How does a rocket work in space

In summary: I'm not sure. But at the most fundamental level, a rocket works by ejecting something (fuel) and the fuel pushes back on the rocket.
  • #1
shredder666
63
0
when there is nothing for the reaction force to push on?

My textbook says, ironically rockets work better in space because in atmosphere it has to do work against the pressure thingy. But it doesn't explain why, all it says is "at the microscopic level its complicated"

I remember asking my teacher once and he said the fueling pushes against the spent fuel, but that's not really "complicated"
 
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  • #2
Rockets work by ejecting material (from burning fuel) at high speed. The rocket pushes the exhaust and the exhaust pushes back on the rocket--Newton's 3rd law. Rockets don't need anything else to push on.
 
  • #3
Rockets are the purest application of Newton's Third Law:

For every action there is an equal and opposite reaction.

Fuel goes backward, rocket goes forward.

Think about sitting on a rolling chair and throwing heavy books away from you. You will move in the opposite direction. It has nothing to do with what the book "pushes on" once you throw it.

In fact, it works better in a vacuum.
 
  • #4
Yes I understand how the third law works, but I'm REALLY asking is, how it works in space, where there is nothing to push against

There was sort of a scandle thing before the apollo mission in the 1960s where Goddard was ridiculed by the New York Times for suggesting a rocket moving in space, they argued that the fuel isn't pushing against anything, but in fact it worked better. If a bird keeps flapping its wings in space its not going to go underwhere. If I "kick" the empty space in space, I'm not going to move anywhere. So how does the rocket move?
 
  • #5
shredder666 said:
Yes I understand how the third law works

Apparently not.

shredder666 said:
but I'm REALLY asking is, how it works in space, where there is nothing to push against

Where is the "push against" in the 3rd law?
 
  • #6
shredder666 said:
Yes I understand how the third law works, but I'm REALLY asking is, how it works in space, where there is nothing to push against
These two statements are contradictory. Not to put too fine a point on it but, if you are asking what it pushes against, you don't understand the 3rd law.


shredder666 said:
If a bird keeps flapping its wings in space its not going to go underwhere. If I "kick" the empty space in space, I'm not going to move anywhere.
Correct. The bird's wings stay attached to it. Your leg stays attached to you.

shredder666 said:
So how does the rocket move?
By expelling a portion of itself.

Fuel goes left, rocket goes right.

Think about the centre of mass of the entire system in all the examples.

1] Bird beats its wings: centre of mass stays stationary, so does bird.
2] PF member kicks his legs, centre of mass stays stationary, so does PF member.

as opposed to:

3] PFer throws book. Centre of mass of [book/PFer system] stays stationary. But book goes left, PFer goes right.
4]Rocket expels exhaust plume. Centre of mass of [rocket/exhaust-plume system] stays stationary. But exhaust plume goes left, rocket goes right.
 
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  • #7
Or think of it as conservation of momentum.

Momentum of expelled fuel = Momentum of rocket
 
  • #8
perhaps I've been confusing y'all with my dumb person talk. To make sure that there are no mistakes being made on my side, I will now quote from the book "College Physics 8th edition from Serway"
From chapter 6. In the section "Rocket Propulsion" on page 178 - 179
Starting now. (dont worry its not a long read)
"In a now infamous article in the New York Times, rocket pioneer Robert Goddard was ridiculed for thinking that rockets would work in space, where according to the Times, there was nothing to push against. The Times retracted rather belatedly, during the first Apollo moon landing mission in 1969. The hot gases are not pushing against anything external, but against the rocket itself-ironically the rockets actually work better in a vacuum. In an atmosphere the gases have to do work against the outside air pressure to escape the combustion chamber, slowing the exhaust velocity and reducing the reaction force.

At the microscopic level, this process is complicated, but it can be simplified by applying the laws of conservation of momentum to the rocket and its ejected fuel"
*end*
What I wanted to ask about, is the process in the microscopic level that's complicated
 
  • #9
Yeah, sure, if you want to get into the "microscopic" level, of how forces are actually transmitted according to quantum mechanics, or what the ejected "mass" really is, and where it all came from, and WHY?

Yeah, you can go as deep as you want into it. Deeper than even the top scientists understand.

But...if you just want to know how a rocket works, it's pretty much the simplest concept in physics. It "pushes" against its fuel. I'm not sure why the article claims that it's so "complicated". Everything can be more complicated than anybody understands on some fundamental level.

Maybe the editor just had some recent vision or something...
 
  • #10
The editor doesn't quite sound like he entirely knows what he's talking about...

Why are you going into the microscopic level when the macroscopic one works just fine?

"Rocket goes up, exhaust goes down." No need for microscopics at all.
 
  • #11
Char. Limit said:
The editor doesn't quite sound like he entirely knows what he's talking about...

Why are you going into the microscopic level when the macroscopic one works just fine?

"Rocket goes up, exhaust goes down." No need for microscopics at all.

It sounds like editor just recently saw some small glimpse of slightly deeper physics, and has somehow been enlightened to the existence of a deeper reality. He wants to make sure that the world knows that HIS knowledge goes beyond the average.

But yeah...to every action is an equal and opposite reaction. You don't need to split the atom and unfold the fabric of space-time to understand this.
 
  • #12
wow.
 
  • #13
Why should you expect a newspaper to get something like Newtonian Physics right? They don't seem do a very good job with anything that you happen to know a lot about yourself. 'Even' Science Journalists (who really should know better) make some amazing howlers.

Char.limit
"No need for microscopes"
A man after my own heart!
 
  • #14
To all the sarcastic people who are having a go at the OP and just quoting laws at him. It's a perfectly reasonable question with a perfectly reasonable answer, OK?

Let's simplify the design:

- the rocket motor is a hollow sphere with very thick walls. There's a hole in one side of the sphere opening into space.

- continuously inject flammable gas into the sphere through tiny pipes of negligible cross-section. Set fire to the gas. The gas molecules acquire huge kinetic energy/momentum and fly about every which way, and either end up hitting the inside of the sphere, or flying out the hole into space.

- at every point on the sphere the average force is radially outwards. Add up all these vector forces around the whole interior surface of the sphere and find the resultant.

- If there were no hole in the sphere, the resultant is zero and the thing doesn't move at all. As there is in fact a hole on the sphere, the forces on that bit don't exist and the resultant is a very big arrow pointing radially outwards on the side of the sphere opposite to the hole.

- Result : the rocket flies off very fast in that direction.

So, despite what has been said by the mickey-takers, the stuff that just gets ejected straight into space (i.e. flies out the back of its own volition) has no effect whatsoever on the movement of the rocket. The molecules have to bounce off the interior of the forward hemisphere inside the engine before anything gets to move. So all the '[Slaps forehead] For God's sake, the rocket goes right, the fuel goes left, you idiot' explanations the OP has been getting are actually seriously misleading.
 
  • #15
You could say that your spherical rocket loses only those molecules that happen to be moving in a certain direction (with a certain direction of momentum vectors). Total momentum is conserved so blah blah.
But is that any more useful or less confusing than talking about the reaction force due to material of the fuel being ejected and giving a simple example of throwing a book from an office chair?
The nonsense being pointed out was surely in the notion that you might need to 'push against" anything like an atmosphere.
Personally, the only micky taking I was doing was against newspaper editors - who should be capable of receiving as well as dishing it out.
 
  • #16
sophiecentaur said:
You could say that your spherical rocket loses only those molecules that happen to be moving in a certain direction (with a certain direction of momentum vectors).

That's what I said, yes.
Total momentum is conserved so blah blah.

Don't quote laws. He's asking for an explanation of why the rocket moves forward.
But is that any more useful or less confusing than talking about the reaction force due to material of the fuel being ejected and giving a simple example of throwing a book from an office chair?

Sophie - read what I wrote. There is no reaction force if something just flies out the back - the analogy with throwing a book is not correct.

There is a force on the rocket moving forward because there is an unopposed pressure on one side of the combustion chamber. Here is a nice picture:
 

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  • #17
zenith8 said:
the stuff that just gets ejected straight into space (i.e. flies out the back of its own volition) has no effect whatsoever on the movement of the rocket.
Hi zenith8, I know you understand this stuff, but this is an incorrect statement imo. Let's say that we are using a fuel where one molecule of fuel gets split into two molecules of exhaust, and let's say further that a given molecule of fuel burns in the combustion chamber such that one molecule of exhaust goes straight out the back and the other goes straight forward. The one going straight out the back has a momentum of -p and the one going forward has a momentum of p, when the forward one collides with the ship and rebounds its final momentum is -p and the change in momentum of the rocket is 2p. From this interaction the total momentum of the two exhaust molecules is -2p and the total change in momentum of the rocket is 2p. So the molecule of exhaust which is ejected straight back does in fact have an effect on the movement of the rocket because it has an effect on the movement of the fuel which strikes the rocket. This is why it is sufficient to simply consider the total change in momentum from a macroscopic level.
 
  • #18
So if you don't want to "quote laws" how are you going to describe what has happened to the molecules of the gas inside and what relevance their particular direction of travel has? How does a gas exert pressure?
That's a nice picture and it gives another (useful) view of the situation.
But what causes the pressure and what has the fact that it is "unopposed" is certain directions got to do with the movement of the rocket, IF you're not going to "quote laws" when you want to relate how the particles are involved in the process? Why should the pressure on the inner surface only cause the rocket to go in that direction? How intuitive are we allowed to be and which bits of "laws" are we supposed to / allowed to use?
If you really want to 'get down to it' then you can't be picky. The fact is that there is no limit to how deep you can go into a topic. Dunno why you seem to be getting so upset.
 
  • #19
You guys do realize that that excerpt is from a textbook, not a newspaper article, don't you?
 
  • #20
A textbook that uses the word "thingy" sounds a bit suspect?
 
  • #21
shredder666 said:
To make sure that there are no mistakes being made on my side, I will now quote from the book "College Physics 8th edition from Serway"
From chapter 6. In the section "Rocket Propulsion" on page 178 - 179
Starting now. (dont worry its not a long read)
"In a now infamous article in the New York Times, rocket pioneer Robert Goddard was ridiculed for thinking that rockets would work in space, where according to the Times, there was nothing to push against. The Times retracted rather belatedly, during the first Apollo moon landing mission in 1969. The hot gases are not pushing against anything external, but against the rocket itself-ironically the rockets actually work better in a vacuum. In an atmosphere the gases have to do work against the outside air pressure to escape the combustion chamber, slowing the exhaust velocity and reducing the reaction force.

At the microscopic level, this process is complicated, but it can be simplified by applying the laws of conservation of momentum to the rocket and its ejected fuel"
*end*
I don't see the word "thingy" in there.
 
  • #22
vela said:
You guys do realize that that excerpt is from a textbook, not a newspaper article, don't you?
But the quoted excerpt does refer to a famous New York Times editorial that appeared in 1920:
http://astronauticsnow.com/blazingthetrail/gruntman_btt_pages/gruntman_blazingthetrail_p_117.pdf" [Broken]

Another reference for that NYT editorial: http://www.clarku.edu/research/archives/goddard/faqs.cfm#question8" [Broken]

Note that the Times printed a "correction" to that 1920 editorial in 1969, just three days before we walked on the Moon.
 
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  • #23
I read "thingy" in the OP, actually.
In any case, there are occasions when a textbook can be wrong. I have had lots of trouble with irate students. They get more upset than when they find out "there ain't no sanity clause".

Actually, it doesn't sound so hard to accept that atmospheric effect. The average exit velocity could also be affected by the presence of slower moving air molecules absorbing net KE of the jet. Some air molecules could find themselves in the end of the nozzle, due to turbulence, etc. The energy imparted to these molecules would be in the form of more random motion - KE being given to molecules moving from side to side - not backwards. This represents work done and would reduce the useful work done on the rocket nozzle. Without the presence of air, the molecules leaving the nozzle would be undisturbed.
Perhaps you could also look on it as a heat engine losing some thermal energy to its surroundings which can't then be used for useful work.
I suppose the simple fact would have also been noted that there is no friction from passing through an atmosphere.
 
  • #24
DaleSpam said:
Hi zenith8, I know you understand this stuff, but this is an incorrect statement imo. Let's say that we are using a fuel where one molecule of fuel gets split into two molecules of exhaust, and let's say further that a given molecule of fuel burns in the combustion chamber such that one molecule of exhaust goes straight out the back and the other goes straight forward. The one going straight out the back has a momentum of -p and the one going forward has a momentum of p, when the forward one collides with the ship and rebounds its final momentum is -p and the change in momentum of the rocket is 2p. From this interaction the total momentum of the two exhaust molecules is -2p and the total change in momentum of the rocket is 2p. So the molecule of exhaust which is ejected straight back does in fact have an effect on the movement of the rocket because it has an effect on the movement of the fuel which strikes the rocket. This is why it is sufficient to simply consider the total change in momentum from a macroscopic level.

Hi Dale,

Everything you say is, of course, correct. All the OP and others should take from my post is that what is important for propelling the rocket forward is (1) the impact of molecules on the forward half of the combustion chamber, and (2) the absence of impacts on the rear half of the combustion chamber, because there isn't a rear half. This is merely intended to answer the question about 'what is there to push against in space?'. I'm not trying to derive the conservation of momentum from first principles.
 
  • #25
sophiecentaur said:
So if you don't want to "quote laws" how are you going to describe what has happened to the molecules of the gas inside and what relevance their particular direction of travel has? How does a gas exert pressure?
That's a nice picture and it gives another (useful) view of the situation.
But what causes the pressure and what has the fact that it is "unopposed" is certain directions got to do with the movement of the rocket, IF you're not going to "quote laws" when you want to relate how the particles are involved in the process? Why should the pressure on the inner surface only cause the rocket to go in that direction? How intuitive are we allowed to be and which bits of "laws" are we supposed to / allowed to use?
If you really want to 'get down to it' then you can't be picky. The fact is that there is no limit to how deep you can go into a topic. Dunno why you seem to be getting so upset.

I'm not upset, dear - you're being overly literal. "Not quoting laws" doesn't mean that one has to rederive the whole of physics from first principles. It's just that sometimes if you say "the conservation of momentum means that the rocket goes up and the exhaust goes down" or "sugar cubes glow blue if you crack them with a pair of pliers because of triboluminescence" then that isn't enough to answer a question.

Here it's a given that we know that force (pressure) is caused by the electromagnetic repulsion of atoms brought into close proximity, that forces are bigger if things bang into each other very fast, and that we understand Newton's third law and the conservation of momentum. And yet here, the OP still doesn't understand why the rocket goes forward. Deeper explanation required. Hence my post.
 
  • #26
Z8
Fair enough but when we stop using terms like momentum it's a thin line between that and saying things like "the force carried the cricket ball out of the ground" as if the force was there all the time.
The only time a force is involved in our problem is when 'momentum is conserved'. You can either say this happens during molecular collisions or on a macroscopic level, after all the collisions have taken place and we're just dealing with the mass of gas on the way out of the back. Momentum ideas have the beauty of working at all levels.

I must say, I am always a bit twitchy about insisting on using particles to explain virtually everything. I have heard a poor Science Teacher try to explain Convection in terms of particles to a group of 14 year olds because he thought he should be able to. It was a nightmare for him and they went away shaking their heads.We do use appropriate 'levels' of complexity for a very good reason.
 
  • #27
OP specifically said that he understands Newton's laws.

The reason he got confused is because of these "microscopic effects" that got needlessly thrown in there.

If OP intrinsically understands why a rocket works, but is led to believe that in fact he doesn't because of his lack of understanding for the string theory and super symmetry, then there is a problem.
 
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  • #28
sophiecentaur said:
Z8
Fair enough but when we stop using terms like momentum it's a thin line between that and saying things like "the force carried the cricket ball out of the ground" as if the force was there all the time.
The only time a force is involved in our problem is when 'momentum is conserved'. You can either say this happens during molecular collisions or on a macroscopic level, after all the collisions have taken place and we're just dealing with the mass of gas on the way out of the back. Momentum ideas have the beauty of working at all levels.

I must say, I am always a bit twitchy about insisting on using particles to explain virtually everything. I have heard a poor Science Teacher try to explain Convection in terms of particles to a group of 14 year olds because he thought he should be able to. It was a nightmare for him and they went away shaking their heads.We do use appropriate 'levels' of complexity for a very good reason.

I really don't get your point. What different does it make if you once heard some guy give a poor explanation about something completely different? It's not like what I said earlier is difficult to understand. Or is it? Oh well, I'll clear off back to the Quantum Physics forum.
 
  • #29
Conservation of momentum is not a poor explanation. It is a very good explanation. Explaining how real rockets work at the molecular level is a very, very difficult undertaking. The best we can do is computational fluid dynamics models, and those are well beyond someone with a (somewhat shaky) freshman physics level of understanding.
 
  • #30
Lsos said:
The reason he got confused it because of these "microscopic effects" that got needlessly thrown in there.

If OP intrinsically understands why a rocket works, but is led to believe that in fact he doesn't because of his lack of understanding for the string theory and super symmetry, then there is a problem.

But before I do, I mean what? What a gross mischaracterization of this discussion.

The OP says "..but surely there is nothing for the reaction force to push against?". I say "molecules bang on the upper side of the reaction chamber" and now you're saying "Ooh, lah di dah, no need to talk about string theory and supersymetry". Come on.. this is silly.

The guy understands the conservation of momentum well - but for that to operate there needs to be some interaction between two objects. He's just asking "what objects?".
 
  • #31
zenith8 said:
It's a perfectly reasonable question with a perfectly reasonable answer, OK?

- the rocket motor is a hollow sphere with very thick walls. There's a hole in one side of the sphere opening into space.

The difficulty with the above explanation is that it is specious. There are many, many ways of getting propulsion without using exploding, expanding fuel and a nozzle. You can get propulsion by throwing a book, no expanding gases involved.

The general principle is indeed conservation of momentum as explained. Ejected mass goes left, rocket goes right. How you get that ejected mass to move (and how much and how fast) is entirely up to your imagination, and your engineers.


Also,
zenith8 said:
To all the sarcastic people who are having a go at the OP and just quoting laws at him...
So, despite what has been said by the mickey-takers...
Ooh, lah di dah...
The only one here being sarcastic is you. Please, let's keep the emotional bickering out of it.
 
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  • #32
D H said:
Conservation of momentum is not a poor explanation. It is a very good explanation. Explaining how real rockets work at the molecular level is a very, very difficult undertaking. The best we can do is computational fluid dynamics models, and those are well beyond someone with a (somewhat shaky) freshman physics level of understanding.

No - producing a numerical simulation of a real rocket engine so that the computer model behaves exactly the same as the real one is a difficult computational fluid dynamics problem. Understanding how it works in general is not.
 
  • #33
D H said:
Conservation of momentum is not a poor explanation. It is a very good explanation. Explaining how real rockets work at the molecular level is a very, very difficult undertaking.
You can use Conservation of momentum, but make it more detailed than just saying "If fuel goes back, rocket has to go forward". The forces on the walls of the burning chamber are too just a result of Conservation of momentum. But for laymen they are easier to accept as a cause for the rocket's acceleration, than some bookkeeping rule like Conservation of momentum.
 
  • #34
A.T. said:
The forces on the walls of the burning chamber are too just a result of Conservation of momentum. But for laymen they are easier to accept as a cause for the rocket's acceleration,

The trouble is, it doesn't grok the problem. Expanding gases are NOT necessary for propulsion. Throwing a book will work just fine.

It will be much more beneficial for the layperson to understand the overarching principle that applies in ALL cases, rather than having them get caught up in details of a specific example.



The principle of momentum, which you call "bookkeeping" is, in fact, the fundamental principle. Everything else is mere bookkeeping.
 
  • #35
zenith8 said:
But before I do, I mean what? What a gross mischaracterization of this discussion.

The OP says "..but surely there is nothing for the reaction force to push against?". I say "molecules bang on the upper side of the reaction chamber" and now you're saying "Ooh, lah di dah, no need to talk about string theory and supersymetry". Come on.. this is silly.

The guy understands the conservation of momentum well - but for that to operate there needs to be some interaction between two objects. He's just asking "what objects?".
He went back and forth between "I understand" to seeming like he doesn't. With the final explanation, he led me to believe that he DOES, just that the "microscopic" stuff is throwing him off. So, I tell him not to worry about that.

You believe that he doesn't understand, so you gave a deeper explanation which perhaps will make him understand. I applaud you. You interpreted the problem differently than I did, and you're probably right.

If you are right, I still don't think we should be held accountable for giving OP the wrong or simplistic answer. I believe the problem rests in how OP went about asking for his answer. Specifically, this example "Yes I understand how the third law works, but I'm REALLY asking is..."

Basically he had an overinflated (almost cocky) assumption of what he understands, and he dismissed attempts at trying to give him a proper answer. Can't blame us for that.
 
<h2>1. How does a rocket generate thrust in space?</h2><p>A rocket generates thrust in space through the process of combustion. The rocket's engines mix liquid or solid propellants together, which creates a controlled explosion. This explosion produces hot gases that are expelled out of the back of the rocket, propelling it forward.</p><h2>2. How does a rocket steer and change direction in space?</h2><p>A rocket steers and changes direction in space by using small thrusters located on the sides of the rocket. These thrusters can be fired in different directions to change the rocket's orientation and trajectory. Rockets also use gyroscopes and other navigation systems to help with steering and navigation.</p><h2>3. How does a rocket overcome the lack of air resistance in space?</h2><p>In space, rockets do not have to overcome air resistance like they do in Earth's atmosphere. Instead, they use the principle of Newton's Third Law of Motion, which states that for every action, there is an equal and opposite reaction. The expulsion of hot gases from the rocket's engines creates a force in the opposite direction, propelling the rocket forward.</p><h2>4. How does a rocket achieve escape velocity to leave Earth's orbit?</h2><p>A rocket achieves escape velocity by reaching a speed of approximately 25,000 miles per hour. This speed is necessary to overcome the gravitational pull of Earth and break free from its orbit. Rockets typically use multiple stages of engines and boosters to gradually increase their speed and reach escape velocity.</p><h2>5. How does a rocket navigate and travel to other planets in space?</h2><p>Rockets use a combination of navigation systems, such as gyroscopes, star trackers, and radio signals, to determine their position and trajectory in space. They also use precise calculations and orbital mechanics to plan and execute trajectories that will take them to other planets in our solar system.</p>

1. How does a rocket generate thrust in space?

A rocket generates thrust in space through the process of combustion. The rocket's engines mix liquid or solid propellants together, which creates a controlled explosion. This explosion produces hot gases that are expelled out of the back of the rocket, propelling it forward.

2. How does a rocket steer and change direction in space?

A rocket steers and changes direction in space by using small thrusters located on the sides of the rocket. These thrusters can be fired in different directions to change the rocket's orientation and trajectory. Rockets also use gyroscopes and other navigation systems to help with steering and navigation.

3. How does a rocket overcome the lack of air resistance in space?

In space, rockets do not have to overcome air resistance like they do in Earth's atmosphere. Instead, they use the principle of Newton's Third Law of Motion, which states that for every action, there is an equal and opposite reaction. The expulsion of hot gases from the rocket's engines creates a force in the opposite direction, propelling the rocket forward.

4. How does a rocket achieve escape velocity to leave Earth's orbit?

A rocket achieves escape velocity by reaching a speed of approximately 25,000 miles per hour. This speed is necessary to overcome the gravitational pull of Earth and break free from its orbit. Rockets typically use multiple stages of engines and boosters to gradually increase their speed and reach escape velocity.

5. How does a rocket navigate and travel to other planets in space?

Rockets use a combination of navigation systems, such as gyroscopes, star trackers, and radio signals, to determine their position and trajectory in space. They also use precise calculations and orbital mechanics to plan and execute trajectories that will take them to other planets in our solar system.

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