Relevant bibliographies by topics / Yarn hairiness

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'Yarn hairiness'

Author: Grafiati
Published: 4 June 2021
Last updated: 3 February 2022

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Journal articles on the topic "Yarn hairiness"

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Zhang, Xi Chang, Yu Heng Su, Guang Song Yan, and Long Di Cheng. "Stochastic Simulation of Hairiness with Compact Spinning Yarn." Advanced Materials Research 332-334 (September 2011): 989–94. http://dx.doi.org/10.4028/www.scientific.net/amr.332-334.989.

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Reducing yarn hairiness is the greatest ascendancy for compact spinning. Based on the test of fiber length distribution, the hairiness of compact yarn is simulated in order to study the rule of hairiness producing. The hairiness of different fineness yarn is simulated by changing the twist factory and the diameter of yarn and the hairiness of different kinds of yarns such as compact yarn and ring spinning yarn are simulated by changing the transition probability of fiber. The simulation data are in accordance with the experimental data. It can make prediction about yarn hairiness according to the fiber length distribution in order to guide production.
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Su, Xu Zhong, Wei Dong Gao, Ting Ting Wu, Xin Jin Liu, and Yun Zhang. "Reducing Yarn Hairiness in a Modified Ring Spinning Yarn Path by Various Offsets." Advanced Materials Research 331 (September 2011): 493–97. http://dx.doi.org/10.4028/www.scientific.net/amr.331.493.

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Spinning triangle is a critical region in the spinning process of yarn. Its geometry influences the distribution of fiber tension in the spinning triangle and the properties of spun yarns, such as the yarn breakage and hairiness. In this paper, the relationships between the spinning angle and yarn properties especially the yarn hairiness were investigated under various horizontal offsets. The properties of spun yarns produced by the modified system were evaluated and analyzed. Both left diagonal and right diagonal yarn arrangements were examined. The results indicate that the right diagonal yarn path leads to reduce yarn hairiness but the left diagonal yarn path leads to increase yarn hairiness; the breaking force of yarn changes little; yarn evenness deteriorates slightly with the changes of offset.
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Yu, Xue Zhi, and Peng Zi Sun. "Effect of Carding Plate Gauge under the Licker-in of Carding Machine on Polyester Yarn Hairiness." Advanced Materials Research 937 (May 2014): 400–403. http://dx.doi.org/10.4028/www.scientific.net/amr.937.400.

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Effect of different gauge of pin carding plate and saw-tooth carding plate respectively installed under the licker-in of carding machine on polyester yarn hairiness was studied. The hairiness of polyester yarns produced in the condition of installing pin carding plate and saw-tooth carding plate under the licker-in at four different gauges were tested by YG172 yarn hairiness tester. The results show that the two kinds of carding plate at the gauge of 0.7mm are most beneficial to reducing the number of polyester yarn hairiness. When the pin carding plate gauge is 1.0mm and the saw-tooth carding plate gauge is 0.3mm, the number of polyester yarn hairiness is the most. As a whole, installing saw-tooth carding plate under the licker-in is more favorable for reducing the number of polyester yarn hairiness.
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Li, Peiying, Mingrui Guo, Fengxin Sun, and Weidong Gao. "Reducing yarn hairiness in ring spinning by an agent-aided system." Textile Research Journal 89, no. 21-22 (March 13, 2019): 4438–51. http://dx.doi.org/10.1177/0040517519835769.

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An agent-aided system (AAS) for improving comprehensive properties of ring spun yarns with the aid of viscosity and surface tension of the agent is reported in this paper. The mechanism of the humidification and friction process of the AAS was investigated, and related experiments were also carried out to verify the mechanism of analysis. The results confirm that the AAS can attach the fiber ends protruding out of a yarn body on the yarn surface and assist in twisting the fiber ends back into the interior of the yarn body, resulting in a significant reduction of the modified ring spun yarn hairiness. Moreover, the yarn hairiness is prominently reduced after the winding process. The experimental results also show that a speed ratio of 1.3 between the rotating speed of the cylinder and the output speed of the yarn leads to the greatest extent of harmful hairiness reduction (34%), which also corresponds to optimal modified yarn tenacity. Meanwhile, the modified ring spun yarns show a tight and smooth appearance, and the yarn evenness has no deterioration. In addition, the AAS is applicable to both cotton and viscose yarns with different yarn counts. Therefore, the AAS can potentially be used to reduce yarn hairiness for ring spun yarns and enhance the quality of ring spun yarns in the textile industry.
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Xia, Zhigang, Xin Liu, KeZuo Wang, Bo Deng, and Weilin Xu. "A novel analysis of spun yarn hairiness inside limited two-dimensional space." Textile Research Journal 89, no. 21-22 (April 10, 2019): 4710–16. http://dx.doi.org/10.1177/0040517519841368.

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Surface hairiness of spun yarns is critical to the yarn post-processing deficiency and resultant fabric quality. Several test methods are available for measuring yarn hairiness but they cannot detect the accurate hair amount and precise hair length. This paper provides a novel method to perform accurate hairiness tests on the spun yarn. A new test apparatus was devised by installing a blowing pipe outside of the hairiness testing area comprising a projection receiver and a corresponding laser. The rectangle end plane of the blowing pipe air inlet is vertical to the laser plane and tangent to the edge line of the projection receiver surface. Pressure generated through this inlet stretches yarn wild hairiness straightly in one direction, and fully maps accurate hairiness amount and length configuration on the projection receiver surface. The subsequent measurement showed that this novel test apparatus detected more hairiness with improved accuracy in both number and length of hairiness. Approximately real gravimetric hairiness weight can be obtained by this method which is impracticable for other conventional photoelectric apparatus.
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Mirzaei, Majid, Ali Akbar Gharehaghaji, and Mohammad Zarrebini. "A new method of yarn hairiness reduction by air suction during carding." Textile Research Journal 82, no. 20 (July 26, 2012): 2128–36. http://dx.doi.org/10.1177/0040517512447586.

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Yarn hairiness has remained an issue of enormous interest in the field of yarn spinning research, since it directly affects yarn quality. In this work, a new method for the reduction of yarn hairiness is presented by attaching a simple effective air suction system to the web detaching zone of a conventional carding machine immediately behind crushing rollers. The slivers produced were almost free from dust or short loose fibers. Yarn properties such as hairiness, tenacity, elongation at break and evenness were evaluated. The ring-spun yarn that was produced was called Vacuum Cleaned Carded yarn or VCC yarn, due to the removal of the short fibers by air suction. The properties of VCC yarns were compared with those of conventionally produced reference yarn sample. Comparison of the results showed that the hairiness of optimum VCC yarn decreases by approximately 20%, while its tenacity, elongation at break and evenness were significantly improved. It was also found that the VCC yarn exhibited better spinning stability and was more environmentally friendly than the reference yarn.
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Viswanathan, G., V. G. Munshi, A. V. Ukidve, and K. Chandran. "Comparative Evaluation of Yarn Hairiness by Different Methods." Textile Research Journal 58, no. 8 (August 1988): 477–79. http://dx.doi.org/10.1177/004051758805800808.

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Using a rapid yarn hairiness tester, the Shirley yarn hairiness meter, this work has confirmed that for cotton yarns, the statistical distribution of the number of protruding ends of different lengths is exponential. The study indicates that, compared to the other hair length settings available on the hairiness meter, the recommended 3 mm hair length is suitable and advantageous. Further there is a high correlation between the Shirley hairiness meter and two other hairiness indices, the modified Jedryka and the Digital fibrograph, considered in this work.
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Gorjanc, Dunja Šajn, and Neža Sukič. "Determination of Optimum Twist Equation for the Long Staple Combed Cotton Ring-Spun Yarn." Fibers 8, no. 9 (September 21, 2020): 59. http://dx.doi.org/10.3390/fib8090059.

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The aim of this research was to determine the optimum twist equation for ring-spun yarns. The yarn twist can be calculated by different equations. With the research, we tried to find the appropriate equation to determine the yarn twist, which is determined by the values of yarn strength and hairiness. In the research, yarns from long staple combed cotton rovings and of different fineness (10 tex, 11.8 tex, 20 tex and 29.4 tex) were analyzed. The yarn twist was calculated using the equations of Koechlin and Laetsch. The analyzed yarns were produced in the spinning mill on the laboratory ring spinning machine Spinntester. In the second part of the investigation, yarn strength and hairiness were analyzed as a function of yarn twist. The results showed that Laetsch’s equation is suitable for determining the twist for yarns with a fineness of 10 tex, 11.8 tex, 20 tex and 29.4 tex, since, in this case, the calculated number of yarn threads is higher and thus the strength and elongation at break are also higher. The yarn hairiness is higher in analyzed samples for yarns with the twist calculated according to the Koechlin’s equation.
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Moučková, Eva, Iva Mertová, Petra Jirásková, Gabriela Krupincová, and Dana Křemenáková. "Properties Of Viscose Vortex Yarns Depending On Technological Parameters Of Spinning." Autex Research Journal 15, no. 2 (June 1, 2015): 138–47. http://dx.doi.org/10.2478/aut-2014-0046.

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AbstractThis paper analyzes the relationship between technological parameters of spinning of 100% CV Vortex yarns of different counts and its selected geometrical parameters (a lead of helix of wrapping fibre ribbon, yarn diameter) as well as yarn properties. The number of twist of wrapping fibre layer is determined. The effect of the yarn delivery speed, hollow spindle diameter, and the main draft on the hairiness, mass irregularity, tenacity, elongation, resistance to abrasion and bending rigidity of Vortex yarn is observed. The yarn properties are compared with the properties of open-end rotor spun yarns. Slivers of the same spinning lot were used for the production of both kinds of yarn. The results showed that the delivery speed in combination with spindle diameter affects yarn diameter, hairiness and abrasion resistance. Mass irregularity and imperfections of yarn is mainly affected by the main draft of drafting unit. Technological parameters of spinning do not affect the level of bending rigidity of the Vortex yarn. Tested rotor spun yarns had a larger diameter, higher hairiness, lower tenacity and higher elongation, lower mass irregularity and number of imperfections, higher abrasion resistance and lower bending rigidity compared to tested Vortex spun yarns.
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Ma, Chongqi, Xinlong Li, and Baoming Zhou. "Investigation of Mechanical and Physical Properties of Far-Infrared Tencel/Acrylic and Far-Infrared Tencel/Cotton Blended Ring-Spun Yarns." Journal of Engineered Fibers and Fabrics 10, no. 3 (September 2015): 155892501501000. http://dx.doi.org/10.1177/155892501501000311.

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It has been a universal method to obtain better-property yarns by blending different kinds of fibers together. This study, was aimed to investigate the mechanical and physical properties of far-infrared tencel/acrylic (FIT/A) and far-infrared tencel/cotton (FIT/C) blended ring-spun yarns. Yarn samples with five different blend ratios (100/0, 65/35, 50/50, 35/65, 0/100) were spun as 19.7 tex on a ring spinning system. The elongation, breaking strength, yarn irregularity, and hairiness of the two sets of blended yarns were analyzed using the simple rule of mixtures (ROM) and generalized rule of mixtures (GROM). The results show that acrylic blended yarns show higher elongation values, similar breaking strength, lower yarn irregularity values, and higher hairiness values compared to cotton blended ones. In addition, the interactions between the two fibers in both the two sets of yarns have a positive effect on yarn elongation, breaking strength, and yarn irregularity; but a negative effect on the hairiness with a different degree.
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Dissertations / Theses on the topic "Yarn hairiness"

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Chang, Lingli, and mikewood@deakin edu au. "An investigation of yarn hairiness." Deakin University. School of Engineering and Technology, 2002. http://tux.lib.deakin.edu.au./adt-VDU/public/adt-VDU20060823.141926.

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Yarn hairiness affects not only the quality of products, but also the productivity in spinning and weaving. Too much yarn hairiness is undesirable for many end uses as well as the spinning and post spinning processes. The main aims of this project are to examine the hairiness features of various yarns and to reduce yarn hairiness. The thesis covers five related areas – hairiness assessment, factors affecting yarn hairiness, the hairiness of newly developed yarns, yarn hairiness reduction, and effect of yarn hairiness on the energy consumption in ring spinning. The worsted cashmere, pure wool and wool/cashmere blend yarns were employed to investigate the effect of some fibre parameters on the yarn hairiness. A single exponential distribution of the hair-length was confirmed first, using the data from the Zweigle G565 Hairiness Meter. A linear relationship was observed between the blend ratio and the hairiness indexes. In particular, the effect of fibre crimp or curvature on yarn hairiness is examined. The theory of yarn hairiness composition was also developed further. The effect of draft ratio and spindle speed on the hairiness of worsted wool yarn was examined next with a factorial experiment design. Several new hairiness indexes, namely the relative hairiness indexes, have been used to explain the results obtained. In the investigation of the hairiness of newly developed yarns, the hairiness of the Compact Spun and Roller-Jet-Spun yarns was examined first. The composition of the yarn hairiness, the hair-length distribution, and the effect of test speed on yarn hairiness were then studied. An important finding is that for both yarns, the predominant hairiness feature is the looped hairs. A comparison of the hairiness of Solospun yarns and the equivalent ring spun wool yarns was undertaken. The hair-length distribution of the Solospun yarn was examined first. The Solospun yarns used had fewer hairs in most hair-length groups and lower variations in hairiness. In addition, the effect of twist level and spindle speed on the hairiness of Solospun and conventional ring spun yarns has also been discussed. A novel approach of reducing yarn hairiness – spinning with a ‘Diagonal’ yarn path was examined next. Both ‘Left Diagonal’ and ‘Right Diagonal’ yarn arrangements were studied. A new finding is that the ‘Right Diagonal’ yarn path leads to reduced hairiness for the Z-twist yarn, while yarn evenness and tenacity are not as sensitive to the modified yarn path. The mechanism of hairiness reduction with the ‘Diagonal’ yarn path has been discussed. The spinning performance of “Right Diagonal” yarn arrangement has also been evaluated. Finally, the effect of yarn hairiness on the energy consumption in ring spinning has been investigated theoretically and experimentally. A theoretical model has been developed, which represents the first attempt at theoretically investigating the influence of yarn hairiness on energy consumption during the winding stage of ring spinning. The experimental results have generally confirmed predictions of this model. Recommendations for further research in this area have also been made in the concluding chapter of this thesis.
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Souza, Clara Silvestre de. "Varia??o de temperatura e umidade e suas influ?ncias nas caracter?sticas f?sicas e mec?nicas dos fios de algod?o." Universidade Federal do Rio Grande do Norte, 2011. http://repositorio.ufrn.br:8080/jspui/handle/123456789/15715.

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Made available in DSpace on 2014-12-17T14:58:22Z (GMT). No. of bitstreams: 1 ClaraSS_DISSERT.pdf: 3432218 bytes, checksum: 7e008670903eeebdf6b98724b154b050 (MD5) Previous issue date: 2011-10-03
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Cotton is a hydrofilic textile fiber and, for this reason, it changes its properties according to the environment changes. Moisture and Temperature are the two most important factors that lead a cotton Spinning sector and influence its quality. Those two properties can change the entire Spinning process. Understanding this, moisture and temperature must be kept under control when used during the Spinning process, once the environment is hot and dry, the cotton yarns absorb moisture and lose the minimal consistency. According to this information, this paper was developed testing four types of cotton yarns, one kind of cotton from Brazil and the others from Egypt. The yarns were exposed to different temperatures and moisture in five different tests and in each test, six samples that were examined through physical and mechanical tests: resistance, strength, tenacity, yarn?s hairness, yarn?s evenness and yarn?s twisting. All the analysis were accomplished at Laborat?rio de Mec?nica dos Flu?dos and at COATS Corrente S.A., where, it was possible to use the equipments whose were fundamental to develop this paper, such as the STATIMAT ME that measures strength, tenacity, Zweigler G566, that measure hairiness in the yarn, a skein machine and a twisting machine. The analysis revealed alterations in the yarn?s characteristics in a direct way, for example, as moisture and temperature were increased, the yarn?s strength, tenacity and hairness were increased as well. Having the results of all analysis, it is possible to say that a relatively low temperature and a high humidity, cotton yarns have the best performance
O algod?o ? uma fibra t?xtil hidr?fila e por essa raz?o muda suas caracter?sticas em fun??o das condi??es do ambiente. A umidade e a temperatura s?o dois fatores que influenciam o ambiente de uma fia??o de algod?o. Estes dois fatores podem alterar a qualidade de toda uma produ??o de fios. Sendo assim, umidade e temperatura devem ser mantidas sob o controle para o processamento do algod?o, uma vez que em um ambiente seco e quente os fios de algod?o liberam umidade e se rompem, aumentando o ?ndice de quebra da fia??o com o ambiente frio e ?mido, os fios absorvem umidade e perdem a consist?ncia m?nima.Com base nessas informa??es, este trabalho foi desenvolvido experimentando quatro tipos de fio de algod?o sendo de origem brasileira e os demais, de origem eg?pcia. Os fios foram expostos a temperatura e umidade diferentes em cinco experimentos distintos, contendo cada experimento seis amostras que passaram por testes f?sicos e mec?nicos: resist?ncia, for?a, tenacidade, pilosidade, t?tulo e tor??o. As an?lises foram realizadas no Laborat?rio de Mec?nica dos Fluidos na Universidade Federal do Rio Grande do Norte e na empresa COATS Corrente S.A., onde foi poss?vel fazer uso dos equipamentos fundamentais para o desenvolvimento deste trabalho, tais como o STATIMAT ME que mede a resist?ncia, for?a e tenacidade do fio, Zweigler G566 o qual mensurou a quantidade de pilosidade no fio e, a meadeira e o torc?metro, respons?veis pelo t?tulo e tor??o. As an?lises revelaram altera??es nas caracter?sticas dos fios de forma diretamente proporcional, como por exemplo, conforme aumentava-se a umidade e temperatura havia um aumento da resist?ncia, for?a, tenacidade e pilosidade. Em posse desses resultados, ? poss?vel afirmar que a uma temperatura relativamente baixa e uma umidade alta, os fios de algod?o tem sua performance m?xima
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Huang-Chin, Hung, and 洪滉進. "A Study of Reducing Yarn Hairiness on Ring Spinning with Air Vortex Nozzle." Thesis, 2003. http://ndltd.ncl.edu.tw/handle/60720613750392423174.

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碩士
國立臺灣科技大學
高分子工程系
91
In this study,an air vortex nozzle is installed below the front roller of conventional ring spinning machine,a fiber strand passes through it before the yarn is formed completely. After treating by air vortex,we can improve yarn hairiness. In first stage, we used 100% Lyocell rovings,with the fiber length of 88mm to produce air-ring yarn.We had found the optimum conditions by Taguchi Method.When the ring-spun and air-ring yarn were produced and ready for property test,Zweigle G565 were used to measure their yarn hairiness.It is found that the number of hairs which exceeds 3mm protruding from the yarn is 50% less than that of the conventional ring yarn. In second stage,we used the improved air nozzle which was installed in the same position as mentioned to spin air-ring yarn in cotton and wool spinning system.We can find that, in cotton spinning, the yarn hairiness reduced percentage with 100% cotton yarn is 58.6% ,100% Rayon yarn is 74.6% ,T/C 65/35 is 31.4% ,T/R 65/35 is 40.9%. In wool spinning system, the yarn hairiness reduced percentage with 100% wool yarn is 17%, A/W 50/50 is 24.5% ,N/W 50/50 is 26.3%. In addition,a lower lever of yarn twist is Required for this new spinning system ,and a better efficiency of yarn production can be obtained by it.
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Books on the topic "Yarn hairiness"

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Barella, A. Yarn hairiness: A further update. Manchester: Textile Institute, 2002.

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Harrison, P. W. The hairiness of yarns. Manchester: Textile Institute, 1993.

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Barella, A. The effect of fibre parameters on the hairiness of ring-spun and rotor-spun cotton yarns. Port Elizabeth: South African Wool and Textile Research Institute, 1988.

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Yarn Hairiness Update (Textile Progress,). North Carolina State University, 1996.

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Barella, A. The Hairiness of Yarns (Textile Progress,). North Carolina State University, 1993.

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Book chapters on the topic "Yarn hairiness"

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Zhao, Bo. "Study on Hairiness of Polyester/Cotton Blended Yarn in Rotor Spinning Via Artificial Neural Network Theory." In Lecture Notes in Electrical Engineering, 487–94. London: Springer London, 2013. http://dx.doi.org/10.1007/978-1-4471-4853-1_61.

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Bo, Zhao. "A Prediction Model Based on Linear Regression and Artificial Neural Network Analysis of the Hairiness of Polyester Cotton Winding Yarn." In Advances in Intelligent and Soft Computing, 97–103. Berlin, Heidelberg: Springer Berlin Heidelberg, 2011. http://dx.doi.org/10.1007/978-3-642-25989-0_18.

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"Control Of Yarn Hairiness In Spun Yarns." In Process Control and Yarn Quality in Spinning, 319–36. WPI Publishing, 2016. http://dx.doi.org/10.1201/b18797-12.

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Majumdar, A. "Yarn hairiness and its reduction." In Technical Textile Yarns, 112–39. Elsevier, 2010. http://dx.doi.org/10.1533/9781845699475.1.112.

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Conference papers on the topic "Yarn hairiness"

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Carvalho, Vitor H., Paulo J. Cardoso, Rosa M. Vasconcelos, Filomena O. Soares, and Michael S. Belsley. "Optical Yarn Hairiness Measurement System." In 2007 5th IEEE International Conference on Industrial Informatics. IEEE, 2007. http://dx.doi.org/10.1109/indin.2007.4384783.

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Roy, Subhasish, Anindita Sengupta, and Surajit Sengupta. "Yarn hairiness evaluation using image processing." In 2014 International Conference on Control, Instrumentation, Energy and Communication (CIEC). IEEE, 2014. http://dx.doi.org/10.1109/ciec.2014.6959157.

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Carvalho, Vitor, Filomena Soares, Rosa Vasconcelos, Michael Belsley, and Nuno Goncalves. "Yarn hairiness determination using image processing techniques." In Factory Automation (ETFA 2011). IEEE, 2011. http://dx.doi.org/10.1109/etfa.2011.6059217.

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Bo, Zhao. "Predicting Cotton Yarn Hairiness in Rotor Spinning." In 2010 International Conference on Optoelectronics and Image Processing (ICOIP). IEEE, 2010. http://dx.doi.org/10.1109/icoip.2010.264.

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Xu, Bugao, Lei Wang, and Weidong Gao. "3D measurement of yarn hairiness via multi-perspective images." In Optics, Photonics and Digital Technologies for Imaging Applications, edited by Peter Schelkens, Touradj Ebrahimi, and Gabriel Cristóbal. SPIE, 2018. http://dx.doi.org/10.1117/12.2307844.

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Kuzanski, Marcin, and Lidia Jackowska-Strumillo. "Yarn hairiness determination the algorithms of computer measurement methods." In Perspective Technologies and Methods in MEMS Design, MEMSTECH 2007. III International Conference of Young Scientists. IEEE, 2007. http://dx.doi.org/10.1109/memstech.2007.4283454.

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Zhao Bo. "Predicting the hairiness of cotton yarn in winding process." In 2010 International Conference on Educational and Network Technology (ICENT 2010). IEEE, 2010. http://dx.doi.org/10.1109/icent.2010.5532278.

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Carvalho, V., P. Cardoso, M. Belsley, R. M. Vasconcelos, and F. O. Soares. "Development of a Yarn Evenness Measurement and Hairiness Analysis System." In IECON 2006 - 32nd Annual Conference on IEEE Industrial Electronics. IEEE, 2006. http://dx.doi.org/10.1109/iecon.2006.347502.

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Bo, Zhao. "Neural Network for Prediction of Hairiness of Ring Spun Cotton Yarn." In 2011 International Conference on Information Technology, Computer Engineering and Management Sciences (ICM). IEEE, 2011. http://dx.doi.org/10.1109/icm.2011.386.

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Bo, Zhao. "Prediction of Hairiness of Polyester/Viscose/Cotton Blended Ring Spinning Yarn." In 2010 International Conference on Optoelectronics and Image Processing (ICOIP). IEEE, 2010. http://dx.doi.org/10.1109/icoip.2010.263.

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