Ethiopian airliner down in Africa
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I don't think there is any dispute about the fact that grasping the trim wheel stops the stab moving. Reportedly, and depending on how positively you grab it, you may lose a bit of skin in the process.
Once the wheel is held, you are not fighting against the electric trim motor, which is disabled if resistance is detected at the cable drum.
Once the wheel is held, you are not fighting against the electric trim motor, which is disabled if resistance is detected at the cable drum.
handle, shedding no skin at all !!
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Yes....that's how amazing captains are !
Sorry folks, just trying to lighten it up a bit,
but don't intend to imply any disrespect to
the victims of these crashes.
(It just happens that in my now ancient 737 times,
this was the joke about the runaway stab drill)
Sorry folks, just trying to lighten it up a bit,
but don't intend to imply any disrespect to
the victims of these crashes.
(It just happens that in my now ancient 737 times,
this was the joke about the runaway stab drill)
Last edited by Deepinsider; 9th Apr 2019 at 10:01.
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But Tesla called it AutoPILOT instead of Lane/TrafficASSISTANT and used the System far beyond it's clearly stated limitations (no cross-traffic detection, 0,4s driver reaction). All other OEMs limited the system to 30 sec. without driver interaction.
After the accident, the company stopped delivering their system to Tesla because they then knew that it was used beyond it's limits (like MCAS?)
Mobileye claimed Tesla was 'pushing the envelope in terms of safety'. I'm not allowed to post the link (Reuters).
In addition, Tesla was forced to prevent the forseeable misuse by stopping the car after a certain time without driver interaction (touching the steering wheel...)
All other OEMs ripped Teslas apart to learn all the modern new solutions and mostly considered the solutions not state of the art in terms of safety.
It's the same story, management wanted something impossible. In one case a new aircraft without additional training, in the other case being in the news as first autonomous car manufacturer with affordable electric cars...
In one case it may have been forseeable that pilots go into the stall memory item (more speed), in the other one that people may take a nap while driving.
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Jus' sec here. AF447 had plenty of stall warning. It only stopped after the crew held it into the deep stall. The crew didn't register the warning or believed it spurious.
On the 60 kt criteria, I find it hard to criticize that design decision. It would get increasingly difficult to get reliable meaningful data from the sensors at that point (i.e. IAS vs CAS spread). And who would have thought an airliner would actually manage to be flown to that point.
On the 60 kt criteria, I find it hard to criticize that design decision. It would get increasingly difficult to get reliable meaningful data from the sensors at that point (i.e. IAS vs CAS spread). And who would have thought an airliner would actually manage to be flown to that point.
Something I have never understood wrt this - is it possible for the a330 to be in the air with an airspeed of 60 knots or even 70 knots and NOT be stalled? If not then why inhibit the warning? Worrying about sensor accuracy seems to be missing the bigger picture wrt the purpose of the warning!
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Also DaveReid's post above about motors stopping if they meet resistance.
I can't see any reason for the 'blips' in nose up trim other than pilot trying it and it not working/ not appearing to work. Why else would you release the switch when it's the one thing you're focussing on, the one thing you know you need?
Bernd
Psychophysiological entity
Surely the Tristar predated GPS by some years.
LR, Yanrair, we used IRS GS for monitoring headwind correction. Did that on the DC8 too using the INS, from the early 70's on, as a formal, (book) procedure. The Lockheed, (100 & 500), didn't have GPS when I flew it in the late '80's..
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To me as an engineer everything lines up if one adds this clutch/force limit:
Pilots try manual trim: Too much force, no chance (and free hands)
Pilots reactivate electric trim: Short movement and the clutch/force limit stops it. (FDR Trace...)
Pilots try a few times: Small blips... (FDR Trace...)
Pilots give up: MCAS kicks in again...
If you find people at Boeing with lot's of bandaid, you know they had the same idea recently...
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The cutout switch function was changed with the 737MAX from all prior 737 models. The legacy switch combination was one switch to cutout electric trim altogether, the other to cutout the autopilot trim commands. MCAS and Speed Trim System are both commands from the “autopilot”. With the legacy switch configuration, the flight crew can disable the autopilot commands and retain electric trim. With the 737MAX, the flight crew lose both electric trim and autopilot trim with the cutout switch.
The Flight Standardization Board (FSB) took notice of the nomenclature change of the cutout switches but did not make any mention of the difference in responding to autopilot stab trim runaway. On the 737NG, the flight crew retain electric trim; on the 737MAX the flight crew must use manual trim. It turns out, this is a significant difference in pilot workload and pilot capacity to fly the airplane.
The Flight Standardization Board (FSB) took notice of the nomenclature change of the cutout switches but did not make any mention of the difference in responding to autopilot stab trim runaway. On the 737NG, the flight crew retain electric trim; on the 737MAX the flight crew must use manual trim. It turns out, this is a significant difference in pilot workload and pilot capacity to fly the airplane.
Most of this has been reviewed in the thread elsewhere, but to perhaps summarize from a B737-400 AMM describing the HS trim system:
The horizontal stabilizer trim control system provides longitudinal trim of the airplane by varying the angle of attack of the horizontal stabilizer. The horizontal stabilizer is moved through 17 degrees of travel by means of a jackscrew with ball nut. The main electric actuator and the cable drum on the jackscrew gearbox provide for trim control from three separate control systems. The normal control is an electrical system which actuates the jackscrew through the main electrical actuator. The main electric actuator and autopilot actuator, autopilot control is provided by the autopilot actuator on the gearbox. A manual control system drives through cables to the cable drum on the jackscrew gearbox. The manual system remains engaged at all times and is therefore back-driven by the main electric actuator or autopilot actuator during normal operation. Manual system operation will disengage both the normal electrical and autopilot actuators if these systems become jammed. A continuous indication of stabilizer position is provided by trim position indicators adjacent to trim wheels on the control stand. The indicators are positioned by the manual system. A takeoff warning system indicates any unsafe stabilizer position for takeoff.The control column actuated cutout switch located under the cockpit floor, stops electric trimming of the stabilizer when opposed by the motion of the elevator control.
Normal electrical trim control system consists of control switches, cutout switches, a column- actuated cutout switch, trim control relays, flap switch and relay, limit switches and an electric actuator. The electric actuator contains an electric motor, two electromagnetic clutches, a speed change relay, torque limiting clutch and output shaft to drive the jackscrew gearbox. The motor is operated by 3 phase AC power and the relay and clutches by DC power. The stabilizer actuator is controlled by the trim control switches, control cutout switch, limit switches and cutout switches. The control switches, located on the outboard horn of each control wheel, have two momentary positions, nose up and nose down, and are spring-returned to the center off position.The column- cutout switch located beneath the cockpit floor is actuated by forward and aft movement of either control column. Stabilizer limit switches are located on the bulkhead aft of the jackscrew gearbox and actuated by a striker to limit stabilizer leading edge up and down travel. The cutout switches on the control stand are used to remove power from the main electric actuator or the autopilot actuator.
Normal electrical trim control system consists of control switches, cutout switches, a column- actuated cutout switch, trim control relays, flap switch and relay, limit switches and an electric actuator. The PSTA contains an electric motor, two electromagnetic clutches, a speed change relay, torque limiting clutch and output shaft to drive the jackscrew gearbox. The motor is operated by 3 phase AC power and the relay and clutches by DC power. The PSTA is controlled by the trim control switches, control cutout switch, limit switches and cutout switches. The control switches, located on the outboard horn of each control wheel, have two momentary positions, nose up and nose down, and are spring-returned to the center off position. The column-cutout switch located beneath the cockpit floor is actuated by forward and aft movement of either control column. Stabilizer limit switches are located on the bulkhead aft of the jackscrew gearbox and actuated by a striker to limit stabilizer leading edge up and down travel. The cutout switches on the control stand are used to remove power from the PSTA.
Normal electric trimming of the stabilizer is done at one of two rates as controlled by flap position. Trim rate with flaps retracted is 1/3 the trim rate with flaps extended. The autopilot actuator also trims at one of two rates as controlled by flap position. High speed autopilot rate is equal to the normal electric low speed rate. The low speed autopilot rate is 1/2 the rate of the high speed autopilot rate.
Normal electrical trim control system consists of control switches, cutout switches, a column- actuated cutout switch, trim control relays, flap switch and relay, limit switches and an electric actuator. The electric actuator contains an electric motor, two electromagnetic clutches, a speed change relay, torque limiting clutch and output shaft to drive the jackscrew gearbox. The motor is operated by 3 phase AC power and the relay and clutches by DC power. The stabilizer actuator is controlled by the trim control switches, control cutout switch, limit switches and cutout switches. The control switches, located on the outboard horn of each control wheel, have two momentary positions, nose up and nose down, and are spring-returned to the center off position.The column- cutout switch located beneath the cockpit floor is actuated by forward and aft movement of either control column. Stabilizer limit switches are located on the bulkhead aft of the jackscrew gearbox and actuated by a striker to limit stabilizer leading edge up and down travel. The cutout switches on the control stand are used to remove power from the main electric actuator or the autopilot actuator.
Normal electrical trim control system consists of control switches, cutout switches, a column- actuated cutout switch, trim control relays, flap switch and relay, limit switches and an electric actuator. The PSTA contains an electric motor, two electromagnetic clutches, a speed change relay, torque limiting clutch and output shaft to drive the jackscrew gearbox. The motor is operated by 3 phase AC power and the relay and clutches by DC power. The PSTA is controlled by the trim control switches, control cutout switch, limit switches and cutout switches. The control switches, located on the outboard horn of each control wheel, have two momentary positions, nose up and nose down, and are spring-returned to the center off position. The column-cutout switch located beneath the cockpit floor is actuated by forward and aft movement of either control column. Stabilizer limit switches are located on the bulkhead aft of the jackscrew gearbox and actuated by a striker to limit stabilizer leading edge up and down travel. The cutout switches on the control stand are used to remove power from the PSTA.
Normal electric trimming of the stabilizer is done at one of two rates as controlled by flap position. Trim rate with flaps retracted is 1/3 the trim rate with flaps extended. The autopilot actuator also trims at one of two rates as controlled by flap position. High speed autopilot rate is equal to the normal electric low speed rate. The low speed autopilot rate is 1/2 the rate of the high speed autopilot rate.
Last edited by PJ2; 9th Apr 2019 at 13:34. Reason: clean up duplications
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Something I have never understood wrt this - is it possible for the a330 to be in the air with an airspeed of 60 knots or even 70 knots and NOT be stalled? If not then why inhibit the warning? Worrying about sensor accuracy seems to be missing the bigger picture wrt the purpose of the warning!
The AF447 stall warning problem is even more subtle though - invalid data was designed for, the problem is (it appears) that it was designed without state so known invalid data resulted in "no warn". This was arguably incorrect, but known invalid data shouldn't result in "warn" either. With a stateful design a transition from stalled-data to invalid-data would not take you out of the "warn" state, not complicated (he says, having forgotten most of his NFA/DFA and statemachine stuff), just wasn't done that way.
Ironically if AF had taken the optional (standard on later buses) A330 feature that they said their pilots didn't need, the stall warning design issue would have been fixed (BUSS, optional on 330, fixes it). Whether it would have saved them, I don't know for sure, very possibly irrecoverable by the time they got to that point.
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Control column actuated stabilizer trim cutout switches stop operation of the main electric and autopilot trim when the control column movement opposes trim direction.
Stabilizer Trim Override Switch
OVERRIDE – bypasses the control column actuated stabilizer trim cutout switches to restore power to the Stabilizer Trim Switches
NORM (guarded position) – normal operating position
OVERRIDE – bypasses the control column actuated stabilizer trim cutout switches to restore power to the Stabilizer Trim Switches
NORM (guarded position) – normal operating position
Bernd
Or can the motor distinguish where the force is coming from?
You can trim ANU while pulling back on the column, but not AND.
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This is one of the simplest and neatest examples of Boeing philosophy of helping the pilot not do stupid but never by overriding the pilot's primary control inputs. This was a good system, but not any more. MCAS broke the system. Now there is another way to trim forward whilst pulling back - just let HAL do it for you, all the way down.
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The 737 manuals says that incase of extreme nose-down out-of-trim, one should INCREASE speed to relieve elevator load and permit manual trimming.
That's insane !
(see https://www.satcom.guru/2019/04/what...-on-et302.html)
That's insane !
(see https://www.satcom.guru/2019/04/what...-on-et302.html)
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This is one of the simplest and neatest examples of Boeing philosophy of helping the pilot not do stupid but never by overriding the pilot's primary control inputs.
This was a good system, but not any more. MCAS broke the system. Now there is another way to trim forward whilst pulling back - just let HAL do it for you, all the way down.
Bernd
Last edited by bsieker; 9th Apr 2019 at 15:16. Reason: Struck out incorrect portions. Thanks to infrequentflyer789 and 737 Driver!
Salute!
AvWeek has a summary of the thjings Big B is doing, and also iterates the purpose and function of MCAS. If it's paywalle I'll come back and cut-and-paste.
https://aviationweek.com/commercial-...-max-grounding
I wonder why Boeing didn't separate the two stab trim cutout switches. One for only the wheel electric trim switches and the other for all of HAL's stuff -STS, A/P and MCAS.
That would seem to have saved both planes and it also allows the "revert to manual" procedure that many of the 737 drivers here have bragged about. 'cause I do not see using electric trim switches to reduce loads as being much removed from cranking a wheel, just less tiring and faster.
Gums sends..
AvWeek has a summary of the thjings Big B is doing, and also iterates the purpose and function of MCAS. If it's paywalle I'll come back and cut-and-paste.
https://aviationweek.com/commercial-...-max-grounding
I wonder why Boeing didn't separate the two stab trim cutout switches. One for only the wheel electric trim switches and the other for all of HAL's stuff -STS, A/P and MCAS.
That would seem to have saved both planes and it also allows the "revert to manual" procedure that many of the 737 drivers here have bragged about. 'cause I do not see using electric trim switches to reduce loads as being much removed from cranking a wheel, just less tiring and faster.
Gums sends..
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... The normal control
is an electrical system which actuates the jackscrew through the main electrical actuator. The main
electric actuator and autopilot actuator, autopilot control is provided by the autopilot actuator on the
gearbox. A manual control system drives through cables to the cable drum on the jackscrew
gearbox. ...
Normal electric trimming of the stabilizer is done at one of two rates as controlled by flap position.
Trim rate with flaps retracted is 1/3 the trim rate with flaps extended. High speed autopilot rate is
equal to the normal electric low speed rate. The low speed autopilot rate is 1/2 the rate of the high
speed autopilot rate.
is an electrical system which actuates the jackscrew through the main electrical actuator. The main
electric actuator and autopilot actuator, autopilot control is provided by the autopilot actuator on the
gearbox. A manual control system drives through cables to the cable drum on the jackscrew
gearbox. ...
Normal electric trimming of the stabilizer is done at one of two rates as controlled by flap position.
Trim rate with flaps retracted is 1/3 the trim rate with flaps extended. High speed autopilot rate is
equal to the normal electric low speed rate. The low speed autopilot rate is 1/2 the rate of the high
speed autopilot rate.
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 coniguration.
From what has been posted here it seems very likely, that this has been changend on the MAX.
So unfortuneately this actually raises more questions to me.
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