Knitted fabric properties

Wales per cm of knitted fabric

Wales per cm is a very much important properties knitted fabric. Wales are perpendicular lines of loop along the knitted fabric length. Wales is the column of loops along the length of the fabric. Wales determine the width of the knitted fabric and are measured as Wales per centimeter. The number of Wales per cm is depend the types of knitted fabric. For examples, 10 wales per cm is taken for single jersey knitted fabric and 7 wales per cm is taken for rib fabric knitting, it is measured along the course direction by using counting glass and needle.

  

Process sequence for measuring wales per cm of knitted fabric:

· When loop transfer occurs it is possible to transfer a wale A to another B and to recommence knitting with the second needle in which case more than one needle will have produced intermeshed loops in the same wale. 

· In warp knitting a wale can be produced from the same yarn if the same guide laps the same needle at successive knitting cycles . 

· Wales are connected together across the width of the fabric by sinker loop(weft Knitting) or under laps (Warp knitting) 

· Wales show most clearly on the technical face and technical back of single needle bed fabric. 

· For single jersey fabric wales show on face side as V shape and from back side as half circle.

Course per cm of knitted fabric:

A course is a predominantly horizontal raw of needle loops produced by adjacent needle during the same knitting cycles. Course is a row of loops across the width of fabric. A course determines the length of fabric and measured as course per centimeter. The number of course per centimeter is called course/cm. It Is measured along the wale direction by using counting glass and needle.

REACTIVE DYES FOR WOOL FIBRES

Fig: Types of reactive dyes for wool

 

Fig: Reactions of bromoacrylamido reactive dyes with wool

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BATCH DYEING OF WOOL WITH REACTIVE DYES

Wool fibre is a animal protein fibre. The chemical construction of the wool fibre is very much complex but contains a reactive functional group that used to react with the reactive group of reactive dyes. The somewhat late development of fibre-reactive dyes was partly caused by a lack of appreciation of the considerable reactivity of made of cellulose fibres (specially cotton fibre) or proteins fibres (specially wool fibre).

A number of dyes developed for wool with 2-sulphatoethylsulphone or chloroacetylamino groups were not immediately recognised as reactive dyes. In fact, the development of reactive dyes really started with the introduction of the Procion reactive dyes for cotton by ICI in 1955. Despite the many possible reactive groups in reactive dyes capable of covalent bond formation with nucleophilic groups in wool, only a limited number of types of reactive dye have been commercially successful. Figure-1 shows the major types of reactive groups. The dye chromophores are essentially those used for cotton fibre reactive dyeing. The most important reactive groups in wool fibre are all nucleophilic and are found mainly in the side-chains of amino acid residues.






































They are, in order of decreasing reactivity, thiol (the –SH of cysteine), amino (–NH– and –NH2 of say histidine and lysine) and hydroxyl groups (–OH of serine or tyrosine). Difluorochloropyrimidines undergo aromatic nucleophilic substitution of one or both fluorine atoms, the fluorine between the two nitrogen atoms being the most reactive. Bromoacrylamido groups are stable in boiling water at pH 7 and react by both nucleophilic addition to the double bond and nucleophilic substitution of the bromine atom. They can form a three-membered aziridine ring that can react further with the protein fibre resulting in a new crosslink. The actual reactive dyes are probably dibromopropionamides, which eliminate HBr on dissolving in hot water. Methyltaurine-ethylsulphones and 2 sulphatoethylsulphones form the vinyl sulphone reactive group of reactive dyes relatively slowly at pH 5–6 (1 h at the boil). This allows some textile levelling during dyeing before the vinyl sulphone dyes reacts with the wool fibre and becomes immobilized. 

This is useful in hank and winch dyeing where the liquor/goods interchange is less favourable. In fact, all commercial reactive dyes for wool have absorption rates that are greater than the rate of reaction with the wool fibre to allow some migration. Chloroacetylamino groups (–NHCOCH2Cl) react by an SN2 mechanism (Scheme 16.5). Wool reactive dyes are applied like acid dyes in weakly acidic solution. The degree of exhaustion and fixation are usually very high and clearing of unfixed dye from the goods may only be needed for deep shades. Reactive dyes for wool tend to be unlevel dyeing and are prone to give skittery dyeings. They are used more on loose fibre and slubbing than on piece goods, where they accentuate fibre nonuniformity and poor, uneven fabric preparation. A number of amphoteric or weakly cationic auxiliary products are available to assist level dyeing. Despite their good light fastness and very good washing fastness, they are still not widely used, partly because of their high cost. Red to maroon shades are very popular but there are no black reactive dyes available that can match the chrome blacks on wool fibre.

MORE POST
Informative articles on Dye reactivity, Application and Storage of Reactive dyes 

Structural discussion of reactive dyes those suitable for cotton fibre 

After Treatment And Stripping of Reactive Dye 

Vinyl sulphone dyes or Remazol dyes are good quality Reactive dyes

  

REFERENCES

1. J Shore, in Cellulosics Dyeing, J Shore, Ed (Bradford: SDC, 1995).

2. D M Lewis, in Wool Dyeing, D M Lewis, Ed (Bradford: SDC, 1992).

3. A H M Renfrew, Adv. Colour Sci. Technol., 1 (1998) 12.

4. A H M Renfrew and J A Taylor, Rev. Prog. Coloration, 20 (1990) 1.

5. D A S Phillips, Adv. Colour Sci. Technol., 1 (1998) 1.

6. J A Taylor, Rev. Prog. Coloration, 30 (2000) 93

Informative articles on Dye reactivity, Application and Storage of Reactive dyes

Dye reactivity is very important terms for dyeing cellulose fibre. Shed of dyed textile fabric directly depend on the reactivity of reactive group. Highly reactive group of reactive dyes makes strong covalent bond with cotton fibre structure. The reactive groups of different types of reactive dyes have different chemical structures and show a wide range of reactivities. They were originally divided into cold- and hot-dyeing types but many current ranges would be better called warm dyeing. The most reactive types, such as DCT reactive dyes, are applied at lower temperatures (20–40 °C) and for dyeing process only require a weak alkali such as NaHCO3 or Na2CO3 for fixation. The less reactive types, such as MCT dyes required higher temperatures (80–90 °C) and stronger alkalis such as Na2CO3 plus NaOH. Many reactive dyes manufacturers now market several ranges of reactive dyes for cotton fibre , each with its own particular recommended dyeing procedure.

Gives some typical examples of reactive dyes based on the type of reactive grouping.
 

Reactive group	Commercial name of reactive dyes	Reactivity	Exhaust dyeing temperature (°C)
DCT	Procion MX (BASF)	high	25–40
MCT	Procion H (BASF) Basilen (BASF) Cibacron (Ciba)	low	80–85
MFT	Cibacron F (Ciba)	moderate	40–60
DCQ	Levafix E (DyStar)	low	50–70
DFCP	Drimarene K (Clariant) Levafix E-A (DyStar)	moderate to high	30–50
VS	Remazol (DyStar)	moderate	40–60
TCP	Drimarene X (Clariant)	low	80–95
NT	Kayacelon React (Nippon Kayaku)	moderate to high	100–130   *

Because most reactive dyes are prone to hydrolysis, their handling and use requires care. Most of the reactive dyes are readily water-soluble dye and the dye solution in dye bath is prepared in the usual way by pasting with water and then adding more water. The temperature of the water used depends upon the ease of solution and the reactivity of the dye. Hot water is not recommended for dissolving dyes of high reactivity, because of the risk of hydrolysis of the reactive group, but is suitable for the less reactive types.
 Special care must be taken for storing reactive dyes. Highly reactive dyes could be react with air. Once the dye solution of reactive dye has been prepared, it cannot be stored for later use without some risk of hydrolysis of the reactive group of reactive dyes. This decreases its fixation ability after dyeing and is a particular problem with the most reactive types of dye. Dyes containing a 2 sulphatoethylsulphone group, however, can be dissolved in neutral water at the boil without risk of hydrolysis. Formation of the reactive vinyl sulphone group requires the addition of alkali. Reactive dyes for printing are usually dyes of low reactivity so that the print paste can be stored for some time at room temperature without deterioration from hydrolysis of the reactive group. Reactive dyes of low reactivity and relatively high substantivity are valuable for dyeing using long (high) liquor ratios, using a winch machine for knitted fabric and twill tape dyeing. Exhaust dyeing method with low reactivity of reactive dyes at the higher temperatures required for fixation allows better penetration of the dyes into the cotton fibres. For continuous dyeing with reactive dyes stabilised liquid forms are available. Although these contain special pH buffers and stabilisers to minimise the hydrolysis reaction, they only have a limited shelf life. Many commercial reactive dyes are dusty powders but all physical forms must be handled with care. These dyes react with the amino groups in proteins in the skin and on mucous surfaces. Inhalation of the dust is dangerous and a dust mask is obligatory during handling. Reactive dye powders and grains are sometimes hygroscopic and drums must be carefully re-sealed. Most reactive dyes have a limited storage period, after which some deterioration can be expected. Standardisation and comparison of reactive dye powders or liquids cannot be done by the usual spectrophotometric procedure involving absorbance measurements of standard solutions. Both the reactive dye and its hydrolysed form are evenly coloured, but only the former is capable of reaction with the cellulose fibre during dyeing. Therefore, dyeing must be prepared and their colors compared with standard dyeings. Chromatographic techniques usually allow separation and quantitative measurement of the relative amounts of a reactive dye and its hydrolysis product in a given dye.
 
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