Found some other interesting things, from the same webpage-
In reference to the spitfire's ellptical wings-
The elliptical planform has very small theoretical advantage, but only theoretical, and only valid if the planform is truly elliptical. Spitfire's planform is only approximating elliptical, and what is left has been sold out by the aerodynamic twist it's wing has. It has effect on just one of several factors of wing efficiency, causing a whopping 0.05 improvement in comparison to a trapezoidal planform used in for example Bf 109, that is, IF Spit's wing were truely elliptical...
You also have to take into account the fact that the profile thicknes ratio of Spit's wing is VERY thin, both in maximum and in average. This in turn leads to the small coefficient of lift. This pretty much takes away the advantage of the large wing area.
BTW, ever wondered where did all the elliptical wings go?
If they are so magically efficient, why nobody uses them anymore?
Answer is simple, later aerodynamic research has proven that most of the benefits of elliptical wing were a fallacy created by insufficient or faulty research methods. They simply were not worth the trouble.
Even the developements of Spitfire, Spiteful and Seafang gave up on the elliptic planform and went to normal trapezoid form. Wonder why?
Only thing special in it is the elliptic planform, that dropped of favour just after it, when it was found out that the theoretical benefits of elliptic planform were actually only theoretical, and practical applications did not yield benefits that would justify the almost astronomical manufacturing difficulties and costs.
In Spitfire's case the benefits of elliptic planform (even lift distribution along the span) are nullified by the 2 degree twist (washout) that was needed for at least partially taming the nasty and violent stall behaviour of such wing. In short, the wing twist negated the effect of the elliptical wing. Although the wing was physically elliptical, its lift was not.
Besides, wing aspect ratio has larger effect on the lift/drag characteristics than the Oswald efficiency factor (where the theoretical difference between Spit's and Bf 109's wing is only of magnitude of 0.05), and Bf 109's wing has higher aspect ratio than Spit's...
Spit's wing uses the exactly same NACA 2300 root profile as Bf 109's wing, but with only 13 % thickness ratio, while Bf 109 has 14.2 % thickness ratio. Lower thickness ratio translates to lower Cl max. Bf 109 uses the same NACA 2300 with thickness ratio of 11%, but Spit's wing profile gradually changes along the span to NACA 2200 (more symmetric profile with smaller Cl max) with thickness ratio of only 9 %.
All the above leaves the lower wingloading as the only even theoretical advantage for Spit's wing, but even that is somewhat negated by wingprofile that has less Cl max and Cl in general.
- Pentti Kurkinen, enthusiast
Drop tanks:
The droptank system in every Messerschmitt worked the same way. Fuel to the engine was always drawn from the main tank. The droptank replenished the main tank. This was done with an automatic float controlled device that opened the flow from droptank if the fuel level in main tank dropped. There was no pump driving the fuel from the droptank, it was kept pressurized by bleeding compressed air from the engine supercharger into the droptank.
The plumbing was routed from the droptank to the right upper forward edge of the cabin, and from there along the cabin edge to rear, into the fuel tank. There was a piece of perspex tube at the right side of pilot, from where he could see the fuel flowing. When the tube became filled with air (easy to see from the colour) it was time to release the droptank.
A nice system. If you had to jettison the droptank, you always knew that your main tank was full. And it also did not heed any preliminary actions like turning a feed selection valve or somesuch, just tug the release cord...
"109's controls locked up in high speed."
- Another very mythical subject. Before answering one must be asked: "What model are you talking about?"
- There was large differences between various types in the high speed controls. Each newer version handled better in high speeds, the best being the 109 K series which had flettner tabs for enhanced aileron control - at least in theory, as it is debated whether many Me 109 K-4s actually had those flettners enabled. 109 G series were much better on this regard compared to 109 E, which yet again wasn't such a dog as many claim. 109 test pilots, Russians included, have said that the 109 had pretty good roll at higher speeds - again not as good as the 190s, P-51 or P-47 - but it maintained a good lateral control ability. Recovering from extremerely fast 750-900 km/h vertical dives was the problem - not level flight or even normal combat flying.
- Spitfire and a 109 had equal roll rates at up to 400 mph speeds. Not even the favourite warhorse of the Americans, P-51, exactly shined with its roll rate at high speeds. P-51 pilots have actually said that flying P-51 at high speeds was like driving a truck.
- An often quoted British report made of a Me 109 E talks about the "short stick travel", "due to the cramped cockpit a pilot could only apply about 40 pounds side force on the stick" and "at 400 mph with 40 pounds side force and only one fifth aileron displaced, it required 4 seconds to get into a 45 degree roll or bank. That immediately classifies the airplane as being unmaneuverable and unacceptable as a fighter."
- The report claims that The 109-E needed 37lb stick force for a 1/5 aileron deflection at 400mph. Coincidentally, the Spitfire 1 required 57 lb stick force from the pilot for similar deflection at similar speed. This is a 54% higher stickforce for the Spitfire pilot.
- The British test is taken as gospel by many, while it is just one test, made by the enemy, using a worn out and battle damaged airframe. German flight tests report pilots using aileron forces of over 45 lbs and 109's stick was designed for elevator stick forces of up to or over 85kg, over 180 lbs. Finnish Bf 109 G-2 test revealed that at 450 km/h the stick could be still fully taken to the limit with ~10 kg force (20 pounds). Aileron roll without rudder could be performed to both direction from 400-450 km/h in 4-5 s. This is better than the Spitfire with fabric ailerons, about the same as Spitfire with metal ailerons and slightly below clipped wing Spitfire. So it was more matter of the pilot and the test procedures, than maneuverability of the Bf 109. Several details of that test are suspicious and German chief test pilot Heinrich Beauvais disagreed with it and with Eric Brown. Beauvais tried to get into contact after the war with Eric Brown to discuss the matters, but Brown refused to discuss with him. This being the case, it seems that Brown wasn't willing to listen a pilot who'd flown more on the 109 than he ever had, and was more interested on believing his negative findings of the 109 than being proven wrong by a real expert.
http://www.virtualpilots.fi/feature/articles/109myths/
