Input force refers to the force applied to a system, while output force is the force exerted by the system. Load force, on the other hand, is the external force that opposes the motion or function of a system. In summary, input and output forces are internal forces within a system, while load force is an external force acting on the system.
The weight of a load is the force of gravity acting on an object, while the amount of effort needed to lift it is the force a person applies to overcome that weight. The difference depends on factors like the weight of the load, the distance it needs to be lifted, and the efficiency of the lifting mechanism.
the difference is the position of the fulcrum. a first class lever has the fulcrum between the lode and applied force. a second class lever has the load between the fulcrum and applied force. A third class lever has the applied force between load and fulcrum. The load happens to be the thing that you are affecting in the system. On a seesaw the load and applied force changes as either kid goes up, but the lower kid is always the force and upper is the load with the fulcrum in the middle. this happens to be a first class lever. a second class lever could be a bottle cap opener with the fulcrum at the end the bottle cap(load) in the middle and you pushing (force) on the other. a third class lever are like tweezers with the fulcrum on the closed end, force is you pushing in the middle, and affected load is whatever you pick up. There are also compound levers like nailclippers, but by diagramming the whole system it should be pretty easy to discover that it is a first class lever. It's compund because of the use of a lever system
A dead load is a permanent force, acting on a structure.This includes the weight of the structure itself.A live load is a changing, or non-permanent force acting on a structure.This includes the force of the wind and the weight of things that are in or on a structure.
The applied load is the force acting on a structure or material. The relationship between the applied load and force is direct - as the applied load increases, the force applied to the structure also increases. This relationship is described by Newton's second law of motion, F = m*a, where F is the force, m is the mass, and a is the acceleration.
The load or resistance is positioned between the fulcrum and the input force on a lever. The input force is applied on one side of the fulcrum, while the load is typically located on the opposite side. The lever uses this arrangement to magnify the force applied to move the load.
Axial load (or thrust load) is a force applied parallel to the longitudinal axis, whereas, a radial load is a force applied transverse to this longitudinal axis.
The only difference between a shock load and a gradually applied load is something called an impulse; defined as the integral of a force with respect to time. When a force is applied to a rigid body it changes the momentum of that body. A small force applied for a long time can produce the same momentum change as a large force applied briefly, because it is the product of the force and the time for which it is applied that is important.
'Voltage' is simply another term for 'potential difference', and an electromotive force is the open-circuit, or no-load, potential difference of a source such as a battery or generator.
no difference
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The weight of a load is the force of gravity acting on an object, while the amount of effort needed to lift it is the force a person applies to overcome that weight. The difference depends on factors like the weight of the load, the distance it needs to be lifted, and the efficiency of the lifting mechanism.
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the difference is the position of the fulcrum. a first class lever has the fulcrum between the lode and applied force. a second class lever has the load between the fulcrum and applied force. A third class lever has the applied force between load and fulcrum. The load happens to be the thing that you are affecting in the system. On a seesaw the load and applied force changes as either kid goes up, but the lower kid is always the force and upper is the load with the fulcrum in the middle. this happens to be a first class lever. a second class lever could be a bottle cap opener with the fulcrum at the end the bottle cap(load) in the middle and you pushing (force) on the other. a third class lever are like tweezers with the fulcrum on the closed end, force is you pushing in the middle, and affected load is whatever you pick up. There are also compound levers like nailclippers, but by diagramming the whole system it should be pretty easy to discover that it is a first class lever. It's compund because of the use of a lever system
sudden load differ from impact load by the velocity of loading
The primary difference between first-order and second-order levers lies in the arrangement of the load, effort, and fulcrum. In a first-order lever, the fulcrum is positioned between the load and the effort, as seen in a seesaw. In contrast, a second-order lever has the load situated between the fulcrum and the effort, exemplified by a wheelbarrow. This configuration affects the mechanical advantage and the way force is applied to lift the load.
Because an electromotive force is a potential difference (voltage) -specifically, an electromotive force is the open-circuit or no-load potential difference of a source such as a battery or generator.