Calculating Velocity of a Block Launched by an Ideal Spring

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Homework Help Overview

The discussion revolves around calculating the velocity of a block launched by an ideal spring. The problem involves concepts from energy conservation, specifically the conversion of potential energy stored in a spring to kinetic energy of a block on a frictionless surface.

Discussion Character

  • Exploratory, Assumption checking, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the energy stored in the spring and its conversion to kinetic energy. There are questions about the correct expression for potential energy and the importance of unit conversion in calculations.

Discussion Status

Some participants have provided guidance on the correct formula for potential energy and highlighted the need for unit consistency. There is an acknowledgment of a common mistake regarding unit conversion, but no explicit consensus has been reached on the overall approach.

Contextual Notes

Participants are working under the constraints of a homework problem, which may limit the information shared and the depth of the discussion. The original poster's confusion about the energy equations and unit conversions is a focal point of the conversation.

king_naeem
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An ideal spring is used to fire a 15.0-g block horizontally across a frictionless table top. The spring has a spring constant of 20 N/m and is initially compressed by 7.0 cm. The speed of the block as it leaves the spring is:


i do the following:

energy stored by spring: (kv^2)/2= 0.049

when the spring is at equilibrium position all the energy wwould be in kinetic thus i solve for the velocity,

but i get the wrong answer...what am i doing wrong?
 
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king_naeem said:
An ideal spring is used to fire a 15.0-g block horizontally across a frictionless table top. The spring has a spring constant of 20 N/m and is initially compressed by 7.0 cm. The speed of the block as it leaves the spring is:


i do the following:

energy stored by spring: (kv^2)/2= 0.049

when the spring is at equilibrium position all the energy wwould be in kinetic thus i solve for the velocity,

but i get the wrong answer...what am i doing wrong?

Er... if you meant by "v" above as "velocity", then you need to double check the expression for the potential energy of a compressed spring. Hint: it involves the compressed LENGTH, and not dependent on any velocity.

Zz.
 
It's hard to tell what you are doing wrong since you don't show us HOW you solve for velocity!

The potential energy stored in the spring, with spring constant 20 N/m, by compressing it 0.07 meters is (1/2)(20)(0.07)2= 0.049 Joules.

Once the spring has "uncompressed", all of its potential energy goes into the kinetic energy of the block so (1/2)(0.015kg)v2= 0.049 and v= 2.56 m/s approximately.
 
aah...my problem was that i forgot to convert 15 grams into kilograms...ahh!
 

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