effect of raw material on yarn quality and its yeild %
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Transcript of effect of raw material on yarn quality and its yeild %
Effect of raw materialon yarn quality and its yield %
PROJECT SUPERVISOR:
MR.Ashgar siddique
PROJECT MEMBERS:
SYED KHURAM HASSAN BET SP07- 003
MUHAMMAD UMAR SATTAR BET FA06 -008
SYED UZAIR HUSSAIN BET FA06-068
MUHAMMAD ALI BET SP07-008
DEPARTMENT OF TEXTILE ENGINEERING
THE UNIVERSITY OF FAISALABAD
PAKISTAN
We hereby declare that this project, neither as a whole nor as a part therefore
has been copied out from any source. It is further declared that we develop this
project and this report entirely on the basis of our personal efforts made under
the sincere guidance of our project supervisor Sir Ashgar siddique.
We further declare that this project and all associated documents and records
and partial requirement for the degree of Bachelor of Science in Textile
Engineering (Spinning technology)
WITH THE DEEP SENSE OF HONOUR
TO OUR BELOVED AND DEAREST
PARENTS
BROTHERS AND SISTERS
RESPECTED TEACHERS
AND ALL THOSE
WHO DEVOTED THEIR YESTERDAY FOR
OUR
BRIGHT TODAY
With the blessings of almighty ALLAH and prayers of our parents we made this
humble attempt to achieve the goal that we set for us in the beginning of final
year. Although it was not an easy task but with the devotion of our project team
and cooperation of our respected teachers we have at least succeeded in
completion of our project.
The support and encouragement rendered by our MASOOD TEXTILE MILLS staff
was very vital in the completion of this project, their guidance and
encouragement played a key role in the planning and completion of this project.
We are also very thankful to the Head of Department of Textile Engineering
Mr.AD CHUDARY for facilitating us. We are very thankful to our project advisor
MR.ASHGAR SIDDIQUE for his guidance and providing us the facilities which was
the real source of inspiration for the completion of this project.
In the end we are thankful to all the lab attendants and staff members without
the cooperation of whom the achievement of this goal would have been a dream
only.
introduction
Project introduction
Title:
The effect of raw material on yarn quality and its yield percentage.
BRIEF INTRODUCTION: The Raw material through from which we made cotton yarn is called cotton. In spinning mill yarn is final product we achieve required quality of yarn after passing trough various process.
As yarn is produced for preparation of fabric which is basic need of human being. So with the development civilization best quality yarn is demanded now a days which mainly depend on yarn quality. There are different quality parameters of material and by applying these we decide what the grade of our yarn?
In our project we have correlated the standard characteristics of cotton with mill cotton standard and then we have compared the standard yarn parameters with mill yarn standards. We have studied each and every property of cotton which they buy from different areas.
Different area cotton has different properties with respect to its length, fineness, strength, trash and color. We compare the yarn produced with the material used in mill with yarn standard parameters and observe the difference in quality and yield percent
MILL
INTRODUCTION
INTRODUCTIONOur group of four students was advised to study of raw material and its quality at MTM. MTM is situated at a distance of 32 Km from our university on Faisalabad Sheikupura road. It is a composite unit which consist of spinning, Knitting and Dying house. The stitching unit of MTM Ltd is in the Faisalabad city. The mission statement of this organization is that "Our vision is to be the world's best textile company", our values “Trust, integrity, respect".
A brief introduction about machines of different department of, spinning is given below:
BLOW ROOM In this blow-room department there is a single line with 3 scutchers. All the blow-room line is of TOYODA OHARA (model 1987-1988) except a porcupine beater and one scutcher which are of Chinese.
CARDING In carding department there are 24 cards of model CROSSROL MK4.
DRAWING There are 10 drawing machines in this department
COMBINGThere are 8 comber machines in this unit. Seven of them are TOYODA CM-10 (MODEL 1992) and one is Cherry. There is 1 lap former of model TOYODA SK-4-A.
SIMPLEX There are 6 frames in this department. All the frames are TOYODA FL-16 (1988).
RING The no. of frames in ring department is 30. All of them are TOYODA RY-4 (1988). All the frames have 480 spindles each.
AUTOCONE This department is equipped with 6 frames. All are MURATA ·MODEL 7-11
AIR CONDITIONER Air conditioning plant is established in this unit which fulfil the requirements of humidification satisfactorily.
LABOUR STRENGTH
MIXING Mixing in charge = 1 Jobber = 1 Floor cleaning and mixing labour = 52/ shift
BLOWERROOM
Maintenance staff Foreman = 1 Head fitter = 1Fitter = 2 Assistant fitter = 1 Helper = 1
PRODUCTION STAFF/ SHIFT Jobber = 1 Opener tenter = 3 Picker tenter = 2 Floor cleaner = 1
CARDING SECTION
Maintenance staff Foreman = 1Head fitter = 1Fitter = 3Assistant fitter = 1 Helper = 2
PRODUCTION STAFF/ SHIFT Jobber = 1
(The card & BR jobber is same)Card tenter = 5 Lap man = 2 Floor cleaner = 1
DRAWING & SIMPLEX
Maintenance staff Foreman = 1Head fitter = 1 Fitter = 1 Assistant fitter = 1 Helper = 2
PRODUCTION STAFF/SHIFT Jobber = 1 Simplex tenter = 3Drawing tenter = 2 Doffer = 5 Floor cleaner = 2
LAP FORMER & COMBER
Maintenance staff Assistant foreman = 1 Head fitter = 0 Fitter = 1Assistant fitter = 0Helper = 2
PRODUCTION STAFF/ SHIFT
Comber tenter = 2
Fly cleaner = 1 Floor Cleaner = 1 Lap man = 1
RING SECTION
Maintenance staff Foreman = 1 Head fitter = 1 Fitter = 2 Assistance fitter = 3 Helper = 6
PRODUCTION STAFF/SHIFT Production Incharge = 1 Supervisor = 1 Jobber = 2 Six sider = 10 Piecer = 12 Doffer = 8 Trolley man = 1
WINDING SECTION
Maintenance staff Foreman = 1Head Fitter = 1Fitter = 3Assistance fitter = 3Helper = 2
PRODUCTION STAFF/SHIFT Finishing Incharge = 1 Jobber = 1 Cone checker = 1 Bobbin sorter = 5 Winder operator = 14 Floor cleaner = 2 Trolley man = 1
PACKING SECTION Package Incharge = 1Packing boy/shift = 10
RAW MATERIAL The cotton variety used IS MNH-93.It is obtained from different stations such as Hasalpur, Bahawalpur, Lodhara, Khanpur, Melsi, Burewala, Rahim Yar Khan, Ahmad Pur, Multan, Kabirwala. In MTM Finance Officers select the cotton variety. Some samples are tested physically and samples are sent to laboratory for testing as well. They started to purchase cotton from September and their target is to purchase about 40,000 bales. Purchasing continues often from September to March. Cotton is selected on the bases of following parameters.
Staple Length Micronair Trash Moisture Dead cotton Strength Contamination Colour grade Stiffness Honey dew U% of fibres
Acceptable values of following: Staple Length = 1.06 - 1.07 Micronair value = 4.5 - 5 Trash = 8.5% Moisture = up to 9% Dead cotton = 0 Strength = 85 - 90 Contamination = as minimum as possible
CHARACTERISTICS OF COTTON USED AT MTM Name = MNH-93Average Staple Length = 1.073 inchesMicronair Value = 4025 ug/inchMoisture %age = 9-9.55Type of Picking = hand pickingType of Ginning = saw ginningForm of Raw Cotton = bales #Pressly Strength = 90,000 lb/in2Trash %age = 9%Short Fibre %age = 9.7%Consumption of Cotton per day = 75-80 bale
IMPORTANCE OF MIXINGNow-a-days mixing of raw cotton before blow room action is of entire need for the quality of yarn and fabric. If the cotton is not mixed properly then due-to different characteristics of different cotton shading will occur in the fabric.
SYSTEM OF MIXING There are 3 ways of mixing
1. Blow room mixing 2. Lap to lap mixing 3. Sliver to sliver mixing
TYPES OF MIXING The following types or mixing are used now a days
a) Stack mixing b) Hopper blending c) Continues blending d) Batch blending e) Sliver blending (simple blending, cross can blending)
SPECIAL MIXING PROCESS IN THE MTMSometimes special which is being used In MTM is their special mechanism which is prepared by our "Textile Graduate" the Mill Manager Mr. Munir Ahmad Sahib. He has developed this method of mixing is running successfully.
OBJECTIVES1. To get more check points2. To increase the cleaning efficiency3. Dust removal4. To improve the mixing efficiency
In mixing dept. three auto pluckers are being used one of which is reserved to avoid the stoppage of feed to blow-room. Two of these are always in working condition.Each pluckers feed the material to twelve beaters equipped with small lattices from these lattices the material goes to the main lattice. Cage condenser through suction pipe is to avoid the fluff which also gives advantage of dust removal. Two cages are used; one cage is used for twelve lattices.There are two women working on each side of lattices for contamination picking
COMPONENTS OF EACH UNIT 1. Feed Rollers
There is a pair of fluted rollers which feed the material to the beater.
2. Beater The main component of this unit is a beater which is used for opening of bigger tufts into smaller, tufts. The specifications of beater are as follows:No of rows = 6No of pins/roe = 18Height of pins = 1 ½ inch Thickness of pins at base = 1 ½ inch
DEFLECTING PLATEThere is a deflecting plate below the beater. Its surface is perforated when the material strikes the deflecting plate, the heavy impurities fall down through perforation and material comes on small lattice form which woman picks the contaminations.
Contaminations picked by women are of following types:
1. Coloured cloth 2. Jute 3. Polypropylene 4. Coloured tarn 5. Hairs 6. Yellow cotton 7. Feathers8. Polythene 9. Wrappers10. Straws
SPECIFICATIONSNo of Charnbers = 31 No. of worker/ lattice = 2Length of small feed lattice = 10 ft Width of small feed lattice = 4ft Rpm of beater = 50 r.p.mNo. Of long lattices = 4Width of long lattices = 4 ft
Length of long lattices = 20 ft No. of beating point = 1
STACK MIXING PROCESS It is also celled Sandwich Mixing. It is still preferable. It is pre blow-room treatment. The bales are opened by auto plucker and are taken on to the special mixing region. It is then taken to the mixing room pneumatically and is piled in the form of stack for at least 24 'hours. The moisture content of each bale becomes equal and constant according to atmosphere.
TECHNICAL DATA Cotton 'Variety = MNH 93 1 lot size = 100 bales Issue of bales/day = 110 bales Blend used = 64 lots Bale gross weight = 168 kg Packing material wt = 1.75 kg Net fibre wt = 166.25 kg
Volume of bale = 19.3 cub. Ft
Density of bales = 26.6 lbs/cub: Ft Contamination removed = 60 gms/bale Colour mass removed = 0.75 gms/baleJute removed = 14 gm/baleStrains = 41.77 gms/balePre-Blow room TreatmentModal = FA002Origin = CHINANo. of Machines = 3 Maximum output = 800 kg/hrLoading capacity = 2000-2500 kgsRPM of plucking beater = 700 rpmCarriage RPM = 1.5 rpmDia of beater plate = 13 inchesOne plucker disc = 15 teethBeater motor speed = 960 wpm (2kw)Carriage motor speed = 53 rpm (.55kw)Carriage lifting motor = 53 rpm (.25kw)Rail dia = 5122 mmRail dia = 4155 mmRail height = 31No. of grids = 29Beater penetration after every
Revolution = 0.5 inchesExtension of blades form rib = 7.5 mm (adjustable)Beater length = 64 inchesBales used per Plucker = 10 bales at a time
The worker on auto plucker is continuously throwing material from outer periphery of the machine to inner side because at the periphery the supervision is necessary to provide even surface of material. This is also a disadvantage with this machine.
ATMOSPHERIC CONDITIONS Relative, humidity and weather conditions for “Mixing hall” are name outside the hall. No special emphasize is given to control environment.
SPECIAL FEATURE 1. There are metallic separators to remove metallic impurities.2. Due to lattices the jute picking become easy. 3. There are enough no of lattices.
BLOW ROOM
INTRODUCTION
After mixing comes the blow-room line. The approach to extract the foreign material is to convert the bulky mass into small tufts thus convenient situation to extract the wastage the blow room has gained, a very position in the spinning line now a days. Even so that YARN is made in the blow room.
ACTION IN BLOW ROOMThe action of blow-room lines are as given
1. Action of opposing spikes 2. Action of air current 3. Action of breakers4. Action of centrifugal force5. Action of gravity6. Regulation action
OBJECTIVES OF BLOWROOM Following basic function are performed in blow room
1. Opening 2. Cleaning 3. Dust removed 4. Blending and mixing 5. Regulation 6. Lap formation
OPENINGIt is a basic function performed in blow room. We get tuft opening here. A tuft of 0.5 kg (about) is opened to about .0.1 mg in the blow room line.
CLEANINGAfter opening second most important function of BR lines' is cleaning i.e. Removal of foreign matter. New blow room approximately remove 40%-70% of foreign matters.
BLENDING AND MIXING According to quality parameter's mixing is most important parameter. Mixing of various materials can be done in blow room to get satisfactory results for hosiery yarn to avoid shade problem. Flock to flock mixing is done in BR.
DUST REMOVAL In blow room line about 64% of dust can be removed. To increase the dust removal, opening of grid bars should be optimum.
REGULATION ACTION: Regulation of material is very important for accur.ate working of cards. Regulating action is obtained by hopper, swing door, photo cells and distributors.
LAP FORMATIONEven today this is best method of feed even material to card. Now a days shoot feed system is also getting popularity throughout the world.
SPECIFICATIONS OF BLOW ROOM LINE: Make = Toyoda Ohara Model = 1987-88 Origin = JapanNo of beating point = 8.0Temp in BR = lO5-l06F RH% in BR = 53%Laps rejection %age = 3-8% Production
(effectives) = 85-95 bales/day
Efficiency = 85% Waste/shift = 250kg
INFORMATION OF DIFFERENT MACHINES OF BLOW ROOM
1. BALE BREAKER This machine is composed of creeper lattice, feed lattice inclined lattice evener roller and stripper roller, A photo cell is mounted to stop the feed when a pre determined
amount of cotton is executed in the hopper bin. A photo cell is also mounted to stop the machine when there is not material on creeper lattice
Specification of Bale BreakerMake = Toyoda Ohara Model = BX 87-88 Origin = Japan Speed of evener roller = 100 r.p.m Speed of stripper roller = 280 r.p.m. Speed of clearer roller = 162 r.p.m Speed of inclined lattice bowl = 206 r.p.m Speed of feed lattice bowl = 38rpm Speed of crupper lattice bowl = 5.3 rpm Angle of inclination of spikes = 40 Dia of spikes = 6mm Inclination of spikes = 45 Pitch of spikes = 45mm Bottom lattice length = 1820mm Dia of stripper roller = 411mm No of rows on stripper = 6 Needle dia on stripper roller = 10mm Spike dia on stripper roller = 27mm Evener roller dia = 416mm No of rows on evener roller = 8 Needle dia on evener roller = 14mmSpikes pitch on evener roller = 45mm Clearer roller dia = 324mm No of rows on clearer roller = 4 Speed ratio of inclined and Feed lattice = 1:6.7
MULTI-MIXER: A four cylinder multi mixer is attached on this machine to improve the blending of different varieties of cotton. The material from bale breaker is thrown to the 2 fold multi mixer in which 4 cylinders are rotating in each compartment and a conveyer lattice is running under these cylinders. The material from these 4 cylinders is fed on lattice and hence mixing is done on this lattice. Four couples of delivery rollers are mounted over the 4-cylinders which assist in feeding the material to the cylinder for mixing. The cylinders are horn type and open the material for better mixing. Two specifications of different parts are as follows:
Specification of Multi Mixer:
Make = Toyoda Ohara Model = BR (1992) Origin = Japan No. of hoppers = 1Feed Roller dia = 128mmNo. of feed rollers = 8Speed of feed roller = 1 rpm (range 0.3-2 rpm)Mixing/horn cylinder dia = 302mmNo. of horn cylinder = 4Horn type = LeatherSpikes height = 51mmSpikes pitch = 120mmSpikes rows = 4No. of spikes = 42mmHorn rpm = 615Conveyer belt width = 1220mmConveyer belt length = 1950mmConveyer bowl dia = 150mmSpeed of conveyer bowl = 120mmCareer roller dia = 100mmPress roller dia = 128mm Press roller speed = 144rpmNo. of motors = 2Press roller type = Star type roller aluminium alloy
MS CLEANER:
Porcupine beater are used as condenser beater for the separation of leaf particles and is kept earlier in the cleaning line. In this type, of beater three cylinders are used having gradually increasing speeds and is inclined. The specifications of these machines are as given:
Specification of Ms Cleaner: Cylinder diameter = 302mm No. of cylinder = 3 Spike height = 51mm Spike pitch = 120mm Spikes rows = 3 No of spikes = a) 340rpm
b) 395rpm c) 445rpm
METAL DETECTOR: To avoid damage of sensitive parts of fore coming machinery the metal pieces are removed by the magnetic track and cotton is passed through it.
AXI-FLO CLEANER: This machine consists of two cylindrical beaters mounted horizontally with grid bars beneath each beater. Both cylinders rotate in same direction.
Specifications of Axi-Flow:Make = Toyoda Ohara Hergth (Japan)
Model = WR (1992)Machine = 1250mmSpiked Cylinder diameter = 574mmNo. of cylinders = 2Gauge b/w cylinders = 26mm (fixed) 137mmSpike length = 137 mmTotal no. of spikes = 62/cylinderSpiked cylinder rpm = 520rpmGauge b/w cylinder and = 20mm (fixed) grind barNo. of grid bars (triangular = 33/cylindertype grid bars) Angle of grid bars = 0-170°Distance b/w grid bars = 5mm (fixed)Maximum production rate = 650kg/hrNo. of motor = 1
FEED BOX (FS-1) The feed box serves as a reserve box for the subsequent machines. The speed of feed rollers under which a beater is arranged, are being controlled by. Subsequent machines. By means of geared motor drive of the two feed rollers a consistently uniform feeding to the forth coming machine IS arranged.For FS-I the beater arranged below feeding roller will open the material evenly and thus good cleaning efficiently is obtained. And also underneath the beater of FS I there is an adjustable and for separation of waste. Specifications of machines are as under.
Specifications of Feed Box 1:Make = Toyoda Ohara Model = FS-1 (1992)Feed roller rpm = 7.3 rpmSwing door = 1Porcupine beater with 4 Spikes speed = 362 rpm
FINE OPENER: (VO-I) In this type of opener a porcupine type beater is provided which is running at high speed and hence impurities are separated with the help of grid bars which are mounted below the grid bars.
Specification of Fine Opener:Make = Toyoda Ohara (Japan) Model = Vol (1992)Type of beater = Porcupine beater Beater dia = 40mm Beater speed = 890mm No of rows of strikers = 12 (metallic type) Feed roller speed = 70 rpm No of grid bar = 21 Grid bar angle = 7.5° Gauge b/w a beater and feed
Roller = 7mm std Beater to stripping rail = 3mm std Beater to grid bar = 15mm std.
CAGE CONDENSER KD-1 AND KD-2 The cage condensers are used for the transportation of material with the help of a fan and cage. Also an extra advantage of dust removal can be obtained KD.l is used for transportation of material to the step cleaner.
Specification of Cage Condenser-1:Cage dia = 500mmcage speed = 160-180rpmFan speed = 1200-1700rpmNo. Of motors = 2
Specification of Cage Condenser-2:Cage dia = 500mmCage speed = 160-180rpmFan speed = 1200-1700rpmNo. Of motors = 2
FEED BOX FS 2 Its functions and principles are same as those of FS 1 Feed box..
Specifications of Feed Box 2:Make = Toyoda Ohara (Japan) Model = FS-2 (1992)Feed roller rpm = 6rpmSwing door = 1Beater speed = 450rpm
HR-6 (STEP CLEANER) It is good example of opening and cleaning of cotton by the combination of action of opposing spikes and beating action. The cotton is fed at even and regular rate to the machine from where it immediately comes under the action of first of 6 beater. These beater are arranged at an angle of 45◦.Each beater consists of four spikes. Each beater rotates above the grid bars except that of last one.
Specifications of Step Cleaner:Model = HR-6No. Of beaters = 6
Dia of beaters = 454mmSpeed of beaters = 1st = 416rpm
2nd = 417rpm3rd = 473rpm4th = 477rpm5th = 539rpm6th = 522rpm
Motor = 980rpmNo. Of striker’s row = 4Angle of inclination = 45°Grid bar setting under each other = 29-12-29
FINE OPENER (VO.2) It is same as vo-1 except the beater.
Specification of Fine Opener 2:Make = Toyoda Ohara Model = VO-2 (1992)Type of Beater = Kirschener beaterNo. Of legs = 3Beater speed = 786rpm1st pressing rollers speed = 31rpm2nd pressing rollers speed = 50rpmFeed roller speed = 60rpmSpeed of feed lattice bowl = 32rpmNo. Of grid bars = 21rpmGrid bar angle = 7.5°Gauge b/w;
i. Beater & feed roller = 7mm std.ii. Beater to striping roller = 3mm std.iii. Beater to grid bar = 15mm std.iv. No. Of motors = 2v. Motor = 1484
RVK OPENER:
It is used for the cleaning of low grade cotton which has a major portion of trash like vegetable impurities. The specifications are as follows:
Specifications of RV Opener:Make = Trutzshler Model = RV (1990)Origin = GermanyKirschener beater speed = 807rpmSpeed of lattice bowl = 30rpmSpeed of pair of feed roller = 68rpmPhoto cell = 1No. Of motors = 3Waste removal = ManualSpeed of fan = 1200-1800rpmHopper beater = 806rpmHopper beater feed roller = 106rpmSpeed of cage = 160-180
RESERVE HOPER FEEDER This hopper feeder is attached before scutcher to give a uniform and continuous feeding of material to the scutcher. The spiked lattice takes the material to the evener totter.
Specifications of Reserve Hoper Feeder:Make = Toyoda Ohara (Japan)Model = KS (1992)Origin = JapanNo. of machines = 3Swing door = 1 per machine
SCUTCHER There are 2 Toyoda scutchers and one Chinese.
Specifications of Scutcher:Make = Toyoda Ohara
Model = SW-3 (Single cage)Origin = JapanNo. of machines = 2 Japanese & 1 Chinese
Rollers Diameter(mm) Speed(r.p.m) Surface Speed (m/min)Beater Motor 1490Kirschner Beater 402 1124 1418.800Fan 330 2380 2467.400Pedal roll 70 11 2.4191st Stripping roll 67 9 1.8942nd Stripping roll 67 5 1.052Large press roll 120 5 1.884Small press roll 83 10 2.607Cage 504 4.5 7.1253rd Calender roll 162 18 9.1602nd Calender roll 128 24 9.6511st Calender roll 126 25 9.896Bottom Calender roll 180 18 10.178Shell roll 240Normal 14 10.556During doffing 88 66.350
CARDING SECTIONINTRODUCTION Card is mostly considered as one of the most important m/c in spinning industry. It is also called "the heart of spinning" because it separate the fibres up to single fibre stage without which drafting imperfection cannot be eliminated and in spinning industry yarn is manufactured by drafting so card is considered as the most important machine in spinning industry.
OBJECTIVE OF CARDING Opening to Individual Fibres State Removal of impurities Elimination of short fibres Dust removal Removal of neps Fibre blending Fibre orientation Silver formation
SETTING:Between feed roll and feed plate = 5”/1000Between feed plate and taker in = 17”/1000Between taker in and cylinder = 7”/1000Between mote knife and under Casing = 30mm
Between taker in and waste Plaster = 22”/1000Between taker in and under Casing = 5mm Between taker in and mote Knife = 50”/1000Setting at cylinder = 10”/1000Between cylinder and back bottom plate =
Bottom = 31/1000Top = 22”/1000
Between cylinder and back top plate =Bottom = 22”/1000Top = 22”/1000
Between cylinder and front top plate = 34”/1000 (bottom & Top)
MACHINE SPECIFICATION: Make = Crosrol (England) Model = MK-4 (1992) No of Machines = 24 TemperatureDry = 102°F Wet = 85°F RH% = 48.69% Total Installed power rating = 4.2Kw Production Rate = 44-160 Ibs/hr Air abstracted for M/C = 3060 m3 /hr Lap / hank fed = 14.75 oz/ydHank sliver delivered = 58 gr/ydWaste % removed = 5-5.5%Working efficiency = 85%Cleaning efficiency = 90%C.V % = 1.5-2%No. of Stationary Flats = 8U % = 4.48%Sliver rejection % = 0.1% No. of revolving flats = 101Flats in working condition = 37Carding elements at front of card = 4 At back of card = 2Type of coiling = Over coiling Type of coiler = Star and plant systemCan size = 24 x 42 inch Coiling ratio = 1:26
Coil dia = 15 InchCoil length = 47014Eccentricity = 4.6 inch T.Y.P in sliver = 0.769 Empty can wt = 19.25 kg Full can wt = 38.75 kgWt. of sliver in can = 19.5Length of sliver in can = 4500 yards Volume of can
= 0.292m3
Packing density = 66.78 kg/m3
Card Clothing The clothing mounted IS E.C.C. the specification of the clothing is given below:
Taken In:No. of teeth per linear inch = 5.65No. of rows in transverse direction = 8 rows per inchNo. of teeth per square inch = 36Wire height = 5.65 mmAngle of wires = 80°Life of clothing = 6-9 month
Cylinder Base width = 0.50 Pitch of wires = 1.31 mmNo. of wire points/sq. Inches = 860Life of clothing = 2-3 yearsWire height = 2.00 mmAngle = 63°
Doffer
Doffer Base thicknesss = 1mm
Pitch = 2.015 m
No . of wire pints/sq.inch = 298
Life of clothing = 2-3 years
Height of wire = 4 mm
Angle = 60 degree
Top set No of wire points
Per sq .inch = 438
Wire height = 7.5 mm
Life clothing = 1 year
Angle = 72 degree
Station flats No of wire points/sq.inch = 544
Wire height = 2 mm
Life of clothing = 1 year
Grinding method Long dead roll grinding
Indication and stop points
The cared confirm to all safety regulations and all other safety interlocks and signals are provided.
The following indication are provided as below :
Drawing section
Objective : Uniformity
Parallelization
Mixing and blending
Dust removal
Working : four or eight slivers are fed into the drafting arrangement a positively driven feed roller pair is located above each can to enable the feed to be performed in a contolled manner without false drafting .The slivers running into the drafting arrangement leave it after
a draft of 4.48-11.69 in order to disintegration of the web ,it is condensed in to a sliver by a reducer immediately after drafting operation .The sliver by is then guided though a tube via gear passage in to can .
automatic can changing the modern high performance drawing frames are usually filled with automatic can changers. These reduce the burden on the personnel ,enabling more m/cs to be allocated to one person.
Machine detail: In MTM machine specifications:
As a breaker D/F:Breaker D/F = 5
Make = Rieter
Model = SB -2
Year = 2001
Make = toyoda - 4
As finisher D/F
Finisher D/F = 5
Make = Rieter
Model = RSB –D 30C = 2
Model = RSB – D35 = 3
Year = 2001
M/C specification :
Machine = SB -2
Make = Rieter
Model = 2001
No . of M/cs = 1
Used as = Breaker D/F
Doubling = 8
Draft range = 5.17 – 11.83
Drafting system = 3/3 with pressure
Box .
Type of coiling = over coiling
C.C Roller dia = 55 mm
Top drafting roller dia:
Fronter roller = 38 mm
Middle roller = 38 mm
Back roller = 38 mm
Bottom drafting Roller dias :
Front roller = 40 mm
Middle roller = 30 mm
Back gauges = 30 mm
Roller Guages :
Front middle roller = 4mm
Middle and back roller = 14 mm
Drafts :
Total draft in drafting zone = 7
Back draft (back zone) = 1.32
Main draft (font zone) = 5.3
Tension drfat b/w F.D.R S.C.R :
Drafting system = auto doffing
Sliver system (fed ) = 65 gr/ yd
Waste = 0.1%
Sliver hank (delivered) = 66 gr/yd
Working efficiency = 85 %
Dia of can = 5080 mm
Height of can = 1067 mm
No . of delivery M/c = 2
Type of coiler = moving can
Type of creel = +ve driven
Delivery rate = 400 m/min
Fisher draw frame : The drawing of combed sliver is called finisher drawing in combed yarn preparation .So in MTM two finisher drawings are sued for combed yarn .In MTM high speed drawing frames of rieter spinning system are used as finisher for combed yarn.These drawing frames are of single delivery and are fully eduipped with modern quality equipments like auto leveler etc.
Machine specification:Machine = RSD – D30C
Make = Rieter
Model = 2001
No .machines = 2
Used as = Finisher D/F
Doubling = 8
Drafting range = 4.48 – 11.69
Drafting system = 4 over 3
Draft length = 7.84
Working efficiency = 85%
Type of coiling = over coiling
C.C roller dia = 55 mm
Waste = 0.1%’
Length of sliver in can = 4000 yds
Dofing system = Auto doffing
Dia and height of can = 20*42”
Sliver hank (fed) = 65 gr/yd
Sliver hank (del) =65 gr/yd
Creel type = +ively
Delivery speed = 350 m/mm
Top drafting roller dias :
Deflection roller = 38 mm
Front roller = 38 mm
Middle roller =38 mm
Back roller = 38 mm
Bottom drafting roller dias :
Front roller = 40 mm
Middle roller = 30 mm
Back roller = 30 mm
Roller gauges :
Front and middle roller = 4 mm
Middle and back roller = 12 mm
Drafts :
Total draft in drafting zone = 7
Break draft 9 back zone = 1.28
Main draft = 5.468
Leveling system : The auto leveler draw frame RSB-D30c is equipped with an electronic leveling system.
All slivers fed to m/c pass through a pair of scanning rollers.one of the two rollers is equipped with a moveable bearing. This roller moves according to the variation in the sliver cross –section .
These movement are transformed into voltage by a signal converter and forwarded to an electronic leveling processor D90 .
The leveling process D90 furnishes the accurate target speed to the servo motor M90 and servo leveler G90 – based on :
1) Electric signals supplied by scanning roller and sliver feed .
2) Draw frame delivery speed The servo drive generates the controls speed for the planetary gearing (differential)This controlled speed pf planetary gearing drivers the entry of the drafting system back roll and middle roll.This way the required changes in draft are accomplished and the weigth varia tion of incoming sliver are leveled . The speed of delivery roll remains constant depending upon the selected delivery speed and ensures production rates which can be calculated exactly .
Lap Former Comber Lap Essentials 1) Comber lap should be prepared in such a way that sufficient no
.of doubling be used .2) It should be sufficicently drafted 3) Regular lap along its linear density should be prepared 4) These should be no phasing tendency in the lap step drafting
discouraged5) Even no of macjine should be used between comber and card 6) Hook should be first fed to comber7) The lap should be homogenous with no any identity of the
sliver
Machine specifications :Make = Toyoda
Model = SK4A
Machine height = 1680mm
Creel length = 5575 mm
Can size = 20*42”
Temperature (dry) = 95 F (degree)
Wet = 83 F (degree)
R.H% = 51%
Dia of empty lap roller = 120 mm
Grains / yard fed = 65
Lap grains/yard fed = 950
No of doublings = 39
Lap length = 110 yds
Draft range = 2.0 – 5
Time to complete one lap = 98 sec
Drafting system = 2/3
Doffing time = 10 sec
Efficiency = 90%
Waste % = 0.5 %
Shell roller delivery =65.07 m/min
C.V of lap = 0.4 %
Motor r/m = 142 r/m
Load at top rollers
Front top roller = 80 kg
Second top roller = 120 kg
Dias of different rollers :
Roller name Dia (mm)
Lifter roller 38
Lap roller 35
Back roller 35
Second back roller 28
Front roller 35
Press roller 78
Converyer roller 75
Calendar roller 140
Shell roller 460
The combing machine
Introduction:
Comber was developed due to wishes of quality mass now a days is the age of production .particularly hosiery yarn production .The combing has achieved an important place in the spinning line for fine counts.Comber improves the following parameters of the yarn by removing the short fibers and the neps.
1) strength2) Cleanliness3) Smoothness4) Visual appearance
In addition to the above ,yarn made of combed cotton needs a less twist than a carded yarn and obviously more production.Comber is unique is its operation .it is a combination of complex mechanicl expectancy .
Types of comber These are four types of comber:
Rectilinear comber (with stationary or oscillating nipper )
Circular comber (English worsted process)
Rotary comber
Hacking machine
Degree of combing :
1. Scratch combing Noil % removed in scratch combing is 6 – 8 % . It is done for imported cotton
2 . Ordinary combing
Noil % removed in ordinary combing is 12 – 16 %.it is used for Pakistani and imported cotton
3 .super combing : Noil % removed in super combing is 18 – 20 , ensure that no fiber is present in combed sliver the manufacturing of special yarn.
4. double combing :
It is a two stage process
. in first stage 60 % of the total noil is removed .
. And remaining 40 % is removed in the second stage
Machine specification: Make = toyoda (japan)
Model = CM-10 (1992)
No of machines:
Toyoda = 7
Cherry = 1
Length of machine = 5825 mm
Width of machine = 1240 mm
Height of machine = 1388 mm
Distance b/w 2 m/cs = 1000 mm
Temperture
Dry = 95 F
Wet = 85 F
R.H% = 51 %
Can size = 20*42”
Can coil ratio = 1:26
Eccentricity = 76 mm
Dia of internal hole in can = 7”
Drafting system = 2/2
Drafting range = 4.1 – 9.4
Dia of top rollers = 33 mm
Lap feed = 950 gr/yd
Back roller dia = 35 mm
Front roller = 32 mm
Nips over minute = 190 nips/min
Noli % = 20 %
Working efficiency = 85 %
Dia of trumpet guide = 340 mm
Tpy = 0.856
Dia of trumpet guide:
D= 0.015625 * C * W
Wher C =1.12 W = 65 grains/ yd
Hence
D = 3.58 mm
Type of comb on cylinder = uni comb
Top comb density = 60 needles/inch
Cylinder needle density = 22 – 80 needles/ inch
Rows of needle = 35
Back roller pressure = 81.2 – 118.8 kg
Front roller pressure = 940
Roller guage (average staple length of upper half of fiber ) + 7 mm
= 35 – 55 mm
Simplex
Objectives :
1) Drafting2) Twisting3) Package formation
Machine specification :
Make = toyoda (japan)
Model = FL – 16 ( 1988 )
No .of machine = 6
Dimensions of machine:
Length = 14520 mm
Width = 1000 mm
Height = 1350 mm
Creel length = 13520 mm
Min .space b/w two = 4 ft
Machines
Total lift of frame = 390 mm
No .spindle per frame = 120
Temperature
Dry = 95 f (degree)
Wet = 83 f (degree )
R.H % = 60 %
Drafting system = SKF PK 1500 (4)
Draft range = 4.5 – 13
Spindle pitch = 220 mm
Length roller boss = 50 mm
Working efficiency = 85 %
Waste %age = 0.4 %
Wt of empty bobbin = 222 gm
Dia of bare bobbin = 45 mm
Length of bobbin used = 445 mm
Length of bobbine = 390 mm
Dia of bobbine collar = 60 mm
Type of flyer = closed type + open
Pressing winding = double
Flyer speed = 1000
Dia of full bobbin = 146 mm
Package length = 2500 m
Apron size :
Top roller = 37× 39.9 × 1 mm (lincotex )
Bottom roller = 38.8 ×39.9×1.4 mm (Lincotex )
Guage setting in different one
Front zone = 35 mm
Middle rooler = 48 mm
Bark zone = 49 mm
Dia of different rollers:
Specification of top rollers
Roller DIA(mm) Roller Dia(mm)
Creel roll 50 Front roll top 28
Back roll 2 8. Bottom 28.5
(top)
Back roll 28.5 motor pulley 175
(Bottom)
1st roll top 28 driven pulley 220
Bottom 28.5 empty bobbin 45
2nd roll top 28 ratio of cone drum 1.718
Bottom 28.5
Different places at simplex Sliver fed (gr/yd) 60 and 65
Sliver hank fed 0.1282
Roving hank 0 .95
Actual draft 7.41
M.D 6.00
TM 1.15
TPI 1.006
Twist contraction 0.96
RING
RING
FUNCTIONS OF RING FRAME
1. Drafting to attenuate the material to require fitness.2. Twisting to impart the strength and peculiar properties.3. Winding to store data in a suitable form for further processes.
RINGRing is a steel band narrow vertical cylinder with horizontal flange
which projects at right angles from both sides of the top edge.
It serve as a path for traveler so it help in twisting and winding of yarn package. It main parts are.
1. Flange
2. Web
3. Base
DIFFERENT TYPES OF RING ARE:
Common ring
Su ring
Self lubricating ring
Back slope rings
Porous sinted metal PSM
Nylon rings
TRAVELLER
A spinning traveler is ashort length of steel wire which has been bent into “C shape, hardened, tempered, scoured and polished, so it may revile main parts of travelers are:
a. Arch
b. Horn
c. Flange
Traveler size or numbers
This system is base on the weight of 10 travelers
Range of traveler 25/0 25
TYPES OF TRAVELLER
1. C shaped traveler
2. Elliptical shape edge traveler
3. Flap top traveler
4. S U traveler
5. Ear shaped traveler or vertical traveler
6. Conical traveler
PK-225 DRAFTING SYSTEM
3/3 drafting system
Double apron system
Bottom apron is longer than top apron
Inclination of roller 40 degree
Cotton blends, pure polyester, and men made fibers can be processed
APRONS Usually two aprons are used, upper are short and bottom are longer and are made of leather. They run over a guide bars to position. Close to nip like of delivery roller.
Their thickness is about 12 mm. aprons are used to support short fibers in main drafting zone to control yarn imperfection.
SPACER
Spacers are distinguished by their colors. As red, yellow lilac, white, grey, black, bright, green, pink, blue, brown. These numbers are in ascending orders.
LAPPET GUIDE
It is yarn guide to deliver the yarn to form balloon. These are mounted on lappet rail. If also moves up and down with ring rail but with less traverse.
SPINDLE
It is main part of Ring Frame. It is made of hardened and tempered carbon steel. The bobbin is placed on spindle.
BOLSTER
It is device bearing in which Ring Spindle is placed. It is filled 75% with special oil.
TRAVELLER CLEARER
The traveler is used to clear the fiber from ring. It is placed very closed to ring to keep it clean so that end breaking can be reduced. It strips among any fibrous mass from traveler to keep it clean.
SEPARATOR
These are used to separate the one balloon of yarn from other to avoid end breakage. They are made to plastic, metallic, or synthetic. In MASOOD TEXTILE MILLS Plastic separators are used.
MACHINE SPECIFICATION
Make = Toyoda (Japan)
Model = RY-4 (1998)
No of machines = 30
Spindle/machine = 480
Total spindles = 14400
Temperature:
Dry = 93 F
Wet = 84 f
RH = 64.65%
Draft range = 7.97-61.08
Lift of frame = 180mm
Chase length = 48 mm
Pneunafil = 0.95%
Waste % = 1.5%
Working efficiency = 94%
Angle of drafting system = 40º
Wt. Of empty bobbing = 40gm
Wt. Of full bobbing = 115gm
Net wt. Of yarn = 75g,
Bobbing length = 8”
Length of yarn on bobbing = 2777 yars
Base bobing dia
Top = 19mm
Bottom = 24mm
Till bobbing optimum dia = 40mm
Linear speed of ring rail
Upward = 216mm/min
Downward = 432mm/min
Type of package build = cop build
No . of balloon control ring = 1 ring/spindle
Spindle speed 18s comb .hosiery yarn = 1550 rpm
Steel ring
Make = Chinese
Ring dia = 42mm
Flange width = 3.1mm
Flange no = 1
Life of ring = 1 year
Traveler no. use for new ring = 2/0
After ½ month = 1/0
After 6 months = 2
Traveler life = 6 days
Traveler clearer guage = 2.0mm
Spacers:
Spacers used for 18s combed = yellow
End down rate = 2-2.25%
Maximum tolerance limit
For ends down/sp/hr = 40
Spindle tape length for four
Spindle = 240mm or 6’2”
Doffing freq = 1 hr 25 min
Doffing time = 2 min
Bottom roller guage
Front zone = 44mm
Back zone = 48mm
Top roller guage
Front zone = 48mm
Back zone = 46mm
Top roller pressure is distinguished by its color of spring
Back = 10kg
Green = 14kg (present)
Red = 18 kg
AUTOCONE
WHAT IS MACH CONER?
“MACH CONER” is an individual spindle type automatic winder
for one cycle of joining to complete in 9 seconds to which
continuous automatic bobbin feeder (CBF), automatic doffer
(AD) and murata measuring and monitoring system (MMM) can
be attached.
OBJECT OF MACH CONER
1. removal of thick and thin places
2. slub removing
3. waxing ( if required)
4. package formation according to required weight OK weight
required length of yarn.
5. splicing
1. ATMOSPHERIC CONDITIONS
Dry temperature = 93 º F
Wet temperature = 83 º F
Quality parameter of Raw Material
in MTM
Serial no Test date Micro nair Staple length
Floating fiber
Uniformity ratio
Trash Moisture
1 1/05/2010 5.04 1.048 22.7 47.9 7.19 8.372 2/05/2010 5.05 1.051 18.62 49.29 6.42 93 3/05/2010 5.05 1.049 22.55 47.95 7.23 7.24 4/05/2010 5.1 1.046 22.2 48.09 7.75 6.875 5/05/2010 4.8 1.05 18.24 49.42 6.52 5.526 6/05/2010 5 1.048 17.48 49.71 6.34 8.85
7 07/05/2010 4.85 1.054 16.58 49.9 6.02 7.18 8/05/2010 5.1 1.059 16.63 49.59 6.56 8.539 09/05/2010 5.15 1.044 18.63 49.32 49.99 8.5610 10/05/2010 4.7 1.044 18.37 49.42 5.52 8.9211 11/05/2010 4.8 1.052 18.2 49.43 6.42 8.712 12/05/2010 5.05 1.045 18.21 49.47 5.87 8.6613 13/05/2010 4.9 1.056 17.86 49.53 7.15 7.1414 14/05/2010 5.05 1.045 17.68 49.66 7.27 8.4515 15/05/2010 5.15 1.056 18.24 49.43 4.89 8.5316 16/05/2010 4.85 1.055 17.48 49.67 7.22 8.1817 17/05/2010 5 1.063 16.56 49.95 6.87 8.7118 18/05/2010 5 1.051 18.09 49.67 5.77 9.1319 19/05/2010 5 1.052 18.47 49.33 6.66 8.9820 20/05/2010 5.05 1.051 17.82 49.57 7.61 8.7321 21/05/2010 4.75 1.051 19.43 49 6.76 8.1522 22/05/2010 5.1 1.052 18.2 49.43 6.51 8.1423 23/05/2010 4.8 1.052 18.2 49.43 6.26 8.624 24/05/2010 4.85 1.048 22.43 47.99 6.03 6.5625 25/05/2010 5.05 1.048 22.3 48.38 6.14 6.9726 26/05/2010 4.85 1.053 18.05 49.48 6.04 8.4227 27/05/2010 4.65 1.056 16.3 50.09 6.04 8.0428 28/05/2010 4.9 1.057 15.9 50.24 6.86 7.6729 29/05/2010 4.75 1.056 16.56 50 5.17 8.5530 30/05/2010 4.6 1.05 19.05 49.14 5.97 7.81
31 31/05/2010 4.9 1.052 18.2 49.43 5.35 8
32 01/06/2010 4.7 1.051 18.09 49.48 6.61 7.56
33 02/06/2010 4.9 1.054 7.37 49.71 7.22 7.55
34 02/06/2010 5.1 1.053 16.74 49.95 6.3 8.72
35 02/06/2010 4.9 1.055 16.44 50.05 6.06 7.99
36 02/06/2010 4.79 1.06 16.23 50.09 6.2 9.12
37 03/06/2010 4.95 1.058 16.01 50.19 7.39 8.365
38 03/06/2010 4.95 1.054 17.11 49.81 6.05 8.27
39 03/06/2010 5.1 1.059 16.37 50.05 5.75 9.82
40 04/06/2010 5.15 1.052 18.73 49.24 6.66 7.99
41 06/06/2010 4.95 1.051 18.86 49.19 7.45 8.73
42 07/06/2010 5.1 1.055 17.74 49.57 6.9 9.87
43 09/06/2010 5.15 1.051 18.89 49.19 5.35 7.05
44 09/06/2010 5.1 1.056 17.07 49.81 6.25 8.75
45 11/06/2010 5.1 1.051 18.35 49.38 7.17 8.22
46 11/06/2010 5.07 1.051 18.01 49.47 6.77 8.33
47 11/06/2010 4.9 1.052 17.67 49.62 5.51 6.82
48 12/06/2010 4.95 1.054 17.37 49.71 5.77 9.22
49 13/06/2010 4.75 1.055 17.22 49.76 5.69 7.52
50 13/06/2010 4.9 1.057 16.67 49.95 5.05 8.7
51 14/06/2010 5.1 1.06 16.48 50 8.54 8.88
52 14/06/2010 4.9 1.055 17.22 49.76 7.95 7.86
53 17/06/2010 5.1 1.057 16.92 49.86 6.46 9.46
54 17/06/2010 5.05 1.058 16.52 50 5.57 8.6
55 24/06/2010 4.7 1.054 17.37 49.7 6.15 8.03
Average quality Parameters of Raw
Material in MTM
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 4.9 1.053 18 49.5 6.4007 8.2202
Minimum 4.6 1.04 15.9 47.9 4.89 5.52
Maximum 5.2 1.06 22.7 50.2 8.54 9.87
CV % 3 .399 8.9 1.1 12.299 10.025
Quality Parameter of Raw material
in MTMSERIAL NO Test date Micro nair Staple
lengthFloating fiber
Uniformity ratio
Trash Moisture
1 01/07/2010 5.15 1.046 20.23 48.76 8.15 13.37
2 01/07/2010 5.15 1.045 18.75 49.28 7.52 12.08
3 01/07/2010 5.2 1.046 18.59 49.33 6.25 10.6
4 02/07/2010 5.17 1.043 18.25 49.33 7.25 10.6
5 02/07/2010 5.25 1.045 17.41 49.76 8.54 11.17
6 08/07/2010 5.25 1.043 19.34 49.09 8.58 9.9
7 08/07/2010 5.3 1.046 18.59 49.33 7.05 12.17
8 08/07/2010 5.15 1.045 18.21 49.47 7.67 9.5
9 11/07/2010 5.35 1.042 17.87 49.62 6.35 11.1
10 11/07/2010 5.35 1.046 17.53 49.71 7.09 10.29
11 11/07/2010 5.25 1.046 19.13 49.14 8.23 9.26
12 14/07/2010 5.3 1.045 19.02 49.19 7.64 9.48
13 14/07/2010 5.35 1.043 18.79 49.29 8.85 9.5
14 16/07/2010 5.35 1.046 23.35 47.7 8.55 8.86
15 16/07/2010 5.2 1.046 20.78 48.56 9.12 9.45
16 17/07/2010 5.3 1.05 18.2 49.43 7.51 9.38
17 17/07/2010 5.15 1.046 19.95 48.85 7.96 10.26
18 19/07/2010 5.25 1.051 18.35 49.38 8.29 11.76
19 19/07/2010 5.35 1.049 20.85 48.52 7.05 9.62
20 19/07/2010 5.15 1.051 19.43 49 7.6 12.1
21 23/07/2010 5.1 1.051 19.43 49 6.77 9.82
22 23/07/2010 5.35 1.042 22.59 47.98 7.21 9.9
23 23/07/2010 5.35 1.046 20.78 48.56 8.32 9.45
24 23/07/2010 5.45 1.048 20.46 48.66 7.12 9.68
25 23/07/2010 5.4 1.052 20.09 48.76 7.86 10.22
26 29/072010 5.35 1.049 20.02 48.81 6.93 9.4
26 29/07/2010 5.45 1.055 17.22 49.76 8.04 9.25
27 29/07/2010 5.25 1.054 16.59 50. 7.07 10.07
28 29/07/2010 5.15 1.045 22.36 48.04 6.81 10.53
29 29/07/2010 5.11 1.052 20.64 48.57 6.07 9.75
30 31/07/2010 5.35 1.052 19.79 48.9 7.05 11.12
31 31/07/2010 5.25 1.048 18.82 49.24 6.61 10.03
32 01/08/2010 5.45 1.05 16.93 49.9 8.65 10.2
33 01/08/2010 5.35 1.052 21.76 48.19 5.76 9.73
34 01/08/2010 5.25 1.039 20.81 48.6 7.83 9.8
35 02/08/2010 5.25 1.054 17.11 49.86 7.88 10.7
36 02/08/2010 5.35 1.056 16.7 49.19 7.08 9.75
37 05/08/2010 5.4 1.052 16.37 50.9 7.74 10.83
38 05/08/2010 5.25 1.053 15.71 50.33 6.66 9.75
39 07/08/2010 5.45 1.052 15.1 50.57 6.28 10.14
40 07/08/2010 5.25 1.047 22.94 47.85 7.13 9.25
41 09/08/2010 5.25 1.055 18.54 49.29 5.01 9.58
42 11/08/2010 5.2 1.051 18.09 49.48 6.56 9.75
43 11/08/2010 5.45 1.049 17.86 49.57 8 9.45
44 14/08/2010 5.45 1.04 15.64 50.38 7.65 10
45 14/08/2010 5.25 1.049 18.66 49.28 6.63 9.8
46 17/08/2010 5.2 1.05 17.45 49.75 6.27 9
47 17/08/2010 5.15 1.051 18.34 49.38 6.75 9.65
Average quality Parameters of Raw
Material in MTM
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 5.3 1.048 18.9 49.2 7.3856 10.135
Minimum 5.0 1.04 15.1 47.7 5.01 8.86
Maximum 5.5 1.06 23.4 50.6 9.12 13.37
CV % 2.0 .370 9.9 1.3 11.936 9.3585
Quality Parameters of Raw Material
in MTMSerial no Test date Micro nair Staple
lengthFloating fibers
Uniformity ratio
Trash Moisture
1 1/10/2010 5.35 1.048 18.82 49.24 6.15 8.8
2 1/10/2010 5.3 1.049 21.41 48.33 7.13 8.93
3 1/10/2010 5.4 1.051 19.7 48.91 6.58 8.68
4 4/10/2010 5.2 1.047 20.34 48.71 6.83 8.25
5 4/10/2010 5.2 1.05 19.59 48.59 6.53 7.1
6 4/10/2010 5.65 1.051 18.62 49.29 7.21 9.33
7 4/10/2010 5.25 1.052 19 49.14 6.85 8.87
8 6/10/2010 5.4 1.053 18.31 49.38 6.08 8.83
9 6/10/2010 5.35 1.053 19.12 49.1 6.08 8.8
10 7/10/2010 5.35 1.053 18.58 49.29 5.95 8.48
11 7/10/2010 5.45 1.052 18.2 49.43 6.49 8.83
12 7/10/2010 5.35 1.055 17.48 49.67 7.9 8.43
13 7/10/2010 5.45 1.058 16.52 50 6.4 9.27
14 7/10/2010 5.45 1.049 17.86 49.57 5.67 9.53
15 9/10/2010 5.3 1.06 16.74 49.91 3.86 8.95
16 9/10/2010 5.4 1.05 16.67 50 6.91 9.31
17 10/10/2010 5.38 1.051 17.3 49.76 6.1 8.98
18 10/10/2010 5.25 1.057 16.92 49.86 6.07 9.14
19 10/10/2010 5.4 1.056 15.54 50.38 7.12 9.81
20 10/10/2010 5.25 1.052 18.74 49.24 4.61 9.39
21 15/10/2010 5.35 1.051 18.09 49.48 5.77 9.13
22 15/10/2010 5.35 1.052 17.94 42.92 5.13 9.31
23 15/10/2010 5.2 1.053 17.52 49.67 5.27 8.67
24 17/10/2010 5.45 1.051 18.09 49.48 5.48 8.76
25 17/10/2010 5.35 1.052 18.2 49.43 5.73 9.3
26 19/10/2010 5.35 1.052 18.2 49.43 5.93 9.08
27 19/10/2010 5.4 1.053 18.05 49.48 5.93 9.06
28 22/10/2010 5.45 1.052 17.94 42.25 6.25 8.83
27 22/10/2010 5.25 1.058 16.78 49.9 4.7 7.45
28 23/10/2010 5.4 1.058 16.2 50 5.08 7.91
29 23/10/2010 5.3 1.056 16.4 50.19 6.85 8.74
30 23/10/2010 5.3 1.054 16.59 50 5.97 8.6
31 24/10/2010 5.5 1.057 16.41 50.50 6.42 7.94
32 26/10/2010 5.6 1.057 15.64 5.033 4.97 8.56
33 26/10/2010 5.6 1.051 18.89 49.19 6.43 8.87
34 28/10/2010 5.5 1.055 17.22 49.76 6.48 9.08
35 28/10/2010 5.45 1.057 16.92 49.86 6.11 9.38
36 28/10/2010 5.5 1.057 17.22 49.86` 8.85 8.9
37 29/10/2010 5.55 1.056 16.81 49.9 6.7 9.1
38 29/10/2010 5.45 1.057 16.67 49.95 5.9 8.93
39 01/11/2010 5.6 1.056 16.56 50 6.88 9.12
40 01/11/2010 5.35 1.057 16.41 50.05 7.42 9.53
41 01/11/2010 5.55 1.057 16.15 40.14 6.91 9.81
42 01/11/2010 5.55 1.064 15.9 50.19 6.17 8.9
43 04/11/2010 5.65 1.06 15.97 50.19 6.25 9.98
44 04/11/2010 5.55 1.06 15.47 50.38 6.45 9.43
45 04/11/2010 5.2 1.052 17.67 49.62 7.8 8.5
46 09/11/2010 5.35 1.054 17.9 49.53 5.63 8.99
47 09/11/2010 5.2 1.055 17.48 49.67 6.43 7.82
48 09/11/2010 5.45 1.049 20.02 48.81 5.47 9.12
49 12/11/2010 5.35 1.059 15.86 50.24 5.84 9.2
50 12/11/2010 5.75 1.048 20.18 48.76 5.72 8.9
51 12/11/2010 5.35 1.055 17.22 49.76 6.18 9.73
52 16/11/2010 5.25 1.054 17.11 49.81 5.49 7.7
53 16/11/2010 5.35 1.057 16.92 49.86 4.41 9.27
54 16/11/2010 5.45 1.057 16.92 49.86 6.01 10.12
55 19/11/2010 5.35 1.056 16.81 49.9 5.27 9.73
56 19/11/2010 5.35 1.055 16.44 50.05 4 7.27
57 22/11/2010 5.3 1.095 16.12 50.14 5.34 8.6
58 22/11/2010 5.3 1.062 15.68 50.28 6.19 8.39
59 22/11/2010 5.35 1.061 16.34 50.05 5 8.77
60 24/11/2010 5.3 1.059 16.12 50.14 6.11 8.4
61 24/11/2010 5.75 1.054 17.37 49.7 4.98 6.75
62 26/11/2010 5.75 1.057 16.92 49.86 5.65 7.52
63 26/11/2010 5.55 1.059 16.63 49.95 5.06 7.28
64 26/11/2010 5.5 1.059 16.89 49.86 5.79 7.35
65 28/11/2010 5.85 1.052 18.47 49.33 4.63 6.9
66 28/11/2010 5.4 1.053 17 49.86 6.13 7.12
67 01/12/2010 5.4 1.053 16.48 50.05 6.11 9.05
68 01/12/2010 5.35 1.046 17.79 49.61 4.96 9.37
69 04/12/2010 5.35 1.053 17.26 49.76 5.24 8.95
70 04/12/2010 5.5 1.049 18.13 49.48 7.63 8.98
71 07/12/2010 5.35 1.0453 17.52 49.67 5.87 8.87
72 07/12/2010 5.45 1.0546 19.4 498.04 5.62 8.85
73 10/12/2010 5.3 1.05 18.51 49.33 5.79 8.6
74 10/12/2010 5.4 1.055 17.48 49.67 7.22 8.18
75 10/12/2010 5.38 1.051 17.3 49.76 6.1 8.98
76 15/12/2010 5.25 1.057 16.9 49.86 6.07 9.14
77 15/12/2010 5.4 1.056 15.54 50.38 7.12 9.89
78 15/12/2010 5.25 1.052 18.74 49.24 4.61 9.39
79 17/12/2010 5.35 1.051 18.09 49.48 5.77 9.13
80 17/12/2010 5.35 1.052 17.49 49.52 5.13 9.39
81 19/12/2010 5.2 1.053 17.52 49.67 5.27 8.67
82 19/12/2010 5.45 1.051 18.09 49.48 5.48 8.71
83 22/12/2010 5.35 1.052 18.2 49.43 5.73 9.3
84 22/12/2010 5.3 1.052 18.2 49.43 5.93 9.08
85 26/12/2010 5.35 1.056 16.81 49.9 5.27 9.7
86 26/12/2010 5.35 1.055 16.44 50.5 4 7.2
87 30/12/2010 5.3 1.059 16.12 50.14 5.34 8.6
88 30/12/2010 5.3 1.062 16.68 50.28 6.19 8.35
89 31/12/2010 5.75 1.054 17.37 49.71 4.98 6.75
Average quality Parameters of Raw Material
in MTM
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 5.4 1.054 17.5 47.1 6.0032 8.7264
Minimum 5.2 1.05 15.5 50.0 3.86 6.65
Maximum 5.9 1.06 21.4 50.4 8.85 10.12
Cv % 2.6 .362 7.0 10.4 14.592 8.5018
Average quality parameters report of MTM
From 01/05/2010 To 24/06/2010
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 5.4 1.054 17.5 47.1 6.0032 8.7264
Minimum 5.2 1.05 15.5 50.0 3.86 6.65
Maximum 5.9 1.06 21.4 50.4 8.85 10.12
Cv % 2.6 .362 7.0 10.4 14.592 8.5018
Average quality parameters report of MTM
From 01/07/201 To 17/08/2010
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 5.3 1.048 18.9 49.2 7.3856 10.135
Minimum 5.0 1.04 15.1 47.7 5.01 8.86
Maximum 5.5 1.06 23.4 50.6 9.12 13.37
CV % 2.0 .370 9.9 1.3 11.936 9.3585
Average quality parameters report of MTM
From 01/10/2010 To 22/12/2010
Micro nair Staple length
Floating fibers
Uniformity ratio
Trash moisture
Average 4.9 1.053 18 49.5 6.4007 8.2202
Minimum 4.6 1.04 15.9 47.9 4.89 5.52
Maximum 5.2 1.06 22.7 50.2 8.54 9.87
CV % 3 .399 8.9 1.1 12.299 10.025
Standard quality parameters of Raw
Material of MTM
Parameters Extra long Long Medium Short
Staple length 27 – 28 mm 24 – 26 mm 20 - 23 mm Less than 20
Micro nair High
5.5
medium
4.5
Low
4
Uniformity Above
55
50 - 55 45 – 50 Less than 45
Trash % High
10
Medium
6 – 8
Low
3- 5
Moisture % High
12
Medium
7 – 11
Low
Below 7
Floating fiber High
15
Medium
10 – 14
Low
Below 10
Quality Parameters of yarn in MTM
Sr. # Test date U % Cv % Cv/1m Thin place (-50)per/km
Thick place +50
Neps200
1 01/08/10 10.89 13.08 6.01 5.06 140 3302 02/08/10 11.05 13.06 6.22 26 152 3563 03/08/10 11.09 14.08 5.56 0.00 126 3644 04/08/10 10.08 14.09 5.06 15 110 3945 05/08/10 12.00 13.06 5.23 16 156 4166 06/08/10 10.07 14.05 6.86 17 145 4247 07/08/10 11.05 13.09 6.23 12 123 3868 08/08/10 12.06 13.06 6.76 8 158 3489 09/08/10 11.05 14.09 5.89 6 169 36910 10/08/10 11.07 14.02 5.23 5 145 42611 11/08/10 11.02 14.06 6.25 12 128 41512 12/08/10 11.08 13.05 6.45 14 125 38513 13/08/10 11.05 13.08 5.12 18 145 34614 14/08/10 11.09 14.07 6.45 19 124 39515 15/08/10 12.06 15.09 5.12 11 158 37216 16/08/10 10.08 12.00 6.00 10 170 33017 17/08/10 11.02 13.06 5.09 5 165 32918 18/08/10 11.02 13.06 5.45 7 152 34619 19/08/10 11.06 14.05 6.12 9 126 41620 20/08/10 11.08 15.00 6.58 11 128 42821 21/08/10 11.09 14.09 5.08 19 145 43522 22/08/10 11.04 13.02 6.55 15 152 44023 23/08/10 10.9 13.08 5.12 9 148 359
24 24/08/10 10.8 13.03 5.89 14 170 37825 25/08/10 12.05 14.08 6.15 16 168 41626 26/08/10 13.00 14.09 5.45 22 152 33127 27/08/10 11.08 13.05 5.14 21 146 43828 28/08/10 11.09 13.08 6.85 14 110 39529 29/08/10 11.07 14.06 5.87 6 110 34830 30/08/10 13.00 15.06 6.45 18 152 41931 31/08/10 12.04 13.09 6.84 25 146 395
Quality Parameters of yarn in MTMSr. # Test date U % Cv % Cv/1m Thin place
(-50)per/km
Thick place +50
Neps200
1 01/10/10 10.88 13.85 5.23 5 120 3522 02/10/10 10.45 13.34 5029 26 190 3563 03/10/10 10.65 13.58 5.31 25 170 3854 04/10/10 10.26 13.26 5.12 24 180 3455 05/10/10 9.89 13.00 5.01 25 190 3306 06/10/10 9.86 13.01 5.04 22 177 3127 07/10/10 9.96 13.05 5.02 21 152 3018 08/10/10 10.26 13.65 5.42 19 119 2859 09/10/10 10.89 13.85 5.25 14 145 24710 10/10/10 10.95 13.95 5.24 15 180 26911 11/10/10 12.24 14.25 6.23 17 177 24512 12/10/10 12.58 14.85 6.86 16 156 29813 13/10/10 12.00 14.50 6.51 0.00 145 27814 14/10/10 11.85 14.22 6.14 14 124 34515 15/10/10 11.69 14.16 6.02 13 188 32116 16/10/10 11.68 14.16 6.02 18 200 30117 17/10/10 10.95 13.95 5.85 19 188 38918 18/10/10 10.56 13.57 5.47 15 179 39019 19/10/10 11.23 14.34 6.51 12 196 34720 20/10/10 11.89 14.29 6.54 11 158 29821 21/10/10 11.58 14.18 6.52 6 145 24822 22/10/10 12.45 14.67 6.56 8 110 37823 23/10/10 12.58 14.71 6.58 9 162 35824 24/10/10 11.98 14.29 6.86 7 188 29825 25/10/10 12.58 14.85 6.75 11 149 388
26 26/10/10 11.48 14.00 6.01 18 189 36527 27/10/10 10.98 13.95 5.89 24 152 25828 28/10/10 10.96 13.86 5.69 25 175 37829 29/10/10 11.23 14.25 6.25 27 189 37830 30/10/10 11.58 14.36 6.15 23 125 365
Quality Parameters of yarn in MTMSr. # Test date U % Cv % Cv/1m Thin place
(-50)per/km
Thick place +50
Neps200
1 01/11/10 12.24 14.25 6.23 17 177 2452 02/11/10 12.58 14.85 6.86 16 156 2983 03/11/10 12.00 14.50 6.51 0.00 145 2784 04/11/10 11.85 14.22 6.14 14 124 3455 05/11/10 11.69 14.16 6.02 13 188 3216 06/11/10 11.68 14.16 6.02 18 200 3017 07/11/10 10.95 13.95 5.85 19 188 3898 08/11/10 10.56 13.57 5.47 15 179 3909 09/11/10 11.23 14.34 6.51 12 196 34710 10/11/10 11.89 14.29 6.54 11 158 29811 11/11/10 11.58 14.18 6.52 6 145 24812 12/11/10 12.45 14.67 6.56 8 110 37813 13/11/10 12.58 14.71 6.58 9 162 35814 14/11/10 11.98 14.29 6.86 7 188 29815 15/11/10 12.58 14.85 6.75 11 149 38816 16/11/10 11.48 14.00 6.01 18 189 36517 17/11/10 10.98 13.95 5.89 24 152 25818 18/11/10 10.96 13.86 5.69 25 175 37819 19/11/10 11.23 14.25 6.25 27 189 37820 20/11/10 11.58 14.36 6.15 23 125 36521 21/11/10 10.88 13.85 5.23 31 120 35222 22/11/10 10.45 13.34 5029 26 190 35623 23/11/10 10.65 13.58 5.31 25 170 38524 24/11/10 10.26 13.26 5.12 24 180 34525 25/11/10 9.89 13.00 5.01 25 190 33026 26/11/10 9.86 13.01 5.04 22 177 312
27 27/11/10 9.96 13.05 5.02 21 152 30128 28/11/10 10.26 13.65 5.42 19 119 28529 29/11/10 10.89 13.85 5.25 14 145 24730 30/11/10 10.95 13.95 5.24 15 180 269
Quality Parameters of yarn in MTMSerial #
Test date U% Cv% Cv% (1m)
Thin place(-50)
Thick place(-50)
Neps(200)
1 1/07/2010 10.15 13.15 6.25 0 150 3262 2/07/2010 10.50 13.55 5.55 20 110 3853 3/07/2010 12.25 13.88 5.25 12 150 3454 4/07/2010 11.75 14.25 5.00 25 110 3265 5/07/2010 12.25 13.88 6.69 5.0 160 4306 6/07/2010 10.85 13.55 6.23 0 162 4257 7/07/2010 12.22 14.25 5.25 5 125 4368 8/07/2010 12.50 14.25 6.55 25 145 1859 9/07/2010 11.25 14.55 6.95 15 135 38510 10/07/201
010.75 13.55 5.58 25 170 345
11 11/07/2010
13.80 14.85 5.25 0 115 326
12 12/07/2010
12.00 13.12 6.00 13 115 440
13 13/07/2010
11.15 13.00 6.25 0 165 326
14 14/07/2010
10.80 12.55 5.00 30 125 345
15 15/07/2010
11.25 14.25 5.75 12 170 395
16 16/07/2010
13.00 15.00 5.26 0 142 375
17 17/07/2010
10.99 13.00 6.00 20 168 430
18 18/07/201 12.25 13.56 5.65 25 110 425
019 19/07/201
011.25 14.55 6.69 16 115 326
20 20/07/2010
12.25 14.25 6.45 5 155 385
21 21/07/2010
10.35 13.55 5.98 5 165 375
22 22/07/2010
11.25 13.85 5.32 0 170 430
23 23/07/2010
11.32 13.55 5.25 16 134 425
24 24/07/2010
11.00 13.88 6.25 5 131 395
25 25/07/2010
10.99 13.77 6.95 10 165 436
26 26/07/2010
13.00 14.25 5.00 0 145 326
27 27/07/2010
11.99 14.00 6.25 20 122 440
28 28/07/2010
12.85 13.25 6.00 5 123 330
29 29/07/2010
12.55 13.00 5.96 0 147 440
30 30/07/2010
10.70 13.85 5.25 16 159 395
31 31/07/2010
11.00 13.85 6.69 20 115 425
Quality Parameters of yarn in MTMSerial #
Test table U% Cv% Cv%(1m) Thin place(-50)
Thick place(-50)
Neps(200)
1 1/09/2010 9.70 13.25 5.00 5 110 2502 2/09/2010 9.85 13.24 5.25 15 172 3153 3/09/2010 9.55 13.55 5.55 25 152 375
4 4/09/2010 12.70 15.00 6.00 30 162 2135 5/09/2010 12.25 14.25 5.55 13 190 4006 6/09/2010 12.50 14.35 6.00 5 118 2547 7/09/2010 9.55 13.95 5.00 17 165 3008 8/09/2010 9.85 13.25 5.25 25 110 2509 9/09/2010 10.25 13.56 5.50 13 165 24610 10/09/201
010.95 14.00 5.25 16 162 213
11 11/09/2010
10.55 14.55 5.35 6 172 246
12 12/09/2010
12.70 15.12 5.99 30 118 254
13 13/09/2010
12.25 14.35 6.00 5 165 315
14 14/09/2010
12.25 14.25 5.45 17 110 390
15 15/09/2010
10.95 13.00 5.25 14 170 300
16 16/09/2010
10.65 13.45 5.35 16 172 213
17 17/09/2010
9.25 13.25 5.12 18 190 345
18 18/09/2010
9.45 13.35 5.25 5 152 250
19 19/09/2010
9.55 13.55 5.00 18 170 365
20 20/09/2010
12.78 14.65 5.99 17 145 254
21 21/09/2010
12.35 14.25 5.85 16 152 300
22 22/09/2010
12.72 14.35 6.00 5 165 425
23 23/09/2010
10.95 14.00 5.25 6 118 246
24 24/09/2010
10.85 14.05 5.55 30 162 315
25 25/09/2010
10.25 13.99 5.50 14 172 300
26 26/09/2010
9.70 13.25 5.05 25 118 254
27 27/09/2010
9.85 13.45 5.25 14 110 213
28 28/09/2010
9.55 13.55 5.45 30 162 400
29 29/09/2010
10.58 14.00 5.35 6 190 375
30 30/09/201 12.25 14.25 6.11 13 152 315
0
Quality Parameters of yarn in MTM
Serial #
Test table U% Cv% Cv%(1m) Thin place(-50)
Thick place(-50)
Neps(200)
1 1/12/2010 9.70 13.00 5.00 5 110 2502 2/12/2010 9.85 13.24 5.25 15 172 3153 3/12/2010 9.55 13.55 5.55 25 152 3754 4/12/2010 10.70 13.80 6.00 30 162 2135 5/12/2010 9.00 13.25 5.55 13 190 4006 6/12/2010 9.50 13.35 6.00 5 118 2547 7/12/2010 9.55 13.95 5.00 17 165 3008 8/12/2010 9.85 13.25 5.25 25 110 2509 9/12/2010 10.25 13.56 5.50 13 165 24610 10/12/201
010.95 14.00 5.25 16 162 213
11 11/12/2010
10.55 13.15 5.35 6 172 246
12 12/12/2010
10.70 14.12 5.99 30 118 254
13 13/12/2010
10.25 13.35 6.00 5 165 315
14 14/12/2010
12.25 13.25 5.45 17 110 390
15 15/12/2010
10.95 13.00 5.25 14 170 300
16 16/12/2010
10.65 13.15 5.35 16 172 213
17 17/12/2010
9.25 13.25 5.12 18 190 345
18 18/12/2010
9.45 13.35 5.25 5 152 250
19 19/12/2010
9.55 13.55 5.00 18 170 365
20 20/12/2010
12.78 14.65 5.99 17 145 254
21 21/12/2010
12.35 13.25 5.85 16 152 300
22 22/12/2010
12.72 14.15 6.00 5 165 425
23 23/12/2010
10.95 13.00 5.25 6 118 246
24 24/12/2010
10.85 14.05 5.55 30 162 315
25 25/12/2010
10.25 13.99 5.50 14 172 300
26 26/12/2010
9.70 13.25 5.05 25 118 254
27 27/12/2010
9.85 13.45 5.25 14 110 213
28 28/12/2010
9.55 13.55 5.45 30 162 400
29 29/12/2010
10.58 13.00 5.35 6 190 375
30 30/12/2010
10.25 14.00 6.11 13 152 315
Impact of raw cotton on yarn
Quality of yarn in
Masood textile Mills
1) On 02/05/2010 MTM issued cotton having moisture content 9 .The cotton was processed in three days and on 05/05/2010 yarn U % was 10.97.It was increased from 10.1.which was processed on 03/05/2010.It shows negative impact on yarn U% .
2) On 13/05/2010 MTM issued cotton having moisture content 7.14 .The cotton was processed in three days and on16/05/2010 yarn U % was 9.88.It was reduced from 10.5.which was processed on 13/05/2010. It shows positive impact on yarn U% .
.
EFFECT OF MOISTURE:
Moisture in atmosphere has a great impact on the physical properties of textile fibres and yarns..Relative humidity and temperature will decide the amount of moisture in the atmosphere. High relative humidity in different departments of spinning is not desirable. It will result in major problems. But on the other hand, a high degree of moisture improves the physical properties of yarn. Moreover it helps the yarn to attain the standard moisture regain value of the fiber. Yarns sold with lower moisture content than the standard value will result in monetary loss. If the moisture perecentage in the raw material is more than the fiber get stick with one another
if we use moisture with less perecentage then fiber lost their strength and fiber become weak.Therefore the aim of conditioning is to provide an economical device for supplying the necessary moisture in a short time, in order to achieve a lasting improvement in quality.
4)On 07/05/2010 MTM issued cotton having Trash percentage 6.02 .The cotton was processed in three days and on 11/05/2010 yarn U % was 9.91.it was reduced from 10.45 which was processed on 07/05/2010. It shows positive impact on yarn U% . .5)On 02/06/2010 MTM issued cotton having Trash percentage 7.22 .The cotton was processed in three days and on 06/06/2010 yarn U % was 10.27 .it was increased from 9.87 which was processed on 03/06/2010.It shows negative impact on yarn U% .
EFFECT OF TRASH: Trash, often referred to as non-lint, commonly comprises fragments of leaves, bark and grass, as well as particles of sand and dust. The levels of such contaminants are determined by growing, harvesting and ginning
conditions. Plastic materials also represent a serious source of contamination. Trash content is directly and indirectly related to processing waste, the removal of trash being associated with fibre breakage and the removal of fibres as waste, as well as nep formation. These in turn can considerably affect spinning performance, particularly rotor spinning, and yarn quality. if the percentage of trash is more than we have to do more opening and cleaning which results more neps. Short fibers and impurities .If the percentage is low then the yarn quality is increased
6)On 03/06/2010 MTM issued cotton having floating fiber 16.01.The cotton was processed in three days and on 07/06/2010 yarn U % was 9.87.It was reduced from 10.22 .which was processed on 05/06/2010.It shows positive impact on yarn U% . .7)On 01/10/2010 MTM issued cotton having floating fiber 21.41.The cotton was processed in three days and on 04/10/2010 yarn U % was 10.26.It was increased from 10.1which was processed on 02/05/2010.It shows negative impact on yarn U% .
Effect of floating fibers: The negative effects of the presence of a high proportion of short fibres are well known. A high percentage of short fibres are usually associated with,
- Increased yarn irregularity and ends down which reduce quality and increase processing costs - Increased number of neps and slubs which is detrimental to the yarn appearance - Higher fly liberation and machine contamination in spinning, weaving and knitting operations. - Higher wastage in combing and other operat
8) On 07/05/2010 MTM issued cotton having Staple length1.054 .The cotton was processed in three days and on 11/05/2010 yarn U % was 9.91.It was reduced from 10.11 which was processed on 09/05/2010.It shows positive impact on yarn U% . .
9)On 21/05/2010 MTM issued cotton having Staple length 1.048 .The cotton was processed in three days and on 24/05/2010 yarn U % was10.25.It was increased from 10.11which was processed on 26/05/2010.It shows negative impact on yarn U% .
Effect of staple length: Length, length uniformity and length distribution, including short fibre content, are probably the most important cotton fibre properties, although their importance does depend somewhat on the spinning system used.The staple length affects more on the yarn quality .The longer the staple length the yarn will be stronger and uniform .An increase of 1 mm in fibre length increases yarn strength by some 0.4 cN/tex or more. If the staple length is short .then yarn will be uneven and weak
10)On 03/05/2010 MTM issued cotton having Uniformity ratio 47.9.The cotton was processed in three days and on 07/05/2010 yarn U % was 10.45It was increased from 10.1which was processed on 03/05/2010. It shows negative impact on yarn U%
11)On 03/06/2010 MTM issued cotton having Uniformity ratio 50.19 .The cotton was processed in three days and on 07/06/2010 yarn U % was 9.87 .It was reduced from 10.22 which was processed on 05/06/2010.It shows positive impact on yarn U% . .
Effect of uniformity ratio: Length uniformity or uniformity ratio is determined as “a ratio between the mean length and the upper half mean length of the fibers. If the uniformity ratio of fibers is good then more the yarn will be uniform and if the uniformity ratio is low then it gives less uniform or less even yarn. Which lowers the quality of the future textile product?
12)On 08/05/2010 MTM issued cotton having Micro Nair 5.15 .The cotton was processed in three days and on date 10/05/2010 yarn U % was 10.99.It was increased from 10.14 which was processed on 08/05/2010.It shows negative impact on yarn U% .
13)On 30/05/2010 MTM issued cotton having micro Nair 4.6 .The cotton was processed in three days and on date 02/06/2010 yarn U % was10.6.it was reduced from 10.11which was processed on 31/05/2010 It shows positive impact on yarn U% . .
EFFECT OF MICRO NAIR: If the value of mice is more than it’s create thick and thin places in the yarn and the quality of yarn. So there should be moderate value.