DE10213364B4 - Process for the heat stabilization of silicone rubber - Google Patents

Abstract

Process for improving the stability of addition-crosslinking 2-component silicone rubber to heat and flame exposure, characterized in that the polymers before or during processing, a pyrogenically prepared, non-hydrophobicized titanium dioxide having a BET specific surface area greater than 65 m ² / g granules based on pyrogenic titanium dioxide having a mean particle diameter of 10 to 150 microns, a BET surface area of 25 to 100 m ² / g, a pH of 3 to 6 and a tamped density of 400 to 1200 g / l, which are prepared by dispersing pyrogenically produced titanium dioxide in water, spray drying and optionally heat treatment of the resulting granules at a temperature of 150 to 1100 ° C for a period of 1 to 8 hours, except.

Description

The The invention relates to a method for improving the stability of polymers across from Heat and flame.

It is known pyrogenic titanium dioxide in silicone rubber to be used (publication series pigments No. 56 Degussa Aktiengesellschaft 1989, page 27).

It is known to produce granules based on pyrogenic titanium dioxide, using titanium dioxide P 25 having a surface area of 50 ± 15 m ² / g ( DE 199 28 851 A1 ).

According to DE 199 29 851 A1 is a pyrogenic titanium dioxide with a surface of 50 ± 15 m ² / g known that has been surface-modified with amino-functional silanes.

According to DE 100 59 002 A1 discloses a method for improving the stability of polymers to heat and flame exposure, in which the polymers added to a pyrogenic hydrophobic titanium dioxide.

According to JP 102 79 308 A1 (abstracts of Japan) Patent is a pyrogenic titanium dioxide is known which has a surface area of 10 to 120 m ² / g and has been hydrophobed with an organosilicon compound. It can be used in silicone rubber to improve the heat and flame stability.

The invention relates to a method for improving the stability of addition-crosslinking 2-component silicone rubber to heat and flame exposure, which is characterized in that the polymers prior to or during processing a pyrogenic, non-hydrophobized titanium dioxide having a specific BET surface area of greater than 65 m ² / g added, wherein granules based on pyrogenic titanium dioxide having an average particle diameter of 10 to 150 microns, a BET surface area of 25 to 100 m ² / g, a pH of 3 to 6 and a Tamping density of 400 to 1200 g / l, which are prepared by dispersing pyrogenic titanium dioxide in water, spray drying and optionally heat treatment of the resulting granules at a temperature of 150 to 1100 ° C for a period of 1 to 8 hours, except.

When Silicones are called chemical compounds that are at least contain a -Si-O-Si bond in a molecule, wherein the silicon atom the two remaining bonds are incorporated with organic groups. The synthetically prepared linear polyorganosiloxanes become generally as silicone oil designated. In the synthesis of the silicone polymers is the chain length and the nature of the substituents hereinafter referred to as "R" in more diverse Way changeable.

• R = substituent

is the radical "R" is a methyl group, this is the quantitatively most important silicone polymer Polymethylsiloxane. By suitable combination of different substituents or targeted incorporation of reactive groups in the polymer chain can desired Substance properties of the polymers can be realized.

at the selection of silicone polymers for the preparation of silicone elastomers can the most diverse types of polymers of different reactivity in question come. For the choice of for reinforcing purposes used silica is the type and reactivity of the present polymer is of great importance.

One Distinguishing feature between the different silicone systems is the vulcanization temperature. HTV silicone rubber (High Temperature Vulcanizing) is vulcanized at temperatures above 100 ° C.

At the RTV silicone rubber (Room Temperature Vulcanizing), as can be seen from the name, crosslinked at room temperature.

Around Another distinguishing feature is the characterization the chemical cross-linking reaction important.

at Rubber, the peroxide-initiated vulcanization can be performed. This peroxidically initiated crosslinking is particularly easy with vinyl group-containing From polymers.

The Crosslinking principle of a polyaddition in which by insertion a Si-H group in an olefinic double bond a so-called Hydrosilylation reaction takes place, can be done both at high and at low temperature. As for this used polymers a significantly lower viscosity than the Having crosslinked with peroxides, this silicone system is also as "Liquid Silicone Rubber "(LSR) or liquid silicone rubber designated.

One another type of crosslinking is based on the polycondensation reaction, in which the crosslinking by reaction of two molecules under Cleavage of a small condensate molecule takes place.

The silicone types can, as in 4 be shown.

at 1-component systems (1K) is vulcanization by moisture initiated from the ambient air and / or from the substrate. Depending on Sealant type reaction products are split off and released. The speed of networking is both of the gap thickness as well as the humidity or the temperature dependent. For the 2-component systems (2K) are the almost invariably filled with base polymers (Component A) separated from the crosslinker (component B) packaged.

With Exception of the RTV 1K silicone rubber, in which by the comparatively high moisture content of precipitated silicas only fumed silica, such as Aerosil, can be used for all others Crosslinking systems both types of silica. In the table 1 below are typical silicone rubber applications and those with it related requirements for the silica used, the as a filler serves, shown.

Table 1

The For example, titanium dioxide may be used before or during vulcanization or Crosslinking be added to the polymers.

The pyrogenic titanium dioxide can be in an amount of 0.05 to 20 wt .-%, preferably 0.5 to 2.5 wt .-%, added to the polymers become.

The Production of pyrogenic titanium dioxide is known from Ullmann's Encyclopedia of Technical Chemistry 4th Edition, Volume 21, page 464 (1982).

The inventive method has the advantage that the Polymers improved stability to heat and flame exposure exhibit. That means the split of organic materials at higher temperatures significantly is reduced.

hereby will be added achieved an improved flame retardancy.

Example 1:

(No addition of pyrogenic Titanium dioxide, reference sample)

approach a 2-component silicone rubber (liquid silicone rubber) without the addition of titanium dioxide (Reference sample). The basic component is a two-component silicone rubber Bayer, trade name Silopren LSR 2040 used. (Addition crosslinking).

To Homogeneous mixing of the two components with a dissolver finds the vulcanization at 180 ° C for 10 min.

It are sample plates (about 10 × 15 cm) of 6 mm thickness produced.

The Sample plates are at 80 ° C conditioned in the oven to constant weight (about 1 day).

To check the stability across from Heat is carried out a warm storage.

there becomes a sample strip of 5 × 7 cm in a convection oven at 300 ° C stored.

At This test strip is the Shore hardness A and after different storage times measured the rebound resilience.

The results are in the 1 to 3 shown graphically.

there you realize that the Sample without heat protection stabilization already within the first day of warm storage glazed and splintered. The sample is destroyed.

Example 2: (Comparative Example)

(Addition of pyrogenic titanium dioxide)

When Basic component is a two-component silicone rubber from Fa. Bayer, trade name Silopren LSR 2040, used (addition-curing).

In one of the components is (based on the total batch) 1.5 wt .-% pyrogenic titanium dioxide (titanium dioxide P 25 S, Degussa AG Frankfurt) incorporated with a dissolver for 5 min. After that takes place, as in example 1, the vulcanization and preparation of the test plates instead of.

test strips from 5 × 7 cm are at 275 ° C stored. It will be the weight loss, the Shore hardness A and the rebound resilience of the sample measured.

The Samples glaze after approx. 33 hours storage time.

The results are in the 1 to 3 shown graphically.

Example 3:

(Addition of pyrogenic Titanium dioxide with higher BET surface area according to invention)

When Basic component is a two-component silicone rubber from Fa. Bayer, trade name Silopren LSR 2040 used (addition-curing).

In one of the components is (based on the total batch) 1.5 wt .-% pyrogenic titanium dioxide (name VPTN 90, manufacturer Degussa-Hüls AG Frankfurt), incorporated with a dissolver for 5 min. After that takes place, as in example 1, the vulcanization and preparation of the test plates instead of.

To different storage times at 300 ° C is the Shore hardness A and the rebound resilience of the sample measured.

The results are in the 1 to 3 shown graphically.

at These samples occur only after a storage period of up to 5 weeks a glazing.

The physico-chemical data of the pyrogenic titanium dioxide used are given in Table 2.

Table 2 Comparison of the storage behavior of Liquid Silicone Rubber LSR at 300 ° C

Table 3 Comparison of physico-chemical data of VPTN 90 and P 25

Assessment: From the 1 to 3 , in particular from the curve of 1 (Weight loss, that is, cleavage of organic material from the silicone polymer) can be clearly read the improvement of the heat protection (stability to heat) by the inventive use of higher surface area titania.

The invention will be explained in more detail with reference to the drawings:
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1 : Weight loss of liquid silicone rubber vulcanizates as a function of storage time at a temperature of 275 ° C.

2 : Shore-A hardness of liquid silicone rubber vulcanizates as a function of the storage time at a temperature of 275 ° C.

3 : Resiliency of liquid silicone rubber vulcanizates as a function of storage time at a temperature of 275 ° C.

Claims (2)

Process for improving the stability of addition-crosslinking 2-component silicone rubber to heat and flame exposure, characterized in that the polymers before or during processing, a pyrogenically prepared, non-hydrophobicized titanium dioxide having a BET specific surface area greater than 65 m ² / g granules based on pyrogenic titanium dioxide having a mean particle diameter of 10 to 150 microns, a BET surface area of 25 to 100 m ² / g, a pH of 3 to 6 and a tamped density of 400 to 1200 g / l, which are prepared by dispersing pyrogenically produced titanium dioxide in water, spray drying and optionally heat treatment of the resulting granules at a temperature of 150 to 1100 ° C for a period of 1 to 8 hours, except. Method according to claim 1, characterized in that that he the titanium dioxide before or during the vulcanization or crosslinking added to the polymers.