SU364636A1 - METHOD OF STABILIZATION OF RUBBER - Google Patents

Description

one

The invention relates to the stabilization of rubber by introducing phosphorous acid derivatives as a stabilizer. These rubbers have high heat resistance.

A known method of stabilizing rubbers based on general purpose rubbers is by introducing phosphorous acid derivatives, di- (alkyl) -mo "o- (alkyl-phenyl) -phosphites, trinaphthylphosphite, into the polymer, before the vulcanization step. However, this method is unsuitable for stabilizing rubber based on fluororubber, since the introduction of phosphorous acid derivatives into the rubber mixture makes it possible to vulcanize fluororubber.

The purpose of the invention is to improve the heat resistance of rubber based on fluororubber.

The goal is achieved as follows.

A stabilizer is introduced into the finished fluorocarbon-based vulcanizer when the vulcanizate is swelling in the stabilizer solution. In this case, the vulcanization agent is kept in solution until the equilibrium swelling is reached, and then it is present. Tronaphthylphosphite (TNF) is used as a stabilizer in an amount of 1-10 weight. hours per 100 weight. including polymer. The solvent can be a product in which fluoride-based vulcanizates are used.

swell in the range of 80-200%, for example acetone.

Vulcanizates, treated in this way, have improved heat resistance but compared to conventional ones.

Example 1. Peroxide vulcanizates based on SCF-260 are immersed in a solution of trinaftilfosfnt in acetone concentration

1.27%, which provides the introduction of 2 wt. including trnnaftilfosita 100 weight. H. Polymer The vulcanizate is kept in solution for 3 days and dried to constant weight. Zatom.m volcannates treated in this way are subjected to heat aging at 300 ° C for 3 and 5 days.

The physicomechanical parameters of the vulcapizates treated with the proposed stabilizer in comparison with the physicomechanical

The indicators of peroxide-free vulcanizates not containing stabilizer are shown in the table.

Example 2. The peroxide vulcanizates based on SCF-260 are treated according to the procedure described in Example 1, using a solution of trine Oil phosphonate in acetone with a concentration of 1.9%, which provides 3 wt. including stabilizer per 100 weight. including polymer. Zate.m vulcanizates subjected to heat aging.

Table

Physicomechanical

indicators hint, T, ejjb in the table.

Example 3. Peroxide vulcanizates based on SCF-260 are treated according to the procedure described in Example 1, and the solution and trinaphthylphosphite are 3.1%, providing 5 wt. including stabilizer per 100 weight. including polymer. Then the vulcanizates are subjected to heat aging.

The physicomechanical indicators are listed in the table.

Example 4. Peroxide vulcanizates based on SCF-260 are treated according to the procedure described in Example 1, using a solution of trinaphthylphosphite in acetone with a concentration of 6.29%, which ensures the introduction of 10 wt. including stabilizer per 100 weight. including polymer.

Physicomechanical indicators after thermal aging are given in the table.

Thus, the proposed method allows to obtain heat-aggressive rubber that retains elastic properties at a temperature of 300 ° C for a significantly longer period than the elastic properties of rubber without a stabilizer (5 times).

Subject izob) eteni

A method for stabilizing rubbers with trinaftilphosphite, characterized in that, in order to increase the heat resistance of fluoro-based resins, they produce a swelling of vulcanizates in a solution of trinaphthyl phosphite in organic solvents.