Determine the force needed to lift a load with a screw jack

What is the force required to lift a load using a screw jack?

The handle of the screw jack is 35 cm long and the pitch of the screw is 0.5cm. What force must be applied at the end of the handle when lifting a load of 2000 N if the efficiency of the jack is 30%?

Answer:

To lift a 2000N load with a screw jack having a handle length of 35cm, a pitch of 0.5cm, and an efficiency of 30%, a force of approximately 15.2N needs to be applied to the end of the handle.

When dealing with a screw jack, the force required to lift a load can be calculated based on the handle length, screw pitch, load weight, and the efficiency of the jack. In this scenario, we have a handle length of 35cm, a screw pitch of 0.5cm, and a load weight of 2000N with an efficiency of 30%.

The first step is to determine the Mechanical Advantage (MA) of the screw jack using the formula MA = 2πL/P, where L is the handle length and P is the pitch of the screw. So, MA = 2π(35cm)/0.5cm = 140π.

Next, we calculate the Actual Mechanical Advantage (AMA) based on the efficiency of the jack, which is AMA = Efficiency x Ideal Mechanical Advantage (IMA). Substituting the values, AMA = 30/100 * 140π = 42π.

Finally, we find the force required by dividing the load weight by the Actual Mechanical Advantage: Force = Load / AMA = 2000N / 42π ≈ 15.2N. Therefore, a force of approximately 15.2N needs to be applied to the end of the handle to lift the 2000N load, considering the efficiency of 30%.

Understanding the calculations and concepts behind the force required to lift a load using a screw jack can help in determining the necessary input force for various weight lifting scenarios.

← Plate boundaries divergent vs transform Net force and equilibrium exploring the dynamics of forces →