DE1052058B - Textile melts - Google Patents

Description

In order to make textile fibers pliable for spinning, means are required that are during the Storage of the textiles do not volatilize and can be removed by simply washing them out. Even the consistency of such lubricants should be such that they can be compared to conventional methods of application adjust.

So far, mineral oils in particular have been used as lubricants for textiles. Against the use of these oils, as they have hitherto been used either alone or in a modified form, can be objected to that they evaporate quickly and are difficult to remove. So have difficulty removing the Oils often make dyeing and other post treatments difficult. In addition, when storing textiles the volatilization of the mineral oils makes the material hard and unusable for the manufacture of textiles.

Also less volatile lubricants that do not consist of mineral oil and whose lubricating power is effective is known. The usefulness of these lubricants is controversial, as they are very difficult to wash out and are viscous.

It has been found that blends of 51 to 98% of a refined mineral oil and 49 to 2% of the following Mixture are particularly suitable as smelting. The mixture contains on the one hand 50 to 20% of a Compound of the general formula

Rt (C ₂ H ₄ O) _is C _i H ₄ RJ _ej

in which R denotes a radical of aliphatic alcohols, acids, amines and amides which are formed by reducing by one active hydrogen atom and which contain 12 to 18 carbon atoms exclusively substituted by hydrogen; R is a hydroxyl group or the radical R; λ ; a number from 0 to 9 and y an integer below 3, and on the other hand 50 to 80% of a mineral oil-soluble partial ester of hexitol or hexitane polyethylene ether and fatty acids with 12 to 18 carbon atoms.

The mixture preferably contains from 75 to 98% mineral oil, from 1 to 12.5% of the compound indicated in the formula and 1 to 20% of the partial ester.

The formula given includes compounds such as

Polyoxyethylene ether of lauryl alcohol with two

Oxyethylene groups,
Ten cetyl alcohol polyoxyethylene ether

Oxyethylene groups,
Polyoxyethylene stearic acid with three

Oxyethylene groups,
Seven polyoxyethylene palmitic acid

Oxyethylene groups,
Polyoxyethylene stearylamine with four

Oxyethylene groups,

Applicant:

Atlas Powder Company,
Wilmington, Del. (V.St.A.)

Representative: Dr. W. Beil, lawyer,
Frankfurt / M.-Höchst, Antoniterstr. 36

George Downes Jefferson, Embreeville, Pa.,
and Richard De Mott Fine, Merchantville, NJ
(V. St. A.),
have been named as inventors

Polyoxyethylene stearylamine with ten

Oxyethylene groups,
Polyoxyäthylenlaurylamin with a

Oxyethylene group,
Polyoxyethylene stearic acid amide with five

Oxyethylene groups,
Polyoxyäthylenlaurinsäureamid with ten

Oxyethylene groups.

Similar and dissimilar long-chain amino, amido and carboxy radicals can be found in the compounds be substituted at each end of the oxyethylene chain, such as. B. in the diester of polyoxyethylene glycol (see example 10).

The partial ester used as a dispersant must be oil-soluble. Its job is to keep the mineral oil and to make the non-mineral oil phase compatible with one another and the aqueous emulsion of the mixture to be stable. The partial esters are converted by acids such as myristic, stearic, palmitic, Lauric and oleic acid with Hexitan- or Hexitpolyoxyäthylenäthern obtained. Among these are the polyoxyethylene ethers of hexitol moiety esters of fatty acids containing 12 to 18 carbon atoms. The ratio of the oxyethylene groups to the fatty acid radicals should be 3 to 8.

809 768/514

Typical examples of mineral oil-soluble partial esters suitable as dispersants are

Polyoxyethylene sorbitan monostearic acid ester

with four oxyethylene groups per mole,
Polyoxyethylene sorbitan monooleic acid ester

with five oxyethylene groups per mole,
Polyoxyethylene mannitane monolauric acid ester

with three oxyethylene groups per mole,
Polyoxyethylene sorbitan tristearic acid ester

with twenty oxyethylene groups per mole,
Polyoxyethylene sorbitan trioleic acid ester

with twenty oxyethylene groups per mole,
Polyoxyethylene sorbitan tripalmitic acid ester

with sixteen oxyethylene groups per mole,
Tetraoleic acid ester of polyoxyethylene sorbitol

with thirty oxyethylene groups per mole,
Tetralauric acid ester of polyoxyethylene mannite

with twenty-five oxyethylene groups per mole,
Monolauric acid ester of polyoxyethylene sorbitol

with three oxyethylene groups per mole, monopalmitic acid ester of polyoxyethylene sorbitol

with six oxyethylene groups per mole.

The mixtures according to the invention are made by mixing the ingredients, preferably simultaneously Heating, established. The lubricants are inherently not soluble in mineral oil, but become by the oil-soluble dispersants in solution or

brought fine suspension. At certain concentrations it can happen that some of the mixtures after the compilation are slightly clouded. However, this cloudiness impairs the usefulness of the mixtures not. Solutions that appear clear are preferable if the lubricant is to be stored for a long period of time got to. In many cases, adding a very small amount of water will result in a cloudy dispersion removes the haze.

These mixtures have a low viscosity compared to the mineral oils used therein and will on textile products with normal facilities, such as those needed for the use of mineral oils, upset. The evaporation of the mineral oil does not affect the lubricating effect, as the polyoxyethylene lubricant is not volatile and because it is a much more effective lubricant by weight than the mineral oil. In addition, the polyoxyethylene lubricant has a softening effect, especially on viscose yarn, which cannot be achieved with mineral oil. The mix, including the Mineral oil can be removed from the textile materials by simply washing them out.

The following examples illustrate the invention. The related mineral oil was a refined, white one Paraffin oil. The oil is heated to about 60 ° C, the dispersant and lubricant are preheated and added with stirring.

example percentage
mineral oil Dispersants Vo lubricant % 1 95 Polyoxyethylene sorbitan
monooleic acid ester (five
Oxyethylene groups) 2.5 Polyoxyethylene stearyl
alcohol (three oxyethylene
groups) 2.5 2 80 the same thing 5.0 Polyoxyethylene stearyl
alcohol (five oxyethylene
groups) 15.0 3 80 the same thing 15.0 Polyoxyethylene stearic acid
(seven oxyethylene
groups) 5.0 4th 95 the same thing 2.5 Polyoxyethylene stearylamine
(four oxyethylene groups) 2.5 5 95 Polyoxyethylene sorbitan
tripalmitic acid ester
(sixteen oxyethylene
groups) 2.5 Polyoxyethylene stearic acid
amide (five oxyethylene
groups) 2.5 6th 75 Tetraoleic acid ester of poly
oxyethylene sorbitol (thirty
Oxyethylene groups) 15.0 Polyoxyethylene oleic acid
(two oxyethylene groups) 10.0 7th 60 Polyoxyethylene sorbitan
triolic acid ester (twenty
Oxyethylene groups) 25.0 Polyoxyethylene laurylamine
(three oxyethylene groups) 15.0

The following examples describe typical forms of use of the lubricants according to the invention.

Example 8 g ₅

Twisted polyamide yarn of 20 denier previously sized with polyvinyl alcohol borate, is run on a cone machine over a roller that rotates in a container in which there is a lubricant with the following composition:

Polyoxyethylene stearic acid

(three oxyethylene groups) 2.5%

Polyoxyethylene ether of sorbitan monooleic acid ester (five oxyethylene groups) 2.5%

White mineral oil (50 w) 95%

The yarn treated in this way produces excellent knitting results. Also lets

Claims (4)

1 the agent can be easily removed by washing with conventional agents. The dyeing process is normal. Example 9 Dyed knitting yarn made of cotton is treated on a cone machine with a 20% strength aqueous emulsion of the lubricant mentioned in Example 2 by sliding it over a roller which rotates in a tub. With the yarn treated in this way when using a circular knitting machine to knit, excellent results are achieved; the handle of the product obtained here is satisfactory. Example 10 Washed wool is sprayed with a lubricant of the following composition: Polyoxyethylene stearic acid ester (ten oxyethylene groups) 10% polyoxyethylene ether of mannitan monooleic acid ester (five oxyethylene groups) 10% white mineral oil (50 w) 80% The wool treated in this way can be combed easily and the spinning properties are satisfactory. EXAMPLE 11 Washed wool is treated as in Example O with a 20% strength aqueous emulsion of a lubricant of the following composition: polyethylene stearylamine (ten oxyethylene groups) 5% polyoxyethylene ether of the sorbitan monool acid ester (five oxyethylene groups) 15% white mineral oil (50%) 80% cellulose acetate is treated as it comes from the spinneret using a lubricant with the following composition: Polyoxyethylene oleic acid (nine oxyethylene groups) 10% polyoxyethylene ether of the sorbitan monooleic acid ester (five oxyethylene groups) 10% white mineral oil 80% The amount of lubricant applied is approximately 0.5 % of the yarn weight. The yarn treated in this way has a soft hand and is less electrostatically charged. EXAMPLE 13 Freshly spun viscose artificial silk yarn which has been desulphurized, bleached and washed is treated in a machine suitable for processing spinning cake with a 1% aqueous emulsion of a lubricant of the following composition: polyoxyethylene stearic acid (seven oxyethylene groups) 10% polyoxyethylene ether of sorbitan monostearic acid ester (four oxyethylene groups) 10% white mineral oil (50 w) 80% The yarn prepared in this way and then spun off and dried is soft and easy to work with during winding and all other work processes. In order to determine the various coefficients of friction that result from artificial silk fibers pretreated according to the invention and according to known methods on rollers made of stainless steel, comparative tests were carried out with the following textile melts: 1. Textile melts according to the present invention: (a) 80% white mineral oil (SAE viscosity = 50), (b) 10% 2-oxyethylene stearic acid (lubricant), (c) 10% 4-oxyethylene sorbitan monostearic acid ester (dispersant); 2. Textile smelts as in 1, but without component (b) and a correspondingly larger proportion of (a): 90% white mineral oil (viscosity = 50), 10% 4-oxyethylene sorbitan monostearic acid ester; 3.Textile melts as in 1, but without component (b) and a correspondingly larger proportion of (c): 80% white mineral oil (viscosity = 50), 20% 4-oxyethylene sorbitan monostearic acid ester; 4. Textile melts according to Example I of the USA patent specification 2,461,043: 95% white mineral oil (viscosity = 50), 5% 5-oxyethylene sorbitan monooleic acid ester. The rayon yarn was treated with equal amounts of the textile melts given above and with % relative humidity edited. The resulting friction values are given in the following table, the values obtained with the malt 1 have been designated as 100%. Lard Friction comparison value 1 100% ' 2 113% 3 121% 4th 124% The friction values show the superiority of the textile melts according to the invention. Claim: Textile smelts, characterized in that they contain 51 to 98% of a refined mineral oil and 49 to Contains 2% of a mixture which is composed of 50 to 20% of a compound of the general formula R [(C ₂ H ₄ O) _x C ₂ H ₄ R ₁ ] _v , where R is a radical of aliphatic alcohols, acids, amines or amides with 12 to 18 carbon atoms, R _{1 is} a hydroxyl group or the radical R, χ is a number from 0 to 9 and y is an integer less than 3, and 50 to 80% Partial esters of hexitol or hexitane polyoxyethylene ethers with C ₁₂ to C ₁₈ fatty acids which act as mineral oil-soluble dispersants, the ratio of oxyethylene groups to fatty acid radicals being 3 to 8. Documents considered: U.S. Patents Nos. 2,460,400, 2,461,043, 184 009, 2 436 219. © 809 768/514 2.59