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Terminal velocity of falling objects in water depends on the object's shape, size, and density, as well as the water's viscosity. Generally, small objects like spheres have lower terminal velocities due to less drag, while larger or less streamlined objects will have higher terminal velocities. The terminal velocity is reached when the force of gravity on the object is balanced by the drag force acting in the opposite direction.
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What is the terminal velocity of water and how does it impact the motion of objects falling through it?
The terminal velocity of water is the maximum speed at which an object can fall through water due to the resistance of the water. It impacts the motion of objects falling through water by slowing them down until they reach a constant speed where the force of gravity is balanced by the resistance of the water.
What is terminal velocity and how does it apply universally to all objects falling through a medium?
Terminal velocity is the maximum speed that an object reaches when falling through a medium, like air or water, due to the balance between gravity pulling it down and air resistance pushing against it. This concept applies universally to all objects falling through a medium, as they will eventually reach a constant speed where the force of gravity is equal to the force of air resistance.
What is terminal velosity?
Terminal velocity is the constant speed that a freely falling object reaches when the drag force (air resistance) equals the force of gravity pulling it downwards. At this point, the object no longer accelerates and falls at a constant speed. Terminal velocity varies depending on the object's size, mass, and shape, as well as the medium through which it is falling (such as air or water).
What is terminal velocity dependent upon?
Terminal velocity is dependent on the drag force acting on an object and its weight. As an object falls through a fluid (like air or water), the drag force increases until it balances out the weight of the object, causing it to stop accelerating and to fall at a constant speed known as terminal velocity. The shape and size of the object, as well as the density of the fluid it is falling through, also impact its terminal velocity.
What is the terminal velocity of a falling bullet?
The Terminal velocity depends on a few properties of the object falling and the medium that the object is falling through. 1. The mass of the object F=m*a where in this case a = gravity A balloon the size of a bowling ball and a bowling ball do not have the same terminal velocity due to the mass of each. The balloon is a very small mass and the resulting force due to gravity is also very small. Therefore, the wind friction required to counter the gravitational force is very small. The bowling ball has a rather large mass in comparison and the wind friction required to counter its gravitational force is large, so the falling/terminal velocity is much higher. 2. The shape of the object A flat piece of paper will float down more slowly than a piece of paper that is crumpled up in a ball. 3. The orientation of the object Facing one way the object may present a larger surface area to the oncoming wind slowing it down. Facing another way, a smaller surface area may be presented to the wind allowing the object to fall faster. 4. The viscosity of the medium the object is falling through Oil is less dense than water, but it is more viscous and objects fall/sink slower through oil than through water. There may be a couple of others. So what is falling through what medium? Old answer: 120 mph
What is the terminal velocity of water and how does it impact the motion of objects falling through it?
The terminal velocity of water is the maximum speed at which an object can fall through water due to the resistance of the water. It impacts the motion of objects falling through water by slowing them down until they reach a constant speed where the force of gravity is balanced by the resistance of the water.
Why is terminal velocity in water less than the terminal velocity in air?
The incompressibility, inertia and relatively higher viscosity of water make it difficult to displace, so its reactive forces on the falling object are greater; hence the terminal velocity is reduced.
How would the terminal velocity of an object falling towards earth differ than the terminal velocity of the same object falling through water?
because water has higher viscosity than air so resisting the movement of the body in it more than air so decreasing the velocity
What is terminal velocity and how does it apply universally to all objects falling through a medium?
Terminal velocity is the maximum speed that an object reaches when falling through a medium, like air or water, due to the balance between gravity pulling it down and air resistance pushing against it. This concept applies universally to all objects falling through a medium, as they will eventually reach a constant speed where the force of gravity is equal to the force of air resistance.
What is terminal velosity?
Terminal velocity is the constant speed that a freely falling object reaches when the drag force (air resistance) equals the force of gravity pulling it downwards. At this point, the object no longer accelerates and falls at a constant speed. Terminal velocity varies depending on the object's size, mass, and shape, as well as the medium through which it is falling (such as air or water).
What is the terminal velocity of a water droplet 312 miles wide?
Terminal velocity of an object depends on its size, shape, and weight. For a water droplet that is 312 miles wide, the terminal velocity would be extremely slow, approaching zero, as its size would create significant air resistance and prevent it from falling at any noticeable speed.
What is terminal velocity dependent upon?
Terminal velocity is dependent on the drag force acting on an object and its weight. As an object falls through a fluid (like air or water), the drag force increases until it balances out the weight of the object, causing it to stop accelerating and to fall at a constant speed known as terminal velocity. The shape and size of the object, as well as the density of the fluid it is falling through, also impact its terminal velocity.
Why is the terminal velocity in water less than the terminal velocity in air?
More resistance, caused by a greater density.
Is terminal velocity the same in water as in air?
no
What is the terminal velocity of a falling bullet?
The Terminal velocity depends on a few properties of the object falling and the medium that the object is falling through. 1. The mass of the object F=m*a where in this case a = gravity A balloon the size of a bowling ball and a bowling ball do not have the same terminal velocity due to the mass of each. The balloon is a very small mass and the resulting force due to gravity is also very small. Therefore, the wind friction required to counter the gravitational force is very small. The bowling ball has a rather large mass in comparison and the wind friction required to counter its gravitational force is large, so the falling/terminal velocity is much higher. 2. The shape of the object A flat piece of paper will float down more slowly than a piece of paper that is crumpled up in a ball. 3. The orientation of the object Facing one way the object may present a larger surface area to the oncoming wind slowing it down. Facing another way, a smaller surface area may be presented to the wind allowing the object to fall faster. 4. The viscosity of the medium the object is falling through Oil is less dense than water, but it is more viscous and objects fall/sink slower through oil than through water. There may be a couple of others. So what is falling through what medium? Old answer: 120 mph
What causes a freely falling object to stop acclerating and continue to fall at its final velocity?
The answer lies in air resistance, which sets a limit, the so-called terminal velocity, on the speed of a falling object. Air resistance creates drag, a real physical phenomenon associated with objects moving through a fluid. You experience drag riding a bike. Imagine how much drag is on a jet airliner! A boat is affected by drag moving through water. Aerodynamics and hydrodynamics address these issues.
What is the speed of a diver hitting the water from a height of ten meters?
Terminal velocity
