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The input motion and force of a can opener come from the user's hand rotating the handle. This motion is then transferred to the gear mechanism inside the can opener which applies force to the blade, allowing it to puncture the can. The output motion and force occur as the blade cuts around the can lid, driven by the user's continued rotation of the handle.
What else can I help you with?
Where are the input and output forces on a can opener?
The input force on a can opener is the force exerted by the user's hand to turn the handle. The output force is the force that the can opener applies to the can as it punctures and cuts through the lid.
What is the input motion and the output motion of a can opener?
The input motion of a can opener is the user turning the handle to rotate the cutting wheel. The output motion is the cutting wheel piercing through the can lid to open the can.
The output force is between the fulcrum and the input force for a bottle opener. Which class of lever is a bottle opener?
A bottle opener is a class 2 lever because the output force is between the fulcrum and the input force. In this case, the fulcrum is at one end, the input force is applied on the other end, and the output force is in the middle.
Where is the input and output force of a bottle opener?
The input force of a bottle opener is applied by the person using it to remove the bottle cap. This force is typically exerted by the hand or arm. The output force is the force exerted by the bottle opener on the bottle cap to lever it off the bottle.
What is the input force and output force of a can opener?
A "regular" can opener is a machine that combines a wedge (to cut through the top of the can) with a wheel and axle (which moves the can opener's cuttng wheel -- the wedge -- around the top of the can). The input force is provided by the operator, either by hand or via electric power. The output force is the separation of the metal of the top and the movement of the opener around the can. We also find that the can and the openers parts get a bit warmer with its use, and there are losses in the system due to friction.
Where are the input and output forces on a can opener?
The input force on a can opener is the force exerted by the user's hand to turn the handle. The output force is the force that the can opener applies to the can as it punctures and cuts through the lid.
What is the input motion and the output motion of a can opener?
The input motion of a can opener is the user turning the handle to rotate the cutting wheel. The output motion is the cutting wheel piercing through the can lid to open the can.
The output force is between the fulcrum and the input force for a bottle opener. Which class of lever is a bottle opener?
A bottle opener is a class 2 lever because the output force is between the fulcrum and the input force. In this case, the fulcrum is at one end, the input force is applied on the other end, and the output force is in the middle.
What is input and output force?
An output force is the force that is exerted from the input force to create motion of the resisting object. the input force can be less or more then the output force
Where is the input and output force of a bottle opener?
The input force of a bottle opener is applied by the person using it to remove the bottle cap. This force is typically exerted by the hand or arm. The output force is the force exerted by the bottle opener on the bottle cap to lever it off the bottle.
What is the output and input forces?
An output force is the force that is exerted from the input force to create motion of the resisting object. the input force can be less or more then the output force
If you exert a force of 20 newtons on a can opener and the opener exerts a force of 60newton on the can the ideal mechanica advantage of the can opener is?
The ideal mechanical advantage of the can opener is calculated as the ratio of the output force to the input force. In this case, it would be 60 newtons (output force) divided by 20 newtons (input force), which equals 3. This means that for every 1 newton of input force applied, the opener can exert 3 newtons of force on the can.
What is the input force and output force of a can opener?
A "regular" can opener is a machine that combines a wedge (to cut through the top of the can) with a wheel and axle (which moves the can opener's cuttng wheel -- the wedge -- around the top of the can). The input force is provided by the operator, either by hand or via electric power. The output force is the separation of the metal of the top and the movement of the opener around the can. We also find that the can and the openers parts get a bit warmer with its use, and there are losses in the system due to friction.
What is the input force and the output force of a can opener?
A "regular" can opener is a machine that combines a wedge (to cut through the top of the can) with a wheel and axle (which moves the can opener's cuttng wheel -- the wedge -- around the top of the can). The input force is provided by the operator, either by hand or via electric power. The output force is the separation of the metal of the top and the movement of the opener around the can. We also find that the can and the openers parts get a bit warmer with its use, and there are losses in the system due to friction.
Is a flip-top opener on a soda can a first-class lever?
yes, the fulcrum is in between the input and output force.
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 definiton of output force?
An output force is the force that is exerted from the input force to create motion of the resisting object. the input force can be less or more then the output force
