PL9352B1 - The method of securing rubber objects from sticking together. vol - Google Patents

Description

In the production of rubber articles, it is necessary to protect non-vulcanized blanks, such as, for example, rubber sheets, sheets, balloons and the like from sticking together. For this purpose, powders, aqueous suspensions or other liquids are used. Until now, such powders have been used as powders of licopium, megnesium oxide or carbonate, talc, aurpigment, realgar, sulfur, dyes and similar materials. These measures prevent the rubber from sticking together, even in those places that are to be bonded during the further processing of the articles. The presence of the flour used so far in these places, which are then joined by means of seam clamping tools, causes that the strength of a cold vulcanized seam is only about 50% of the tear strength of non-welded rubber, and that of a hot vulcanized seam is only about 15% of the strength of non-welded rubber. For this reason, the seams of the welded rubber had to be cold-vulcanized or, in order to be hot-vulcanized, they had to be strengthened by sticking special tapes. The present invention allows to increase the strength of the seam of the object Cold vulcanized rubbers, in particular hot vulcanized, up to 90% by the use of organic sprinkling powders or suspensions of such powders in suitable liquids. Organic powders have the advantage that when rubber is combined with heated compressing tools and with subsequent vulcanization, they lose the separation properties of the rubber layers, because they either melt or dissolve in the rubber, or decompose into volatile components. or melting or soluble in rubber. Organic chemistry offers many agents having the above-mentioned properties, but they must be selected according to the strength and speed of the rubber to be processed and other conditions. Below are some examples of The use of the invention for the preparation of agents for the protection of unvulcanized rubber. Naphthaline in the form of a powder is melted under the action of heated stamping tools. It can be assumed that part of the naphthaline exits under pressure to the outside, and part dissolves in the rubber. In any case, the mothballs take up less space in the liquid state than in the powdered state, and in addition, the fine droplets formed from the naphthalene pollen are combined into larger droplets so that in this state the ability of the mothballs to separate the rubber layers is greatly reduced. An alcoholic solution is applied to those areas that do not stick together, and then dried. Acetanilide melts at vulcanization temperature and behaves in the same way as naphthalene, hexamethyl tetramine in powder form. Probably some of the powder sublimes during the tightening of the seam and some dissolves in the rubber and as is known to accelerate vulcanization, Thiocarbanilide (diphenyl thiocarbanide) suspended in water. The prepared slurry is coated (for example, with a Schop gun) on those places of the rubber products that do not have a bad foam and then dries out. During heating, the thiocarbanilide most likely bonds with the rubber and the moss. In fact, these examples show a sufficiently diverse chemical composition of the compounds that can be used in the context of the present invention. The most advantageous compounds seem to be those which dissolve in rubber or decompose when heated, and the products of their decomposition dissolve in rubber. Trials have shown that organic metal salts, e.g. salts of fatty acids, are also very suitable. metals which are used in the rubber industry, such as, for example, lead zinc and metal derivatives. The above-mentioned metallic compounds also have the advantage that they are odorless. The substances mentioned can be used alone or in mixtures, for which the composition of such mixtures may also include dyes, known rubber preservatives and similar substances. prepared with the agents described in the present invention, can be glued together without applying pressure and then vulcanize them when heated, it is only necessary to wash the surfaces to be treated with gasoline beforehand (without scraping). The joints obtained in this way are strong and durable. The seams obtained with stamping or cutting tools and cold vulcanized have a greater strength than seams obtained by known methods, and hot vulcanized seams have a strength hitherto not achieved by any other method. The anti-caking agent loses its detaching properties during hot vulcanization so quickly that the parts of the rubber that come into contact with each other during volcanization would accidentally stick together. This can be prevented by sprinkling already embossed one of the known rubber sprinklers, or in such a way that the hot vulcanization is carried out in water. PL PL

Claims (4)

1. Patent claims. 1. The method of securing non-vulcanized rubber products against sticking, characterized by the fact that a substance is used made of powdered organic substances, dissolved or dissolved luL which are in suspension and have the property that they disappear when pressing the rubber without heating tools and then vulcanization due to liquefaction or solubility in rubber, or due to decomposition into (at least partially) volatile or liquefiable components, or soluble in rubber, thereby withstanding the number of cold or hot vulcanized seams increases up to%% of the strength of non-welded rubber, 2. The method according to claim The method of claim 1, characterized by the addition of known agents for sprinkling rubber, dyes, sulfur and the like. 3. The method according to p. 1 and 2 in the use of rubber articles by means of pressure welding of thin rubber sheets and subsequent vulcanization, characterized by the fact that the pressed articles are subject to hot vulcanization. 4. The method according to p. 3, the characterized by the fact that in order to prevent accidental sticking of the rubber during hot vulcanization, water vulcanization is performed. Karl Me d gy es. Deputy: Dr. M. Kryzari, patent attorney. Printed by L. Boguslawski, Warsaw. PL PL