Acceleration of a Car on a Frictionless Ramp

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SUMMARY

The discussion centers on the acceleration of a car on a frictionless ramp connected to a mass hanger via a pulley system. It is established that as the mass of the hanger increases, the acceleration of the car also increases due to the greater force exerted by gravity on the hanger, which translates to increased tension in the string. Key concepts include Newton's 2nd Law and the distinction between forces acting on the hanger and the car. Properly deriving the equations for acceleration requires careful attention to mass differentiation and consistent sign conventions.

PREREQUISITES
  • Understanding of Newton's 2nd Law of Motion
  • Familiarity with pulley systems and tension forces
  • Basic knowledge of free body diagrams
  • Ability to differentiate between multiple masses in a system
NEXT STEPS
  • Study the derivation of acceleration equations in pulley systems
  • Learn about free body diagrams and their applications in mechanics
  • Explore the effects of mass on tension in strings
  • Investigate the implications of frictionless surfaces in physics problems
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Students of physics, educators teaching mechanics, and anyone interested in understanding dynamics in systems involving pulleys and mass interactions.

Jacob87411
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I have a question dealing with acceleration. A car is on a frictionless ramp. The car is tied to a string that goes over a pulley and over the pulley there is a hanger. As the mass of the hanger increases should the acceleration of the car increase, decrease or stay the same. I thought it would remain the same since the hangar will accelerate at the same rate regardless of mass but results show otherwise. Thanks
 
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Jacob87411 said:
I have a question dealing with acceleration. A car is on a frictionless ramp. The car is tied to a string that goes over a pulley and over the pulley there is a hanger. As the mass of the hanger increases should the acceleration of the car increase, decrease or stay the same. I thought it would remain the same since the hangar will accelerate at the same rate regardless of mass but results show otherwise. Thanks

Think about Newton's 2nd. The greater the mass on the hanger, the greater the force the Earth exerts on it. So a greater mass on the hanger should produce a greater force on the car (via the tension force). Thus the car accelerates faster.

-Dan
 
Just to add to Dan's comments...

Jacob87411 said:
I thought it would remain the same since the hangar will accelerate at the same rate regardless of mass but results show otherwise.
I presume you are thinking that all objects have the same acceleration due to gravity regardless of mass. That's only true for objects in free fall, where the only force acting on them is gravity. But the hanger is not in free fall; gravity is not the only force acting on it--the string is also pulling it upwards.
 
Ok I have a question then when solving for the forces. First the forces of the hanger that's falling

The sum of the forces = T-mg=ma assuming down is negative, up is positive.

Sum of forces on the car being dragged in the Y direction is 0. Assuming this is frictionless is the sum of the forces just the force of tension pulling the car? Thanks
 
yes.
If friction is zero, the only (horizontal) Force applied to the car is Tension.

Be sure to use the correct prepositions :
We add the Forces APPLIED TO the hanger by other things ... these
are called Forces ON the hanger BY the other things (not "of" the hanger).

The sum of the Force y-components on the car is zero ...
this is not quite the same as "sum of forces on the car ... is 0" .

By the way, why don't you call the coordinate along the string as "x"?
 
Well I am trying to derive the equation for acceleration to help explain why it increases and I am having problems doing that.

For the hanger:
Sum of Forces X = 0
Sum of Forces Y = T-mg=ma

Car:
Sum of forces X= T=ma
Sum of forces Y= 0

I know that much but I am having issues deriving for the acceleration of the system to explain why mass increase results in acceleration increase
 
Careful with those equations. I see several problems:
(1) You failed to distinguish between the two masses. Call them by different symbols: m_h versus m_c.

(2) You failed to use a consistent sign convention and properly reflect the acceleration constraint. The constraint is that if the car has acceleration +a (up the ramp) then the hangar will have acceleration -a (down).

(3) You neglected the weight of the car.​

Try rewriting those equations with that in mind.
 

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