How Should a Spring Be Compressed to Launch Blocks to Specific Heights?

Click For Summary
SUMMARY

The discussion focuses on calculating the required compression of a spring to launch two blocks to specific heights using principles of energy conservation and Hooke's Law. Block A, with mass m, is launched to a height of 4m, requiring a spring compression of approximately 14.1 cm. Block B, with mass 2m, is launched to a height of 2m, necessitating a different compression calculation, which is derived from the energy needed to reach the specified height. The key equations utilized include the potential energy of the spring and gravitational potential energy.

PREREQUISITES
  • Understanding of Hooke's Law and spring constants
  • Knowledge of gravitational potential energy (PE = mgh)
  • Familiarity with energy conservation principles
  • Ability to manipulate algebraic equations for problem-solving
NEXT STEPS
  • Study the derivation and application of Hooke's Law in various contexts
  • Learn how to calculate potential energy in different scenarios
  • Explore energy conservation in mechanical systems
  • Practice solving problems involving springs and mass launch dynamics
USEFUL FOR

Students studying physics, particularly those focusing on mechanics and energy conservation, as well as educators looking for practical examples of spring dynamics in problem-solving contexts.

cooltee13
Messages
25
Reaction score
0
Hey guys, this is an example from a quiz last semester that I am studying off of. However I can't figure out how to solve this question. Here is goes:

1. Block A, with Mass m, sits on top of a spring which is compressed 10 cm. When the spring is released, the block is launched to a maximum height of 2m above its starting point. Block B, with mass 2m, is placed on the same spring and launched 2m above the starting point.

a) how far should the same spring be compressed to launch block A 4m above its starting point?

b) how far should the same spring be compressed to launch block B to a max height of 2m above its starting point.


For part A, I ended up with 40 cm. However I am pretty sure that's wrong. if someone can take me through the thought process and help id really appreciate it.
 
Physics news on Phys.org
Work by a spring and such

Homework Statement



Hey guys, this is an example from a quiz last semester that I am studying off of. However I can't figure out how to solve this question. Here is goes:

1. Block A, with Mass m, sits on top of a spring which is compressed 10 cm. When the spring is released, the block is launched to a maximum height of 2m above its starting point. Block B, with mass 2m, is placed on the same spring and launched 2m above the starting point.

a) how far should the same spring be compressed to launch block A 4m above its starting point?

b) how far should the same spring be compressed to launch block B to a max height of 2m above its starting point.




Homework Equations



hookes law: 1/2kxf^2 + 1/2kxi^2 = W
Kinetic Energy: W = 1/2mv^2
Kd= mg
* I may need a different equation I am not aware of


The Attempt at a Solution



Part A)
I tried solving for the compressiob of the spring by setting up 2 equations. Kd=mg, i solved for K to get K = m(9.8)/.1m

Then I tried solving for x, using the equation ws + wg = 0 , so 1/2Kx^2 -mgh = 0 --> x = sqrt(2(mgh/k) ---> x = sqrt(2(m(9.8)(2m)/m(9.8)/.1m))) and got 40 cm as the resulting compressed spring.

Im pretty sure that its wrong, I am just overwhelmed and confused
 
Why don't you explain how you ended up with 40 cm. Hint: Energy is conserved.
 
Well, here's what I did..although it could be way off.

I set kd=mg, and solved for k. the answer i got was k = m(9.8)/.1m.
Then i used the equation ws + wg = 0 => 1/2Kx^2 - mgh = 0 => x = sqrt((2mgh)/k) then i plugged in the numbers and ended up with 40 cm.

but I think d is equal to 2.1 and not .1, correct?

*this whole thing may be wrong, but that's as far as I can get by myself.
 
cooltee13 said:
Well, here's what I did..although it could be way off.

I set kd=mg, and solved for k. the answer i got was k = m(9.8)/.1m.
You're not given any data to solve for k, but you don't need to solve for k to answer the questions. (Just because the spring is compressed 10 cm, does not mean that the weight alone is doing the compressing.) Just call the spring constant "k".

What you need to do is track energy changes: from spring PE to gravitational PE.

Hint for part a): By what factor must the energy change for mass A to reach a height of 4 m?
 
alright, I figured out part A. I used the PEs = PEgrav equation, which is 1/2Kx^2 = mgh
I plugged in .1 for x for part A (along with all of the other given info) and the answer i came up with was 3920m = K, and I plugged it into the equation again to get x = .141m as the amount its compressed.

Now my question is, for part B, is the "x" value still .1? because it doesn't specify.
 
cooltee13 said:
Now my question is, for part B, is the "x" value still .1? because it doesn't specify.
No you cannot assume that the compression remains the same, since that's what they are asking you to find. The spring constant is the same though, since its the same spring.

Hint: How much energy is needed to launch block B to the height specified?
 
hmm, well if the spring constant is the same, i got the same answer for part B as I did for A. because B is twice the mass, but goes half as high. Is that correct? or am I still missing something
 
cooltee13 said:
hmm, well if the spring constant is the same, i got the same answer for part B as I did for A. because B is twice the mass, but goes half as high. Is that correct? or am I still missing something
No, not correct. Block B is launched 2m. You know how much spring compression is needed to launch block A 2m; so how much is needed to launch block B (which has twice the mass) the same height?

How much energy is needed? How does spring energy depend on compression?
 

Similar threads

Building a Marble Catapult
  • · Replies 3 ·
Replies
3
Views
1K
Distribution of Energy when work is done on a system of 2 masses connected by a spring
  • · Replies 17 ·
Replies
17
Views
2K
A block of mass m is dropped onto the top of a vertical spring....
  • · Replies 8 ·
Replies
8
Views
6K
Why can we move the spring with constant speed when we apply a force?
  • · Replies 29 ·
Replies
29
Views
3K
Problem with when to use Force and Energy. What compresses spring/
  • · Replies 3 ·
Replies
3
Views
1K
A block dropping onto a spring system
  • · Replies 58 ·
2
Replies
58
Views
3K
Finding the speed of the block for one and two springs
  • · Replies 5 ·
Replies
5
Views
10K
Conservation of Energy: Spring pushing a block up an incline
  • · Replies 15 ·
Replies
15
Views
4K
Spring and block on an inclined plane
  • · Replies 27 ·
Replies
27
Views
10K
Force transmitted to a block in viscous fluid through a spring, cord, and pulley
  • · Replies 6 ·
Replies
6
Views
982