But how its velocity can be reduced?Nidum said:Bringing a spacecraft to a dead stop in space is not something that is usually needed or desirable .
Bringing an Earth orbit spacecraft safely back to the surface requires a controlled reduction of it's velocity . Bringing it to a stop would just cause it to plummet to the ground .
Docking to another spacecraft means matching orbits and velocities . The two craft are not moving relative to one another but they are still both moving .
A spacecraft anywhere in our solar system will experience gravitational attraction from nearby bodies such as Earth , moon , sun , planets . If spacecraft where actually brought to a stop these gravitational attractions would start it moving again . Spacecraft would gain velocity and it would probably eventually crash into one of the bodies .
Either by turning around and firing the rocket, or using a gravity assist to slow down a rocket, by passing by in front of a planet or moon rather than behind it. Using a gravity assist to slow down is common when sending spacecraft to Venus or Mercury which are closer to the sun than the earth.Ajit Kumar said:But how its velocity can be reduced?
means launching a missile in the forward direction, so as to reduce the velocity by applying a negative force? isn't it?rcgldr said:firing the rockes
It is not even well-defined. At rest relative to what?Nidum said:Bringing a spacecraft to a dead stop in space is not something that is usually needed or desirable
Spacecrafts don't launch missiles, they use their engines that fire the exhaust gases away at high speed. The spacecraft accelerates in the opposite direction as result of this. The spacecraft can fire its engines in any direction. One direction can be perceived as "forwards" (e. g. as seen from earth), one as "backwards". Those labels are arbitrary - something that slows a rocket relative to Earth can make it faster relative to the sun, for example.Ajit Kumar said:means launching a missile in the forward direction, so as to reduce the velocity by applying a negative force? isn't it?
Most of our spacecraft are headed somewhere specific, so "at rest" would be relative to their destination. Yeah, no one would try to "stop" unless they knew what they were stopping relative to. What happens with real spacecraft is they either:mfb said:It is not even well-defined. At rest relative to what?
But it must have some surface to exert pressure on. Like on Earth it exerts high pressure on ground.mfb said:It is not even well-defined. At rest relative to what?
Spacecrafts don't launch missiles, they use their engines that fire the exhaust gases away at high speed. The spacecraft accelerates in the opposite direction as result of this. The spacecraft can fire its engines in any direction. One direction can be perceived as "forwards" (e. g. as seen from earth), one as "backwards". Those labels are arbitrary - something that slows a rocket relative to Earth can make it faster relative to the sun, for example.
What if near the moon, if I find a beautiful girl? Who wouldn't like to stop?! ;)russ_watters said:Most of our spacecraft are headed somewhere specific, so "at rest" would be relative to their destination. Yeah, no one would try to "stop" unless they knew what they were stopping relative to. What happens with real spacecraft is they either:
1. Stop (land).
2. Slow down and enter orbit.
3. Whiz on by.
You mean the rockets themselves? The only surface they need to push on is the inside of the combustion chamber, which pushes the rocket away from the combustion gases. Being near a surface actually gets in the way of that: rockets are more efficient in space (a vacuum) than they are on earth/in the atmosphere. Again, a different way: thrust comes from the rocket and exhaust gases pushing on each other.Ajit Kumar said:But it must have some surface to exert pressure on. Like on Earth it exerts high pressure on ground.
But in space, nothing is there. No air.
That's where you're confused. Rockets don't work by exerting pressure on anything. Rockets work perfectly fine, even in a vacuum.Ajit Kumar said:But it must have some surface to exert pressure on. Like on Earth it exerts high pressure on ground.
But in space, nothing is there. No air.
Please explain this in more detail.russ_watters said:You mean the rockets themselves? The only surface they need to push on is the inside of the combustion chamber, which pushes the rocket away from the combustion gases. Being near a surface actually gets in the way of that: rockets are more efficient in space (a vacuum) than they are on earth/in the atmosphere. Again, a different way: thrust comes from the rocket and exhaust gases pushing on each other.
There are two ways to analyze how a rocket works - like pressure/force because thrust is force:Ajit Kumar said:Please explain this in more detail.
Have you read about this anywhere else? There are countless links that describe how rockets work and the basic ideas of momentum that are involved. The second post on this thread actually gave you a pretty good answer. Speeding up or slowing down by using a rocket are both the same thing, basically; it's just changing velocity. (As Newtons law tells you)Ajit Kumar said:Please explain this in more detail.
Ajit Kumar said:Please explain this in more detail.
The rocket braking system works by using Newton's First Law of Motion, also known as the Law of Inertia, which states that an object at rest will remain at rest and an object in motion will remain in motion unless acted upon by an external force. The rocket's thrusters provide this external force, pushing against the direction of travel to slow the rocket down.
The purpose of a rocket braking system in space is to slow down or stop the motion of a spacecraft. This is crucial for maneuvers such as entering orbit around a planet or landing on a celestial body.
Newton's First Law of Motion is applied in the rocket braking system by using thrusters to create an external force that acts against the motion of the rocket. This force causes the rocket to slow down or come to a stop, as stated by the Law of Inertia.
One of the main challenges of using a rocket braking system in space is the lack of friction. In space, there is no air resistance or other forces to slow down a spacecraft, so the thrusters must provide enough force to overcome the inertia of the object. This requires precise calculations and control to ensure the spacecraft is not slowed down too much or too little.
Yes, the rocket braking system can be used for landing on other planets. In fact, it is a crucial component of any planetary landing mission. By using the thrusters to slow down the spacecraft, the rocket braking system allows for a controlled landing on the surface of a planet or moon.