High speed drafting - its impact on cots and aprons

High speed drafting  -

its impact on cots and aprons

Now-a-days, in normal ring spinning system to increase the productivity two key factors which determine the increased productivity are spindle speeds of ring frame and end breakage rate. Modern ring frames can run at high spindle speeds of 25000 rpm. End breakage rate in ring spinning is influenced by the quality of raw materials used, level of modernization and condition of machinery, type of opening and blending operations, regularity of draw frame sliver and roving, effective humidification control, use of optimum process parameters, efficient house-keeping and careful materials handling.

For a spinning mill, an increase in spindle speed leads to a reduction of overheads and wages costs per unit production. On the other hand increase in spindle speeds proportionately increases the load on drafting unit, Drafting speed will be increased with respect to spindle speed , drafting force gets increased in case of high draft ratio (in particular for processing long staple fibres).These factors directly or indirectly increase the mechanical load on cots & aprons. A spinning cot or an apron has to withstand these high speeds drafting with high draft ratio in order to deliver high quality yarns with better consistency.

Key words:

Draft, draft ratio, roller drafting, feed hank, delivery hank, apron surface speed, front cot surface speed, fibre pulling force, fibre gripping force , drafting force, resilience, abrasion resistance , wear and tear resistance.

Introduction:

Draft:

The amount of attenuation of textile material at different stages of spinning preparatory and spinning process, for example. 1 m of input material when delivered as 5 m is said to have undergone a draft of 5.In other words reducing the linear density of textile material with respect to time by passing the material through successive pair of rollers rotating at higher peripheral speeds.

Various formulas used in textile industry to calculate the draft as follows:

Drafting:

It is a process of reducing the bulk and weight per unit length of a semi processed textile material such as rove or sliver and simultaneously parallelizing its fibrous components, as it passes through the various machines used in making yarn

Roller drafting system:

Commercially, there are various methods to draft the textile fibrous material like roller drafting system applied at ring spinning, speed frame and draw frames etc, aero dynamic drafting functional at rotor spinning, electro mechanical drafting, frictional drafting, etc. Out of these techniques, roller drafting system is

the most commercially successful one due to its high versatility, simple design and construction, high reliability and can handle variety of fibres and a wide spectrum of count range can be spun.

3/3 roller drafting system at ring spinning

High speed drafting of textile material on 3/3 double apron drafting system and its impact on cots and aprons at ring spinning machine:

Theory:

High speed drafting:

Increasing the delivery speed or productivity of a spinning machine but maintaining the same hank or feed material linear density will proportionately increase the speed of drafting but draft ratio remains constant.

High draft ratio:

Maintaining the same delivery rate or productivity of the spinning frame but reducing the feed hank from finer side to courser side will proportionately increase the draft ratio.

High speed drafting with high draft ratio:

Increasing the delivery speed or productivity of a spinning machine and the same time reducing the feed hank from finer side to courser side will proportionately increase both the speed of drafting and also draft ratio.

Parameter	High speed drafting	High draft ratio	High speed drafting with high draft ratio
Front roller speed or Delivery rate	increases	remains same	increases
Feed hank	remains same	decreases	decreases
Surface velocity of apron	Increases	decreases	remains same
Surface velocity of Front top cot	increases	remains same	increases
Front zone Draft	remains constant	increases	increases

Case Study 1 Mills normal parameter to spun 100s Ne:

Make of RF	LR 6	Material Processed	100% Cotton
Drafting type	P 3-1	Fibre Length / Denier	35.5
Blend ratio	N/A	Total draft	35.71
Dyed / grey	N/A	Break Draft	1.136
Yarn Count In Ne	100s Cwd	Spindle speed	19000
Roving hank	2.8	FRS	12.46 Mts / Min
Roving TM	1.12	RF - TM	3.8

Parameter	Normal	High speed drafting	High draft ratio	High speed drafting with high draft ratio
Front roller speed or Delivery rate mts /min	12.46	16	12.46	16
Feed hank	2.8	2.8	2.0	2.0
Delivery hank	100s	100s	100s	100s
Surface velocity of apron in mts/min	0.396	0.509	0.283	0.396
Surface velocity of Front top cot	12.46	16	12.46	16
Front zone Draft	31.43	31.43	44	44

                                              

Impact of high speed drafting/ high draft ratio on cots & aprons:

1. The surface speed of front top roller cot increases as a result it has to make more revolution per unit time (rpm) as a result cots relaxation time (Rt) gets reduced proportionately. Here resilience property along with low compression set values of a cot plays a vital role. A cot having poor resilience will not recover its original geometry within that time interval and it may have permanent deformation leading to quality detoriation.

2. For the same time period, the cot and aprons should handle more volume of fibres since the productivity is more. Here abrasion resistance, wear & tear property along with other physical properties of the cots and aprons plays an important role.

3. Due to increased surface speed, handling high volume of fibres chances of lapping will be high (especially while using softer cots) due to excess static charge generation on the cots surface. In this case rubber compound conductive properties, core conductivity plays an important role.

4. In case of high draft ratio, the load on the aprons will be very high. This is due to the fact that front roller cot will have to exert more pulling force to get the fibres out of apron nip since surface speed of aprons will be lesser and more static friction takes place between fibers and apron surface. This increases the wear and tear of drafting apron.

5. The drafting combination had a significant influence on fiber speed. Increasing the drafting ratio will results in higher fiber speeds.

Conclusion:

High speed drafting with increased draft ratio significantly affects the life of individual drafting zone components especially cots & aprons. Frequency of flexing of bottom aprons at nose bar, wear out on both inner/outer layers generally increases Cots rubber compounds abrasion resistance, anti-lapping properties together with high resilience property plays a vital role. in deciding definitive yarn quality with consistency even at increased drafting speed with high draft ratio.

                                                                                                                            

Courtesy : Fibre2Fashion

DIFFERENT TYPES OF YARN COMPACTING SYSTEMS

DIFFERENT TYPES OF YARN COMPACTING SYSTEMS 


COMPACT SPINNING

In conventional ring spinning, fibres in the selvedge of strand emerging from front roller nip do not get fully integrated into the yarn because of the restriction to twist flow by the spinning triangle. These fibres show up partly as protruding hairs or as wild fibres.
The spinning triangle exists because of higher width of the strand as compared to final yarn diameter. Further the fibres are tensioned to varying extent depending upon their position in the spinning triangle. As a result full realization of fibre strength is not achieved in the yarn.
The hairiness gives a rough feel to the yarn. Variation in hairiness is a source of weft bars and warp way streaks in the fabric. Long protruding hairs from the yarn contribute to multiple breaks in weaving and fabric faults like stitches and floats.

This problem is solved by applying the compact spinning systems that increases yarn quality. It is carried out by means of narrowing and decreasing the width of the band of fibres which come out from the drawing apparatus before it is twisted into yarn, and by the elimination of the spinning triangle. It can be used for spinning both short and long staple yarns. 

The compact spinning process produces a new yarn structure, which approaches the ideal staple fibre yarn construction even more closely. This has positive effects on raw material use, productivity, downstream processing, and on the product appearance. 

Factors Affecting The Spinning Triangle

The twist that is transmitted to the yarn in the ring spinning process originates along the curve between the traveler and front drafting rollers. Transmission of twists is opposite to the yarn movement in this area. The traveler transmits twists to already drafted fibres as close as possible to the clamping point after the front rollers. However, the twists never reach the clamping point, because after leaving the front rollers the fibres tend to direct towards yarn axis. The different lengths of the path of the inner and outer fibres that form the yarn cause a spinning triangle in ring spinning.

If the spinning triangle is too short (a), then the fibres on the edge must be strongly deflected to bind them in. This is not possible with all fibres, and lost as fly. Thus with shorter triangle, smaller weak point resulting into fewer end breaks but makes the yarn hairy. On the other hand, a long spinning triangle (b) implies a long weak point and hence more end breaks giving smoother yarn and less fly.

The length of the spinning triangle depends on spinning geometry and twisting intensity. The form and dimensions of the spinning triangle significantly influence the structure, surface characteristics, physical and mechanical characteristics of spun yarn. Not all fibres that are placed at the external edges of the triangle can be spun into the yarn structure, and can leave the drafting equipment without having been spun into the yarn. Such fibres also increase yarn hairiness.

When the Open End (OE) process was commercialised, the future of conventional ring spinning system was questioned. However, it is now accepted that ring spinning will continue to remain important because of its versatility. In view of the long-term prospects of this versatile spinning system, manufacturers/researchers have further developed and incorporated innovation on conventional ring spinning system. One of the examples of such developments is 'Compact Spinning System'. With the installation of compacting system, the yarn quality is improved, mainly because of the less hairiness and incorporation of more fibres in the yarn body.

Compact spinning system

The demand from the modern machines is to run at higher speed, produce better quality product, which should be suitable for further processing and give benefit in the downstream processing. Importance also is given to reduce personnel/labour required, which may not be much relevant in countries like India where labour is much cheaper. Thus the innovations on the machines are incorporated keeping these factors in mind.

Compact spinning is such a system where the yarn can be produced with higher speed, and better quality and which gives benefit in the downstream. Consequently, fabric made from the compact yarn gives better look. In conventional ring spinning system, the width or spread of the fibres emerging out from the front roller is greater than width or diameter of the yarn. Since the twist is not fully penetrated into the front roller nip, there is always a 'Delta Zone' called "Spinning Triangle" (Figure 1).

If the twists are imparted, the fibres at the edges are either loosely bound or lost as a fly and produce hairy yarn. The main purpose of the Compact Spinning is to eliminate spinning triangle at front roller, technically speaking the 'weakest point' of the ring spinning (Figure 2). The elimination of the spinning triangle results in permanent change of yarn structure, which distinguishes the compact spinning from conventional ring spinning.

Methods of compacting fibre strand

In compact spinning the mass of fibres is condensed before twist is imparted. This condensation happens in so called 'Condensing Zone' following the main drafting zone⁽¹⁾. Different machine manufactures are using different methods to condense the fibres emerging out from the front roller. These methods are:

1. Aerodynamically compacting system: a) Suction by drum and b) Suction through perforated apron.
2. Mechanical compact system.
3. Magnetic compacting system. 
   
   
    
   
   
                            Figure  : Conventional (a) and compact (b) ring spun yarns

Aerodynamically compacting system

In this methods the condensation of the fibres strand take place with help of perforated drum or apron. The examples of aerodynamically compacting system are Com4Spin^® of Rieter, Elite^® Compact Spinning by Suessen, CompACT3 by Zinser, Com4^®wool by Cognetex, Olfil system by Marzoli, Toyota's compact spinning, etc. All these methods will be discussed in detail in the subsequent sections.

Com4Spin^® of Rieter

Com4Spin^® compact spinning system of Rieter produces a yarn what they call COM4^® yarn. Com stands for 'comfort 'as claimed by the manufacturer that the wear comfort is increased whereas '4' stands for distinct advantages of yarn(1), namely,

1. Lower hairiness
2. Highest strength elongation
3. Unequaled wearing comfort
4. Minimal environmental impact (favourable ecological balance)

The ComforSpin^® technology allows aerodynamic parallelization and condensation of the fibres after the main draft. Com4Spin^® compact process, as comparison to conventional spinning system, is shown in Figure 3. A 3-over-3 drafting system with double apron is followed immediately by the fibre compacting zone3. The compact zone consists of following elements (Figure 4):

1. Perforated drum.
2. Suction system.
3. Bottom roller.
4. Top roller.
5. Nip roller.
6. Air guide element.

The delivery cylinder of the drafting system has been replaced by a perforated drum⁽¹⁾. The directly driven perforated drum is wear-free surface and is also free of fibre drag. Each drum has an exchangeable stationary suction insert, with a specially shaped slot, which is connected to the machine's suction system⁽²⁾ and generates airflow from outside into the interior of the drum. The fibres supplied by the main draft of the drafting system are held firmly to the surface of the perforated drum by the air current and move at the circumferential speed of the perforated drum. The fibre web is compacted in the fibre compacting zone. The air current generated by the vacuum in the perforated drum enables the fibres to be compacted efficiently following the main draft. This compacting process is supported by a specially designed and patented air guide element⁽⁶⁾.

The special feature of "Air Guide element" is to enhance the compacting efficiency in the compacting zone (Figure 5). A second top roller located after the compacting zone, the so-called nip roll⁽⁵⁾, clamps the spinning triangle. As a result of the compacting process, width 'b' (Figure 3) of the fibre bundle entering the twist insertion zone is considerably smaller than width 'B' of the fibre bundle emerging from the drafting mechanism, so that the size of the spinning triangle is substantially reduced. Subsequent twist insertion is similar to that in the ring spinning process. Optimum interaction of the compacting elements ensures complete compacting of all fibres. This results in the typical properties of yarn as called by Rieter "COM4^® yarn". 

                                    Figure  : Profile of top roller and perforated drum
Characteristics of COM4^® yarn

The improvement in the yarn characteristics (Figure 6) due to ComforSpin^® Process as claimed by the manufacturer are as follows⁽⁴⁾:

The abrasion resistance (Staff tester) of COM4^® yarn is between 40% to 50% higher.

Hairiness (UT4) is 20-30% lower.

Hairiness (Zweigle S3 values) is much more sensitive and measured values are up to 60% lower by comparison.

Yarn strength is 8-15% higher.

Capacitive uniformity (UT4) also shows better results for yarns finer than 40s Ne.

Degree of sizing can be reduced thus reduces the cost of sizing and subsequent desizing (Figure 7).

Consequently the fabric made from the COM4^® yarn shows higher strength (Figure 8) and more abrasion resistance⁽⁵⁾ (Figure 9).

Suessen Elite^® Compact Spinning

An alternating approach to produce compact yarn is given by Suessen under the name Elite^® Compact Spinning⁽⁶⁾. As shown in the Figure 10, the drafting system is followed by condensing zone, which consists of profile tube (1), the lattice apron (2) and delivery top roller (3). The delivery top roller (3) is driven by front top roller (5) via a small gear (4). The profile tube (1) is closely embraced by a lattice apron (2) driven by delivery top roller (3). The profile tube is under negative pressure produced by suction unit (6). Profile Tube (1) has an oblique slot (Figure 11) extending up to the clamping point between profile tube and delivery top roller (7).

The fibres emerging from the drafting system are gripped by the airflow created by vacuum and lattice apron and transported towards the oblique edge of the slot and consequently condensed. At the delivery clamping line the fibre strand has achieved optimum condensation. After the clamping line, twist is imparted to an ideally straightened fibre strand, with individual parallel and optimally condensed fibres without protruding hair. In addiction, a slight draft is also applied to enhance consolidation that causes further reduction in the width of the strand during yarn formation.

Two different forms of suction slots are shown in Figure 11. Suction slot of form 'B' is for yarn finer than 30s Ne whereas 'A' type suction slot, with delta shaped beginning, is for yarn coarser than 30s Ne8. For processing carded yarn suction slot of 'A' form should be used whereas for combed and synthetic fibres 'B' type suction slot should be used. Slot applied at a certain angle to the flow of fibres enables the peripheral fibres to be parallelised along yarn core. Suessen offers different Compact Spinning systems for different application(7) as given in Table 1.

Table 1: Suessen Compact spinning systems for different application:

EliTe®CompactSet-S (for short-staple fibres, cotton, synthetics and blends)	Yarn Type	EliTe®CompactSet-L (for long-staple fibres wool, synthetics and blends)
EliTe®CompactSet-S	Single yarn	EliTe®CompactSet-L
EliCore®S	Core Yarn	EliCore®L
EliTwist®S	Two-component yarn	EliTwist®L
EliCoreTwist®S	Two-component yarn+ filament core yarn	EliCoreTwist®L

Advantages of Elite® Compact Yarn⁽⁹⁾

1. Higher work capacity by 30% (max).
2. Higher yarn strength (Figure 12a) by 20% (max).
3. Better elongation (Figure 12b) by 20%.
4. Lower hairiness (Figure 12c) by 85% (max) Zweigle S3.
5. Better yarn evenness.
6. Lower imperfection value (IPI).

The benefit range of Elite^® CompactSet (red zone) is shown in Figure 13. This range is the product of the two vectors for quality improvement and production increase⁽⁷⁾.

CompACT3 by Zinser

The compact spinning system by Zinser supplied under the trade name of CompACT³, is a pneumatic (aerodynamic) compacting system based on the fibres bundling/compacting via several suction points⁽¹⁰⁾. CompACT³ compacting zone is installed after 3-over-3 double aprons drafting system that consists of perforated aprons which is supplied with low pressure and of drive shaft (Figure 14). The bundle of fibres are guided over a perforation row with circular holes, diameter of which does not suck in the individual fibres and the holes distance, which allows a sufficient fixing over the fibre length (Figure 15).

The dimension of the holes diameter depends on the yarn count. It is claimed by the manufacturer that the compACT³ Apron has been developed in its functional design⁽¹⁰⁾. If it is required to extend the collection area, some of the holes are replaced by ellipses (Figure 16). These are design for including the individual fibres even more at the outside by means of presenting airflow. The distance of the perforation holes is chosen so that the desire hairiness is still kept. It is further claimed that apron design guarantees good fibre transporting feature, optimum sliding characteristics and very long service life under production conditions. The 'willingness to condense' is different for different fibres. This can be tackled with overfeeding of 0% for fibres those are very willing fibres up to an overfeeding of 4% for more critical fibres those are difficult to condense. 

                   Figure  : Drafting and condensing zone
Advantages of CompACT³ yarn

The advantages claimed by the manufacture are shown in Figure 17. These can be summarised as follows⁽¹¹⁾:

1. The UT4 hairiness for carded cotton CompACT³ yarn is 20% lower as compared to conventional ring spinning. The S3 hairiness value according to Zweigle reduced by 93% (max).
2. Yarn irregularities (Zellweger Uster) show improvements of 6% (max).
3. 25% (max) lower IPI values (Zellweger Uster).
4. 20% higher tenacity values compared to the values of conventionally spun yarns.
5. Productivity increase at the spinning machine is 10% (max) through increasing the spinning speed and/or reducing the yarn twist.
6. Displacement of the spinning limit by 15% (max). 
   
   
   
   
   
   

Com4^®wool by Cognetex

Com4^®wool is the trademark of the compact spinning for long staple fibres that Cognetex (an Italian based company) has developed for 'IDEA' make ring spinning machine in cooperation with Rieter⁽¹²⁾. This system performs fibre parallelisation and aerodynamic condensation thus reduces the spinning triangle. Compact yarn produced is very tight, smooth and with high strength as all the fibres are taken in by the torsion. Its special structure and uniformity provide considerable advantages compared to conventional yarns. Here front drafting roller is replaced by a perforated drum (Figure 18). This enables the airflow to compact the fibres directly on the drafting cylinder. It is claimed by the manufacturer that for the wool sector, a patented elastic control roller with a slant axis prevents fibres that are being pinched at the same time by the drafting system and the front roller, from being tensioned. The IDEA Com4^®wool spinning frame is available in two different configuration of spinning sections:

1. Compact spinning with conventional spindle.
2. Compact spinning with controlled balloon spindle.

The comparative spinning tests of worsted yarns, conventional/Com4^®wool (100% wool, Nm 40, ?m 104, 10500rpm) 13, as claimed by the manufacturer, are shown in Figure 19. There is overall improvement in the yarn quality in comparison to conventional yarn.

Olfil system by Marzoli

Olfil is the compact spinning system designed and developed by Marzoli⁽¹⁴⁾. The condensing system is positioned at the delivery of the drafting unit (Figure 20). The bottom section of the condensing system has one stainless steel pipe for every 8 spindles with a perforated apron at each spindle. The top section of the condensing system is composed of two pressure rollers driven by the toothed belt. For each 48 spindles section, there is one motorised inverter driven fan that provides suction for the condensing system. A wide area air distribution and compensation allows for the correct balancing of the suction.

An exhaust air distribution specially designed to prohibit turbulence that could otherwise damage the spinning provides the possibility for a centralised air recycling system. There is a provision to change the conventional spinning frame to compact spinning frame. It is claimed by the manufacturer that time required for installation of compact system per 8 spindles on Marzoli standard spinning frame is 45 seconds only⁽¹⁴⁾.

Toyota's compacting method

RX240NEW-EST-make Toyota's ring spinning frame is equipped with compact spinning system (Figure 21). The condensing device consists of suction slit and perforated apron and works on aerodynamic compacting principle⁽¹⁵⁾. The special features of the machine, as claimed by the manufacturer are⁽¹⁵⁾:

1. Smooth collection of fleece fibres by suction slit and perforated apron.
2. Precise slip-free rotation of the perforated apron because of positive drive of the top and bottom delivery rollers.
3. Inverter-controlled adjustable suction pressure.
4. Easily detachable condensing unit.
5. Perforated apron, driven by a bottom roller, is not affected by top roller diameter.
6. Easy switching over to compact and conventional spinning.
7. Placing the suction ducts on the upper part of the roller stands results in a simplified design and shortened piping route.
8. For easier handling, each 4-spindle condensing unit can be conveniently detached and disassembled without using special tools.
9. The rollers are driven by a geared front-bottom roller and maintenance-free carrier gear, resulting in a simpler structure.

Mechanical Compact System

Mechanical Compacting Spinning (MCS) is given by Officine Gaudino for long staple. This compact system makes the compact yarn without the use of air. The compacting of the fibre strand is carried out with smooth bottom front roller and an angled top roller. Officine Gaudino offers long staple spinning machine (Model FP 03) with mechanical compacting system. This compacting system does not require the additional suction system . The MCS consists of an additional smooth bottom front roller and an angled top roller. These rollers run at a slightly slower speed than the front drafting rollers and this 'negative draft', coupled with offset top roller, creates false twist which compacts the drafting strand as it comes out from the compacting zone. This system can be incorporated into the new machines and is claimed to be easily added or taken off the spinning frame.

Magnetic Compacting System

Magnetic Compact Spinning, as the name implies, is a compacting system that makes the compact yarn with the use of magnetic compactor. The RoCoS compact spinning system, developed by Hans Stahlecker of Rotorcraft Maschinenfabrik, Switzerland is incorporated into LMW's Ring Spinning Frame. RoCoS stands for 'RotorCraft Compact Spinning' system and it works without air suction and uses magnetic mechanical principle only . 

                                                    Figure  : Components of RoCoS device 

The bottom rollers⁽¹⁾, support the front roller⁽²⁾ and delivery roller⁽³⁾. The condensing zone extends from clamping line A to B. The very precise magnetic compactor⁽⁴⁾ is pressed by permanent magnets without clearance against cylinder⁽¹⁾. It forms, together with the bottom roller, an overall enclosed compression chamber whose bottom contour, the generated roller surface of the cylinder, moves synchronously with the strand of fibres and transports this safely through the compactor. The manufacturer offers two types of the compacting system⁽¹⁷⁾: 

                              

1. RoCoS 1: Suitable for 100% cotton and cotton/synthetic blends and 100% synthetic fibres with maximum staple length of 60 mm.
2. RoCoS 2: Suitable for 100% wool, 100% synthetic and wool/synthetic blends having minimum staple length of 50 mm.

Thus RoCoS compact spinning system does not require air suction, air pipes and perforation drum or apron. So it is claimed by the manufacturer that no extra power, extra maintenance or erection installation is required for this compacting method.

Precautions for compact spinning system

So these methods can be used to make compact yarn. But to work successfully with compact spinning system certain precautions have to be taken. These precautions are:

1. Extremely low degree of hairiness results in under lubrication of rings. So it is recommended that rings of higher strength and wear resistance should be used.
2. The overhead cleaner must be equipped with special blower nozzle so that the fibres in compact zone are not disturbed with the blower air.
3. Compact spinning frames must be separated from conventional spinning frames with some partition.
   
   
   In compact spinning the spinning triangle associated with conventional ring spinning is eliminated by pneumatic compaction, which happens by suction and compaction on a perforated revolving drum/ apron in the front zone of the drafting system. The process is characterised by the introduction of a fourth nip point downstream of the exit from the conventional 3/3 drafting system, which acts as an aerodynamic condenser.
   
   The aerodynamic condensing of the fibres through suction results in narrower spinning zone, and with individual fibres more effectively bound into the yarn assembly, it offers the potential to create a near perfect yarn structure by applying air suction to condense the fibre stream in the main drafting zone, thereby virtually eliminating the spinning triangle.
   
   In conventional spinning a spinning triangle is formed immediately after the drafting mechanism in the ring frame. The spinning triangle is a weak zone due to less twist in this region; under normal working conditions most of the breaks occur near-vicinity of the spinning triangle. The strength of the fibrous mass in the spinning triangle determines the attainable spindle speed. Hence, if the spinning triangle is avoided or its length reduced, the achievable spindle speed would be increased. It is with this objective in mind, compact spinning was being tried.
   
   Compact spinning technology has potential for improving both the quality and profitability aspects of cotton yarn manufacturing. Depending on the objectives of the textile manufacture, different approaches are available. One approach could be to reduce the cost of the raw material, while maintaining quality. Another could be reducing twist, while using the same raw material. Yet another is to eliminate some or all of the combing, while still producing acceptable yarn quality.
   
   Properties of compact yarn compared with that of conventional yarn
   
   With compact spinning yarn, strength and elongation at break are higher. Compact spun yarn has better abrasion resistance. Fabric properties in terms of breaking strength, breaking elongation and tear strength are also better with compact yarn. Table showing the comparison of yarn properties of compact yarn and normal spun yarn are given below.
   
   
   
   Abbreviation: ↑Improvement W.R.T.: With Respect To
   Results are of bulk production of COMPACT & NORMAL yarn
   
    
   
   
   Benchmarking of compact yarn with conventional ring spun yarn
   
   The following charts benchmark select properties of both combed and carded cotton yarns spun on compact spinning system and conventional ring spinning system. In carded/combed for fine counts, long/extra long cotton is used; same roving is used with respect to each count, on both systems. And highlight the superiority of compact yarn.
   
   Materials and method
   These studies were carried out on regular production in different mills by using their regular mixing. On conventional and compact yarn same roving is used and testing is done in their own laboratories.
   
   It can be observed that Compact Combed cotton yarns reported 3 per cent less Irregularity. 30 per cent less IPI, 7 per cent higher RKM, 10 per cent less UT-4 Hairiness and 70 per cent less S3 Hairiness.
   
   Over the conventional combed ring spun yarn.
   
   Similarly compact carded cotton yarn for the same count range resulted in 5 per cent less Irregularity, 35 per cent less IPI, 10 per cent higher RKM, 15 per cent less UT-4 hairiness and 80 per cent less S3 hairiness.
   
   Over the conventional carded ring spun yarn.
   
   Other than yarn hairiness. Other yarn parameters such as strength, elongation, short IPI, Classimat faults, etc of compact yarn are also better than ring spun yarn and these results are advantages in the downstream processing.
   
   Knitting
   
   Due to low hairiness, low pilling tendency ensures good wear behaviour and results in better running properties and improved quality. Since fibre fly and oil cannot combine to form clumps of fly, which are occasionally knitted into the fabric and can cause thread and needle breaks. The wear on guide elements, needles and sinkers is reduced as a result of lower residual dust content of compact yarn. Due to low twist, body twist is also minimised.
   
   Sizing
   
   Clinging tendency of compact yarn displays considerably fewer and less pronounced clinging phenomena. Lower clinging tendency of yarn results in improvement of reparability of the warp. This reduces the cost of sizing and subsequently de-sizing, at the same time, resulting in lesser environment pollution.
   
   Weaving
   
   Despite the lower degree of sizing, thread break rates are lower, which significantly improves efficiency.
   
   Finishing
   
   The higher stretch recovery is also retained in the finished fabric. This is an advantage, especially in shirting fabrics with non-iron finish. Printed fabrics' appearance looks better due to less hairiness.
   
   Twisting
   The advantage in spinning also has an impact, when it comes to twisting. In compact yarn, less twist is possible, without any loss of strength. This result in lower manufacturing cost and the opportunity to manufacture new and softer twist yarns.
   
    Singeing
     The customary addition of weight to the yarn count, which is burnt off in singeing is no longer necessary. This amounts to raw material saving. The re-winding process, which is usually necessary to remove the singeing dust for the ply/ single yarn can also dispensed with.
   
   Advantages of compact yarn
   Other than yarn hairiness, other yarn parameters such as Strength, Elongation, IPI and Uniformity are also better than ring spun yarn and these advantages can also exploited in downstream processing.
   
   Commercialisation
   The Compact Spinning System being commercialised is by Rieter is called Com4 Spinning. Suessen system was first introduced to the market at ITMA 99 in Paris. This covers a full spectrum of raw materials and counts.
   
   However, compact spinning system is also made by: Zinser, Toyota, Rotorcraft, etc; which are designed to accommodate the full spectrum of staple length spin today. These compact spinning systems offer the possibility of using cotton with short staple lengths to long, to produce high quality yarns that heretofore required long or extra long staple cottons.
   
   In Compact Spinning there are still doors to open, like carded compact yarn nearly equivalent to conventional combed ring yam, blended yarn, etc; all the possibilities are opening a wide field for the creation and development of future products and applications.
   Reduced yarn hairiness and improved tensile properties are the key benefits of the compact yarn. Both characteristics are crucial for yarn performance in downstream manufacturing processes. Compact spinning technology has potential for improving both the quality and profitability.
    These can be done by:
   
   • Reducing the cost of raw material while maintaining yarn quality;
   • Reducing twist while using the same raw material; and/or
   • Eliminating some or all the combing and still producing acceptable yarn quality.
   The advantageous compact yarns can be economically utilised in a variety of ways. All these possibilities are opening a wide field for the creation and development of future products and applications, and singeing can be completely or partially dispensed with. It can be said about sizing also, which also is a saving. If the strength of the conventional yarn is sufficient for the intended applications, using the compact technology will allow a reduction of twist. This means, increased production and reduced consumption.
   
   Other benefits are: Printing is more brilliant due to better dye uptake, piling resistance, and increase in lustre and strength. And last but not the least is compact yarn can be spun from less expensive raw materials and conventional combed yarn can be replaced by compact carded yarn.
   
   

Conclusion

It has already been proved and established by many researchers and industrial people that the compact yarns have improved quality in comparison to conventional yarns and subsequently results in substantial improvement in the downstream processing. There are many methods offered by the machine manufacturers to choose for making compact yarn. Some of these methods, especially based on aerodynamic compacting, are already proven and running successfully in the mills. Still there is scope for spinning mills to establish the workability of other compacting methods offered by the manufacturers.





Courtesy  : ITJ August 2009
                   ITJ August 2007

BAMBOO FIBRE - YARN - FABRIC

BAMBOO   FIBRE - YARN - FABRIC





Bamboo textile fibre is made from bamboo timber which has matured in the forest for at least 4 years.
  Bamboo botanically categorized as a grass and not a tree, bamboo just might be the world’s most sustainable resource. It is the fastest growing grass and can shoot up a yard or more a day. The first patents for bamboo paper occurred in 1864 and 1869.Mordern bamboo clothing was first introduced by Beijing University but commercial use increased during 2004-2010.
 Even in remote areas of China and India bamboo forests are highly valued and carefully tended and managed. In summer, when new shoots reach their full height, they are marked with a year code which makes sure they are harvested at the right maturity. When harvested they are taken to mills where they are crushed and submersed in a strong solution of sodium hydroxide which dissolves the bamboo cellulose. With the addition of carbon disulfide it renders the mix ready to regenerate fibres which are then drawn off, washed and bleached to a bright white colour and dried. The resultant fluff is very long in staple and visibly finer than other fibres. Then they are spun into yarn, like any other textile fibre. The longer staple and higher tensile strength is what makes a tough, soft yarn – which is not as susceptible to wearing and fraying as many other yarns. This is what gives bamboo fabrics excellent durability. The hollowness of the fibre contributes to its very high level of absorbency. But it also takes longer to dry on a clothesline. The hollowness of the fibre also enables it to hold dyes and pigments more readily and permanently, thus making it much more colourfast.
The two main chemicals used in the process are sodium hydroxide and carbon disufide.
It was only discovered that carbon disulfide was a nerve poison after many years of exposure at high concentrations by factory workers in Italy in the 1930s and 40s. With adequate ventilation it is not a problem these days and it breaks down when in contact with the natural elements. Neither carbon nor sulfur are poisonous elements.
Sodium hydroxide is also known as caustic soda, and it is true that it is strongly alkaline and will react with many substances. However, it is not toxic at all and is used extensively in cooking. Used in quite high concentrations it is what gives traditional pretzels their distinctive flavour.
 Bamboo leaves and the soft, inner pith from the hard bamboo trunk are extracted and crushed.The crushed bamboo cellulose is soaked in a solution of 15% to 20% sodium hydroxide at a temperature between 20 degrees C to 25 degrees C for one to three hours to form alkali cellulose. The bamboo alkali cellulose is then pressed to remove any excess sodium hydroxide solution. The alkali cellulose is crashed by a grinder and left to dry for 24 hours. Roughly a third as much carbon disulfide is added to the bamboo alkali cellulose to sulfurize the compound causing it to jell. Any remaining carbon disulfide is removed by evaporation due to decompression and cellulose sodium xanthogenate is the result.A diluted solution of sodium hydroxide is added to the cellulose sodium xanthogenate dissolving it to create a viscose solution consisting of about 5% sodium hydroxide and 7% to 15% bamboo fiber cellulose. The viscose bamboo cellulose is forced through spinneret nozzles into a large container of a diluted sulfuric acid solution which hardens the viscose bamboo cellulose sodium xanthogenate and reconverts it to cellulose bamboo fiber threads which are spun into bamboo fiber yarns to be woven into reconstructed and regenerated bamboo fabric. Newer manufacturing facilities have begun using other technologies to chemically manufacture bamboo fiber that are more benign and eco-friendly. The chemical manufacturing process used to produce lyocell from wood cellulose can be modified to use bamboo cellulose. The lyocell process, also used to manufacture TENCEL®, uses N-methylmorpholine-N-oxide which is non-toxic to humans and the chemical manufacturing processes are closed-loop so 99.5% of the chemicals used during the processing are captured and recycled to be used again. Nano Technology is being also used for Bamboo fibers. 

  Mechanical Processing
During the mechanical processing of bamboo, the bamboo plant is crushed into a pulp. The bamboo’s natural enzymes are used to form a mushy substance from which fibers can be combed out. These fibers can then be spun into yarn, which is then used as bamboo fabric or linen to make cloth products. The mechanical processing of bamboo fiber is very eco-friendly, and is similar to the manufacturing of flax or hemp cloth.

Chemical Processing
Chemical processing is the most common form of bamboo fiber processing. Though many chemical processing methods are not environmentally friendly, there are some methods that are more eco friendly than others. Chemical processing of bamboo fibers involves “cooking” the fiber using chemicals to create a kind of regenerated cellulose fiber, which can then be used for thread and woven into cloth fabric. All parts of the bamboo plant are used in the process of turning it into usable fabric.

Environmentally Friendly Chemical Processing
The Lyocell process is generally considered to be the most environmentally friendly method of manufacturing bamboo cloth fiber. This is because it is in general more sustainable than most common chemical processing methods. According to the FTC, Lyocell is defined as a cellulose fabric made by an organic solvent spinning process. The chemicals used in this processing method are non-toxic and much safer for humans than other traditional processing chemicals. About 99.5% of the chemicals used are captured in a close-loop container, which means they can then be recycled with minimal amounts of them being released into the environment, avoiding air and water pollution.

Right now, people are still in the process of the developing new manufacturing methods to add to the available “green” options of bamboo fabric making. One of these processing methods is Greenyarn, which makes use of chemicals to form nano bamboo charcoal particles that can be woven into fabrics.

Common Chemical Processing Method
The most common chemical method of bamboo fabric manufacturing involve the use of carbon disulfide. First, the bamboo is crushed and its moisture kept at about 65%. The substance is then sulfirized by the addition of the carbon disulfide chemical. This step turns the bamboo cellulose solution into gel, which is in turn diluted using sodium hydroxide. The ensuing product is a viscous solution that gets passed through various nozzles and then place into another chemical solution and left to harden. After it has hardened, it gets converted into thread and spun into actual, usable fabric.

Regardless of how it is processed, bamboo makes for a very versatile clothing material. It has antibacterial qualities, for one, which it retains even after multiple washings. This means that bacteria that tend to thrive in clothing and cause unpleasant odors tend to not be as present in bamboo fabric. Bamboo can even kill odor causing bacteria in the wearer’s skin. It also has insulating qualities that help keep you warm in winter and cool in the summer. 


The cellulase treatment harms the excellent functions of the bamboo fiber. Also, the product is expensive because mass production is very hard.
The present invention aims to solve such problems.

Solution to Problem

A method according to the present invention is for manufacturing blend yarn with bamboo fiber. The method includes: immersing bamboo in alkali solution; drying the bamboo took out from the alkali solution; obtaining bamboo fiber from the dried bamboo; performing a heat and pressure treatment over the obtained bamboo fiber; and mixing and spinning the treated bamboo fiber with second fiber to form blend yarn.
The term “bamboo” is intended to mean any plants belonging to Bambusoideae. It may include Bambuseae, Arundinarieae, Olyreae and the like. Phyllostachys bambusoides, Phyllostachys nigra, Phyllostachys edulis, Neosinocalamus affinis, or the like is preferable because they have high toughness and flexibility. Also, the bamboo is preferable within the first year of growing, i.e., logged before 12 months pass after a bamboo shoot becomes bamboo. More preferably, the age of the bamboo is between 2 and 7 months, because it has excellent fiber strength and easy processing. Also, this enables to log new bamboos every year in order to manufacture bamboo fiber.
Before the immersing, bamboo joints may be eliminated from the bamboo. Removal of the bamboo joints, which are very hard, makes it easier to get the bamboo fiber from the bamboo.
Preferably, bamboo surfaces are not eliminated from the bamboo. Residual bamboo fibers derived from the bamboo surfaces, which causes high antibacterial, increases antibacterial of the blend yarn.
Bamboo may be cut to a predetermined length. This increases uniformity of lengths of the bamboo fibers.
The alkali solution is liquid with a pH over 7. It may include sodium hydroxide aqueous solution, ammonia water, sodium bicarbonate liquid, and the like. Immersing the bamboo in the alkali solution makes binder materials, such as lignin, dissolved. This facilitates obtaining the bamboo fiber from the bamboo. Also, this softens the bamboo fiber, especially derived from the bamboo surface.
Preferably, pH of the alkali solution is 10 or more. higher pH promotes more dissolution of the binder. In the case of sodium hydroxide aqueous solution, its concentration is preferably over 1 weight %.
However, too high pH causes damage of the bamboo fiber. Thus, the pH of the alkali solution is preferably 12 or less, and more preferably 11 or less. In the case of sodium hydroxide aqueous solution, its concentration is preferably under 6 weight %, and more preferably under 3 weight %.
The immersing is performed for a sufficient period to make the alkali solution to soak into the bamboo and to dissolve the binder. A preferable duration depends on a thickness of the bamboo. Generally, it may be between 24 and 48 hours, or substantially 36 hours.
Preferably, the bamboo is not washed after took out from the alkali solution. This eliminates problems of industrial effluent polluted with the alkali solution.
The obtaining of the bamboo fiber is performed by dividing the bamboo into the bamboo fibers. The bamboo may be recarded using a recarding machine, and/or defibrated using a defibrating machine.
The heat and pressure treatment is for applying high temperature and high pressure objects, i.e., bamboo fiber. It may include dry distillation treatment, steam explosion treatment, and the like. This removes impurities, such as oil, water, worms, and the like. Residue of the alkali solution, such as sodium hydroxide, is also removed. Lignin is changed to polyphenol, which strengthens antioxidative effect. Also, increasing porosity notably reinforces adsorption of odor, adhesion of floating materials such as formaldehyde or the like, antifungal effect, and the like. Also, combining the heat and pressure treatment with the immersing treatment makes the bamboo fiber, especially derived from the bamboo surface, further soft to restrain prickle sensation.
The dry distillation treatment is for heating objects inside a hermetic vessel such as a pot. This causes pyrolysis without combustion.
The steam explosion treatment is for holding objects under hyperbaric environment, and then suddenly reducing the pressure. This causes breaking the objects in pieces.
Preferable maximum pressure achieved in the heat and pressure treatment is between 5 and 6 atmospheric pressures, i.e., more than about 5,000 hPa (hectopascal) and less than about 6,000 hPa.
Preferable maximum temperature achieved in the heat and pressure treatment is between 140 and 200° C., and more preferable is between 150 and 160° C.
Preferable duration of keeping the maximum pressure and the maximum temperature is between 3 and 10 minutes.
Before the mixing and spinning, the bamboo fiber may be preprocessed, such as screening, drying, or the like. For example, bamboo fibers with lengths between about 15 and about 70 mm and average diameters of 0.2 mm or smaller, preferably between about 0.07 and about 0.1 mm, are extracted from the obtained bamboo fibers. longer and/or thicker bamboo fiber causes higher content rate in the blend yarn, which enhances functions derived from bamboo. Uniformity of lengths and/or thickness of the bamboo fibers promotes entanglement with the second fibers, which facilitates the mixing and spinning. Almost the same lengths of the bamboo fiber as that of the second fiber enables uniform mixing and spinning.
The second fiber may be any fiber except bamboo fiber. It may be derived from plant such as cotton or flax, animal such as sheep or silkworm, or any other sources. Also, it may be natural fiber such as cotton or silk, or artificial fiber such as nylon or carbon fiber.
Before the mixing and spinning, the second fiber may be preprocessed, such as mixing and blowing, cutting, or the like. For example, the second fibers may be cut to have about 40 mm lengths.
The bamboo fiber and the second fiber preferably have almost the same lengths. This enables uniform mixing and spinning
The mixing and spinning may include a mixing step, a carding step, a drawing step, a roving step, a fine spinning step, a winding step, and the like.
The mixing, or blending, step is for mixing the bamboo fiber and the second fiber. Changing a mixing ratio of the bamboo fiber to the second fiber enables the blend yarn to have various properties.
The carding step is for combing the fiber to form a sliver. This enables to uniform directions of the fibers, to remove dust, short fibers, and the like.
The drawing step is for drawing the slivers to form a drawn sliver. This produces uniformity of thickness of the slivers, and removal of short fibers. The drawing step may be performed repeatedly, i.e., applied to the drawn slivers.
The roving step is for drafting and twisting the sliver such as the drawn sliver, to form rove. This reduces the thickness of the sliver.
The fine spinning step is for further drafting and twisting the sliver or rove, to form yarn.
The winding step is for rewinding the yarn to form a large package. This enables to remove neps, dust, yarn unevenness, or the like.

Advantageous Effects of Invention

The present invention enables to manufacture blend yarn with bamboo fiber with low-cost, while keeping the excellent properties of the bamboo fiber. Products using the blend yarn inherits excellent functions from bamboo, such as high strength, antibacterial effect, antioxidative effect, deodorant effect, and soundproof effect, with no problems of texture and dyeability.

BRIEF DESCRIPTION OF DRAWINGS

Referring to the accompanying drawings, embodiments will be described in detail. the embodiments and the drawings are provided only for more complete understanding of the present invention. They are not intended to limit the present invention in any meanings.


Manufacturing Bamboo fiber
As shown in FIG. 1, Bamboo is firstly provided, for example, by logging bamboo within the first year of growing. And, bamboo splitting machine is used to split the provided bamboo into 4 to 6 pieces. Then, bamboo joints are eliminated from the split bamboo pieces. It should be noted that bamboo surfaces are not eliminated, in contrast to conventional methods. This enables blend yarn to inherit excellent properties, such as antibacterial, from the bamboo surface.
Next, the bamboo pieces are immersed in 1 to 6%, preferably 1 to 3%, sodium hydroxide aqueous solution. They are left as they are for about 36 hours.
Then, the bamboo pieces are took out from the solution. And, the bamboo pieces are drained and dried.
Next, bamboo fibers are obtained from the dried bamboo pieces. In some embodiments, a recarding machine may be used to scrape the bamboo pieces to make small fibers. Alternatively or Additionally, a pair or pairs of rollers may be used to crush the bamboo pieces to make them thinner, and a defibrating machine may be used to defibrate the crushed thin bamboo pieces to get fine and long fibers. In the same manner as strip processing of metal plates, each of the pairs of the rollers may be spaced with a different gap width, and they may be arranged in descending order of the gap widths. The rollers may have grooves with different shapes.
Then, the obtained bamboo fibers are screened to uniform their lengths and thickness. In some embodiments, the screening may be performed by eliminating nonstandard bamboo fibers, such as with lengths under 15 mm, with lengths over 70 mm, with average diameters under 0.07 mm, and with average diameters over 0.1 mm. The remaining bamboo fiber may further be dried.
Finally, dry distillation treatment is applied to the bamboo fibers. The dry distillation may be performed under 5.5 atmospheric pressures and 156° C. Alternatively, steam explosion treatment may be applied to the bamboo fibers.

Manufacturing Blend Yarn

As cotton fibers are firstly provided, as well as the manufactured bamboo fiber. The cotton fibers may have lengths of about 40 mm. Alternatively, silk fiber may be provided. The silk fiber may be cut to have about 40 mm lengths.
Next, a mixing and blowing machine is used to mixing and blowing the provided cotton fibers to form a lap , which has a sheet shape  and which includes a large number of randomly entangled cotton fibers. This eliminates dust adhered with the cotton fibers. Different types of cotton fiber may be mixed. This restrains un uniformity of quality. The lap may be wound around a roller.
Then, the cotton fiber lap is mixed with the bamboo fibers to make mixed fiber. The blend ratio may be arbitrary. Proportion of the bamboo fibers over 50% facilitates to exert excellent effect of bamboo fiber. In contrast, lower ratio of the bamboo fiber makes the mixing and spinning easier. However, a ratio of the bamboo fiber is preferable to be a few % or more, in order to keep excellent properties derived from bamboo.
Next, a carding machine is used to comb the mixed fiber to form a sliver. This makes the mixed fiber separated to each of the fibers, and arranged parallel. Also, small dust and short fibers are removed. Remaining long fibers, which include a large number of bamboo fibers and cotton fibers  are shaped into a thin sheet, which is converged to form a converged sheet  with a triangle shape, which is further converged to form a sliver  with a string shape.
A drawing machine is used to double 6 or 8 strings of the slivers and draft them to increase their lengths by 6 or 8 times, to form one drawn sliver  with a string shape. This makes the fibers straight, and eliminates unevenness of thickness to make the drawn sliver uniform. Also, short fibers are removed. A plurality of the drawn sliver may be drawn to form one further drawn sliver. The drawing step may be repeated 2 times or more.
Then, a roving machine is used to draft and twist the drawn sliver to form a rove. This makes the rove sufficiently thin to make blend yarn. The rove  may be wound around a bobbin.
Next, the rove is further drafted and twisted to form a blend yarn, which is an end product. The twist of the blend yarn may be between 150 and 3000 turns per meter. The blend yarn may be immersed in and thereby coated with paste of arum root. This significantly enhances its fineness, and it can be used for making beautiful fabric or knitting. The blend yarn may be wound around a bobbin.
Finally, plural strings of the blend yarn are wound together to make one large package. The package may be shaped into a cone.
The blend yarn manufactured in this manner has about twice the strength of yarn made of only cotton fiber. Also, it has an adsorbing effect of formaldehyde or the like, a deodorizing effect, a soundproof effect, and an antibacterial effect against Staphylococcus aureus or the like. These effects are remarkable, and scarcely decreased even when laundered. The blend yarn is suitable to be used in products, especially required to have antioxidative effect, antibacterial effect, and/or deodorizing effect.
When the blend ratio of the bamboo fiber to the cotton fiber is 55:45, the blend yarn is suitable to be used for business shirts or jeans. This can be achieved by using cotton fiber with cotton count of 12, i.e., about 50 tex. When the blend ratio is 30:70, it is suitable to be used for socks or towels. This can be achieved by cotton fiber having cotton count of 20, i.e., about 300 tex. Using cotton fiber with cotton count of 5, i.e., about 120 tex, enables to make blend yarn in which the bamboo fiber is more than the cotton fiber and which is suitable to be used for shop curtains or carpet rags.
The manufacturing method in this manner is suitable to mass production. Also, its environmental load is very small. Thus, the blend yarn can be manufactured with low-cost.
The above described embodiments are examples to make it easier to understand the present invention. The present invention is not limited to the example, and includes any modified, altered, added, or removed variations, without departing from the scope of the claims attached herewith. This can be easily understood by persons skill in the art.
 







                                                 
                                  Bamboo fiber                    

                   






 
 Structure of bamboo fiber


Longitudinal View



Cross sectional View

                                      





N








Characteristics of Bamboo Fiber
Bamboo fiber is naturally anti-bacterial, UV protective, green & biodegradable, breathable & cool, strong, flexible, soft and has a luxurious shiny appearance.

Smooth, Soft and Luxurious Feel: Bamboo fiber can be softer even than silk fiber when spun into yarn. It has a basic round surface which makes it very smooth and to sit perfectly next to the skin.

Good Absorption Ability: Bamboo fiber absorbs and evaporates sweat very quickly. It's ultimate breathability keeps the wearer comfortable and dry for a very longer period. It is 3-4 times more absorbent than cotton fabrics.

Temperature Adaptability: Fabrics made from bamboo fiber are highly breathable in hot weather and also keep the wearer warmer in cold season. Bamboo is naturally cool to the touch. The cross-section of the bamboo fiber is filled with various micro-gaps and micro-holes leading to much better moisture absorption and ventilation. It is also very warm in cold weather, because of the same micro structure as the warm air gets trapped next to the skin.

Antibacterial: Bamboo is naturally antibacterial, antifungal and anti-static. Bamboo has a unique anti-bacteria and bacteriostasis bio-agent named "bamboo kun" which bonds tightly with bamboo cellulose molecules during the normal process of bamboo fiber growth. This feature gets retained in bamboo fabrics too. Many tests have been conducted whose results show over 70% death rate after bacteria was incubated on bamboo fiber fabric. Tests by the Japanese Textile Inspection Association shows that, even after fifty washes, bamboo fabric still possessed these properties. It makes bamboo fabrics healthier, germ free and odor free.

 




















 


 


Bamboo knitting yarn is a relatively new entry in the knitting world, but it has become quite popular very quickly, and with good reason. Bamboo is a beautiful natural fiber that wears well and is often considered natural antibacterial.
Bamboo is a grass that is harvested and distilled into cellulose that is then spun into the yarn.

Positive Things About Bamboo Yarn

• Bamboo is a renewable resource. Bamboo can be harvested without killing the plant, and it only takes a few months before the plant is ready to be harvested again. That makes it an environmentally friendly choice                                                                    
• Bamboo yarn, when not mixed with unnatural fibers, is biodegradable.
• Bamboo yarn is often dyed with more natural dyes that are safer for the environment.
• Bamboo fabric is naturally antibacterial.
• Bamboo also has ultra-violet protective properties.
• Fabric knitted with bamboo is quite breathable and cool and has great drape.
• Bamboo has a good luster, similar to mercerized cotton.
• Bamboo is strong, flexible, and can be softer than silk when spun into yarn.

Potential Bamboo Negatives

• Bamboo yarn loses strength when it is wet and swells considerably in water.
• The yarn may not be very cohesive. Some brands split much more than others.
• Bamboo needs to be hand-washed, so it isn't a great choice for things that need to be washed frequently.

Tips for Working with Bamboo Yarn

• If the antibacterial property is something you are looking for, stick with a 100 percent bamboo yarn or choose one that has at least 70 percent bamboo for best results.

• Use blunt-ended needles to cut down on the splitting (perhaps bamboo needles?).
• Knit slowly at first to avoid splitting.
• If you're looking for strength in the fabric but are using a fine bamboo yarn, try knitting with two strands held together.

Chemically-manufactured bamboo rayon has some wonderful properties which are adored by conventional and eco-aware designers and consumers:

• Bamboo fabric has a natural sheen and softness that feels and drapes like silk but is less expensive and more durable.
• Bamboo clothing is easy to launder in a clothes washer and dryer.
• Because of the smooth and round structure of its fibers, bamboo clothing is soft and non-irritating, even to sensitive skin. Some people with chemical sensitivities can not tolerate bamboo clothing. We are not sure if this intolerance is due to the intrinsic nature of bamboo but it more likely because of other chemicals added or used during the manufacturing and finishing processes of the clothing.
• Bamboo is naturally anti-bacterial and anti-fungal supposedly because of a bacteriostatis agent unique to bamboo plants called “bamboo kun” which also helps bamboo resist harboring odors. “Kun” is also sometimes spelled “kunh”. The bamboo kun in bamboo fabric stops odor-producing bacteria from growing and spreading in the bamboo cloth allowing bamboo clothing to be more hygienic and to remain fresher smelling.
• Bamboo clothing is hypoallergenic.
• Bamboo is highly absorbent and wicks water away from the body 3 to 4 times faster than cotton. In warm, humid and sweaty weather, bamboo clothing helps keep the wearer drier, cooler and more comfortable and doesn’t stick to the skin.
• The structure of bamboo fibers make bamboo fabrics more breathable and thermal regulating than cotton, hemp, wool or synthetic fabrics.
• Bamboo clothing is naturally more wrinkle-resistant than cotton, and while it might still require ironing after washing, bamboo fabric can be ironed at a lower temperature than cotton. Shrinkage during washing and drying is minimal at warm temperatures.
• Bamboo fibers and fabrics absorb dyes faster and more thoroughly than cotton, modal and viscose with better color clarity. Bamboo fabrics do not need to be mercerized to improve their luster and dye-ability like cotton requires.
•  Disadvantages :  
•  Bamboo tends to shrink more than all cotton fabrics, therefore special laundering may be required. Bamboo fabric also wrinkles more than other fabrics. Depending on what the fabric is being used for, bamboo may not be the ideal choice. sometimes it is difficult to achieve antimicrobial finish.
  

The bottom line on bamboo. 
The growing of bamboo is environmentally friendly but the manufacturing of bamboo into fabric raises environmental and health concerns because of the strong chemical solvents used to cook the bamboo plant into a viscose solution that is then reconstructed into cellulose fiber for weaving into yarn for fabric.
Bamboo clothing marketers have found a variety of ways to put the most eco-friendly and sustainable face on the manufacturing of bamboo fabric. The dominant manufacturing process of hydrolysis alkalization and multi-phase bleaching is generally referred to as a rather benign process utilizing caustic soda and bleach. The chemicals used are known to create a variety of health problems and neural disorders which can be hazardous to the health of fiber manufacturing workers. If the manufacturing facility lacks adequate pollution control systems – all too common in developing countries where regulations and enforcement are nearly non-existent – then these toxic chemicals can escape into the atmosphere through air vents and smokestacks and into waterways through inadequately treated waste water disposal systems.
Some bamboo fiber manufacturing facilities trumpet their sustainability and green credentials by establishing ISO 9000 Quality Management policies and ISO 14000 Environmental Management policies. This is largely a PR red herring tossed by the manufacturing facilities and marketers because these ISO standards do not mean that the facilities, their manufacturing processes or their fabrics have been certified by any of the international certification bodies such as SKAL, Soil Association, Demeter, KRAV, or OKOTex.                        
       

Physical Parameters of Bamboo Fiber                                                                            Testing condition: Temperature : 20 ℃ Relative humidity: 65%±3%) 1.5DX38MM 2DX51MM 3DX86MM 3DX89MM 3DX102MM Dry tensile strength (CN/dtex) 2.15 2.11 2.4 2.36 2.29 Dry elongation at break (%) 24.9 25.7 21.2 19 18.1 Wet tensile strength (CN/dtex) 1.21 1.25 1.36 1.19 1.35 Linear density percentage of deviation (%) 0.6 0 -2.4 -1.8 -1.5 Percentage of length deviation (%) -3.1 1.4 -2.3 -3.6 -0.3 Over-length staple fiber (%) 0.4 1 0 0 0 Over-cut fiber (mg/100g) 3.2 10.1 3.5 0 1.1 Oil content (%) 0.2 0.26 0.28 0.3 0.3 Residual sulfur (mg/100g) 12.2 18.4 9.5 11.8 10.5 Whiteness (%) 68.8 59.9 66.3 61.8 66.5 Coefficient of dry tenacity variation (CV)(%) 16.72 8.66 12.11 10 12.6 Defect (mg/100g) 3.4 3.7 3.6 0.6 2.7 Oil-stained fiber (mg/100g) 0 0 0 0 0 Moisture regain (%) 10.82 12.96 11.4 10.37 10.29 Rate GRADE A GRADE A GRADE A GRADE A GRADE A
	Physical Parameters of Bamboo Fiber
	Testing condition: Temperature : 20 ℃ Relative humidity: 65%±3%)	1.5DX38MM	2DX51MM	3DX86MM	3DX89MM	3DX102MM
	Dry tensile strength (CN/dtex)	2.15	2.11	2.4	2.36	2.29
	Dry elongation at break (%)	24.9	25.7	21.2	19	18.1
	Wet tensile strength (CN/dtex)	1.21	1.25	1.36	1.19	1.35
	Linear density percentage of deviation (%)	0.6	0	-2.4	-1.8	-1.5
	Percentage of length deviation (%)	-3.1	1.4	-2.3	-3.6	-0.3
	Over-length staple fiber (%)	0.4	1	0	0	0
	Over-cut fiber (mg/100g)	3.2	10.1	3.5	0	1.1
	Oil content (%)	0.2	0.26	0.28	0.3	0.3
	Residual sulfur (mg/100g)	12.2	18.4	9.5	11.8	10.5
	Whiteness (%)	68.8	59.9	66.3	61.8	66.5
	Coefficient of dry tenacity variation (CV)(%)	16.72	8.66	12.11	10	12.6
	Defect (mg/100g)	3.4	3.7	3.6	0.6	2.7
	Oil-stained fiber (mg/100g)	0	0	0	0	0
	Moisture regain (%)	10.82	12.96	11.4	10.37	10.29
	Rate	GRADE A	GRADE A	GRADE A	GRADE A	GRADE A

100% Bamboo    Ringspun Yarn Technical Data
NE	16NE	21NE	24NE	30NE	32NE	40NE	50NE
NM	27NM	35.5NM	40.6NM	50.7NM	54NM	67.6NM	84NM
CV%	2	2	2.2	2.3	2.3	2.8	2.4
TWIST	523.1	583.7	781.7	712.8	724.8	815.7	930
TPI	13.08	16.51	19.54	17.82	18.12	20.39	23.25
CV%	2.6	3.2	2.81	3.79	3.38	2.46	3.8
STRENGTH(CN)	550.7	439.2	350	290.3	286.7	209.4	158
RKM	15.6	15.7	14	14.8	14.4	13.6	12.6
CV% RKM	9	8.1	8.2	8.3	8.3	9.5	11.9
ELONGGATION(%)	12.5	11.9	11.4	11.4	11.1	10.3	9.7
CV% ELONGGATION	13.2	12.1	10.3	10.1	9.4	9.5	13
IMPERFECTIONS
THICK/1000M	5	7	8	10	10	35	40
THIN/1000M	4	1	1	1	1	4	14
NEPS/1000M	9	10	15	23	25	39	51
HAIRINESS%	4	3.98	4.13	5.2	4.3	3	4
U%	11.2	10.3	13.2	12.4	12.3	13.5	14.8

70% Bamboo/30%cotton Ringspun Yarn Technical Data
NE	21NE	32NE	40NE
NM	35.5NM	54NM	67.6NM
CV%	2	2.2	2.7
TWIST	580	725	816
TPI	16.4	18.12	20.4
CV%	3.15	3.35	3.35
RKM	13.6	12.3	11.8
CV% RKM	8.3	8.5	9.5
ELONGGATION(%)	11.9	11.1	10.3
CV% ELONGGATION	12	9	9
IMPERFECTIONS
THICK/1000M	4	15	40
THIN/1000M	0	1	6
NEPS/1000M	10	29	47
HAIRINESS%	4	4.2	4.3
U%	10.4	12.3	13.9

Bamboo rayon filament Anti bacterial test	item	test result	test result
		75D/30F	120D/42F
	Dtex
	Average	82.8	134.9
	Deviation	-0.6	1.2
	CV%	1.66	1.47
	Dry tensile strength (CN/dtex)	2	1.97
	Dry elongation at break (%)	12.8	12.8
	Dry enlongaton CV%	8.68	8.39
	Color evenness	3.5	3.5
	F deviation	0	0
	Sizing rate%	1.76	1.49

                    
                                        Physical Parameters Compared With Other Fibers                      

Testing Item		Measure		Cotton 100%	Bamboo100%	comparison	Testing method
Antibacterial	Sterilization		Log	4.4	1.3	3.4 Times Up	JAFET Method
Activity	Reduction			7.1	1.3	5.5 Times Up
Electrostatic Propensity		Volt		(cotton)190	(cotton)15	12 Times Up	B Method
				(wool)680	(wool)290
Water Absorption		%		74.2	115.7	60%Up	Tumble Jar Dynamic Test
Drying Rate		g/202.5cm2		27.32	32.58	20%Up	B Method
Breaking Strength		%		50	65	30%Up	Gas Detection Tube M.
Bursting Strength		N		(warp)827.1	(warp)833.4	15%	C.R.E, Grab Method
				(weft)490.8	(weft)559.8
Abrasion Resistance		kgs/cm2		7.6	8.0	--	Diaphragm Method
Colorfastness To Light		Times		15000	Above20,000	30%Up	Martindale Method
Colorfastness To Washing		Grade		4-5	4-5	--	A-1 Method
Colorfastness To Rubbing		Grade		4-5	4-5	--	A-1 Method
Colorfastness To Perspiration		Grade		4	4	--	A-1 Method

                                                         

top specification	3D×88mm
Average length	68.7mm
Standard weight	21
Moisture regain %	10.7
Average weight (m/g)	20.8
Weight unevenness %	0.97
Coefficient of dispersion	20.1
Staple under 30mm	0.84
Ranges(+ -)	+0.4 -0.4
Mean-square deviation	17.7
Nub/g	0.25

                                         Physical parameters of Bamboo Top