The only way the bag of apples can have zero acceleration is that the sum of forces
on it is zero. The 20-N downward gravitational force on it must be exactly canceled
by some upward force of 20-N. That's the tension in the rope.
The tension in the rope would be equal to the weight of the apples, which is 20 N, at rest. This is because the rope has to support the weight of the bag of apples without any other external forces acting on it.
Same 20 N
The tension in the rope would be equal to the weight of the bag of apples, which is 20 N. This is because the rope must exert an upward force equal to the weight of the bag to keep it at rest.
The tension at every point in the rope must be 20N, and it must exert 20N of upward vertical force on the top of the bag. If there's any point in the whole arrangement where the upward and downward forces are not exactly equal, then the mass at that point must be accelerating up or down.
The rope tension will increase when the block is accelerated upward. This is because the tension in the rope must now counteract not only the weight of the block but also the additional force due to the block's acceleration.
At rest, tension in the string and weight of the bob are the two forces both equal and opposite. During its displaced position, the weight of the bod, tension of the string and restoring force all the three would act on it
Surface tension acts perpendicular to the surface of the liquid, attempting to minimize the surface area and causing the liquid to form into droplets or exhibit a meniscus in a container. This force is due to the cohesive forces between the liquid molecules at the surface.
20 N
20 N
The tension in the rope would be equal to the weight of the bag of apples, which is 20 N. This is because the rope must exert an upward force equal to the weight of the bag to keep it at rest.
The only way the bag of apples can have zero acceleration is that the sum of forces on it is zero. The 20-N downward gravitational force on it must be exactly canceled by some upward force of 20-N. That's the tension in the rope.
The only way the bag of apples can have zero acceleration is that the sum of forces on it is zero. The 20-N downward gravitational force on it must be exactly canceled by some upward force of 20-N. That's the tension in the rope.
The only way the bag of apples can have zero acceleration is that the sum of forces on it is zero. The 20-N downward gravitational force on it must be exactly canceled by some upward force of 20-N. That's the tension in the rope.
The tension at every point in the rope must be 20N, and it must exert 20N of upward vertical force on the top of the bag. If there's any point in the whole arrangement where the upward and downward forces are not exactly equal, then the mass at that point must be accelerating up or down.
The tension at every point in the rope must be 20N, and it must exert 20N of upward vertical force on the top of the bag. If there's any point in the whole arrangement where the upward and downward forces are not exactly equal, then the mass at that point must be accelerating up or down.
20 N, N is a weight(Force) therefore gravity is already included.
Four apples unless it is intentionally a trick question and the rest doesn't count as apples- then it would be two and a crappy example of a logic question.
YES. eat nothing but apples the rest of your life.
Increasing the duration of the rest period increased the duration of the subsequent maximal tension.