To lift a 45 kg mass, you would need to apply a force equal to the gravitational force acting on the mass, which is approximately 441 Newtons (45 kg * 9.81 m/s^2). This force would need to be greater than the weight of the mass to overcome gravity and lift the object upward.
To lift a mass of 40 kilograms on Earth, you would need to exert a force equal to the weight of that mass, which is approximately 392 newtons (9.8 m/s^2 * 40 kg). This is due to Earth's gravitational pull on the mass.
To calculate the work done when lifting an object, you can use the formula: work = force × distance. The force required to lift an object is equal to its weight, which is mass × gravity. So, you would need to know the mass of the object to calculate the work done when lifting it 1600 meters.
If the weight is 300 pounds, you will need to apply a force of at least 300 pounds to lift it against the force of gravity. This force is known as the weight of the object.
To lift 200 pounds of weight, you would need to apply a force equal to the weight being lifted, which in this case is 200 pounds. This is because the force needed to lift an object against gravity is equal to its weight.
To lift a 45 kg mass, you would need to apply a force equal to the gravitational force acting on the mass, which is approximately 441 Newtons (45 kg * 9.81 m/s^2). This force would need to be greater than the weight of the mass to overcome gravity and lift the object upward.
To lift a mass of 40 kilograms on Earth, you would need to exert a force equal to the weight of that mass, which is approximately 392 newtons (9.8 m/s^2 * 40 kg). This is due to Earth's gravitational pull on the mass.
To calculate the work done when lifting an object, you can use the formula: work = force × distance. The force required to lift an object is equal to its weight, which is mass × gravity. So, you would need to know the mass of the object to calculate the work done when lifting it 1600 meters.
If the weight is 300 pounds, you will need to apply a force of at least 300 pounds to lift it against the force of gravity. This force is known as the weight of the object.
Assuming you need a metric ton, that's 1000 kilograms. To lift that, you need a FORCE of 9800 newtons. Force is related to pressure by: pressure = force / area, so the answer to the original question would depend, over what area the force is applied.
To lift 200 pounds of weight, you would need to apply a force equal to the weight being lifted, which in this case is 200 pounds. This is because the force needed to lift an object against gravity is equal to its weight.
Using 3 pulleys in a block and tackle system reduces the force required to lift an object by one-third. Therefore, to lift 100 lbs with 3 pulleys, you would need to apply approximately 33.33 lbs of force.
It depends on how you want to move it. To lift it, the force will need to be greater than the weight of the elephant. To push it, you will need sufficient force to both displace its mass and overcome the friction between the elephant's feet or body and the surface it rests on. I think before I did anything else, I'd entice it with an apple. Dead elephants I leave to Phyicists who have nothing better to do.
As gauss is a measure of magnetic attraction and 55 pounds is a mass the question is difficult to answer, please give more detail of what you intend to lift
With a fixed pulley, the effort force would be equal to the weight being lifted (300kg) in this case. So, to lift 300kg using a fixed pulley, you would need to apply an effort force of 300 kg-force.
You need two forces, which you simply add together: 1) The force required simply to support the weight. Multiply the mass times the gravity. 2) The force required to accelerate it. Find this force with Newton's Second Law. Then just add the two forces together.
To lift 100 pounds against gravity, you would need to apply a force of 100 pounds. This accounts for overcoming the force of gravity pulling the object downward. If the object is being lifted vertically at a constant speed, the force required would be equal to the weight of the object.