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Something like that. Though, I'm not exactly sure how it wound up here.gruntguru wrote:Ohhh THAT work!
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That's when you really start to feel the "power".bhall II wrote:I guess this is what happen when one touches the third rail.
I would rephrase that as, "torque without a relevant measure of speed" means nothing... which ultimately gets us back to power.GitanesBlondes wrote:Torque without a gearbox means nothing right?
I'd say so, yes.What everyone considers "torque", it's just a measure of the turning force on the flywheel, no?
You're on the right path here, yes. You've got how fast the engine is turning (or can turn fastest), and then you've got how fast you need to wheels and tires to turn to go a certain speed. So with that you're forced to be in a certain ballpark range for overall reduction ratio between the two.However that turning force measured (torque is a measurement of force) at the flywheel is irrelevant because what really matters is how the gearbox multiplies that turning force created by the power (the amount of energy being unleashed by the engine and defined generally as horsepower?) of the engine at various RPM?
YesOver the course of the way from the flywheel, through the gearbox, down the driveshaft (assuming RWD) through the rear end to the wheels there is a loss of power that varies from vehicle to vehicle?
I guess it depends what your intended use is. In a racing engine, yes you want power at high revs because with a limited set of gears that gives you best top speed. In a lugging engine, you want power at lower revs (and hence what is sometimes referred to as a "torquey engine") coupled to a gearbox that allows you to lug but still have useful speed when required.Jersey Tom wrote: So if your engine makes lots of torque but at pitifully low RPM - who cares? You'd have to gear the thing in such a way that the torque at the wheels would be tiny and your car would be very slow. If you have an engine that makes the same torque at higher RPM you don't have to have as tall of gear ratios and you can deliver much more torque to the driving wheels.
the electrical equivalent to speed and torque would be voltage and current.GitanesBlondes wrote:For some reason I struggle so much with torque.
I don't know if it is because the more that people chime in, it takes what I thought was an understanding, and makes it feel uncertain.
Where I am currently:
Torque without a gearbox means nothing right?
What everyone considers "torque", it's just a measure of the turning force on the flywheel, no?
However that turning force measured (torque is a measurement of force) at the flywheel is irrelevant because what really matters is how the gearbox multiplies that turning force created by the power (the amount of energy being unleashed by the engine and defined generally as horsepower?) of the engine at various RPM?
Over the course of the way from the flywheel, through the gearbox, down the driveshaft (assuming RWD) through the rear end to the wheels there is a loss of power that varies from vehicle to vehicle?
maybe you didn't understand what I tried to say - for an object that is rotating continuously - there is no way to measure its torque directly, so on a dyno you let this rotating object do some work, generate electricity, move water, spin up heavy object, whatever - do things that you can more or less precisely calculate the amount of energy required to do this work in some period of time, so you have work done and you have time it took to do this work, and from this you determine how much energy it took to change the state of the thing you were looking at (rotational speed of a steel drum, electric current flowing through a load circuit etc.), and from that you calculate the equivalent momentum of the rotating object at some point in time (rpm) - this torque by itself does not do any work at all - this is fundamental to understand - it is simply a potential of the object to do work, then you give it some time and get work donestrad wrote:What do you think an engine dyno does? ..darn sure is running. Ever scatter an engine on a dyno? big bang fer sure.jz11 wrote:you can't measure torque of a running engine directly
measuring torque directly isn't a problem it is done all the time, measure the twist of a calibrated shaft or measure the force it takes to prevent the motor from rotatingjz11 wrote:maybe you didn't understand what I tried to say - for an object that is rotating continuously - there is no way to measure its torque directly, so on a dyno you let this rotating object do some work, generate electricity, move water, spin up heavy object, whatever - do things that you can more or less precisely calculate the amount of energy required to do this work in some period of time, so you have work done and you have time it took to do this work, and from this you determine how much energy it took to change the state of the thing you were looking at (rotational speed of a steel drum, electric current flowing through a load circuit etc.), and from that you calculate the equivalent momentum of the rotating object at some point in time (rpm) - this torque by itself does not do any work at all - this is fundamental to understand - it is simply a potential of the object to do work, then you give it some time and get work donestrad wrote:What do you think an engine dyno does? ..darn sure is running. Ever scatter an engine on a dyno? big bang fer sure.jz11 wrote:you can't measure torque of a running engine directly
same way you don't measure speed directly, you measure change of things over time and can calculate the speed
so power is not more fundamental than torque, it is simply different expression of the same thing
understanding how things are measured, what are the sources of possible errors, and how it can affect the final quantification of something is very important to avoid such mistakes as was the initial rule of the fuel flow this year
The power at high revs in racing engines is largely due to a limit on engine displacement. You want power, to get it with a limited displacement you have to rev higher and higher. You then use gearing to get what you want out of that power. You can tow a boat with an F1 engine, you just have to rev the piss out of it and gear it accordingly.Just_a_fan wrote: I guess it depends what your intended use is. In a racing engine, yes you want power at high revs because with a limited set of gears that gives you best top speed. In a lugging engine, you want power at lower revs (and hence what is sometimes referred to as a "torquey engine") coupled to a gearbox that allows you to lug but still have useful speed when required.
It is probably just easier to look at how torque and engine speed are used to calculate a vehicle's performance, rather than thinking about analogies. The equation below is basically a slightly rearranged and expanded version of Newton's F=mA:-GitanesBlondes wrote:For some reason I struggle so much with torque.
Actually you do measure the torque directly, it is reacted through the engine mounts. Apparently you know bugger all about engine dynos. Old ones used to have a little arm stuck out sideways with a weight on them that you used to balance the torque. I left the rest of your pompous gibberish in because it is so funny in context.jz11 wrote:maybe you didn't understand what I tried to say - for an object that is rotating continuously - there is no way to measure its torque directly, so on a dyno you let this rotating object do some work, generate electricity, move water, spin up heavy object, whatever - do things that you can more or less precisely calculate the amount of energy required to do this work in some period of time, so you have work done and you have time it took to do this work, and from this you determine how much energy it took to change the state of the thing you were looking at (rotational speed of a steel drum, electric current flowing through a load circuit etc.)....strad wrote:What do you think an engine dyno does? ..darn sure is running. Ever scatter an engine on a dyno? big bang fer sure.jz11 wrote:you can't measure torque of a running engine directly
understanding how things are measured, what are the sources of possible errors, and how it can affect the final quantification of something is very important to avoid such mistakes as was the initial rule of the fuel flow this year