The present invention relates to a rubber tyre compound with improved crack propagation resistance.
An essential characteristic of rubber tyre compounds, to ensure long working life of the tyre, is good fatigue resistance. Fatigue resistance is the resistance to failure of a material subjected to periodic stress, and is normally measured in the number of cycles required for an object to fracture.
Crack formation and propagation of a cured rubber compound are one of the main parameters of its fatigue resistance. So, obviously, effectively improving resistance to crack propagation also prolongs the working life of the tyre.
Common practices, to improve crack propagation resistance, are to use natural as opposed to synthetic rubber; a larger quantity of reinforcing filler, such as carbon black; and a larger content of silica not bonded to the polymer base.
These solutions, while improving crack propagation resistance, may conflict with other characteristics demanded of the compound, such as low rolling resistance. Moreover, demand exists for a more marked improvement in crack propagation resistance than is achievable using the above solutions.
It is an object of the present invention to provide a solution to improving crack propagation resistance without also impairing other characteristics of the compound, such as rolling resistance.
For a clearer understanding of the problem the present invention is designed to solve, it is important to bear in mind that a reduction in carbon black content, while improving rolling resistance, also impairs hardness and crack propagation resistance.
According to the present invention, there is provided a rubber tyre compound comprising at least a polymer base; a filler; and a curing system; said compound being characterized by comprising treated silica with an adsorbed curing activator; and said curing activator being in the group comprising sulphenamides, benzothiazoles, guanidines and thiurams.
Preferably, the compound comprises 2 to 15 phr of treated silica.
Preferably, the adsorbed curing activator of said treated silica equals 5-30% by weight of silica.
Preferably, the polymer base comprises 20 to 60 phr of a polymer compound of S-SBR containing 20-50% styrene and 30-70% vinyl, and comprises 10-90% of a first fraction with a mean molecular weight of 50-100×103 and a molecular weight distribution of ≦1.5, and 10-90% of a second fraction with a mean molecular weight of 800-1500×103 and a molecular weight distribution of 3.0.
Preferably, the polymer base comprises 20 to 60 phr of polybutadiene, of which preferably 5 to 50% of 1,2 syndiotactic microstructure; and 40 to 80 phr of natural rubber.
Preferably, the filler comprises 5 to 50 phr of carbon black and 5 to 50 phr of silica.
A further object of the present invention is a tyre comprising at least one portion made from a compound in accordance with the present invention.
A further object of the present invention is a method of producing rubber tyre compounds, the main characteristics of which method are indicated in Claim 9, and the preferred and/or auxiliary characteristics of which are indicated in Claims 10 to 15.
A number of non-limiting embodiments are described below by way of example, for a clearer understanding of the present invention.
Five control compounds (A-E) and seven compounds (F-L) according to the present invention were produced.
The compounds according to the present invention all contain the same amount of treated silica, on which a curing activator was adsorbed.
The treated silica was produced as described below.
—Treated Silica Production Procedure—
the silica was dried in an oven at 150° C. for 2 hours;
a quantity of curing activator equal to 10% by weight of the silica was dissolved in cyclohexane at 50° C.:
the silica was added to the solution and stirred continuously for 1 hour at ambient temperature;
the silica was allowed to settle, and was then separated from the solvent, washed once, and dried under a hood for 1 hour.
The treated silica used in compounds F-I according to the present invention was produced as described above.
All the compounds were produced as described below.
—Compound Production Procedure—
(First Mixing Step)
Prior to mixing, a 230- to 270-litre tangential-rotor mixer was loaded with the polymer base and the ingredients in Tables I, II and III to a fill factor of 66-72%.
The mixer was operated at a speed of 40-60 rpm, and the resulting mixture was unloaded on reaching a temperature of 140-160° C.
(Second Mixing Step)
The mixture from the first step was mixed again in the mixer operated at a speed of 40-60 rpm, and was unloaded on reaching a temperature of130-150° C.
(Third Mixing Step)
The curing system, comprising sulphur and accelerants, and other ingredients shown in Tables I, II and III were added to the mixture from the second step to a fill factor of 63-67%.
The mixer was operated at a speed of 20-40 rpm, and the resulting mixture was unloaded on reaching a temperature of 100-110° C.
Table I shows the compositions in phr of the five control compounds, and the mixing steps in which the ingredients were added.
TDAE is a plasticizer in accordance with European Standard 2005/69/EEC governing tyre oil.
TBBS (N-ter-butylbenzothiazolesulphenamide) is a curing accelerant.
Table II shows the compositions in phr of the first four compositions according to the present invention, and the mixing steps at which the ingredients were added.
S-SBR LMW is a polymer compound of S-SBR containing 20-50% styrene and 30-70% vinyl, and comprises 10-90% (in this case, 27.3%) of a first fraction with a mean molecular weight of 50-100×103 and a molecular weight distribution of 1.5, and 10-90% (in this case, 72.7%) of a second fraction with a mean molecular weight of 800-1500×103 and a molecular weight distribution of ≦3.0.
VCR BR is a polymer compound containing 5-50% of 1,2 syndiotactic polybutadiene in a 1,4 cis polybutadiene matrix.
TREATED SILICA1 is silica on which the TBBS (N-ter-butylbenzothiazolesulphenamide) curing activator has been adsorbed.
Table III shows the compositions in phr of the other three compounds (J, K, L) according to the present invention, and the mixing steps at which the ingredients were added. Compounds J, K and L have the same compositions as compound I in Table II.
TREATED SILICA2 is silica on which an MBTS (2,2′-DIBENZOTHIAZYL DISULPHIDE) curing activator has been adsorbed.
TREATED SILICA3 is silica on which a DPG (DIPHENYL GUANIDINE) curing activator as been adsorbed.
TREATED SILICA4 is silica on which a TBZTD (TETRABENZYLTHIURAMDISULPHIDE) curing activator as been adsorbed.
The compounds so formed were tested for crack propagation resistance, tenacity, and rolling resistance.
More specifically, the rolling resistance values were calculated from Tan δ values measured as per ASTM Standard D5992; the tenacity test was conducted as per ISO Standard 37, using the stress-strain curve area and therefore the failure energy of the test piece as a representative tenacity value; and the crack propagation resistance test was conducted as per ISO Standard 27727.
Tables IV and V show the results of the above tests. The values are indexed with respect to those of control compound A (the higher the value, the better the performance).
As shown by the results in Tables IV and V, the compounds according to the present invention give excellent crack propagation resistance values without compromising the rolling resistance values.
The above advantages are achieved using adsorbed curing activators in the group comprising sulphenamides, benzothiazoles, guanidines and thiurams. These curing activators have the ability to lower the resilience of rubber close to the silica particles on which they are adsorbed, thus improving crack propagation resistance.
Particularly noteworthy are compounds G-L containing both treated silica and the S-SBR LMW polymer base. These all give excellent results, especially compound I also comprising silica and the silane bonding agent.
An interesting point to note in Table IV is how the addition of untreated silica (compound C) or extra TBBS together with untreated silica (compound D) at the third mixing step does not have the same effects as when using treated silica. Which therefore confirms how the advantage achieved actually depends on employing silica with an adsorbed, as opposed to separate, curing activator.
Number | Date | Country | Kind |
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TO2012A000064 | Jan 2012 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2013/050674 | 1/25/2013 | WO | 00 | 7/24/2014 |