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Crop and Pasture Science Crop and Pasture Science Society
Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE (Open Access)

An assessment of alternative cotton fibre quality attributes and their relationship with yarn strength

Robert L. Long A D E , Michael P. Bange B D , Christopher D. Delhom C , Jeffrey S. Church A and Greg A. Constable B
+ Author Affiliations
- Author Affiliations

A CSIRO Materials Science and Engineering, PO Box 21, Belmont, Vic. 3216, Australia.

B CSIRO Plant Industry, Locked Bag 59, Narrabri, NSW 2390, Australia.

C USDA-ARS Southern Regional Research Centre, 1100 Robert E. Lee Boulevard, New Orleans, LA 70124, USA.

D Cotton Catchment Communities Co-operative Research Centre, Australia.

E Corresponding author. Email: robert.long@csiro.au

Crop and Pasture Science 64(8) 750-762 https://doi.org/10.1071/CP12382
Submitted: 13 November 2012  Accepted: 15 February 2013   Published: 9 April 2013

Journal Compilation © CSIRO Publishing 2013 Open Access CC BY-NC-ND

Abstract

Knowing the yarn-strength performance potential of cotton fibre is advantageous to spinners during mill preparation, and to researchers developing new genotypes and management strategies to produce better fibre. Standard High Volume Instrument (HVI) fibre quality attributes include micronaire (a combined measure of fibre linear density and maturity) and bundle tensile properties. While these attributes relate well to yarn strength, alternative fibre quality attributes may better explain the variation in yarn strength. Two field experiments over two seasons were conducted to assess the fibre and yarn performance of some Australian cotton genotypes. The aim was to assess and compare alternative measures for micronaire, and to compare bundle and single-fibre tensile measurements, and assess the relative yarn-strength predictive performance of these attributes. Specific fibre measurement comparisons were for linear density (double-compression Fineness Maturity Tester (FMT) and gravimetric), maturity ratio (FMT, polarised light, calculated, and cross-sectional), and tensile properties (HVI bundle and Favimat Robot single fibre). Multiple linear regression models for yarn strength that included yarn manufacturing variables and standard HVI fibre quality parameters performed well (standard error of prediction (SEP) 2.40 cN tex–1). Multiple linear regression models performed better when alternatives to micronaire were used, e.g. using gravimetric linear density (SEP, 2.15 cN tex–1) or laser photometric determined ribbon width (SEP 1.71 cN tex–1). Yarn strength models were also better when single fibre tensile properties were substituted for bundle tensile properties (SEP 1.07 cN tex–1). The substitution of alternative fineness variables for micronaire or single-fibre strength for bundle strength in a simple fibre quality index also improved the prediction of yarn strength.


References

Abbott AM, Higgerson GJ, Long RL, Lucas SR, Naylor GRS, Tischler CR, Purmalis MM (2010) An instrument for determining the average fiber linear density (fineness) of cotton lint samples. Textile Research Journal 80, 822–833.
An instrument for determining the average fiber linear density (fineness) of cotton lint samples.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXmvFCltLg%3D&md5=da365d80873f75242de1b16cb482913fCAS |

Adedoyin AA, Li C, Toews MD (2010) Characterization of single cotton fibers using a laser diffraction system. Textile Research Journal 81, 355–367.
Characterization of single cotton fibers using a laser diffraction system.Crossref | GoogleScholarGoogle Scholar |

ASTM (1997) Standard test methods for linear density and maturity index of cotton fibers (IIC-Shirley Fineness/Maturity Tester) D3818-92. In ‘Annual book of ASTM standards. Section seven: Textiles. Vol. 07.02’. pp. 133–136. (American Society for Testing and Materials: West Conshohocken, PA)

ASTM International (2010a) Standard test methods for linear density of textile fibers D1577-07. In ‘Annual book of ASTM standards. Section seven: Textiles. Vol. 07.01’. pp. 368–377. (ASTM International: West Conshohocken, PA)

ASTM International (2010b) Standard test method for maturity of cotton fibers (sodium hydroxide swelling and polarized light procedures) D1442-06. In ‘Annual book of ASTM standards. Section seven: Textiles. Vol. 07.01’. pp. 321–326. (ASTM International: West Conshohocken, PA)

ASTM International (2010c) Standard test methods for diameter of wool and other animal fibers by Sirolan-Laserscan fiber diameter analyser D6466-10. In ‘Annual book of ASTM standards. Section seven: Textiles. Vol. 07.02’. pp. 590–598. (ASTM International: West Conshohocken, PA)

Behery HM (1993) ‘Short fiber content and uniformity index in cotton—ICAC review article on cotton production research. No. 4.’ (CAB International: Wallingford, UK)

Bradow JM, Wartelle LH, Bauer PJ, Sassenrath-Cole GF (1997) Small-sample cotton fiber quality quantitation. The Journal of Cotton Science 1, 48–60.

Chapman WE, Staten G (1957) Cotton fiber maturity rapidly predicted with variable volume of sample in micronaire. Textile Research Journal 27, 991–992.
Cotton fiber maturity rapidly predicted with variable volume of sample in micronaire.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaG1cXhvVOgsw%3D%3D&md5=35fc864ee32502f868c7eabebc1d5563CAS |

Charlton D (1995) Sirolan-Laserscan. A review of its development, performance and application. Wool Technology and Sheep Breeding 43, 212–228.

Chee PW, Campbell BT (2009) Bridging classical and molecular genetics of cotton fiber quality and development. In ‘Genetics and genomics of cotton, plant genetics and genomics: crops and models 3’. (Ed. AH Paterson) pp. 283–311. (Springer Science + Business Media: New York)

Cheng L, Adams DL (1995) Yarn strength prediction using neural networks part 1: fiber properties and yarn strength relationship. Textile Research Journal 65, 495–500.
Yarn strength prediction using neural networks part 1: fiber properties and yarn strength relationship.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2MXnslWqs7s%3D&md5=3b3b4683f7e073f6254b389dcbc4c67bCAS |

Delhom CD, Cui X, Thibodeaux DP (2010) Single fiber testing via Favimat. In ‘2010 Beltwide Cotton Conference’. New Orleans, Louisiana, 4–7 January 2010. (National Cotton Council of America: Cordova, TN)

Deutscher SA, Wilson LJ, Mensah R (2004) ‘Integrated pest management guidelines for cotton production systems in Australia.’ (The Australian Cotton Cooperative Research Centre: Narrabri, NSW)

El Sourady AS, Worley S, Stith LS (1974) The relative contribution of fiber properties to variations in yarn strength in upland cotton, Gossypium hirsutum L. Textile Research Journal 44, 301–306.
The relative contribution of fiber properties to variations in yarn strength in upland cotton, Gossypium hirsutum L.Crossref | GoogleScholarGoogle Scholar |

Foulk JA, McAlister DD (2002) Single cotton fiber properties of low, ideal, and high micronaire values. Textile Research Journal 72, 885–891.
Single cotton fiber properties of low, ideal, and high micronaire values.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38XnvFKjt7o%3D&md5=4b260333477d0757273f482634645c60CAS |

Foulk J, Meredith W, McAlister D, Luke D (2009) Fiber and yarn properties improve with new cotton cultivar. The Journal of Cotton Science 13, 212–220.

Fowler JL, Hertel KL (1940) Flow of a gas through porous media. Journal of Applied Physics 11, 496–502.
Flow of a gas through porous media.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaH3MXktFGk&md5=c96d9f170689d8f6dfc11c6a46731dd8CAS |

Gordon SG, Phair NL (2005) An investigation of the interference colors in mature and immature cotton fibers. In ‘Proceedings Beltwide Cotton Conferences’. New Orleans, LA. 4–7 January 2005. (Eds P Dugger, D Richter) pp. 2284–2290. (National Cotton Council of America: Cordova, TN)

Grimes MA (1945) Polarized light: Preferred for maturity tests. Textile World 161–163.

Hearn AB, Fitt GP (1992) Cotton cropping systems. In ‘Ecosystems of the world—field crop ecosystems’. (Ed. CJ Pearson) pp. 85–142. (Elsevier: London)

Hebert JJ, Boylston EK, Wadsworth JI (1979) Cross-sectional parameters of cotton fibers. Textile Research Journal 49, 540–542.
Cross-sectional parameters of cotton fibers.Crossref | GoogleScholarGoogle Scholar |

Hebert JJ, Thibodeaux DP, Shofner FM, Singletary JK, Patelke DB (1995) A new single fiber tensile tester. Textile Research Journal 65, 440–444.
A new single fiber tensile tester.Crossref | GoogleScholarGoogle Scholar |

Hequet EF, Wyatt B, Abidi N, Thibodeaux DP (2006) Creation of a set of reference material for cotton fiber maturity measurements. Textile Research Journal 76, 576–586.
Creation of a set of reference material for cotton fiber maturity measurements.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XnsVeitrw%3D&md5=a475668fb84cc3d879375582f0444315CAS |

Hunter L (2004) Predicting cotton yarn properties from fibre properties in practice. In ‘Proceedings 27th International Cotton Conference’. 24–27 March, Bremen, Germany. pp. 62–77. (Faserinstitut Bremen: Bremen, Germany)

Huson MG, Phair NL, Maxwell JM, Turner PS (2000) Bundle strength and intrinsic fibre strength of finewools from different bloodlines. Asian–Australasian Journal of Animal Science 13, 268

Isbell RF (2002) ‘The Australian Soil Classification.’ (CSIRO Publishing: Melbourne)

Long RL, Bange MP, Gordon SG, van der Sluijs MHJ, Naylor GRS, Constable GA (2010) Fiber quality and textile performance of some Australian cotton genotypes. Crop Science 50, 1509–1518.
Fiber quality and textile performance of some Australian cotton genotypes.Crossref | GoogleScholarGoogle Scholar |

Lord E (1956) Air flow through plugs of textile fibers. Part II – The micronaire test for cotton. The Journal of the Textile Institute 47, T16–T47.

Lord E (1961) ‘The characteristics of raw cotton.’ (The Textile Institute: Manchester, UK)

Lord E, Heap SA (1988) ‘The origin and assessment of cotton fibre maturity.’ (International Institute for Cotton: Manchester, UK)

Lunney HWM, Irvine PA (1979) Some factors affecting measurement by the CSIRO fiber-fineness distribution analyser. Textile Research Journal 49, 371–379.
Some factors affecting measurement by the CSIRO fiber-fineness distribution analyser.Crossref | GoogleScholarGoogle Scholar |

Lynch LJ, Michie NA (1976) An instrument for the rapid automatic measurement of fiber fineness distribution. Textile Research Journal 46, 653–660.

Matic-Leigh R, Cauthen DA (1994) Determining cotton fiber maturity by image analysis – part 1 direct measurement of cotton fiber characteristics. Textile Research Journal 64, 534–544.
Determining cotton fiber maturity by image analysis – part 1 direct measurement of cotton fiber characteristics.Crossref | GoogleScholarGoogle Scholar |

May OL, Taylor RA (1998) Breeding cottons with higher yarn tenacity. Textile Research Journal 68, 302–307.
Breeding cottons with higher yarn tenacity.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXitFeisLw%3D&md5=883dad22dc3e5a0140f53392b524d74fCAS |

Montalvo JG (2005) Relationships between micronaire, fineness, and maturity. Part I – Fundamentals. The Journal of Cotton Science 9, 81–88.

Naylor GRS, Purmalis M (2005) Update on Cottonscan: An instrument for rapid and direct measurement of fiber maturity and fineness. In ‘Proceedings Beltwide Cotton Conferences’. New Orleans, LA, 4–7 Jan. 2005. (Eds P Dugger, D Richter) pp. 2302–2306. (National Cotton Council of America: Cordova, TN)

Padmaraj L, Krifa M, Xu B (2011) Evaluating immature fiber bias in fiber cross-section analysis. In ‘Proceedings Beltwide Cotton Conferences’. Atlanta, GA, January 2011. (Eds S Boyd, M Huffman, B Robertson) p. 1476. (National Cotton Council of America: Cordova, TN)

Patt DH (1958) Findings and recommendations on the use of the vibroscope. Textile Research Journal 28, 691–700.
Findings and recommendations on the use of the vibroscope.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaG1cXhtVSlsLY%3D&md5=57e161e131298f2c4e8eb45d00dea5a2CAS |

Qi K, Lupton CJ, Pfeiffer FA, Minikhiem DL (1994) Evaluation of the optical fibre diameter analyser (OFDA) for measuring fiber diameter parameters of sheep and goats. Journal of Animal Science 72, 1675–1679.

Ramey HH, Lawson R, Worley S (1977) Relationship of cotton fiber properties to yarn tenacity. Textile Research Journal 47, 685–691.

Rodgers J, Delhom C, Fortier C, Thibodeaux D (2012) Rapid measurement of cotton fiber maturity and fineness by image analysis microscopy using the Cottonscope®. Textile Research Journal 82, 259–271.
Rapid measurement of cotton fiber maturity and fineness by image analysis microscopy using the Cottonscope®.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC38XjsV2itr0%3D&md5=6ea83f24951236606f2fa70cac502ed9CAS |

Sasser PE, Shofner FM, Chu YT, Shofner CK, Townes MG (1991) Interpretations of single fiber, bundle, and yarn tenacity data. Textile Research Journal 61, 681–690.
Interpretations of single fiber, bundle, and yarn tenacity data.Crossref | GoogleScholarGoogle Scholar |

Schleth A, Ghorashi H, Furter R (2007) ‘Uster HVI 1000 application report—the role of cotton classification in the textile industry.’ (Uster Technologies AG: Uster, Switzerland)

Schwarz ER, Hotte GH (1935) Micro-determination of cotton fiber maturity in polarized light. Textile Research Journal 5, 370–376.
Micro-determination of cotton fiber maturity in polarized light.Crossref | GoogleScholarGoogle Scholar |

Skau EL (1951) Simple expressions for the circularity and fullness of fibers. Textile Research Journal 21, 14–17.
Simple expressions for the circularity and fullness of fibers.Crossref | GoogleScholarGoogle Scholar |

Smith WS (1947) Air gauge measures fiber fineness. Textile Industries 111, 86–88.

Stiller WN (2005) Sicala 350B. Plant Varieties Journal 19, 76–80.

Stiller WN (2008) Sipima 280. Plant Varieties Journal 21, 112

Thibodeaux DP, Rajasekaran K (1999) Development of new reference standards for cotton fiber maturity. The Journal of Cotton Science 3, 188–193.

Thibodeaux DP, Hebert JJ, El-Gawad NSA, Moraitis JS (1998) Relating bundle strength to mantis single fiber strength measurements. The Journal of Cotton Science 2, 62–67.

Ureyen ME, Kadoglu H (2006) Regressional estimation of ring cotton yarn properties from HVI fiber properties. Textile Research Journal 76, 360–366.
Regressional estimation of ring cotton yarn properties from HVI fiber properties.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28XlsVOgsL0%3D&md5=5df56b039741f12fb4724f7dda29f230CAS |

USDA (2005) ‘Cotton classification understanding the data.’ Agricultural Marketing Services Cotton Program. (United States Department of Agriculture: Washington, DC)

Williams GF, Yankey JM (1996) New developments in single fiber fineness and maturity measurements. In ‘Proceedings Beltwide Cotton Conferences’. Nashville, TN, 9–12 January 1996. (Eds P Dugger, D Richter) pp. 1284–1289. (National Cotton Council of America: Cordova, TN)

Xu B, Yao X, Bel P, Hequet EF, Wyatt B (2009) High volume measurements of cotton maturity by a customized microscope system. Textile Research Journal 79, 937–946.
High volume measurements of cotton maturity by a customized microscope system.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXnvV2is7k%3D&md5=8e1499bbcbf0ae9b0b2fccdac130e243CAS |

Zhang Z, Lu C, Su Y (2010) A novel method to assess cotton fiber qualities based on fraunhofer diffraction. In ‘Proceedings 2nd International Asia Conference on Informatics in Control, Automation and Robotics’. Wuhan, China. 6–7 March, Vol. 1. pp. 226–228.

Zurek W, Frydrych I, Zakrzewski S (1987) A method of predicting the strength and breaking strain of cotton yarn. Textile Research Journal 57, 439–444.
A method of predicting the strength and breaking strain of cotton yarn.Crossref | GoogleScholarGoogle Scholar |