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What else can I help you with?
Where can you find a picture of a third class lever?
You can find pictures of third class levers by searching online on educational websites or science resources, such as textbooks or online science lesson materials. Additionally, you may find examples of third class levers in everyday objects like a broom, shovel, or fishing rod.
How do you find the input force and output force?
let the input force be F1,and the distance between point of application of input force and the lever point is x1,similarly if output force iis F2,and distance of it's point of apllication is x2,then efficiency of the lever is (F2*x2)/(F1*x1) actually F*x gives the work done,and efficiency of any machine is output work/input work
How do you find the input force for a lever?
Ok, so a lever can be broken up into two 'sides' with a fulcrum in the middle. This idea simply utilizes the laws set forth for torque, or Force*distance. Static equilibrium (which would be when you input enough force on one side of the lever to balance the other) states the followingF1*D1 = F2*D2Starting from the left side of the lever, for have a force (F1) multiplied by the distance between that force and the fulcrum (D1). This can be set equal to the distance between the fulcrum and the second force, with this distance denoted as D2. If you want to know the input force, you need to know the other force, and both distances. Then you can simply divide. For example say want to know your input force, F2.F2 = (F1*D1)/D2Hope this helps
What type of lever do you find most often in the human body?
The most commonly found lever in the human body is a third-class lever. This type of lever has the effort force located between the fulcrum and the resistance force. An example is the bicep muscle lifting a forearm.
How do you find output force if you are only given efficiency and work?
You can find the output force by dividing the work done by the input force by the efficiency. This formula is: Output Force = Work / (Input Force * Efficiency).
If a lever with a mechanical advantage of 13 is used to move a rock with a force of 845N what is the imput force?
To find the input force, divide the output force (845N) by the mechanical advantage (13). So, the input force = 845N / 13 = 65N.
How do you find theoretical mechanical advantage?
The theoretical mechanical advantage is calculated by dividing the effort arm (distance from the fulcrum to the point where the input force is applied) by the resistance arm (distance from the fulcrum to the point where the output force is exerted) of a lever system. It provides insight into the effectiveness of a lever in amplifying force.
How do you find the output force of an object?
I'm not sure how to tell you how to find the output force of an object, any suggestions?
What are the 3 classes of levers?
Levers are classified into three types (first-class, second-class, and third-class) depending on the relative position of the fulcrum (pivot point), the point of applied (input) force, and the location of the load (output force). In a first-class lever, the fulcrum is between the input force and the output force, and the load is moved in the opposite direction of the applied force. Placing the fulcrum closer to the load gives an advantage of force (less force needed to move the load a shorter distance), while a fulcrum closer to the point of applied force gives an advantage of distance (the load is moved a greater distance but more applied force is needed). First-class levers include a crowbar, using a hammer's claw end to remove a nail, and a pair of scissors. In a second-class lever, the load is between the fulcrum and the point of applied force, so both forces move in the same direction. Less force is needed to move the load, but the load does not move as far as the direction over which the input force must be applied. Examples include the wheelbarrow, a bottle opener, and a door on its hinges. In a third-class lever, the input force is applied between the fulcrum and the load, and both move in the same direction. The amount of applied force is always greater than the output force of the load, but the load is moved a greater distance than that over which the input force is applied. Examples include a hammer driving a nail and the forearm of a person swinging a baseball bat. If you want to find out any more, go to: http://www.technologystudent.com/forcmom/lever1.htm :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :) :)
How do you find the output force of a wheel and axle if you already know the input force?
To find the output force of a wheel and axle, you can use the formula: Output Force = Input Force * (Radius of Wheel / Radius of Axle). The output force is determined by the ratio of the radii of the wheel and axle, with the input force determining the overall scaling factor.
How do you find output force?
Output force can be found by multiplying the input force by the mechanical advantage of a machine. The mechanical advantage is the factor by which a machine multiplies the input force to generate the output force. The formula for calculating mechanical advantage is output force/input force.
What first degree lever can you find on a playground?
A see-saw is a first class lever that can be found in playgrounds.
