BALE MANAGEMENT
The function of Bale Management is very much unique to the Spinning Industry. The module should have a function in such a way that the system should automatically generate the issues for Mix or a Count, where all the Lay down or Issues should have a consistent quality parameter both in terms of average and SD.The system should be capable of generating the Issues or Lay down as per the User requirements like:
- Standard Distribution – The average Quality of all Parameters are same from the first issue to the final issue.
- Normal Distribution – The Issue should contain the required average for the selected Quality parameters and it should follow the theory of normal distribution.
- Moving point distribution – If the user prefers to have a very narrow working range for the selected Quality parameter, the system should generate the issue and according to the availability the shift in the parameter should happen gradually till all the bales are exhausted in the Lot. For example if the User would like to have the Micronaire working range of 4.2 to 4.6. After exhausting the bales in 4.6 Micronaire, the system should automatically shift to 4.1 to 4.5. After exhausting 4.5, the system should go for 4.0 to 4.4.
Factors considered for efficient Bale management system:
- Origin (Country of origin)
- Length & Length uniformity
- Fibre fineness (MIC value, ugm/inch)
- Strength & Elongation
- SIC (Spinning Consistency Index)
- Maturity
- Color
- Trash% etc.
Which should be Consider in a particular lot?
- Micronaire range of the cotton bales used should be same for all the mixings of a lot.
- Micronaire average of the cotton bales used should be same for all the mixings of a lot.
- Range of color of cotton bales used should be same for all the mixings of a lot.
- Average of color of cotton bales used should be same for all the mixings of a lot.
- Range of maturity coefficient of cotton bales used should be same for all mixings of a lot.
- Average of maturity coefficient of cotton bales used should be same for all mixings of a lot.
It is important to have an effective bale management system to ensure correct fiber combinations. In cotton lines we employ automatic bale management systems to certify correct mixing percentages for consistent fibre properties to avoid shade variation during fabric dyeing. Cotton bales are stocked up to 6 months in order to provide our repeat customers with consistent quality from the same batch of fibers. In synthetic lines, automatic weighing blenders are used to measure exact blending percentages. Blended fibers are maintained up to 20 days to ensure that every customer receives a homogeneous blend of yarns with low barrenness.
Mixing Strategy
A systematic mixing plan by
maintaining the lowest possible variation in cotton quality parameters
ensures trouble-free yarn production with consistent yarn quality.
In a spinning mill control over cotton quality is involved in the three steps stated below:
1. Approval of cotton bales:
It is very important to purchase the right quality cotton bales
according to defined quality standards. As cotton is a natural fibre and
also a commercial commodity, its availability, prices and quality vary
time to time based on supply and market demand, and therefore it is very
important to select the required quality cotton bales at reasonable
prices which should be viable for spinning industries. Approval of
cotton bales should be very strict against its standards, otherwise this
will result in stock of huge quantity of off-standard bales.
2. Grading of cotton bales:
After reaching cotton bales in mill, these should be tested and properly
graded according to mill standards. If possible it should be stacked in
warehouse grade-wise.
3. Mixing planning: According
to grade-wise, cotton bales stock and spinning count pattern, cotton
bales must be selected for mixing plan with minimum possible variation.
Critical cotton properties
The following are the most common cotton properties, which are measured at the time of selection of cotton bales:
1. Length: Measured either in inches or in mm.
2. Fineness: Cotton fibre fineness usually measured in micronaire, ie, weight of fibres in microgram per inch.
3. Strength: Measured as fibre bundle breaking force in gms per tex.
4. Maturity: Measured either in term of maturity coefficient or in maturity ratio.
5. Uniformity: Measured either in % or as an index.
6. Short fibre content: Measured as %.
7. Trash content: Measured as %.
8. Moisture content: Measured as %.
9. Brightness: Represents as Rd value against degree of reflection.
10. Yellowness: Represents as +b value.
11. Colour grade: Colour grade is determined with conjunction of Rd & +b value.
All in one single value - SCI
Spinning Consistency Index (SCI) is a
calculated value based on a regression equation. This equation takes
into account all HVI properties and calculates one value to be used on
each sample tested. The SCI is an index derived with data from a large
number of cotton samples having a wide range in properties that is
related to test data from yarn spun from each sample. By multiple
regression analysis the contribution of each fibre property to yarn
properties is revealed. Consequently, a single SCI value is influenced
by inherent relationships of cotton micronaire, length, uniformity,
strength, Rd and +b.
The following are SCI equation for the most important HVI measurements including colour:
For HVI Calibration Mode:
SCI = - 414.67 + (2.9 x Strength) -
(9.32 x Mic) + (49.17 x Length in inch) + (4.74 x Uniformity Index) +
(0.65 x Rd) + (0.36 x +b)
If no colour module is installed then SCI equation is as follows:
SCI = - 322.98 + (2.89 x Strength) - (9.02 x Mic) + (43.53 x Length) + (4.29 x Uniformity Index)
For ICC Calibration Mode:
SCI = - 414.67 + (2.9 x Strength) - (9.32 x Mic) + (49.17 x Length) + (8.61 x Uniformity Ratio) + (0.65 x Rd) + (0.36 x +b)
If no colour module is installed then SCI equation is as follows:
SCI = - 322.98 + (2.89 x Strength) - (9.02 x Mic) + (43.53 x Length) + (7.79 x Uniformity Index)
Effect of fibre properties
Each cotton characteristic imposes its own influence on spinning process and ultimately on the yarn quality explained as below:
Fibre length: Fibre length is
the most important factor for spinning. Selection of cotton fibre is
usually based on fibre length only and it is also the main deciding
factor for count range to be spun. Hence this impacts each and every
process of spinning operation. The following are the main influencing
areas where fibre length impacts on spinning performance and yarn
quality.
Count pattern and spinning production rate:
Fibre length is the main deciding factor for count pattern in a
spinning mill. Production speeds of spinning machinery also very much
depend on fibre length of cotton. In modern high production spinning
set-up cotton fibre length cannot be selected as per old traditional
systems. For modern high production spinning set-up cotton fibre
properties required are as below:
Definition of modern high production spinning set-up:
Spinning set-up running with more than 50 kg/hr carding production
rate, getting 40s converted GPSS above 110 with a HOK level of below 12
in spinning, equipped with modern Autoconer.
Working performance:
Higher length variation causes poor working performance of spinning
processes, which lead to lower production and huge disturbance in
process. Only achieving average fibre properties as per standard is not
guarantee for better spinning performance; hence it should be ensured
that each cotton lot should have minimum length variation. Cotton lots
having higher variation should run in controlled quantity, which is
given in next chapter, ie, Mixing plan.
Higher irregularity or unevenness:
If cotton lengths are not suitable to the spin plan or have higher
length variation, eg, to produce the 30s NE count if cotton selected
below 28 mm length, it will lead to high irregularity or unevenness in
yarn and will also cause higher autoconer cuts and fabric defects.
High hairiness: Cotton
selected of lower fibre length will cause high yarn hairiness, leading
to high fluff generation in department, more tendency of traveller
loading, excessive EYC cuts and cops rejection at autoconer and pilling
or barre problem in fabric.
Fineness/Micronaire of fibre:
The second most important factor for spinning mills to decide the count
pattern is fineness of cotton fibre that is commonly known as
micronaire. Same as fibre length, it is also the deciding factor for
cotton selection and spin plan of a spinning mill.
Number of fibres in yarn cross-section:
Spinning of a particular fineness of yarn is based on the fibre length
of cotton and its fineness which decide how many fibres will be in the
cross-section of yarn. It seems that below 90 numbers of fibres in
cross-section of ring spun yarn (for coarse & medium count range)
can lead to major working problem at spinning with lower yarn strength
while more than 300 numbers of fibres in cross-section of yarn lead to
higher unevenness in ring spun yarn. Hence it is recommended to use
right micronaire value for a particular spin plan. Table 1 recommends
guideline for micronaire value for different count range.
Higher neps generation: Low
micronaire value causes high neps generation in blow room and carding,
which lead to higher neps and imperfection in final yarn and white spots
or dots in dyed fabric. Low fineness cotton fibres always have tendency
to form fibre entanglement or neps, hence it is recommended to reduce
blow room beaters speed and carding production rate whenever low
micronaire value cotton is being processed.
Barre or shade variation: Too much variation in micronaire values can lead to barre problem or shade variation in fabric.
Genetic character: Micronaire
value of any cotton fibre strongly exhibits its origin variety genetic
character. If a cotton fibre fineness value does not belong to normal
distribution of its origin variety, it means either this fibre is
immature or it does not belong to the said variety. This type of cotton
lot should be avoided. Table 2 shows a general trend for critical cotton
characteristics for most common Indian cotton varieties.
Fibre strength:
Fibre strength is an important factor for working of spinning process
and yarn strength. Fibre strength is directly proportionate to yarn
strength and working performance of spinning machines. However it seems
that strength of fibre is also related with others cotton properties
like fibre length, micronaire and maturity. Fibre bundle strength is a
deciding factor for spinning machine speeds. If fibre is not adequately
stronger, then there has to be a compromise with production rate and
force to reduce speed of machines. Similarly ultimate yarn strength will
be less as required.
Maturity: Maturity of cotton
fibre is related with its growing process. A fully mature fibre means
the fibre has achieved its complete growth process and has developed in
all respects. Mature fibres achieve and exhibit better fibre properties
in all respect as per their origin of variety characteristics, as
described in Table 2. Fibres which are not grown in a normal condition
or picked up before their complete growth will fail to have their
specific characteristics and will be shorter, weak & fine as
compared to mature fibres.
In HVI testing, the maturity index
is a relative value that is calculated by using a sophisticated
algorithm including other HVI measurements, such as micronaire, strength
and elongation. It indicates the degree of cell wall thickness within a
cotton sample. Table 3 shows the average test results of total 98241
number of bales wrt degree of maturity index.
Hence maturity is a key parameter
for cotton selection and spinning process. In various testing methods it
is represented as maturity coefficient, maturity index or as maturity
ratio. Higher the numerical value means higher will be maturity of
fibres. Low maturity value impact at spinning process or yarn quality as
below:
Fibre rupture:
Immature fibres breaks into multiple pieces in blow room and carding
section during metallic action of beaters and carding wires cause
increase in short fibres & micro-dust which further reduce the
effective length of fibre and strength. This fibre rupture increases
yarn breaks, yarn defects, spinning waste and yarn imperfection level,
subsequently reducing the working efficiency of spinning machinery
causing lower production, yarn recovery with lower yarn strength.
Dead cotton neps: Immature
fibres create heavy neps during spinning process, which ultimately
reflect as white dots in dyed fabric, causing fabric rejection. Table 3
and Figure 1 showing that fibre maturity is directly proportionate to
fibre length & bundle length of fibres.
Uniformity: Settings of
spinning drafting rollers depends on the length of fibres. To obtain
optimised and correct spinning draft roller settings fibre uniformity is
very important factor. Cotton fibre with low uniformity causes very
high variation in process and creates difficulties for spinners to set
the right setting for particular cotton mixing.
Short fibre content: Fibre
lengths below half inch, ie, below 12.5 mm are considered as short
fibres. High short fibre % in cotton leads to many problems in spinning
process such as high end breaks, excessive yarn defects, very high fluff
generation, lower machine efficiency, lower yarn realisation and higher
worker turnover.
Trash content: High trash
content in mixing causes higher waste extraction, high end breaks rate
at ring frame, higher yarn imperfection and Classimat faults. It also
appears as black dots in greige fabric, usually known as kitti
particles.
Moisture content: Cotton is a
hygroscopic fibre, it absorbs moisture from a high humid atmosphere and
evaporates it when stored in dry atmosphere. For smooth spinning
operation, the cotton fibre should have moisture in the range of 6 to 8
per cent. Moisture content below this limit causes high fluff generation
and higher end breaks, while cotton having high moisture content is
difficult to open and clean in blowroom-carding, hence creating very
high imperfection and yarn slubs which again cause end-downs at ring
frame stage, lowering the production efficiency with increase in yarn
imperfection and defects.
Colour Grade: Variation in colour grade is a major responsible factor for shade variation in cotton yarn and fabric.
Grading of cotton bales
It is very difficult to grade a
cotton lot based on all 11 parameters mentioned above, and hence we can
decide four major critical parameters for grading of cotton bales, which
represent the overall grading of cotton. These parameters may be
utilised for cotton bales procurements, stacking and finally for
selecting the cotton bales for Mixing Plan. If a mill's cotton
purchasing is strictly from a particular region then there will be less
chances of too much variation in colour grade, and so critical
parameters for them might be as below:
1. Fibre length: A must requirement to decide the count pattern of spin plan.
2. Micronaire: A must requirement to decide the count pattern of spin plan.
3. Maturity: Required to control the quality of cotton, it also represents to fibre strength.
4. Short fibre %: Required to
control the working performance of spinning mill and yarn realisation.
It also represents to uniformity of cotton. Less the SFC more the
uniformity of fibre.
If cotton procurement of mill is
from different regions, then there might be a possibility of variation
in cotton colour grade. Hence in that case, colour grade also is to be
taken into consideration.
Mixing planning
Object: To mix cotton fibres
of different bales in a homogeneous form to overcome the variations of
cotton properties and maintain the uniformity and consistency throughout
the spinning process and in yarn quality.
Making a mixing plan may be a
tedious job, but spinning performance totally depends on it. Hence
investing time and skill on mixing plan will pay consistency in spinning
wrt working and quality as a result. A practical mixing plan may be
prepared as below:
1. First check the availability of grade-wise cotton bales and spin plan.
2. Then select grade-wise number of
cotton bales in ratio of present cotton bales stock and as required for
spin plan. Stock of cotton bales to be utilised in such a manner that
long staple cotton (ie, A ++ in Table 4) to be used for fine count
pattern.
3. If present spin plan is not
supporting fine count range then it should be preserved for future, if
there is a possibility in future.
4. To control the length variation
in a selected mixing plan either we have to consume "A++" grade cotton
first or we have to preserve it till all the bales of "B" grade cotton
are exhausted.
5. Refer to cotton grading system as
per Table 4, in a mixing plan either there should be top three grade
bales (ie, A++, A+ & A Grade) to be used or lower three grade bales
(ie, A+, A & B Grade) to be used.
6. In a mixing plan fibre length
range should not exceed more than 2.5 mm and micronaire range to be
maintained below 0.60. (Refer Table 6.)
7. Low variation in fibre length is
required to set right the correct gauges of spinning drafting rollers
and to avoid the fibre rupture and drafting waves. Variation in fibre
length causes poor quality and working of spinning along with high fly
generation.
8. Low micronaire range must require
maintaining the uniform number of fibres in cross-section of yarn,
which ensures better yarn evenness and single yarn strength.
9. Number of cotton lots in a mixing
plan to be selected in such a manner that participation of each cotton
lot bales should not be more than 5 per cent. For example, if we are
making a mixing plan for 100 number of bales than there should be at
least 20 number of cotton lots contributing 5 bales each for each batch.
This is required to avoid wide changes in the mixing plan, even if
there is change of one single cotton lot then there will be only 5 per
cent change in particular mixing plan.
10. Replacement of cotton lot should
be in decreasing and increasing order. If one cotton lot is going to be
exhausted in mixing that should be run out slowly and replacement lot
to be inserted in same way, which ensures minimum variation in process
during replacement of cotton lots. Table 5 shows how one cotton lot
should run out and another should replace it.
11. This system ensures very little
change in mixing on day-to-day basis. Only one bale replacement out of
100 bales mixing will be only 1 per cent change in mixing plan, which is
almost negligible.
12. To further minimise the
variation during lot change care should also be taken so that same grade
cotton or cotton lot with same characteristics are replaced.
13. If cotton is procured from different station, then try to replace the cotton lot with same origin or station.
Monitoring of colour Grade: Monitoring
of colour grade is also a very important job to control the shade
variation or barre problem in resultant yarn and fabric. The following
guidelines might be useful for better control on colour grade of cotton.
Rd value: Usually in Indian
cotton Rd values lie between 72 and 82. For better control it is
advisable to maintain the Rd value range below 5 in daily mixing plan.
(Refer Table 6.)
+b: +b value significantly
differs region-wise and variety-wise. In Indian cotton +b lies in range
of 6.0 and 11.0. It is better to maintain the +b range below 2.5 in one
variety cotton mixing. (Refer Table 6.)
Colour grade: The colour
grade is determined by locating the quadrant of the colour chart in
which the Rd and +b values intersect. For example, a sample with Rd
value of 72 and +b value of 9.0 would have a colour code of 41-3. Colour
grade is represented in three digits as xx-y. First digit represents
brightness of cotton. Lower the number higher will be the brightness of
cotton. Second digit represents yellowness of cotton; yellowness
increases with increase in second digit number. There are 25 colour
grades and five categories of colour grades. Indian cotton usually lies
in white and light spotted categories with middling to good middling
colour grade.
To avoid the shade variation or
barre problem it is advisable that only four adjacent cotton grades be
selected for mixing plan, eg, 11, 12, 21, 22 may run together but
running 11 with 31 or 11 with 13 should be avoided.
Colour grade categories of spotted,
tinged and yellow stained, ie, represented by 3, 4 & 5 numbers in
second digit of colour grade should be strictly avoided.
Use of off-standards bales:
In spinning mills there should be strict control on purchasing of cotton
bales or passing for quality specification, otherwise a lot of
off-standard cotton bales accumulate in mill godown, which will never
allow spinners to prepare a controlled mixing plan. However even after
better control there might be chances of some off-standard cotton bales
lying, which do not belong to normal standard either for any single
parameter or due to failure of multiple parameters. These bales are to
be utilised in very controlled manner so that their bad quality should
not affect spinning process and yarn produced. Based on quality
parameters of off-standard bales these may be consumed in controlled
manner (ie, in a range of 1 to 5 per cent according to quality
parameter) as below:
1. If there is only a slight
variation in any one or two parameters from standard, then such cotton
bales may be considered in mixing with 3 per cent contribution. For
example, if standard for fibre length is above 29 mm and the micronaire
is above 3.6 and actual values of a cotton lot found are 28.5 mm and 3.5
mic value then such cotton bales may be considered with 3 per cent
ratio in mixing.
2. If there is a significant
deviation in a single value, such as instead of 29 mm fibre length it is
27 mm while rest other parameters observed are within range, in that
case such cotton bales may be consumed with below 2 per cent ratio.
3. If 2 - 3 parameters fail to meet
the standard specs, then such cotton bales should be strictly consumed
with below 1 per cent ratio.
Mixing Plan monitored through Spinning Consistency Index:
Instead of monitoring of several parameters for a mixing plan, it might
be more easy to monitor the "SCI" value of cotton properties obtained
from HVI test report. The following guidelines may be adapted for using
"SCI" value in cotton grading and mixing planning:
1. Cotton may be graded in five grades and stored in warehouse according to their SCI value, ie, as below:
2. According to stock position a
mixing plan must be prepared and average, minimum, maximum and range
should be drawn for SCI value.
3. Average SCI value of daily mixing
should be maintained constant and there should not be more than +/-2
deviations on daily basis.
4. It should be tried that maximum
and minimum range of SCI value should not be more than 30, for an ideal
mixing plan it should be maintained below 20.
5. The total range of maximum and
minimum SCI value should also be monitored on a daily basis and there
should not be too much variation on daily basis.
Conclusion
Cotton is the most favourable fibre
for spinning industries. As cotton is a natural fibre, hence variation
in its properties is also an inherent characteristic. To overcome these
variations, scientific and systematic control is required on cotton
quality. Control over cotton quality in a spinning mill is recommended
in three stages, ie, approval of cotton bales, grading of cotton bales
and finally selection of cotton bales for mixing plan.
Major cotton fibre properties and
their impacts on spinning processes and yarn quality have been explained
in details with examples, data and graphical representations. More
emphasis has been given on SCI and maturity of fibres. Maturity of
cotton fibre is an important parameter and also impacts on others
parameters such as length, strength, elongation, etc. All in one single
value derived from regression equation Spinning Consistency Index (SCI)
is a value influenced by inherent relationships of cotton micronaire,
length, uniformity, strength, Rd and +b, which may help spinners to
monitor only one parameter for decision making.
Mixing planning is a very important
function for spinning operation and investing the time and skill for
systematic mixing plan pays good returns such as consistency in
productivity and quality. A systematic mixing plan by maintaining the
lowest possible variation in cotton quality parameters ensures
trouble-free yarn production with consistent yarn quality. Variation in
cotton colour grade is a major responsible factor for shade variation
and barre problem in fabric, and hence control over cotton colour grade
is one of the most important functions of mixing plan, which cannot be
ignored. Consuming the off-standard quality bales is a tricky job and it
should be used in a very controlled manner so that performances of
spinning process and yarn quality are not affected.
|
PMP CERTIFICATION COURSE
ReplyDeleteThe PMP course provides managers with the latest information on Project Management norms and practices.Click here to know more
pmp certification course
Nice articles and your information valuable and good articles thank for the sharing information AUTOMATIC BATCH BLENDING SYSTEM
ReplyDelete