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Has anyone else thought of installing a third autopilot servo? The rudder would be more challenging than the aileron and elevator, because the rudder doesn't use a closed loop system. My goals would be to come up with a method that makes it virtually impossible to foul the pilot-driven rudder cables (obviously), and that it be possible to install the system in a covered fuselage, because, well, I don't have an uncovered fuselage.
This thread shows a version of rudder servo on the RV:
It looks like the goal is to create a little closed loop somewhere in the system, and connect the servo to that. Here is another idea with a bellcrank mounted to the airframe, but it looks much more cantankerous:
Both of these installations look to me like they put a lot of side displacement on the rudder cable, and being that the RV-10 has a little black plastic grommet at the bulkhead and not even a fairlead, this seems problematic. Wouldn't it be great if a bridle system was able to apply the force in a more parallel and coaxial way to the original rudder cable?
Here's what I imagine for the rigging: visualize a capstan servo with a bridle wire that is oriented span-wise across the fuselage. That bridle wire would then turn aft 90 degrees at a pulley (probably a few more degrees than 90) and join the rudder cable with a bolt-on plastic block like in the Garmin VAF link above. The pulley would need to be vertically as close as possible to the rudder cable, to keep from displacing the rudder cable vertically. I'd create a bolt-on bracket that would hold the pulley onto one of the mostly vertical fuselage tubes, and position it laterally so that the aft-pointing cable exits the pulley on the same vertical plane as the rudder cable. This would eliminate left-right deflection of the rudder cable.
Station F, right behind the cabin, is the easiest to access, but bottom of the mostly-vertical t10 tubes is cluttered with cabin sides, and it wouldn't be easy to bolt on a pulley bracket. Moving back to station G, there is better access to the mostly vertical t7 tubes, and it is close enough to still be accessible from the cabin. The rudder cables don't have a fairlead at station G, so there may be concern with rubbing if they bounce up and down and collide with a pulley bracket. Also, as the rudder cables move aft in the fuselage, they also move up vertically a little. This would give more mounting area on the t7 tube for a pulley bracket.
The standards tell us that a fairlead shouldn't exceed 3 degrees of cable deflection, so that leads me to pulleys. I haven't been able to find the standards for pulleys, other than here:
Perhaps someone knows of a better source? I've tried using the specs from the ACS page to narrow down the best pulley to use. Since the bridle cable is 1/16 inch, that rules out all of the MS20220 series. The MS20219 is allowed for 1/16, but the -1 is not allowed for flight controls. So that leaves the -2 and -4. The -3 has a huge diameter bore, so we can rule out that one.
Regarding the MS24566 series, it says AN210-1A, AN210-3A, AN210-1B and AN210-3B shall not be installed on frequently used aircraft controls to bend the cable more than 15 degrees from a straight line. So in that series only the -2 pulley would be acceptable. For some reason the -2 pulley is larger than the -1 and -3, thanks to the guy who came up with that.
I'm not sure to what degree these standards apply in this type of application, especially with not having their source. And we are bending the secondary cable, not the flight control cable. Doesn't a rudder autopilot count as secondary? I'm not sure. It seems that rudder trim would be secondary.
Please share any thoughts that you might have on this topic!
This thread shows a version of rudder servo on the RV:
It looks like the goal is to create a little closed loop somewhere in the system, and connect the servo to that. Here is another idea with a bellcrank mounted to the airframe, but it looks much more cantankerous:
Both of these installations look to me like they put a lot of side displacement on the rudder cable, and being that the RV-10 has a little black plastic grommet at the bulkhead and not even a fairlead, this seems problematic. Wouldn't it be great if a bridle system was able to apply the force in a more parallel and coaxial way to the original rudder cable?
Here's what I imagine for the rigging: visualize a capstan servo with a bridle wire that is oriented span-wise across the fuselage. That bridle wire would then turn aft 90 degrees at a pulley (probably a few more degrees than 90) and join the rudder cable with a bolt-on plastic block like in the Garmin VAF link above. The pulley would need to be vertically as close as possible to the rudder cable, to keep from displacing the rudder cable vertically. I'd create a bolt-on bracket that would hold the pulley onto one of the mostly vertical fuselage tubes, and position it laterally so that the aft-pointing cable exits the pulley on the same vertical plane as the rudder cable. This would eliminate left-right deflection of the rudder cable.
Station F, right behind the cabin, is the easiest to access, but bottom of the mostly-vertical t10 tubes is cluttered with cabin sides, and it wouldn't be easy to bolt on a pulley bracket. Moving back to station G, there is better access to the mostly vertical t7 tubes, and it is close enough to still be accessible from the cabin. The rudder cables don't have a fairlead at station G, so there may be concern with rubbing if they bounce up and down and collide with a pulley bracket. Also, as the rudder cables move aft in the fuselage, they also move up vertically a little. This would give more mounting area on the t7 tube for a pulley bracket.
The standards tell us that a fairlead shouldn't exceed 3 degrees of cable deflection, so that leads me to pulleys. I haven't been able to find the standards for pulleys, other than here:
Perhaps someone knows of a better source? I've tried using the specs from the ACS page to narrow down the best pulley to use. Since the bridle cable is 1/16 inch, that rules out all of the MS20220 series. The MS20219 is allowed for 1/16, but the -1 is not allowed for flight controls. So that leaves the -2 and -4. The -3 has a huge diameter bore, so we can rule out that one.
Regarding the MS24566 series, it says AN210-1A, AN210-3A, AN210-1B and AN210-3B shall not be installed on frequently used aircraft controls to bend the cable more than 15 degrees from a straight line. So in that series only the -2 pulley would be acceptable. For some reason the -2 pulley is larger than the -1 and -3, thanks to the guy who came up with that.
I'm not sure to what degree these standards apply in this type of application, especially with not having their source. And we are bending the secondary cable, not the flight control cable. Doesn't a rudder autopilot count as secondary? I'm not sure. It seems that rudder trim would be secondary.
Please share any thoughts that you might have on this topic!
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