CN102108142B - Rubber composition for tire tread and tire manufactured using composition - Google Patents

Abstract

The invention provides a rubber composition for a tire tread and a tire manufactured using the rubber composition, and the rubber composition comprises 100 parts by weight of rubber raw materials which contain 70-90 parts by weight of solution polymerized styrene-butadiene rubbers (S-SBR) with the styrene content of 20-30 wt% and the content of the vinyl group contained in butadiene of 50-60 wt%; 10-30 parts by weight of butadiene rubbers (BR); and 60-90 parts by weight of silicon dioxide. The end of the molecule of the solution polymerized styrene-butadiene rubber is modified to be alkoxy silane, and the molecules are coupled by silicon. The rubber composition for a tire tread reduces hysteresis loss and maximizes the performance of low fuel consumption, and the reduced braking performance as a result of the maximization of the performance of low fuel consumption becomes excellent; the rubber composition for a tire tread also improves the processability in an unvulcanized state, the braking performance in a vulcanized state, the abrasion resistance and the revolving resistance.

Description

Rubber composition for tire tread and the tire that utilizes said composition to make

Technical field

The tire that the present invention relates to rubber composition for tire tread and utilize said composition to make, particularly, relate to the excellent processability under sulfided state not, and the tire that has improved simultaneously the rubber composition for tire tread of braking, wear resistance and low burnup performance and utilized said composition to make.

Background technology

In recent years, along with the high performance of passenger car, human consumers have also proposed the requirement of high performance to tire, particularly, demand to the tire that has simultaneously wear resistance, handling, driving, wetland braking ability and low burnup performance concurrently causes the application of active research exploitation novel material.In order to develop the tire that has simultaneously above-mentioned wear resistance, handling, driving, wetland braking ability and low burnup performance concurrently, particularly carrying out a large amount of research in Material Field.

Generally, in order to reduce the rotational resistance relevant with the burnup performance of tire, reduce the usage quantity of reinforcing filler, thereby reduce the interaction between toughener and toughener, in order to reduce hysteresis loss.

Yet, in this technology, exist the content along with the enhancement weighting agent to reduce, as the braking ability of the key property of tire tread and the shortcoming that control stability can reduce.

As mentioned above, in the developing material technology of existing tire, if improve wear resisting property and the burnup performance of tire, the situation that braking ability reduces on the contrary can occur; When improving the braking ability of tire, can be unfavorable for the burnup performance or reduce the situation that wear resisting property reduces.So, with regard to the various performances of tire, if improve wherein a kind of performance, the phenomenon that other performances reduce can occur, therefore, when needing exploitation to improve a kind of performance, other reduction of performances minimize as far as possible, perhaps two kinds of technology that performance improves simultaneously.

Summary of the invention

The object of the present invention is to provide a kind of rubber composition for tire tread, make under sulfided state not, processing characteristics is good, also improves simultaneously braking, wear resistance and low burnup.

Another object of the present invention is to, the tire that uses above-mentioned rubber composition for tire tread to make is provided.

To achieve these goals, the rubber composition for tire tread that one embodiment of the invention relate to, comprise: the crude rubber of 100 weight parts, it contains: the solution polymerization type styrene butadiene rubbers (S-SBR) of 70 to 90 weight parts, wherein, cinnamic content is 20 to 30 % by weight, and the contents of ethylene that divinyl comprises is 50 to 60 % by weight; Divinyl rubber (BR) with 10 to 30 weight parts; And the silicon-dioxide of 60 to 90 weight parts; Molecular end in mentioned solution aggretion type styrene butadiene rubbers is modified as organoalkoxysilane, passes through the mutual coupling of silicon between molecule.

Preferably, the nitrogen adsorption specific surface area of above-mentioned silicon-dioxide is 150 to 185m ²/ g, cetyl trimethylammonium bromide (CTAB) adsorption specific surface area is 150 to 170m ²/ g.

According to another embodiment of the present invention, provide a kind of tire that uses above-mentioned rubber composition for tire tread to make.

Below, describe the present invention in detail.

Above-mentioned rubber composition for tire tread comprises: the crude rubber that contains styrene butadiene rubbers and divinyl rubber; And silicon-dioxide.

For the rotational resistance performance of the best, above-mentioned styrene butadiene rubbers is preferably used 70 to 90 weight parts.When the content of above-mentioned styrene butadiene rubbers surpassed 90 weight part, wear resisting property can reduce; When containing quantity not sufficient 70 weight part, rotational resistance characteristic and braking ability can reduce.

Above-mentioned styrene butadiene rubbers comprises that cinnamic content is that the contents of ethylene that 20 to 30 % by weight, divinyl comprise is the solution polymerization type styrene butadiene rubbers of 50 to 60 % by weight.Be in the situation of above-mentioned styrene butadiene rubbers of 20 to 30 % by weight when using cinnamic content, due to the microtexture that is beneficial to rotational resistance, make low burnup excellent property.

Above-mentioned styrene butadiene rubbers, emulsion polymerization type styrene butadiene rubbers (Emulsion-polymerized Styrene Butadiene Rubber is arranged, E-SBR) and two kinds of solution polymerization type styrene butadiene rubbers (Solution-polymerized Styrene Butadiene Rubber, S-SBR).

Generally, mentioned solution aggretion type styrene butadiene rubbers can obtain by continous way method and batch process manufacturing.Particularly, mentioned solution aggretion type styrene butadiene rubbers can be by the batch process manufacturing.Solution polymerization type styrene butadiene rubbers by above-mentioned continous way method manufacturing, compare with the solution polymerization type styrene butadiene rubbers by above-mentioned batch process manufacturing, although excellent processability some, but a large amount of low molecular weight substances can cause producing a large amount of hysteresis losses, therefore, be unfavorable for low burnup performance.On the contrary, the solution polymerization type styrene butadiene rubbers of making by batch process, because its molecular weight distribution degree (MWD) is 1.3 to 1.5, therefore, with compare by the styrene butadiene rubbers of continous way method manufacturing, present narrower molecular weight distribution, be conducive to rotational resistance performance and low burnup performance.

Molecular end in mentioned solution aggretion type styrene butadiene rubbers is modified as organoalkoxysilane, can pass through silicon coupling (coupling) between molecule.

Molecular end is modified as in the solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane, can improve the dispersiveness of silicon-dioxide, and the interaction between enhancing silicon-dioxide and rubber, improve the low burnup performance of rubber, and, linked reaction by silicon connects each molecule, produces the molecule terminal number of reason thereby reduce as lagging behind, and can make low burnup performance maximization.In addition, its processibility and low burnup performance are also good.

Above-mentioned organoalkoxysilane refers to the silane compound that contains alkoxyl group.Be modified as in the solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane in molecular end, the organoalkoxysilane of the molecular end that is modified can represent with following Chemical formula 1.

[Chemical formula 1]

In above-mentioned Chemical formula 1,

Above-mentioned R ₁And R ₃Respectively independently from being that 1 to 15 alkyl, charcoal prime number are that 1 to 15 special-shaped alkyl, carbon element number are that 3 to 15 ring-like alkyl, carbon element number are that 3 to 15 different ring-like alkyl, carbon element number are any that select 1 to 15 alkoxyl group and their group that constitutes by hydrogen, halo atom, charcoal prime number, preferably from being that 1 to 10 alkyl, carbon element number are that 1 to 10 special-shaped alkyl, carbon element number are any that select 1 to 10 alkoxyl group and their group that constitutes by hydrogen, halo atom, charcoal prime number.

Above-mentioned R ₂From being that 1 to 15 alkyl, charcoal prime number are that 1 to 15 special-shaped alkyl, carbon element number are that 3 to 15 ring-like alkyl, carbon element number are any that select 3 to 15 shaped rings alkyl and their group that constitutes by hydrogen, halo atom, charcoal prime number, preferably from being that 1 to 10 alkyl, carbon element number are any of 1 to 10 special-shaped alkyl and their group selection that constitutes by hydrogen, halo element, carbon element number.

Above-mentioned special-shaped alkyl refers to the carbon atom in alkyl is replaced to 1 to 3 different (hetero) atom selecting from the group that is made of above-mentioned N, O, S and P, and above-mentioned shaped rings alkyl refers to the carbon atom in ring-like alkyl is replaced to the exotic atom of 1 to 3 of selecting from the group that is made of above-mentioned N, O, S and P.Above-mentioned halogen atom can be any that select from the group that is made of fluorine, chlorine, bromine, iodine.

Particularly, molecular end is modified as in the solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane, and molecular end can be modified as from by any alkoxysilane compound containing trialkylsilyl group in molecular structure of selecting propyl trimethoxy silicane, propyl-triethoxysilicane, N-hexyl Trimethoxy silane, methyl dimethoxysilane, benzene Trimethoxy silane, Ethenylbenzene methyl-amino methyl-aminopropyl-triethoxyl silane, sulfydryl Trimethoxy silane and their group that constitutes.

Molecular end is modified as the solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane, butadiene type monomer, vinyl monomer and organoalkoxysilane can be carried out polymerization and make in non-active solvent.

The representative of above-mentioned butadiene type monomer is 1,3-butadiene, but is not limited to this; The representative of vinyl monomer is vinylbenzene, but the present invention is not limited to this.Above-mentioned non-active solvent can be from by select benzene,toluene,xylene, pentane, hexane, heptane, different oxane, hexanaphthene and their group that constitutes any, but be not limited to this, if the non-active solvents such as aliphatics carbonization hydrogen, alicyclic hydrocarbon, aromatic series hydrocarbon can use.

Be modified as in the manufacturing of solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane in molecular end, can use polymerization starter, above-mentioned polymerization starter can use basic metal, alkaline-earth metal etc., can also use from by select lithium, barium and their group that constitutes any, but be not limited to this.

Above-mentioned polyreaction can be carried out under 20 to 120 ℃ continuously or discontinuously.

Molecular end is modified as in the solution polymerization type styrene butadiene rubbers of above-mentioned organoalkoxysilane, can pass through the mutual coupling of silicon between molecule.

The solution polymerization type styrene butadiene rubbers that makes molecular end be modified as above-mentioned organoalkoxysilane is carried out the method for coupling by silicon, can adopt the known method of the technical field of the invention to carry out, but be not limited to ad hoc approach of the present invention.

The solution polymerization type styrene butadiene rubbers that makes molecular end be modified as above-mentioned organoalkoxysilane is carried out the method for coupling by silicon, can be following method: add the polymerization starter of dual anionic form in the mixing solutions of vinylbenzene and divinyl after, carry out polymerization while stirring, then the salinization tin that adds as coupling agent stirs as the agent that terminates again, at this moment, in the polymeric molecular end of styrene butadiene, have the reaction of reactive free radical and salinization tin, make multiple polymers carry out coupling with tin as medium.

For above-mentioned divinyl rubber, so long as the divinyl rubber that uses in rubber composition for tire just can use.The content of above-mentioned divinyl rubber can be 10 to 30 weight parts, when the content that uses above-mentioned divinyl rubber surpasses 30 weight part, the rubbery intensity ratio of weak divinyl rubber uprises, therefore braking may reduce, when use contained quantity not sufficient 10 weight part, the problem that wear resistance reduces can occur.

Above-mentioned divinyl rubber preferably uses the divinyl rubber that does not contain oils.When above-mentioned divinyl rubber does not contain oils, have low burnup and the favourable effect of processibility.

Above-mentioned rubber composition for tire tread contains silicon-dioxide as the enhancement weighting agent.

In order to obtain realizing the tread rubber composition of the object of the invention, it is 150 to 185m that above-mentioned silicon-dioxide preferably uses the nitrogen adsorption specific surface area ²/ g, cetyl trimethylammonium bromide (cetyltrimenthyl ammonium bromide, CTAB) adsorption specific surface area are 150 to 170m ²The silicon-dioxide of/g, more preferably using the nitrogen adsorption specific surface area is 160 to 185m ²/ g, cetyl trimethylammonium bromide (CTAB) adsorption specific surface area are 155 to 165m ²The silicon-dioxide of/g.

With respect to the crude rubber of 100 weight parts, can use the above-mentioned silicon-dioxide of 60 to 90 weight parts, when the content of above-mentioned silicon-dioxide surpassed 90 weight part, the rotational resistance performance can reduce; During less than 60 weight part, unfavorable to wear resistance when content.

Above-mentioned silicon-dioxide can use all silicon-dioxide by wet type method for making or the preparation of dry type method for making, as commercially available product, can use Ultrasil VN2 (Degussa company make), Ultrasil VN3 (Degussa company make) etc., but be not limited to this.

In order to improve the dispersiveness of above-mentioned silicon-dioxide, can further contain coupling agent in above-mentioned rubber composition for tire tread.

As above-mentioned coupling agent, can use from being that coupling agent, ethene base system coupling agent, amino are that coupling agent, glycidoxy are that coupling agent, nitro are that coupling agent, chloro are that coupling agent, methacryloyl are any that select coupling agent and the group that constitutes thereof by sulfide-based coupling agent, sulfydryl.

above-mentioned sulfide-based coupling agent can be from by two [3-(triethoxysilicane) propyl group]-tetrasulfides, two [2-(triethoxysilicane) ethyl]-tetrasulfides, two [4-(triethoxysilicane) butyl]-tetrasulfides, two [3-(trimethoxy silicon) propyl group]-tetrasulfides, two [2-(trimethoxy silicon) ethyl]-tetrasulfides, two [4-(trimethoxy silicon) butyl]-tetrasulfides, two [3-(triethoxysilicane) propyl group]-trisulphides, two [2-(triethoxysilicane) ethyl]-trisulphides, two [4-(triethoxysilicane) butyl]-trisulphides, two [3-(trimethoxy silicon) propyl group]-trisulphides, two [2-(trimethoxy silicon) ethyl]-trisulphides, two [4-(trimethoxy silicon) butyl]-trisulphides, two [3-(triethoxysilicane) propyl group]-disulphide, two [2-(triethoxysilicane) ethyl]-disulphide, two [4-(triethoxysilicane) butyl]-disulphide, two [3-(trimethoxy silicon) propyl group]-disulphide, two [2-(trimethoxy silicon) ethyl]-disulphide, two [4-(trimethoxy silicon) butyl]-disulphide, 3-trimethoxy silicon propyl group-N, N-dimethyl thiocarbamoyl tetrasulfide, 3-triethoxysilylpropyl-N, N-dimethyl thiocarbamoyl tetrasulfide, 2-triethoxy silica ethyl-N, N-dimethyl thiocarbamoyl tetrasulfide, 2-trimethoxy silica ethyl-N, N-dimethyl thiocarbamoyl tetrasulfide, 3-trimethoxy silicon propyl group benzothiazole tetrasulfide, 3-triethoxysilylpropyl benzothiazole tetrasulfide, 3-trimethoxy silicon propyl methyl acid esters list sulfide, any one that select in 3-trimethoxy silicon propyl methyl acid esters list sulfide and the group that constitutes thereof.

Above-mentioned sulfydryl be coupling agent can be from by select (3-sulfydryl propyl group) Trimethoxy silane, (3-sulfydryl propyl group) triethoxyl silane, (2-mercaptoethyl) Trimethoxy silane, (2-mercaptoethyl) triethoxyl silane and the group that constitutes thereof any.Above-mentioned ethene base system coupling agent can be from by select Ethoxysilane, vinyltrimethoxy silane and the group that constitutes thereof any.Above-mentioned amino be coupling agent can be from by select APTES, 3-TSL 8330,3-(2-amino-ethyl) aminopropyltriethoxywerene werene, 3-(2-amino-ethyl) TSL 8330 and the group that constitutes thereof any.

Above-mentioned glycidoxy be coupling agent can be from by select γ-glycidoxy propyl-triethoxysilicane, γ-glycidoxypropyltrime,hoxysilane, γ-glycidoxy propyl group methyldiethoxysilane, γ-glycidoxy propyl group methyl dimethoxysilane and the group that constitutes thereof any.Above-mentioned nitro be coupling agent can be from by select 3-nitro propyl trimethoxy silicane, 3-nitro propyl-triethoxysilicane and the group that constitutes thereof any.Above-mentioned chlorine be coupling agent can be from by select 3-r-chloropropyl trimethoxyl silane, 3-chloropropyl triethoxysilane, 2-chloroethyl Trimethoxy silane, 2-chloroethyl triethoxyl silane and the group that constitutes thereof any.

Above-mentioned methacryloyl be silane compound can be from by select (γ-methacryloyl propyl group) Trimethoxy silane, (γ-methacryloyl propyl group) methyl dimethoxysilane, (γ-methacryloyl propyl group) dimethyl methyl TMOS and the group that constitutes thereof any.

With respect to the crude rubber of 100 weight parts, can contain the above-mentioned coupling agent of 4.8 to 7.2 weight parts.During less than 4.8 weight part, insufficient with the reaction of silicon-dioxide when the content of above-mentioned coupling agent, cause the processibility of rubber to reduce, perhaps low burnup performance reduces; When content surpassed 7.2 weight part, the interaction between silicon-dioxide and rubber was excessively strong, although low burnup excellent property, braking ability may reduce a lot.

Above-mentioned rubber composition for tire tread can also comprise the various additives such as the vulcanizing agent that optionally appends, vulcanization accelerator, vulcanization accelerator additive, antiaging agent, tenderizer.For above-mentioned various additives, so long as the additive that often uses in the technical field of the invention just can use, its content is according to the proportioning decision of using in common rubber composition for tire tread, this without particular limitation of.

Above-mentioned vulcanizing agent can use the metal oxides such as sulphur class vulcanizing agent, organo-peroxide, resin curative, magnesium oxide.

As above-mentioned sulphur class vulcanizing agent, can use the inorganic sulphide agent such as sulphur powder (S), insoluble sulfur (S), precipitation sulphur (S), colloid sulphur (colloid), and tetramethyl-thiuram disulfide (tetramethyl thiuram disulfide, TMTD), the organic sulfurizing agents such as tetraethylthiuram disulfide (tetraethyl thiuram disulfide, TETD), dithio morpholine (dithiodimorpholine).Particularly, above-mentioned sulfur vulcanizing agent can use the vulcanizing agent that can prepare primary sulfur or sulphur, such as curing amine (amine disulfide), polymer sulphur etc.

above-mentioned organo-peroxide can use from by benzoyl peroxide, dicumyl peroxide, ditertiary butyl peroxide, the tert-butyl peroxide diisopropylbenzyl, methylethyl ketone peroxide, Cumene Hydroperoxide 80, 2, 5-dimethyl-2, 5-two (t-butylperoxy) hexane, 2, 5-dimethyl-2, 5-two (benzoyl peroxy) hexane, 2, 5-dimethyl-2, 5-two (t-butylperoxy) hexane, 1, two (t-butylperoxy propyl group) benzene of 3-, di-tert-butyl peroxide-diisopropylbenzene(DIPB), t-butylperoxy benzene, peroxidation 2, the 4-dichloro-benzoyl, 1, 1-di-t-butyl peroxy-3, 3, the 5-trimethicone, 4, any that select in 4-di-tert-butyl peroxide n-butyl pentanoate and the group that constitutes thereof.

Comprise the above-mentioned vulcanizing agent of 0.5 to 2.5 weight part with respect to the above-mentioned raw materials rubber of 100 weight parts, this can realize better cure efficiency, makes crude rubber insensitive to heat, and stable chemical performance, is therefore preferred content.

The promotor (accelerator) that above-mentioned vulcanization accelerator refers to promote vulcanization rate or promotes delayed action at initial sulfurating stage.

As above-mentioned vulcanization accelerator, can use from by select sulfenamide, thiazoles, thiocarbamyl class, Thiourea, guanidine class, dithiocarbamate(s), aldehyde amines, aldehyde ammonia class, imidazolines, xanthogenic acid salt and the group that constitutes thereof any.

As above-mentioned sulfenamide vulcanization accelerator, for example can use from by N cyclohexyl 2 benzothiazole sulfenamide (CBS), N tert butyl benzothiazole 2 sulfenamide (TBBS), N, N-dicyclohexyl-2-[4-morpholinodithio sulphenamide, N oxydiethylene 2 benzothiazole sulfenamide, N, any sulphenamide compounds of selecting in N-di-isopropyl-2-[4-morpholinodithio sulphenamide and the group that constitutes thereof.

As above-mentioned thiazoles vulcanization accelerator, for example can use from sodium salt, the zinc salt of 2-mercaptobenzothiazole, the mantoquita of 2-mercaptobenzothiazole, the cyclohexylamine salt of 2-mercaptobenzothiazole, 2-(2 by 2-mercaptobenzothiazole (MBT), dibenzothiazyl disulfide (MBTS), 2-mercaptobenzothiazole, the 4-dinitrophenyl) any thiazole compound of selecting in mercaptobenzothiazole, 2-(2,6-diethyl-4-morpholinothio) benzothiazole and the group that constitutes thereof.

as above-mentioned thiocarbamyl class vulcanization accelerator, for example can use from by tetramethyl-thiocarbamyl disulphide (TMTD), tetraethyl-thiocarbamyl disulphide, tetramethyl-thiocarbamyl list sulfide, two pentylidene thiocarbamyl disulphide, two pentylidene thiocarbamyl disulphide, two pentylidene thiocarbamyl tetrasulfides, two pentylidene thiocarbamyl hexasulfides, tetrabutyl thiocarbamyl disulphide, any thiocarbamyl compounds of selecting in pentylidene thiocarbamyl tetrasulfide and the group that constitutes thereof.

As above-mentioned Thiourea vulcanization accelerator, for example can use from by any thiourea of selecting thiocarbamide, diethyl thiourea, dibutyl thiourea, trimethyl thiourea, di-o-tolyl-thiourea and the group that constitutes thereof.

As above-mentioned guanidine class vulcanization accelerator, for example can use from by the guanidine compound of selecting diphenylguanidine, di-o-tolylguanidine, triphenyl guanidine, di-o-tolylguanidine, diphenylguanidine phthalic ester and the group that constitutes thereof.

as above-mentioned dithiocar-bamate vulcanization accelerator, for example can use from by zinc-ethylphenyl dithiocarbamate, the butyl phenyl zinc dithiocarbamate, Sodium dimethyldithiocarbamate 40min, ziram, zinc diethyldithiocarbamate, zinc dibutyl dithiocarbamate, zinc diamyldithiocarbamate, dipropyl disulfide is for carbaminate, the complex compound of zinc pentamethylene dithiocarbamate and piperidines, hexadecyl sec.-propyl zinc dithiocarbamate, zinc octadecylisopropyldithiocarbamate, zinc dibenzyldithiocarbamate, Thiocarb, pentamethylene dithiocarbamic acid piperidines, dimethyl dithiocarbamic acid arsenic, tellurium diethyl dithiocarbamate, any dithiocarbamate(s) compound of selecting in lead diamyldithiocarbamate and the group that constitutes thereof.

As above-mentioned aldehyde amines or aldehyde ammonia class vulcanization accelerator, for example can use from by aldehyde amines or the aldehyde ammonia compounds selected acetaldehyde-aniline reaction product, butyraldehyde-aniline complex compound, hexamethylenetetramine, aldamine reaction product and the group that constitutes thereof.

As above-mentioned imidazolines vulcanization accelerator, such as using the imidazolines such as 2-mercaptoimidazoline, as above-mentioned xanthogenic acid salt vulcanization accelerator, such as using the xanthogenic acid compounds such as dibutyl xanthogenic acid zinc.

For by promoting that vulcanization rate makes the raising of productivity and the raising of rubber physical property reach maximization, with respect to the above-mentioned raw materials rubber of 100 weight parts, can contain the above-mentioned vulcanization accelerator of 0.5 to 4.0 weight part.

Above-mentioned vulcanization accelerator additive be with above-mentioned vulcanization accelerator and with and make the more abundant Synergist S-421 95 that uses of facilitation effect, can use from by select mineral-type vulcanization accelerator additive, organic vulcanization accelerator additive and the group that constitutes thereof any.

As above-mentioned mineral-type vulcanization accelerator additive, can use from by select zinc oxide (ZnO), charcoal acid zinc (zinc carbonate), magnesium oxide (MgO), plumbous oxide (lead oxide), potassium hydroxide and the group that constitutes thereof any.As above-mentioned organic vulcanization accelerator additive, can use from by select stearic acid, Zinic stearas, palmitinic acid, linolic acid, oleic acid, lauric acid, DBAO dibutylammonium oleate (dibutyl ammonium oleate), their derivative and the group that constitutes thereof any.

Especially, as above-mentioned vulcanization accelerator additive, can use simultaneously above-mentioned zinc oxide and above-mentioned stearic acid, in this case, above-mentioned zinc oxide is dissolved in above-mentioned stearic acid, form effective mixture (complex) with above-mentioned vulcanization accelerator, generate free sulphur in vulcanization reaction, thus the crosslinking reaction of easy realization and rubber.

Use at the same time in above-mentioned zinc oxide and above-mentioned stearic situation, in order to obtain the effect of better vulcanization accelerator additive, with respect to the crude rubber of 100 weight parts, can use respectively 1 to 5 weight part and 0.5 to 3 weight part.

The processibility of above-mentioned rubber composition for tire tread is good, so can not comprise tenderizer when mixed rubber, still, also can be included in conventional tyre with the tenderizer that uses in rubber.

Easily process or reduce the hardness of vulcanized rubber in order to give plasticity-to rubber, can add above-mentioned tenderizer in rubber combination.Above-mentioned tenderizer can use from by select treated oil (Process oil), Vegetable oil lipoprotein and the group that constitutes thereof any, but the invention is not restricted to this.

As above-mentioned treated oil, can use from by select paraffin, naphthenic oil, fragrant same clan oil and the group that constitutes thereof any.

But, along with the raising of environmental consciousness in recent years, the content of recognizing the polycyclic aromatic hydrocarbons (Polycyclic Aromatic Hydrocarbons below is called " PAHs ") that contains in above-mentioned aromatic oil is 3 % by weight when above, and the possibility of bringing out cancer strengthens.Treated oil as above-mentioned tenderizer use, can preferably use with respect to whole above-mentioned treated oils, the total content of PAHs composition is that 3 % by weight are following, dynamic viscosity aromatic component in (210 °F of SUS), tenderizer more than 95 ℃ is that 27 to 37 % by weight and alkanes composition are the treated oil of 38 to 58 % by weight at 15 to 25 % by weight, naphthenic composition.

Above-mentioned treated oil has following characteristic, and namely, make cold property, the burnup excellent property of the tire tread that comprises above-mentioned treated oil, the cancer that also is beneficial to PAHs is simultaneously brought out the Environmental Factors such as possibility.

As above-mentioned Vegetable oil lipoprotein, can use from by select Castor oil, Oleum Gossypii semen, Semen Lini oil, mustard caul-fat, soybean oil, palm crude oil, Oleum Cocois, peanut oil, Pinus pumilio oil, Stockholm tar, pine tar, Semen Maydis oil, Rice pollard oil, Thistle oil, sesame oil, sweet oil, sunflower seed oil, palm-kernel oil, Camellia oil, Oenothera oil, Queensland nut oil, Thistle oil, tung oil and the group that constitutes thereof any.

Consider from improving the crude rubber processibility, preferably, with respect to the above-mentioned raw materials rubber of 100 weight parts, use the above-mentioned tenderizer of 20 to 40 weight parts.

Above-mentioned antiaging agent is the additive that uses for the chain reaction of the tire autoxidation of ending to be caused by oxygen.As above-mentioned antiaging agent, can use from by select amine, phenol, imidazoles, carbamic metal-salt and the group that constitutes thereof any.

As above-mentioned antiaging agent, can preferably use from by N-(1, the 3-dimethylbutyl) (N-(1 for-N '-diphenyl-para-phenylene diamine, 3-Dimethybutyl)-N-phenyl-p-phenylenedia mine, 6PPD), N-phenyl-N-sec.-propyl Ursol D (N-phenyl-N-i sopropyl-p-phenylenediamine, 3PPD), (2,2,4-trimethylammonium-1,2-dihydroquinoline polymkeric substance (Poly (2,2,4-trimethyl-1,2-dihydroquinol ine, RD) and the group that constitutes in the compound selected.

Above-mentioned antiaging agent is except having anti-aging effect, solubleness that need to be in rubber is large, volatility is little, not active for rubber, and do not hinder sulfuration etc., consider these conditions, with respect to the above-mentioned raw materials rubber of 100 weight parts, can contain the above-mentioned antiaging agent of 1 to 10 weight part.

Above-mentioned rubber composition for tire tread can use throughout the year, but preferably as using summer.When above-mentioned rubber composition for tire tread can improve low burnup performance, keep braking ability and directional control performance, braking ability in the snowfield that requires during compared with use in winter or wear resisting property, above-mentioned rubber composition for tire tread is more suitable for as summer having favourable effect with the braking on the burnup performance of the salient features of tire tread, wet road surface, the directional control performance when running at high speed etc.

The tire that another embodiment of the present invention relates to is to use above-mentioned rubber composition for tire tread to make.About utilizing above-mentioned rubber composition for tire tread to make the method for tire, so long as the method that tire in the past adopts in making, all applicable, therefore, description is omitted in this manual.

Rubber composition for tire tread of the present invention, reduced hysteresis loss, and low burnup performance is maximized, simultaneously, the braking ability that may reduce because of the maximization of low burnup performance also becomes good, improved simultaneously processibility, the braking ability under sulfided state, wear resistance and rotational resistance etc. under sulfided state not.

Embodiment

Below, describe embodiments of the invention in detail, make person of ordinary skill in the field of the present invention can easily go to realize it.But the present invention can show as various different shapes, the embodiment that is not limited to here illustrate.

[Production Example: the manufacturing of rubber composition for tire tread]

(embodiment and comparative example)

Utilize the composition shown in following table 1, made the rubber composition for tire tread that following examples and comparative example relate to.The manufacture method of common tire tread rubber is adopted in the manufacturing of rubber composition for tire tread.

Table 1 (unit: weight part)

Composition	Comparative example 1	Comparative example 2	Comparative example 3	Embodiment 1	Embodiment 2
						E-SBR (1)	80	-	-	-	-
S-SBR (2)	-	60	-	80	80
						S-SBR (3)	-	-	80	-	-
BR (4)	20	40	20	20	20
						Silicon-dioxide (5)	80	80	80	80	-
Silicon-dioxide (6)	-	-	-	-	80

Coupling agent (7)	6.4	6.4	6.4	6.4	6.4
						Zinc oxide	3	3	3	3	3
Stearic acid	1	1	1	1	1
						Sulphur	1.75	1.75	1.75	1.75	1.75
Promotor (8	1	1	1	1	1
						Promotor (9)	2	2	2	2	2

(1) E-SBR: letex polymerization styrene butadiene rubbers SBR1502;

(2) S-SBR: styrene content is that the contents of ethylene that 20 to 30 % by weight, divinyl contain is 50 to 60 % by weight, be modified as organoalkoxysilane by batch process manufacturing and molecular end, and intermolecular solution polymerization type styrene butadiene rubbers (SBR) by the Si coupling;

(3) S-SBR: styrene content is that the contents of ethylene that 20 to 30 % by weight, divinyl contain is 50 to 60 % by weight, is modified as the solution polymerization type styrene butadiene rubbers (SBR) of organoalkoxysilane by batch process manufacturing and molecular end;

(4) BR: divinyl rubber;

(5) silicon-dioxide: the nitrogen adsorption specific surface area is 170m ²/ g, CTAB adsorption specific surface area are 160m ²The precipitated silica of/g;

(6) silicon-dioxide: the nitrogen adsorption specific surface area is 153m ²/ g, CTAB adsorption specific surface area are 154m ²The precipitated silica of/g;

(7) coupling agent: Si69, Degussa company makes;

(8) promotor: CBS (N-cyclohexyl-2-benzothiazole sulfenamide);

(9) promotor: DPG (vulkacit D);

[test example: measure the physical property that the tire tread of making is used rubber]

The tire tread that utilizes above-mentioned comparative example 1 to make to comparative example 3 and embodiment 1 and the embodiment 2 is measured physical property with rubber, and it be the results are shown in following table 2.

Table 2

	Comparative example 1	Comparative example 2	Comparative example 3	Embodiment 1	Embodiment 2
						Buddhist nun's viscosity not	67	69	68	65	67
Hardness (Shore A)	66	65	64	65	64
						300% modulus (Mpa)	12.6	13.2	12.4	15.0	12.0

Elongation (%)	385	402	314	356	364
						Fastness to rubbing (Index)	100	105	99	106	97
0℃tanδ	0.304	0.284	0.299	0.342	0.354
						60℃tanδ	0.116	0.105	0.102	0.076	0.105

-Mo Ni viscosity (ML1+4 (125 ℃)) is measured according to ASTM standard D1646.

-hardness is measured according to DIN53505.

-300% modulus and elongation are according to the ISO37 canonical measure.

Elongation when-elongation refers to rupture is that the Strain value when quilt is broken in tensile testing machine with testing plate is measured with the method that % represents.

-fastness to rubbing is to use blue Berne wear testing machine (Lambourn abrasion tester) to measure.Carry out take comparative example 1 as benchmark that exponentiate represents.

-visco-elasticity is to use the RDS survey meter, has measured tan δ from 60 ℃ to 80 ℃ to 0.1% strain (strain) under the 10Hz frequency.

In above-mentioned table 2, above-mentioned not Buddhist nun viscosity means the numerical value of the viscosity of unvulcanized rubber, and this value is lower, represents that the processibility of unvulcanized rubber is better.0 ℃ of tan δ represents braking ability, and this numerical value is larger, and braking ability is better; 60 ℃ of tan δ represent the rotational resistance characteristic, and this numerical value is less, this more excellent performance.Above-mentioned hardness represents control stability, and this numerical value is larger, and control stability is better.The numerical value of 300% modulus and elongation is larger, represents that its tensile properties is better; The value of fastness to rubbing is higher, and wear resisting property is better.

With reference to above-mentioned table 2, use with the content beyond content range in the situation of comparative example 2 of S-SBR of the present invention, compare its braking ability with embodiment 1 with 2 and reduce; In the situation of comparative example 3, compare with 2 with embodiment 1, elongation and braking ability show as lower.Embodiment 1 compares and can find out with the comparative example 1 to 3 of conduct tread rubber composition in the past with 2 rubber, when having kept control stability, braking is good, and wear resisting property and rotational resistance characteristic are all very good, and fastness to rubbing, low burnup performance and braking ability are all very good.

Above; describe the preferred embodiments of the present invention in detail, but the claimed interest field of the present invention is not limited thereto, utilizes key concept of the present invention; by various distortion and the improvement that the person of ordinary skill in the field carries out, still belong to the interest field of request of the present invention.

Claims (2)

1. a rubber composition for tire tread, is characterized in that, comprises:

The crude rubber of 100 weight parts, contain: the solution polymerization type styrene butadiene rubbers (S-SBR) of 70 to 90 weight parts, wherein, cinnamic content is 20 to 30 % by weight, the contents of ethylene that divinyl comprises is 50 to 60 % by weight; Divinyl rubber (BR) with 10 to 30 weight parts;

And the silicon-dioxide of 60 to 90 weight parts;

Molecular end in mentioned solution aggretion type styrene butadiene rubbers is modified as organoalkoxysilane, passes through the mutual coupling of silicon between molecule,

The nitrogen adsorption specific surface area of above-mentioned silicon-dioxide is 150 to 185m ²/ g, cetyl trimethylammonium bromide (CTAB) adsorption specific surface area is 150 to 170m ²/ g.

2. tire that utilizes tire tread claimed in claim 1 to make with composition.