What's the point of Escape Velocity?

In summary, the conversation discusses the concept of escape velocity and its relevance to space travel. The main points made are that escape velocity allows a spacecraft to escape the gravitational pull of a body, but it is not necessary to reach this velocity for all space travel. Other factors, such as the distance to the next body and the type of orbit, also play a role. There is some confusion around the exact definition of escape velocity, but it is generally agreed that it is the minimum speed required to escape a gravitational field.
  • #36
QuantumPion said:
Escape velocity is a property of position only, I think. A rocket in LEO still needs ~11km/s as escape velocity - it is just easier to reach it.
A rocket in LEO still needs 11 km/s to escape but it is already going 7 km/s due to its orbital velocity. Otherwise it wouldn't be in orbit.
That is what I said?
Yes, gravity is considered as a type of drag in this sense.
Well, it is completely different from air drag or similar types of drag.

sophiecentaur said:
Is it not true to say that no spacecraft has ever been given the full 'escape velocity' with its motors?
Starting from what? Every interplanetary mission uses the velocity of Earth (~30km/s), and most rockets use the rotation of Earth (up to ~500m/s) to begin the mission.
 
Physics news on Phys.org
  • #37
mfb said:
Well, it is completely different from air drag or similar types of drag.

Actually gravity drag it is very analogous to air drag in the context of rockets. Both are forces which oppose the acceleration of the rocket during its launch. The difference is air drag is proportional to speed, while gravity drag is constant but only in the vertical direction.
 
  • #38
QuantumPion said:
Actually gravity drag it is very analogous to air drag in the context of rockets. Both are forces which oppose the acceleration of the rocket during its launch. The difference is air drag is proportional to speed, while gravity drag is constant but only in the vertical direction.

That is a strange way of looking at it. When you increase your GPE, that energy is of some use to you (it's half of the energy involved in your final orbit). Energy lost because of drag is of no use at all.
I understand the message in that link but it strikes me that it's not much more than an alternative explanation for the process of carrying fuel and extra rocket stages with you in a launch. It is taking two values of 'wasted energy' and lumping them together. There is no 'gravity drag' on the bit of the vehicle that is finally up there and in orbit. It still possesses the same amounts of GPE and KE it was given.
 
  • #39
sophiecentaur said:
That is a strange way of looking at it. When you increase your GPE, that energy is of some use to you (it's half of the energy involved in your final orbit). Energy lost because of drag is of no use at all.
I understand the message in that link but it strikes me that it's not much more than an alternative explanation for the process of carrying fuel and extra rocket stages with you in a launch. It is taking two values of 'wasted energy' and lumping them together. There is no 'gravity drag' on the bit of the vehicle that is finally up there and in orbit. It still possesses the same amounts of GPE and KE it was given.

Correct, energy lost to gravity drag is of no use at all. As MFP said, if you had a rocket burning at full thrust just to hover, you have 100% of your energy lost to gravity drag. There is no air drag on the vehicle that finally gets to orbit either. Gravity drag and air drag are terms used for determining how much extra delta-V over the theoretical minimum you need to reach orbit. If you had a spaceplane that could fly to the very upper reaches of the atmosphere using jet engines, and then ignite rocket engines to accelerate horizontally to orbital velocity, losses due to gravity drag would be very low for example.
 
  • #40
QuantumPion said:
Actually gravity drag it is very analogous to air drag in the context of rockets. Both are forces which oppose the acceleration of the rocket during its launch. The difference is air drag is proportional to speed, while gravity drag is constant but only in the vertical direction.
In the limit of burning all the fuel at once, gravity still acts on the rocket, but there is no energy loss due to gravity. Air drag, on the other hand, is always there if the rocket is in motion, just its amount is variable.

Who is MFP?
 
  • #41
mfb said:
In the limit of burning all the fuel at once, gravity still acts on the rocket, but there is no energy loss due to gravity. Air drag, on the other hand, is always there if the rocket is in motion, just its amount is variable.

Who is MFP?

I meant mfb not P, sorry. But yes you are correct.
 
  • #42
mfb said:
Who is MFP?

Your long lost dyslexic brother, perhaps.

I really don't like the term Gravity Drag but, if it's used by people in the know, I think we have to go along with it. After all, it is Rocket Science. :smile:
 
  • #43
I just want to chime in and say that drag should should be used for forces acting in the opposite direction as the velocity. Typically drag is defined as:
From Merriam-Webster
the retarding force acting on a body (as an airplane) moving through a fluid (as air) parallel and opposite to the direction of motion

So while a component of gravity may be acting as a "drag" force, certainly when the craft is pointed directly opposite the direction of Earth's gravitational acceleration, I don't think it's at all useful to call it gravity drag...

In the upper atmosphere, the craft must still overcome gravitational acceleration to continue climbing, but due to it's thrust vector and velocity, it's using very little energy overcoming the "drag" component of that force.
 
Back
Top