They don’t wear like traditional tires. At some point I’m sure planned obsolescence will creep into the design process, because capitalism. But as they stand, they’re one set of tires for the lifecycle of a vehicle.
The only benefit regarding wear is that an airless tire obviously cannot be operated with impropper air pressure and thus, the assumed 8 % tires that are replaced due to uneven wear caused by wrong pressure could be saved.
Airless tyres are generally less efficient with regards to rolling resistance though, right? How does the wasted energy compare to the reduction in replacement rate?
About 90% of energy loss from tire rolling resistance comes from repeated changes in the shape of the tries as they roll. By simplifying the structure of the tire, Bridgestone was able to minimize the energy loss in these “air free concept tires.” As a result, these tires have the same level of low rolling resistance as Bridgestone pneumatic fuel efficient Ecopia tires, contributing to reductions in CO2 emissions.
I see. Is price the current limiting factor, in that case?
The reason I’m asking is that if this is actually true and ready for deployment, it would be adopted by every single competing cyclist in the world - they are crazy about managing efficiency and removing the possibility of getting a flat would be even more valuable.
Hence there’s something missing, however I don’t know what.
Probably it’s the missing possibility to tweak the stiffness or rigidity according to ones special demands. An air filled tire offers this possibly to adjust the driving behaviour by elevating or decreasing the pressure. These airless tires don’t, which is good for a car driven on road, but isn’t for bikes where the setup is usually adjusted to the demands of the driver.
I’m not entirely convinced of this being the case. Adjusting tyre pressure is something that is always looked at quite seriously by pro cycling teams, but it’s not going to be something that would be impossible to overcome by just buying several more tyres to have the desired range of properties available for the conditions of any given race.
Regardless, this will be an interesting space to follow in the future.
Ah, OK. I was more thinking of mountain biking and related stuff. I didn’t know that punctuation of tires still is a thing in (street) cycling.
However, I assume an airless tire for biking should have the same round cross section like an air filled bike tire, while the car tires both have a rectangular cross section. Thus the tires for biking need to be constructed differently. The one I’ve found is from Schwalbe and is basically a usual tire filled with a PU having a similar stiffness than a common tire with an air pressure of 3.5 bar. Currently, they don’t have a system for racing yet.
They don’t wear like traditional tires. At some point I’m sure planned obsolescence will creep into the design process, because capitalism. But as they stand, they’re one set of tires for the lifecycle of a vehicle.
Do you mean tires like this? Why shouldn’t it wear the same way like a common tire with air?
Ask Michelin, it was in one of the videos. Maybe the composite they’re using is more resilient.
https://michelinmedia.com/michelin-uptis/
The only benefit regarding wear is that an airless tire obviously cannot be operated with impropper air pressure and thus, the assumed 8 % tires that are replaced due to uneven wear caused by wrong pressure could be saved.
Lol, The life of a typical American vehicle is about 16 years…
https://en.m.wikipedia.org/wiki/Car_longevity
Airless tyres are generally less efficient with regards to rolling resistance though, right? How does the wasted energy compare to the reduction in replacement rate?
Actually, the manufacturers claim the opposite:
https://www.bridgestonetire.com/learn/tire-technology/airless-concept-tires/#
I see. Is price the current limiting factor, in that case?
The reason I’m asking is that if this is actually true and ready for deployment, it would be adopted by every single competing cyclist in the world - they are crazy about managing efficiency and removing the possibility of getting a flat would be even more valuable.
Hence there’s something missing, however I don’t know what.
Probably it’s the missing possibility to tweak the stiffness or rigidity according to ones special demands. An air filled tire offers this possibly to adjust the driving behaviour by elevating or decreasing the pressure. These airless tires don’t, which is good for a car driven on road, but isn’t for bikes where the setup is usually adjusted to the demands of the driver.
I’m not entirely convinced of this being the case. Adjusting tyre pressure is something that is always looked at quite seriously by pro cycling teams, but it’s not going to be something that would be impossible to overcome by just buying several more tyres to have the desired range of properties available for the conditions of any given race.
Regardless, this will be an interesting space to follow in the future.
Ah, OK. I was more thinking of mountain biking and related stuff. I didn’t know that punctuation of tires still is a thing in (street) cycling.
However, I assume an airless tire for biking should have the same round cross section like an air filled bike tire, while the car tires both have a rectangular cross section. Thus the tires for biking need to be constructed differently. The one I’ve found is from Schwalbe and is basically a usual tire filled with a PU having a similar stiffness than a common tire with an air pressure of 3.5 bar. Currently, they don’t have a system for racing yet.