“and don’t use castle nuts with cotter pins in there”. Hmm. Isn’t that the exact case (nut subject to rotation) for which use of a castle nut and cotter pin is mandated? Are you depending on the inner diameter of the tube to prevent the nut from coming off or do you have a different solution? Thanks. My bolt, castle and cotter seem ok in there (no contact) and not much slop. Maybe I’m missing something? The bearing sounds like a great idea. I’ll do it if it gets sloppy in future. Still fiddling with the fork at the idler though, so I have more than a passing interest in the whole assembly.

There's lots of talk about the control stick slop. I have it. Maybe a 1/4" deadband in pitch and roll. I was thinking about how much of a non-issue it is while flying yesterday. I've never noticed it without looking for it in flight. If there is something wrong, and getting jammed, of course deal with it, but the design is fine.

I fixed this L/R slop by TIG welding a donut onto the hinge tube, under-drilling and reaming it. The bottom of the sticks I secured with low profile castle nuts that also have nylocs in it (ACS has them). The bolt I cut and hand-drilled to allow for maximum L/R clearance.

While I generally like the simplicity and effectivness of the Patrol design, the torque tube and stick assembly is a bit finicky to get right. From a weight perspective it probably hard to beat though.

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Here is some data. You make the call. I think a good argument to make is the designer trumps AC43.13. But I will be making my build so these nuts are easy to inspect on the preflight.

The text below (in bold and italics) and the attached drawing is cut and pasted from bearhawksafety.com. Its Title is Call out for bolts and nuts at bottom of the control stick. It was issued for the Patrol and LSA December 2013.

Hardware nomenclature.
-AN3-5a bolts are undrilled standard AN3 bolts. (letter "a" at the end is undrilled. absent letter "a" is drilled)
-AN364 nut is a standard low profile elastic stop nut. They are not castleated. The Castle nut is AN310, The thinner shear casatle nut is AN320.


Control stick hardware on Bearhawk LSA Drawing #26 and Patrol Drawing #29.

The bolts and nuts at the bottom of the control sticks are being called out to insure no interference with the torque tube throughout the travel range (see drawing below).

Install the nuts on the side of the control stick that has the most clearance with the inside diameter of the torque tube.

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Slop and rubbing. I no longer have either.

I think the two problems are common with installing this stick. Rubbing of the Push/Pull tube as it enters the torque tube (green Arrow) and stick slop that results in rubbing of nuts on the bottom of the stick (red arrow) Look for and remove all slop from the stick and all rubbing.

Here is the drawing. Below is "How to install/avoid common error" text.
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Slop: Removing L to R Stick Slop
Don't accept stick L to R slop at the upper stick hinge 1/4-28 bolt. and Torque that bolt down tight to 60 in. lbs.

Look at the drawing and visualize the stick moving Forward and Aft. See the Interconnect Tube gently rise and fall inside of the Torque Tube. See the clearances of the Control Stick bolt (RED ARROW....AN3-5A bolt with AN364 shear nut...see drawing in post 5) as it rises and falls inside the torque tube. If there is slop in the stick's 1/4-28 hinge bolt above then these three bolts wiggle inside the torque tube and may contact and rub inside the torque tube as the descend at the bottom of the arc. The front bolt looks like a turtle head as its head moves in and out of its shell. Can you see how L-R slop at the hinge bolt creates a hazard down at the entryway of the tube? If a cotter pin catches here in flight it would be when the stick is being pushed forward. The serious failure mode of this happening can not be overemphasized.

The stick hinge bolt above is 1/4-28. Torque it to 60 +/- 10 in lbs. (AC43.13) My stick had L-R slop until I tightened this bolt to specs. That Castle nut tight to 60 in. lbs. squeezes the tower bushings against the stick bushing and stops the slop. The slight increase friction in the system is negligible. Backing off the nut's torque one flat results in slop returning to the stick. So, the design depends on the Nut being torqued down.

Common error is to...

1) Accept slop as normal.
2) rely on the cotter pin to safely hold the nut on (it will, but...)
3) Believe the torque chart only applies to non-castlated nuts.
4) Think a tight bolt unacceptable because it will increase stick friction.


Rubbing of Push/Pull Tube

To rig the Push/Pull Tube system, Neutralize the elevator. Adjust the aft Torque Tube so the Idler Arm is and the bottom of the arc like Bob shows in his Plans. Then adjust the front torque tube with the Heim Joint threads so the position matches the plans.
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The Elevator has three tubes. Bob calls them (starting from the front) The Interconnect tube and one forward & one aft Push/Pull Tube.

Look at the green arrows. Again visualize moving the stick for and aft and See the tube rise and fall inside the torques tube. Widen your sight picture and see the Idler Arm at Station F. Can you see it swing back and forth, and see the arc the Heim Joint makes as the stick is moved? It also moves up and down. If you have the elevator system all assembled and functioning, the system stops when the elevator reaches full travel by the Elevator Horn in the tail hitting a tube welded to the fuselage. Thats key.

Adjustment of the three Heim Joints does nothing to adjust the elevator stop.

The ONLY thing the three Heim Joint adjust are the position the Idler Arm at Station F and the stick. IF the rigging of the system is correct the rise and fall of the Push/Pull tube will be perfect. If not expect rubbing at the entrance of the torque tube when stick is back and at the left and right stop.

To see why look at the drawing's front Push/Pull tube. Now, visualize pulling the stick aft so the elevator hits the stop, then mentally make the Heim Joint adjustment longer and see the stick move aft and also see more of the Push/Pull tube enter the Torque Tube. Do you see T6 - T7 welded joint just aft of the Entryway? That joint begins to enter the torque tube! Make sure that joint does not contact the torque tube with full left and right aileron.

So, The Push/Pull Tube may rub when joint enters the torque tube if things are not adjusted right. Secondly, When The Tube Lengths are off then the the Idler Arm may be off too. The Idler's arc lifts the Heim Joint up, thus it lifts the entire tube up, thus the position of the tube as it enters into the Torque Tube is higher. When Full left/right stick is held then for/aft stick movement is made, you will have that T7 tube rubbing again at the entrance of the torque tube.

Conclusion: Accept no slop in the stick and tighten that 1/4-28 bolt. Accept no rubbing of the Push/Pull tube as it enters the Torque Tube. Rubbing should be prevented by Adjusting the Push/Pull tubes three Heim joints to position the Idler iaw Bob's Plans with neutral stick. This will place push/pull tube entry into the Torque Tube vertically and longitudinally to avoid rubbing at the T6-T7 welded joint.

Hardware
Also, I keep thinking about Pbruce's strong argument from post #2.

I've got shear (thin) castle nuts on the way and still have caution of a failure mode if a cotter pin catches on the torque tube. I Absolute respect his quote above. We have data (post #5) that conflicts with AC43.13 and will experiment with a locking method that has a gentler failure mode than a cotter pin catching. It's a bit creative and will not jive with AC43.13.
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The last week talked you were using AN363 or MS21042 nuts on the lower end of the sticks. Have you rethought that approach?

Yes.

I'm away right now from the hangar. I had my airframe inspected by an IA. But the inspection was Very thorough. VERY! it changed how I look at things. It made me better and changed what I see and how I think.

That and This thread and the input given comes together to some new things. Giving away the 1.5 thread exposure standard plus the washer, plus the hinging action drives me be creative to remove doubt about fastener security. The nut and cotter like Pbruce and Neoma show does that. I'll shortned the AN3-5A bolt like Bob says adn give up the thread exposre but will lock it in place. I see a risk of stick slop maybe returning. I want to experiment with the safety wire of the bolts instead of cotter pins to make the failure mode of a sloppy stick tolerable to to me and maybe please the crusty old OCD mechanic.