| Your Results | Global Average | |
|---|---|---|
| Questions | 5 | 5 |
| Correct | 0 | 3.36 |
| Score | 0% | 67% |
The mechanical advantage of a block and tackle is equal to which of the following?
the number of input forces |
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the number of pulleys |
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the number of loads |
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the number of connecting ropes |
Two or more pulleys used together constitute a block and tackle which, unlike a fixed pulley, does impart mechanical advantage as a function of the number of pulleys that make up the arrangement. So, for example, a block and tackle with three pulleys would have a mechanical advantage of three.
Tension is a force that does which of the following?
compacts an object |
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slows an object |
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heats up an object |
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stretches an object |
Tension is a force that stretches or elongates something. When a cable or rope is used to pull an object, for example, it stretches internally as it accepts the weight that it's moving. Although tension is often treated as applying equally to all parts of a material, it's greater at the places where the material is under the most stress.
Which of these is the formula for force?
F = am2 |
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F = a/m |
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F = m/a |
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F = ma |
Newton's Second Law of Motion states that "The acceleration of an object as produced by a net force is directly proportional to the magnitude of the net force, in the same direction as the net force, and inversely proportional to the mass of the object." This Law describes the linear relationship between mass and acceleration when it comes to force and leads to the formula F = ma or force equals mass multiplied by rate of acceleration.
| 14 ft. | |
| 1 ft. | |
| 0.88 ft. | |
| 3.5 ft. |
To balance this lever the torques at the green box and the blue arrow must be equal. Torque is weight x distance from the fulcrum so the equation for equilibrium is:
Rada = Rbdb
where a represents the green box and b the blue arrow, R is resistance (weight/force) and d is the distance from the fulcrum.Solving for da, our missing value, and plugging in our variables yields:
da = \( \frac{R_bd_b}{R_a} \) = \( \frac{5 lbs. \times 7 ft.}{10 lbs.} \) = \( \frac{35 ft⋅lb}{10 lbs.} \) = 3.5 ft.
Which of the following will increase the mechanical advantage of a second-class lever?
move the object being lifted farther away from the fulcrum |
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move the fulcrum between the force and the object being lifted |
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decrease the length of the lever |
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move the object being lifted closer to the fulcrum |
A second-class lever is used to increase force on an object in the same direction as the force is applied. This lever requires a smaller force to lift a larger load but the force must be applied over a greater distance. The fulcrum is placed at one end of the lever and mechanical advantage increases as the object being lifted is moved closer to the fulcrum or the length of the lever is increased. An example of a second-class lever is a wheelbarrow.