The two forces acting on a parachute are gravity pulling it downward and air resistance pushing against it as it falls. The parachute's design allows it to create enough air resistance to slow down its descent and increase the time it takes to reach the ground.
The main forces acting on a parachute during descent are gravity, air resistance, and the weight of the parachute itself. Gravity pulls the parachute and its load downwards, while air resistance provides an upward force that slows the descent. The weight of the parachute adds to the overall force acting on the system.
On a parachute falling through the air, the main forces acting are gravity pulling it downward and air resistance pushing against it. Gravity accelerates the parachute towards the ground, while air resistance, or drag, slows down its descent. The balance between these forces determines the speed at which the parachute falls.
The two forces acting on a parachute when it falls are gravity, pulling it downward, and air resistance (drag), pushing against its motion. As the parachute opens, air resistance becomes higher, counteracting gravity and slowing down its descent. Unfortunately, I can't draw a diagram as I'm a text-based assistant, but you can easily search for parachute force diagrams online.
A parachute is not uniformly accelerated because it experiences air resistance, which increases as the parachute opens and slows down the descent of the object. This non-uniform acceleration is caused by the changing forces acting on the parachute as it falls through the air.
When a parachute is falling at a steady speed, the forces acting on it are balanced. The force of gravity pulling the parachute downward is equal to the air resistance pushing upward, resulting in a state of equilibrium.
The main forces acting on a parachute during descent are gravity, air resistance, and the weight of the parachute itself. Gravity pulls the parachute and its load downwards, while air resistance provides an upward force that slows the descent. The weight of the parachute adds to the overall force acting on the system.
On a parachute falling through the air, the main forces acting are gravity pulling it downward and air resistance pushing against it. Gravity accelerates the parachute towards the ground, while air resistance, or drag, slows down its descent. The balance between these forces determines the speed at which the parachute falls.
The two forces acting on a parachute when it falls are gravity, pulling it downward, and air resistance (drag), pushing against its motion. As the parachute opens, air resistance becomes higher, counteracting gravity and slowing down its descent. Unfortunately, I can't draw a diagram as I'm a text-based assistant, but you can easily search for parachute force diagrams online.
A parachute is not uniformly accelerated because it experiences air resistance, which increases as the parachute opens and slows down the descent of the object. This non-uniform acceleration is caused by the changing forces acting on the parachute as it falls through the air.
When a parachute is falling at a steady speed, the forces acting on it are balanced. The force of gravity pulling the parachute downward is equal to the air resistance pushing upward, resulting in a state of equilibrium.
In the case of a parachute, the person and parachute fall at a constant speed once the forces acting on them are balanced. This means that the net acceleration, including gravity, is zero. Gravity is still acting on the person and parachute, but it is balanced by the drag force exerted by the parachute, resulting in a constant speed descent.
how two forces are added if they are not concurrent but are acting in same direction
The main forces acting on a parachute are drag force (opposes the motion) and the force of gravity (pulls the parachute downwards). Upthrust, also known as lift force, can also be present when the parachute is deployed properly and creates a lifting force that helps slow down the descent. Overall, the forces involved include drag, gravity, and lift.
If there are two or more unequal forces acting on an object then the object will be acting on the forces. ^_^
No, all objects do not necessarily have two forces acting on them at all times. Objects can have multiple forces acting on them simultaneously, or just one force, depending on the situation.
The resultant of two forces P and Q acting along the same line is the algebraic sum of the two forces. If they are acting in the same direction, the resultant is equal to the sum of the forces. If they are acting in opposite directions, the resultant is equal to the difference between the two forces.
Two forces acting in opposite directions are called balanced forces. When balanced forces act on an object, the object's motion remains constant or remains at rest.