DE2107537C3 - Elastomeric mass - Google Patents

Description

The subject of the invention is an elastomeric mass behavior and processability. Under these geaus a copolymer of butadiene and styrene, 35 points of view, 50 to 60 parts by weight of carbon black were found 100 parts by weight of butadiene-styrene rubber added in particular for the production of the treads Vehicle tires are designed to be offset by this one, but even these resulted in a compromise to convey better cut resistance. forming mixtures do not produce satisfactory

When driving on unpaved roads, especially results regarding the desired cut resistance of the Over rocky roads, the tread of the tire becomes 30 treads.

Often through the sharp edges of the rock, the more extensive attempts yielded the over gravel or the like. Damaged, so that more or less surprising result that some petroleum resins, especially deep cuts in the running surface and of this those of cyclopentadiene or dicyclopentadiene, more or less fewer large particles are torn off. Wear instead of carbon black The tire industry has therefore been making attempts at high speeds for a much longer period of time to find new and relocated and consequently the cut resistance of the better-running materials for the tread of large tires for surfaces.
Heavy goods vehicles, buses or even for the elastomeric mass according to the invention

Construction site vehicles, for example for gravel pits, made from a mixture of an elastomeric mixture develop around such injuries to the barrel 40 polymer made of butadiene and styrene and a petroleum surface to avoid, which very often leads to tire breakages resin based on polymers made of cyclomite their often catastrophic consequences. pentadiene and / or dicyclopentadiene or mixed

In the development of such new substances or micropolymers made from cyclopentadiene and / or dicyclases have, however, great difficulties pentadiene and an olefin, which are characterized by since the relationship between the 45 net is that the amount of petroleum resin is 5 to 40 strength and the physical properties are parts by weight per 100 parts by weight of rubber, Kanized rubbers by laboratory tests do not unpolynomize the petroleum resin by more than 30 percent by weight were clearly identifiable. But it could be merized cyclopentadiene and / or dicyclopentadiene it is found that a sharp-edged stone or contains a bromine number from 40 to 150 and an er gravel, which at relatively high speed and 50 softening point of 50 to 200 ° C, determined according to the high load on the vehicle under the running surface ring and ball test according to J / S K-5902, of the tire enters the tread for a short time. What is particularly surprising is that such intrusion and damaged it. The applicant is therefore also ideally suited as a plasticizer, assumed the cut resistance of the tread To improve the workability of the of a tire by reducing wear and tear, elastomeric compounds have hitherto been the most varied To improve the speeds used in most plasticizers, but their addition a reproduction carried out on the test bench often shows the physical properties of the vulcanized of cuts in the tread in abrasion rubbers, since the plasticizer itself Tests observed at speed are not only found to have no elasticity, but also to have none can. The rate in question here was the reaction of the same with the rubber compound, is 5 m / sec (18 km / h), which is 600 times faster. The petroleum resin used according to the invention can speed (500 mm / min) for ordinary rubber but not only for the processing ability of the chewing strength tests corresponds to how it is used in Japanese chuks as a plasticizer in not yet vulcanized see industry standard (JIS) No. K-6301 are specified. State of the rubber compound contribute, rather it As from the publication by G. Fromandi, 65 can also include the elastomeric properties of the mixture R. Ecker and W. H e i d e m a η η in »Improving rubber. In contrast to the usual one up to now und Gummi ”, Volume 13, WT 25, 1960, is known, processing oils can do this essentially there is no relationship between two velocities - cyclopentadiene or dicyclopentadiene

Petroleum resin tensile strength at high speeds should improve the properties of the tread compound and cut resistance of the elastomeric petroleum resin, preferably in an amount of 5 to mixture, without the 20 parts by weight a per 100 parts by weight of butadiene processability and the exothermic behavior of styrene rubber used will,
would be disturbed. Such an effect could not be expected from the usual plasticizers or processing oils, especially as a material for producing the barrel. areas of vehicle tires is determined, so can

Among those in the mixture according to the invention, this mass of course also applies to others

Used olefin hydrocarbons are used in objects where an appropriate

For example, monoolefinic aliphatic hydrocarbons are required to cut resistance. Two examples should

substances such as 1-butene, 2-butene, isobutene, 1-pentene, explain the invention in detail below.

2-pentene, 2-methyl-1-butene, 3-methyl-1-butene, 2-Me-.

ethyl-2-butene; Diolic aliphatic hydrocarbons - Example 1

substances such as butadiene, isoprene, 2-methyl-l, 3-butadiene, the composition of the inventive ela-

1,3-pentadiene, 3-methyl-1,2-butadiene; and vinylsub- 15 stomer compositions of cyclopentadiene petroleum resin and

Substituted aromatic hydrocarbons such as styrene, butadiene-styrene rubber is in the following

p-vinyltoluene, m-vinyltoluene, o-vinyltoluene, «-Me Table 1 in comparison to masses shown which

methylstyrene, / 9-methylstyrene, m-ethylstyrene, p-ethyl with aromatic processing oils and coumarone

styrene, indene, 3-methylindene, 1-vinylnaphthalene, 2-vinylene resin are combined, which are usually at

nylnaphthalene, each of which is mixed with cyclopentadiene 20 butadiene-styrene rubber as a plasticizer

or dicyclopentadiene can be used by means of Friedel-Crafts. As wax, antioxidants and

Reaction in the presence of a suitable catalyst Vulcanization accelerators were used in the manufacture

is copolymerizable. Positioning of common materials for tread compounds

However, these petroleum resins must have a softening effect. The specified ratios mean point (according to the ring and ball test 25 in their entirety parts by weight,
according to JIS K-5902) from 50 to 200 ⁰ C and preferential The single components were in the usual way from 80 to 150 ° C and a bromine number (ASTM way with a Banbury mixer No. 11 mitein-D-1158-57T) from 40 to 150 and preferably 50 to the other mixed. The physical properties 150 in terms of molecular weight and reactivity to hardness, tensile strength at 500 mm / min double bond activity to have the desired 30, and peel strength were measured according to the th physical properties of the vulcanized JIS K-6301. Reach the speed train rubbers. The according to the state of the strength tests at 5 m / sec were in accordance with DIN technology with an elastomeric mass of the patent no. Test pieces from 2 mm thick Vulkanianspruch specified genus known use-based material using a Plasteconeines petroleum resin with a bromine number of ettva 13 35 tensile strength tester carried out. The impact (cf. Soviet Rubber Technology, Volume 28 [1969], cutting tests were carried out in this way, Issue 4, pages 24/25) in no way leads to the desired success of a steel blade of the pendulum impact tester. Specimen was driven to the depth of the

It was found that the combination with butadiene cuts could be determined. The arrival

Styrene rubber excellent wear resistance 40 gave in terms of the appearance of the tread

at high speed, from which can be deduced from measurements after a running time of 2200 km

men can be that in addition to the reaction of on stony paths in the gravel pit with frequent

Sulfur with the petroleum resin during vulcanization sudden brakes, whereby the tires have a dimension

also possessed the mutual π-electron bond between solution of 10.00 χ 20 "for the motor vehicle

the cyclopentadiene ring and styrene play a role. 45 and each had a tread made of four parts,

With regard to the processing ability of the still soft one, made of four different treads

not vulcanized material and the desired mixtures were made.

Table 1

X A. B. C. D. Butadiene-styrene rubber 100 100 100 100 100 Stearic acid 2 2 2 2 2 Highly abrasion-resistant furnace soot 60 60 60 60 60 Aromatic processing oil 20th - 10 - - Coumarone-indene resin *) - 20th - - - Cyclopentadiene resin A **) - - 10 20th __ Cyclopentadiene resin B ***) - - - - 20th Wax and antioxidants 3 3 3 3 3 zinc oxide 3 3 3 3 3 Vulcanization accelerator 1.6 1.6 1.6 1.6 1.6 sulfur 2 2 2 2 2

Hardness (Japanese Ind. Norm) 60 63 64 67 68

5
Table 1 (continued)

530 590 580 630 600 205 242 212 215 202 18.4 19.7 20.3 21.4 21.5 87 103 91 92 88 54 61 58 62 61 7G5 745 680 680 675 170 181 188 195 193 100 119 121 134 129 30.4 26.2 14.7 0.6 1.3 3.5 3.3 1.9 0.6 0.5 14.4 9.6 6.4 3.4 4.6 4.2 3.3 2.8 0.8 1.0

At a pulling speed of 500mm / min:

Strain (%)

Tensile strength (kp / cm ² )

100% Modol (kp / cm ² )

300% module (kp / cm ² )

Tear strength (kp / cm ² )

At a pulling speed of 5 m / sec:
Elongation (° / ₀ )
Tensile strength (kp / cm ² )
300% module (kg / cm ¹⁸ )
Impact-cut test (mm)

Appearance of the tread: ****)
Big cuts
Small cuts
cutlet

In the above table 1:

*) Softening point of 72 ⁰ C and bromine number of 21.

♦ *) A copolymer of about 50% cyclopentadiene, about 40% aromatic hydrocarbon and about 10% other olefins, having a softening point of 105 ⁰ C and a bromine value 99th
** ·) A copolymer of about 70% cyclopentadiene and about 30% other olefins, with a softening point of 102 ^° C. and a bromine number of 107.

♦♦♦ ·) The number of cuts and chips per 100 cm ¹ running surface after the running test, whereby "large cuts" are those with a cut depth of more than 5 mm, tsmall cuts "those with a cut depth between 1 and 5 mm and "Schnitzel" mean torn tread pieces of more than 25 mm *.

As can be seen from the table above, the 35 and the others have a tread made from the mixtures

Cyclopentadiene resin compared to the usual compound X-I-J-K possessed.

working oil and coumarone resin essentially contribute to a From Table 2 it can be seen that the cyclopentadiene

Improvement of the cut resistance of the elastomeric petroleum resins the cut resistance of the butadiene-styrene

Mass at. Rubber compounds improve, but that too

B ice ρ ie 1 2 ⁴ ° ^erm i ß ^he amount of resin or at too low bromine number

or too low a softening point of the

As in Example 1, the blends and resins had the same effect as Blends J and K

Tests carried out in the same way, whereby show is worse than in the case of the invention

however, the appearance of the tread as a result of the masses, albeit always with cyclopentadiene petroleum resins

Driving tests with tires is given, one of which gives 45 even better results than the usual

a tread made from the four mixtures X — F — G — H additives.

Table 2

X F. G H I. J K Butadiene-Styrene-Kautscl · ¹ uk 100 100 100 100 100 100 100 Stearic acid 2 2 2 2 2 2 2 Highly abrasion-resistant furnace soot 60 60 60 60 60 60 60 Aromatic processing oil 20th - - - - - - Cyclopentadiene resin C *) - 20th - - - - - Cyclopentadiene resin D **) - - 20th - - - - Cyclopentadiene resin E ***) - - - 20th - - - Cyclopentadiene resin F ****) - - - - 20th - - Cyclopentadiene resin G *****) - - - - - 20th - Cyclopentadiene resin H ******) - - - - - - 20th Wax and antioxidants 3 3 3 3 3 3 3 zinc oxide 3 3 3 3 3 3 3 Vulcanization accelerator 1.6 1.6 1.6 1.6 1.6 1.6 1.6 sulfur 2 2 2 2 2 2 2

/ 7 X F. G H I. 8th K Table 2 (continued) 5m / sec: 670 690 690 660 680 j 630 At a train speed of 172 194 196 195 203 180 Rotation (° / ₀ ) 95 108 110 121 123 710 99 Tensile strength (kp / cm ¹ ) 21.5 2.6 3.2 1.1 0.7 168 15.1 300% module (kp / cm ¹ ) 91 Impact-cut test (mm) 4.9 1.1 1.1 0.6 0.7 18.4 4.1 Appearance of the tread: 18.2 5, Γ. 6.1 4.9 3.4 13.9 Big cuts 4.0 Small cuts 15.4

Schnitzel 3.1 0.4 0.3 0.4 0.5 2.4 3.5

J and K represent comparison tests. In the above table 2:

*) A cyclopentadiene resin with a softening point of 148 ° C and a bromine number of 131.

**) A copolymer of about 50% cyclopentadiene, about 10% aromatic olefins and

about 40% other olefins, with a softening point of 72 ° C and a bromine number of 115.

* · *) A copolymer of about 35% cyclopentadiene, about 55% aromatic olefins and

about 10% other olefins, with a softening point of 109 ° C and a bromine number of 59.

* · ♦ *) A copolymer of about 85% cyclopentadiene, and about 10% aromatic olefins,

with a softening point of 145 ⁰ C and a bromine number of 122.

· »» · *) A copolymer of about 15% cyclopentadiene, about 25% aromatic olefins and about 60% other olefins, with a softening point of 42 ° C and a bromine number of 97. ·) A copolymer of about 10% cyclopentadiene and about 90% aromatic olefins, with a softening point of ISl ⁰ C and a bromine number of 31.

Claims (1)

abilities related to the wear properties. Claim: For the speed wear tests Reproduction of the cuts was a Elastomeric compound, consisting of a mixture of metal blades, pushed into the barrel of an elastomeric copolymer made of buta 5 at high speed, taking into account the position of polymers made of cyclopentadiene and / or cuts in addition to the measurements that are usual for basic wear tests with velocity diene and styrene and a petroleum resin After numerous mixtures of materials, olefin characterized by the fact that the amount of petroleum resin was found to be 5 to 40 parts by weight of 100 parts by weight of rubber was satisfactorily ascertainable wear weight parts at high speeds, or dicyclopentadiene and a copolymerizable material showed, is that petroleum resin is more than 30 percent by weight To develop a bromine number of 40 genes for the tread, which have up to 150 and a softening point of 50 to 15 desired cut resistance.
200 ⁰ C as measured by the ring and ball test Extensive experiments were conducted with carbon black-containing according to J / S K-5902. Elastomers such as natural rubber and butadiene Styrene rubber. It is well known that adding a great deal of carbon black to the ao rubber compound on the one hand improve the cut resistance can, but on the other hand deteriorates other properties of treads made of such mixtures be e.g. B. Tear resistance, elasticity, exothermic