Tire load sensitivity
In this article, we will explore the fascinating world of Tire load sensitivity and its impact on different areas of society. From its influence on art and culture to its relevance in science and technology, Tire load sensitivity has left its mark on history and remains a topic of great interest today. We will analyze its evolution over time, from its origins to its current state, and examine how it has shaped the way we think and act. Through this comprehensive analysis, we hope to offer an enriching and insightful view on Tire load sensitivity and its relevance in the modern world.
Tire load sensitivity describes the behaviour of tires under load. Conventional pneumatic tires do not behave as classical friction theory would suggest. The load sensitivity of most real tires in their typical operating range is such that the coefficient of friction decreases as the vertical load, Fz, increases. The maximum lateral force that can be developed does increase as the vertical load increases, but at a diminishing rate.
Behaviour
Coulomb friction theory says that the maximum horizontal force developed should be proportional to the vertical load on the tire. In practice, the maximum horizontal force Fy that can be generated is proportional, roughly, to the vertical load Fz raised to the power of somewhere between 0.7 and 0.9, typically. [citation needed]
Production car tires typically develop this maximum lateral force, or cornering force, at a slip angle of 6-10 degrees, although this angle increases as the vertical load on the tire increases. [1] Formula 1 car tires may reach a peak side force at 3 degrees [2]
Example
As an example, here is data extracted from Milliken and Milliken's "Race Car Vehicle Dynamics", figure 2.9:
| Vertical load | Fy/Fz | Slip Angle |
| (lbf) | max | degrees |
| 900 | 1.10 | 5.6 |
| 1350 | 1.08 | 6.0 |
| 1800 | 0.97 | 6.7 |
The same sensitivity is typically seen in the longitudinal forces, and combined lateral and longitudinal slip.
See also
References
- ^ Milliken, W.F., Milliken, D.L., 1995, "Race Car Vehicle Dynamics", Society of Automotive Engineers (SAE) Warrendale, PA. page 27.
- ^ Wright P., 2001, "Formula 1 Technology", Society of Automotive Engineers (SAE) Warrendale, PA.
