Warning, anecdote: I can say that climbing out of Stehekin in Mike Creek's 250hp 4-place with 3 aboard at 65-70 mph was quite steep.

It seems like in those steeper pitch attitudes, the head pressure would increase as the column of fuel vertically would actually increase in height (at least for the outlet that counts.)

Hey I plan to go into Stehekin here for the first time when they open it up!

But wouldn't the max head pressure, at the fuel valve in this case, be in level flight? Thinking when you pitch up you're rotating the fuel valve about the wings and moving it up in relation to the (rear) tank pickups? If we're talking minimum fuel, which I believe is the scenario to be tested for flow rates.

When I had my RV-7 AW inspection I had to show the results of my fuel flow test. AC 90.89B has a procedure for determining the fuel flow rate starting on page 33. Here is most of the test.

"Fuel Flow. A fuel flow and unusable fuel check is a field test to ensure the aircraft engine will get enough fuel to run properly, even if the aircraft is in a steep climb or stall attitude, and is accomplished by:
(1) Place the aircraft’s nose at an angle 5 degrees above the highest anticipated climb angle. The easiest and safest way to do this with a conventional gear aircraft is to dig a hole and place the aircraft’s tail in it. For a nose gear aircraft, build a ramp to raise the nose gear to the proper angle.
(2) Make sure the aircraft is tied-down and chocked. With minimum fuel in the tanks, disconnect the fuel line to the carburetor. The fuel flow with a gravity flow system should be 150 percent of the fuel consumption of the engine at full throttle. With a fuel system that is pressurized, the fuel flow should be at least 125 percent. When the fuel stops flowing, the remaining fuel is the “unusable fuel” quantity.
(3) The formula for fuel flow rate for a gravity-feed fuel system is 0.55 times engine horsepower (HP) times 1.50. This gives a fuel flow rate in pounds of fuel per hour. Divide the pounds-per-hour number by 60 to calculate pounds per minute, and divide again by 6 to calculate gallons per minute. To get gallons per hour for Avgas divide pounds per hour by 6; or multiple gallons per minute by 60. For a pressurized system, substitute 1.25 for 1.50 to calculate the fuel flow rate.
(4) The fuel consumption rate of most modern engines is about 0.55 pounds per hour per brake HP.

Still looking for a pitch setting. I would think a flight path angle during best rate of climb at a light weight, in conjunction with the angle of attack of the wing would give us a pitch setting we could target for this test. Digging a hole for the tail wheel helps, but lacks a scientific, repeatable, valid and accurate answer to my question.

Maybe the 5 degrees above the climb angle take the angle of attack into account?

After writing Post #5, I recalled reading this report of a flight test evaluation of the Prototype Patrol...


Author Greg King says the prototype Patrol Angle of Climb at Vx at 1300 lbs. was 19 degrees. So, a test in accordance with AC90.89B would require a 24 degrees pitch setting......time for a reality check, will the Patrol fly with a 24 degree nose up attitude in full power climb?

Blindly following AC90.89B advice and digging a little hole for the tail wheel will be easiest and a photo might convince the DAR that your test was valid. But if you are a thinking person, and want to know a factual answer for 5 degrees above the highest anticipated climb angel, you will need a deep hole......a 35 inch deep hole will put the level datum at 24 degrees ( Vx of 19 degrees plus AC90.98B recommendation of 5 degrees)

Seems to me a real world Vx flight test evaluation/demonstration during the Test Flight phase is a reasonable and prudent course of action. Also a prudent builder might impose a Pitch attitude limitation to limit extreme attitudes with small amounts of fuel to ensure no spectacular events with a Patrol get recorded on video during your favorite STOL event.

I don't classify digging holes as recreation, so I used two cinder blocks under each wheel. If that isn't enough, one could remove the tailwheel and get a few more degrees. Once you get it all figured out, please consider doing a Beartracks article or a write-up for the KBM. There is an entry for the test on the map, but it does not yet have an instructional post.

Here is what I did with my 4-place Bearhawk:



Eric Newton

Welcome back Eric!