Another thought on choosing wheels.
Moderator: robbosmans
Lately on our large group training rides there has been a trend towards these balls out drag race accelerations after each stop sign, and there are quite a few. Add to that rolling terrain, complete with sharp bergs within technical narrow country roads and you are going to expend a lot of energy. Even though the long flat sections make up a fair percentage of these rides some people have found they have adapted better by switching to smaller profile, hence lighter rims.
What I find interesting is that this wasn't the case before this change in tactics. People benefited from the deeper wheels here. We've were discussing how this isn't the case in racing conditions, even in crits, cause at least you can carry a lot of speed through the corners.
Just something to consider if you're thinking of taking that next step towards racing and are training in similar conditions.
What I find interesting is that this wasn't the case before this change in tactics. People benefited from the deeper wheels here. We've were discussing how this isn't the case in racing conditions, even in crits, cause at least you can carry a lot of speed through the corners.
Just something to consider if you're thinking of taking that next step towards racing and are training in similar conditions.
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Lighter rims will definitely make accelerations feel more responsive and lively, but does that correlate to real world speed increase? Thats debatable. Maybe a very, very small amount. But if someone ever uses the excuse, "Ahh I lost that sprint because I'm on my Deep Vs instead of my Alpha 340s", then they should receive a swift Chuck Norris roundhouse kick to the dome piece.
Here is a good discussion: https://en.wikipedia.org/wiki/Bicycle_p ... ght_wheels
The benefit of lighter wheels on accelleration is small, and could be equaled or outweighed by heavier but more aero wheels depending on how heavier and how much more aero.
The benefit of lighter wheels on accelleration is small, and could be equaled or outweighed by heavier but more aero wheels depending on how heavier and how much more aero.
Thanks for the math compilation reference Eric. It will be interesting to go through some numbers, thought it suggests wheel weight makes little difference.
The point I was trying to emphasize was the numerous changes in dynamics. Some days it smooth and fast while other days it's very choppy and fast.
The consensus here is that when you sum the effects of 10 to 12 very hard accelerations from stops signs along with the chaos from other sources (cops, vehicles and other cycling groups, etc.) yielding very dramatic changes in velocity, you may be better off with lighter wheels. Conversely, when it's smooth, with gradual accelerations to very high speeds then aero should be more beneficial. This is going with the assumption the power account is finite.
I am merely passing along observations from riders after the rides, though I would tend to agree. Under these extreme conditions heavier wheels can take their toll, or so it would seem.
The point I was trying to emphasize was the numerous changes in dynamics. Some days it smooth and fast while other days it's very choppy and fast.
The consensus here is that when you sum the effects of 10 to 12 very hard accelerations from stops signs along with the chaos from other sources (cops, vehicles and other cycling groups, etc.) yielding very dramatic changes in velocity, you may be better off with lighter wheels. Conversely, when it's smooth, with gradual accelerations to very high speeds then aero should be more beneficial. This is going with the assumption the power account is finite.
I am merely passing along observations from riders after the rides, though I would tend to agree. Under these extreme conditions heavier wheels can take their toll, or so it would seem.
If you have the opportunity - ride different wheels and tires and pressure. Its a lot easier and IMO more accurate than calculations.
Most calculations treat the bike and cyclist as if they go in a straight line and the bike is perpendicular to the ground at all times. I agree on the average the bike goes in a straight line and on average it is perpendicular to the ground, however there is lots of side to side movement in real riding and the rotational inertia of the wheel has bearing on that and it is changing constantly as the rider does mini turns right and left riding at 25mph just balancing the bike. Then there is the stiffness part. Energy gets scrubbed off in tire casing deformations, bumps, flex in wheels - without the rider even standing and sprinting.
Most calculations treat the bike and cyclist as if they go in a straight line and the bike is perpendicular to the ground at all times. I agree on the average the bike goes in a straight line and on average it is perpendicular to the ground, however there is lots of side to side movement in real riding and the rotational inertia of the wheel has bearing on that and it is changing constantly as the rider does mini turns right and left riding at 25mph just balancing the bike. Then there is the stiffness part. Energy gets scrubbed off in tire casing deformations, bumps, flex in wheels - without the rider even standing and sprinting.
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Unfortunately the "ride it" method also introduces rider perception into the equation... and that may mask the relatively small effects from lighter weight on accelleration or aerodynamics on speed.
I'd love to see some energy loss calculations from wheel deformation. My gut feeling is that most of it is in the spokes (especially on deep section carbon rims which are stiff due to their cross section) and the majority of spoke flex is returned- i.e. they act as springs.
I'd love to see some energy loss calculations from wheel deformation. My gut feeling is that most of it is in the spokes (especially on deep section carbon rims which are stiff due to their cross section) and the majority of spoke flex is returned- i.e. they act as springs.