TEXTILE

RING FRAME MACHINE

Ring Frame Working diagram :

A - unwinding zone

B - drafting zone

C - winding zone

Objective of ring frame machine :

Attenuate the roving untill the required fineness achieved.
To impart strength to fibre strand by twisting it.
To wind up the resulting yarn in a form of suitable for storage, transportantion and futher processing.

Operating principle :

The roving bobbins (1) are creeled (A) in appropriate holders (3). Guide rails (4) lead the rovings (2) into the drafting arrangement (5) which attenuates them to the final required count.

The drafting arrangement (B) is inclined at an angle of about 45 – 60⁰. It is one of the most important assemblies on the machine since it has considerable influence on irregularities present in the yarn.

After the drafting arrangement, the machine have twisting and winding zone (C).

Upon leaving the front rollers, the emerging fine fiber strand (6) receives the twist needed to give it strength. This twist is generated by the spindle, which rotates at high speed. Each revolution of the spindle imparts one turn of twist to the fiber strand. Spinning of the yarn is thus complete.

In order to wind up the twisted yarn to bobbin mounted on Spindle( 8) , a traveller (9) is required to cooperate with the spindle. The traveller moves on guide provided on the ring (10) encircling the spindle.

The traveller has no direct drive; instead, it is carried along by the yarn it is threaded with. The speed of the traveller is lower than that of the spindle owing to significant friction generated between the traveller and ring.

This difference in speed enables winding of the yarn to bobbin.

Winding of the yarn on to the bobbin is done by raising and lowering the ring rail. The traverse stroke of the ring rail is less than that of the bobbin height. The ring rail must therefore be raised by small amount after each layer of coils.

Cross-section of the machine :

The cross-section of a typical ring spinning machine. The ring frames are two sided machines with the spinning positions located on both sides of the machine. Each spindle is a spinning position. The spindle rail houses the spindles. The creel housing the feed roving bobbins are arranged in two rows on each side of the machine. The drafting arrangement is carried on the roller beams. Each intermediate section stands on two feet adjustable in height by means of screws, thereby permitting easy leveling of the machine.

In modern machines, an auto-doffer is also provided. Including the auto-doffer, the width of the machine varies from 800 to 1000 mm (up to 1400 mm when the doffer arm is swung out). Today, the machine length can reach 50 m. Spindle gauges usually lie between 70 and 90 mm.

ADVANTAGE :

It is universally applicable, most of the textile fibres can be spun to required fineness.
The yarn spun from this machine demonstrate excellent quality features like uniform structure and good strength.
It is easy to operate as compared to other spinning machines.
The “know-how” for operation of the machine is well established.
It is flexible as regard to quantities in terms of blend and lot sizes.

DISADVANTAGE:

More process stages. Roving stage exists as an extra process compared to the other systems.
The high speed of the traveller damages the fibers.
The capacity of the cops is limited.
Energy cost is very high.

Study of bobbin speed,break draft constant, draft constant and twist constant and production of speed frame.

Experiment name :

Study on drafting and draft constant calculation of simplex m/c.

Introduction:

It is an important factor to make fibres long and thick by drawing while making yarn from fibres. It is known as drafting. This work is done by pairs of rollers. In simplex m/c using any of the following drafting system drafts applied.

1.Conventional/roller drafting system.

3 over 3 roller drafting system
4 over 4 roller drafting system

2.Modern drafting system

With apron
b.Without apron

In this simplex m/c conventional 4 over 4 roller drafting is used.

Description:

There are 4 pairs of rollers which are situated up and down in pairs. Usually the bottom rollers are made of steel and snarled type, which are kept on u type bearing. Usually the front roller can not be moved but the others can be moved according to fibre length. There is a steel trap at the back of the last roller which is spreaded along the full length. This strip has a hole through which the sliver is entered. These holes are called guide hole. These guide holes help the sliver to pass through the specific place of the rollers and the stip moves to and fro by a cam so that the rollers are not harmed in same place. The top rollers are coated with leather, flannel etc and loaded on the bottom rollers. The total draft given to the sliver is divided in to two. In back zone that is between the 3rd and back roller, the draft given is called break draft. This draft prepares the sliver for the final draft of the front zone and break the twist if remains in sliver. Its amount depends on twist, amount of feed, characteristics of fibre etc. It is usually form 1.1 to up to 2. The rest draft of the total draft is given between 1st, 2nd and 3rd rollers. The total draft in simplex is usually 10-15.

TWIST : is the spiral turns given to a yarn to increase the strength of the yarn. But in speed frame machine vary small amount of twist is given to the roving to make it able to wound onto a bobbin. For a fibrous material twist is measured by the parameter twist per inch (TPI), twist per centimeter or twist per meter (TPM). For the cotton sample twist is measured by TPI.

In speed frame machines twist per unit is varied with the variation of raw material and its different parameters. This variation of twist is inserted by changing a wheel that is connected with the main driving shaft named twist change pinion (TCP). And the multiply of TCP and TPI, present in a machine is called twist constant. This value is applicable for any required twist with corresponding TCP. So we can find out the required TCP to get a given TPI. The generalize formulae is as below:

Objects:

To find out the total draft of m/c.
To find out the draft of every zone.
To find out the draft constant of m/c.
twist constant.

Gearing diagram 4 over 4 Roller Drafting System:

GEARING DIAGRAM:

CALCULATION:

Singeing

The aim of singeing is to bum-off the protruding fibres and hairs from the fabric surface. The spinning process produces hairiness of the yam and lower the yarn counts (Ne 26/1 - 36/1) greater is the degree of hairiness. Therefore the reasons for singeing should be considered more closely.

(i) Singeing improves the end use and wearing properties of texiles.

(ii) The burning-off of protruding fibres results in a clean surface which allows the suructure of the fabric more clear.

(iii) Singeing reduces the fogginess caused by differing reflection of light by the projecting fibre and the dyed fabrics appear brighter.

(iv) Singeing is an effective means of reducing pilling in blended fabrics containing synthetic fibres.

(v) Unsinged fabrics soil more easily than singed fabrics.

(vi) A closely singed fabric is essential for printing fine intricate patterns.

(vii) Singeing process facilitates and speeds up desizing, if the fabric is impregnated with desizing liquor immediately after singeing.

On the other hand there are singeing faults which are not visible and once occurred can no longer be repaired. They are :

(i) Uneven singeing effect can cause streaks when the fabric is dyed, or bubbles when the fabric is finished.

(ii) In the cotton system singeing is done on the grey cloth, but for blended fabrics containing synthetic fibres grey state singeing is not advisable because small globules of melted synthetic fibres absorb dye preferentially,giving cloth a speckled appearance.

(iii) There is a possibility of thermal damage to temperature sensitive fibres, for instance polyester.

(iv) Stop-offs can cause heat bars on fabrics. Creasing produces streaks which is magnified when dyed.

(v) Protruding fibres are firmly bound by singeing on the surface by the sizing agent by hardening of the size and can lead to difficulties in desizing.

(vi) When singeing is done after dyeing, heat can cause colour loss from polyester portion of the blend because of sublimation of dye.

(vii) There may be reduction of tear strength due to over singeing of the fabric.

Generally, singeing is done on both sides of the fabric. No chemical change occurs in the fabric during singeing and the reaction is basically one of oxidation. Singeing and desizing can be frequently combined by passing the singed cloth through the water bath which include enzymes. The enzymes digest the various sizing agents, making it easy to remove them during the scouring operation. The

combined process also prevents possible latent damage to fabric from the singeing flame or heated plates.

Singeing different kinds of fibres fabrics

In singeing the short fibres are burnt off from the surface of the fabric by direct or indirect heating systems without damage to the cloth by scorching or burning. The thermal behaviour of different kinds of fibres are different and singeing at higher temperature is naturally associated with greater hazards on excessive contact period and may cause thermal degradation of the fibre. In case of vegetable fibres, grey singeing is necessary as it leads to slight yel-

lowing which needs subsequent bleaching to get high degree of whiteness. Grey singeing is also economical as singeing at any other stages of processing requires additional washing and drying. Vegetable and regenerated fibres fabrics can be singed very strongly with maximum burner intensity to obtain good results. Regenerated fibres normally bum to a little less easily than natural fibres.Wool has poor combustion properties and are very sensitive to temperatures and hence woollen materials are not subjected to intense flame like cotton. In woollen fabric flame is not generally allowed to penetrate the material and this can be obtained by blowing air through the fabric from the opposite side of the flame so that the flame will be restricted only on the surface of the fabric. Alternatively, the fabric can be guided to water cooled guide rollers allowing the flame to heat the cloth. When the flame strikes the fabric it is reflected by air/steam cushion created within the material. Amongst the synthetic fibres polyester has the greatest significance. It melts at 280-290~ but does not burn till about 500~ 'Reflector' or 'refractory' singeing machines produce smears of fused polymer on the surface of the polyester cloth and therefore unsuitable for polyester material. Thus flame singeing machine with a powerful flame is needed and also helps in overcoming the problems of oligomers i.e. the small chain polymers that come to the surface. High temperature singeing process may sometimes change the glass-transition temperature (Tg) of synthetic fibres that lead to uneven dyeing.For blended fibre fabrics singeing conditions are to be selected depending on the sensitiveness of the kinds of fibres to heat, blend composition, weight of fabric and fabric geometry. For example, singeing should be carefully conducted to avoid heat damage of the acetate component of the accetate/viscose blended fibre fabrics.Though singeing improves the restistance to pilling of the polyester/wool blended fabrics, but should not be carried out on low weight fabrics because of risk of damage. In the case of 80/20 polyester/cotton blended fabrics or fabrics with dented pattern, sometimes, the cloth gets weekened only in the thinner or shadow portion. This is not detected until the material reaches to finish folding. If singeing is carried out after dyeing the sublimation fastness of disperse dyes used must be adequate to

withstand the singeing conditions. Singeing machineries are mainly based on direct and indirect singeing systems. The cloth is first passed over one or more steam-heated copper drying cylinders to

remove the moisture and to raise the nap. The direct singeing may be done either on a hot plate, or on a rotary cylinder, or on a gas singeing machine or on a machine combining plates and gas burners. The special features of indirect singeing systems

are no flame contact, uniform singeing, heat retention zone and singeing by means of heat radiations. The indirect system produces fabrics which have a softer touch as compared to other methods. Gas singeing is more convenient, more economical and more effective than other methods and is well accepted commercially. The plate singeing and roller singeing machines are now out of date. Clean singeing of potentially troublesome synthetic fibres can be achieved by using the scavenger tubes which are specifically designed to avoid thermoplastic melt (beading) prob-

lems.

Plate singeing machine

The machine consists of two copper plates of about 1-2" thick. The plates are 58 Preparation Before Chemical Processes heated to bright red from the opposite side. The furnaces are fired by heavy petroleum oil, which is vaporised through special nozzles, by the action of steam, into a fine spray. The properly dried cloth passes over the plates at speeds up to 200 yards per minute, according to quality. A special traversing arrangement for the cloth is supplied to prevent local cooling of the hot plate. The singed cloth is then run

through water to extinguish the spark, passed through a padding mangle and delivered to a winch or plaiter. The machine is driven by electric motor, steam engine orbelt pulleys.

Rotary cylinder machine

In this type of singeing machine the cloth passes over a hollow cylinder which revolves slowly in the opposite direction of the goods. The hollow cast iron or copper cylinder may be fired internally. The cloth is drawn through the machine by a powerful squeezer nip, singed, run through water bath and plaited.

Gas singeing machine

Old singeing machines are often used which in their time worked acceptably when only pure cotton materials were singed, but which, however are no longer suitable for singeing of newer fibres and their blends. New technologies and techniques have been developed to suit the modem requirements.