SU529198A1 - Polyorganosiloxane liquid composition - Google Patents

Description

Neither at 200 C during the day - up to 250-28 units, i.e. for 30-50 units The purpose of the invention is to obtain a petroleum jelly-like composite with high stability of mechanical properties both during storage at normal temperature and when exposed to elevated temperatures. This is comprehended due to the fact that, as a silica filler, the composition contains aerosil with a content of physically sorbed moisture in the range of 0.001-1.5%. The use of aerosil in composidium with a limited content of physically sorbed moisture slows down aging processes in it. Systematic studies have shown that the strength of the composition under mechanical action during storage is directly dependent on the moisture content of the azrosil surface, therefore the use of aerosil with a content of physically sorbent moisture in the range of 0.001-1.5% makes it possible preserved; The most necessary level of mechanical heating both during heat treatment and in:: storage9 storage at normal temperature — as well as goliorganosiloxanes can be Tb ;;, L (fluids of the general formula where n 2,0004-2,4, -; -; 1; univalent monovalent or halogen-free redical, and the quality of boron compounds can be doped; boric anhydride; boric acid (: cgr (MI-ta, orta, tetra) i alkylborates, in -:::: the hydrocarbon redical contains 1 / to 5 carbon atoms, as well as liOOi;, f; biK aroid dimethyl borosiloxane with mol. Weight; -j C O- 1 O O C O O, containing 3-7%, Kolistno boron compounds are introduced into the composite in the calculation of 0.01-0.42 parts by weight, boron in the compound per 100 parts by weight of the mixture of polyortic anosiloxane liquid and aerosil. Aero-forces with a specific surface of 50 m / g can be used as a filler with a content of physically sorbed moisture in the range of 0.00 to 1.5%. The ratio of components in the composition, e.g. Polyorganosiloxane liquid, 80-95 Aerosil, containing physically orbied moisture in the range of 0.001-1.5% 5-20 quantity, providing 0.01-0,42 weight.h. boron per 100 weight.h. a mixture of polyorganosiloxane fluid and aerosil. Example 1 Composition A. 92 g of polydimethylsiloxane fluid with a viscosity of 486 cSt / 20 C, 8 g of aerosil {sp. 350 m / g with a content of physically sorbed moisture of 0.001% (the moisture content is determined by bleaching the aerosil at 200 C to constant weight) and 1.2 g of boric acid are mixed. Then, the penetration according to GOST 5346-50 at the LP penetrator of GOST 1440-42 of a freshly prepared composition after storage for 24 hours at normal temperature and also after temperature aging (, 24 hours) is determined. Similarly, compositions B and C are physically different in content. sorbed moisture on the surface of aerosil (B-3.9%; C-7.8%). The test results of these compositions, as well as the data of the prototype are presented in table. 1. Table 1

218

216

207

216

200 218

210

2OO

216

190

218

216

20О

254

224 306 232268

280

22О

270

From the data table. As can be seen from Fig. 1, the strong properties of the proposed composition do not practically change during room and temperature aging (penetration after mixing 218, 21-6, respectively),

PRI mme R 2. 92 g of polydimethylsiloxane with a viscosity of 486 cct / 20 C are mixed with 8 g of aerosil with a specific surface of 350 m / g with a moisture content of 0.01% and 3.9 g of polydimethyl borosiloxane (boron content 5, 46%; silicon - 31.8%).

Penetration of the freshly prepared composition 222/214, penetration after aging at 200 ° C for 24 hours. 222/216.

218

216

From the data table. 2 shows that warming up

The composition improves the stability of mechanical properties during subsequent storage at normal temperature.

Example 4. 89 g of polydimethylmethylphenylsiloxane (dimethyl methylphenylsiloxane ratio 25: 2; viscosity 170 CST / 2O C) is mixed with 3.8 g of tributylborate and 11 g of aerosil from example 2.

Penetration of the freshly prepared composition 226/224, penetration after aging at 200 ° C for 24 hours 200/220.

Example5. 86 g of polydimethyl methylchlorophenylsiloxane (viscosity 42 cct / 2O С, chlorine content 6.5%) are mixed with 14 g of aerosil from example 2 and 0.57 g of boric anhydride previously ground to particle size vVO microns.

Penetration of a freshly prepared compound PRI me R 3. Ogpididimetilsiloksana viscosity of 486 eats / 20 ° C is mixed with 80 weight.h. Aerosil with a specific surface of 35 O and a moisture content of 0.001% and 12 g of boric acid, divide the mixture into 2 parts: and C C is left for aging at normal temperature, Cj, heated at 50 C for 5 hours and left for aging at normal temperature

The penetration of the freshly prepared compositions and the penetration after 4 months of storage at normal temperature are determined. The results of determination of penetration are presented in table. 2,

Table 2.

238

216

210

206

206

210

position 250/252, penetration after aging at 200 ° C for 24 hours 240/248. Thus, the introduction of Aerosil into a composition based on a polyorganosiloxane fluid with a physically sorbed moisture content in the range of 0.001-1.5% makes it possible to obtain a composition with high mechanical stability, providing a high level of reliability when used as a protective dielectric coating.

Formula and 3 gains

Composition based on polyorganosiloxanes & liquid, silica filler and boron compound, characterized in that, in order to increase mechanical stability, it contains aerosil with a silica filler

OjOOl-1,5% physically sorbed moisture with the following content of components, weight, h,

Polyorganosiloxane fluid ° 9

Aerosil5-20

The boron compound is taken in an amount that provides 0.01-0.42 weight, h. boron per 100 weight, h, a mixture of polyorganosiloxane fluid and aerosil.

eight

Sources of information taken into account in the examination:

1. US Patent No. 2428608, cl. 17435,1948.

52. Andrianov K.A., Khananashvili L.M.

Technologists of organoelement monomers and polymers, M., Himi, pp. 149151, 1973.

3. Patent of England No. 998658, cl. C 3 T, 10 1965 (prototype).