedil;kowska A and Masłowski M. POSS compounds as an accessory and additives for elastomer composites. Patent PL218804, Poland, 2015.

17.

Adamus-Włodarczyk

Bacciarelli-Ulacha

Irzmańska

, et al. Evaluation of the elastomeric composite self-repair process for the construction of protective gloves. Fibers Text East Eur 2018; 26: 104–110.

18.

Zaborski

Strańkowska

Kosmalska

, et al. POSS compounds as modifiers and additives for elastomer composites. Polimery 2013; 58: 772–782.

19.

ISO 6330:2012. Textiles—domestic washing and drying procedures for textile testing.

20.

EN 16523-1:2015-05. Determination of material resistance to permeation by chemicals—Part 1: permeation by liquid chemical under conditions of continuous contact.

21.

EN 388:2016. Protective gloves against mechanical risks.

22.

Abramavičiu¯tė

Mikučionienė

Čiukas

. Structure properties of knits from natural yarns and their combination with elastane and polyamide threads. Mater Sci 2011; 17: 43–46.

23.

Jones RG, Ando W and Chojnowski J (eds). Silicon-containing polymers: the science and technology of their synthesis and applications. Netherlands: Springer, 2013.

24.

Straaogon;kowska A, Kosmalska A, Masłowski et al. POSS as promoters of self-healing process in silicone composites. Polym Bull 2019; 76: 3387–3402.

25.

Kennedy JF, Phillips GO, Wedlock DJ, et al. (eds). Cellulose and its derivatives: chemistry, biochemistry, and applications. Chichester: Ellis Horwood Ltd, 1985.

26.

Landel RF and Nielsen LE (eds). Mechanical properties of polymers and composites. 2nd ed. CRC Press, 1993.

27.

Robitaille

Clayton

Long

, et al. Geometric modelling of industrial preforms: warp-knitted textiles. P I Mech Eng L-J Mat 2000; 214: 71–90.

28.

Wang

Gregory

Minor

. Improving mechanical properties of molded silicone rubber for soft robotics through fabric compositing. Soft Robot 2018; 5: 272–290.

29.

Jabbar

Shaker

Umair

, et al. Optimizing the performance of woven protective gloves using grey relational analysis. J Text I 2017; 108: 1715–1719.

The effects of textile reinforcements on the protective properties of self-healing polymers intended for safety gloves

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