Minimum Power of the engine on a car climbing a hill

In summary, the car climbs a hill with a gradient of 1 in 3, and reaches a top speed of 22m/s. The minimum power needed to achieve this speed is 36.2 kW.
  • #1
Matthias85
18
0
Hi, Can someone please solve this question for me, including step by step instructions ?
I can solve the ones where the mass of a car is given, but can't do this one.

Homework Statement



Setting off from rest the car accelerates uniformly and climbs a steep hill which has a gradient of 1 in 3. It accelerates to 22m/s while traveling a distance of 100m up the incline.
What is minimum power of the engine?

Homework Equations


None given in the question.
P= F x v

The Attempt at a Solution


I keep on getting wrong answers ;(
 
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  • #2
Matthias85 said:
Hi, Can someone please solve this question for me, including step by step instructions ?
I can solve the ones where the mass of a car is given, but can't do this one.

Homework Statement



Setting off from rest the car accelerates uniformly and climbs a steep hill which has a gradient of 1 in 3. It accelerates to 22m/s while traveling a distance of 100m up the incline.
What is minimum power of the engine?

Homework Equations


None given in the question.
P= F x v

The Attempt at a Solution


I keep on getting wrong answers ;(

Usually when a quantity is not given, it is because it is not necessary. To see if that is the case here [or perhaps an omission] work the problem assuming the car has mass, say, 900kg and 1400kg. [you said you cna do these problems when you know the mass]

If you get the same answer each time, it means the mass really was unnecessary. If you get a different answer, then the mass was important.

Perhaps the answer if of the form XX kW/Tonne?

And re-read the question carefully - perhaps the mass of the car was actually given and you didn't notice.
 
  • #3
This is part C of the Exercise, mass was given fort part B and it was 600kg.The answer is 36.2kW

However I get 42kW :(
 
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  • #4
Matthias85 said:
This is part C of the Exercise, mass was given fort part B and it was 600kg.


The answer is 36.2kW

However I get 42kW :(

I noticed you listed P = F x v as an appropriate formula. That is used for a body being driven at constant speed. This car is accelerating.

I would be using P = work/time
= (Force x distance)/time.
= (mass x acceleration x distance)/time

From the data given, you can calculate the acceleration, ad the time taken to get to the top of the hill - so away you go.
 
  • #5
Matthias85 said:
This is part C of the Exercise, mass was given fort part B and it was 600kg.


The answer is 36.2kW

However I get 42kW :(

by the way - does the gradient 1 in 3 mean a rise of 1 metre for each 3 metres along the hill or does it mean a vertical rise of 1m for each 3m horizontal displacement.
To find the angle involved you use sin for one, but tan for the other?
 
  • #6
PeterO said:
I noticed you listed P = F x v as an appropriate formula. That is used for a body being driven at constant speed. This car is accelerating.

I would be using P = work/time
= (Force x distance)/time.
= (mass x acceleration x distance)/time

From the data given, you can calculate the acceleration, ad the time taken to get to the top of the hill - so away you go.


v=22m/s
s=100m

acceleration
v^2 = u^2 + 2as
484=0 + 200a
a=2.42m/s/s

time
t=v/a
t=22/2.42
t=9.09s

Are these correct?


PeterO said:
by the way - does the gradient 1 in 3 mean a rise of 1 metre for each 3 metres along the hill or does it mean a vertical rise of 1m for each 3m horizontal displacement.
To find the angle involved you use sin for one, but tan for the other?

Think its notation for vertical rise of 1m for each 3m horizontal displacement.
 
  • #7
Matthias85 said:
v=22m/s
s=100m

acceleration
v^2 = u^2 + 2as
484=0 + 200a
a=2.42m/s/s

time
t=v/a
t=22/2.42
t=9.09s

Are these correct?




Think its notation for vertical rise of 1m for each 3m horizontal displacement.

2.42 and 9.09 look just fine.

Now don't forget the drive from the engine will be partially canceled by the component of weight down the slope, so the engine may be pushing harder that you thought. That was why I queried what the "1 in 3" slope actually meant.
 
  • #8
So what's the next step?
I have tried using 1/2mv^2 + mgh but I kept getting wrong answer.


Maybe the 600kg is incorrect, can this question be solved without knowing weight of the car?
 
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  • #9
Matthias85 said:
v=22m/s
s=100m

acceleration
v^2 = u^2 + 2as
484=0 + 200a
a=2.42m/s/s

time
t=v/a
t=22/2.42
t=9.09s

Are these correct?




Think its notation for vertical rise of 1m for each 3m horizontal displacement.


Of course now you know the time, you could just consider the gain in kinetic energy [moving fast now] plus the gain in Potential Energy [higher up].

Power is (work)/(time) = (gain in energy)/(time)
 
  • #10
I've tried that I got incorrect answer of 70k W, should be 36.2W

Maybe the 600kg I've quoted from section B is misleading. Can this question be solved without knowing the mass of the car?
 
  • #11
Matthias85 said:
So what's the next step?
I have tried using 1/2mv^2 + mgh but I kept getting wrong answer. Maybe the 600kg is incorrect, can this question be solved without knowing weight of the car?

what gain in altitude do you get, and what vale of g did you use?

I get the 36.2 kW when I use the mass you said and the time you calculated?
 
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  • #12
h=100Cos(18.43)=94.87m
g=9.8m/s/s



Could you please solve this question for me, so I know where I am making the mistake?
 
  • #13
Matthias85 said:
h=100Cos(18.43)=94.87m
g=9.8m/s/s



Could you please solve this question for me, so I know where I am making the mistake?

THINK!

Do you really believe 100m of hill will rise 94.87 m when the gradient is 1 in 3?

a gradient of 1 in 3 neans you go up about 1/3 the distance you move.

That is where your problem lies.

The cosine function is the wrong function!
 
  • #14
Thanks that helps !

I am still getting 36.4W not 36.2W :(

KE = 0.5x600x22^2 = 145200J
PE= 600x9.81x100Sin(18.43) = 186131J
WD = 331331J

Power = 331331/9.09 = 36450W
 
  • #15
Matthias85 said:
Thanks that helps !

I am still getting 36.4W not 36.2W :(

KE = 0.5x600x22^2 = 145200J
PE= 600x9.81x100Sin(18.43) = 186131J
WD = 331331J

Power = 331331/9.09 = 36450W

Could be rounding errors.

I notice a lot of people on this forum use 9.81 for g. In our school system we always used 9.8

I am very comfortable with the answer.

by the way with g = 9.8, and the time being 100/11 rather than 9.09, it is 36.42 kW are you sure you were reading the "official" answer correctly, and weren't over looking the 4 ?
 
  • #16
These calculations look like they are for average power (total work divided by total time) rather than the minimum required power. Shouldn't the engine be developing more power at the 100m mark (where the velocity is greatest) in order to maintain the force required to keep the acceleration constant (P = F*V)?

Is the question really asking for the minimum power?
 
  • #17
PeterO said:
Could be rounding errors.

I notice a lot of people on this forum use 9.81 for g. In our school system we always used 9.8

Heh. Problems in beginning physics classes often say to take g as 10 m/s2. Presumably this makes the numbers easier to deal with so that the student can concentrate on the physics rather than calculator operation. Later they find that 9.8 gives more realistic results. Still later, when they start worrying about error analysis and preserving significant figures through lengthier calculations, they start using 9.81, 9.807, or even 9.80665.

With the advent of spreadsheets and computer algebra systems, it's convenient to assign g the most accurate value you have and then forget about it!
 
  • #18
gneill said:
These calculations look like they are for average power (total work divided by total time) rather than the minimum required power. Shouldn't the engine be developing more power at the 100m mark (where the velocity is greatest) in order to maintain the force required to keep the acceleration constant (P = F*V)?

Is the question really asking for the minimum power?

In the real world, you would have to allow for friction - which increases with speed.

Since the car has reached 22 m/s [approx 80 km/h or 50 mph - not sure if you are from a metric country] air resistance for one would be becoming significant.

We tend to ignore friction - or pay lip service by fixing it as XX-Newtons throughout.

The reason we say minimum, is that it would be quite possible [easy in fact] to do this if the car had a 50 kW motor, or a 300 kW motor etc, but there is no way you could do it with a 30 kW motor..

midnight here - won't be answering for a while.
 
  • #19
PeterO said:
In the real world, you would have to allow for friction - which increases with speed.

Since the car has reached 22 m/s [approx 80 km/h or 50 mph - not sure if you are from a metric country] air resistance for one would be becoming significant.

We tend to ignore friction - or pay lip service by fixing it as XX-Newtons throughout.

The reason we say minimum, is that it would be quite possible [easy in fact] to do this if the car had a 50 kW motor, or a 300 kW motor etc, but there is no way you could do it with a 30 kW motor..

midnight here - won't be answering for a while.

Even discounting all forms of friction, at the 100m mark the car must be developing power Force x Velocity at that instant. That'll be twice the average power over the whole run.
 
  • #20
PeterO said:
Could be rounding errors.

I notice a lot of people on this forum use 9.81 for g. In our school system we always used 9.8

I am very comfortable with the answer.

by the way with g = 9.8, and the time being 100/11 rather than 9.09, it is 36.42 kW are you sure you were reading the "official" answer correctly, and weren't over looking the 4 ?
Answer says 36.2kW however the sheet also says that some of the answer may be mis-typed :)
gneill said:
These calculations look like they are for average power (total work divided by total time) rather than the minimum required power. Shouldn't the engine be developing more power at the 100m mark (where the velocity is greatest) in order to maintain the force required to keep the acceleration constant (P = F*V)?

Is the question really asking for the minimum power?

Yes, the question is asking for the minimum power of the engine.

Do you know if there's a way of solving it without knowing mass of the car?
 
  • #21
Matthias85 said:
Answer says 36.2kW however the sheet also says that some of the answer may be mis-typed :)
Well, that's very helpful of them :smile:
Yes, the question is asking for the minimum power of the engine.

Do you know if there's a way of solving it without knowing mass of the car?
If you think about it qualitatively, it is clear that the required power must go up when the mass of the car goes up; imagine a 10kg toy car performing the feat, and then a 10000kg monster car doing it just the same!

So in order to solve the problem numerically the mass should be known. As already mentioned, though, one way of answering such a problem in general terms is to put the answer in the form of Specific Power, that is, the power required per kg of mass.
 
  • #22
If you're worried about the mass of the car, and if the mass was found in a previous part of the question, perhaps you should post the contents of the entire question so that others can evaluate it in context.
 
  • #23
This question is now solved, the answer must have been miss-typed.
Thank you guys for help.

PetrerO,
I think you are right about value of gravity as I just did very similar question to this one, and got correct answer when I used g at 10m/s/s.
 

1. What is the minimum power required for a car to climb a hill?

The minimum power required for a car to climb a hill depends on various factors such as the weight of the car, the steepness of the hill, and the friction between the tires and the road. However, on average, a car would need at least 15 horsepower (hp) to climb a hill.

2. How does the weight of the car affect the minimum power required to climb a hill?

The weight of the car directly affects the minimum power required to climb a hill. A heavier car would need more power to overcome the force of gravity and move up the hill. Therefore, a lighter car would require less power to climb the same hill compared to a heavier car.

3. Is the minimum power required to climb a hill the same for all types of cars?

No, the minimum power required to climb a hill may vary for different types of cars. Factors such as engine size, transmission, and traction control can all affect the power needed to climb a hill. For example, a car with a larger engine may need less power to climb a hill compared to a car with a smaller engine.

4. How does the steepness of the hill affect the minimum power required?

The steeper the hill, the more power a car would need to climb it. This is because the force of gravity pulling the car down the hill is greater, and the car would need more power to overcome it and move up the hill. Therefore, a car would need more power to climb a steep hill compared to a gradual incline.

5. Can the minimum power required to climb a hill be calculated?

Yes, the minimum power required to climb a hill can be calculated using the formula P = mgv, where P is the power (in watts), m is the mass of the car (in kilograms), g is the acceleration due to gravity (9.8 m/s2), and v is the speed at which the car is climbing the hill (in meters per second). However, this is a simplified calculation and does not take into account other factors such as air resistance and friction.

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