Online Control of Knitted Fabric Quality: Loop Length Control
Circular knitting machine makes the fabric with more than two knitting tools. Variation of yarn tension between different knitting tools causes different loop length of stitches duration knitting process. In this research, a new intelligent method is applied to control loop length of stitches in various tools based on ideal shape of stitches and real angle of stitches direction while different loop length of stitches causes stitches deformation and deviation those of angle. To measure deviation of stitch direction against variation of tensions, image processing technique was applied to pictures of different fabrics with constant front light. After that, the rate of deformation is translated to needed compensation of loop length cam degree to cure stitches deformation. A fuzzy control algorithm was applied to loop length modification in knitting tools. The presented method was experienced for different knitted fabrics of various structures and yarns. The results show that presented method is useable for control of loop length variation between different knitting tools based on stitch deformation for various knitted fabrics with different fabric structures, densities and yarn types.
[1] Iyer I., Mammel B., Schach J., Circular knitting: technology process
structure yarn quality, Second Edition, Meisenbach GmbH, Bambreg,
Germany, 1957.
[2] Jensen K.L. and Carstensen M., "Fuzz and Pills Evaluated on Knitted
Textiles by Image Analysis", Textile Research Journal, 72(1), 34 - 50,
2002.
[3] Ghazi Saeidi R., Latifi M., Shaikhzadeh Najar S., and Ghazi Saeidi A.,
"Computer Vision-Aided Fabric Inspection System for On-Circular
Knitting Machine" Textile Research Journal, 75(6), 492-497, 2005.
[4] Sirikasemlert A. and Tao X., "Objective Evaluation of Textural Changes
in Knitted Fabrics by Laser Triangulation" Textile Research Journal,
70(12), 1076 - 1087, 2000.
[5] Celik O., Ucar N. and Ertugrul S., "Determination of spirality in knitted
fabrics by image analysis", Fibers and Textiles in Eastern Europe,
13(3), 47-49, 2005.
[6] Knapton, J.J.F, Truter E. V. and Aziz A.K.M.A., "The geometry,
dimensional properties and stabilization of the cotton plain-knit fabrics",
Journal of the textile Institute, 66, 413-419, 1975.
[7] Shady E., Gowayed Y., Abouiiana M., Youssef S. and Pastore C.,
"Detection and Classification of Defects in Knitted Fabric Structures",
Textile Research Journal, 76(4),295-300, 2006.
[8] Slah M., Amine H. T. and Faouzi S., "A new approach for predicting the
knit global quality by using the desirability function and neural
networks", Journal of The Textile Institute, 97(1), 17-23, 2006.
[9] Abouiiana M., Youssef S., Pastore C. and Gowayed Y., "Assessing
structure changes in knits during processing", Textile Research Journal,
73(6), 535-540, 2003.
[10] Semnani D., Latifi M., Tehran M.A., Pourdeyhimi B., Merati A.A.,
"Effect of yarn appearance on apparent quality of weft knitted fabric",
Journal of The Textile Institute, 96(5), 259-301, 2005.
[11] Sakaguchi A., Wen G. H., Matsumoto Y. I., Toriumi K., Kim H., "Image
analysis of woven fabric surface irregularity", Textile Research Journal,
71(8), 666-671, 2001.
[12] Sawhney, "A novel technique for evaluation the appearance of a cotton
fabric", Textile Research Journal, 70(7), 563-567, 2000.
[13] Kang T. J., Choi S. H., Kim S. M. and Oh K. W., "Automatic structure
analysis and objective evaluation of woven fabric using image analysis",
Textile Research Journal, 71(3), 261-270, 2001.
[14] Chiun H.C. and Chun C.I., "Neural-Fuzzy Classification for Fabric
Defects", Textile Research Journal, 71, 220-224, 2001.
[15] Zhang Y.F., Bresee, R. R., "Fabric Detection and Classification Using
Image Analysis", Textile Research Journal, 65(1), 1-9, 1995.
[16] Wood E., "Applying Fourier and Associated Transforms to Pattern
Characterization in Textiles", Textile Research Journal, 60, 212-220,
1991.
[17] Mallik-Goswami B. and Datta A.K, "Defect Detection in Fabrics with a
Joint Transform Correlation Technique: Theoretical Basis and
Simulation", Textile Research Journal, 69(11),. 829 - 835, 1999.
[18] Hu M.C. and Tsai I.S., "Fabric Inspection Based on Best Wavelet Packet
Bases", Textile Research Journal, 70(8), 662 - 670, 2000.
[19] Mallik-Goswami B. and Datta A.K.,"Detecting Defects in Fabric with
Laser-Based Morphological Image Processing", Textile Research
Journal,70 (9), 758 - 762, 2000.
[20] Thibault X. and Bloch J.F., "Structural Analysis by X-Ray
Microtomography of a Strained Nonwoven Papermaker Felt", Textile
Research Journal, 72(6), 480 - 485, 2002.
[21] Canny, John. "A Computational Approach to Edge Detection", IEEE
Transactions on Pattern Analysis and Machine Intelligence, 8(6), 679-
698, 1986.
[22] Strack, L., Image Processing and data analysis, Cambridge University
Press, England, 1998.
[23] Zadeh L.A., "Fuzzy sets", Inform. and Control, 8, 338-353, 1695.
[24] H.J. Zimmermann, Fuzzy Set Theory and its Applications, 2nd edition.,
Kluwer Academic Publishers, Boston.
[25] Takagi, T. and Sugeno, M., "Fuzzy identification of systems and its
applications to modeling and control", IEEE Transactions on
SystemsMan and Cybernetics, 15(1) 116-132, 1985.
[1] Iyer I., Mammel B., Schach J., Circular knitting: technology process
structure yarn quality, Second Edition, Meisenbach GmbH, Bambreg,
Germany, 1957.
[2] Jensen K.L. and Carstensen M., "Fuzz and Pills Evaluated on Knitted
Textiles by Image Analysis", Textile Research Journal, 72(1), 34 - 50,
2002.
[3] Ghazi Saeidi R., Latifi M., Shaikhzadeh Najar S., and Ghazi Saeidi A.,
"Computer Vision-Aided Fabric Inspection System for On-Circular
Knitting Machine" Textile Research Journal, 75(6), 492-497, 2005.
[4] Sirikasemlert A. and Tao X., "Objective Evaluation of Textural Changes
in Knitted Fabrics by Laser Triangulation" Textile Research Journal,
70(12), 1076 - 1087, 2000.
[5] Celik O., Ucar N. and Ertugrul S., "Determination of spirality in knitted
fabrics by image analysis", Fibers and Textiles in Eastern Europe,
13(3), 47-49, 2005.
[6] Knapton, J.J.F, Truter E. V. and Aziz A.K.M.A., "The geometry,
dimensional properties and stabilization of the cotton plain-knit fabrics",
Journal of the textile Institute, 66, 413-419, 1975.
[7] Shady E., Gowayed Y., Abouiiana M., Youssef S. and Pastore C.,
"Detection and Classification of Defects in Knitted Fabric Structures",
Textile Research Journal, 76(4),295-300, 2006.
[8] Slah M., Amine H. T. and Faouzi S., "A new approach for predicting the
knit global quality by using the desirability function and neural
networks", Journal of The Textile Institute, 97(1), 17-23, 2006.
[9] Abouiiana M., Youssef S., Pastore C. and Gowayed Y., "Assessing
structure changes in knits during processing", Textile Research Journal,
73(6), 535-540, 2003.
[10] Semnani D., Latifi M., Tehran M.A., Pourdeyhimi B., Merati A.A.,
"Effect of yarn appearance on apparent quality of weft knitted fabric",
Journal of The Textile Institute, 96(5), 259-301, 2005.
[11] Sakaguchi A., Wen G. H., Matsumoto Y. I., Toriumi K., Kim H., "Image
analysis of woven fabric surface irregularity", Textile Research Journal,
71(8), 666-671, 2001.
[12] Sawhney, "A novel technique for evaluation the appearance of a cotton
fabric", Textile Research Journal, 70(7), 563-567, 2000.
[13] Kang T. J., Choi S. H., Kim S. M. and Oh K. W., "Automatic structure
analysis and objective evaluation of woven fabric using image analysis",
Textile Research Journal, 71(3), 261-270, 2001.
[14] Chiun H.C. and Chun C.I., "Neural-Fuzzy Classification for Fabric
Defects", Textile Research Journal, 71, 220-224, 2001.
[15] Zhang Y.F., Bresee, R. R., "Fabric Detection and Classification Using
Image Analysis", Textile Research Journal, 65(1), 1-9, 1995.
[16] Wood E., "Applying Fourier and Associated Transforms to Pattern
Characterization in Textiles", Textile Research Journal, 60, 212-220,
1991.
[17] Mallik-Goswami B. and Datta A.K, "Defect Detection in Fabrics with a
Joint Transform Correlation Technique: Theoretical Basis and
Simulation", Textile Research Journal, 69(11),. 829 - 835, 1999.
[18] Hu M.C. and Tsai I.S., "Fabric Inspection Based on Best Wavelet Packet
Bases", Textile Research Journal, 70(8), 662 - 670, 2000.
[19] Mallik-Goswami B. and Datta A.K.,"Detecting Defects in Fabric with
Laser-Based Morphological Image Processing", Textile Research
Journal,70 (9), 758 - 762, 2000.
[20] Thibault X. and Bloch J.F., "Structural Analysis by X-Ray
Microtomography of a Strained Nonwoven Papermaker Felt", Textile
Research Journal, 72(6), 480 - 485, 2002.
[21] Canny, John. "A Computational Approach to Edge Detection", IEEE
Transactions on Pattern Analysis and Machine Intelligence, 8(6), 679-
698, 1986.
[22] Strack, L., Image Processing and data analysis, Cambridge University
Press, England, 1998.
[23] Zadeh L.A., "Fuzzy sets", Inform. and Control, 8, 338-353, 1695.
[24] H.J. Zimmermann, Fuzzy Set Theory and its Applications, 2nd edition.,
Kluwer Academic Publishers, Boston.
[25] Takagi, T. and Sugeno, M., "Fuzzy identification of systems and its
applications to modeling and control", IEEE Transactions on
SystemsMan and Cybernetics, 15(1) 116-132, 1985.
@article{"International Journal of Information, Control and Computer Sciences:63628", author = "Dariush Semnani and Mohammad Sheikhzadeh", title = "Online Control of Knitted Fabric Quality: Loop Length Control ", abstract = "Circular knitting machine makes the fabric with more than two knitting tools. Variation of yarn tension between different knitting tools causes different loop length of stitches duration knitting process. In this research, a new intelligent method is applied to control loop length of stitches in various tools based on ideal shape of stitches and real angle of stitches direction while different loop length of stitches causes stitches deformation and deviation those of angle. To measure deviation of stitch direction against variation of tensions, image processing technique was applied to pictures of different fabrics with constant front light. After that, the rate of deformation is translated to needed compensation of loop length cam degree to cure stitches deformation. A fuzzy control algorithm was applied to loop length modification in knitting tools. The presented method was experienced for different knitted fabrics of various structures and yarns. The results show that presented method is useable for control of loop length variation between different knitting tools based on stitch deformation for various knitted fabrics with different fabric structures, densities and yarn types. ", keywords = "Circular knitting, Radon transformation, Knittedfabric, Regularity, Fuzzy control", volume = "1", number = "5", pages = "1465-6", }
