Color matching of fiber blends: Stearns‐Noechel model of digital rotor spun yarn

Yang, Rui; Han, Rui Ye; Lu, Yu Zheng; Gao, Wensheng

doi:10.1002/col.22192

Cited by 17 publications

(15 citation statements)

References 14 publications

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“…On this basis, models that demonstrate the relationships between the blending recipes and desired colours are built to improve efficiency, and studies have been conducted in this field for decades. Among them, 8‐10 Stearns and Noechel proposed an empirical formula based on the summation formula to explain the blending colour characteristics of fabrics produced by precoloured black and white wool fibres. Their formula—named the S‐N model—was developed with extensive experimental data.…”

Section: Introductionmentioning

confidence: 99%

Colour matching for smart and sustainable spinning of coloured textiles

Yang

Pan

Deng

et al. 2020

Coloration Technology

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The colours and patterns of coloured textiles are usually obtained via dyeing or printing processes. However, these processes consume large amounts of electricity and cause water pollution, which affects the ecological environment. The hand feel of dyed fabrics is superior to that of printed fabrics. Three-channel rotor spinning is a highly flexible, adaptable and sustainable method for producing coloured textiles by blending precoloured fibres during the spinning process. Additionally, the process requires approximately half the water required for fabric dyeing or printing. Herein, the colour characteristics, as well as the advantages, of the coloured textiles produced by the new method are demonstrated. Three types of Stearns-Noechel models are modified to describe the relationship between the blending ratios and resulting textile colours. The colour-matching accuracy is high. As demonstrated by the results, the threechannel rotor spinning method can effectively promote coloured textile engineering.Processes which make coloration cheaper, simpler and highly flexible, in addition to being more sustainable, have never been more attractive. The approach outlined in this Feature article could be one of them. It involves AbstractThe colours and patterns of coloured textiles are usually obtained via dyeing or printing processes. However, these processes consume large amounts of electricity and cause water pollution, which affects the ecological environment. The hand feel of dyed fabrics is superior to that of printed fabrics. Three-channel rotor spinning is a highly flexible, adaptable and sustainable method for producing coloured textiles by blending precoloured fibres during the spinning process. Additionally, the process requires approximately half the water required for fabric dyeing or printing. Herein, the colour characteristics, as well as the advantages, of the coloured textiles produced by the new method are demonstrated. Three types of Stearns-Noechel models are modified to describe the relationship between the blending ratios and resulting textile colours. The colour-matching accuracy is high. As demonstrated by the results, the three-channel rotor spinning method can effectively promote coloured textile engineering.

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Section: Introductionmentioning

confidence: 99%

Colour matching for smart and sustainable spinning of coloured textiles

Yang

Pan

Deng

et al. 2020

Coloration Technology

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“…However, to develop a commercially viable system it is necessary to have models that can predict the colour of blends, given the colour of the primaries used in the blend and their proportional amounts. Fortunately, a number of methods have been shown to be able to predict the colour of fibre blends with varying degrees of success, including the Stearns‐Noechel model, the Friele model, the Kubelka‐Munk model and artificial neural networks …”

Section: Introductionmentioning

confidence: 99%

“…2 However, to develop a commercially viable system it is necessary to have models that can predict the colour of blends, given the colour of the primaries used in the blend and their proportional amounts. Fortunately, a number of methods have been shown to be able to predict the colour of fibre blends with varying degrees of success, including the Stearns-Noechel model, 3,4 the Friele model, 5,6 the Kubelka-Munk model [7][8][9] and artificial neural networks. [10][11][12][13] However, in addition to the problem of colour prediction, there is also the issue of how many primaries are required to essentially cover the normal gamut of coloured textiles, and how these should these be distributed in colour space.…”

Section: Introductionmentioning

confidence: 99%

Towards the design of a blending system for precoloured fibres

Hemingray

Dean

Westland

2019

Coloration Technology

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In order to create a commercial system for blending precoloured fibres that will appear visually solid once combined, it is necessary to understand the maximum colour difference required between the blend components. Based on this understanding, the lowest number of primaries required to populate a given colour gamut can be determined. A series of psychophysical experiments was carried out to explore the colour difference between fibre‐blend components and whether the resulting blended samples are perceived as visually solid. Experiments were carried out with loose stock fibre, yarn and knitted samples. Generally, it was found that the likelihood a blend appeared as visually solid increased as the average colour difference between the blend components, or primaries, decreased. The value of the mean colour difference at which 50% of participants viewed the blend as being visually solid was found to be 20.8, 20.5 and 18.0 for fibre, yarn and knitted samples, respectively. Consequently, it was found that it was more difficult to obtain a solid shade with the knitted form than with the loose stock fibre form.

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“…Color matching blends of precolored fibers have been researched for decades. Several methods have been introduced to describe the color blending of precolored fibers, such as Kubelka‐Munk theory, Friele equation and Stearns‐Noechel model . In recent years, many people have used K‐M to study blending effects with different fiber materials and have achieved satisfactory results.…”

Section: Introductionmentioning

confidence: 99%

“…Several methods have been introduced to describe the color blending of precolored fibers, such as Kubelka-Munk theory, 4,5 Friele equation 6,7 and Stearns-Noechel model. [8][9][10] In recent years, many people have used K-M to study blending effects with different fiber materials 11,12 and have achieved satisfactory results. According to the previous study of K-M, there were two methods for solving the absorption coefficient (K) and the scattering coefficient (S) of monochromatic fibers in color blended yarns or fabrics, namely, the least squares method and the relative value method.…”

Section: Introductionmentioning

confidence: 99%

K‐M theory of fabric knitted by three‐channel rotor spun wool yarn

Yang

Deng

et al. 2018

Color Research & Application

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Two‐component and three‐component color blended yarns were spun by red, yellow, and blue wool slivers using a three‐channel rotor spun machine, and the corresponding plain fabrics were knitted. The color‐matching models of K‐M theory were built with the relative method and the least squares method, respectively. Colors and blending ratios of the fabrics were predicted by the model. The results showed that the average color differences of the samples predicted by the two methods are both about 1.0 and the mean value of the proportional error is below 3%. The least squares method has a better color‐matching effect for the three‐component sample, and the relative value method has better color‐matching results for the two‐component sample. When the tolerance range is 2.0, the pass rates of the samples predicted by either the relative value method or the least squares method reach 100%.

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Color matching of fiber blends: Stearns‐Noechel model of digital rotor spun yarn

Cited by 17 publications

References 14 publications

Colour matching for smart and sustainable spinning of coloured textiles

Colour matching for smart and sustainable spinning of coloured textiles

Towards the design of a blending system for precoloured fibres

K‐M theory of fabric knitted by three‐channel rotor spun wool yarn

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