The greatest velocity a falling object reaches is called the terminal velocity.
For an object falling at the terminal velocity, the weight force of the object
is balanced by the drag force and buoyant force on the object.
W + FDRAG + FBUOYANT = FNET = 0.0
The greatest velocity a falling object reaches is called terminal velocity. It occurs when the force of gravity pulling the object downward is balanced by the force of air resistance pushing upward. At terminal velocity, the object falls at a constant speed with no further acceleration.
When the upward and downward forces on a falling object are equal, the object reaches terminal velocity. At terminal velocity, the object stops accelerating and falls at a constant speed.
The velocity of a falling object increases as it falls due to the acceleration of gravity acting on it. As the object falls, it gains speed and accelerates toward the ground until it reaches a constant velocity known as terminal velocity.
Yes, it is false that balanced forces are equal forces acting on an object in opposite directions. Balanced forces are equal in magnitude and opposite in direction, resulting in no overall change in an object's motion. When forces are balanced, the object will either remain at rest or move at a constant velocity.
Technically, its false.... Terminal Velocity is defined as "the constant maximum velocity reached by an object falling through the atmosphere under the attraction of gravity". The crash is simple a result of and the conclusion to the fall....
the greatest velocity a falling object reaches is terminal velocity
the greatest velocity a falling object reaches is terminal velocity
Terminal
The name for it is "terminal velocity". What it is depends on what the object is.
The greatest velocity, achieved when the acceleration due to gravity is balanced by the aerodynamic deceleration, is called the terminal velocity.
The greatest velocity a falling object can reach is called terminal velocity. Terminal velocity occurs when the force of air resistance on the object matches the force of gravity pulling it down, resulting in a constant speed.
The greatest velocity that a falling object can achieve is termed, terminal velocity. The equation for terminal velocity is equal to the square root of (2mg / (air density * projected area * drag coefficient))
On any planet with an atmosphere, gravity is counteracted by the force of air friction with the object that is falling. This is known as terminal velocity - the point at which the forces of air resistance and gravity balance.
The greatest velocity any object can have on earth is it's terminal velocity. That means when the force of gravity is eventually overcome by the force of air resistance of the falling object. An example of this would be that a falling feather reaches its terminal velocity much quicker (and therefore falls much slower) than something that is more dense and aerodynamic, such as a bowling ball or a baby.
The greatest speed a falling object is known as its terminal velocity. At this speed, the drag force from the air is equal to the object's weight, and so there is no net force to accelerate the object further.
When THE FRICTION BETWEEN THE OBJECT AND THE ATMOSPHEREequals the force of gravity on a falling object the object reaches terminal velocity.
The greatest velocity a falling object reaches is called terminal velocity. It occurs when the force of gravity pulling the object downward is balanced by the force of air resistance pushing upward. At terminal velocity, the object falls at a constant speed with no further acceleration.