Just following up after completing the fuel flow test, I came in with the below results.

Aircraft with 8.5 tires positioned on 2 concrete blocks with the tail on the floor gave me 20 degree pitch angle. Mine was a boosted fuel flow test with a Air Flow Performance boost pump after the gascolator. I disconnected the fuel line at the inlet of the fuel servo. I achieved more than double the required 125% BSFC calculation.

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Those are great numbers! Guess it is easier to pass this test with a pump system versus gravity alone. Is your fuel flow sender ahead of the fuel servo or between it and the fuel spider? I have some 90s in my system and have the Andair boost pump. Well after purchasing it I found out it creates a significant pressure drop when bypassing. Besides the test with the boost pump on I will check flow to the mechanical pump with the boost pump off to make sure it is adequate.

I thought the requirement was to test with the pump off, if you have a pumped system? 150% with gravity flow and 125% with a pump (pump off).

For a 260hp fuel injected engine with no return lines, 125% of peak fuel flow is about 113 to 115 L/hr - AKA - 30.0 GPH

If your system cannot get 125% of max flow with the pump off, based on practical experience from testing and then flying our fuel system - then the fuel pressure will nose-dive when you take-off without the boost pump running or if one pump fails during take-off (measured upstream of the pump).

Our fuel system is Bob's design with a filter, transducer, and boost pump included under the floor. No other changes.

Even with compliant fuel flow, it is still possible get ahead of the fuel system and cause a low pressure condition. It's not common, but it can happen. This situation requires the electric boost pump to stabilize the pressure until you reduce throttle and let the system catch up.

Low fuel pressure can cause issues, although it is rare... normally missing / rough running and lower power output. The bendix injection system will run at cruise power with just a handful of psi.

So the Flight Testing Handbook reference seems vague to me but here is an excerpt from AC 23-16A pertaining to certified aircraft. It talks about gravity fed systems in much the same way as the FAA Flight Testing Handbook for EABs does. Then it goes into a little more detail about planes with pumps:

I think it stands to reason that having better psi without the pump running is a very good idea - but perhaps not required per the FAA. I believe Rob's results are valid for that purpose.

In our setup, with the mechanical diaphragm pump running, at cruise power we see between 23 and 25 psi measured after the mechanical pump. With the electric boost pump running, we see about 28 psi.

At full power we see about 19 psi with just the mech pump, and about 23 with the boost pump. In some cases you can catch the engine with low pressure and I have seen it drop to about 13 psi with just mech pump.

Our system acheived the 125% fuel flow test without the pumps running, but only with a small margin. We did not achieve 150% flow. Flows were measured at the inlet of the mech pump.

With hot fuel system after engine shutdown, fuel pressure can rise to 31 psi (engine off). Turning on the electric boost pump at this stage can create pressures up to 50 psi between the two pumps. Care is necessary, but it hasn't blown our system.

That seems really odd to me. You have fuel pressure before the mechanical pump with the boot pump off? How is that possible? If anything the mechanical pump should be lowering the pressure at the inlet and there is nothing behind it to make 23-25psi. What am I missing?

Rob,

Regardless of what the FAR says or if you interpret the fuel flow to be measured before or after the pump, what you really care about is that the inlet of the pump is always flooded to make sure it's not sucking, then verify that the pumps are able to make the pressure you need. As Zach points out, this is a hybrid gravity/pressurized setup, so, you want to verify both parts independently.

If it were me, I would take a fuel flow test at the inlet of the mechanical pump. I'd look for 31GPH. If you don't have that, then you could in theory have a situation where that pump is sucking. Next, I would do a fuel pressure test at the inlet of the servo with the boost pump on. If you see 25+ PSI, then the pump is working right and you can assume it's inlet is flooded as you saw it flooded all the way to the mech pump. After that I would start the engine and confirm that you get 25+ PSI with the boost pump off.

That process confirms:
Both pumps are flooded to more than 125% fuel flow.
Both pumps are making pressure needed to run the engine.

schu

This is what I did.

Additional thoughts:

I like the fuel system with injection/pumps better than carb/gravity. I know everybody loves gravity because it's so reliable, but is it? Even my 170 has placard about single tank operation during cruise due to unexplained engine stoppages, and both tanks are vented together with an in-air scoop that slightly pressurizes the tank. There are a lot of bearhawks that have hundreds of hours with gravity based systems, but I also know at least one BH member that won't operate with 'BOTH' tanks selected. I suspect the difference is the variety of fuel system routing, especially when people move the fuel valve as they don't like the factory location.

In the case of fuel injection, assuming your boost pump is mounted under the floor, I think it would be really hard to have fuel problems as the fuel line routing is pretty vertical directly to the boost pump, and once it hits the pump, it can force the fuel into the engine. I would bet that most people would have more than 50GPH gravity feed to the pump at that location.

All that said, I think it's important to have 30GPH to the mechanical pump, so that single pump operation is reliable, but should something happen, turning that boost pump on should fix it.

Of course the con to fuel injection is no mogas, or perhaps mogas in one tank and 100ll in the other, then using mogas in cruise only, but I think that's worth it for a fuel system that balances fuel delivery to each cylinder.

Otherwise will disagree, and I have no idea what I'm talking about, so consider that too....

I think the fuel flow test is to be performed with electric boost pump on. If my thinking is wrong, help me understand.

Cut/Pasted text from AC90-89b p.33 below are in Italics. They helped me to form my opinion.

The FAA's Fuel Flow Test objective is to have enough Fuel Flow for proper engine operation until fuel exhaustion.

Any aircraft that has fuel supplied to the engine under pressure has a "fuel system that is pressurized. It is clear to me that the fuel flow test on these aircraft must be performed with the pump ON. How else is an RV-6 going to pass the test?

A Bearhawk with a properly installed Fuel Boost Pump has a very very low bar to pass and can pass the fuel flow test easily with little effort.
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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:

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.

Changing Fuel Flow or Pressure.
If the aircraft’s fuel flow rate is less than planned, there is a volume or pressure problem. An increase in the fuel flow volume may necessitate installation of larger fuel line fittings on the fuel tanks, fuel selector, and carburetor in addition to larger internal diameter fuel lines. To increase fuel pressure, install an electrically driven or engine-driven mechanical fuel pump prior to the first flight.
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Zkelley is of similar thinking as me. The BH system is gravity fed to the pump inlet. Then it is pressure fed. In my perfect world, the pump inlet would never "suck". But then again, in low wing aircraft, the pump inlet always "sucks".

What standard do we test too? If a low wing aircraft is allowed to test to 125%, obviously pump on, why can't we? The high wing gives us an about 1 psi head pressure over a low wing. But I still like the idea of no sucking.

I still kind of think Whee got it right with 1/2" fuel lines.

The issue with a “sucking” pump only comes into play on tanks with dual ports. If the fuel level in one tank gets below one of the ports the pump will suck air and not fuel. I don’t know about all low wing airplanes but many have single port tanks which eliminates the unporting issue. This is the same reason high wing airplanes with fuel injection have header tanks.

I agree with Battson’s perspective on fuel testing but the challenge is testing a fuel system that requires an engine driven pump but not being able to run that pump. However, I do think the FAA guidance expects that the pump will be running during the test.

I chose to test my system by ensuring the electric boost pump was always flooded with fuel. So I tested the gravity fed fuel to the inlet of the boost pump. Then I tested to see if gravity supplied sufficient fuel to the inlet of the engine pump. Then I performed additional testing once initial flight testing was complete.

This is a good discussion.

My answer to both of Battson's questions in post #25.1 is......NO, I do not want the boost pump on during all phases of flight, and I do not want it ON at all times above a certain power setting. The fuel system should tolerate the boost pump to be turned off after take off, then be turned on before landing, and be on when moving the fuel selector valve.

Battson says "The engine could be sucking fuel." If either pump will ever suction feed fuel then a header tank (a tank with a single fuel port) seems to be a prudent installation. If a fuel flow test is done with the boost pump off and it flows 125% at the intake of the second fuel pump I can see we have proven it will not suction feed.

There is a time and place for a header tank, however where you install it and how you vent it matters a lot. You will effectively have a gravity fed fuel system to the header tank, but since the tank will likely be at or below the floor, the fuel up to the mechanical pump may not flow as well causing your mechanical pump to suck slightly. This shouldn't be a problem because you can't unport the header tank, however if you ran the airplane out of gas while on one wing tank, it might be more difficult to restart.

I break down the bearhawk to 3 fuel systems:

Gravity/carb. Build it exactly like Bob says, but I'd also add a cross vent.

Lycoming returnless injection: Build it like Bob says, but make sure you have the fuel flow to the mechanical pump to ensure the gravity part works up to the pump where you pressurize the fuel.

EFI/contiental return injection: This is the complex one. You really want to try and make sure that any parts of the system that are gravity fed are able to flow more than 80GPH as dual electric pumps with an idling engine can cycle this much fuel. Most EFI vendors recommend a header tank. Personally, I avoided this because it's complex, but if I was forced to go this route, I'd probably run 1/2 fuel lines to the dual pump mounted under the pilot seat. This ensures that the lines to the pump hold a bit of fuel and are vertical. I suspect that would keep the pump flooded even at 80GPH flow rates. The con is that this setup wouldn't work with a 'both' setting. You could build a header tank and return the fuel to that, but I'd be very careful to make sure that it's positioned such that the pump is always flooded even under very high fuel flows, is vented to the main tanks, and large enough that the fuel doesn't get hot.

But like I said, I don't have a clue, so it's up to the builder to think this through....

Technically an RV6 is gravity fed to the electric pump(s) which sit just below the fuel tank level in the fuselage correct? The electric pumps have to be on for startup even with a carb, but then in cruise, yes, the engine driven pump is sucking the whole time. But as whee pointed out, there's only 1 port on the tank and no both.