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2016 | OriginalPaper | Buchkapitel

4. Yarn Constructions and Yarn Formation Techniques

verfasst von : Beata Lehmann, Claudia Herzberg

Erschienen in: Textile Materials for Lightweight Constructions

Verlag: Springer Berlin Heidelberg

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Abstract

Yarns are an important basic element for both the production and the assembly of textile reinforcement structures. They consist of either a 100 % reinforcement fibers or a blend of reinforcement and matrix fibers. They are made from filaments and/or staple fibers by means of different technologies, which allow the customization of structure and properties of the yarns according to the respective functional requirements. These chapters give an overview of the yarns currently used in lightweight construction and shows that their design has considerably influence of further processing and on the characteristics of composite materials. During textile processing, the yarns have to be processed easily at high speeds and must be formable force- or form-fit. Defined, anisotropic characteristics are achieved by the preferred orientation of the fibers in the yarn and the 2D or 3D yarn orientation during the production of textile semi-finished products. In the composite material itself, the yarn structures offer mechanic fixations.

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Vorheriges Kapitel Textile Fiber Materials

Nächstes Kapitel Woven Semi-finished Products and Weaving Techniques

LONG, A. C.;WILKS, C. E.; RUDD, C. D.: Experimental characterisation of the consolidation of a commingled glass and polypropylene composite. In: Composites Science and Technology 61 (2001), No. 11, PP. 1591–1603. DOI 10.1016/S0266–3538(01)00059–8166

FELEKOGLU, B.; TOSUN, K.; BARADAN, B.: Effects of fibre type and matrix structure on the mechanical performance of self-compacting micro-concrete composites. In: Cement and Concrete Research 39 (2009), No. 11, pp. 1023–1032. DOI 10.1016/j.cemconres.2009.07.007

SVENSSON, N.; SHISHOO, R.; GILCHRIST, M.: Manufacturing of thermoplastic composites from commingled yarns - a review. In: Journal of Thermoplastic Composite Materials 11 (1998), No. 1, pp. 22–56. DOI 10.1177/089270579801100102

BEYREUTHER, R.; BRÜNIG, H.; VOGEL, B.: Preferable filament diameter ratios of hybrid yarn components for optimized long fibre reinforced thermoplastic. In: Proceedings. 17th Annual Meeting of the PPS. Montreal, Canada, 2001

BRÜNIG, H.; BEYREUTHER, R.; VOGEL, R.; TÄNDLER, B.: Melt spinning of the fine and ultra fine PEEK-filaments. In: Journal of Materials Science 38 (2003), No. 10, pp. 2149–2153. DOI 10.1023/A:1023719912726

GOLZAR, M.; BRÜNIG, H.; MÄDER, E.: Commingled hybrid yarn diameter ratio in continuous fiber-reinforced thermoplastic composites. In: Journal of Thermoplastic Composite Materials 20 (2007), No. 1, pp. 17–26. DOI 10.1177/0892705707068069

YE, L.; FRIEDRICH, K.; KASTEL, J.; MAI, Y. M.: Consolidation of unidirectional CF/PEEK composites from commingled yarn prepreg. In: Composites Science and Technology 54 (1995), No. 4, pp. 349–358. DOI 10.1016/0266–3538(95)00061–5

ALAGIRUSAMY, R.; FANGUEIRO, R.; OGALE, V.; PADAKI, N.: Hybrid yarns and textile preforming for thermoplastic composites. In: Textile Progress. Cambridge : Woodhead Publishing Limited, 2006

CURBACH, M.; JESSE, F.: Eigenschaften und Anwendung von Textilbeton. In: Beton- und Stahlbetonbau 104 (2009), No. 1, pp. 9–16. DOI 10.1002/best.200800653

10.

Protective right US 005182839 (2nd February 1993).

11.

Protective right US 5200620 (6th April 1993).

12.

JOU, G. T.; EAST, G. C.; LAWRENCE, C. A.; OXENHAM, W.: The physical properties of composite yarns production by an electrostatic filament-charging method. In: Journal of the Textile Institute 87 (1996), No. 1, pp. 78–96. DOI 10.1080/00405009608659058

13.

Protective right US 4874563 (17th October 1989).

14.

Protective right EP 0486884 A1 (7th November 1991).

15.

Protective right EP 0364874 (25th April 1990).

16.

BALASUBRAMANIAN, N.; BHATNAGAR, V. K.: The effect of spinning conditions on the tensile properties of core-spun yarns. In: Journal of the Textile Institute 61 (1970), No. 11, pp. 534–554. DOI 10.1080/00405007008630021

17.

Protective right US 5094883 (10th March 1992).

18.

KLETT, J. W.; EDIE, D. D.: Flexible towpreg for the fabrication of high thermal conductivity carbon/carbon composites. In: Carbon 33 (1995), No. 10, pp. 1485–1503. DOI 10.1016/0008–6223(95)00103–K

19.

FITZER, E.; MANOCHA, L. M.: Carbon Reinforcements and Carbon/Carbon Composites. 1st Edition. Berlin, Heidelberg, New-York : Springer Verlag, 1998

20.

Protective right US 005241731 (7th September 1993).

21.

Protective right US 3704485A (5th December 1972).

22.

Protective right US 4539249 (3rd September 1985).

23.

WU, W. Y.; LEE, J. Y.: Effect of spread width on the structure, properties, and production of a composite yarn. In: Textile Research Journal 65 (1995), No. 4, pp. 225–229. DOI 10.1177/004051759506500406

24.

Protective right DE 102009029437 A1 (25th March 2010).

25.

CHERIF, Ch.: Entwicklung eines Verfahrens zur schädigungsarmen Durchmischung vonMultifilamentgarnen (IGF-No. 14686 BR) / TU Dresden, Institut für Textil- und Bekleidungstechnik. Dresden, 2008. – Final report

26.

Cytec Industries Inc.: Cytec Engineered Materials http://www.cytec.com/engineeredmaterials/prepreg.htm (24-04-2010)

27.

OCV Reinforcemcents: Twintex ^®. http://www.twintex.com/ (16-04-2010)

28.

MÄDER, E.; ROTHE, Chr.; BRÜNIG, H.; LEOPOLD, Th.: Online spinning of commingled yarns - equipment and yarn modification by tailored fibre surfaces. In: Key Engineering Materials 334-335 (2007), pp. 229–232. DOI 10.4028/www.scientific.net/KEM.334–335.229

29.

MÄDER, E.; RAUSCH, J.; SCHMID, N.: Commingled yarns - Processing aspects and tailored surfaces of polypropylene/glass composites. In: Composites Part A: Applied Science and Manufacturing 39 (2008), No. 4, pp. 612–623. DOI 10.1016/j.compositesa.2007.07.011

30.

CHERIF, Ch.; RÖDEL, H.; HOFFMANNN, G.; DIESTEL, O.; HERZBERG, C.; PAUL, C.; SCHULZ, Ch.; GROSSMANN, K.; MÜHL, A.; MÄDER, E.; BRÜNIG, H.: Textile Verarbeitungstechnologien für hybridgarnbasierte komplexe Preformstrukturen/Textile manufacturing technologies for hybrid based complex preform structures. http://www.kunststoffe.de/directlink.asp?WAK090202 (20-04-2010)

31.

ABOUNAIM, Md.; HOFFMANN, G.; DIESTEL, O.; CHERIF, Ch.: Development of flat knitted spacer fabrics for composites using hybrid yarns and investigation of two-dimensional mechanical properties. In: Textile Research Journal 79 (2009), No. 7, pp. 596–610. DOI 10.1177/0040517508101462

32.

Standard DIN 60900 Teil 5 July 1988. Garne: Texturierte Filamentgarne, Herstellungsverfahren und Begriffe

33.

ACAR, M.; TURTON, R.; WRAY, G. R.: Analysis of the air-jet texturing process. II. Experimental investigation of the air flow. In: Journal of the Textile Institute 77 (1986), No. 1, pp. 28–43. DOI 10.1080/00405008608658519

34.

MIAO, M.; SOONG, M.-C. C.: Air interlaced yarn structure and properties. In: Textile Research Journal 65 (1995), No. 8, pp. 433–440. DOI 10.1177/004051759506500801

35.

MÄDER, E.; ROTHE, Ch.; GAO, S.-L.: Commingled yarns of surface nanostructured glass and polypropylene filaments for effective composite properties. In: Journal of Materials Science 42 (2007), No. 19, pp. 8062–8070. DOI 10.1007/s10853–006–1481–x

36.

Oerlikon Heberlein Temco Wattwil AG: Taslan-Luftblastexturieren Heberlein ^® HemaJet-Düsenkerne patentiert. 2010. – Company document

37.

Protective right EP 0801159 A2 (15th October 1997).

38.

CHOI, B. D.: Entwicklung von Commingling-Hybridgarnen für langfasererstärkte thermoplastische Verbundwerkstoffe. Dresden, Technische Universität Dresden, Fakultät Maschinenwesen,Dissertation, 2005

39.

ALAGIRUSAMY, R.; OGALE, V.: Development and characterization of GF/ PET, GF/Nylon, and GF/PP commigled yarns for thermoplastic composites. In: Journal of Thermoplastic Composite Materials 18 (2005), No. 3, pp. 269–285. DOI 10.1177/0892705705049557

40.

OGALE, V.; ALAGIRUSAMY, R.: Properties of GF/PP Commingled Yarn Composites. In: Journal of Thermoplastic Composite Materials 21 (2008), No. 6, pp. 511–523. DOI 10.1177/0892705708091281

41.

MANKODI, H.; PATEL, P.: Study the effect of commingling parameters on glass/ polypropylene hybrid yarn properties. http//www.autexrj.org/No3-2009/0316.pdf (28-04-2010). Version: 2009

42.

COMFIL: Yarns/Rovings. http://www.comfil.biz/products/yarnsroving.php (22-04-2010)

43.

Rieter Machine Works Ltd.: Spinning documentation. 2008

44.

SEDLACIK, G.: Beitrag zum Einsatz von unidirektional naturfaserverstärkten thermoplastischen Kunststoffen als Werkstoff für großflächige Strukturbauteile. Chemnitz, Technische Universität Chemnitz,Dissertation, 2003

45.

LEE, D. H.; CHOWDHARY, U.; SEO, M. H.; JEON, B. S.: Effect of the stretch breaking process on fiber length distribution. In: Textile Research Journal 79 (2009), No. 7, pp. 626–631. DOI 10.1177/0040517508099391

46.

Protective right EP 1319740 A1 (18th June 2003).

47.

NG, S.; MEILUNAS, R.; ABDALLAH, M.G.: Stretched broken carbon fiber (SBCF) for forming complex curved composite structures. In: Proceedings. 51st International SAMPE Technical Conference. Long Beach, USA, 2006

48.

LEE, K.; LEE, S. W.; NG, S. J.: Micromechanical modelling of stretch broken carbon fiber materials. In: Journal of Composite Materials 42 (2008), No. 11, pp. 1063–1073. DOI 10.1177/0021998308090449

49.

BLACK, S.: Aligned discontinuous fibers come of age. http://www.compositesworld.com/articles/aligned-discontinuous-fibers-come-of-age (20-04-2010)

50.

http://www.google.de/search?hl=deei=8l7NS63lDIKAOJDd7KwPsa=Xoi=spellresnum=0ct=resultcd=1ved=0CBAQBSgAq=Hexcel+Stretched+Broken+fiberspell=1 (20-04-2010)

51.

Protective right US 5910361 (8th June 1999).

52.

ROSS, A.: Will Stretch-broken Carbon Fiber Become The New Material Of Choice? http://www.compositesworld.com/articles/will-stretch-broken-carbon-fiberbecomethe-newmaterial-of-choice (20-04-2010)

53.

http://www.schappe.com/rubrique.php3?idrubrique=25lang=en (27-04-2010)

54.

Protective right WO2006020404 A1 (23rd February 2006).

55.

Protective right US 5487941 (30th January 1996).

56.

Pepin Associates, Inc.: Disco Tex. http://www.pepinassociates.com/discotex.html (27-04-2010)

57.

TOONEN, M.: Ökologischer Hanfanbau und Anwendungsmöglichkeiten im Textilbereich. In: Proceedings. Tagungsband zur Fachtagung am 19. Juni 2007 in Kassel-Wilhelmshöhe / Schriftenreihe IBDF, Band 20. Darmstadt : Verlag Lebendige Erde, 2007

58.

MIAO, M.; HOW, Y.-L.; HO, S.-Y.: Influence of spinning parameters on core yarn sheath slippage and other properties. In: Textile Research Journal 66 (1996), No. 11, pp. 676–684. DOI 10.1177/004051759606601102

59.

60.

CARPENTER, J. E. P.; MIAO, M.; BRORENS, P.: Deformation behaviour of composites reinforced with four different linen flax yarn structures. In: Advanced Materials Research 29–30 (2007), pp. 263–266. DOI 10.4028/www.scientific.net/AMR.29–30.263

61.

ZHANG, L.; MIAO, M.: Commingled natural fibre/polypropylene wrap spun yarns for structured thermoplastic composites. In: Composites Science and Technology 70 (2010), No. 1, pp.130–135. DOI 10.1016/j.compscitech.2009.09.016

62.

THOMANNY, U. I.; ERMANNI, P.: The influence of yarn structure and processing conditions on the laminate quality of stampformed carbon and thermoplastic polymer fiber commingled yarns. In: Journal of Thermoplastic Composite Materials 17 (2004), No. 3, pp. 259–283. DOI 10.1177/0892705704041988

63.

BABAARSLAN, O.: Method of producing a polyester/viscose core-spun yarn containing spandex using a modified ring spinning frame. In: Textile Research Journal 71 (2001), No. 4, pp. 367–371. DOI 10.1177/004051750107100415

64.

NAJAR, S. S.; KHAN, Z. A.;WANG, X. G.: The new solo-siro spun process for worsted Yarns. In: Journal of the Textile Institute 97 (2006), No. 3, pp. 205–210. DOI 10.1533/joti.2005.0182

65.

GHARAHAGHAJI, A. A.; ZARGAR, E. N.; GHANE, M.; HOSSAINI, A.: Cluster-spun yarn - a new concept in composite yarn spinning. In: Textile Research Journal 80 (2010), No. 1, pp. 19–24. DOI 10.1177/0040517508099916

66.

MERATI, A.A.; KONDA, F.; OKAMURA, M.; MARUI, E.: False twist in core yarn friction spinning. In: Textile Research Journal 68 (1998), No. 6, pp. 441–448. DOI 10.1177/004051759806800609

67.

MATSUMOTO, Y.-I.; FUSHIMI, S.; SAITO, H.; SAKAGUCHI, A.; TORIUMI, K.; NISHIMATSU, T.; SHIMIZU, Y.; SHIRAI, H.; MOROOKA, H.; GONG, H.: Twisting mechanisms of open-end rotor spun hybrid yarns. In: Textile Research Journal 72 (2002), No. 8, pp. 735–740. DOI 10.1177/004051750207200814

68.

YANG, R.-H.; XUE, Y.;WANG, S.-Y.: Comparison and analysis of rotor-spun composite yarn and sirofil yarn. In: FIBRES TEXTILES in Eastern Europe 18 (2010), No. 1 (78), pp. 28–30

69.

Protective right DE19915955 C2 (13th September 2001).

70.

Standard DIN 60900 Teil 2 July 1988. Garne: Beschreibung im Tex-System

71.

KOLKMANN, A.: Methoden zur Verbesserung des inneren und äußeren Verbundes technischer Garne zur Bewehrung zementgebundener Matrices. Aachen, RWTH Aachen, Fakultät Maschinenwesen,Dissertation, 2008

72.

http://www.agteks.com (04-05-2010)

73.

OFFERMANN, P.; DIESTEL, O.; CHOI, B.-D.: Commingled CF/PEEK hybrid yarns for use in textile reinforced high performance rotors. In: Proceedings. 12th International Conference on Composite Materials. Paris, France, 1999

74.

HERZBERG, C.; RÖDEL, H.: Beanspruchungsgerechte 3D-Verstärkungen durch funktionsgerechte Nähtechnik (Informationsblatt). 2000

75.

ZHAO, N.; HERZBERG, C.; RÖDEL, H.: Assembly of textile preform for the composite material with sewing technology. In: Proceedings. 5th Pacific Rim International Conference on Advanced Materials und Processing. Beijing, China, 2004

76.

HERZBERG, C.; RÖDEL, H.: New sewing threads for composite applications. In: Proceedings. 4th International Conference IMCEP 2003. Maribor, Slowenien, 2003, pp. 139–143

77.

HERZBERG, C.; KRZYWINSKI, S.; RÖDEL, H.: Load-adapted 3D-reinforcement through function-adjusted stitching technique. In: Proceedings. 13th International Conference on Composite Materials. Beijing, China, 2001

78.

BLEAY, S. M.; LOADER, C. B.; HAWYES, V. J.; HUMBERSTONE, L.; CURTIS, P. T.: A smart repair system for polymer matrix composites. In: Composites Part A: Applied Science and Manufacturing 32 (2001), No. 12, pp. 1767–1776. DOI 10.1016/S1359–835X(01)00020–3

79.

PAUL, C.: Funktionalisierung von duroplastischen Faserverbundwerkstoffen durch Hybridgarne. Dresden, Technische Universität Dresden, Fakultät Maschinenwesen,Dissertation, 2010

BAGHAEIA, B.; SKRIFVARS, M.; SALEHI M.; BASHIR T.; RISSANEN M.; NOUSIAINEN, P.: Novel aligned hemp fibre reinforcement for structural biocomposites: Porosity, water absorption, mechanical performances and viscoelastic behavior. In: Composites: Part A, 61 (2014), pp. 1-12

HASAN, MMB.; CHERIF, Ch.: Analysis of the influence of process parameters on the mechanical properties of carbon core friction spun hybrid yarns for composites. In: FIBRES & TEXTILES in Eastern Europe 19 (2011), no. 4 (87) pp. 59-64

HASAN, MMB.; DIESTEL, O.; CHERIF, Ch.: Electro-mechanical properties of friction spun conductive hybrid yarns made of carbon filaments for composites. In: Textile Research Journal 81 (2011), pp 1603-1616

HASAN, MMB.; NOCKE, A.; CHERIF, Ch.: High temperature resistant insulated hybrid yarns for carbon fiber reinforced thermoplastic composites. In: Journal of Applied Polymer Science 130 (2013), no. 2, pp. 1179-1184

HASAN, MMB.: Development of new functional hybrid yarn constructions for structural health monitoring of high performance composites. Dresden, Technische Universität Dresden, Fakultät Maschinenwesen,Dissertation, 2013

KRAVAEV, P.; STOLYAROV, O.; SEIDE, G.; GRIES, T.: A method for investigating blending quality of commingled yarns. In: Textile Research Journal (2012), pp. 1-8. DOI: 10.1177/0040517512456760

KRAVAEV, P.; STOLYAROV, O.; SEIDE, G.; GRIES, T.: Influence of process parameters on filament distribution and blending quality in commingled yarns used for thermoplastic composites. In: Journal of Thermoplastic Composite Materials (2014), pp. 1-14. DOI: 10.1177/0892705712446167

MAHMOOD, A. H.; GONG, R. H.; PORAT, I.: Development of air textured core-and-effect glass yarns for improving the bonding strength of laminated composites. In: Fibers and Polymers 14 (2013), no. 2, pp. 271-276

MILLER, W.; REN, Z.; SMITH, C.W.; EVANS, K.E.: A negative Poisson’s ratio carbon fibre composite using a negative Poisson’s ratio yarn reinforcement. In: Composites Science and Technology 72 (2012), pp. 761-766

MORIMOTO, T.; IIZUKA, H.: Tensile behaviors of pre-twisted composite strands. In: Arch Appl Mech, 83 (2013), pp. 193-205

RAJWIN, AJ.; GIRIDEV, VR.; RENUKADEVI, M.: Effect of yarn twist on mechanical properties of glass fibre reinforced composite rods. In: Indian Journal of Fibre & Textile Research 37 (2012), pp. 343-346

SHAH, D. U.; SCHUBEL, P. J.; LICENCE, P.; CLIFFORD, M. J.: Determining the minimum, critical and maximum fibre content for twisted yarn reinforced plant fibre composites. In: Composites Science and Technology 72 (2012), pp. 1909-1917

TORUN, A. R.; HOFFMANN, G.; MOUNTASIR, A.; CHERIF, Ch.: Effect of twisting on mechanical properties of GF/PP commingled hybrid yarns and UD-composites. In: Journal of Applied Polymer Science 123 (2012), no. 1, pp. 246-256

YAN, L.; CHOUW, N.; JAYARAMAN, K.: Flax fibre and its composites – a review. In: Composites: Part B 56(2014), pp. 296-317

Titel: Yarn Constructions and Yarn Formation Techniques
verfasst von: Beata Lehmann
Claudia Herzberg
Verlag: Springer Berlin Heidelberg
Buch: Textile Materials for Lightweight Constructions
Print ISBN: 978-3-662-46340-6

Electronic ISBN: 978-3-662-46341-3

Copyright-Jahr: 2016
DOI: https://doi.org/10.1007/978-3-662-46341-3_4

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