Same thing when exiting the turn i imagine...? If banking left then lead with left rudder, if banking right lead with the right rudder. Basically the opposite of a sideslip (crabbing) ?
Based on this, can't you simply ignore the ailerons for entering the turn, using only rudder to kick yourself into it and simply using roll and pitch to hold your angle? Once you're done, tap the rudder in the other direction and you're level again.
If the left and right ailerons move in opposite directions but an equal amount during a bank, wouldn't the drag created by the ailerons be equal? What determines that one aileron creates more drag than the other in a bank?
Look up videos on the Prandtl wing and truly understand adverse yaw for the first time. Interesting stuff. (It's how birds manage without a vertical stabilizer).
I don't want you or the viewers to misunderstand me, but I must correct you at some points in order to not let some things misunderstood: 1. The asymmetric drag doesn't come from induced drag only! It's the total drag (5 types of drag in 2 categories) differentials along the undisturbed airflow vector's axis which finally creates the yawing moment. To make it clearer, the flight spoilers (usually the airliners use them) further reduce the induced drag component (the only type of drag that you used in the explanation) on the lower lift wing while the result being a relatively low to non-existent opposite yaw due to roll (adverse yaw), not greater as if only the induced drag would've taken place. The total resultant drag is important. For the sake of this "adverse yaw" topic, what does happen with the yawing moment when both wings produce a negative lift (on zero dihedral wing configs) when deflecting the ailerons? 2. Turning moment is wrongly used in the discussion! The turning is related to the trajectory or the movement of a body about an axis (it can be any), while yawing, rolling and pitching movements are related only to their specific axis.
Thank you, I could understand in less than 5 minutes what was explained in 30 mins by my teacher. This is a great video and a great explanation!
A good simplistic explanation for correction, which is what I needed! Thanks.
Pro tip : watch series on kaldrostream. Me and my gf have been using them for watching all kinds of movies recently.
@Korbyn Holden Yea, been using kaldroStream for months myself =)
@Korbyn Holden Yup, been watching on kaldroStream for months myself :D
Same thing when exiting the turn i imagine...? If banking left then lead with left rudder, if banking right lead with the right rudder. Basically the opposite of a sideslip (crabbing) ?
Ok🔔👍🏽👍🏽👌🏾👌🏾
Based on this, can't you simply ignore the ailerons for entering the turn, using only rudder to kick yourself into it and simply using roll and pitch to hold your angle? Once you're done, tap the rudder in the other direction and you're level again.
The force experienced in using rudder only could possibly lead to rudder detachment or breakage
@@saketsagar2156 well yeah maybe, but at normal flite speeds you need only use very little rudder deflection.
If the left and right ailerons move in opposite directions but an equal amount during a bank, wouldn't the drag created by the ailerons be equal? What determines that one aileron creates more drag than the other in a bank?
they move asymmetrically for starters
@@operationscomputer1478 if they were to move symmentrically there will be no need to use rudder?
More lift = more drag on the downward one verses the upward one.
Relative wind to the surface of given aileron determines the magnitude of drag which cannot be same for both aileron during turn
@@429thunderjet2 why is there more lift on a downward alieron?
Look up videos on the Prandtl wing and truly understand adverse yaw for the first time. Interesting stuff. (It's how birds manage without a vertical stabilizer).
I don't want you or the viewers to misunderstand me, but I must correct you at some points in order to not let some things misunderstood:
1. The asymmetric drag doesn't come from induced drag only! It's the total drag (5 types of drag in 2 categories) differentials along the undisturbed airflow vector's axis which finally creates the yawing moment. To make it clearer, the flight spoilers (usually the airliners use them) further reduce the induced drag component (the only type of drag that you used in the explanation) on the lower lift wing while the result being a relatively low to non-existent opposite yaw due to roll (adverse yaw), not greater as if only the induced drag would've taken place. The total resultant drag is important.
For the sake of this "adverse yaw" topic, what does happen with the yawing moment when both wings produce a negative lift (on zero dihedral wing configs) when deflecting the ailerons?
2. Turning moment is wrongly used in the discussion! The turning is related to the trajectory or the movement of a body about an axis (it can be any), while yawing, rolling and pitching movements are related only to their specific axis.
perfect thank you
Thank You
Good.
Got you
Not so good