Ethiopian airliner down in Africa
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Not all opposing electric trim is stopped. Only main electric (control wheel switch) and autopilot trim. STS is not the autopilot.
.......
And if you insist that something "broke" the column cutout switch design philosophy, STS did it first. It also trims against stick deflection, explicitly to "increase control column forces".
.......
And if you insist that something "broke" the column cutout switch design philosophy, STS did it first. It also trims against stick deflection, explicitly to "increase control column forces".
From this excerpt it seems that there were two discrete actuators for autopilot and for electric manual (hence the need for two cut out switches).
This would also suggest that there could be two electric motors fighting each other when AP and manual el. trim are applied the same time?
Which one would succeed? I would also expect the rate switch to have some impact on available torque. So the outcome may be dependent on AC configuration.
This would also suggest that there could be two electric motors fighting each other when AP and manual el. trim are applied the same time?
Which one would succeed? I would also expect the rate switch to have some impact on available torque. So the outcome may be dependent on AC configuration.
Yoke trim wil outvote A/P trim.
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It looks as if the STAB CUT-OUT switches were set to OFF at around 05:40:39 and remained OFF until around 05:43:06. Presumably, during this period the crew tried to use the manual trim crank wheels to counteract the ND trim which had been applied by MCAS before the STAB CUT-OUT was switched to OFF. The pitch trim trace shows no sign of reduced ND trim using the trim crank wheels so, presumably, the force needed to turn the trim wheels was too great. Switching the manual electric trim back on must have been a last-ditch attempt by the crew to save their aircraft. I'm wondering if the two short manual electric trim inputs just before the aircraft entered its final dive are an indication that manual NU electric trim becomes impossible once ND trim reaches a certain point.
It should be possible to calculate the turning moment about the HS pivot point for a range of ND trim units at various aircraft speeds and elevator positions. This should determine the range of forces which has to be resisted by the HS trim jackscrew. A ground test rig capable of applying this range of forces to a jackscrew could then be used to check the ability of the manual trim (both electric and crank wheel) to apply NU trim under all circumstances.
It should be possible to calculate the turning moment about the HS pivot point for a range of ND trim units at various aircraft speeds and elevator positions. This should determine the range of forces which has to be resisted by the HS trim jackscrew. A ground test rig capable of applying this range of forces to a jackscrew could then be used to check the ability of the manual trim (both electric and crank wheel) to apply NU trim under all circumstances.
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Not all opposing electric trim is stopped. Only main electric (control wheel switch) and autopilot trim. STS is not the autopilot.
[...]
And if you insist that something "broke" the column cutout switch design philosophy, STS did it first. It also trims against stick deflection, explicitly to "increase control column forces".
Bernd
[...]
And if you insist that something "broke" the column cutout switch design philosophy, STS did it first. It also trims against stick deflection, explicitly to "increase control column forces".
Bernd
STS is not the autopilot, and it only operates with autopilot off, but it operates using the autopilot trim signal. It is therefore cutout by (a) the "autopilot" console cutout switch on NG, and (b) the column cutout switch (if in opposing direction). I have multiple references all clearly stating this and functional diagrams showing it, but I'll quote just one, from the NG AMM 27-41-00:
The column cutout switches stop the stabilizer trim actuator when the pilot moves the control column in a direction opposite to the trim direction.
But not on the MAX - the cutout is bypassed when MCAS enabled (and that new bypass wouldn't be needed if STS already bypassed it).
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Avionista
I sincerely hope that Boeing engineers are doing this as we speak, otherwise they won't have a leg to stand on if this ever comes to trial. Saying that it was designed and calculated to do X and Y back in 1968, is not going to impress a jury...
It should be possible to calculate the turning moment about the HS pivot point for a range of ND trim units at various aircraft speeds and elevator positions. This should determine the range of forces which has to be resisted by the HS trim jackscrew. A ground test rig capable of applying this range of forces to a jackscrew could then be used to check the ability of the manual trim (both electric and crank wheel) to apply NU trim under all circumstances.
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The easiest fix was to automatically apply a little nose down trim at high angles of attack.
25.173 Static longitudinal stability.
Under the conditions specified in 25.175, the characteristics of the elevator control forces (including friction) must be as follows:
(a) A pull must be required to obtain and maintain speeds below the specified trim speed, and a push must be required to obtain and maintain speeds above the specified trim speed. This must be shown at any speed that can be obtained except speeds higher than the landing gear or wing flap operating limit speeds or VFC/MFC, whichever is appropriate, or lower than the minimum speed for steady unstalled flight.
(b) The airspeed must return to within 10 percent of the original trim speed for the climb, approach, and landing conditions specified in § 25.175 (a), (c), and (d), and must return to within 7.5 percent of the original trim speed for the cruising condition specified in § 25.175(b), when the control force is slowly released from any speed within the range specified in paragraph (a) of this section.
(c) The average gradient of the stable slope of the stick force versus speed curve may not be less than 1 pound for each 6 knots.
(d) Within the free return speed range specified in paragraph (b) of this section, it is permissible for the airplane, without control forces, to stabilize on speeds above or below the desired trim speeds if exceptional attention on the part of the pilot is not required to return to and maintain the desired trim speed and altitude.
Under the conditions specified in 25.175, the characteristics of the elevator control forces (including friction) must be as follows:
(a) A pull must be required to obtain and maintain speeds below the specified trim speed, and a push must be required to obtain and maintain speeds above the specified trim speed. This must be shown at any speed that can be obtained except speeds higher than the landing gear or wing flap operating limit speeds or VFC/MFC, whichever is appropriate, or lower than the minimum speed for steady unstalled flight.
(b) The airspeed must return to within 10 percent of the original trim speed for the climb, approach, and landing conditions specified in § 25.175 (a), (c), and (d), and must return to within 7.5 percent of the original trim speed for the cruising condition specified in § 25.175(b), when the control force is slowly released from any speed within the range specified in paragraph (a) of this section.
(c) The average gradient of the stable slope of the stick force versus speed curve may not be less than 1 pound for each 6 knots.
(d) Within the free return speed range specified in paragraph (b) of this section, it is permissible for the airplane, without control forces, to stabilize on speeds above or below the desired trim speeds if exceptional attention on the part of the pilot is not required to return to and maintain the desired trim speed and altitude.
Last edited by Lost in Saigon; 9th Apr 2019 at 14:52.
Just about everything you have read in the media is wrong. MCAS is not stall protection. It is only there because the larger engine nacelles of the B737 MAX cause an aerodynamic pitch up moment at high angles of attack that did not meet FAA stick force certification standards.
For the mainstream media, and even some of the industry press, knowing that aircraft can stall and that it's generally considered a BAD THING represents about the limit of their understanding.
Start talking about FARs and stick force gradient certification standards and their eyes will start to glaze over ...
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The easiest fix was to automatically apply a little nose down trim at high angles of attack.
Am I reading that correctly?
I fear you are fighting a losing battle in your campaign.
For the mainstream media, and even some of the industry press, knowing that aircraft can stall and that it's generally considered a BAD THING represents about the limit of their understanding.
Start talking about FARs and stick force gradient certification standards and their eyes will start to glaze over ...
For the mainstream media, and even some of the industry press, knowing that aircraft can stall and that it's generally considered a BAD THING represents about the limit of their understanding.
Start talking about FARs and stick force gradient certification standards and their eyes will start to glaze over ...
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It appears as though they have now remedied the situation.
Keeping Danny in Sandwiches
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The easiest fix was to automatically apply a little nose down trim at high angles of attack.
Couldn't the same effect have been achieved by inputting nose down elevator? At least the crew would be kept in the picture and no lasting aerodynamic input would have been involved.
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737 Driver, infrequentflyer789, I stand corrected. Thanks!
I have amended my previous post.
The posted diagrams are quite inconclusive because the various switches are only labelled with cryptic identifiers, and the outgoing signals not at all, and it is hard to tell what is what.
Bernd
I have amended my previous post.
The posted diagrams are quite inconclusive because the various switches are only labelled with cryptic identifiers, and the outgoing signals not at all, and it is hard to tell what is what.
Bernd
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That probably would have been the preferred option, however the elevator feel system cannot accept these inputs. I know that this is a very long thread, but this has been gone into in some depth earlier. Search for posts by FCEng84, which are particularly authoritative and illuminating.
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apologies. Quite right. INS ground speed. Just as accurate though. And on 737-200 we had Doppler ground speed - and 707. Pretty accurate too!
GPS ground speed will get you out of trouble in all these cases of chaotic airspeeds/stickshakers etc. Couple it with pitch and power and you actually cannot stall or over speed. Maintain ground speed at time of failure.
GPS ground speed will get you out of trouble in all these cases of chaotic airspeeds/stickshakers etc. Couple it with pitch and power and you actually cannot stall or over speed. Maintain ground speed at time of failure.
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I’ll Switching AP ON in chaotic situations of unreliable airspeeds and concurrent stick shakers is deadly since it’s inputs become unreliable. Better to fly the plane using the reliable information that is available PITCH. POWER. GROUNDSPEED. it works. Some time back (1980s) 737 suffered bird strike which took out AOA. And all air data including airspeed and altitude. Safe landing using above parameters. This became a standard training exercise. Fly a circuit with no speed info at all- except of course GPS which is a great help.
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Wouldn't it be possible to just measure the nose up tendency - be it caused by engine nacelle lift or thrust at low speed - by evaluating both pitch change rate and control column position, and apply ND trim accordingly?
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The very bright "solution" for the above problems from Boeing was to move the stab up to 6 units (from original 2 or so which were "not enough") in order to produce additional force on the stick. Yes, the bright heads at Boeing used one of the most essential flight control surfaces just to produce feedback force. Sending the plane straight to the ground in the process is just an overlooked side effect. Ooopsie. Well at least MCAS provided great (false!) tactile feedback of supposedly high AoA in the process - which was never there in the first place (a single faulty AoA vane).
Yes. Read it again. Let it sink.
Now imagine how a jury is going to react to that once Boing is sued by the victims families.
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you are correct of course. It was INS groundspeed. For those unfamiliar with how this works it’s easy. Say VRef +5 =140. Surface wind headwind 30 kts. Fly approach at 110 g/s.
Target threshold speed less headwind. All the way down. Guarantees excellent speed control and avoids wind gradient shear effects.
Target threshold speed less headwind. All the way down. Guarantees excellent speed control and avoids wind gradient shear effects.