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Abstract

The spunlacing technique for producing auto interior nonwovens is examined. A 50/50 flax/polypropylene nonwoven is processed using an AquaJet spunlace system with two different spunlacing settings. The spunlaced nonwovens are thermally bonded into 2D and 3D interior parts by a panel press and a stamp-forming press. Physical properties, mechanical properties, and moldability of the nonwovens after spunlacing and molding are evaluated in accordance with relevant European and German industrial standards. The statistical method of variance analysis and image analysis method are used for data process. The research work finds that the spunlacing process brings some technical merits for the flax/polypropylene nonwoven in auto interior applications, in particular, an enhancement of tensile and flexural strengths, a large thickness reduction with controlled ultimate weight, and a competitive moldability. The experimental data also reveals that using a setting of lower water-jet pressure on the spunlacing process line is more suitable for entangling flax/polypropylene nonwovens to produce high performance auto interior composites.

Keywords

spunlacing flax/polypropylene nonwoven composite molding auto interior mechanical strength impact strength.

References

Sherman, L.M. (2007). Natural Fibers: The New Fashion in Automotive Plastics . Plastics Technology 1999, http://www.ptonline.com/articles/199910fa1.html (Retrieved April 9, 2007).

Teresko, J. (2007). Green Machines . IndustryWeek 2005, www.industryweek.com/CurrentArticles/Asp/articles.asp?ArticleId=1739 (Retrieved April 9, 2007).

Müssig, J. , Karus, M. and Frank, R.R. (2005). Bast and Leaf Fibre Composite Materials. In: Frank, R.R. (ed.), Bast and Other Plant Fibres, pp. 345-376, Woodhead Publishing, Ltd, Cambridge, UK.

Karus, M. and Kaup, M. (2002). Natural Fibres in the European Automotive Industry , Journal of Industrial Hemp, 7(1): 119-131.

Karus, M. , Ortmann, S. and Vogt, D. (2005). All Natural on the Inside ? Kunststoffe-Plast Europe, 95(7): 51-53.

Madlener, R. and Schwager, H. (2003). (Geruchs- und Emissionsverhalten von naturfaserverstärkten Werkstoffen im Fahrzeug . Messe CongessCenter Erfurt, (Hrsg.und Veranst.): naro.tech - 4, In: Internationales Symposium Nachwachsende Rohstoffe, Sep. 11, Messe Congress Center Erfurt, Erfurt , Germany, pp. 1-14.

Merten, T. (2002). Geruchsproblematik bei naturfaserbasierten Automobilinnenverkleidungen , In: Universität Gh Kassel, Institut für Werkstofftechnik, Kunststoff- und Recyclingtechnik (Hrsg.und Veranst.): Geruchsbewertung und -minderung von Kunststoffen (4.Workshop), Apr 9, Universität Kassel Institut für Werkstofftechnik, Kassel, Germany, pp. 7-1-7-18.

Fischer, H. , Müssig, J. , Geppert, N. and Bluhm, C. (2004). Beurteilung des Geruchspotenzials von Naturfasern für den Einsatz im Automobilbereich. Arbeitsgemeinschaft Verstärkte Kunststoffe - Technische Vereinigung e.V.(AVK-TV) (Hrsg.und Veranst.), In: Internationale AVK-TV Tagung für verstärkte Kunststoffe und duroplastische Formmassen, Sep. 28, Baden-Baden , Germany. Arbeitsgemeinschaft Verstärkte Kunststoffe - Technische Vereinigung e.V., Frankfurt /Main, Germany: (AVK-TV) (Hrsg. und Veranst.), pp. B11-1 -B11-7.

Vuillaume, A.M. (1991). A Global Approach to the Economics and End-Product Quality of Spunlace Nonwovens , Tappi Journal, 74(8): 149-152.

10.

Widen, C.B. (1991). Forming Fabrics for Spunlace Applications , Tappi Journal, 74(5): 149-153.

11.

Huang, H. and Spunlace, G.X. (Hydroentanglement) (1999). Education-Training-Research for the Apparel and Textile Industry, http://www.apparelsearch.com/Education/Research/Nonwoven/2001_Kermit_Duckett/education_research_nonwoven_spunlace.htm (Retrieved April 9, 2007).

12.

Watzl, A. (2007). AquaJet Spunlace System - Technology for Cotton Fibers . Texdata International AG 2002 November 16, www.texdata.com (Retrieved April 15, 2007).

13.

Watzl, A. (2007). Spunbonding and Spunlacing - Two Leading Technologies Coming Together . Texdata International AG 2002 December 10, www.texdata.com (Retrieved April 15, 2007).

14.

Watzl, A. (2007). Spunbonding and Spunlacing - Spunbond Applications on New Paths . Texdata International AG 2004 November 13, www.texdata.com (Retrieved April 15, 2007).

15.

Watzl, A. and Desch, A. (2001). Use of Spunlace Technology for Woven Fabrics, International Textile Bulletin, 47(January): 68-70.

16.

Watzl, A. (1997). Energy Consumption for Hydroentanglement with Fleissner-Aquajet Spunlace Systems , Chemical Fibers International , 47(4): 153 .

17.

Lang, A. (2006). Spunlace & PM 2.5 - The Right Alternative? Technical Textiles, Chemical Fibers International, 56(5): 312 .

18.

Cohen, D. (1999). Spunlaced Nonwovens Overview , Nonwoven Industry, 30(2): 20-24.

19.

Gilmore, T.F. , Timble, N.B. and Morton, G.P. (1997). Hydroentangled Nonwovens Made from Unbleached Cotton , Tappi Journal, 80(3): 179-183.

20.

Fleissner GmbH. (2007). The Technical Center . Fleissner Homepage 2007, www.fleissner.de (Retrieved April 15, 2007).

21.

Müssig, J. (2001). Neue technische Textilien aus heimischen Pflanzenfasern (Hanf und Nessel). Faserinstitut Bremen e.V. - FIBRE, Bremen, Germany, Report No. AiF 11918N.

22.

Sun, X. , Fang, X. and Guan, L. (1979). Mechanics of Materials, The Publishing House of Higher Education, Beijing, China.

23.

SAS Institute Inc. (1990 ). SAS/STAT User's Guide, Version 6.4, Cary, N.C. (ed.), SAS Institute Inc .

Spunlaced Flax/Polypropylene Nonwoven as Auto Interior Material: Mechanical Performance

Abstract

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