Sage Journals: Discover world-class research

Abstract

Carbon fiber fabrics have been largely used in composite structures as they provide high mechanical strength and potential weigh reduction, allowing more efficiency in product design. However, the production of the parts generates scraps that is discarded as a waste, becoming a challenge to recycle the carbon fiber with predictable mechanical strength. Within this context, this research analyzed strategies of laying up carbon woven fabrics based scraps, in order to reach a desirable mechanical properties in bending loading. Three types of laminates were manufactured using varied fabric size and number of discontinuities in the layup combined with polyethylene terephthalate (PET) film as a matrix. The obtained composites were tested under four-point-bending test and an energy-strength based analysis was conducted. This analysis explained a strategic position of fabric scrap to maximize the bending strength: providing a value of 106.33 MPa for a composite with high number of discontinuities against 83.11 MPa for another with less discontinuity.

Keywords

Flexural test fracture strength of materials thermoplastic composites reuse

Get full access to this article

View all access options for this article.

References

Cousins

Suzuki

Murray

, et al. Recycling glass fiber thermoplastic composites from wind turbine blades. J Clean Prod 2019; 209: 1252–1263.

Shiino

de Siqueira

GSM

Cioffi

MOH

, et al. Hygrothermal effect on composites under in-plane fatigue at stress ratios of R = −1 and R = 0.1: an analysis of quasi-Isotropic stitched carbon fibers. J Mater Eng Perform 2018; 27: 5964–5972.

Castegnaro

Gomiero

Battisti

, et al. A bio-composite racing sailboat: materials selection, design, manufacturing and sailing. Ocean Eng 2017; 133: 142–150.

Howarth

Mareddy

SSR

Mativenga

PT.

Energy intensity and environmental analysis of mechanical recycling of carbon fibre composite. J Clean Prod 2014; 81: 46–50.

Echeverria

Handoko

Pahlevani

, et al. Cascading use of textile waste for the advancement of fibre reinforced composites for building applications. J Clean Prod 2019; 208: 1524–1536.

Quintana

Alba

del Rey

, et al. Comparative life cycle assessment of gypsum plasterboard and a new kind of bio-based epoxy composite containing different natural fibers. J Clean Prod 2018; 185: 408–420.

Pimenta

Pinho

ST.

Recycling carbon fibre reinforced polymers for structural applications: technology review and market outlook. Waste Manag 2011; 31: 378–392.

Henshaw

Han

Owens

AD.

An overview of recycling issues for composite materials. J Thermoplast Compos Mater 1996; 9: 4–20.

Saccani

Manzi

Lancellotti

, et al. Composites obtained by recycling carbon fibre/epoxy composite wastes in building materials. Constr Build Mater 2019; 204: 296–302.

10.

Annamalai

Vijayan

Saeedipour

, et al. The rise of short fibre reinforced plastics. Reinf Plast 2020; 64: 97–102.

11.

Snudden

Ward

Potter

Reusing automotive composites production waste. Reinf Plast 2014; 58: 20–27.

12.

Kouparitsas

Kartalis

Varelidis

, et al. Recycling of the fibrous fraction of reinforced thermoset composites. Polym Compos 2002; 23: 682–689.

13.

Turner

Pickering

Warrior

Development of recycled carbon fibre moulding compounds – preparation of waste composites. Compos Part B Eng 2011; 42: 517–525.

14.

Feraboli

Kawakami

Wade

, et al. Recyclability and reutilization of carbon fiber fabric/epoxy composites. J Compos Mater 2012; 46: 1459–1473.

15.

Liu

Wong

Thimsuvan

, et al. Effect of fibre length and suspension concentration on alignment quality of discontinuous recycled carbon fibre. ICCM Int Conf Compos Mater 2015: 19–24. http://www.iccm-central.org/Proceedings/ICCM20proceedings/

16.

Liu

Zhu

, et al. Investigation of the recycling of continuous fiber-reinforced thermoplastics. J Thermoplast Compos Mater 2019; 32: 342–356.

17.

Pietroluongo

Padovano

Frache

, et al. Mechanical recycling of an end-of-life automotive composite component. Sustain Mater Technol 2020; 23: e00143.

18.

Montoro

Shiino

Da Cruz

, et al. Influence of voids on the flexural resistance of the NCF/RTM6 composites. Proc Eng 2011; 10: 3220--3225.

19.

Daniel

Ishai

Engineering mechanics of composite materials. 2nd ed. New York: Oxford University Press, 2006.

20.

Mujika

On the effect of shear and local deformation in three-point bending tests. Polym Test 2007; 26: 869–877.

Waste size and lay up sequence strategy for reusing/recycling carbon fiber fabric in laminate composite: Mechanical property analysis

Abstract

Keywords

Get full access to this article

References