One way that we perceive weight is the normal force we experience from the ground. In physics problems, when you are asked to determine apparent weight, the quickest method is usually to compute the normal force provided by the "ground".
One way to experience a reduced apparent weight is to strap into a harness of ropes and have someone (or some weight) pull down on the other end like they do in theater or films. Another way is to jump into a swimming pool, where the water lifts up on you. Another possibility, which we explore in this problem, is to enter an environment where the "ground" is capable of moving, such as an elevator.
Part A
Suppose a person with a weight of 686 N is in an elevator which is accelerating downwards at a rate of 3.0 m/s2. What is the person's apparent weight?
Solution
System:
Person as a point particle.
Interactions:
External influences from the earth (gravity) and the floor of the elevator (normal force).
Model:
Approach:
Diagrammatic Representations
The physical picture and free body diagram for the person is:
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Physical Picture |
Free Body Diagram |
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Mathematical Representation
which leads to the form of Newton's 2nd Law for the y direction:
In our coordinates, the acceleration of the person is ay = -3.0 m/s2, giving:
Is it clear why the acceleration must have a minus sign?
This result for the normal force is less than the person's usual weight, in agreement with our expectation that the person should feel lighter while accelerating downward.
Part B
Suppose a person with a weight of 686 N is in an elevator which has been ascending at a constant rate of 1.0 m/s and is now slowing down at a rate of 3.0 m/s2. What is the person's apparent weight?
Solution
System, Interactions and Model:
As in Part A.
Approach:
Part C
Suppose a person with a weight of 686 N is in an elevator which is ascending, speeding up at a rate of 3.0 m/s2. What is the person's apparent weight?
Solution
System, Interactions and Model:
As in Part A.
Approach:
2 Comments
Anonymous
Part B slowing down ay = +3.0 m/s2
Anonymous
yield:
\begin{large}\[ N = ma_{y} + mg = \mbox{896 N} \]\end{large}