Complex Power Work (J): W Force (N): F Distance (m): d Formulas:

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Complex Power Work (J): W Force (N): F Distance (m): d Formulas: Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t Complex Power Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Example 1 - A 1.2 HP winch can lift a 2350 kg Land Rover up 14.5 m into a tree in what time? (1 HP = 745.7 W) (373.18 ≈ 370 s)

Complex Power Work (J): W Force (N): F Distance (m): d Formulas: Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t Complex Power Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Example 2 - Gumi Baere drags a 45.1 kg box that has a coefficient of friction between it and the floor of .34 a distance of 16 m in 11.7 seconds. What is her power output? (205.5 ≈ 210 W)

What must be the power rating of a motor if it is to lift a 560 kg elevator up 3.2 m in 1.5 seconds? Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Work (J): W Force (N): F Distance (m): d Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t 11700 W

A. 75 HP winch can lift a car 5. 2 m in 37 seconds A .75 HP winch can lift a car 5.2 m in 37 seconds. What must be the mass of the car? 1 HP = 745.7 W Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Work (J): W Force (N): F Distance (m): d Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t 406 kg

Red Elk leads a dog team that can put out 2. 5 kW of power Red Elk leads a dog team that can put out 2.5 kW of power. They skid a 312 kg sled a distance of 340 m in 93 seconds. What must be the coefficient of friction? Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Work (J): W Force (N): F Distance (m): d Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t .22

A 150 HP tractor can drag a 350 kg load how far in a minute if the coefficient of friction between the load and the ground is .78. 1 HP = 745.7 W Formulas: F = mg (Lifting) F = mg (Dragging) P = W/t (Power) W = Fd (Work) Work (J): W Force (N): F Distance (m): d Mass (kg): m Coeff. of Friction: μ Power (W) : P Time (s): t 2500 m