Purpose

This is a blog containing the build history of an experimental home built airplane. The RV-7A is a two place, piston powered, low wing, tractor configuration, tricycle gear, aluminum and composite aircraft. The original purpose of this blog was to document the construction of my experimental category aircraft in order to satisfy the build log requirement for the FAA. Now it's just for the amusement of friends and family as I document some of our aviation experiences. For more information on the RV series of aircraft see www.vansaircraft.com.

Wednesday, May 18, 2016

Step 14.0, Engine first start

Holy smokes that thing is loud!  That was the second thing that went through my mind when I saw the propeller turning on its own for the first time.  The first thing was just the surprise that it happened so quickly.  In retrospect, I guess there is no real reason to be surprised, but it seems that few things ever come along this easily and this was a glittering counter-example to everyday experience.

The one remaining task to perform before starting the engine was to check the fuel flow rate.  I wanted to be confident that when I finally turned the key, there would be fuel ready to ignite.  But in order to get fuel to the engine, I first had to have a place to store the fuel.  The fuel tanks are in the wings so I needed to put the wings back on temporarily.  I say temporarily because I can not transport the plane to the airport with the wings on. But on the other hand, I can't start the plane without the wings.  So on they go, for now.

I built a couple of saw horses that are at different heights to comp-ensate for the wing dihedral. This time around, and with the help of my new saw horses, I found the wing installation much easier.  After the wings were on I could move on to the fuel flow tests.  

To better understand what happens next, I'll explain the path that the fuel takes on its way to the engine cylinders.

The aviation fuel, 100LL, is held in the aforementioned wing tanks, each holding 21 US gallons.

The fuel pickup in each tank begins the fuel's journey to the engine.  The first stop is the fuel selector valve where the pilot chooses from which tank to feed the go-juice.  After the fuel selector the gas goes through the auxiliary electric fuel pump and through a maze of check valves, bypasses, and a filter.  It then goes on to the engine mounted mechanical fuel pump.  Either of these pumps is sufficient to power the engine, we have two for redundancy.  After the mechanical pump, the fuel travels to the fuel servo where it is metered using the mixture control and the manifold pressure. Following the fuel servo, the fuel then travels through the fuel flow transducer and then on to the flow divider, also called a spider.  The spider is so named because of its physical appearance is similar to its namesake.  The spider divides the fuel flow among the four cylinders.  The last stop on the fuel highway is the injector where the 100LL is atomized and inserted directly into each cylinder just ahead of the intake valve.

Center:  Fuel spider
The purpose of the fuel flow tests are to verify that the fuel pumps can supply enough fuel to the engine to sustain flight at high power and with a generous safety margin.  For my plane that number would be 125% of max flow at rated horsepower or about 21.35 gallons per hour.

Fuel test 1.
I broke the connection between the fuel servo and the spider and routed the fuel through a hose to a quart sized graduated container.  I then measured the amount of fuel delivered to the container over a period of 1 minute.  Simple, right?  Well, the fuel was just dribbling out and the fuel pump sounded like it was sucking air along with fuel.  This was troubling to say the least.  The amount of fuel collected after a minute was no where near that which would be required to sustain the motor under full power.

To trouble shoot the low flow rate , I started at the aux fuel pump because that is where I thought I could hear the sound of air being sucked into the lines.  There were no loose connections and no leaking fuel.  I then thought that perhaps the fuel pickup in the tank was sucking air.  But before I could test that I decided to move my attention to the output side of the aux fuel pump and check the flow there.

Fuel test 2.
The flow coming out of the aux fuel pump was quite robust.  In excess of 50 gallons per hour.  So the problem wasn't in the tank, fuel selector, or aux fuel pump after all.

Fuel test 3.  
I moved the collection point to after the mechanical pump, but before the fuel servo.  The flow here was awesome as well.  So now I was back to where I started, the problem was in the fuel servo.

This is when I had to change my operational method, and only as a last resort;  I would take a new tack, going forward, I decided to think a little before I tried stuff.  So it occurred to me that the fuel servo could not provide the flow I was hoping to see because its job is to provide fuel at the optimum ratio of air to fuel.  In my test there was no air component since the engine was not running and consequently, that meant that the servo was doing exactly what it should do -- provide only enough fuel to get the engine started.  Woo hoo! this thinking stuff was starting to pay dividends.

Well, a lot of hours were wasted chasing a phantom problem, but it's better than having a real one.  It was now time to actually start the motor.  After pulling the plane out of the shop, I removed the plugs and poured a small quantity of oil into each cylinder.



Then I rotated the prop by hand for a few minutes to try to get the engine's oil pump primed.  The plugs were then replaced and I positioned my pickup behind the plane to give me something to tie it to because I haven't been able to test the plane's brakes yet.

I have read many accounts of people having a great deal of trouble getting their engine going so I wasn't expecting much on my first try.   I even informed Carol that I would only let it turn for 20 seconds without starting before we would have to abort and let the starter motor cool down.   Carol's job was to video the event and check for leaks with fire extinguisher at the ready.




So as you can see, the engine started quite easily.  The white smoke at the beginning was just the oil that I had previously poured in to the cylinders.  There were no leaks observed and I was able the check the P-Mags.  In addition, the various sensors seemed to all be indicating correctly: oil pressure, fuel pressure, fuel flow rate, RPM, exhaust temperature, cylinder head temperature.  I cycled the prop control and verified the propeller governor was working.  After I looked at everything I could think of I shut it off.  Total run time was about 6 minutes.  So what kind of fuel flow did I actually measure?  I only let the RPM go to 2700 at which point I saw 16.9 GPH.  That is very close to the estimated value using HP*BSFC/6 = 17.03GPH.  More testing will be required and I will need to adjust the stops on the prop governor to limit the RPM.

Since I had the carpet out of the cockpit and since I had the canopy cracked open, my overall impression is that this thing is loud.  Crazy loud.  Like, dragster loud.  With four short pipes and no muffler it is not entirely unexpected, but jeez, this thing is scary powerful.  I was thankful that I thought to tie it to the truck because it was difficult to stop it from rolling. 


Finally, I'll wrap it up with another video that answers the question:
"Yeah it's an airplane, but what else is it good for?"




Answer:  Automatic tailgate lifter and bed liner extractor.

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