The tension in the crane's cable would be equal to the force being lifted, in this case, 1000 N. This is due to the fact that the tension in the cable must match the force being lifted in order to maintain equilibrium.
The tension force on a mass of 1000 kg will depend on the context in which the mass is placed. It could be affected by factors such as acceleration, gravitational force, and any other external forces acting on the mass. Without additional information, it is not possible to provide a specific value for the tension force.
The work done by the crane is given by the formula: Work = Force x Distance. Assuming the force required to lower the material is equal to its weight, the work done would be equal to the weight (Force) multiplied by the distance. If the weight of the material is known, multiply it by 150 meters to find the work done in lowering the material.
The work done in lifting the box is given by W = force x distance = 100 N x 10 m = 1000 J. Since power is the rate at which work is done, the power used in lifting the box is P = work / time = 1000 J / 5 sec = 200 Watts.
According to Newton's third law of motion, the force exerted by the ball on the bat would be equivalent to the force exerted by the bat on the ball. Therefore, if the bat hits the ball with 1000 N of force, the ball would also hit back on the bat with 1000 N of force.
1000 newtons is equivalent to approximately 224.81 pounds of force.
The tension force on a mass of 1000 kg will depend on the context in which the mass is placed. It could be affected by factors such as acceleration, gravitational force, and any other external forces acting on the mass. Without additional information, it is not possible to provide a specific value for the tension force.
try it and see
The work done by the crane is given by the formula: Work = Force x Distance. Assuming the force required to lower the material is equal to its weight, the work done would be equal to the weight (Force) multiplied by the distance. If the weight of the material is known, multiply it by 150 meters to find the work done in lowering the material.
The work done in lifting the box is given by W = force x distance = 100 N x 10 m = 1000 J. Since power is the rate at which work is done, the power used in lifting the box is P = work / time = 1000 J / 5 sec = 200 Watts.
On earth, the weight of 1 kilogram is approx. 9.8 newtons (2.20462 pounds).The total tension in all of the cables is the weight of the passenger car = (1,000 x 9.8) =9,800 newtons (2,205 pounds) rounded.
According to Newton's third law of motion, the force exerted by the ball on the bat would be equivalent to the force exerted by the bat on the ball. Therefore, if the bat hits the ball with 1000 N of force, the ball would also hit back on the bat with 1000 N of force.
1000 newtons is equivalent to approximately 224.81 pounds of force.
What happens is that the resistance of 1100 newton is the MAXIMUM resistance. If a force of 1000 newton is applied, the actual resistance will also be 1000 newton. If a force greater than the maximum force of friction is applied, the object will start to move.
newtons / 9.80665 = kilograms force, then * 1000 = grams force So > (5.12244898 / 9.80665) * 1000 = 522.34 grams force (per meter square)
If a 90 kg weightlifter exerts a 1000 N force upwards against a 50 kg barbell, the NET vertical force acting on the barbell is 1000 N. It does not matter how heavy the weightlifter or the barbell might be.
Force = mass * acceleration Since the only force acting on the elevator is gravity, the force is 1000*9.81 = 981N Towards the ground Note that it is essential to put the direction that the force is acting as it is a vector quantity.
The force exerted can be calculated by multiplying the pressure by the area: Force = Pressure x Area. In this case, the force would be 10,000 Newtons (1000 Pa x 10 m²).