In order to get a good idea of cruise performance before and after the modification, I used Foreflight track logs and the 3 leg GPS method outline here:
http://www.kilohotel.com/rv8/rvlinks/ssec.html
To measure cruise speed, I flew three stable legs 120 deg from each other at a stable temp and pressure altitude at various power settings as determined using my CGR-30P, and then took the mean magnetic course and true airspeed of 10 measurements from the track log once stabilized on a direction, and plugged those values into the Excel spreadsheet described above. It’s possible to derive a drag coefficient and Oswald efficiency factor from the TAS and %Power from that data by plotting the data as shown here for the flight with the VG’s on:
Donald Crawford’s “A Practical Guide to Airplane Performance and Design” was used to calculate those parameters, and they in turn can be used to predict aircraft performance at standard altitudes:
Based on the data, there’s negligible difference in full throttle at sea level, but up to 3.5 KTAS loss in TAS at 14,000 ft. At 7,000 ft, only about 1.4 KTAS is lost at full throttle.
Stall speed was measured by averaging the indicated airspeed of three stalls per flap setting at the same temp and pressure altitude; that data, along with the onset of the stall warn horn, corrected to gross weight and reported as mph:
The full flap stall speed was hard to determine with and without VG’s because the airspeed indicator was very near the zero indication and the airplane just quit maintaining altitude without a detectable buffet to initiate recovery, both with and without the VG’s.
At 0 deg flaps, the data appears to show about a 14% decrease in stall speed, and at 20 deg only a 2% decrease in stall speed. I suspect that the truth is somewhere in between as the indicated airspeeds were measured at very low indications on the airspeed dial, and as mentioned above getting a firm airspeed corresponding to a stall buffet was essentially impossible at full flaps.
So, how does it fly? Aileron and elevator control feel more precise without being fidgety at low airspeed. The conventional short field takeoff on a smooth surface with the control wheel held back until the aircraft lifts off no longer has a wallowing feeling and the lift-off is definitely more positive. The tailwheel will get beaten up if I use that technique at my home strip, however, a tail low takeoff with rotate at 40-45 mph achieves a positive rate of climb with just of touch of stall warning vs. 50-55 before. Previous landing speeds using a tail-low wheel landing (not 3 point) landing technique at my rough-surfaced landing strip used to be 70 to 75 mph IAS depending on gross weight, but are now flown at 60 – 65 mph IAS, with the stall warning coming on in the flare/power off. Takeoff and landing distances appear shorter, perhaps 15% or so.
Overall, probably worth it. Lost a touch of cruise speed, but gained improved control and a slower takeoff and touch down speed with negligible weight and balance change.
