Falcon 9 TVC: Which engines participate in roll control?

Question

Stage 1 of Falcon 9 uses its gimballed engines during launch to control roll, pitch, and yaw.

Only the eight peripheral engines can be used for roll control since the center engine couldn't possibly exert a significant counter torque about the rocket's length axis.

But eight engines seems overkill for roll control... Do they all participate in roll control or is it just a subset of the eight that do?

It seems four engines would suffice, or maybe even just two (in pairs of diametrically opposed engines).

Sources would be appreciated, but if you don't have them handy, a comment pointing me in the right direction would still do.

Would be curious also if all engines participate in pitch and yaw control, or if again only some of them do. Thanks!!!

Answer 1

As Jörg W Mittag says, we don't know. But since they can gimbal all of the engines, I'd be surprised if they didn't.

Gimbaling all of the engines a little, as opposed to gimbaling just a few of them a lot, has (at least) the following advantages:

• It generally maximizes the clearance between adjacent engine bells, since you're turning all the engines by the same amount in approximately the same direction. Especially for roll control, if you only gimbaled some of the outer engines, the bells on the ones you did gimbal would get pushed closer to the bells of adjacent non-gimbaling engines.

• It minimizes cosine losses: when you tilt an engine with $F$ Newtons of thrust by an angle $\alpha$, your forward thrust drops to $F \cos(\alpha)$ Newtons, but you gain $F \sin(\alpha)$ Newtons of lateral thrust in exchange. For small angles, $\sin(\alpha) \approx \alpha$ (in radians), while $\cos(\alpha) \approx 1 - \frac12 \alpha^2$. Thus, to obtain some desired amount of total lateral thrust, it's better to tilt more engines by a smaller amount, since the lateral thrust from each engine scales linearly with the gimbal angle, but the loss of forward thrust scales quadratically.

  (Of course, what you really want is some desired amount of lateral torque, and for that, engine placement matters too. In general, if you have engines at different distances from the desired rotation axis, as in the old Falcon 9 v1.0 engine configuration, you'll want to gimbal the outer ones more since they provide more torque per thrust. But with the "Octaweb" arrangement used by SpaceX since Falcon 9 v1.1, all of the outer engines are at the same distance from the roll axis. And for pitch and yaw, all the engines are approximately the same distance from the axis anyway, being all located at the tail end of the rocket.)

• By keeping adjacent engines pointing in approximately the same direction, it also keeps the plumes of those engines from impinging on each other. Honestly I have no idea if this matters in practice, but such impingement might potentially have some negative effect on the vessel's aerodynamics and/or heat management by creating unwanted turbulence and/or pressure variations in the combined plume of the engines.

In general, the only reason why you might not want to use all your engines for attitude control is if you can't, e.g. because you prefer to save on mass and/or cost by making only some of your engines able to gimbal at all, or by restricting them to only gimbal along one axis. But AFAIK all the Merlin engines on Falcon 9 have full two-axis gimbal control, so they can all be used for all attitude maneuvers (except, obviously, that the center engine cannot exert any roll torque), so there's no really reason why they wouldn't use them all.

Answer 2

We don't know.

What we do know is that the Falcon 9 has engine-out capability which means you cannot pick a fixed setup beforehand, you have to be able to adapt to the loss of any one of the 9 engines.

Other than that, everything is possible.

We also know that SpaceX is constantly improving and changing, so what is true today is not necessarily true tomorrow and was not necessarily true yesterday. It is very well possible that the answer is "all of the above, at some point in time, in some version of the flight software".