DE911911C - Process for lightening non-white fabrics - Google Patents

Description

Method of lightening non-white fabrics In many branches it is customary in technology to lighten non-white fabrics by treating them at any stage of manufacture or even the finished product one as possible all light waves reflecting substance, practically a white pigment, adds. Such additives are, for example, natural and synthetic rubbers, plastics, Synthetic resins, synthetic fibers, paper, linoleum and others. m. made. To be brightened essentially lithopone, zinc oxide, barium sulfate, titanium white and similar white pigments used. In most cases it is desirable to use as little additive as possible to achieve the greatest possible lightening, since the additives are often other valuable Reduce the properties of the substance to be lightened. For the lightening it has In many cases the titanium dioxide proved to be particularly suitable, as it is a special has high color strength.

It has already been described that the color strength of a pigment Is a function of the particle size, furthermore that an optimum of the color strength at about i, u Particle size is titanium dioxide pigments. A proportionality between color strength and whitening power is also present with the commercially available titanium dioxide pigments.

There has now been a method of lightening fabrics that are given a Can incorporate lightening bodies, such as natural and synthetic rubber, plastics, Synthetic resins, synthetic fibers, paper, linoleum and others. m., with the help of rutile titanium dioxide found with the most uniform possible particle size, which consists in the fact that one A rutile titanium dioxide is added to the substances to be lightened, the one Particle size from about 0.2 to 0.14 lc. Has radius and, measured by the Reynold method ,,. shows a color strength of about 1600.

The method of determining color strength used in the pigment industry is published in Plivsical and Chemical Examination of Paints Varnishes Laquers Colors by H. A. G a r d n e r, Chapter 2, Pages 92 and 93, 8th Edition, January 1937, New York. With these rutile pigments with a particle size of 0.2 to o, .1 c, radius is a proportionality between lightening power and color power unavailable. Rather, the lightening effect is far above that of the general one Beliefs to be expected.

Such pigments can be obtained, for example, by eluting or centrifuging out the relevant portion of approximately 0.2 to 0.4 cc radius from rutile titanium dioxide pigments, which are obtained in known ways or by the method of patents 700 918, 707 020 and Additives.

With such a pigment it is possible, for example, to lighten a crude rubber mixed with 0.125 parts by weight of .Ultramarine with only @ parts by weight of a rutile pigment with a color strength of about 160o and a uniform particle size of about 0.2 to 0.4 / r radius to the same degree of brightness as by adding 12 parts by weight of a commercially available titanium dioxide with a color strength of 130o. The color strengths of the two titanium dioxide pigments with 1300 and 160o are in a ratio of 1: 1; 23, so that 1 kg of a pigment with a color strength of 10000 would correspond to an amount of 1.23 kg of a pigment of 1300. In actuality, however, the amounts used, as indicated above, are in a ratio of 9 parts by weight of pigment with a color strength of 100 to 12 parts by weight of a pigment with a color strength of 1300, i.e. in a ratio of 1: 1.33. It is not known what causes this surprising fact. Presumably this is the effect of a particularly peculiar inclusion of this homogeneous pigment in the substance to be lightened. The pigment distribution in rubber for the two pigments listed shows the: micrograph. On the left side of the photomicrograph a rutile preparation can be seen with an approximate radius of 0.2 to 0.4, while on the right side a commercially available titanium dioxide can be seen in the same dispersion medium and the same concentration. The yardstick is also. captured in the picture. A division means 1o u.

Example i A crude rubber containing 0.1250 / 0 L: ltramarine blue is measured with 12 0 / m of commercially available titanium dioxide with a color strength of 1300 according to R e y no 1 d, lightened. The color of the end product is identical to one second sample of the same raw rubber with the same ultramarine content and 9% of one Rutile pigment with a color strength of 1600 and a uniform particle size from about 0.2 to 0.4p radius.

Example e A crude rubber containing 0.25% cadmium sulfide selenide is made with 2% commercial titanium dioxide with a color strength of 1300, measured according to R e y n o 1 d, lightened. The color of the end product is identical to one second sample of the same raw rubber with the same cadmium sulfide selenide content and 90 / a of a rutile pigment with a color strength of 160o and a uniform Particle size from about 0.2 to 0.4, u radius.

EXAMPLE 3 A crude rubber containing 0.08% carbon black is lightened with 121 / o commercially available titanium dioxide with a color strength of i300, measured according to Reynold. The color of the end product is identical to a second sample of the same raw rubber with the same carbon black content and 9% of a rutile pigment with a color strength of 160 ° and a uniform particle size of approximately 0.2 to 0.4 cc radius. Example d. 100 g linoleum cement, 100 g wood flour and 25 g commercial titanium dioxide with a color strength of 1300 and 3 g basic lead chromate are processed in the usual way to make linoleum panels. The color tone is identical to that of a linoleum made with 19 g of a rutile titanium dioxide with a color strength of 160o and the same cement mixture with the same addition of basic lead chromate and a uniform particle size of about 0.2 to 0.4 u radius. For example, 5 100 g linoleum cement, 100 g wood flour and 25 g commercial titanium dioxide with a color strength of 1300 and 12 g ultramarine blue are processed in the usual way to make linoleum panels. The color tone is identical to that of a linoleum made with 19 g of a rutile titanium dioxide with a color strength of 160 and a uniform particle size of approximately 0.2 to 0.4 liters radius from the same cement mixture with the same ultramarine addition.

Claims (1)

PATENT CLAIM: Process for lightening substances into which a lightening body can be incorporated, such as natural and synthetic rubber, plastics, synthetic resins. Synthetic fibers, paper. Linoleum etc. with the help of rutile titanium dioxide with the most uniform possible particle size, characterized in that a rutile titanium dioxide is added to the substances to be lightened, which has a particle size of approximately 0.2 to 0.4 cc radius and, measured by the Reynolds method, shows a color strength of approximately 160o .