I think Hitech's point that "turn performance would degrade or possibly remain the same" implies that the elevator normally has more authority than it needs. I don't think anyone said it would fly normally. I thought we were talking about flying better than intuitively expected.
There have plenty of comments from folks that the aircraft missing a stab turns as well or better, that's what pretty much started this thread. That just shouldn't happen because of structural loads or instability. If it were true, why add all the extra weight and complexity of that "redundant" stab??? Just leave it off and you're good to go with a lighter and less complex airplane!
If the stab attachment is built into the fuselage in some manner and has the effect of a continuous spar then it's not a continuous spar but I don't think it's worth quibbling over definitions.
I didn't say it was a continuous spar, I said it acted like one and qualified my comments with "in essence" and "essentially". This is really, really basic mechanics for levers here so I'll try one more time. With a complete horizontal stab generating approximately equal lift from tip to tip the resulting stress at the fuselage junction is in essentially a straight line normal (i.e., 90deg) to the spar. With a single stab the type of stress is completely different, it's not a straight line, it's a twist. Maybe this example will make sense. Glue a block of wood to a wood deck and try to pull the block straight up with all your strength (say 200lbs). With good wood glue this would be very difficult or even impossible to do. That is a "normal" load, in other words it's 90deg to the joint and in the direction of the joint's maximum strength and can easily handle that 200lb pull. That's the type of stress created by a complete stab. Torque is a completely different type of stress. Attach one end of a horizontal 2x4 (a hypothetical single "stab") to the block and pull up on the other end of the 2x4 with the same 200lbs you used previously. The resulting torque will probably easily twist the joint apart. This demonstrates that the uneven leverage (or torque) is much more capable of separating the joint than a straight pull so it's not just the load that matters but how it's applied. If this still doesn't make sense then you'll just have to trust me and yes, my degree is in engineering.
I assumed that the attachment points pictured were part of a fuselage structure that was designed for more than the anticipated normal range of loads. I will happily call it a continuous spar for this discussion. I just don't see where it makes a difference since the individually attached stab is designed for the forces applied to it.
It has nothing to do with the stab itself, it has everything to do with the fact that the stress applied to the fuselage juncture with a single stab is pure torque, not the normal "forces applied to it" that the aircraft designer intended.
You haven't shown where the attachment requires balanced forces on both sides in order to maintain structural integrity which I believe is the point in contention.
I didn't say it required balanced forces or that it would automatically come apart, I'm saying that it's unlikely that sufficient structural margin exists to handle very high torque stresses that were
never intended to be applied. I've personally seen the tips of F14 horizontal stabs bend downward (as the wingtips bend up) while generating maximum pitch rates. That's a lot of load on those suckers and I wouldn't want to see what happened if I generated the same load with a single stab.
Aircraft design is really a balancing act. Make things too weak and they break, make things too strong and the airplane gets too heavy. All aircraft are "overdesigned" to a degree to provide a safety margin and that margin is specified in contracts and MILSPEC. For instance an aircraft with a +6G limit will not fall apart at +6.1G but it will begin to have permanent deformation and/or structural failure at some point. Take the +6.0g wing and push it to -6.0G and it probably will fail as that's not the load it's designed to handle. As I mentioned previously, the F14 was specifically designed to handle the torque produced by differential tails, that's what makes it roll (well that and spoilers). Even so, when they added new computers for the stability augmentation system and tested its improved roll capability the test aircraft was severely overstressed and damaged by the torque. Basically what happened is the increased torque produced by the differential tails with the new computers exceeded the safety margin and almost twisted the back end of the airplane off of the front end.
Still, much of this argument may be moot given HiTech's comments about loads being reduced by reduced static stability but it's an interesting discussion anyway. I still contend that the airplane will not fly anywhere near "normal" as some people here have claimed and you certainly wouldn't be able to continue to fight with half your stab missing.
