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140122 ||| eng |
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|a 9783642975363
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| 100 |
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|a Mahall, Karl
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| 245 |
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|a Quality Assessment of Textiles
|h Elektronische Ressource
|b Damage Detection by Microscopy
|c by Karl Mahall
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| 250 |
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|a 1st ed. 1993
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| 260 |
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|a Berlin, Heidelberg
|b Springer Berlin Heidelberg
|c 1993, 1993
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| 300 |
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|a XVI, 227 p
|b online resource
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|a 4.3 Thermal Damage to Synthetic Fibers due to Impact -- 4.4 Thermal Deformation of Synthetic Fibers Due to Cutting, Punching and Sewing -- 5 Streaks and Bars in Textile Fabrics Due to Yarn Differences and Technological Reasons -- 5.1 Streaks Due to Variations in the Yarn Volume or Yarn Count -- 5.2 Streaks and Bars Parallel to Threads Due to Yarn Mixture Errors -- 5.3 Streak and Bar Formation Due to Other Yarn-Related Influences -- 5.4 Streaks in Pile Goods -- 6 Causes of the Formation of Tight Threads and Their Effects -- 6.1 Tight Threads in Wool Fabrics Caused by Uneven Yarn Moisture -- 6.2 Tight Picks in a Fabric Made of Viscose- Practical Example -- 6.3 Tight Threads Caused by Different Yarn Twist - Practical Example -- 7 Defects Caused by Deposits and Encrustations on the Fiber Material -- 7.1 Detection of Oil, Grease, Paraffin or Wax Deposits by Means of Dyeing with Oil-Soluble Dyes -- 7.2 Detection of Oil, Grease, Wax and Paraffin Deposits by Means of Film Imprints --
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|a Appendix: Technical Equipment, Chemicals, Reagents and Dyes for the Microscopic Damage Analysis
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|a 7.3 Detection of Pigment Deposits on Imprints -- 7.4 Detection of Film-Forming Products and Film-Like Deposits by Means of Imprints -- 7.5 Detection of Deposits in Staining Tests, Yarn Cross-Sections and/or Fabric Cross-Sections -- 8 Other Defects in the Quality of Textiles -- 8.1 Skittery Dyed Wool Yarn - Practical Example -- 8.2 Uneven Wool Printing - Practical Example -- 8.3 Small Light Spots Caused by Trapped Air Bubbles During the Dyeing of Wound Packages -- 8.4 Dye Unlevelness in Polyester Knitwear Caused by Water Drops - Practical Example -- 8.5 Dye Unlevelness Within a Spinning Lot Due to Separation of the Fiber Components - Practical Example -- 8.6 Darker Specks of Dyed Feather Bed Ticking Due to Non- Decomposed Seed Husks - Practical Example -- 8.7 Spots Due to Dark-Dyed Fly Fibers - Practical Example -- 8.8 Red Specks Due to Dyed, Melted and Flat-Rolled Man-Made Fly Fibers on a White Viscose Staple Fabric --
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|a Fundamentals and Priming -- 1.1 Necessary Equipment -- 1.2 Preliminary Examination of Textile Test Material -- 1.3 Classical Examination Methods -- 1.4 Preparation of Negative Imprints with the Size of Microscope Slides -- 1.5 Preparation of Negative Imprints of Fibers and Yarns on Thermoplastic Films -- 1.6 Imprints of Larger Areas -- 1.7 Microtome Sections -- 2 Chemical Damage -- 2.1 Chemical Damage to Wool -- 2.2 Chemical Damage to Silk -- 2.3 Chemical Damage to Cotton -- 2.4 Chemical Damage to Synthetics -- 3 Mechanical Damage -- 3.1 Mechanical Damage to Wool -- 3.2 Mechanical Damage to Silk -- 3.3 Mechanical Damage to Cotton -- 3.4 Mechanical Damage to Cellulose Regenerated Fibers Graying During Dyeing on the Winch - Practical Example -- 3.5 Mechanical Damage to Synthetic Fibers -- 4 Thermal and Thermo-Mechanical Damage to Synthetics -- 4.1 Thermal Damage Caused by Direct Heat -- 4.2 Thermal Deformation of Synthetic Fibers Due to Frictional Heat --
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|a 8.9 Light, Undyed Short Bristly Fibers in a Wool Yarn - Practical Example -- 8.10 Gray, Dot-Like Stains on Needlefelt Sheets - Practical Example -- 8.11 Running Marks in a Cotton Tricot Fabric - Practical Example -- 8.12 Shade Differences in Dress Fabrics Due to Different Hairiness - Practical Example -- 8.13 Brittle, Dope-Dyed Acrylic Fiber Material on the Carding Machine and Drawing Frames - Practical Example -- 8.14 Light Specks in a Milled Terry Towelling Fabric Due to Dead Cotton - Practical Example -- 8.15 Bonded Yarns in a Cotton Cross-Wound Bobbin - Practical Example -- 8.16 Knitted Goods Sticking Together in Garment Production Due to Hairiness of Cotton Yarn - Practical Example -- 8.17 Cotton Fabrics With Side-to-Center Shading Due to Uneven Squeezing Effects - Practical Example -- 9 Microbiological Damage to Fibers -- 9.1. Damage Caused by Fungi -- 9.2 Damage Caused by Bacteria -- References -- Figures --
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| 653 |
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|a Polymers
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| 653 |
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|a Machines, Tools, Processes
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| 653 |
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|a Manufactures
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| 653 |
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|a Materials / Analysis
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| 653 |
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|a Characterization and Analytical Technique
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|a eng
|2 ISO 639-2
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| 989 |
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|b SBA
|a Springer Book Archives -2004
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| 028 |
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|a 10.1007/978-3-642-97536-3
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| 856 |
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|u https://doi.org/10.1007/978-3-642-97536-3?nosfx=y
|x Verlag
|3 Volltext
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| 082 |
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|a 620.112
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| 520 |
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|a Quality is the decisive criterion by which textile industry is measured in the international competition. Today this is particularly true. Short fashion cycles lead to frequent article changes in production, technologi cal progress requires continual adaptation of the production processes; high and above all constant quality of the textiles remains an indispensable require ment. Today, quality is no longer (mis)understood as the result of quality con trol or successful fault correction, but as the logical result of all chemical and physical or human interventions in the production process; their registration and representation in the form of quality management systems becomes more and more important. Especially in the multi -stage process of textile production and textile finishing, often carried out by several specialized companies, it is very difficult to trace back quality deficiencies in textiles - in particular hidden faults - to their true cause. However, this is the precondition to efficiently eliminate faults and to guarantee correct process control. In his book Karl Mahall describes the damage which can occur in certain fibrous raw materials and during production and storage of textiles; for this purpose he has carefully chosen typical practical examples which he encountered in connec tion with textile auxiliaries during the 40 years which he has been working for the Henkel KGaA. In particular it is demonstrated how microscopic test methods can provide decisive hints at the cause of hidden faults in textiles
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