DE2303698C3 - Plastic-elastic mass - Google Patents

Description

2. Plastic-elastic mass according to claim 1, characterized in that the rubber is a Ethylene propylene rubber is.

10

The invention relates to a plastic-elastic composition based on polymeric olefins.

For many areas of application, such as B. in the construction sector, in equipment and vehicle construction, plastic masses with elastic properties are required. As a result of frequent mechanical and thermal alternating loads, these masses must have good elastic properties with good heat and cold resistance. For use as sealing compounds, a sufficient adhesion and expansion behavior is also required, even in the case of larger expansions. Such masses exist z. B. from filler-containing mixtures of phthalic acid esters with linseed oil, from polysulfides, polyurethanes, bitumen, silicone rubber, etc. Some of these compounds, e.g. B. made of silicone rubber, are only applicable in special cases due to their high price. The cheaper masses, e.g. B. from phthalic acid esters with linseed oil, have the disadvantage that they have only very poor elastic properties.

From the German Offenlegungsschrift 21 31 539 are Sealing compounds known, which are made of crosslinked butyl rubber, polyisobutylene with a molecular weight ', .between 7000 and! 2,000 and soot exist. The crosslinking of the butyl rubber is necessary in order to achieve the To make the masses stable. A particularly suitable method of production, however, apparently also exists Reason for networking, from at least five processing-> o processing stages, namely single or multi-stage mastication on narrow rollers, cutting open the fur in dolls, roller plastification, strip cutting and extrusion into a tape. It was unpredictable that one can avoid this expense and that it is cheap to use plastic-elastic ones that can be used much more widely Masses with high stability are obtained if instead of butyl rubber you use a normal, solid, amorphous polybutene-1 and instead of a sticky polyisobutylene an ordinary, not wi crosslinkable rubber is used.

Similarly, from the German Offenlegungsschrift 1 \ Π i 73 a curable sealant is known, which consists of two components, which in turn have 7 or 6 components, and zv / ar mainly ni butyl rubber, polyisobutylene, liquid, low molecular weight polybutene-1, silicic acid so / ie on the one hand carbon black, lead dioxide and silica with hydroxyl groups, on the other hand zinc oxide and parachinondioxime. This mixture, too, does not meet the requirements of being simple and inexpensive to manufacture on the one hand, and remaining plastic-elastic on the other.

There is therefore a great need for inexpensive elastic plastic masses.

This object is achieved according to the invention by a composition from

40 to 90 percent by weight of a largely amorphous, solid polybutene-1,

10 to 40 percent by weight of a rubber and optionally
5 to 40 percent by weight of a filler.

The substantially amorphous polybutene-1, c is one preferably 50 to 80% used, the largely atactic Potybuten-1 and its co- and terpolymers are of up to 20% Athens, propene and / or hexene-1 and mixtures thereof. The largely atactic structure is expressed by an ether-soluble proportion of over 70%. preferably from 80 to 96%. This polybutene-1 has RSV values from 0.2 to 1.2 dl / g, preferably from 0.3 to 0.5 dl / g. This corresponds to molecular weights, calculated according to the solution viscosity, for polybutene-1 from 35,000 to 394,000, preferably from 61,000 to 132,000.

Such largely amorphous homo- or copolymers are obtained by adding butene-1, optionally with Athens, propene or hexene-1, with contacts of TiCl ₄ , TiCl) or preferably TiCh · π AlCl ₁ on the one hand and AlRi or AlR ₂ H, preferably Aluminum triethyl or aluminum triisobutyl, on the other hand with molar ratio Al: Ti of 1.5 to 3.5, preferably from 2 to 3, polymerized ^{at temperatures from 60 to 120 °} C., in particular from 70 to 100 ^{° C.} The polymerization can be carried out batchwise or continuously, in solution or in bulk. The solvent used is preferably 1-butene or a mixture of 1-butene, 2-butene and, or butane.

Both natural and synthetic rubbers are suitable as rubbers. Of the synthetic rubbers, saturated and unsaturated ethylene-propylene rubbers are preferably used. Besides these z. B. butadiene-styrene and butadiene-acrylonitrile rubbers, butyl rubbers and the stereo rubbers cis-polybutadiene and cis-polyisoprene are also suitable. The ethylene-propylene rubbers are obtained in a manner known per se by copolymerizing ethylene with propylene using Ziegler contacts, e.g. B. with the help of mixed contacts of vanadium oxychloride and ethylaluminum sesquichloride, in an inert solvent such as hexane at temperatures from -20 to +30 ⁰ C (German patent 14 95 349). The cis-polybutadiene and the cis-polyisoprene are also produced by ion polymerisation with Ziegler contacts. Butadiene-styrene and butadiene-acrylonitrile rubbers are obtained by free-radical polymerization, and butyl rubber is obtained by ionic polymerization of isobutylene with 1,3-butadiene with the aid of Friedel-Crafts catalysts. Mixtures of different rubbers are also suitable. The rubber content in the claimed compositions is preferably 10 to 30 percent by weight.

The masses contain powdery substances as fillers, preferably silicic acid, silicates, sulfates, Carbonates, soot, graphite, talc, kaolin, chalk and tonsil. For masses with a high filler content are suitable as fillers especially talc and barite.

These compositions preferably contain 15 to 30% rubber.

Suitable is z. B. a mixture of 40% talc or barite, 10% ethylene-propylene rubber, 50% atactic polybutene). A comparable mixture with chalk has the following composition: 30% chalk, 10% ethylene-propylene rubber, 60% atactic polybutene-1. This mixture has a breaking point (Fraaß) of -52 ⁰ C.

These elastic, plastic masses are suitable for many areas of application, e.g. B. as sealing compounds, joint tapes or adhesive tapes, in building construction and civil engineering, especially in precast concrete construction, pipe laying, automobile construction, for repairs, for connecting of parts made of plastic and in the construction of traffic areas. They have an excellent Hafi- and elasticity, even with prolonged aging and different weather conditions.

Mixing the masses by preferably mixed in mixers, kneaders or similar units at temperatures of 80 to 150 ⁰ C, in particular 90 to 120 ° C, the substantially amorphous solid polybutene-1 with the rubber, and then optionally added to the filler. The mixing process can be shortened if, instead of the solid rubber, a rubber solution, e.g. B. in a hydrocarbon, and the solvent is distilled off when a homogeneous solution is formed.

example 1

In a Beken laboratory kneader, 60 parts by weight of a largely amorphous butene-ethene copolymer containing about 5% Athens, an RSV value of 0.4 dl / g and an ether-soluble content of 96% are obtained by at 90 ° C Polymerization of butene-1 with 5% Athens at 8O ⁰ C with a contact of TiCli 0.5 AlCl ₃ and Al (ISo-QHi)) I at a hydrogen partial pressure of 2.0 at, 20 parts by weight of an uncrosslinked ethylene-propylene Rubber with a Moony viscosity ML-1.4 of 70, measured according to DIN 53 523, and a double bond content of 8 DB / 1000 ° C, produced by copolymerizing ethylene with propylene and small amounts of dicyclopentadiene in hexane as a diluent at 0 ⁰ C with the help of a contact of vanadium oxychloride and ethylaluminum sesquichloride, and 20 parts by weight of chalk mixed until an even mixture is achieved. After cooling to room temperature, a plastic, elastic mass with good resilience is obtained. The mass has a breaking point, measured according to DIN 1995, of -55 ° C.

If a largely amorphous one is used instead of the largely amorphous butene-1-ethene copolymer Polybutene-1 with an RSV value of 0.4 dl / g and an ether-soluble content of 85% is obtained comparable plastic elastic mass, which is somewhat tighter.

You can shorten the mixing process if you mix the ethylene-propylene rubber in a hydrocarbon, ζ. B. hexane, added in solution. The hydrocarbon is distilled off while mixing.

If the mixture is produced without the addition of chalk, a soft, plastic one is obtained elastic compound, which is also very suitable for Ms sealing compound and has excellent adhesive properties has.

30th

35

Example 2

In a laboratory kneader at 90 ⁰ C 70 parts by weight of a substantially amorphous polybutene-1 having an RSV value of 0.5 dl / g and an ether-soluble content of 92%, obtained by polymerization of butene-1 with the aid of a contact of TiCl ₃ 0.3 AlCl ₃ and Al (C ₄ He) ₃ at a hydrogen partial pressure of 1.8 at at 85 ° C., 22 parts by weight of an uncrosslinked ethylene-propylene rubber with a Moony viscosity ML-1.4 of 70, measured according to DIN 53 523, and a double bond content of 8 DB / 1000 C, prepared according to the information in Example 1, and 8 parts by weight of fuller's earth mixed until uniform mixing is achieved. A plastic elastic mass with low permanent elongation is obtained. The mass has a breaking point (Fraaß), measured according to DIN 1995, of below -6O ⁰ C.

If the largely amorphous polybutene-1 is used, a largely amorphous butene-propene copolymer is used with about 6% propene, which has an RSV value of 0.5 dl / g and an ether-soluble portion of 86%, a plastic, elastic mass that is easy to process is also obtained.

Example 3

In a laboratory kneader, 80 parts by weight of a largely atactic polybutene-1 having an RSV value of 0.4 dl / g and an ether-soluble content of 88%, prepared by polymerizing butene-1 at 90 ° C using a 100 ⁰ C Contacts made of TiCl _{3 · 0.5 AICl 3} and Al (ISO-CtHi) ₃ at a hydrogen partial pressure of 1.8 at, with 10 parts by weight of an uncrosslinked ethylene-propylene rubber with a Moony viscosity ML-1.4 of 85, measured according to DIN 53 523, and with a double bond content of 8 D / 1000 C, produced by copolymerization of ethylene with propylene and small amounts of dicyclopentadiene in hexane as a diluent at -5 ° C with the help of a contact of vanadium oxychloride and ethylaluminum sesquichloride, mixed until one uniform mixing is achieved. A soft, plastic, elastic mass with good adhesion is obtained. The mass has a breaking point (Fraaß), measured according to DIN 1995, below -6O ⁰ C.

If 10 parts by weight of kaolin are mixed with the mass, a firmer, plastic, elastic mass is obtained is also very suitable as a sealant.

If, instead of the largely atactic polybutene-1, a largely amorphous butene-propene-ethene terpolymer is used, which contains about 6% propene and 1% Athens and an ether-soluble portion of 92% and has an RSV value of 0.4 dl / g, a comparable plastic elastic mass is obtained.

Example 4

In a laboratory kneader, to be at 110 ⁰ C 45 parts by weight of a largely atactic polybutene-1 having an RSV value of 0.6 dl / g and an ether-soluble content of 77%, prepared by polymerizing butene-1 at 80 ° C with a contact from TiCl ₃ · 0.5 AlCl ₃ and Al (C ₂ Hs) ₃ at a hydrogen partial pressure of 1.5 at, 25 parts by weight of a butadiene-styrene rubber with the composition 76% butadiene and 24% styrene with a Moony viscosity ML-1, 4 of 50, measured according to DIN 53 523, produced by emulsion polymerization of

5 6

1,3-butadiene with styrene at 5 ° C with redox activators, is used in place of the largely atactic

and 30 parts by weight of talc mixed until a polybutene-1 with a butene-1-hexene-1 copolymer

largely homogeneous mass has arisen. A hexene-1 content of about 3% is obtained, the one

a plastic elastic mass with a good recovery ether-soluble portion of 75% and an RSV value of

assets. The mass has a breaking point (Fraaß), 5 0.6 dl / g, so you get a comparable plastic

measured according to DIN 19S5, from -52 ° C. elastic mass.

Claims (1)

Patent claims: 1. Plastic-elastic mass based on polymeric olefins, consisting of: 40 to 90 percent by weight of a largely amorphous polybutene-1 with RSV values from 0.2 to 1.2 dl / g and ether-soluble proportions above 70% or its copolymers and terpolymers with up to 20% Athens, propene and / or hexene-1 as well as their mixtures, 10 to 40 percent by weight of a rubber and possibly
5 to 40 percent by weight of a filler.