When it reaches terminal velocity it is not accelerating. According to newton's 2nd law, if acceleration = 0, then Net force = 0 If we call up to be positive direction Net force = -mg + Force air resistance = 0 So the air resistance force would be equal in magnitude to m*g and opposite in direction. m is mass of object, g is about 9.81 for objects near earths surface
Terminal velocity is typically reached within 10-12 seconds when falling from a height, depending on factors such as air resistance and the height of the fall.
Terminal velocity for a feather will be considerably lower than the terminal velocity of a bullet. The size and shape of the object will play an important role. While objects dropped from a given height in a vacuum will fall to earth at the same velocity, the resistance caused by atmosphere will be different for different objects.
An egg would typically reach terminal velocity in about 12 to 15 seconds when dropped from a significant height. Terminal velocity is the point at which the force of gravity on the egg is equal to the force of air resistance, causing the egg to no longer accelerate.
The terminal velocity for a mouse is estimated to be around 10 mph (16 kph). This means that when a mouse falls from a height, it will reach a maximum speed of about 10 mph before air resistance balances the force of gravity.
The velocity-time graph for a body dropped from a certain height would show an initial spike in velocity as the object accelerates due to gravity, reaching a maximum velocity when air resistance equals the force of gravity. After this, the velocity would remain constant, representing free fall with a terminal velocity. When the object hits the ground, the velocity suddenly drops to zero.
Terminal velocity is typically reached within 10-12 seconds when falling from a height, depending on factors such as air resistance and the height of the fall.
Terminal velocity for a feather will be considerably lower than the terminal velocity of a bullet. The size and shape of the object will play an important role. While objects dropped from a given height in a vacuum will fall to earth at the same velocity, the resistance caused by atmosphere will be different for different objects.
An egg would typically reach terminal velocity in about 12 to 15 seconds when dropped from a significant height. Terminal velocity is the point at which the force of gravity on the egg is equal to the force of air resistance, causing the egg to no longer accelerate.
The terminal velocity for a mouse is estimated to be around 10 mph (16 kph). This means that when a mouse falls from a height, it will reach a maximum speed of about 10 mph before air resistance balances the force of gravity.
The velocity-time graph for a body dropped from a certain height would show an initial spike in velocity as the object accelerates due to gravity, reaching a maximum velocity when air resistance equals the force of gravity. After this, the velocity would remain constant, representing free fall with a terminal velocity. When the object hits the ground, the velocity suddenly drops to zero.
Terminal velocity
Terminal velocity is the maximum speed an object reaches when falling through a fluid (such as air) due to balance between gravity and air resistance. The exact height you need to reach to achieve terminal velocity varies depending on factors like your weight, body position, and the specific characteristics of the air around you. In a general sense, skydivers typically reach terminal velocity within about 10-12 seconds of freefall from an altitude of around 12,000 feet.
The highest velocity ever reached by a falling object is the terminal velocity, which varies based on factors like the object's mass and air resistance. In the absence of air resistance, objects will continue to accelerate due to gravity until they reach a velocity where air resistance equals the force of gravity.
The maximum speed a cat can reach when falling from a great height, also known as its terminal velocity, is around 60 miles per hour.
Yes, you can survive terminal velocity if you have the proper equipment, such as a parachute, to slow down your fall before reaching the ground. Terminal velocity is the maximum speed an object reaches when falling through the air, and with the right precautions, it is possible to survive a fall from this height.
The acceleration of an object that falls from a certain height does not depend on its mass, in an ideal condition with no air resistance. The value of acceleration is the acceleration due to gravity, which is 9.81 m s-2. <><><><><> However, in this case, air resistance is going to matter. 12000 feet is high enough for the person to accelerate to what we call terminal velocity. Terminal velocity is the velocity where the force of acceleration due to gravity (9.81 m s-2) is matched by the air resistance. That velocity varies, depending on the outline shape of the person, and is typically around 200 km/h or 125 mph. That will be the velocity of the fall.
Yes, that is known as the terminal velocity. At that speed, the air resistance (pulling up) would be in equilibrium with the gravitation (pulling down), so there is no further acceleration. The terminal velocity depends on the object's size and shape. In general, heavier objects will fall faster.Yes, that is known as the terminal velocity. At that speed, the air resistance (pulling up) would be in equilibrium with the gravitation (pulling down), so there is no further acceleration. The terminal velocity depends on the object's size and shape. In general, heavier objects will fall faster.Yes, that is known as the terminal velocity. At that speed, the air resistance (pulling up) would be in equilibrium with the gravitation (pulling down), so there is no further acceleration. The terminal velocity depends on the object's size and shape. In general, heavier objects will fall faster.Yes, that is known as the terminal velocity. At that speed, the air resistance (pulling up) would be in equilibrium with the gravitation (pulling down), so there is no further acceleration. The terminal velocity depends on the object's size and shape. In general, heavier objects will fall faster.