28
Given:
Question:
What is the maximum number of passengers that can ride in the elevator?
The Process:
Step-1: convert hp to watts
For an approximate result, multiply the power value in horsepower by 746 .
[tex]\boxed{ \ 40 \ hp \times 746 \ \frac{watts}{hp} = 29828 \ watts \ }[/tex]
Step-2: calculate the amount of work from the elevator
The relationship between power (P), work (W), and time (t) can be formulated as follows.
[tex]\boxed{ \ P = \frac{W}{t} \ }[/tex] [tex]\rightarrow \boxed{ \ W = Pt \ }[/tex]
[tex]\boxed{ \ W = (29828 \ watts)(16.0 \ seconds) \ }[/tex]
So, the work that can be carried out by the elevator is 477248 joules.
Step-3: calculate the net force
The relationship between work (W), the net force (∑F), and displacement (d) can be formulated as follows.
[tex]\boxed{ \ W = (\Sigma F)(d) \ }[/tex] [tex]\rightarrow \boxed{ \ \Sigma F = \frac{W}{d} \ }[/tex]
[tex]\boxed{ \ \Sigma F = \frac{477248 \ J}{20.0 \ m} \ }[/tex]
Thus, the net force of the elevator is 23862.4 N.
Final step: calculate the maximum number of passengers that can ride in the elevator
We prepare the weight of the elevator
[tex]\boxed{ \ w = (600 \ kg)(9.8 \ m/s^2) = 5880 \ N \ }[/tex]
The net force of the elevator is the sum of the weight of the elevator and the passengers.
∑F = the weight of the lift + the weight of the passengers
23862.4 = 5880 + the weight of the passengers
The weight of the passengers = 17982.4 N.
Then we calculate the mass of the passengers.
[tex]\boxed{ \ m = \frac{w}{g} \ } \rightarrow[/tex] [tex]\boxed{ \ \Sigma m = \frac{17982.4}{9.8} = 1834.94 \ kg \ }[/tex]
Finally, the mass of the passengers is divided by the average mass of a passenger.
[tex]\boxed{ \ N = \frac{1834.94 \ kg}{65 \ kg/person} \ }[/tex] [tex]\boxed{ \ N \approx 28.23 \ }[/tex]
Thus, the maximum number of passengers that can ride in the elevator is approximately 28.
If 29 passengers enter the elevator right away, a small alarm signals an overload immediately ringing. The elevator will not move up.
