Race cars - Torque vs Hp - The Undiscovered Country (for many)

In summary: Yes, but to make your comparison (the graph later) you have to ignore any mechanical advantage. The correct comparison for what you want is chassis dyno info (it makes no difference really from your engine graph, but it seems silly to discuss forces at the tire with flywheel data), which is done in a 1:1 gear ratio.Many different types of race cars have all sorts of engines. some with high torque and some with low torque, even some of those might have equal HP output. Since HP is a rate of doing work, a rate of change of kinetic energy, if a two cars were to be compared and both had the same HP, yet one had half the torque output, if their HP curve
  • #71
You are refusing to budge from incorrect thinking and its very difficult to give a techincally correct explination until you do. You need to stop thinking about KE now, and start thinking about momentum if you want a technically correct explanation.

By simply using KE you are ignoring what the dyno is actually measuring. Therefore any further premise from that is based on false mathematics. You are approaching the problem backwards.

Just because you can maniplulate the equations the correct way on paper doesn't mean it is done like that in reality. Without a context energy means very little, and its the context that gives it importance.

What you are saying is correct for the car acceleration, but you are butching the way this is acutally calculated. Its also leading you to incorrect thinking. That more power is more force. This isn't correct and is also why you are getting the 1.5hp motor climing a hill messed up a bit.

More torque is more force, more power is force more quickly. (you cannot do this the other way around)
More power does not = more force.

Now for car acceleration, the rear wheel force (and by extansion engine torque) is larger than the drag forces. So for each torque operation you have a net positive force, so if you apply that more quickly you will accelerate more quickly.

For climbing a hill, the forces stopping the motion are much much higher. Its concevable that for a low powered (read low torque) motor, the torque will not provide the force to overcome the 'drag' forces at the rear wheel. You have a net negative force. Now no matter how often you apply this net negative force it will NEVER become positive and you will never climb the hill.

By your reasoning if you increase the power with the same engine (it spin it faster) you will be developing more power, but you will still never get up the hill.

This is the reason why trucks are so good at climbing hills with a full load, tons of torque. So they can climb steeper hills, but the low power means they won't do it quickly. If you hook up a formula 1 engine (same power or even lots more power rating but much lower torque) to the truck it won't have the pulling power to climb with several tons attached.

your battery/electric motor example. You say doubling the power will allow you to lift something heavier, this is true. But as they are operating at the same rpm, the way it doubles power is by doubling the torque outrput.

I'm going to come up with a worked example to show this.
 
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  • #72
ll concede that calcuating dyno force is really based on acceleration of the load and power is calculated from that. Again, not really the point of the discussion, but thanks, as I do want to stay on the accepted side of the explanations.

HOWEVER, your truck and the climbing hill example does not seem right. first of all , if you add more power to a mini bike climbing a hill, but failing, more hp will result in a higher force, as seen by power=fs. by adding NOS for example to that engine along with Fuel, we increase the power rating of the engine. Its rate of doing work is increased proportionally. If you just increase rpm, as you suggest, the mini bike would have to go faster up the hill, greatly increasing the force demands. however, if the engine rpm increased and the gearing allowed for the same equivilant speed, (and the engine HP curve was flat, or engine torque went down in proportion to rpm going up) then , you would be utilzing more of the available engine power and would be able to climb the hill. torque and force at the rear wheels would go up. By saying that just increasing the frequency or RPM a negative net force, makes no sense, as you would be changing the vehicle speed higher.
This is exactly why cars with gear boxes, downshift to climb hills at the same rate of speed. to take advantage of more available HP of the engine . rpm goes up, torque goes up at the rear wheels due to gearing and more hp is utilized.

With the truck vs the formula one engine, both can climb the hill at exactly the same rate if they have the same HP. Rate of doing work, right? the F1 engine does it by high rpm and low torque, the truck the opposite. in the end, if both are using the same HP, both will have the same rear wheel forces at an speed . The real reason that trucks use high torque, low rpm engines, is wear and efficiency. How long would a 15,000rpm engine last pulling a truck up a 100mile incline? The truck could do it for 100s of thousands of miles due to operating at very low rpm. The truck makes decent HP at very low rpm. very broad HP curve. the F1 engine is peaky and has a narrow max HP range.

I can easily give you resultant rear wheel torque to prove that any engine rated at the same hp, even at much less engine torque, will create the exact same rear wheel forces to the ground. Thats a simple set of equations. This seems to be in direct conflict it with your last sentence. This would be consistant with, "power=force x speed".

mk

xxChrisxx said:
Now for car acceleration, the rear wheel force (and by extansion engine torque) is larger than the drag forces. So for each torque operation you have a net positive force, so if you apply that more quickly you will accelerate more quickly.

For climbing a hill, the forces stopping the motion are much much higher. Its concevable that for a low powered (read low torque) motor, the torque will not provide the force to overcome the 'drag' forces at the rear wheel. You have a net negative force. Now no matter how often you apply this net negative force it will NEVER become positive and you will never climb the hill.

By your reasoning if you increase the power with the same engine (it spin it faster) you will be developing more power, but you will still never get up the hill.

This is the reason why trucks are so good at climbing hills with a full load, tons of torque. So they can climb steeper hills, but the low power means they won't do it quickly. If you hook up a formula 1 engine (same power or even lots more power rating but much lower torque) to the truck it won't have the pulling power to climb with several tons attached.

I'm going to come up with a worked example to show this.
 
  • #73
zanick said:
ll concede that calcuating dyno force is really based on acceleration of the load and power is calculated from that. Again, not really the point of the discussion, but thanks, as I do want to stay on the accepted side of the explanations.

HOWEVER, your truck and the climbing hill example does not seem right. first of all , if you add more power to a mini bike climbing a hill, but failing, more hp will result in a higher force, as seen by power=fs. by adding NOS for example to that engine along with Fuel, we increase the power rating of the engine. Its rate of doing work is increased proportionally. If you just increase rpm, as you suggest, the mini bike would have to go faster up the hill, greatly increasing the force demands. however, if the engine rpm increased and the gearing allowed for the same equivilant speed, (and the engine HP curve was flat, or engine torque went down in proportion to rpm going up) then , you would be utilzing more of the available engine power and would be able to climb the hill. torque and force at the rear wheels would go up. By saying that just increasing the frequency or RPM a negative net force, makes no sense, as you would be changing the vehicle speed higher.
This is exactly why cars with gear boxes, downshift to climb hills at the same rate of speed. to take advantage of more available HP of the engine . rpm goes up, torque goes up at the rear wheels due to gearing and more hp is utilized.

With the truck vs the formula one engine, both can climb the hill at exactly the same rate if they have the same HP. Rate of doing work, right? the F1 engine does it by high rpm and low torque, the truck the opposite. in the end, if both are using the same HP, both will have the same rear wheel forces at an speed . The real reason that trucks use high torque, low rpm engines, is wear and efficiency. How long would a 15,000rpm engine last pulling a truck up a 100mile incline? The truck could do it for 100s of thousands of miles due to operating at very low rpm. The truck makes decent HP at very low rpm. very broad HP curve. the F1 engine is peaky and has a narrow max HP range.

I can easily give you resultant rear wheel torque to prove that any engine rated at the same hp, even at much less engine torque, will create the exact same rear wheel forces to the ground. Thats a simple set of equations. This seems to be in direct conflict it with your last sentence. This would be consistant with, "power=force x speed".

mk

Jesus.Power = force * speed is NOT based in reality.

It is a mathematical relation devised purely for convenience,
 
  • #74
zanick said:
ll concede that calcuating dyno force is really based on acceleration of the load and power is calculated from that. Again, not really the point of the discussion, but thanks, as I do want to stay on the accepted side of the explanations.

HOWEVER, your truck and the climbing hill example does not seem right. first of all , if you add more power to a mini bike climbing a hill, but failing, more hp will result in a higher force, as seen by power=fs. by adding NOS for example to that engine along with Fuel, we increase the power rating of the engine. Its rate of doing work is increased proportionally. If you just increase rpm, as you suggest, the mini bike would have to go faster up the hill, greatly increasing the force demands. however, if the engine rpm increased and the gearing allowed for the same equivilant speed, (and the engine HP curve was flat, or engine torque went down in proportion to rpm going up) then , you would be utilzing more of the available engine power and would be able to climb the hill. torque and force at the rear wheels would go up. By saying that just increasing the frequency or RPM a negative net force, makes no sense, as you would be changing the vehicle speed higher.
This is exactly why cars with gear boxes, downshift to climb hills at the same rate of speed. to take advantage of more available HP of the engine . rpm goes up, torque goes up at the rear wheels due to gearing and more hp is utilized.

With the truck vs the formula one engine, both can climb the hill at exactly the same rate if they have the same HP. Rate of doing work, right? the F1 engine does it by high rpm and low torque, the truck the opposite. in the end, if both are using the same HP, both will have the same rear wheel forces at an speed . The real reason that trucks use high torque, low rpm engines, is wear and efficiency. How long would a 15,000rpm engine last pulling a truck up a 100mile incline? The truck could do it for 100s of thousands of miles due to operating at very low rpm. The truck makes decent HP at very low rpm. very broad HP curve. the F1 engine is peaky and has a narrow max HP range.

I can easily give you resultant rear wheel torque to prove that any engine rated at the same hp, even at much less engine torque, will create the exact same rear wheel forces to the ground. Thats a simple set of equations. This seems to be in direct conflict it with your last sentence. This would be consistant with, "power=force x speed".

mk

Jesus.Power = force * speed is NOT based in reality.

It is a mathematical relation devised purely for convenience, it shas no physical basis. I am talking about the power part, not the force * speed.

By injecting nos you are increasing the engine TORQUE at a given rpm because you are increasing the force on the piston and by extension the power. NOT THE OTHER WAY ROUND.

To talk of gearing, why when you are coming to a hill do you downshift? If power is the key factor in rear wheel force it shoudlnt matter about the gear you are in as the engien is pumping out the same power. They downshift to take advantage of the TORQUE multiplication of the lower gear ratio. Seriesly do the calculations for the F1 and truck engine. I gaurantee you will make the mistake that power = force. IT DOESNT!

See how it works : http://auto.howstuffworks.com/question381.htm

^^ read it^^

You are really confusing yourself by flitting between the rear wheel horsepower and rear wheel torque. give all the equations you can.

you seem to clearly have problems thinking in terms of torque and power.

Seriously please go and buy a book on this. i'll have a look through my library for the best one.
 
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  • #75
ll concede that calcuating dyno force is really based on acceleration of the loads and power is calculated from that. again, not really the point of the discussion, but thanks, as I do want to stay on the accepted side of the explanations.

HOWEVER, you truck and climbing hill example does not seem right. first of all , if you add more power to a mini bike climbing a hill, but failing, more hp will relate in higher force, as seen by power=fs. by adding NOS for example to that engine along with Fuel, we increase the power rating of the engine. Its rate of doing work is increased proportionally. If you just increase rpm, as you suggest, the mini bike would have to go faster up the hill, greatly increasing the force demands. however, if the engine rpm increased and the gearing allowed for the same equivilant speed, (and the engine HP curve was flat, or engine torque went down in proportion to rpm going up) then , you would be utilzing more of the available engine power and would be able to climb the hill. torque and force at the rear wheels would go up. By saying that just increasing the frequency or RPM a negative net force, makes no sense, as you would be changing the vehicle speed higher.

you also say: "More torque is more force, more power is force more quickly. (you cannot do this the other way around)
More power does not = more force.
But with power=fv, it does indicate that more power would create more force. (or to keep on the force side of thinking, a higher power rating would indicate that more force would have to be produced at the same vehicle speed to climb that hill.


Now for car acceleration, the rear wheel force (and by extansion engine torque) is larger than the drag forces. So for each torque operation you have a net positive force, so if you apply that more quickly you will accelerate more quickly."


With the truck vs the formula one engine, both can climb the hill at exactly the same rate if they have the same HP. Rate of doing work, right? the F1 engine does it by high rpm and low torque, the truck the opposite. in the end, if both are using the same HP, both will have the same rear wheel forces at an speed . The real reason that trucks use high torque, low rpm engines, is wear and efficiency. How long would a 15,000rpm engine last pulling a truck up a 100mile incline? The truck could do it for 100s of thousands of miles due to operating at very low rpm. The truck makes decent HP at very low rpm. very broad HP curve. the F1 engine is peaky and has a narrow max HP range.

I can easily give you resultant rear wheel torque to prove that any engine rated at the same hp, even at much less engine torque, will create the exact same rear wheel forces to the ground. Thats a simple set of equations. This seems to be in direct conflict it with your last sentence. This would be consistant with, "power=force x speed".

mk

xxChrisxx said:
Now for car acceleration, the rear wheel force (and by extansion engine torque) is larger than the drag forces. So for each torque operation you have a net positive force, so if you apply that more quickly you will accelerate more quickly.

For climbing a hill, the forces stopping the motion are much much higher. Its concevable that for a low powered (read low torque) motor, the torque will not provide the force to overcome the 'drag' forces at the rear wheel. You have a net negative force. Now no matter how often you apply this net negative force it will NEVER become positive and you will never climb the hill.

By your reasoning if you increase the power with the same engine (it spin it faster) you will be developing more power, but you will still never get up the hill.

This is the reason why trucks are so good at climbing hills with a full load, tons of torque. So they can climb steeper hills, but the low power means they won't do it quickly. If you hook up a formula 1 engine (same power or even lots more power rating but much lower torque) to the truck it won't have the pulling power to climb with several tons attached.

I'm going to come up with a worked example to show this.
 
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  • #76
You are pretty much wrong in everything you've just said regarding power.

Read the links on how stuff works, or go to your amazon and buy a book on this subject.

Until you realize your fundamental error in thinking you will never learn why you are going wrong. You are clinging to P=F*s, but if you'd acutrally read up on this you know that that relation is not what is heppening in reality. you will discorver its a mathemetical relation devised by people AFTER pissing about with torque and rpm and then doing lots of calculations to it for so long. You will also discover why its the torque that creates the force at the wheel NOT POWER.

Until then there is nothing I can do to increase your inderstanding of this.
 
  • #77
I get what you are saying, especially with the NOS example. we get more torque, and subsequently more force at the rear wheels. I just have to change my direction of thinking. (coming from car land.)

But, when you talk of gearing below, you lose me. power is the key. you ask the question below. power is key and as you are crusing along at 50mph with your truck, you are using 100hp of your 800hp rating. Here comes the hill, you need much more force to climp the hill, you downshift to take advantage of the engines power available at the higher rpm and higher fuel requirements. At that prior power setting, you might have only been at 10% of the power available. now, you take advantage of higher gear reduction by downshifting, you now are in the higher rpm ranges and at the higher hp range at full throttle. You also are maximizing you rear wheel forces at the max HP range.

Now, you asked me to compare a high torque, low rpm truck engine and F1 engine at the same power, so here it is. Let's keep it simple. 1000hp 1000ft-lbs of peak torque for the truck and 1000hp and 250ft-lbs of peak torque for the F1 engine. The both go to climp a hill. The Big diesel engine is in the truck. At 50mph, the truck is at 4000rpm and producing 8000ft-lbs of torque at the rear wheels. (1000ft-lbs with 8:1 gearing) At the same 50mph, the truck with the F1 engine is running at 16,000rpm and 250ft-lbs of torque, but the rear wheel torque is the same 8000ft-lbs. (250ft-lbs with 32:1 gearing). vehicle speed is the same, HP is the same, engine torque is way different, yet, rear wheel forces are identical. Where is the mistake there?

mk

xxChrisxx said:
Jesus.Power = force * speed is NOT based in reality.

It is a mathematical relation devised purely for convenience, it shas no physical basis. I am talking about the power part, not the force * speed.

By injecting nos you are increasing the engine TORQUE at a given rpm because you are increasing the force on the piston and by extension the power. NOT THE OTHER WAY ROUND.

To talk of gearing, why when you are coming to a hill do you downshift? If power is the key factor in rear wheel force it shoudlnt matter about the gear you are in as the engien is pumping out the same power. They downshift to take advantage of the TORQUE multiplication of the lower gear ratio. Seriesly do the calculations for the F1 and truck engine. I gaurantee you will make the mistake that power = force. IT DOESNT!

See how it works : I am finding the link now

You are really confusing yourself by flitting between the rear wheel horsepower and rear wheel torque. give all the equations you can.

you seem to clearly have problems thinking in terms of torque and power.

Seriously please go and buy a book on this. i'll have a look through my library for the best one.
 
  • #78
Im hearing you about that its really the force that determines the power, and power is just the power rating. But, you asked me to provide the example, and I did. Your truck powered by F1 or its normal engine, doesn't make your point, as i proved, both can yeild the same rear wheel torque at the same HP ratings, and grossly different engine torque values.
Power ratings is what you and I were comparing here and they seem to yield the same rear wheel torque at any vehicle speed. (if they are running at the same power level)

You mention i was wrong in "everything " i had a said regarding power. can you be more specific? you make the comparison of the truck powered by F1 engine vs its normal low reving high torque engine. that was actually incorrect. If power ratings are the same, the same rate of work can be done by either, and this means the same rear wheel torque can be produced!

In the electric motor and battery rating world, you get things rated in KW or KW-hours. unit measures of work. This indicates the potential rates of doing work. Is this wrong as well?

mk




xxChrisxx said:
You are pretty much wrong in everything you've just said regarding power.

Read the links on how stuff works, or go to your amazon and buy a book on this subject.

Until you realize your fundamental error in thinking you will never learn why you are going wrong. You are clinging to P=F*s, but if you'd acutrally read up on this you know that that relation is not what is heppening in reality. you will discorver its a mathemetical relation devised by people AFTER pissing about with torque and rpm and then doing lots of calculations to it for so long. You will also discover why its the torque that creates the force at the wheel NOT POWER.

Until then there is nothing I can do to increase your inderstanding of this.
 
  • #79
You keep moving the goal posts by changing gearing. Gearing is a torque multiplyer.

He cannot change the gearing he has on his bike when he comes to a hill as he is geared for a certian road speed. For that gearing he doesn't have the RW torque available. When you said that he doesn't have the power available to do it, this is incorrect as the engine always produces the same power output, the phenomenon you are talking about is torque. The determination of whether you can climb the hill is torque, the determination of how fast you can climb is power. A rwhp value doesn't tell you if you can climb the hill or not, a rw force value would.

So to find if you can climb, you use:

RWTorque * wheel radius = Force

The RWHP tells you how fast you can climb it. from P = F * S

If you were theoretically detmining gearing before you set off to go this ans you had a RWHP curve, It would be correct to use P = F* S to determine the gearing for a set speed.

If you have set gearing available (ie you've already set off) The P = F* S does not tell you anything useful.
In this case you have to use RWT*wheel radius = F to determine if you have sufficient torque at the rear wheel to do the job. If you find that you don't you either have to go away and get the gearing that will give the correct RWT or you could slap bigger wheels on the bike. You can then find how fast you can climb the hill form P=T*angular velocity.

As jeff pointed out, he could climb that hill if he was geared for it. Then again with gears you can get any mortor to lift any amount. It'll just do it very slowly. So you see you can use the RWHP formula in some situations, but you can use the torque calculation in all situations.

What you were doing was the former, but applying it to the latter situation. So you were not calcualting anything useful. He stated he was geared for something already, and that it was his lack of torque that was causing the problem. Stating that he can do becuase P = F * S tells him he can is pointless as he can't chgane the gearing to get to the poitput that that equations states.

If you cannot climb a hill at the peak engine torque value, you cannot climb it at peak engine power. (as torque is lower at peak power). This transfers down through the transmission so that. If you can't climb a hill at peak RWT you cannot climb the hill at peak RWHP. It means you need to fiddle with the gearing to be able to do so. If you can't fiddle with the gearing and can't fit a larger wheel, you can't get up the hill. This is something that is easier to visualise using a torque calculation as that is the acutal physicla driving force.

I've got a question that I'm just finishing up that I'm going to post after your next reply. It should demonstrate that power is not the critical factor.
 
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  • #80
Not really, I think we are having the classis problem of rear wheel torque vs engine torque adding to the cross lines of the discussion. you tell me.

I think I see a potential problem. So, getting back to the mini bike. If he is running 1.5 hp and running some top speed say, 30mph, you are right. he has a certain amount of force being generated to sustain that speed. Stilll, power=force x speed. he is not at max torque of the engine, he is at max HP which as you say is higher than max torque of the engine. this is generating the maximum amount of force at that particular speed, 30mph. Now comes the hill. he can't choose a lower gear, because that would slow him down, so you are right. limied by max HP and rear wheel torque. if he adds NOS, it increases force by x% so he can climb the hill at that same speed.

You keep on saying that the bike cannont climb the hill if it doesn't have the torque, what you mean to say, is that if it was at max HP prior, and you wanted to keep the speed constant, yes that would be true. with more HP, you would have more force and then you would. you say its more force so then you can then determine the hp has increased as well. Thats fine. In the electrical /mechanical world, if i dropped in a higher output battery, to the elecrict motor powered bike, it could cause the motor to run with more torque and thus at a higher power level.

truck analogy with its stock engine vs F1 engine. If both engines are installed with appropriate gearing, both will be able to climb the hill at the same speed, using gears appropriate for the trade offs of rpm and speed and mulitplication of torque. One engine would do it at high rpm , low torque and the other would do it with high torque, low rpm. the net forces at the rear wheel would be the same because the rate of work would be the same.

Now , your last paragraph. If I have a transmission, and I can't climb a hill at a certain speed at max engine torque, there is a distinct possibility, and in most cases, that i could climb it at max HP, even though the engine torque would be less at that same vehicle speed, rear wheel multiplied torque would be higher at that same vehicle speed than it would be found at max engine torque. agree? I think you two part sentence is saying that if you have a fixed gear, and you can't climb the hill at max torque, certanly at max HP you wouldn't be able to climb it, because the speed would be much higher. and your second part of the sentence, is saying that if you can't climb the hill with max rear wheel torque, as multipled thorugh the gear box at that speed, certainly you wouldn't be able to climb it at max hp, because those two points are the same engine rpm. max HP would be the point at which you would have max torque at any given speed. just like if we had an infinitely variable gear box, the engine would operate at max hp and not max torque to achieve max torque levels at the rear wheels at any given vehicle speed.






mk

xxChrisxx said:
You keep moving the goal posts by changing gearing. Gearing is a torque multiplyer.

He cannot change the gearing he has on his bike when he comes to a hill as he is geared for a certian road speed. For that gearing he doesn't have the RW torque available. When you said that he doesn't have the power available to do it, this is incorrect as the engine always produces the same power output, the phenomenon you are talking about is torque. The determination of whether you can climb the hill is torque, the determination of how fast you can climb is power. A rwhp value doesn't tell you if you can climb the hill or not, a rw force value would.

So to find if you can climb, you use:

RWTorque * wheel radius = Force

The RWHP tells you how fast you can climb it. from P = F * S

If you were theoretically detmining gearing before you set off to go this ans you had a RWHP curve, It would be correct to use P = F* S to determine the gearing for a set speed.

If you have set gearing available (ie you've already set off) The P = F* S does not tell you anything useful.
In this case you have to use RWT*wheel radius = F to determine if you have sufficient torque at the rear wheel to do the job. If you find that you don't you either have to go away and get the gearing that will give the correct RWT or you could slap bigger wheels on the bike. You can then find how fast you can climb the hill form P=T*angular velocity.

As jeff pointed out, he could climb that hill if he was geared for it. Then again with gears you can get any mortor to lift any amount. It'll just do it very slowly. So you see you can use the RWHP formula in some situations, but you can use the torque calculation in all situations.

What you were doing was the former, but applying it to the latter situation. So you were not calcualting anything useful. He stated he was geared for something already, and that it was his lack of torque that was causing the problem. Stating that he can do becuase P = F * S tells him he can is pointless as he can't chgane the gearing to get to the poitput that that equations states.

This comes down to:

If you have a given gearing - use torque eq.
If you have a given speed (and can vary gearing) - can use torque or power eq.

If you cannot climb a hill at the peak engine torque value, you cannot climb it at peak engine power. (as torque is lower at peak power). This transfers down through the transmission so that. If you can't climb a hill at peak RWT you cannot climb the hill at peak RWHP. It means you need to fiddle with the gearing to be able to do so. If you can't fiddle with the gearing and can't fit a larger wheel, you can't get up the hill. This is something that is easier to visualise using a torque calculation as that is the acutal physicla driving force.
 
  • #81
Will repost q in a second.

Ok Q is:

14.4Kg block on a 45% slope

The motor used is:

100 Watt at 200rpm
4.77Nm at 200rpm

167.2 Watt at 400 rpm
4Nm at 400 rpm.

The reduction gearing is 15:1.
The rolling radius is 1m

Can the motor move the block up the hill?

EDIT: you can assume no losses through the drivetrain, so RWHP = engine HP.

Now after ansering this I'll give you the second part and address the truck and F1 engine thing.

Also buy this book :https://www.amazon.com/dp/1844253147/?tag=pfamazon01-20
and read the last chapter. It's not a very technical book, but is perfect for what we are talking about.
 
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  • #82
Well first off you have two motor speeds and thus driving speeds, fixed by a 15:1 gear box. If I can't change that, then I can't get speeds that utilize the available power of the motor.
the power range for the two speeds is 1:1.65, but the speed difference is 2x. so, I would need much more power to achieve 2x the speed of the 400rpm motor setting. If the slower motor setting works and uses all available power to lift the mass, even with optimal gearing, 1.67x greater power setting could only allow for a small increase in drive speed.

Thats at first glance. it looks like yes for the 100watt setting, but no for the 167watt setting due to the amount of power needed to raise the mass at 2x the speed.



xxChrisxx said:
Will repost q in a second.

Ok Q is:

14.4Kg block on a 45% slope

The motor used is:

100 Watt at 200rpm
4.77Nm at 200rpm

167.2 Watt at 400 rpm
4Nm at 400 rpm.

The reduction gearing is 15:1.
The rolling radius is 1m

Can the motor move the block up the hill?

EDIT: you can assume no losses through the drivetrain, so RWHP = engine HP.

Now after ansering this I'll give you the second part and address the truck and F1 engine thing.
 
  • #83
First of all buy this book:
https://www.amazon.com/dp/1844253147/?tag=pfamazon01-20

And read the last chapter (hell you can read all of it if you want). It'll tell you exatly wehre your thinking is a bit off.Regarding the question.

The acutal answer is neither will get it moving at that ratio.

Those are the peak figures, so the maximum power the motor can produce is 167.2 W. The maximum torque it can produce is 4.77 Nm.

The point of the above was to show that for a given gearing its the torque that creates the moving force. A minimum moving force requites a minimum torque at the wheels. The power figure has no bearing on this force. If it did the power figure would cause larger rear wheel forces and get it moving.

The next thing I was going to ask was try it with 21:1 (ive misplaces my notes on this i think that was the ratio). You'll find that the force at the wheel is then enough to move the block at the lower power figure but not the higher.

If you did rev it up (as more power apparently creates more force at the rear wheel) you should move faster. In fact it does the opposite, it you did rev it up you would no longer be providing enough force to overcome the resistance.

Do the acutal calucaltions and you'll see this is the case.Here is my working for the 1st part:

14.4*9.81*cos(45)= 100N
You need at least 100N to get the block moving up the slope.

It can be shown that the rear wheel forces for each settign are:

100W setting.

Engine_Torque*gearing = Wheel torque.
4.77*15= 71.55 Nm at the wheel.
As the wheel is 1 m Rolling radius.
T=F*d
Force at wheel is 71.55 N

This gives a net negative force of 28.45N

for the higher power setting the wheel force (using the same method above is)
Force =60N

Using the power method: we know the power of the motor and the force necessary.

P=100W
F=100N

using P = F * S

100/100 = 1 m/s So to get the thing moving we need a wheel speed of 1m/s or below.

Wheel speed at lower power = circumfrence of wheel * angular velocity
for 1 second.

S = (2*pi)*(200/(15*60)) = 1.39 m/s
S = (2*pi)*(400/(15*60)) = 2.79 m/s

The wheel speeds are too high to provide the adequate forces to start the block moving.

So more power doesn't = more rear wheel force. And the torque method is fer better at this (its more clear that it won't work) as it is a snapshot in time.
 
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  • #84
xxChrisxx said:
100 Watt at 200rpm, 4.77Nm at 200rpm
167.2 Watt at 400 rpm , 4Nm at 400 rpm.
The reduction gearing is 15:1.
It's not a fair comparason, setting the gearing for the same speed = 1.3963 m/s, with a radius of 1 meter:

100.00 watt at 200 rpm, 4.77465 Nm at 200 rpm, reduction gearing 15:1, force = 71.620 N
167.55 watt at 400 rpm, 4.00000 Nm at 400 rpm, reduction gearing 30:1, force = 120.00 N

As expected, 120.00 / 71.62 = 1.6755 = 167.55 / 100.00
 
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  • #85
You've totally missed the point of the arguement.

It was to show that the instantaneous force was dictated by torque only (not power). To do that they must have the same gearing. If you could change the gearing willy nilly, then the question becomes moot.

Thats why I told him to use 21:1 next. after that 25:1 and after that 30:1.
It shows that power output of the engine is the same, but the gearing changes to torque at the wheels.

I was then going to move on to what if you wanted them to move at the same rate. Now this is a power over time.

So with the 15:1 reduction at the higher power, you have a lack of torque to get it moving. But not when you use a different gearing.

I need him to break the thinking that its power dominating the size of the force (thats torque). and get him to understand that power essentially shows the frequency of the force. So although at the higher power, you have a smaller force. that force acts more often.

HOWEVER: The instantaneous force MUST be large engouh to move the block, otherwise the frequency is irrelevent. Think about trying to hammer in a nail with a feather. You can hit it as often as you want, but you can provide enogh linear force to get it to move. (thats a bit of an over simplified comparison, but it'll do for the purposes of explaining what I want)
 
  • #86
xxChrisxx said:
It was to show that the instantaneous force was dictated by torque only (not power).
I understand that torque is the angular equlivalent to (linear) force.

To do that they must have the same gearing.
Why? If you have gearing, then the gearing should be matched to the expected demands of the motor. This is why cars have transmissions and differentials. This is why a P51D Mustang (WW2 airplane) gears it's prop down to 1437 rpm while it's engine spins at 3000 rpm. Since the title of this thread is race cars, I would assume that those cars would be geared appropriately.

In your example, you specify a torque, a gearing and a wheel radius, allowing the linear force at the wheel to be calculated, but without knowing that this torque occurs at non-zero rpm, it's not known if the motor can move the block.

Take the case of an electronic stepper motor. Dynamic torque (moving) is about 70% of holding torque (not moving), so for example.

reduction gearing 15:1, wheel radius 1 meter, 60N load (required force)

torque == 5.0Nm at rpm = 0, force = 75.0N
torque <= 3.5Nm at rpm > 0, force = 52.5N

The motor has enough torque to hold the load in place, but it can't turn against the load.

Knowing only the torque isn't sufficient to know if it will move unless it's also known that that torque can be generated when the motor is turning. Some knowledge of angular velocity (the fact that it is non-zero) in addition to torque (so therefore power) is required to know if the motor can perform any work.
 
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  • #87
you really missed the point of the entire discussion with that one. I had similar values at my quick glance, using .707 x the 14Nm of the load up the hill. Even still, you missed the part that if you didnt use gears to utilize the available power, of course the load can't be lifted up the hill. there is not enough power available to move those two loads. However, if you slowed things down a bit, the power could be used to move the mass up the hill.

geaering doesn't create HP , it gives you the ability to utilize it. It also multiplies torque, by sacraficing rpm. Because at 200rpm, and the resultant 2m/second requires more torque than the motor can provide. P=fv. however, at a slower speed, the hp can be utilized though deeper gearing and would move/lift the load. I you have more power at 400rpm on the motor, 100watts going to 167watts, then obviously, double the gearing again, for the same output speed , and you will have increased the final torque output proportionally.
You are using more electrical power, creating more mechanical power, and thus have more force generated at any given output speed.

A stepping motor, like Jeff brought up, has its greatest torque at the first signal to move. It has something called a torque vs angle of displacment. however if you want to get a load to move, you can easily gear it, and take advantage of its maximum power capabilities. If the load is above its holding torque, it can't move it Gear it down, and now it has more torque and is better utilizing the available power capacity.

go back to your original idea of the truck powered by its engine or a F1 engine. you said that at the same hp, the F1 engine doesn't do a good job, and that is just not true with half the engine torque and double the gearing with its double the engine speed, the same rear wheel torque is achieved. This is the point of the discussion as I see it.

HP (or HP rating) will determine the torque at the wheels at any given speed, and is proved by the combination of the identities showing:

Acceleration =power/mass x velocity.

why don't you summarize what the last chapter in the book says. I've been racing awhile and always have plotted out torque curves in each gear. I now use HP curves with geared % rpm drops. I can compare other powerplants as well, without looking at engine torque curves and get accurate assesement of which engine will perform best over a given speed range. basically, he who uses more of the available HP, if two cars have the same hp, will win the race (all other things being equal). even if they are different in HP , a lower hp can win if it can be used in such a way where it has more average HP over the operational speed range. Conversely, and more commonly, the broader HP engines can yeild more available torque at the rear wheels, even if its engine torque is lower compared to a high torque same HP engine.

The point of this really was, to confer with the physics community to talk about what terms would be appropriate to describe the charactistics of engines in race cars . Is it HP-seconds that we want to optimize? Becauase as I see it, the amount of time spent at the highest engine hp levels available, will yield the max amount of rear wheel torque, and acceleration at any given vehicle speed.



mk


xxChrisxx said:
First of all buy this book:
https://www.amazon.com/dp/1844253147/?tag=pfamazon01-20

And read the last chapter (hell you can read all of it if you want). It'll tell you exatly wehre your thinking is a bit off.


Regarding the question.

The acutal answer is neither will get it moving at that ratio.

Those are the peak figures, so the maximum power the motor can produce is 167.2 W. The maximum torque it can produce is 4.77 Nm.

The point of the above was to show that for a given gearing its the torque that creates the moving force. A minimum moving force requites a minimum torque at the wheels. The power figure has no bearing on this force. If it did the power figure would cause larger rear wheel forces and get it moving.

The next thing I was going to ask was try it with 21:1 (ive misplaces my notes on this i think that was the ratio). You'll find that the force at the wheel is then enough to move the block at the lower power figure but not the higher.

If you did rev it up (as more power apparently creates more force at the rear wheel) you should move faster. In fact it does the opposite, it you did rev it up you would no longer be providing enough force to overcome the resistance.

Do the acutal calucaltions and you'll see this is the case.


Here is my working for the 1st part:

14.4*9.81*cos(45)= 100N
You need at least 100N to get the block moving up the slope.

It can be shown that the rear wheel forces for each settign are:

100W setting.

Engine_Torque*gearing = Wheel torque.
4.77*15= 71.55 Nm at the wheel.
As the wheel is 1 m Rolling radius.
T=F*d
Force at wheel is 71.55 N

This gives a net negative force of 28.45N

for the higher power setting the wheel force (using the same method above is)
Force =60N

Using the power method: we know the power of the motor and the force necessary.

P=100W
F=100N

using P = F * S

100/100 = 1 m/s So to get the thing moving we need a wheel speed of 1m/s or below.

Wheel speed at lower power = circumfrence of wheel * angular velocity
for 1 second.

S = (2*pi)*(200/(15*60)) = 1.39 m/s
S = (2*pi)*(400/(15*60)) = 2.79 m/s

The wheel speeds are too high to provide the adequate forces to start the block moving.

So more power doesn't = more rear wheel force. And the torque method is fer better at this (its more clear that it won't work) as it is a snapshot in time.
 
  • #88
Look if you care in the slightest about being correct about the physics of this.

Buy/borrow/steal and read the following books.

John Heywood - Internal Combustion Engine Fundamentals
Richard Stone - ICE
A.G Bell - Four-Stroke Performance Tuning
Paul Van Valkenburgh- Race Car Engineering & Mechanics

1. is probably least relevant but is pretty much the engine bible.
2. stone is good for practical workings.
3. Good non technical book reguarding practical tuning
4. a very good all round car setup book. especially the section on gearing and performance.

I have read all of these at some point over the last 3 years. They are all thorough and will show you where you've gone wrong.

Read Bell first. then any of the others. I am in no way inclined to type out whole sections from the book.
 
  • #89
Jeff Reid said:
I understand that torque is the angular equlivalent to (linear) force.

Why? If you have gearing, then the gearing should be matched to the expected demands of the motor. This is why cars have transmissions and differentials. This is why a P51D Mustang (WW2 airplane) gears it's prop down to 1437 rpm while it's engine spins at 3000 rpm. Since the title of this thread is race cars, I would assume that those cars would be geared appropriately.

In your example, you specify a torque, a gearing and a wheel radius, allowing the linear force at the wheel to be calculated, but without knowing that this torque occurs at non-zero rpm, it's not known if the motor can move the block.

Take the case of an electronic stepper motor. Dynamic torque (moving) is about 70% of holding torque (not moving), so for example.

reduction gearing 15:1, wheel radius 1 meter, 60N load (required force)

torque == 5.0Nm at rpm = 0, force = 75.0N
torque <= 3.5Nm at rpm > 0, force = 52.5N

The motor has enough torque to hold the load in place, but it can't turn against the load.

Knowing only the torque isn't sufficient to know if it will move unless it's also known that that torque can be generated when the motor is turning. Some knowledge of angular velocity (the fact that it is non-zero) in addition to torque (so therefore power) is required to know if the motor can perform any work.

jesus.

im going to answer this point 1 last time.

this was a demonstation about a key physical concept to the op. for the purposes of demonstating that physical concept, the gears had to be kept the same.

Gears are torque multipliers. The point was to show that the force at the wheel is given by torque only. not power. if it was given my the power figure, an increase in power should give an increase in wheel force. it doesnt.

in my exapmle i specify a torque AT AN RPM. however this point is moot as:

torque defines the force at the wheel. So a huge torque at 0 rpm would give a huge force that had the POTENTIAL! (READ THIS 50 TIMES) POTENTIAL! to move the block.

if you applied this 0 times per second. which is where power comes in. you would not move the block. as the potential is not being used.

likewise if you had a force that ws not large enough DID NOT HAVE THE POTENITAL due to incorrect gearing. you could have all the power available in the gear but you wouldn't shift he block.
THIS IS THE POINT YOU NEED TO KNOW BOTH! POWER AND TORQUE TO KNOW IF IT'LL MOVE. YOU CAN KNOW POWER and RPM or torque abd RPM. or anything else, but in the end you'll always be boiling down the equations for a torque and power.
 
  • #90
thats me done for this now. Read the books I posted.
 
  • #91
As far as being wrong, you haven't pointed one single point out to that effect. I would certainly like to hear that. What we have been arguing about is the chicken and egg aspects of force and power. I still think its a valid debate. I don't need to win it, as long as we can discuss the way we can apply power and torque curves to race car performance.

The biggest problem that I see with your argument as I see it, is that you keep on bringing the comparisons to the same gear for two equal power sources. Two problems happen here. This gives the power source with a higher rpm, lower torque characteristics a situation where much less than its full HP, or comparitive HP can be realized and we are comparing output speeds that are grossly different. Since, power is the RATE of doing work, and Work is Force x distance. If you have just a force, applied at ANY vehicle speed, it can be created by a high rpm, low torque power source, or a low rpm high torque source. Power dictates a force at any vehicle speed. No net force is applied, until there is movement. if there is movement, there is work, and the faster the rate of doing work the greater the power.


Your analogy if you don't have the torque and you just apply the torque at a faster rate, you still don't move the load is flawed. You are looking strictly at the power source and not what is available at the drive wheels. as you apply the same torque at a higher drive wheel speed, the power requirements to move the load go way up! You have to keep the vehicle speed the same in any comparison , or the comparison or test is flawed. Gearing is used to keep a vehicle as close to its max HP range as possible. in the end, the most amount of hp-seconds used , wins the acceleration race over any speed range.

You still never answered the truck vs the F1 engine powered truck. You made a bold statement that the F1 powered engine, at the same HP counldnt move the load up the hill. IN fact, it can. This is very easy to prove by using the F1 engine at its max HP at higher rpm and with deeper gearing.

Power is a force's capacity to do work. my 6 year old can generate 600ft-lbs of torque. Its not going to do much work, or accelerate anything very fast, because his rate of doing work is very small. However, a 600ft-lb torque engine with 6000rpm available, will be able to accelerate a 3000lb car to 100mph in near 10 seconds!

If you are comparing two same HP engines, or motors, and you don't keep the relative vehicle speeds the same, you are not allowing one of the engines to be at or near its useable HP range.

I do care about being correct. I have asked many times to discuss the venacular of the proper use of watt-seconds, HP-seconds, in looking at the time spent at the higher rpm of the HP curve and the total rear wheel forces created in those engine speed ranges.
certainly, when ploting to vehicle speed, you could use gear ratios, engine torque curves and find optimal shift and thus acceleration values. This will exactly parallel engine HP curves.(as measured at the rear wheels off a dyno, as well as engine torque values as calculated back to the engine). "Parallel" meaning the effects, not the rear wheel torque curves .

If I have this wrong, please show me one example where proportiona gearing is available, where this is not true with two equal HP cars with one having much more engine torque than the other. Here is a couple of engine HP curves of the exact, real life example. which powerplant would you want if you were going racing on a road course?


Again, not trying to get into a wrestling match here. Just in search of truth. Trust me, I know what I am saying works out on paper, works at the track and follows alll the basic equations. But, I've come here for the correct terminology and ways of explanation.

If I am wrong, I CERTAINLY want to know it.

Again, here are two different engines, both at 290rwhp, but grossly different torque values. I contend that the lower torque engine of the two is going to be better on the race track at any speed or point on the race track. use what ever gears you want that suits one over the other, as long as the shift points are at the same MPH in vehicle speed.
See if you agree or not.
mk




xxChrisxx said:
Look if you care in the slightest about being correct about the physics of this.

Buy/borrow/steal and read the following books.

John Heywood - Internal Combustion Engine Fundamentals
Richard Stone - ICE
A.G Bell - Four-Stroke Performance Tuning
Paul Van Valkenburgh- Race Car Engineering & Mechanics

1. is probably least relevant but is pretty much the engine bible.
2. stone is good for practical workings.
3. Good non technical book reguarding practical tuning
4. a very good all round car setup book. especially the section on gearing and performance.

I have read all of these at some point over the last 3 years. They are all thorough and will show you where you've gone wrong.

Read Bell first. then any of the others. I am in no way inclined to type out whole sections from the book.
 

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  • #92
I think I might understand out disconnect from what you wrote below. You seem to be saying, if we can play with gearing the point is moot. same HP, will create the same acceleration at any vehicle speed. And you say, if you don't have the abilty to change gears to optimal values to equal two vehicle's speeds for comparison, you need to know power AND torque. however, i contend if you know the power it is enough. You are talking about a power rating that you may or not be able to use due to lack of gear selections. If this is the case, then of course, without the lack of gear selections, you won't be able to utilize the POWER potentially available. Again, if you can realize the power, you will be able to move the load with a predicted force and will know the rate at which it can be accelerated at any velocity. It is the power rating that will determine the rate of acceleration at any speed. If you are not able to utilize the power rating at that speed, then you are operating at a lower power setting. all this proves is that you didnt gear the car properly for the test.

mk

xxChrisxx said:
likewise if you had a force that ws not large enough DID NOT HAVE THE POTENITAL due to incorrect gearing. you could have all the power available in the gear but you wouldn't shift he block.



THIS IS THE POINT YOU NEED TO KNOW BOTH! POWER AND TORQUE TO KNOW IF IT'LL MOVE. YOU CAN KNOW POWER and RPM or torque abd RPM. or anything else, but in the end you'll always be boiling down the equations for a torque and power.
 
  • #93
I am going to make one final statement (its not this one its coming next) addressing your last post and then that's it.

I have no inclination to try to help you to understand the flaws in your thinking if you just keep repeating what you have said before. I have reccomended some books that, IF you read them, you will see where you went wrong.
 
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  • #94
I invite you to respond to the below, if you wish to dispute anything said you must give evidence to back up your claim. The evidence must be listed so that it can be found by all. By evidence I mean something remotely scientific, not an observation you made and are asserting as true.
zanick said:
As far as being wrong, you haven't pointed one single point out to that effect. I would certainly like to hear that. What we have been arguing about is the chicken and egg aspects of force and power. I still think its a valid debate. I don't need to win it, as long as we can discuss the way we can apply power and torque curves to race car performance.

WHERE YOU ARE INCORRECT:

YOU STATE: chicken and the egg debate about force and power.
REALITY: It is NOT a chicken and egg thing. The physical process is you apply a force and something moves a given distance. You cannot apply power at a speed and create a force.

The physical process is Newtons first law of motion.

"A body persists its state of rest or of uniform motion unless acted upon by an external unbalanced force." Newton 1st Law

The above do NOT work in reverse, something simply cannot start moving spontaneously and a force is created as a result. Because of this:

P = F * V is true, a force acting at a speed will give a power.
P/V = F Cannot occur in nature, as it breaks Newtons 1st law. What you are doing with the equation in this form is finding the NECESSERY force to create a power at a gien speed. It does not mean, if you apply a power at that speed you will get that force.

Energy, and by extention power cannot be directly measured. It is always calculated from more fonamental things.

There is no absolute measure of energy, because energy is defined as the work that one system does (or can do) on another. Thus, only of the transition of a system from one state into another can be defined and thus measured.

"Methods

The methods for the measurement of energy often deploy methods for the measurement of still more fundamental concepts of science, namely mass, distance, radiation, temperature, time, electric charge and electric current." wikipedia. but you can get this from pretty much any physics book.Conclusion to this: Power cannot be directly measured, it requires more fundamental principles to quantify and give context. Applying a power at a speed cannot occur as it violates Newtons 1st law of motion. The fundamental factor in this must therefore be force distance and time. Of which the only one that has potential to do work is force.

Force therefore is first, and power is a method by which we quatify what that force has done.
zanick said:
The biggest problem that I see with your argument as I see it, is that you keep on bringing the comparisons to the same gear for two equal power sources. Two problems happen here. This gives the power source with a higher rpm, lower torque characteristics a situation where much less than its full HP, or comparitive HP can be realized and we are comparing output speeds that are grossly different. Since, power is the RATE of doing work, and Work is Force x distance. If you have just a force, applied at ANY vehicle speed, it can be created by a high rpm, low torque power source, or a low rpm high torque source. Power dictates a force at any vehicle speed. No net force is applied, until there is movement. if there is movement, there is work, and the faster the rate of doing work the greater the power.

This (the power speed force bit) is incorrect for as it violates Newtions first law as stated above.

By the same reason that force and speed can bve used to find power:

P = T * angular velocity torque and angualr velocity can be used to find power
P/angualt velocity = T you can't do it this way. The find the necessary torque. not the actual.You say that the faster the rate of doing work by the engine the greater its power output. This is indeed correct. Now for where you are going wrong with it.

"The engines power output is set. It is defined by:

P=(thermal efficieny * volumetric efficieny * displaced volume * number of revolutions * fuel heating value * density of the air * (fuel air ratio)/2" Equation from Heywood

This defines the amount of work a given engine can do. The POWER OUTPUT IS SET IT DOES NOT CHANGE DEPENDING ON THE GEARING. So if you geared it 1:1 you'd have the same power at the rear wheel as if you used a 100:1 gearning. It would be going this work more slowly, but it would be doing more work.

You are NOT doing more work at the rear wheels by using a higher gear ratio.

"W = F * d" wiki or books.

You are using a higher force but moving
 
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  • #95
I think we all understand that torque corresponds to force, and power is the same for both angular and linear environments.

If you only know the torque, gearing, and radius of tire, then you know the force, but you won't know the speed at which the force can be applied.

If you only know the peak power, then you don't know the torque versus rpm curve and wouldn't know how to set the gearing.

If you know torque or power versus rpm, then you can calculate power or torque versus rpm from that information, and you would know how to optimize the gearing for a specific load range, and the rate of acceleration versus speed for a given load.
 
  • #96
Yup that's bang on the money Jeff.


OP doesn't understand that its torque not power deermining the magnitude of the force. as he's stated that power determines the acutal force at the rear wheels when it doesnt.
 
  • #97
Exactly, but with one comment. you would need to know the HP vs RPM (not just peak HP) as you say in you last sentence, which has been the point of the discussion. by knowing the HP curve, you can optimize max acceleration for any range of speeds by using gearing, without knowing the engine torque values. you could also calculate the applied forces as well at any vehicle speed.

mk


Jeff Reid said:
I think we all understand that torque corresponds to force, and power is the same for both angular and linear environments.

If you only know the torque, gearing, and radius of tire, then you know the force, but you won't know the speed at which the force can be applied.

If you only know the peak power, then you don't know the torque versus rpm curve and wouldn't know how to set the gearing.

If you know torque or power versus rpm, then you can calculate power or torque versus rpm from that information, and you would know how to optimize the gearing for a specific load range, and the rate of acceleration versus speed for a given load.
 
  • #98
I fully understand that torque does the work (or force does the work) . But, HP ratings (rate of doing the work) can determine rear wheel torque, or forces at any vehicle speed. in otherwords, go back to the electric motor and the power source. If the ratings are such that we can create x-KW-hours, with that unit measure of work, we can determine how fast we can do that work and for how long. just as if we had a power sourse being a spinning flywheel that has stored KE. That can be applied quickly or slowly. The force will be a result of how that energy is released. In the end, the change of KE is the work done. the rate of change is the Power.
For any given power, or rate of change of KE, we can determine the force acting on a moving body at any velocity.
This discussion has clearly changed my way of thinking of power as more of a rating, but none the less, if you know the rating, and it is being used, you can determine the force at any speed.

Ill take a look at a couple of the books you have listed, but I think if anything, it will change my way of explaining what we see in reality. Did you have a chance to look at the HP curves I supplied. tell me which one would be better on a race track at any speed. Only given is say the cars have 4 gears, all with 25% rpm drops per shift. Keep MPH shift points the same, to level the playing field and let me know what you think. In the end , the lower torque engine, will have more rear wheel torque. why, because it has more average HP and more HP-seconds available to create the forces at the rear tires.

mk

xxChrisxx said:
Yup that's bang on the money Jeff.


OP doesn't understand that its torque not power deermining the magnitude of the force. as he's stated that power determines the acutal force at the rear wheels when it doesnt.
 
  • #99
Chris, I am going to do my best to answer your challenge. Again, I am not questioning that the force is what creates movement. I am saying that power can create the force. doesn't the explosion create the force. (force doesn't create the explosion) Energy can't be created nor destroyed, right? Energy is converted to mechanical energy (watt-seconds), J, etc. or do I have that backwards?

See my inserts to you comments and see If I am on the right track. with the:
>>>>>>>>>>>>>>>>>>>>>>>>




xxChrisxx said:
I invite you to respond to the below, if you wish to dispute anything said you must give evidence to back up your claim. The evidence must be listed so that it can be found by all. By evidence I mean something remotely scientific, not an observation you made and are asserting as true.




WHERE YOU ARE INCORRECT:

YOU STATE: chicken and the egg debate about force and power.
REALITY: It is NOT a chicken and egg thing. The physical process is you apply a force and something moves a given distance. You cannot apply power at a speed and create a force.

The physical process is Newtons first law of motion.

"A body persists its state of rest or of uniform motion unless acted upon by an external unbalanced force." Newton 1st Law
>>>>>>>>>Agreed, but if I have a spinning flywheel with a known KE, if I release that through a clutch, isn't a force created. I stopped the flywheel and use the rate of change of KE to produce a rate of doing work, (i.e. Power) Didnt I create the force by converting he KE to another form. Force did the work but didn the KE produce the force?


The above do NOT work in reverse, something simply cannot start moving spontaneously and a force is created as a result. Because of this:

P = F * V is true, a force acting at a speed will give a power.
P/V = F Cannot occur in nature, as it breaks Newtons 1st law. What you are doing with the equation in this form is finding the NECESSERY force to create a power at a gien speed. It does not mean, if you apply a power at that speed you will get that force.

Energy, and by extention power cannot be directly measured. It is always calculated from more fonamental things.

>>>>>>>>>I agree. Even in its best case, HP would be calculated form a rate of change of KE. you need to know speed change vs time and mass.

There is no absolute measure of energy, because energy is defined as the work that one system does (or can do) on another. Thus, only of the transition of a system from one state into another can be defined and thus measured.

"Methods

The methods for the measurement of energy often deploy methods for the measurement of still more fundamental concepts of science, namely mass, distance, radiation, temperature, time, electric charge and electric current." wikipedia. but you can get this from pretty much any physics book.


Conclusion to this: Power cannot be directly measured, it requires more fundamental principles to quantify and give context. Applying a power at a speed cannot occur as it violates Newtons 1st law of motion. The fundamental factor in this must therefore be force distance and time. Of which the only one that has potential to do work is force.

Force therefore is first, and power is a method by which we quatify what that force has done.
>>>>>>>>>>>>>>Doesnt KW-hours, watt-seconds, HP-seconds quantify how much work can be done? If I have a battery or a gas tank filled with electrons or fuel, I have potental energy here. is the capacity for how much work can be done. I can do it fast or slow, in the end its work (fs). How fast I do that work, or rate of doing work is power. If push a button and release electrons in motor at a known rate, and it is converted, i know, at any given speed, what the force will be. The force does the work, but the power is the indicator of what the force will be at any particular speed.




This (the power speed force bit) is incorrect for as it violates Newtions first law as stated above.

By the same reason that force and speed can bve used to find power:

P = T * angular velocity torque and angualr velocity can be used to find power
P/angualt velocity = T you can't do it this way. The find the necessary torque. not the actual.


You say that the faster the rate of doing work by the engine the greater its power output. This is indeed correct. Now for where you are going wrong with it.

"The engines power output is set. It is defined by:

P=(thermal efficieny * volumetric efficieny * displaced volume * number of revolutions * fuel heating value * density of the air * (fuel air ratio)/2" Equation from Heywood

This defines the amount of work a given engine can do. The POWER OUTPUT IS SET IT DOES NOT CHANGE DEPENDING ON THE GEARING. So if you geared it 1:1 you'd have the same power at the rear wheel as if you used a 100:1 gearning. It would be going this work more slowly, but it would be doing more work.

>>>>>>>>>>>>>>>>>>>You just made my point right there. sure, if I was at max power and we had 1:1 gearing, the force would be a heck of a lot different greater, at the driven wheels at 100:1 gearing. I think you made a critical mistake next. The rate of doing work would be IDENTICAL the amount of work per unit of time would be identical. Since we are talking the same " car " here. if power is the same in both cases, acceleration and thus rear wheel forces will be proportional to power and inversly proportioal to speed. IN this case, fundamemtally, you changed the conditions by comparing power at two different speeds. (100:1 vs 1:1). power is constant, rate of work is the same, acceleration and force are different based on the car's speed.
To answer your comment directly, if power didnt change with gearing, then the HP curve would be flat, and torque would be very high at start and very low at the higher speeds . If this was the case, rate of work still would be equal and forces would go down with speed proportional to speed.



You are NOT doing more work at the rear wheels by using a higher gear ratio.

"W = F * d" wiki or books.

You are using a higher force but moving

>>>>>>>>>as said above, you are doing the same amount of work, if you are using ANY ratio, if the power is the same. high rpm, low torque vs low rpm, high torque. If they trade off, the amount of work stays the same. Getting back to lifting a mass, 550lbs lifted in 1 second, one foot, is 1hp. 1000lbs lifted 1 foot in 2 seconds is 1 hp. 275lbs lifted 1 foot in .5 seconds is still 1 Hp. (746watt-seconds, 746J, 1hp-second, etc).

I can only think about this in a much broader analogy. what meteor objects to fall to earth, the Earth's mass (power) or gravity (force)? The fact that the Earth has such a large mass creates force that cause objects to be attracted and fall to earth. the more objects that fall to earth, the more the mass the Earth gets and the the greater the force of gravity . Its "power" goes up and creates a greater force. This is where I am either very confused, or think think the discussion is a kind of "chicken and egg" one. :)
 
  • #100
Please buy some books and read them.

No you didnt create a force from the energy. It was the momentum stored that caued the force, due to conservation. Energy stores are not good examples of what you are trying to say as they require forces in.

You can express the energy that its storing, but that energy doesn't create the force.

Read any statics book. Or the flywheel section in Shigley - Mechanical engineering design.YOU DONT USE KE OR RATE OF CHANGE OF IT TO CALCULATE FORCES! YOU USE MOMENTUMS! USING KE IS NOT REPRAT NOT WHAT HAPPENS IN REAL LIFE!
Tell me how do we measure power or energy directly. That means not using any more fundamental principle? I want to see proof of this.I'll respond to your odd thinking about gravity at a later time.
 
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  • #101
Long thread for a relatively simple concept, but Chris is right here: Power is typically calculated from torque and rpm in real life, so it generally makes more sense to discuss the concept from that angle than to say [paraphrase] 'if you know the power and rpm, you can calculate the torque and acceleration'. In other words - if you know the power and rpm, you probably already measured the torque directly. Sure, you can read the power off a performance curve, but where did that curve come from? It came from measuring the rpm and torque!

The wiki for a dyno says it pretty clearly:
A dynamometer or "dyno" for short, is a machine used to measure torque and rotational speed (rpm) from which power produced by an engine, motor or other rotating prime mover can be calculated.
http://en.wikipedia.org/wiki/Dynamometer

Yes, you can make life more complicated if you want and it'll usually work to approach the problem from the opposite direction, but it isn't really all that useful to do it that way. However, the way the issue was stated in the OP, though a little unclear, is clumsily worded and implies something that is not correct. And the conclusion statement in the last paragraph, with the graph that goes with it, is most certainly not correct: Even if, you gear the cars differently to account for the slop difference in the engine performance curve, the car that runs at a higher torque and lower rpm will accelerate faster because the drive losses are less in such a car.

The really therefore is that by overcomplicating the issue and looking at it backwards, you've confused yourself enough about the particulars to get the conclusions wrong.
 
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  • #102
It might be simple but it is one of the most confusing for most in the racing world. (except the very top engineers). You have to understand, that sometimes we only have dyno graphs to go off of, so that addresses you last point, because the resultant torque and HP measured, is at the rear wheels, incorporating the effeciency losses. So, if two engines with their drivetrains have the same rear wheel HP at any vehicle speed, they will have the same rear wheel forces. the advantage of one vs the other will follow the HP curve. (providing the same spacing of the gears) Now, of course, as I have said many times, using the gear output torque curves will tell you what you want to know, but you need to know the engine torque curves, the gear rations, tire diameters and vehicle speeds. With knowing HP curves and vehicle speeds ranges, all you need to know is gear spacing in %.

The conculsion I have come with , is that if two cars have equal HP curves, (as measured at the rear wheels) they will both have the same rear wheel torque at any vehicle speed. This is still true, even if i am coming at it from the wrong direction. The interesting thing about using HP is that it already incorporates engine speed, so in comparisons, it is easy to use to determine which engine is better, where the shift points should be and where its advantages and disavantages would be on a race track.

The entire point of the topic was to get the terminology correct to bring it back to the racing world. a you know, we want to optimize our time spent at the max hp range of the engine. (not max engine torque range of the engine). There is also a factor of the time spent at the higher rpm ranges. Just getting average power or even average torque found at the rear wheels, doesn't show the entire picture. I can even more accurately integrate the HP curve useable range and get a value that might not indicate which engine is going to create more HP-seconds, or Ft-Lb-seconds at the rear wheels. I think the only way to know this is to get a Ft-lb-seconds value based on known time over an operational speed range.

I only got on the chicken and egg discussion because the criticism was in the areas of actually using Hp curves to determine optimal rear wheel forces. Again, I understand that the force is what does the work, but was taking it a bit futher associating power with energy, as a potential that creates the force. Unit measures of work are also in HP-seconds, KW-hours, Watt-seconds and thought it could address the basic question brought up in the beginning. Yes, there was some terminology confusion in the beginning, but that was in areas of engine torque, rear wheel torque as measured at the drive wheels but calculated back to the engine, rear wheel HP and rear wheel torque and forces at generated at the drive wheels.

by the way, there are dynos that are called chassis dynos that do nothing but measure the rate of acceleration of the drums that the car drives. since it needs to know speed, rate of change of speed, and the mass, you might say it is measuring hp as well, right? It can't tell you engine torque, unless it has a engine speed signal. all it can tell you in that case is the tangental force at the driven tires, it can't even tell you final drive torque of the vehicle! However it can accurately provide a MPH vs HP curve.

Now, I've been doing this a long time and have a lot of experience optimizing race cars for the track to be more competitive.
What I do know is that what I am talking about works, even if I am coming at it from the wrong or "odd" direction. Thats why I came here, to get the terminology straightened out.

Mk




russ_watters said:
Long thread for a relatively simple concept, but Chris is right here: Power is typically calculated from torque and rpm in real life, so it generally makes more sense to discuss the concept from that angle than to say [paraphrase] 'if you know the power and rpm, you can calculate the torque and acceleration'. In other words - if you know the power and rpm, you probably already measured the torque directly. Sure, you can read the power off a performance curve, but where did that curve come from? It came from measuring the rpm and torque!

The wiki for a dyno says it pretty clearly: http://en.wikipedia.org/wiki/Dynamometer

Yes, you can make life more complicated if you want and it'll usually work to approach the problem from the opposite direction, but it isn't really all that useful to do it that way. However, the way the issue was stated in the OP, though a little unclear, is clumsily worded and implies something that is not correct. And the conclusion statement in the last paragraph, with the graph that goes with it, is most certainly not correct: Even if, you gear the cars differently to account for the slop difference in the engine performance curve, the car that runs at a higher torque and lower rpm will accelerate faster because the drive losses are less in such a car.

The really therefore is that by overcomplicating the issue and looking at it backwards, you've confused yourself enough about the particulars to get the conclusions wrong.
 
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  • #103
You said this:
This defines the amount of work a given engine can do. The POWER OUTPUT IS SET IT DOES NOT CHANGE DEPENDING ON THE GEARING. So if you geared it 1:1 you'd have the same power at the rear wheel as if you used a 100:1 gearning. It would be going this work more slowly, but it would be doing more work.

This is not correct, but you still stand by it?

The bottom line, is I might not be using the right analogies. I only used the gravity, meteor for an analogy that there could be something that is responsible for the force, in terms of energy or the change in energy.

In my mind power is just torque with a rpm attached to it. Just a short cut to find out what i need in comparative environments.

mk



xxChrisxx said:
Please buy some books and read them.

No you didnt create a force from the energy. It was the momentum stored that caued the force, due to conservation. Energy stores are not good examples of what you are trying to say as they require forces in.

You can express the energy that its storing, but that energy doesn't create the force.

Read any statics book. Or the flywheel section in Shigley - Mechanical engineering design.


YOU DONT USE KE OR RATE OF CHANGE OF IT TO CALCULATE FORCES! YOU USE MOMENTUMS! USING KE IS NOT REPRAT NOT WHAT HAPPENS IN REAL LIFE!



Tell me how do we measure power or energy directly. That means not using any more fundamental principle? I want to see proof of this.


I'll respond to your odd thinking about gravity at a later time.
 
  • #104
Chris,
You did say this below, you know. I think we started out agreeing and then ended up in disagreement. thoughts?

mk

xxChrisxx said:
Yeah, i'll admit I don't know a super amount about racing boxes. Its been a while since I've done anything with transmissions.

Getting slightly back on topic. I'm glad this thread has swung around to what really matters for acceleration. The gear ratios! Yes peak torque and peak horsepower figures are great for willy waving in the paddock, but careful selection of gear ratios and usefulness of the powerband is king.
 
  • #105
The thoughts are, you are wrong about the technical side. And I don't think you are going to be able to break that 'old skool dyno room habit' of using incorrect terminology. I'm now kind of resigned to that fact.(was a bit stresses out about other things yesterday) The subtle difference between things like kinetic energy and momentium is case in point. You talk in terms of KE when its really correct to say momentum. I've given you some books to read if you wwant to get the technical stuff correct.However, from a practical stand point, even though want you are saying is not what is acutally happening, mathematical equtions have been developed to allow you to calculate it. What you do says if something will work, but not WHY it works. And i suppose if all you are after is a 'will it work' then your calculations are fine. Just use HP and calcualte the area, talk in terms of kWh or Hpseconds or sometihng else. Thats perfectly valid for explaining what you want, but it does skew your thinking.

you are correct, I view HP and simply an rpm corrected torque curve. But I know that both variabels are important. For what you want just use HP as that's valid.Just for the hell of it, you keep saying you have more power in a lower gear. And that I am wrong in sayin that you have the sme power whether you have 1:1 or 100:1 ratio.

Prove me wrong, do some calculations and post them. Please TRY to show I am wrong. Dont just state it.
 
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