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When using the wheel and axle the input force moves through a greater distance than the output force?
Wiki User
∙ 11y ago
True
Wiki User
∙ 11y ago
In a wheel and axle system, the input force applied over a larger distance rotates the wheel, which has a larger radius than the axle. This causes the axle, where the output force is exerted, to rotate over a smaller distance but with increased force due to the principle of mechanical advantage.
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If you exert an input force over a greater distance than the distance exerted by the output force for an ideal machine compare the size of the input and output forces.?
In an ideal machine, if you exert an input force over a greater distance than the output force, the input force will be smaller than the output force. This is because work input is equal to work output in an ideal machine, and work is calculated as force times distance. Therefore, if the input force acts over a greater distance, the output force must be larger to balance the work done.
If you exert an input force over a greater distance than the distance exerted by the output force for an ideal machine compare the size of the input and output forces?
In an ideal machine, the input force will be smaller than the output force when the input force is exerted over a greater distance than the output force. This is because work input and work output must be equal in an ideal machine, and since work = force x distance, a smaller input force over a greater distance will result in a larger output force over a shorter distance to maintain equilibrium.
The output force of a rake is greater than the input force?
This is possible when using a lever system with the rake, where the input force is applied over a shorter distance but results in a greater output force over a longer distance. The mechanical advantage gained from the lever system allows for the output force to be greater than the input force in this scenario.
For a machine with a mechanical advantage of 3 how does the distance through which the output force is exerted differ from the distance through which the input force is exerted?
In a machine with a mechanical advantage of 3, the output force is exerted over a shorter distance compared to the distance over which the input force is exerted. The output force is three times greater than the input force but is exerted over a third of the distance traveled by the input force due to the principle of work conservation.
If a mechanical advantage of a simple machine is increased how does the distance of the input force compare to the distance of the output force?
If the mechanical advantage of a simple machine is increased, the distance the input force must be applied decreases in relation to the output force. This means that you can exert less input force over a longer distance to achieve a greater output force over a shorter distance.
If you exert an input force over a greater distance than the distance exerted by the output force for an ideal machine compare the size of the input and output forces.?
In an ideal machine, if you exert an input force over a greater distance than the output force, the input force will be smaller than the output force. This is because work input is equal to work output in an ideal machine, and work is calculated as force times distance. Therefore, if the input force acts over a greater distance, the output force must be larger to balance the work done.
If you exert an input force over a greater distance than the distance exerted by the output force for an ideal machine compare the size of the input and output forces?
In an ideal machine, the input force will be smaller than the output force when the input force is exerted over a greater distance than the output force. This is because work input and work output must be equal in an ideal machine, and since work = force x distance, a smaller input force over a greater distance will result in a larger output force over a shorter distance to maintain equilibrium.
What is the definition of output distance?
input distance- the distance the input force acts through
The output force of a rake is greater than the input force?
This is possible when using a lever system with the rake, where the input force is applied over a shorter distance but results in a greater output force over a longer distance. The mechanical advantage gained from the lever system allows for the output force to be greater than the input force in this scenario.
For a machine with a mechanical advantage of 3 how does the distance through which the output force is exerted differ from the distance through which the input force is exerted?
In a machine with a mechanical advantage of 3, the output force is exerted over a shorter distance compared to the distance over which the input force is exerted. The output force is three times greater than the input force but is exerted over a third of the distance traveled by the input force due to the principle of work conservation.
If a mechanical advantage of a simple machine is increased how does the distance of the input force compare to the distance of the output force?
If the mechanical advantage of a simple machine is increased, the distance the input force must be applied decreases in relation to the output force. This means that you can exert less input force over a longer distance to achieve a greater output force over a shorter distance.
What is the formula of each simple machine by getting the work exerted by the machine?
The formula for work exerted by each simple machine is: Lever: Work = Input force × Input distance = Output force × Output distance Inclined plane: Work = Input force × Input distance = Output force × Output distance Pulley: Work = Input force × Input distance = Output force × Output distance Wheel and axle: Work = Input force × Input radius = Output force × Output radius Wedge: Work = Input force × Input distance = Output force × Output distance Screw: Work = Input force × Input distance = Output force × Output distance
What is the difference between mechanical advantage and Efficiency?
Mechanical advantage refers to the ratio of output force to input force in a simple machine or system. Efficiency, on the other hand, is a measure of how well energy is converted from input to useful output. Mechanical advantage focuses on force ratios, while efficiency assesses energy losses.
If a simple machine provide sn increased output force what happens to the output distance?
If a simple machine provides an increased output force, then the output distance will decrease. This is due to the principle of work conservation, where input work equals output work. As the force increases, the distance through which the force acts decreases proportionally to maintain the balance.
What is a force magnifier and a distance magnifier?
A force magnifier is a mechanism that amplifies the input force to produce a greater output force. It is typically used to make it easier to lift or move heavy objects. On the other hand, a distance magnifier is a mechanism that amplifies the distance over which a force is applied to achieve greater output displacement. These magnifiers are used in various mechanical systems to enhance efficiency and performance.
Why is the ima always greater than the ama for an inclined plane?
In an inclined plane, the mechanical advantage (MA) is always less than 1 because the input force needed to lift an object is greater than the output force. This is due to the trade-off between the distance over which the force is applied (input distance) and the vertical distance the object is lifted (output distance). The ideal mechanical advantage (IMA) assumes a frictionless system and is calculated based on the ratio of input distance to output distance, resulting in a value always greater than the AMA.
What is the output force in a first class lever?
The output force in a first class lever is dependent on the input force and the distance from the fulcrum to the input force. By applying an input force at a certain distance from the fulcrum, the lever can generate an output force at a different distance on the other side of the fulcrum. The output force can be calculated using the lever principle: Input force x Input distance = Output force x Output distance.
