Ya misato, influence ya ba propriétés ya surface na état ya surface ya ba particules ya noir carbone na renforcement.
Chimie ya likolo ya ba particules ya noir ya carbone, rugosité ya surface ya ba particules, mpe état cristallin ya noir ya carbone ezali na influence moko boye na effet de renforcement. groupe ya sulfonium to groupe hydroquinone na surface ya noir ya carbone ekoki ko réagir chimique na caoutchouc oléfin na tango ya ko reférer na ba vulcanisations ya noir ya carbonique, mpe ya ko vulcanisation, mpe ya ko vucanzation, mpe ya ko vucanzation, mpe ya ko vulcanisation, mpe ya ko vulcanzer.
Ya minei, impact ya ba variables ya noir carbone na efficacité ya renforcement!
Motango ya moindo ya carbone na caoutchouc ekoki kozala na bopusi makasi na ba propriétés physiques mpe mécaniques ya caoutchouc vulcanisé. Pratique emonisaki ete makasi, makasi ya traction mpe botongi ya molunge emati monotonement na bomati ya noir ya carbone. taux ya rebound, elongation, mpe ndenge moko emonanaka mpo na kokitisa monotone. wear wear stress, koleka makasi mpe resistance ya makasi, malamu koleka ya makasi mpe ya koleka na yango ya makasi mpe ya koleka na yango ya mabe mpe ya koleka na yango ya makasi mpe ya koleka na yango ya makasi mpe ya koleka na yango ya makasi mpe ya makasi na yango, oyo ezali na bokasi ya koleka, ya malamu koleka mpe ya makasi ya koleka, ya malamu koleka mpe ya makasi na yango na ndenge ya mabe mpe ya koleka na yango na ndenge ya mabe mpe na resistance ya malamu koleka mpe na resistance ya malamu koleka mpe na resistance maximate mpe na resistance ya malamu koleka mpe na resistance ya malamu koleka mpe na resistance maximate mpe na maximum. appears. With the increase of the amount of carbon black, the wear resistance of vulcanized rubber is significantly enhanced at the beginning. After increasing to the maximum value, the carbon black is increased again, and the wear resistance is no longer changed significantly. When the total specific surface area of the carbon black in the rubber is equal, the carbon black of the larger particles has better wear resistance, and the smaller particles have less wear resistance, which is related to the dispersion of the carbon black Na caoutchouc. soki bonene ya particule ya noir ya carbone ezali moke, dispersibilité ekozala mabe koleka, na yango kokitisa résistance ya kolata.
Motango ya moindo ya carbone ezali mpe na effet ya monene na conductivité électrique ya caoutchouc vulcanisé. Tango motango ebakisami, résistance électrique ya caoutchouc vulcanisé ekitisami mingi.
5. Bosali ya mosala ya moindo ya carbone mpe caoutchouc, .
Ba propriétés ya base ya noir de carbone pe effet na mélange ya caoutchouc noir ya carbone ezali très significatif. en raison ya ba propriétés différentes ya noir de carbone, vitesse ya mélange na effet ya dispersion ya noir ya carbone ekeseni, pe ba noirs ya carbone ndenge na ndenge ezali na ba viscosités ya mooney différents. . taux ya alimentation ya poudre ya caoutchouc na caoutchouc ezali proche ya taille ya particule na structure ya likolo, ya moke koleka ya particule, ya moke koleka oyo ezali ya likolo, oyo ezali ya likolo koleka oyo ezali ya likolo, oyo eleki moke, oyo ezali ya likolo, oyo ezali moke koleka oyo ezali ya likolo, oyo ezali moke koleka oyo ezali ya likolo, oyo ezali moke koleka oyo ezali ya likolo, oyo eleki moke, oyo ezali moke koleka oyo ezali ya moke koleka oyo ezali ya moke koleka na oyo ya likolo, oyo eleki moke, oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo ezali moke koleka oyo eleki moke, oyo ezali moke koleka oyo eleki moke, ya moke koleka ya moke koleka ya moke koleka ya ba particules. Noir de carbone na taille ya particule ya moke mpe degré ya structure ya moke ezali na dispersion ya mabe mpe temps ya mélange ya molayi. Noir de carbone ya rainure ezali na effet ya dispersion ya mabe soki tokokanisi yango na noir ya carbone oyo ezali résistantes na ba usures ya likolo, mpe taille ya particule ya mibale ekeseni mingi te mpo structure ya noir ya canal ezali moke.
The carbon black kneading glue is placed in a solvent, and there is a partially insoluble gel particle, which is a combination of carbon black and rubber called a carbon black gel or a bonding rubber. The amount of carbon black gel produced is related to the type and amount of carbon black, the type of rubber, and the conditions of the mixing. The amount of carbon black gel produced is an important measure of the effect of carbon black on rubber reinforcement. The gel is a rubber macromolecule that is combined with carbon black after being broken, and captures the hydrogen atom of the carbon black to form a chemical bond of the combination of the rubber and the carbon black and a physical bond of mutual adsorption. A similar network combination is formed by a combination of chemical and physical. The particle size and structure of carbon black have a significant effect on the ability to form a gel, with a greater influence on the℃of structure. The smaller the particle size and the higher the℃of structure, the easier it is to form a gel. Carbon black is more likely to be produced than carbon black having a high wear resistance particle size. It is more remarkable in rubber with low unsaturation. The amount of gel produced varies with the type of rubber. Natural gel, styrene butadiene rubber, butadiene and neoprene produce much more gel than butylbenzene and butadiene rubber. The low℃of unsaturation of butyl and ethylene propylene is almost impossible to form a carbon black gel. The temperature of the rubber is also closely related to the amount of carbon black gel. At high temperatures, the gel is promoted. During the mixing process, the carbon black gel can continue to form in the rubber. The higher the temperature is. The faster the gel content increases. The Mooney viscosity of the rubber compound has a great relationship with the rubber processing technology, and the high Mooney viscosity rubber compound often causes difficulties in the processing. The viscosity change of the carbon black rubber compound has a direct relationship with the carbon black gel. The larger the gel in the carbon black rubber compound, the higher the Mooney viscosity of the rubber compound. The Bonene ya particule ya noir ya carbone, soki structure ekozala likolo mpe dose ezali likolo, viscosité ya composé ya caoutchouc ekomi likolo. Ntina ezali ete ba facteurs oyo etombolaka formation ya gel.