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Springs Web Link: Introduction to SpringsIntroduction to Springs the force required to stretch it  the change in its length F = k x k=the spring constant.

Published byIrma Morrison Modified over 9 years ago

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Presentation on theme: "Springs Web Link: Introduction to SpringsIntroduction to Springs the force required to stretch it  the change in its length F = k x k=the spring constant."— Presentation transcript:

1 Springs Web Link: Introduction to SpringsIntroduction to Springs the force required to stretch it  the change in its length F = k x k=the spring constant

2 Does a larger k value mean that a spring is A.easier to stretch, or B.harder to stretch?

3 Ex: If a spring stretches by 20 cm when you pull horizontally on it with a force of 2 N, what is its spring constant? 2 N How far does it stretch if you suspend a 2 N weight from it instead? 2 N

4 F = k x The same equation works for compression: the force required to compress it  the decrease in its length * For an ideal spring, the spring constant is the same for stretching and compressing.

5 A spring is an example of an elastic object - when stretched; it exerts a restoring force which bring it back to its original length. This restoring force is proportional to the amount of stretch, as described by Hooke's Law: The spring constant k is equal to the slope of a Force (mg) vs. Stretch graph. Stiffer springs yield graphs with greater gradients e.g. k A > k B When the spring is stationary F spring = mg

6 When a force is exerted on a spring it will either compress (push the spring together) or stretch the spring if the weight is hung on it.

7 Some objects like bridges will also behave like springs. When a weight is placed on a bridge parts will be stretched and under tension, other parts will be be squashed together or compressed

8 When the weight and the upward, restoring force are equal the spring is said to be in equilibrium

9 Because springs stretch proportionally we can use them as a spring balance to measure a force.

10 a)Determine the spring constant (k) for a single spring by finding the gradient from a graph of F (N) vs x (m) Use masses 50g to 250g, let g = 10ms -2 b)Repeat for: 2 springs in series 2 springs in parallel c)Record all data in a labelled table d)Plot all your data onto one graph (3 lines!) e)Compare your experimental values for k series and k parallel with the theoretical formula given below

11 See Wikipedia for theory!

12 F = kx F 0 x x Work kx Spring Potential Energy, E p

13

14 m k m x v Work done by a spring Energy Transformations

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