How does sample thickness affect the rolling resistance of tires?
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Sample thickness does not appear to be directly addressed in the provided abstracts.
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40 Citations | The provided paper does not mention how sample thickness affects the rolling resistance of tires. |
The provided paper does not mention anything about how sample thickness affects the rolling resistance of tires. The paper primarily focuses on factors such as energy loss, frictional energy, and air resistance that contribute to rolling resistance. | |
21 Citations | The provided paper does not mention anything about how sample thickness affects the rolling resistance of tires. |
The provided paper does not mention anything about how sample thickness affects the rolling resistance of tires. The paper discusses established relationships, construction changes, component effects, and compounding material effects on rolling resistance. | |
Open access•Journal Article 1 Citations | The provided paper does not mention anything about how sample thickness affects the rolling resistance of tires. |
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How does the addition of network fillers change the rolling resistance of tires?5 answersThe addition of network fillers in tire tread rubber compounds can change the rolling resistance of tires. Silica fillers, for example, offer advantages such as a reduction in heat build-up and improved mechanical properties compared to carbon black. The reinforcement efficiency of silica-filled rubbers depends on the nature of the rubber matrix and the strength of the silica-to-rubber interactions. The visco-elastic properties of carbon black filled composites with rubber matrices also contribute to reinforcement and dissipation, with the filler network causing a major part of the composite dissipation at small and intermediate strain amplitudes. The formation of a filler network in elastomer compounds affects the rolling resistance and energy losses, which can be influenced by the type and volume fraction of filler as well as the thermodynamic interaction between the host polymer and the polymer chains attached to the filler surface.
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