Thrust.
Thrust on a plane is generated by the engines, which push air backwards to create a forward force that propels the aircraft through the air. This forward force overcomes drag to accelerate the plane, allowing it to take off, maintain speed, and climb. Pilots control the amount of thrust to climb, descend, or maintain altitude during flight.
Take away and forward delivery to the ball
you can either take a plane to LAX of Orange County, Then take a bus to your hotel or to Disneyland. Hope this helps
Newton's 3rd law of motion states is basic terms that for every action there is an equal, but opposite reaction (if you push against a wall with force F, then the wall will push back with force -F). When you walk/run forward, you exert a force on the ground that goes diagonally down and backward. The equal, but opposite reaction is the ground exerting a force on your foot that is diagonally up and forward (exactly opposite that applied by your foot). This helps to propel you forward as you walk or run.
it helps generally to take off into the wind because it gives the plane more lift
Thrust on a plane is the forward force produced by the aircraft's engines, which propels it through the air. It is essential for overcoming drag and achieving lift, allowing the plane to take off, maintain flight, and maneuver. Thrust is generated by jet engines or propellers and is measured in pounds or Newtons. The balance of thrust with drag, lift with weight, is crucial for stable flight.
The sea plane do not fly on sea.The plane just takes off and lands in the sea.You can take of from the sea by accelerating using forward key and then press the key that is used for wheelie.
The planets orbit in the same plane because there is no force to take them out of the plane. The plane is the plane of the average rotations of all the elements of the cloud of gases that made up the solar system.
Yup.You're right to note, that the speed of belt is matching the takeoff speed (some trolls forget about speed being relative). So the plane will take off, with it's wheels on the belt spinning twice as usual.((Yes. The logical error that "catches" many people is that they are more familiar with cars than planes. A car exerts its forward force on the ground, like a person does. When you put them on a treadmill travelling backward at the same speed that the object is attempting to move forward, then they are attempting to move against an equally moving medium. This results in a Red Queen scenario and a stationary object.A plane however, does not move forward using its wheels. They are freespinning objects independent of the propulsion system. A plane is exerting its forward force against the AIR, and therefore will move with respect to the air. A plane attempting to lift off on a conveyor belt (no matter the speed of the belt) will do so essentially just as easily as it would had it been running on a standard runway.Mathmatically, this can be expressed by the fact that stationary objects are stationary because the forces are equal on all sides. A pencil resting on a table is exerting its force (as its weight) against the table, and the table is pressing back with equal force. When an object is moving on a surface (like a car or a grounded plane), frictional force is applied to the object resisting the forward motion. To calcuate the magnitude of this resisting force, you must multiply the normal force (the weight of the object), by the coefficient in friction (the calcuated "roughness" of the surface).This leaves no variable for the speed of the surface below it to apply in order to counteract the thrusting force caused by the pushing of the air. This resisting force for the plane will remain essentially the same regardless if it is on a standard runway, a belt moving at 25 mph, or a belt moving at mach 3. As long as the wheels remain intact, the plane will take off. The only physical difference that the plane will experience in this scenario is that the wheels will move twice as fast. Half of the speed are caused by forces that are driving the plane forward, and the other half of the speed are caused by the conveyor belt moving backward.A simple experiment that can prove this is demostrated on youtube at the following link: http://www.youtube.com/watch?v=4owlyCOzDiEIt clearly demostrates that the speed of the belt has no bearing on the aircraft's ability to move. Once the craft overcomes the frictional force that would be present even with a stationary runway, no more force is needed, even as the author of the video ramps up the speed of the treadmill by several factors without compensating with the thrust.Ergo a conveyor belt, matching the plane's speed or not, is completely impotent to hinder the aircraft's ability to take off.))
The force required to pull a truck up an inclined plane depends on the weight of the truck and the steepness of the incline. The force needed would be higher on steeper inclines and with heavier trucks. This force can be calculated using the equation: Force = Weight * sin(angle) + frictional force.
Let's take the forces one-at-a-time starting with Thrust.1. Thrust - is provided by the propeller or jet engine; thrust acts to move the plane forward into the air.2. Lift - As the plane moves forward the shape of the wing (airfoil) causes a pressure difference that exerts an upward force on the wing -- the lift force. As thrust increases lift increases and the plane rises as lift overcomes the downward pull of gravity.3. Gravity - the force that pulls objects back to Earth. In order to have an object like a plane rise higher the Lift force must be stronger than the pull of gravity. If a plane weighs 10,000 lbs (pull of Gravity) then Lift must be 10,001 lbs or more in order for the plane to rise.4. Drag - Air moving over a surface experiences friction as the air molecules rub against the surface. Rough surfaces have more friction than smooth ones, but even smooth surfaces have some friction; the net effect is to oppose the forward motion and slow the airplane down. Thrust must be strong enough to overcome the total Drag and accelerate the plane to a speed that generates enough Lift to overcome Gravity and allow the plane to rise.
i need that answer for my test please answer my question