Could the Camel turn faster to the right due to gyroscopic effect than could be expected if it was fitted with a conventional engine of equivalent power and weight?
This is something that you could certainly test in simulation, provided the gyroscopic effect is modelled accurately (by simply switching it on and off while testing). So I will put down some ideas as a general outline of this new question:
As we all know in physics (Newtonian physics, Einstein opened a real can of worms beyond the scope of this debate) you can't get something for nothing. So any idea that the gyroscopic effect somehow 'powers' the turn seems invalid. For one thing, there is inertia in the spinning mass which must be overcome. I did some quick experiments with a gyroscope and obtained the following (admittedly rough) data:
Time to spin to a stop from an approximately equal rpm:
No applied torque, gyro spinning freely undisturbed - 3 mins 55 secs
Continual applied torque, gyro free to rotate under precession - 4 mins 05 secs
Continual applied torque, gyro prevented from rotating under precession - 1 min 45 secs
Given some margin for error we can see that by allowing the precession to occur unchecked the energy in the spinning mass dissipates normally, i.e. as when the gyro is undisturbed. But when the precession torque is corrected (the spinning mass prevented from precessing) the energy in the spinning mass dissipates much more rapidly.
This certainly has implications for our infamous left turn with all its' corrective measures (energy drain on engine) but more importantly it demonstrates that the energy to overcome any resistance to the resultant torque originates in the spinning mass, which clearly loses energy when the resultant torque meets resistance. So this is not 'something for nothing', but a valid 1:1 transfer of energy from one axis to another through the spinning mass.
If we now imagine an aircraft with poor rudder authority but more than sufficient elevator authority, equipped with a rotary engine such that a right hand turn might be attempted by simply banking right and pitching up, it seems possible that the resultant gyroscopic torque (right yaw) could indeed occur with more energy than by mere application of rudder, due to the transfer of energy from the 'strong' axis to the 'weak' axis via the gyroscopic effect. If we imagine that same aircraft to have most of its' mass located in very close proximity to the C of G, and consider the effects on the turn of that design in addition to the gyroscopic effect, we can begin to imagine how rapidly this aircraft might turn to the right. No doubt you possess the data on maximum pitch and yaw torques for the Camel, so you can probably evaluate this theory easily.
If that same aircraft was fitted instead with a conventional engine, the entire mass concentration around the C of G would need to be changed due to the unique compact design of the rotary engine. This makes any comparison of turning with and without gyroscopic effect difficult, but still possible by flight testing in simulation.
So in answer to this new question, I would say 'yes' for the following reasons:
1. If the Camel had been fitted with a conventional engine, the entire design would have been different and would be unlikely to turn as rapidly or tightly.
2. If a conventional engine of equal size and power had been available, poor rudder authority would have resulted in a less rapid right turn (and yet a more rapid left turn).
Therefore a conditional 'yes', because at the time there was no other way to achieve this turn rate other than with gyroscopic effect from a small engine situated close to the C of G. The designers at the Sopwith plant seem to have designed the aircraft specifically for this ability following on from their experience with the Pup. The Fokker Dr1 may very well have been an attempt to produce an aircraft of similar performance, but I believe the attempt failed for a number of reasons, not least of which that the Dr1 failed to make as effective use of the gyroscopic effect due to less spinning mass, mass distribution and less power.
HiTech, you clearly want to model flight accurately and just as clearly have the necessary knowledge and skills to achieve the best possible outcome. But models are models and there are bound to be limitations. For instance, I have an old gliding habit of coming in too high on finals (better high than low deadstick lol) and sideslipping to wash off the extra alt, but I have not been able to find a simulation which allows me to do this (other than RoF, which has other issues I can not live with). Anyone following me in must think I am drunk (often true lol) or a terrible pilot (hopefully not entirely true) as I stubbornly swing from one side to the other while the FM modifies the slip and forces me off track. I heave on the stick and kick hard on the rudder in the forlorn hope that your zero torque sum will come to my aid but alas, I can only enjoy the sensation briefly before the rudder authority fails and I end up being forced to swing it across the other way.
So I think you would agree with me that while the highest level of authenticity is sought, there must always be shortcomings. The goal in the end is surely entertainment, and I doubt you would recommend that someone with high hours on an AH Mustang for instance should climb into the cockpit of a P51 at the next airshow and strut their stuff. So if entertainment is a key factor, perhaps I could suggest that issues such as this might be dealt with in less clinical fashion. What has developed in this instance into a rather cold scientific debate might instead be approached from the point of view where historical evidence carries as much weight as raw data. Just a few thoughts, and I've probably drifted off topic (apologies).
Certainly neither of us has flown either a Camel or a Dr1 (and I for one hope never to do so lol). Therefore I think we must look closely at the science, but also make use of whatever evidence we can obtain from historical notes, flying models and the very few replica aircraft still flying. I've contacted the warden of one such aircraft but as yet had no reply.
I do know my campfire etiquette, and bringing a tin of beans to your fire does not give me the right to mess with it. I can enjoy its' warmth and if invited maybe poke it with a stick, but I must always fart downwind and never pee on it. So thanks for being both patient and helpful, I trust my enquiries were not too much of a nuisance. I merely hoped to make a suggestion in the first instance, and perhaps a small positive contribution in the second.
Again conforming to good etiquette, I think you should have the last word (answers to any questions notwithstanding).
Salute
