You're probably thinking of the space shuttle which rolled upside down during launch (there were also pitch and yaw adjustments) for aerodynamic load issues on the shuttle, (it also allowed the ground to be used for references by the on board crew, but I'm not sure how useful that was). I'm not sure why the shuttle wasn't simply attached to a launch tower so the roll manuever wasn't required, unless the setup was historical (not an issue for previous rockets), and too costly to redo. Most rockets don't spin during launch.torquil said:Don't they also start to spin slowly as soon as possible after launch, to increase stability?
Other than the reusable aspect, SpaceX's design is rather old school. Thrust from the bottom, payload at the top, axially symmetric. Those thrusters at the top are not used nominally. They are the launch abort system and are activated only when something goes very wrong with the rocket such as an explosion or loss of control. The capsule detaches from the main body and the launch abort system takes the capsule away from the malfunctioning rocket.Davidthefat said:I just saw SpaceX's future plans to make a fully recyclable launch vehicle; I think it is far fetched TBH.
Gack! No! You are apparently talking about the roll program, which rcgldr already discussed to some extent. Once the roll program has the vehicle in the desired attitude the rotation ceases.torquil said:Don't they also start to spin slowly as soon as possible after launch, to increase stability?
The main reasons for the roll program were to alleviate structural loading problems and to improve line of sight for S-band communications. That it helped the pilot see the ground was a secondary benefit. Once the roll program was completed the Shuttle stayed in that attitude throughout the rest of the launch.rcgldr said:You're probably thinking of the space shuttle which rolled upside down during launch (there were also pitch and yaw adjustments) for aerodynamic load issues on the shuttle, (it also allowed the ground to be used for references by the on board crew, but I'm not sure how useful that was). I'm not sure why the shuttle wasn't simply attached to a launch tower so the roll manuever wasn't required, unless the setup was historical (not an issue for previous rockets), and too costly to redo. Most rockets don't spin during launch.
Not all that similar. An inverted pendulum is unstable. A properly designed rocket is stable.ColinW said:Look up "inverted pendulum". The control principles are similar. Plenty of examples on Youtube.
D H said:Not all that similar. An inverted pendulum is unstable. A properly designed rocket is stable.
A rocket doesn't stay in one direction. It has to turn as it climbs. Plus there are winds to worry about, max Q, and a host of other problems. Most importantly, the rocket has to attain the orbit that the mission planners want it to be in. A rocket without vernier controls will end up far from where the planners want it to be. Stability isn't the only concern, and just because a rocket is nominally stable doesn't mean control problems won't arise.ColinW said:Make your mind up! One post you say they use gimbaled thrusters to maintain stability, next post you say they don't need them.
It's the other way around. Stability is a nice-to-have but is not essential. Controllability is absolutely essential.Filip Larsen said:It seems to me that an abort systems not necessarily has to be controllable (but of course still stable) during its short burn as the main purpose of that subsystem is to separate the manned section from the main hazards during a launch vechicle break-up.
The Shuttle was not safe all the way from pre-launch to on-orbit. New human-rated vehicles must be, at least on paper.I would not be surprised to learn that such systems are design to work safely only in cases where the abort is initiated from normal attitudes.
Yes, a rocket is nominally stable if the center of press is well behind the center of mass. Stability is not the only concern. A rocket that is going to put something into space had better come close to the planned orbit. It is much cheaper fuel-wise to correct errors as they occur than it is to correct errors after the fact once the vehicle has attained orbit.jetwaterluffy said:Try to keep the center of pressure behind the center of mass by more than the diameter of the rocket and the air resistance will keep it straight. That's what I was told! (But that was for a small- scale rocket which only goes up 200m)
D H said:It's the other way around. Stability is a nice-to-have but is not essential. Controllability is absolutely essential.
Antiphon said:I think the basic thing on the OPs mind is: why is a rocket stable if the center of thrust is below the center of mass? It seems counterintuitive because you can pull a dolly with a rope but you can't push it with a stick.
D H said:Other than the reusable aspect, SpaceX's design is rather old school. Thrust from the bottom, payload at the top, axially symmetric. Those thrusters at the top are not used nominally. They are the launch abort system and are activated only when something goes very wrong with the rocket such as an explosion or loss of control. The capsule detaches from the main body and the launch abort system takes the capsule away from the malfunctioning rocket.
I was not being denigrating when I called the SpaceX design "old school". Besides, it's not completely "old school". They are doing many new things with respect to reusability. And with respect to ops. And logistics. And manifesting. One of the biggest lessons learned from the Shuttle program is that the cost of the vehicle itself is a tiny part of the total program cost. Operations, the logistics train, and payload integration can swamp the vehicle costs.Davidthefat said:Isn't the old school design the safer design?
Yep. Side mount creates a whole lot of problems.I mean there really is no way to bail out of a space shuttle, at least with the traditional design, there is a way to survive. Since the human cargo is at the top, there is nothing to "fall" on it to disable it like how the Columbia mission epic-ly failed.
That's a different problem. Those incidents typically happened shortly after launch, when the vehicle's air speed is near zero. A vehicle is stable if the center of pressure is below the center of mass. When a vehicle is barely moving there is no center of pressure, making the vehicle a lot less stable. Note also that a similar problem exists (no center of pressure) once the rocket is outside the atmosphere.Antiphon said:Very clear to me now. Also explains footage of rocket tests where the thing starts doing slow cartwheels.
The shape of a rocket plays a crucial role in its stability during liftoff. The long, narrow shape of a rocket helps to reduce air resistance, allowing it to move smoothly through the atmosphere. This streamlined shape also helps to keep the rocket pointed in the right direction as it ascends.
Fins are an essential part of a rocket's design and contribute greatly to its stability during liftoff. Fins are located at the bottom of the rocket and help to keep it pointed in the right direction by creating drag, which helps to counteract any forces that may cause the rocket to tilt or spin.
The center of mass, also known as the center of gravity, is a crucial factor in a rocket's stability during liftoff. The center of mass must be located below the nose of the rocket, known as the center of pressure, in order to maintain stability. If the center of mass is too high, the rocket may become unstable and tip over.
A guidance system is a critical component of a rocket's stability during liftoff. It uses sensors and control mechanisms to monitor the rocket's orientation and make necessary adjustments to keep it pointed in the right direction. This helps to counteract external forces, such as wind or air resistance, that may affect the rocket's stability.
Thrust vectoring and gimballing are techniques used to control the direction of a rocket's thrust. By adjusting the direction of the engine's exhaust, these techniques can help to keep the rocket stable during liftoff. This is especially important during the initial stages of liftoff when the rocket is still close to the ground and more susceptible to external forces.