Inertia and bicycle wheels related to wattage and time

In summary, the conversation discussed the importance of rotational weight in the bicycle industry, with some arguing that it has a bigger impact on acceleration and competition than static weight. The conversation also delved into the calculations needed to compare the effects of removing 150 grams from each rim in a 2-hour race. It was mentioned that while reducing weight on the bike can improve power-to-weight ratio, there are other factors to consider such as cost and durability. The conversation also touched on the potential benefits of reducing inertia, but it was noted that there are many factors involved in this and it may not have a significant impact.
  • #1
E190
4
0
In the bicycle industry, there is a lot of marketing saying that rotational weight is more important than static weight when it comes to accelerations and competition. I understand I=mr^2 but how do you compare differences.

Keeping the the hub/spokes constant, how much advantage would you get from removing 150 grams from each rim over a 2hr race. For this problem, r=31.1cm

Here is what I "think" I know. It only counts for acceleration and has little to no affect on keeping a steady speed, so let's assume the race is constantly accelerating and decelerating like a criterium or mountain bike race.

Am I wrong saying that watts = I/s^3 ?
If that is the case, then the following problem would break down as follows

I = 150g x 31.1^2 = 145,081.5g/cm^2

to convert to kg/m^2 you multiply by 10 = 1,450,815 kg/m^2

now over a 2hr race divide by 7200^3

Would that mean the savings would only be .00000388 Watts!

And if so, is that per second savings or total savings over the entire race? Either way, it seems basically negligible.

Or am I way off and did this wrong?
 
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  • #2
Most of yuur math is completely wrong, but the marketing guys are right to some extent.

The translational kinetic energy of a mass on the rim (i.e. the energy if the wheel was sliding not rotating) = ##mv^2/2##.

The rotational KE = ##I\omega^2/2##. ##I = mr^2## and ##\omega = v/r##, so the rotational KE also = ##mv^2/2##.

So, in terms effort required to accelerate the bike, a mass on the wheel rim needs twice as much energy as the same mass on the bike frame.

However this is mostly marketing hype, because a mass of 0.15kg is very small compared with the mass of the bike rider. The amount of energy to accelerate a 50kg cyclist compared with an mass of 0.15kg for the wheel rim would be 50/(2 x 0.15) = 167 times bigger.

FWIW the idea behind this is much more important for the rotating parts of an engine in a race car or bike, because the RPM of the engine is much higher than RPM of the wheels.
 
  • #3
Thanks for the help. I understand that accelerating the rider is much more work than accelerating the added wheel weight, how does the decrease in rim weight translate to watts and/or time savings. Let's say I can hold 250 watts over 40km. Using this website (bikecalculator.com) a 300 gram reduction in bike weight saves me only 3 seconds. How much additional time would that save me if I were to reduce that weight from the rim instead of the frame.

In theory, this would also apply to shoes and pedals at the end of the crank arms. I am very interested in learning the math/physics behind this to see exactly how much it could save. Aerodynamics and drag are a big factor, but keeping that constant, I would like to learn how weight alone affects the outcome.
 
  • #4
Are there not many other factors involved here? If you reduce the thickness of your rim then won't it flex and cause you even more energy loss, at least a much as the possible difference in Kinetic Energy? In any case, you don't lose all that KE; it's returned when you slow down.
Also, a 'special' thin will cost more for a start and then need replacing sooner as it will be more vulnerable. Unless you are v. rich, this is also a factor.
 
  • #5
There are tons of factors here. But I am mainly interested in seeing if there is any real life measurable advantage to decreasing inertia. Keeping everything constant (stiffness, thickness, price, etc), is there an advantage if I build up a wheel using rim A at 545 grams, rim B at 425 grams, and rim C at 385 grams.

Decreasing the overall weight by x will increase your power to weight ratio. Keeping power output the same, your time would decrease. But that is for static weight, is there a way to quantify weight savings in inertia over static weight. If the wheels are the same price, quality, stiffness, etc, how would going from a 545g rim to a 385g rim benefit me beyond a total static weight savings of 320g.

I'm 61kg, bike is 9.9kg. At 250 watts my p/w ratio is 3.526 w/kg. If I get new rims my p/w ratio goes up to 3.542 w/kg. Is there a measurable increase by having the weight savings in inertia? And how do I go about calculating this?

Seconds matter, it could mean the difference between a paycheck or a pat on the back.
 
  • #6
E190 said:
Using this website (bikecalculator.com) a 300 gram reduction in bike weight saves me only 3 seconds. How much additional time would that save me if I were to reduce that weight from the rim instead of the frame.

So far as I can tell, "bikecalculator" doesn't include any acceleration effects. If that is correct, it's irrelevant to your question. the "3 seconds" presumably comes from lower rolling resistance of the tires, because of the smaller weight on them.

As a ballpark figure, your acceleration rate will increase by about 0.5%. In other words, if it took you 10 seconds to accelerate through some speed range, you will reduce that by about 0.05 seconds for the same effort.

The effect for pedal cranks etc will be smaller, in proportion to the gearing (i.e. the number of revs of the boke wheel for one rev of the pedals)

In any case, you don't lose all that KE; it's returned when you slow down.
Returned to where? If cyclists can change the way their leg muscles work so they restore energy to the body through regenerative braking, then I'm seriously impresed. (And maybe the drug testing agencies ought to be told how they do it as well :wink:)
 
  • #7
AlephZero said:
Returned to where? (i.e. K.E) If cyclists can change the way their leg muscles work so they restore energy to the body through regenerative braking, then I'm seriously impresed. (And maybe the drug testing agencies ought to be told how they do it as well :wink:)

The KE is returned in as far as the cyclist can put less energy into the last few metres of pedalling. The KE (the few mJ) offset some of the resistive losses when there is deceleration.
 
  • #8
E190 said:
There are tons of factors here. But I am mainly interested in seeing if there is any real life measurable advantage to decreasing inertia. Keeping everything constant (stiffness, thickness, price, etc), is there an advantage if I build up a wheel using rim A at 545 grams, rim B at 425 grams, and rim C at 385 grams.

Decreasing the overall weight by x will increase your power to weight ratio. Keeping power output the same, your time would decrease. But that is for static weight, is there a way to quantify weight savings in inertia over static weight. If the wheels are the same price, quality, stiffness, etc, how would going from a 545g rim to a 385g rim benefit me beyond a total static weight savings of 320g.

I'm 61kg, bike is 9.9kg. At 250 watts my p/w ratio is 3.526 w/kg. If I get new rims my p/w ratio goes up to 3.542 w/kg. Is there a measurable increase by having the weight savings in inertia? And how do I go about calculating this?

Seconds matter, it could mean the difference between a paycheck or a pat on the back.

What 'increase' are you expecting? You are using some very simple calculations, I think but what do they show and how can you apply the result to make any conclusion? If you are just considering the situation when sprinting then mass and MI are considerations but you appear to want to consider the whole race, with lots of speed variation. You suggest a "power saving" of a small fraction of a Watt. Is the Energy not more important? How would you calculate that? The extra KE you put in whilst you are accelerating is not wasted as you need to be putting in less of your muscle energy when slowing down.
But how can it be worth while to do any more than this very approximate calculation, which shows that the energy involved is small, when the energy loss due to flexing hasn't been calculated? I seem to remember that one of the reasons for making frames as stiff as possible is to reduce the effort needed and this has been shown to be relevant. The same thing must apply to the wheel stiffness, too.
I think you may as well go along with what you have found in connection with the wheel mass and now move on to get a ball park figure for flexing losses. When you have compared the two then the result could make the choice more clear for you as to which is more relevant. There will be other factors like roadholding - which may improve as your 'unsprung weight' is being reduced. (Not quite the same as with motor car suspension but I guess it must apply in some way.)

Good Engineering involves identifying the most relevant parameters to work at when you want to improve performance. It also involves defining what is the most relevant aspect of 'performance'. I suppose I'm basically saying that you need to devote an appropriate amount of effort on this particular problem. Your idea of 'keeping all other things equal' is ok as far as it goes and it's a fair principle to apply at the start but other things are not proved to be equal, yet. Other effects may far outweigh what you are looking at.
 
  • #9
Thanks for all the quick replies. In road cycling aerodynamics greatly affect racing. There are many ways to shave 20-30 seconds off your 40km time trial. This is normally accomplished by an aero helmet, wheels, frame, clothing, etc. However, in mountain biking aerodynamics isn't as much a contributor. The speeds are slower, but there are constant accelerations. I was just curious if the affects of a lighter rim would have the same huge benefits that they have in road racing. From what I can gather from the above conversation is that it is negligible even when keeping all else constant.
 

1. How does the weight of a bicycle wheel affect its inertia?

The weight of a bicycle wheel does not affect its inertia. Inertia is a measure of an object's resistance to change in motion, and it is determined by the mass and distribution of that mass. The weight of a wheel only affects its acceleration, not its inertia.

2. How does the size of a bicycle wheel affect its inertia?

The size of a bicycle wheel does not directly affect its inertia. However, a larger wheel may have more mass and therefore a greater inertia compared to a smaller wheel. Additionally, the distribution of mass in a larger wheel may also impact its inertia.

3. Does a heavier bicycle wheel require more wattage to rotate at the same speed as a lighter wheel?

Yes, a heavier bicycle wheel will require more wattage to rotate at the same speed as a lighter wheel. This is because the heavier wheel has a greater inertia, meaning it requires more force to overcome its resistance to change in motion.

4. How does the speed of a bicycle wheel affect the wattage required to maintain its motion?

The speed of a bicycle wheel does not directly affect the wattage required to maintain its motion. However, as the speed of the wheel increases, so does its inertia, meaning more wattage will be needed to maintain its motion. Additionally, air resistance and other external factors may also impact the wattage required to maintain a certain wheel speed.

5. How does the time it takes for a bicycle wheel to reach a certain speed relate to its wattage?

The time it takes for a bicycle wheel to reach a certain speed is directly related to its wattage. The greater the wattage, the faster the wheel will accelerate and reach a desired speed. This is because wattage is a measure of power, which is the rate at which work is done. Therefore, a higher wattage means more work is being done in a shorter amount of time, resulting in a faster speed for the wheel.

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