the frmula for pulley is th weight by its mass
The formula to calculate the mechanical advantage of a pulley system is MA 2 number of movable pulleys.
The formula for the percent efficiency of a pulley is (output work/input work) x 100%. It compares the output work (work done by the pulley) to the input work (work done on the pulley) to determine how efficient the pulley system is in transferring energy.
The tension formula for a pulley system is T 2F, where T is the tension in the rope and F is the force applied to the system.
The velocity ratio of a pulley system is the ratio of the rotational speed of the driving pulley to the driven pulley. It indicates how the speed of the driven pulley relates to the speed of the driving pulley. The formula is: Velocity Ratio = Diameter of driving pulley / Diameter of driven pulley.
The formula for the mechanical advantage of a pulley system is MA = 2 * (number of support ropes). This means that for every additional support rope, the mechanical advantage of the pulley system doubles.
The formula to calculate the mechanical advantage of a pulley system is MA 2 number of movable pulleys.
The formula for the percent efficiency of a pulley is (output work/input work) x 100%. It compares the output work (work done by the pulley) to the input work (work done on the pulley) to determine how efficient the pulley system is in transferring energy.
The tension formula for a pulley system is T 2F, where T is the tension in the rope and F is the force applied to the system.
The velocity ratio of a pulley system is the ratio of the rotational speed of the driving pulley to the driven pulley. It indicates how the speed of the driven pulley relates to the speed of the driving pulley. The formula is: Velocity Ratio = Diameter of driving pulley / Diameter of driven pulley.
The formula for the mechanical advantage of a pulley system is MA = 2 * (number of support ropes). This means that for every additional support rope, the mechanical advantage of the pulley system doubles.
The formula used to calculate mechanical advantage in a pulley system is: Mechanical Advantage Number of supporting ropes or strands.
The tension equation for a pulley system can be calculated using the formula T 2F, where T is the total tension in the system and F is the force applied to the pulley.
The circumference of a pulley is the distance around the outside edge of the pulley. It is calculated by using the formula C = πd, where C is the circumference and d is the diameter of the pulley. The circumference is important when determining the speed and distance traveled by a belt or rope running around the pulley.
For a pulley, it is driver RPM x driver diameter = driven RPM x driven diameter. Keep in mind that the diameter you should use is the diameter where the belt is riding in the pulley. For instance, an A belt in an AB pulley will ride lower in the pulley than it would in an A pulley. For sprockets, the formula is the same, but replace the diameter with # teeth. It looks like this. driver rpm x # teeth of driver sprocket = driven RPM x # teeth of driven sprocket
The pulley formula used to calculate the mechanical advantage of a system involving pulleys is MA 2n, where MA is the mechanical advantage and n is the number of pulleys in the system.
IMA of a pulley= the number of ropes supporting the load. An easier way is to count how many times the rope wraps around the wheel. :)
To accurately calculate the tension in a string passing over a pulley, you can use the formula T1 T2 2ma, where T1 is the tension on one side of the pulley, T2 is the tension on the other side of the pulley, m is the mass of the object being lifted, and a is the acceleration of the object.