Post on 08-Apr-2015
WindingLimitations of Spinning Technology Progress in spinning – automation and productivity Despite of progress, it is still not possible to produce a
fault-free yarn Depending on the raw material and state of the
machinery park, there are about 20 to 100 events over a length of 1000 km yarn
Yarn exhibits a yarn faults every 1 to 5 km. Yarn faults – too thin, too thick, foreign fibre and dirty
places Spinning process leads to formation of disturbing
faults
1. Machine parts - worn out or out of tolerance
2. Contamination – trash, dust, seed coat fragments
3. Foreign materialThese yarn faults cause disruptions in subsequent
processes – productivity and qualityHence spinner has to fulfill the demand of fault free
yarn by two measures
1. Prevent origin of yarn faults by adequate measure- Choice of raw material, m/c maintenance and cleanliness in
mill
2. Remove yarn faults by the aid of yarn clearers - Winding process
Reasons for Disturbing Yarn Faults
Winding Machine
Objects of Winding:
1. Extraction of disturbing yarn faults
2. Conversion of smaller package to bigger
package
3. Waxing of the yarn during winding process
4. Clearing foreign fibres
5. Clearing of Polypropylene
6. Detection of off-standard bobbins
7. Monitoring frequent yarn faults
8. Monitoring & documentation of quality data
Passage of Yarn through Winding Machine
Yarn Faults
Textile industry is dividing the yarn faults in
1. Frequently occurring faults
- Tested on Evenness Tester
- Expressed per 1000 m of yarn
2. Seldom occurring defects
- detected & eliminated during winding
- expressed per 1,00,000 m of yarn
Difference between Frequent faults & Seldom occurring
defects is mainly larger mass or diameter deviation and size
Classification of Yarn Faults1. Neps• Faults that are less than 1cm and having a mass
increase of more than 100% are called Neps
• They are basically produced due to immature fibres / seed coat fragments in the raw material, very short entanglements of fibres and yarns.
2. Short Thick Places• Faults with a length of 1 cm to 8 cm and having
a mass increase of more than 100%
• These faults are basically produced due to short
fibres, improper draft control, bad piecing, flies in spinning
Neps
Short Thick
3. Long Thick Places• Faults with a length of more than 8 cm and
having a mass increase of more than 45% are called Long Thick places.
• These faults are basically produced due to thick places in sliver, roving etc.
4. Thin Places• Faults with a length of more than 8 cm and
having a mass decrease of more than 30% are called Thin places
• These faults are basically produced due to missing sliver in drawing, stretches in sliver and roving etc.
Long Thick
Long Thin
5. Count variations
• Faults with a length of several meters and
having a mass increase / decrease of more
than 5% are called count variations
6. Foreign matters
• Faults with a length of more than 1 mm and
visibility level of more than 5% are called
foreign matters
• They are primarily produced due to mix up
of colour fibres, jute, hair, seed particles etc.
Count
Foreign Fibres
Yarn Fault Classification Matrix
Fault length in (cm)
Fau
lt s
ize
(%)
Spectrum of Yarn Faults
Fault Length (cm)-100%
0
+100%
+200%
+300%
+400%+500%+600%
0.1 21 4 8 16 32 64 . . . . . . . .
Unevenness
Imperfections
Short Thick Places
Long Thick Places
Long Thin Places
Basic setting of N S L T For an easy setting of clearing limits Thick places are divided in to
NSL classes and Thin place expressed as T N – channel - Less than 1 cm (to clear nep faults)
S – channel – 1.0 to 8.0 cm (to clear short thick place faults)
L - channel – up to 200 cm (to clear long thick place faults)
T - channel – up to 200 cm (to clear thin place faults)
Class Clearing Curve
Electronic Yarn Clearing
Yarn Faults Removing Principle1.Yarn faults monitored by an
electronic device
2.As soon as yarn clearer detects a
yarn fault, the yarn will be
separated by the cutter
interrupting winding
3.Yarn fault removed by the suction
of the winding machine
4.Yarn splicing or knotting
5.Winding process continues up to
next fault
Yarn Fault Measuring Principle• Thickness of the yarn monitored and converted into a
proportional electrical voltage signal• Sensor monitors a yarn running up to 120 km/hr and , the
yarn is measured every 2 mm• Signal conversion is carried by – Capacitive measuring principle or Optical measuring principle
1. Electrical measuring condenser
2. Two electrodes
3. Electrical alternating voltage
4. Yarn
5. Electrical signal
Capacitive Measuring Principle
Electrical signal corresponds to the yarn cross-section yarn mass
Changes of the yarn mass cause a proportional change of signal
1. Infrared light source
2. Diffuser
3. Photocell
4. Yarn
5. Electrical signal
Optical Measuring Principle
Electrical signal corresponds to the diameter of the usually round yarn
Changes in yarn diameter cause a proportional change of signal
• Cotton can be contaminated the cotton field to the spinning mill
• Human and animal hair, feathers, strings, packing material, stems, leaves and oil stains
• Foreign fibers –cause fabric defect, lower the efficiency of the following processes
Foreign Fiber Clearing
Detection of Foreign and Polypropylene Fibers
• Optical measuring system
• Comparison between the reflection of the foreign fiber and the normal yarn color
Classification Matrix - Uster
Classification Matrix - Loepfe