airplane control after engine failure
TRANSCRIPT
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Copyright 2005AvioConsult
Airplane Control after Engine Failure
How to Prevent a Dead Engine from Turning into a Killing Engine
Imperfections and deficiencies in aviation regulations, certifica-tion specifications, flight manuals, textbooks, etc., etc., lead toincorrect understanding of air minimum control speed and of
takeoff safety speed which in turn leads to takeoff, go-aroundand training accidents after engine failure on multi-engine air-planes because of inappropriate crew response
June 2005
Harry Horlings
AvioConsultIndependent Aircraft Expert and Consultant
Committed to Improve Aviation Safety
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Airplane Control after Engine Failure
ii Copyright 2005AvioConsult
Airplane Control after Engine Failure
How to prevent a dead engine from turning into a killing engine
Imperfections and deficiencies in aviation regulations, certification specifications, flight manuals, textbooks, etc., etc., lead toincorrect understanding of the air minimum control speed and the takeoff safety speed which in turn leads to takeoff, go-around
and training accidents after engine failure on multi-engine airplanes because of inappropriate crew response.
This paper is an initiative of and is written by Harry Horlings,AvioConsult. An oral presentation to accompany this paper isavailable as well. Availability of both paper and presentation can be checked via the products page of website:www.avioconsult.com.
The author is graduate Flight Test Engineer of the USAF Test Pilot School, Edwards Air Force Base, CA, USA, 1985 and is Lt Col
ret'd (2003), FTE from 1986 and Chief Flight Test of the Royal Netherlands Air Force from 1994 to 2000.
AvioConsultis an independent aircraft expertise and consultancy bureau founded by the author.
E-mail:[email protected].
Copyright 2005,AvioConsult, all rights reserved.
The copyright of this paper belongs to and remains withAvioConsultunless specifically stated otherwise.
By accepting this paper, the recipient agrees that neither this paper nor the information disclosed herein nor any part thereof shall be
reproduced or transferred to other documents or used by or disclosed to others for any purpose except as specifically authorized inwriting byAvioConsult.
AvioConsulthas written this paper in good faith, but no representation is made or guarantee given (either express or implied) as to the
completeness of the information it contains.
By accepting this paper, the recipient agrees thatAvioConsultwillnot be liable for any direct or indirect loss arising from the use ofthe information and materiel contained in this paper.
Paper date: 2005-06-24. Change: 2011-02-10 Paper Number: AC07
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Airplane Control after Engine Failure
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CONTENTS
LIST OF FIGURES ............................................................................................................................................................................... IVLIST OF ABBREVIATIONS AND SYMBOLS .................................................................................................................................. IVEXECUTIVE SUMMARY .................................................................................................................................................................... V1. INTRODUCTION ........................................................................................................................................................................... 12. AIRPLANE CONTROL AFTER ENGINE FAILURE................................................................................................................... 1
2.1. Recovery ............................................................................................................................................................................ 22.2. Straight flight after engine failure ...................................................................................................................................... 3
2.2.1. Straight flight with wings level ( = 0) ...................... ...................... ..................... ...................... ..................... . 32.2.2. Straight flight with zero sideslip ( = 0) .................... ..................... ...................... ...................... ..................... . 42.2.3. Straight flight for certification ( = 35) ....................................................................................................... 42.2.4. Straight flight with zero rudder ( r= 0).............................................................................................................. 4
3. VARIABLE FACTORS THAT INFLUENCE VMCA...................................................................................................................... 53.1. Effect of bank angle and weight on VMCA.......................................................................................................................... 53.2. Two engines inoperative .................................................................................................................................................... 63.3. Critical engine .................................................................................................................................................................... 73.4. Engine thrust, altitude and temperature ............................................................................................................................. 83.5. Thrust derating and flexible thrust ..................................................................................................................................... 83.6. Control deflection .............................................................................................................................................................. 93.7. Slipstream effects ............................................................................................................................................................... 93.8. Propellers ........................................................................................................................................................................... 93.9. Effect of center of gravity on VMCA ................................................................................................................................... 93.10. Rudder boosting ............................................................................................................................................................... 103.11. Landing gear, flaps, slats and spoilers ............................................................................................................................. 103.12. Ground effect ................................................................................................................................................................... 103.13. Stall speed ........................................................................................................................................................................ 103.14. Load factor ....................................................................................................................................................................... 113.15. Configuration changes ..................................................................................................................................................... 113.16. Climbing flight ................................................................................................................................................................ 11
4. FLIGHT-TESTING VMCA ............................................................................................................................................................. 114.1. Static VMCAflight-testing ................................................................................................................................................. 124.2. Dynamic VMCAor transient effects flight-testing .................... ...................... ...................... ..................... ...................... .. 134.3. Other airborne engine-out evaluations ............................................................................................................................. 13
5. IMPROVED ENGINE EMERGENCY PROCEDURE ................................................................................................................ 136. TAKEOFF SAFETY SPEED V2 ................................................................................................................................................... 147. IMPERFECTIONS AND DEFICIENCIES IN AVIATION REGULATIONS ................ ..................... ...................... ................. 168. IMPERFECTIONS ON VMCAIN MANUALS AND TEXTBOOKS ........................................................................................... 16
8.1. Flight manuals ................................................................................................................................................................. 168.2. Textbooks and training manuals ...................................................................................................................................... 168.3. Recommended text on VMCAin flight manuals, training manuals and in textbooks ................................ ...................... .. 17
9. TRAINING AND DEMONSTRATION OF VMCA ....................................................................................................................... 189.1. Cautions for training and demo ...................... ..................... ..................... ...................... ...................... ...................... ...... 18
10. CONCLUSIONS ........................................................................................................................................................................... 1911. RECOMMENDATIONS .............................................................................................................................................................. 19REFERENCES ...................................................................................................................................................................................... 20
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LIST OF FIGURES
Figure 1. Motions after engine failureturboprop ....................... ...................... ..................... ...................... ...................... .............. 2Figure 2. Motions after engine failureturbofan .................... ...................... ...................... ..................... ...................... ..................... 2Figure 3. Straight flight with wings level ..................... ...................... ...................... ...................... ..................... ..................... ........... 3Figure 4. Straight flight with zero sideslip ................................ ...................... ...................... ..................... ...................... .................. 4Figure 5. Straight flight for certification ...................... ...................... ...................... ...................... ..................... ..................... ........... 4Figure 6. Straight flight with zero rudder .................... ...................... ...................... ...................... ..................... ..................... ........... 5
Figure 7. Banking more than 5 away from the inoperative engine ..................... ...................... ..................... ...................... .............. 5Figure 8. Banking into the inoperative engine................................ ...................... ...................... ..................... ...................... .............. 5
Figure 9. Effect of Bank Angle and Gross Weight on VMCAOne Engine Inoperative ........................... ..................... ..................... 6Figure 10. Effect of Bank Angle and Gross Weight on VMCA2Two Engines Inoperative ........ ...................... ..................... .............. 7Figure 11. Side view Nomad with Lift, Drag and Weight vectors .................... ...................... ...................... ..................... .................. 7Figure 12. Thrust distribution on propeller blades .................... ...................... ...................... ..................... ...................... ..................... 7Figure 13. P-factor .................... ..................... ...................... ...................... ...................... ..................... ...................... ...................... ... 7Figure 14. Airbus A400M .................... ..................... ...................... ...................... ...................... ..................... ...................... .............. 7
Figure 15. Center of gravity shift, longitudinal and lateral .................................... ...................... ..................... ...................... .............. 9
Figure 16. Effect of Bank Angle on VMCA. Turbojet, One Engine Inoperative; rudder and aileron deflections and sideslip angle .... 12Figure 17. Effect of Bank Angle on VMCA2. Turbojet, Two Engines Inoperative ................... ..................... ...................... ................ 12Figure 18. Effect of Bank Angle on VMCAand V2, One Engine Inoperative, 4-engine turbojet .................... ...................... ................ 14
Figure 19. Effect of weight and bank angle on takeoff safety speed V2. VMCAwith bank angle 3 was used here ........................... . 15
Figure 20. Effect of Bank Angle on VMCA2and V2, Two Engines Inoperative, 4-engine turbojet ........................ ...................... ........ 15
LIST OF ABBREVIATIONS AND SYMBOLS
Angle of attack
Sideslip angle
Air density
Bank angle
Pitch angle
a Aileron deflection angle
r Rudder deflection angle
AC Advisory Circular
ADI Attitude & Direction Indicator
AGL Above Ground Level
CL Lift coefficient due to angle of attack
CS Certification Specification (EASA)
D Drag
EASA European Aviation Safety Agency
FAA Federal Aviation Administration
FAR Federal Aviation Regulation
ft foot, or feet
FTG Flight Test Guide
ICR Inappropriate Crew Response
IFR Instrument Flight Rules
IMC Instrument Meteorological Conditions
JAR Joint Airworthiness Requirements
kg kilogram
kt knot or knots
L Lift
L Rolling moment
L Rolling moment due to sideslip angle
L a Rolling moment due to aileron deflection a
lb Pound or pounds
LT Rolling moment due to (asymmetric) thrust T
N Yawing moment
N Newton
N Yawing moment due to sideslip angle
N r Yawing moment due to rudder deflection r
NT Yawing moment due to (asymmetric) thrust T
OEI One Engine Inoperative
PFD Primary Flight Display
PSM Propulsion System Malfunction
RNLAF Royal Netherlands Air Force
S Surface area
SL Sea Level
T Thrust of propeller or turbofan/ jet
TEI Two Engines Inoperative
TPS Test Pilot School
USAF United States Air Force
V Velocity or speed
V1 Decision speed
V2 Takeoff Safety Speed
V2MIN Minimum Takeoff Safety Speed
VMC Minimum Control Speed
VMCA Minimum Control Speed in the Air
VMCA1 Minimum Control Speed in the Air, OEI
VMCA2 Minimum Control Speed in the Air, TEI
VMCG Minimum Control Speed on the Ground
VMCL Minimum Control Speed Landing configuration
VMCL1 Minimum Control Speed Landing configuration, OEI
VMCL2 Minimum Control Speed Landing configuration, TEI
VR Rotation speed
VS Stall speed
VS0 Stall speed, landing configuration
VS1 Stall speed, specified configuration
VSR Reference stall speed
VSSE Safe intentional OEI speed (FAR/ CS 23.149)
VXSE Speed for best single engine angle of climb
VYSE Speed for best single engine rate of climb
W Weight
Y Side force due to sideslip angle
Y r Side force due to rudder deflection r
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EXECUTIVE SUMMARY
The aviation community has achieved the lowest airplane ac-
cident rate in history, although accidents following the failure of
an engine or propeller system during takeoff, go-around andaccidents during training flights with an inoperative enginecontinue to happen quite frequently. The conclusion in many
accident investigation reports is either 'out of control' or
'inappropriate crew response to propulsion system malfunction'.Many publications were written to prevent these kinds of acci-
dents, but most reports and papers deal with the early recognition
of propulsion system problems only. This paper reveals the realcause of many propulsion system malfunction related accidentsand presents many recommendations to improve aviation safety.
Propulsion systems (engines and/ or propellers) are not 100%
perfect and may occasionally fail during takeoff, go-around orwhile en-route. This is why multi-engine airplanes are alwaysdesigned to be able to continue to fly safely when an engine fails
or is inoperative. The vertical tail is designed to be just big
enough to generate the side force required to maintain straightflight down to a certain speed, but while maintaining a smallbank angle. During the experimental flight-test phase following
prototype production, experimental flight test crews determine,besides other operational limitations, that speed, which is calledthe air minimum control speed (VMCA), for one or more engine-out configurations as well as a special type of VMCAfor landing(VMCL). The flight test techniques and procedures to be used arepublished in flight test guides issued by the Federal Aviation
Administration (FAA) or the European Aviation Safety Agency
(EASA), and in Military Specifications and Standards publishedby Air Forces. These flight test techniques require the use ofstandardized test conditions, like an aft center of gravity, lowest
possible weight, critical engine inoperative and several others toreduce the otherwise huge amount of data required to determineVMCAfor all values of all variable factors that have influence on
VMCA. These standardized test conditions provide the worst-
case, the highest VMCA for a certain configuration. This worst-case VMCA is listed in flight manuals, as a single number or incharts in which altitude, temperature and ground effect are oftenthe only variable factors. This also simplifies calculating VMCA
by pilots before takeoff and again before landing (to be prepared
for a go-around). However, there is one test condition usedduring flight-testing that hasmay bethe greatest influence onthe value of VMCA, that is regrettably 'forgotten' in Federal Avia-
tion Regulations (FAR) and EASA Certification Specifications(CS) and consequently in many airplane flight and operatingmanuals as well as textbooks. This very influential variable on
VMCA is the bank angle. Its exclusion caused and will continue
to cause many accidents, not only immediately after enginefailure, but also during the remainder of the flight following theengine failure or during training flights with an inoperativeengine, unless improvements are made to rules and regulations
and to flight manuals.
Part 25 airplanes use a takeoff safety speed (V2) to ensure asafe continuation of takeoff following the failure of an engine.
V2is calculated before flight using both VMCAand the stall speed
(VS) of the airplane that applies for the takeoff weight.
Either V2 or VMCA is always displayed in the direct field ofview of the pilots, either on a(n electronic) display, on a takeoffand landing data card, on a placard or as a red radial line on theairspeed indicator, because VMCAand/ or V2 are of vital impor-
tance for maintaining control while an engine is inoperativeduring takeoff, go-around and during low speed flight.
This paper, an initiative of Harry Horlings ofAvioConsult, tho-
roughly explains VMCA and most of the variables that influenceVMCA and therewith V2 and comments on existing regulations,flight manuals, textbooks and training programs.
The major conclusions of this paper are:
Pilots are not made aware that manufacturers use a small bank
angle to design and dimension the vertical tail of their airplaneand to determine VMCA and, hence, that this bank angle is a
condition for the listed VMCA(and derived V2) to be valid.
Many regulatory paragraphs in FAR/ CS 23 & 25 on takeoffsafety and on VMCA do not take into account the adverse ef-
fects of many variable factors, including bank angle, on VMCAand therewith on the derived V2. This has led to imperfect,
deficient, dangerous and even impossible requirements.
Flight manual writers copy these imperfect and incorrect
regulatory paragraphs into their manuals; textbook authors
copy them into their textbooks. Readers will or might get aninappropriate understanding of the controllability of an air-
plane in the event that an engine is inoperative.
The applicant for certification of a multi-engine airplane may
select a bank angle for determining VMCA; a bank angle 35degrees away from the inoperative engine is commonly used.Flight Manuals publish this VMCAand allow a maximum bankangle of 5, in accordance with the definition in FAR and CS,
without specifying the approved direction of banking. How-
ever, the actualVMCAvaries considerably with bank angle. Ifan airline pilot does not maintain the same small bank anglethat was used to determine VMCAwhile an engine is inopera-
tive, then the actualVMCAis higher than the listed VMCAandmight easily increase above the indicated airspeed (or V2),
leading to an uncontrollable airplane at once. VMCAas well asV2 are only valid and safe if the same bank angle is appliedthat was used to determine VMCA. Flight manuals do regretta-
bly not specify the selected bank angle as an essential re-quirement for being able to maintain straight flight (maintaincontrol) following the failure of an engine and do not issue
warnings for this vital requirement because a rule or regula-
tion to do so does not exist for the applicant/ manufacturer.The small bank angle is also used to determine climb perfor-
mance after engine failure: it might mean the difference be-tween life and death.
Some departure procedures require bank angles up to 15 de-grees for takeoff obstacle clearance or noise abatement proce-
dures, even after engine failure. If the airspeed is VMCAor V2,this 15-degree bank angle might also lead to an immediate
loss of control, ending the flight in calamity.
Much design effort has been made to display many cues andalerts of approaching dangerous airspeeds and attitudes, etc.
However, the perhaps most important cause of engine failurerelated accidents never made it to be included in the design ofcockpit displays and alerting systems, may be except for a fewairplane types. There is no bank angle advisory for keeping
the actualVMCA after engine failure to a safe lowest possible
value, no warning of approaching the actualVMCAor of dece-lerating below the actual takeoff safety speed V2 in any air-plane yet. The underestimated, yet life-threatening increase ofactual VMCA if the bank angle deviates from the bank angle
used during flight-testing VMCA, never made it to be includedappropriately in the design of display, warning and alert sys-
tems. In addition, a yaw rate indication to early detect a thrustasymmetry is no longer present on modern displays; a slow
moving heading scale has to be used instead.
Many recommendations are presented in the paper to im-prove regulatory paragraphs, flight manuals, textbooks, trainingprograms, etc. These improvements are definitely required to
decrease the number of multi-engine airplane accidents due toengine failure.
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1. INTRODUCTION
The vertical fin and rudder of a multi-engine airplane are de-
signed to counter the big asymmetrical yawing moment caused
by the remaining engine(s) after engine failure. The aerodynam-ic side force that can be generated by the vertical fin and rudderdepends highly on the (square of the) airspeed. As the airspeed
decreases, the rudder deflection has to increase since the engine
thrust remains the same. However, there are mechanical limitsto the rudder deflection angle and the vertical fin is also limited
in size. So there must be a lower speed at which the vertical fin
plus rudder generate just a high enough side force to counter theasymmetrical thrust and maintain the heading.
The designers of the vertical fin know that the size of the finand/ or rudder deflection can be reduced by banking a few de-
grees away from the inoperative engine. FAR 23.149, 25.149and equivalent allow a bank angle of maximum 5 degrees. Thissmall bank angle adds a component of the airplane gross weight
as a side force to the other side forces that act on the airplane.
The weight and bank angle related side force reduces the size ofthe vertical fin, which saves manufacturing cost. Therefore, thevertical fin including rudder of a multi-engine airplanes is de-
signed and built to a size that generates just a high enough sideforce for maintaining straight flight after engine failure, whilebanking a few, up to maximum 5 degrees away from the in-operative engine down to an airspeed that is lower than or equalto 1.2 VS.
From the engineering or hardware point of view, there is noth-
ing wrong with this tail design approach, because it is in accor-dance with the aviation regulations. During flight, the lowest
airspeed for maintaining straight flight that was used for design-ing the vertical tail can deviate from the actual in-flight value.
Therefore, the regulations require flight-tests to be performed todetermine the airspeed below which straight flight cannot bemaintained after engine failure. During testing, the flight-testcrew would normally use the same bank angle that was used to
design the vertical tail. The measured lowest speed for maintain-ing straight flight while banking the same bank angle as wasused to design the vertical tail is called the minimum controlspeed in the air (VMCA) and is to be published in the Airplane
Flight Manual as an operational limitation.
The problem is that nobody ever told the airline pilots (yet)about the tail design limitations, which are in fact hardwarelimitations, and about the bank angle that needs to be applied for
VMCA to be valid. Hence, pilots do not know that they shouldmaintain straight flight only while also maintaining a small bankangle away from the inoperative engine for the vertical fin to beable to maintain the equilibrium of side forces and yawing mo-
ments, because this is neither prescribed in the Airplane FlightManual nor included in the engine emergency procedures. This
is, to the opinion of the author, why accidents after engine failurehappen. Pilots of Part 25 airplanes use takeoff safety speed V2
and not VMCAanymore. However, V2is derived from VMCAandstall speed VS, making VMCAimportant to all multi-engine pilots.
VMCA is in fact a software fix for a hardware shortcoming.The significance of VMCA for the controllability of a multi-
engine airplane after engine failure seems well documented in
Federal Aviation Regulations (FAR), EASA Certification Speci-fications (CS) and in flight manuals and textbooks, butin fact
it is not. If the applicable VMCAand/ or V2are readily availa-ble to pilots before every takeoff or go-around, why do engine
failures, or in-flight simulation or demonstration of engine fail-ures during training, still turn into catastrophes so often? Many
publications were written to answer this question, but most
reports and papers only discuss the early recognition of engineproblems, for instance references[1] and[2].
It is the objective of this paper to answer this question by tho-roughly explaining the effect of an inoperative engine on the
controllability of a multi-engine airplane while in the air duringtakeoff and go-around and to present a few different options for
continuing the flight safely, bringing down the engine failurerelated airplane accident rate. The first version was published inthe Aviation Safety Magazine of the Royal Netherlands AirForce in 1999[3] and was written after four catastrophic acci-
dents happened with both propeller and turbofan airplanes after
engine failures within a short period of time. Since then, theauthor reviewed several flight manuals, relevant texts in maga-zines and on the Internet, accident reports and sections and
paragraphs out of FAR's and CS's on the subject of controllabili-ty after engine failure. It was concluded that most of these pub-lications were imperfect, in many cases even incorrect and defi-
cient.
For preparing this paper, USAF Test Pilot School (TPS) text-
books[4] were used, including the USAF Paper 'Procedures andanalysis techniques for determining VMCA' [5], as well as theformal FAA and EASA Flight Test Guides [6], [7], [8]). To
avoid proprietary rights problems, no airplane data was copiedfrom formal airplane flight manuals; instead, data resulting from
analysis using the VMCAprediction techniques taught at the TPS
[9] were reworked and used. These are presented in paper 'TheEffect of Bank Angle and Weight on the Minimum ControlSpeed VMCAof an Engine-out Airplane'[12].
The author believes that it is very important that multi-enginerated pilots, aviation authorities, accident investigators andtextbook writers, etc., have a good knowledge of the real value
of VMCAand V2, as well as of the variables that have influence
on the value of VMCA. Most of these variable factors will bediscussed, as will be the effect thereof on takeoff safety speedV2. A few 'secrets' of flight-testing VMCAas performed by expe-
rimental test pilots and flight-test engineers will be revealed.Several imperfections and deficiencies in FAR/ CS 23 and 25, inflight manuals, in training manuals and in textbooks will be
discussed and recommendations for improvement are included.
Although text and figures mainly present propeller airplanes,the theory also applies to turbofan-equipped airplanes.
In this paper, minimum control speed means directional min-imum control speed in the air. Lateral minimum control speed,
which is applicable to airplanes with powered lift devices or verybig propellers, will not be discussed, nor will ground minimumcontrol speed VMCG. This paper is not applicable to multi-engineairplanes with two in-centerline engines either.
2. AIRPLANE CONTROL AFTER ENGINE FAILURE
For equilibrium flight, balance is required of the forces and
moments (a moment = a force its moment arm) that act on an
airplane. This also applies after engine failure. The lift or force
that an aerodynamic airfoil produces can be expressed with
equation V2SCL in which is the air density, V is the air-
speed and S is the surface area of the aerodynamic airfoil. CL
does not only depend on the shape and other characteristics of
the aerodynamic airfoil, but also on its angle of attack to the
incoming air stream. Airspeed V has a significant (squared)influence on the generated lift or force. The lift equation does
not only apply to 'horizontal' airfoils, but also to the vertical fin
and rudder. In the figures presented below, not all of the forcesand moments that act on an airplane are shown and the shownones are not to scale. The power or thrust (T) of engines de-
pends on the engine characteristics, and mostly also on air tem-perature, pressure altitude and airspeed.
After engine failure, the power or thrust distribution on the
airplane is no longer symmetrical. The asymmetrical thrust (T)generates a yawing moment (NT) that, if the airspeed is low andthe thrust is high, rapidly yaws the airplane through a large angle
in the direction of the failed or inoperative engine. The drag of
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the propeller of the failed engine, unless feathered, adds to theasymmetrical thrust T.
A sideslip develops, which instantaneously increases the
drag (D) and hence decreases (climb) performance and airspeed.
The vertical tail generates side force Y due to sideslip that is
stabilizing because the moment N that this force generates,
tends to return the nose of theairplane back into the relativewind (weathercock stability).The sideslip also generates a
destabilizing side force Tsin(in front of the center of
gravity) generated by airflowbending on all propeller discsor turbofan inlets, as long as
the thrust setting is high.
On propeller airplanes, the
blown wing section(s) behindthe propeller(s) of the operatingengine(s) produce more propul-
sive lift than the other wing,which generates a rolling mo-
ment (LT) into the failed orinoperative engine.
Sideslip also generates a rolling
moment L caused by blanking
of a wing, in this case the leftwing, and by the relative windblowing under the high wing.
The asymmetrical slipstream of the propellers will also have
effect on the vertical fin as sideslip increases.
Turbofans mounted under-neath the wings (Figure 2) donot produce propulsive lift.The wings of these types ofairplane however, generate a
bigger rolling moment L due
to the sideslip, the dihedraleffect, and the swept wings.
Without appropriate crew
response to propulsion system
malfunction, the rolling motionwill continue under influence ofthe dihedral of the wings or, onpropeller airplanes, under influ-
ence of the asymmetrical pro-pulsive lift. Ailerons might not
be effective enough to counte-ract the rolling moment if the
airspeed is low, then spoilersmight kick in to assist. Thisgenerates additional drag anddeteriorates the already reduced
performance.
The side forces will start ac-
celerating and consequently displacing the airplane to the deadengine side along a descending flight path in the direction of the
low wing. Then the relative wind and sideslip angle reverse to
the other side and the weathercock stability will start to turn the
nose of the airplane to the ground. This of course is just onepossible scenario. Nevertheless, this actually took place duringseveral accidents. The crews could not put an end to this out of
control situation because the aerodynamic control power of the
control surfaces was not high enough due to a too low airspeedand even more important because the crew was not familiarenough with controllability of the airplane after engine failure.
The pitching moment change caused by engine failure is smalland the elevator is dimensioned to be able to handle the change
easily.
After an engine failure during takeoff or go-around, bigchanges in forces and moments occur due to the high asymme-trical engine thrust and the limited control power of the aerody-
namic control surfaces at low speed ( V2). The resulting dy-namics and motions can be very violent. Motions will continueuntil a new balance of forces and moments is established. If the
airspeed and altitude are both low, this might never happen while
the airplane is still in the air. Turbofans, after failure, take long-er to spool down, so the dynamics of engine failure might not beas violent as the dynamics after engine failure of turboprops. Inany engine failure case, the crew response to a propulsion system
malfunction must be rapid and appropriate.
2.1. Recovery
To recover to steady straight and controlled flight, first theairplane motion must be arrested as soon as possible to prevent
an uncontrollable attitude from developing. The controls availa-
ble to the pilots for recovery are aerodynamic controls, like
rudder, ailerons and elevator, but also propulsive directionalcontrols: the throttles or power levers. A rudder is normally
sized and on big airplanes boosted to be able to provideenough control power to counteract the yawing motions generat-ed by asymmetrical engine thrust after one or two engines fail on
the same wing, down to a certain minimum control speed. Aile-rons have small control power under low speed conditions too,
but are on some airplanes assisted by powerful spoilers. All
pilots are aware though that the downward deflection of anaileron increases the local angle of attack of the wing section infront of that aileron, which if the airspeed is lowmight leadto a partial wing stall that causes an uncommanded roll, which
only aggravates an already critical situation. Aileron deflectionalso generates adverse yaw and additional drag that both increase
the asymmetrical thrust moment NTas well.
The moments needed for recovery after engine failure are a
yawing moment N equal to and opposite of asymmetrical thrustmoment NTand also a rolling moment L.The side force due to rudder deflection
Y r can provide a yawing moment N r
that adds to the yawing moment N due
to side force Y (that normally provides
the weathercock stability). The rudder is the only aerodynamiccontrol available to balance or counteract NT. The ailerons(supported by spoilers) are used to balance the propulsive lift
moment LTand the rolling moment due to sideslip L .
If the aerodynamic control power is insufficient to recover to asafe equilibrium under high asymmetrical thrust conditions, then
the airspeed is below the actual minimum control speed. Nor-mally the elevator (pitch control) is used to adjust the flight path
and therewith to increase the airspeed as required. However, if
the airplane is just after liftoff and still close to the ground thismight not be an option. If rudder and/ or ailerons are not effec-tive enough to provide the control power needed for recovery,then the only option left is to decrease the problem-causing
asymmetrical yawing moment NTand rolling moment LT. Thiscan be achieved by partly closing the throttle of the engine oppo-site of the failed or inoperative engine to reduce the asymmetric-al thrust moments NT and propulsive lift LT to a level that is
equal to or lower than the aerodynamic moments that are being
generated by rudder (N r ), vertical fin (N ) and ailerons at that
very instant (and speed). The throttle of the opposite engine has
very big control power because it decreases or even nulls theasymmetrical yawing moment on the airplane and decreases
propulsive lift LT. Of course, this 'propulsive control' aggravates
an already critical performance problem; the overall performanceis decreased for a while (until control is regained). Nevertheless,
Yr
Y rN +N r
Yr
Y rN +N r
Figure 1. Motions after enginefailureturboprop.
Wsin
T
YN
NT
Tsin
TsinY
LT
WsinW
L
Prop.
drag
Wsin
T
YN
NT
Tsin
TsinY
LT
WsinW
L
Prop.
drag
Figure 2. Motions after enginefailureturbofan.
T
YN
NT Tsin
L
Wsin
Tsin
Y
WWsin
T
YN
NT Tsin
L
Wsin
Tsin
Y
WWsin
Tsin
Y
WWsin
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controllability is more vital to survival than performance, espe-cially if the altitude is low during takeoff or go-around; a wingtip
hitting the ground first causes more trouble than a wings-levellanding in the dirt.
The required control inputs in the roll and yaw axes to stop thedynamic or transient motions after engine failure and return to
stabilized flight will be bigger than for maintaining equilibrium
straight flight. Therefore, both a static and a dynamic VMCA(transient effects) are determined during experimental flight-
tests. These flight-tests will be briefly described later in this
paper (4).
Using the explanation presented above, an engine emergencyprocedure for recovery can be drafted to establish straight flightfollowing the failure of an engine during takeoff or go-around.
This procedure is applicable to all multi-engine airplanes.
Identify which engine failed (e.g. dead leg dead engine);Apply both rudder and aileron away from the inoperative
engine to recover to straight flight;
Increase thrust on remaining engine(s) to maximum availa-
ble (takeoff) thrust;
Note: If rudder and/ or ailerons do not generate enough con-trol power for recovery, reduce the opposite throttle tempo-
rarily as much as required (propulsive control);
Increase airspeed using pitch control, if feasible, to the best
single engine rate of climb VYSE or to the best angle ofclimb speed VXSE, or to takeoff safety speed V2, etc.
In 5,after thoroughly describing the effects of an inoperativeengine on the controllability of an airplane, this emergencyprocedure will be improved with a life saving addition. In the
paragraphs to follow, several options for straight flight afterengine failure will be discussed.
2.2. Straight flight after engine failure
After recovery, many combinations of rudder and aileron def-
lections are possible that will achieve balance of lateral anddirectional forces and moments for a safe straight (equilibrium)flight. Three combinations or options that are most relevant to
takeoff and go-around will be discussed. A fourth option,
straight flight with no rudder input, is presented for referencepurposes only.
The options to be discussed are:
1.Straight flight with wings level (bank angle = 0), whichis easy to fly with outside reference or by using the attitude
display on the primary flight display;
2.Straight flight with zero sideslip ( = 0), because in thiscase the drag is as low as possible and hence the effect of aninoperative engine on airplane performance is minimal;
3.Straight flight for certification ( = 5, or the number of de-grees specified by the applicant, away from the inoperativeengine), which is also the equilibrium of lateral and direc-
tional forces and moments used to determine VMCA duringexperimental flight-testing;
4.Straight flight with zero rudder ( r= 0).
2.2.1. Straight flight with wings level ( = 0)
In the accompanying figures below, not all forces and mo-ments that act on an airplane are shown, only the most importantones.
After failure of the left hand engine (#1) on our sample multi-
engine airplane, the asymmetrical thrust T of engine #2 gene-rates a yawing moment NTabout the center of gravity that can be
balanced only by a yawing moment N rgenerated by rudder sideforce Y r (2.1). However, Y r also causes sideward accelera-
tion and hence a sideslip built-up. This sideslip causes a side
force Y opposite of Y r, an 'air-bending' side force Tsin and a
side component of the drag, thatall decrease the sideward acce-
leration. The yawing moment
N ,generated by Y ,adds to the
asymmetrical thrust momentNT. Therefore, the rudderdeflection needs to be increased
to counteract this moment aswell. Aileron deflection anot
only generates a rolling mo-
ment L a to counteract the
propulsive lift moment LT, butalso an adverse yawing moment
N a for which also additional
rudder deflection is required tocompensate for. On turbofan-
equipped airplanes, the deflec-tion of ailerons might be differ-ent from the deflection in thefigures, because turbofans do
not generate propulsive lift.
With the wings kept level,the only side force available to achieve a balance of forces is the
side force due to sideslip Y .
As airspeed is decreased, Y decreases (control power of thevertical fin with rudder deflected V2) and more rudder deflec-tion is needed to increase Y again and achieve a balance of side
forces and yawing moments for straight flight with wings level.
The airspeed can be decreased until either one or more of the
following limitations are met, both with the trims at normalsetting:
Rudder deflection is maximum or pedal force is 150 lb (667
N) or 180 lb (FAR/ CS and military requirements, respec-tively);
Aileron force is 25 lb and deflection is maximum or 75%throw (FAR/ CS and military requirement, respectively).
Below this airspeed, straight flight cannot be maintained. There-fore, this airspeed is the actual air minimum control speed
VMCA for flight with the wings level. 'Actual VMCA' in thispaper means the real and instantaneous VMCAin the actual confi-guration with the actual values of all variable factors that influ-ence VMCA and not the worst case of the values used to deter-
mine the VMCA that is published in flight manuals. These varia-ble factors and their worst case values will be discussed in detailin 3.
Conclusion. Straight equilibrium flight following enginefailure while the wings are kept level requires a sideslip angleand deflection of both rudder and aileron to balance forces and
moments.
The disadvantage of this lateral and directional balance of
forces and moments is the drag generated by the sideslip, whichdecreases climb performance. Furthermore, due to the sideslip
angle , the prop wash of the inner engines of a 4 or more engine
airplane (#2 or #3) might disturb the airflow around the vertical
fin, affecting the local angle of attack and hence influencing themaximum obtainable rudder control power. The stall characte-
ristics are degraded as well.
Although a good and easy to fly straight flight with the wingslevel can be achieved, a sideslip is required. The drag is not aslow as possible to achieve maximum takeoff performance. As
an example, the sideslip angle required for straight flight during
testing a small twin-engine airplane in a certain configurationwith an inoperative engine and level wings was 14 degrees.
Figure 3. Straight flight withwings level.
T
Y
Y
Y rLT
r
a
L a
NT
W
TsinN r-NN a
Tsin
T
Y
Y
Y rLT
r
a
L a
NT
W
TsinN r-NN a
Tsin
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2.2.2. Straight flight with zero sideslip ( = 0)
If sideslip is zero, there will be no side force due to sideslip
(Y ). As explained in the previous paragraph, besides rudder
and aileron deflection to balance the asymmetrical thrust mo-ments NT and LT, another side force is definitely required for
straight flight to balance side force Y rand prevent the airplane
from slipping again to the dead engine side. This force caneasily be generated. The tail design engineer already used it at
the drawing board for sizing the vertical tail
When an airplane is banking,a component of the weightvector acts as side force in the
center of gravity (2). This
side force Wsin can also be
used to replace Y and achieve
straight flight after enginefailure. It generates no rollingor yawing moments becausethis force acts in the center of
gravity (the moment arm is
zero). Side force Wsin variesobviously with weight (W) and
bank angle ( ), acts in the
direction of banking and is zero
if the wings are level(sin 0 = 0).
In Figure 4, bank angle is afew degrees away from the
inoperative engine, which
generates a side force Wsin
opposite of Y r, as is required for the balance of the side forces.
In this zero sideslip case, the rudder side force Y ronly has to
generate a moment for balancing NTand N a(adverse yaw) and
does not have to overcome Y and the other side forces due to
as well, so less rudder deflection r is required as compared to
straight flight with wings level of the previous paragraph.
Therefore, the airspeed can be further decreased until again the
rudder and/ or aileron limitations are reached that were listed inthe previous paragraph.
The speed at which this happens is the actual air minimumcontrol speed VMCA for straight flight with zero sideslip in the
given configuration. Flight-testing has shown that a favorable
bank angle of only 3 5 degrees away from the inoperative
engine generates a side force Wsin that is big enough to re-
place Y and the other side forces due to . Wsin generates
no side effects since it acts in the center of gravity. The ball ofthe slip indicator is in this case about half a ball width to the
right (into the good engine).An example: the actual VMCAof a small twin-engine airplane
in a certain configuration during testing decreased from 58 kt
with the wings level to approximately 53 kt with a favorablebank angle of 5. This small bank angle adds 5 kt or 10% of'safety'. As will be shown later, the decrease of actual VMCAwill
be much higher on bigger airplanes.
Conclusion. Actual VMCA during straight equilibrium flight with zero sideslip is lower than actual VMCA with wings
level, leading to the conclusion that the margin between the
actual takeoff airspeed and the actual air minimum control speedduring takeoff increases if a small bank angle is used, whichmeans that this small bank angle increases the safety considera-bly. For takeoff and go-around after engine failure, it is impor-
tant that the remaining performance after engine failure is max-imal, requiring the drag to be minimal, which will be the case if
the sideslip is zero and a small bank angle of 3 to 5 is attainedand maintained.
2.2.3. Straight flight for certification ( = 35)
A small bank angle away from the inoperative engine decreas-es the rudder requirement and therewith decreases the air mini-
mum control speed VMCAas was explained in the previous para-graphs. In other words, applying a small bank angle decreasesactual VMCA and therewith increases the small margin betweenV
MCA and the airspeed during takeoff, which increases takeoff
safety. The small bank angle decreases sideslip to almost zero,which is favorable to the remaining climb performance.
Zero sideslip is very difficult to determine in-flight because
sideslip angle cannot easily
be measured and displayed. Asimple means would be a woo-len tuft on the windscreen, but
that does not look very profes-
sionally... A bank angle how-ever, can be read directly andfairly accurately from the atti-tude display (ADI or FD).
The maximum allowable
bank angle is 5 (FAR/ CS23.149 and 25.149 [8], [10]).The reason for this 5 will
become clear in 3.1. Theapplicant (manufacturer) mayselect a bank angle that will be
used to determine the VMCA of
the airplane. In most cases, thisbank angle will be between 3and 5. A bank angle of 5 ismost often used on multi-
engine airplanes with straightwings and is very close to the bank angle for straight flight with
zero sideslip as well as for lowest drag, which again is im-portant for (remaining) climb performance (2.2.2). Using 5 of
bank on straight wing airplanes will result in only a small sides-lip angle of approximately 3. Swept wing airplanes might
only have to use 3 of bank for lowest drag; Figure 16 illustratesthis. As will be shown later, even this small 3 bank angle mightprevent a catastrophic accident after engine failure.
Figure 5 shows the most important forces and moments for
this lateral and directional balance of forces and moments. Thiscase is usually used for determining the VMCA that is listed in
flight manuals.
Conclusion. Straightequilibriumflight with a small bankangle (3 5) away from the inoperative engine is relativelyeasy to fly using the cockpit displays and provides a lower andtherewith more safe actual VMCA. The drag will be minimalwhich is favorable to the remaining climb performance with an
inoperative engine. Therefore, this lateral and directional equili-brium is used during flight-testing to determine the VMCA that
will be listed in flight manuals.
2.2.4. Straight flight with zero rudder ( r= 0)
To complete the overview of four of many possible optionsfor lateral and directional balance of forces and moments for
straight flight while an engine is inoperative, Figure 6 shows
straight flight with zero rudder. Y is now the only side force
that can provide the moment N required to act against NT.
Therefore, the sideslip angle needs to be quite considerable atlow airspeed or the airspeed needs to be high enough to generate
an appropriate side force Y . Side force Wsin is in turn re-
quired to balance Y + Tsin . The bank angle is again awayfrom the inoperative engine and will usually be around 8 degreesat high weight and bigger at lower weights. This option forstraight flight might look attractive because no rudder input is
required. However, the sideslip angle at low takeoff or go-
Figure 4. Straight flight withzero sideslip.
N r
LT
W
a
L a
T
NT
Wsin
Y r r
N a
Wsin
N r
LT
W
a
L a
T
NT
Wsin
Y r r
N a
Wsin
Figure 5. Straight flight forcertification.
Wsin
r
Y
LT
W
a
L a
Y
NTT
Y r
N r+ N
N a
Wsin
Wsin
r
Y
LT
W
a
L a
Y
NTT
Y r
N r+ N
N a
Wsin
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very common for straight wing turboprop airplanes with 5 bank.If however highest gross weight would have been chosen to
determine VMCA, then the actual VMCA for any lower weight ishigher and pilots would have to use weight as entry variable to
determine the actual VMCA; this would require too much data andbe too complex. Low weight is the worst-case weight for deter-mining VMCAand is therefore used during flight-testing and thus
for listing VMCAin airplane flight manuals.
Things change dramatically for this and other multi-engineairplanes if a bank angle is not maintained away from the in-operative engine. If the wings are kept level, the analysis shows
that actual VMCAfor this sample airplane, in this configuration, at
all gross weights (Wsin = 0) will have become 119 kt, 24 kthigher than VMCAwith 3 bank away from the inoperative engineand 11 kt higher than the stall speed VSat high weight. At or
below an airspeed of 119 kt, straight flight cannot be maintained
following the failure of an outboard engine while the wings arekept level and the opposite engine is at maximum availabletakeoff thrust setting, and also provided the other factors thathave influence on VMCAare at their worst-case values.
Actual VMCA will be even higher if the bank angle is only 5
degrees into the wrong side, which is into the failed or inopera-
tive engine: more than approximately 85 kt above VS for thissample airplane. The 10 line is presented too and speaks foritself. The increase of actual VMCA on straight wing airplanes
will be smaller, but still a factor to consider.
The powerful adverse effect of side force Wsin (if is to
the wrong side) can be observed in Figure 9. Of course, VMCAisthe minimum speed for maintaining straight flight (equilibrium)only, which an intentional turn is not, but the control power of
rudder and ailerons might be insufficient to be able to end theturn and return to a wings level attitude once the airplane isallowed to bank away from the favorable 3 5 degrees. Theremaining control power at VMCAis not subject of flight-testing,
and may therefore not be counted on.Figure 9 will be used again in 6,while discussing the takeoffsafety speed V2. The same data will be used for a VMCAversusbank angle plot in 4.
The VMCAthat is listed in flight manuals is always determinedusing the lowest possible gross weight anda bank angle of 3 to
5 away from the inoperative engine, which provides a safeVMCAwhatever the airplane gross weight is. This in fact meansthat this listed VMCA is only safe on the condition that the bank
angle is 3 to 5 away from the inoperative engine.
Although the flight manual of this sample airplane might statethat the airplane is controllable down to the stall, this will onlybe the case as long as the bank angle is the same as used to
determine VMCA: between 3 and 5 away from the inoperativeengine as opted by the manufacturer. Maintaining this small
bank angle is therefore essential for the takeoff and in-flightsafety after engine failure or while an engine is inoperative forthis airplane and most probably for all multi-engine airplanes.
Conclusions.
VMCA
published in flight manuals is a constant value, but
actual VMCA varies considerably with bank angle; actualVMCAis definitely not a constant airspeed.
Actual VMCA increases many knots (at high power settings)
if the wings are kept level, instead of banking 3 5 awayfrom the inoperative engine. The increase will be smalleron straight wing airplanes (approximately 10 knots).
Actual VMCA increases even more while maneuvering into
the inoperative engine side. If actual VMCAincreases abovethe indicated (or calibrated) airspeed due to a change ofbank angle, control will be lost right away.
The VMCAthat is published in Flight Manuals is a minimum
speed for maintaining a straight flight equilibrium followingthe failure of an engine, and is definitely not a minimum
speed for maneuvering the airplane.
These facts about the effect of bank angle and weight on V MCAare not elaborated in most flight, training and operating manuals,
nor in many textbooks on asymmetrical flight, nor in FAR's and
CS's. This might very well be the real cause of many enginefailure related accidents. More on this subject will follow.
3.2. Two engines inoperative
On 4 or more engine airplanes, two engines might occasional-
ly be inoperative simultaneously, for instance after simultaneous
bird ingestion or following the failure of another engine. There-fore, for 4 or more engine airplanes, both VMCA1 and VMCA2(VMCAwith one engine (n-1) and two engines (n-2) on the samewing inoperative respectively) are determined and presented in
the flight manuals of these airplanes. FAR/ CS 25 do not use
VMCA1 and VMCA2, but use VMCL1and VMCL2 (VMCA for landingconfiguration) only. FAR/ CS do obviously not anticipate a dualengine failure in the takeoff or cruise configuration. The
FAR/ CS requirements for VMCLdo not make any difference forthe explanation in this paragraph.
VMCA1 is the VMCA, that is the minimum approved flyingspeed, in anticipation of the failure of any one engine of a 4 or
more engine airplane. After any one of the engines failed or is
inoperative, VMCA2will have become the minimum airspeed formaintaining airplane control in anticipation of the failure of asecond engine. VMCA2 is much higher than VMCA1because it is
determined after shutting down the critical engine as well as theengine next to it on the same wing. On a 4- or more engineairplane, the asymmetrical thrust moment will then be as high as
it can get. VMCA2 is also to be used as the minimum controlspeed after failure of any two engines and not only for two in-operative engines on the same wing! The value of VMCA2, again,represents a worst-case airplane configuration.
In Figure 10 below, the effect of bank angle and weight is pre-
sented for the same 4-engine turbojet airplane as used in Figure 9
on page 5 for the one-engine inoperative case. As shown in thefigure, VMCA2 from this analysis is expected to be 117 kt. ThisVMCA2is determined with the lowest possible weight (160,000 lb
in this example) and with a 5 bank angle away from the inoper-ative engine, as well as other standardized test conditions. If thegross weight is above 225,000 lb, VMCA2is below the stall speed;
then the airplane is controllable down to the stall, but only if
bank angle is 5 away from the failed engines. A bank angle
of 3, less than 3 or to the other side increases actual V MCAabove the stall speed VS for these weights. In paragraph 6 on
takeoff safety speed V2, Figure 10 will again be used for analyz-ing takeoff safety.
Figure 9. Effect of Bank Angle and Gross Weight on VMCAOne Engine Inoperative, Maximum Continuous Takeoff Thrust.
60
80
100
120
140
160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
Actual
VMCA
(kt)
-10
-5
0
3
Vs
4-engine turbojet, OEI
Data basis: analysis X
60
80
100
120
140
160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
Actual
VMCA
(kt)
-10
-5
0
3
Vs
4-engine turbojet, OEI
Data basis: analysis
60
80
100
120
140
160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
Actual
VMCA
(kt)
-10
-5
0
3
Vs
4-engine turbojet, OEI
Data basis: analysis XX
VMCA Flight Manual for = 3
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The VMCA2used in this example is obtained from analysis that
is normally performed before flight-testing VMCA2 to predictVMCA2 as well as any control limitation that might be encoun-
tered during testing[12]. Actual flight-testing is always required
to determine the real VMCA2 that is to be published in flightmanuals.
As can be observed in Figure 10, banking away from the fa-vorable 5 bank angle during straight flight into the other side
will increase actual VMCA2 in the analyzed configuration to 190knots at low gross weight and to 213knots at high gross weight,which is 73 kt respectively 96 kt above the standardized VMCA2
that is listed in the flight manual. Compare this chart also to the
chart in Figure 9 in 3.1 for one engine inoperative.These graphs show that there definitely is a reason for maintain-ing a small bank angle away from the inoperative engine.
Procedures for go-around if one engine is already inoperativerequire the airspeed to be increased first to at least VMCA2 byaccelerating down the glide slope to exchange available altitude
for airspeed and by using symmetrical thrust only. Asymmetric-al thrust may be added, provided directional control can be
maintained. Any increase of asymmetrical thrust increases therequirement for rudder deflection, which increases actual VMCA,and should be accompanied by gradual banking to a bank angleof 5 away from the inoperative engine.
3.3. Critical engine
During low speed flight (including takeoff and go-around), the
angle of attack is increased for the wings to develop the re-
quired lift, as shown in Figure 11. The relative wind not onlyhits the lift-producing wings
with the increased , but also
the propeller blades. This in-
crease affects the resultingthrust of each individual bladeas is illustrated in side views inFigure 12. Vr is the rotational
speed of the propellers; V is theforward airspeed of the airplane.The resulting blade velocity isshown with a dotted vector. The
top half of Figure 12 shows the down-going or descending pro-
peller blade and the right-hand side shows the angles of attack of
two propeller blades (both at the instant they are horizontal) and
the resulting thrust T after the of the wings has been increased.
The b(b = blade) of the descending propeller blade in Figure
11 increases if is increased as can be observed from this fig-
ure, so the thrust T of this blade increases; bof the ascending
propeller blade decreases, so thethrust T of the blade on this side
of the spinner decreases.
At low speed, when is in-
creased, the thrust vector ofwhole propeller disc shifts in the
direction of the descending
propeller blade. This asymme-trical loading of the propellerdisc is also called P-factor, seeFigure 13. If the propellers bothrotate clockwise, then the mo-
ment arm of the propeller thruston the left wing (T1) decreasesand the moment arm of thepropeller thrust on the right
wing (T2) increases with in-
creasing . Then the yawing
moment of engine #2
(T2 arm T2) is bigger than the
yawing moment of engine #1
(T1 arm T1). This effect isalso noticeable during normalallenginesoperating opera-tions at low speed (when ishigh), when a rudder input will
also be required to counteractthe difference in thrust yawing moments for maintaining theheading.
If engine #1 fails, the total remaining thrust moment NT (in
this case generated by engine #2) is bigger than the remaining
thrust moment if engine #2 would fail. A bigger asymmetricalthrust moment NT requires greater rudder deflection to counte-ract this NTorif the rudder is at its limit as required for deter-mining VMCAa higher speed. Hence, VMCA after failure of
engine #1 will be higher than VMCAafter failure of engine #2.The engine that, after failure, leads to the highest VMCAis called
the critical engine. In this case, the (most) left engine #1 is the
critical engine because both propellers rotate clockwise.
If the airplane is equipped with counter-rotating propellers orwith turbofans, there is no difference between NTafter failure ofa left- or right-hand engine provided the gyroscopic effects of
rotating engines and propellers are negligible. In this case, theopposite engines are equally critical. NTand hence actual VMCAdiffer for inboard and outboard inoperative engines though.
The failure of the centerline engine on a tri-jet has no influence
on the yawing moments and hence not on VMCA, but only on thepitching moment requiring a change of elevator input.
Slipstream effects or rudder boosting might influence the se-
lection or determination of the critical engine; refer to the appli-cable paragraphs below.
A new airplane design shown in Figure 14 is the AirbusA400M. Unique on the propulsion of this airplane are the coun-ter-rotating propellers on both wings; both propellers on each
wing rotate in opposite directions to each other, down in-
between. If both engines on awing are operating, the shift ofthe thrust vector with increasingangle of attack is always to-
wards the other engine on thesame wing. The effect of this isthat the resulting (combined)thrust vector of both engines on
the same wing does not shift asthe angle of attack of the air-plane increases when the speed
is decreased, or is low, as long
W
L
D
W
L
D
Figure 11. Side view with Lift,Drag and Weight vectors.
Figure 14. Airbus A400M withcounter-rotating propellers.
NT
Arm R
Arm L
N r
NT
Arm R
Arm L
N r
Figure 12. Thrust distributionon propeller blades, side view.
b b
T
b bVr
T
VVr
Vr
V
T
T
Vr
b b
T
b bVr
T
VVr
Vr
V
T
T
Vr
Figure 13. P-factor.
NT
Arm T2
T1
T2
Arm T1NT
Arm T2
T1
T2
Arm T1
Figure 10. Effect of Bank Angle and Gross Weight on VMCA2 Two Engines Inoperative, Maximum Continuous Takeoff Thrust.
60
80
100
120
140160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
ActualV
MCA2(kt)
-10
-5
0
3
5
Vs
4-engine turbojet, TEI
Data basis: analysis XX
60
80
100
120
140160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
ActualV
MCA2(kt)
-10
-5
0
3
5
Vs
4-engine turbojet, TEI
Data basis: analysis
60
80
100
120
140160
180
200
220
240
260
160 180 200 220 240 260
Weight (1,000 lb)
ActualV
MCA2(kt)
-10
-5
0
3
5
Vs
4-engine turbojet, TEI
Data basis: analysis XX
XX
VMCA2 Flight Manual ( = 5)
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as both engines are operating. There is no overall P-factor; therewill be no difference in magnitude of thrust yawing moments NT
after failure of either engine #1 or #4 with increasing , only in
direction. This means that VMCAafter failure of either one of the
outboard engines will be the same, unless (boosting) systems,that may be required for controlling the airplane, are not installedon both outboard engines. This airplane does therefore not have
a left- or right-hand critical engine; both outboard engines areequally critical.
If an outboard engine fails, for instance #1 as shown in Figure14 above, the moment arm of the vector of the remaining thruston that wing reduces from in between the engines to a bit outside
of the remaining inboard engine, as shown in Figure 14. Theresulting NT is much lower than would be the case for conven-
tional propeller rotation. The maximum Y rand N rto be gener-
ated by the rudder can be smaller and consequently, the size ofvertical fin of this airplane can be reduced. There is however
one very important condition: the feathering system of the big 8-bladed, 17.5 ft (5.33 m) diameter and therefore high drag propel-lers must be automatic, very rapid and failure free to ensure the
lowest possible propeller drag following a propulsion system
malfunction. If not, the failure of the feathering system of anoutboard engine will increase propeller drag, which in turn en-hances NT considerably therewith increasing actual VMCA. Thecontrol power generated by the small vertical fin and rudder
alone is low by the small design. Only rapid reduction of thrust
of the opposite engine, or (increased) airspeed can restore therequired control power to maintain straight flight following thefailure of a feathering system. Designing and approving thefeathering system for this airplane will be a real challenge to
design engineers and to certification authorities.On airplanes with very powerful engines, an asymmetrical thrust
problem is also being solved by applying automatic thrustasymmetry compensation, see also 3.4, but this has conse-
quences for takeoff performance as well.
Flight manuals present the VMCA that is determined after fail-ure of the (or a) critical engine. This provides the highest, theworst case, VMCA that is valid as long as the bank angle is the
same as used for sizing the vertical tail and during VMCAtesting,and the thrust is maximal. The actual VMCAafter failure of any
other engine is lowerwhich is safer. The word 'critical' is onlyof use to airplane design engineers and test pilots to make sure
they use and determine the highest VMCAafter failure of any ofthe engines. Airline pilots should not have to worry whether afailing engine is critical or not; they should not even have tolearn about the criticality of an engine. Just a single VMCA, that
is a safe minimum control speed before and after failure of anyof the engines, applies, as does only a single engine emergencyprocedure. Maintaining the small bank angle away from theinoperative engine(s) however, is a live-saving condition for the
lowest, safest possible actual VMCA, whether the inoperativeengine is critical or not.
3.4. Engine thrust, altitude and temperature
The thrust setting used on the remaining engine(s) for deter-
mining VMCA is the maximum thrust that is guaranteed by themanufacturer in the specification of the engines. The higher the
asymmetrical thrust setting, the higher the rudder requirementwill be and/ or the higher the airspeed must be to provide the
required rudder control power (V2) for straight flight; actualVMCA is higher. As discussed before, if the aerodynamic controlpower is insufficient to restore control, or to maintain straightflight after engine failure, the throttle setting of the engine oppo-
site of the failed or inoperative engine must be decreased a little,
but only as much as required to restore or maintain control.On some airplanes with very powerful engines (and a too
small vertical fin), a thrust asymmetry control system decreasesthe thrust of the engine opposite of the failing engine automati-
cally as required. This keeps the actual VMCA to a safe lowlevel. A system like this, if fitted, must have been considered
important if not indispensable by the manufacturer for restoringand maintaining control after engine failure. The consequence isthat this system will also decrease the remaining climb perfor-mance upon activation.
If the thrust of the engines depends on air density (altitude)
and temperature, increasing altitude will decrease the thrust.After engine failure at high altitude, the asymmetrical thrust will
be lower as well as is the requirement for rudder control power
after engine failure. The actual VMCAwill be lower as well.
If the outside air temperature increases, engine thrust decreas-es and actual VMCA decreases. A too big variation of enginethrust with density and temperature leads to a big variation of
actual VMCA's, which is the reason that (turboprop) airplanemanufacturers provide several charts with VMCAdata for differ-ent altitudes and temperatures in the flight manual.
During an approach while an engine is inoperative, the thrust
setting is low and hence the actual VMCAis low as well. If a go-
around becomes necessary, adding asymmetrical thrust increasesactual VMCA simultaneously with the thrust. To avoid controlla-bility problems, the acceleration to the go-around speed must be
performed while still flying down the glide path before initiating
the climb, using symmetrical thrust, while adding as muchasymmetrical thrust as possible to maintain straight flight.While adding asymmetrical thrust, simultaneous rudder deflec-tion as well as gradual banking to the specified 3 to 5, both
away from the inoperative engine is required to keep actualVMCAas low as possible and prevent the loss of control.
Asymmetrical engine thrust has the greatest effect on VMCA.Actual VMCA is most critical (highest) when the thrust setting is
high and will be no factor for airplane control if the thrust is low.
3.5. Thrust derating and flexible thrust
In the case of thrust derating, the surplus thrust that is in the
engine design is not available at hand by setting the thrust orpower levers (throttles) in the cockpit, but only by engineers by
changing settings on the engine itself at the time of engine fit-ting. This is common practice for installing similar engines ondifferent types of airplane. Thrust derating might be required to
limit the maximum asymmetrical thrust moment to the maxi-mum available rudder control power at the desired takeoff speedfollowing the failure of an engine. The VMCAlisted in the flight
manual will be based on this derated thrust.
On some modern types of airplane though, thrust derating is
settable to several levels during preflight from the cockpit for thenext takeoff. Then the flight manual must present a set of per-formance data for every possible derated maximum thrust set-
ting, including a specific VMCA as operating limitation, because
VMCA is dependent on the maximum thrust that can be set withthe thrust levers. The VMCA after this kind of thrust derating is
lower because the maximum thrust yawing moment NT is lower
following engine failure and after moving the throttles fullyforward (to the derated maximum).
Flexible or reduced takeoff thrust is a thrust level less than themaximum settable thrust with the throttles. It is being used to
preserve engine life. An assumed higher outside air temperature
and/ or reduced throttle setting are used to achieve the lowestpossible thrust level for a takeoff on the available runway length.In this case, still the same VMCAdata apply as for the availablehighest takeoff thrust setting, because maximum takeoff thrust is
still settable anytime by moving the throttles forward. As longas the thrust setting during flexible or reduced takeoff is lower,
the actual VMCAis lower. If however, following the failure of anengine, the thrust levers of the operating engines are set (by
procedure) from the flex setting to maximum available thrust toachieve maximum climb performance, then the actual VMCA
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increases again to the value presented in the flight manual, pro-vided the bank angle is 5, or the number of degrees specified by
the applicant, away from the failed engine.
3.6. Control deflection
VMCAof a multi-engine airplane is determined when the rud-der and/ or ailerons are either fully deflected or after reaching a
predetermined rudder or aileron control force limit, whicheveroccurs first during the test (explained in 4). If the rudder is notfully deflected (while the thrust is maximum) to maintain thestraight flight equilibrium, then the actual airspeed for the ver-
tical fin with rudder to generate a side force high enough tocounter the still same high asymmetrical thrust will have tobe higher than the airspeed that was measured during the flight-test to determine the FAR and CS based VMCA for which fully
deflected directional controls were used (provided the maximumapproved control force is not exceeded). This actualairspeed formaintaining control is therefore higher than the AFM publishedVMCA that was determined under FAR and CS 23.149 and
25.149.
On military transport airplanes, only a maximum of (75%) ofthe available control power of rudder and ailerons may be usedto determine VMCA, to leave some control power margin for
countering gusts and control forces may be higher. This in fact
means that the VMCA's of airplane types that are used both ascivilian and as military transports could differ from each other;the 'military' VMCA's are higher.
3.7. Slipstream effects
Asymmetrical and spiraling slipstream effects might influence
the recovery after engine failure, as well as the value of VMCA,because the slipstream might influence the air stream around thehorizontal and vertical tail. Some airplanes have vortex inducers
on the vertical fin to prevent an early fin stall when the sideslipangle increases during equilibrium flight with an inoperativeengine. Slipstream effects might have influence on the value of
both static and dynamic VMCA and, if the effects are dominant,the slipstream might even determine which of the engines iscritical. During flight-testing VMCA, slipstream effects, if any,will have effect during the determination of VMCA, for the sides-lip and bank angles tested. However, if during operations fol-
lowing engine failure a bank angle is allowed that leads to an
increased sideslip angle, the slipstream effects might increaseactualVMCAto a value higher than the listed VMCAor to an earlyfin stall.
3.8. Propellers
After an engine failure, the airflow will start driving the not
yet feathered propeller (windmilling) causing the drag of thepropeller to increase significantly. The yawing moment generat-
ed by this drag increases the asymmetrical yawing moment of
the opposite operating engine, which during takeoff or go-
around is at maximum available takeoff thrust setting to attain
the maximum available climb performance. The lower the pro-peller drag, the lower the asymmetrical yawing moment and the
less rudder deflection is required to maintain straight flight atany given airspeed. Most propellers are equipped with a fea-
thering system that automatically feathers the propeller bladesafter engine failure (unless disabled or not armed). Feathering a
propeller will decrease its drag considerably. Small twin-engineairplanes might not have a feathering system; after engine fail-
ure, the propeller might continue to windmill, causing highpropeller drag. The VMCAof these airplanes is determined withthis high drag and will therefore be high enough to be able tomaintain control, provided again the bank angle is 5, or the
number of degrees specified by the manufacturer during certifi-cation, away from the failed engine.
Propellers will only auto-feather after engine failure if the
feathering system is enabled or armed, which is normally set
prior to both takeoff and landing (in anticipation of an enginefailure during go-around). If feathering was used for determin-
ing VMCA, the asymmetrical thrust yawing moment NT withoutfeathering is (much) bigger and hence greater rudder deflectionis required for straight flight: actual VMCAis higher. This has aconsequence for training too. A realistic VMCAcannot be dem-
onstrated by just idling one engine. This is the reason that air-
plane manufacturers provide a (number of) thrust setting(s) to beset on the simulated inoperative engine to match the drag of afeathered propeller. The setting corresponds to zero drag, or
zero thrust.
For determining VMCA, the propeller has to be in the pitch set-ting that it assumes by itself after engine failure without pilotintervention, which is either windmilling or feathered. VMCA
data in flight manuals are based on this condition although some
manufacturers report two VMCA's, one with and one without auto-feathered propeller depending on the criticality of the auto feath-er system of the airplane. The drag of an idling propeller is
higher than the drag of a feathered propeller. This higher dragenhances the asymmetrical thrust yawing moment NT. More
rudder deflection is required for straight flight or a higher air-
speed if the rudder is at maximum deflection; hence, VMCA ishigher.
Torque and gyroscopic effects due to rotating engines andpropellers are mostly neglected in the VMCA analysis. Theseeffects, as well as the rapidness of the automatic featheringprocess, if any, play their role in determining the dynamic VMCA
or during transient effects testing (4.2) . The effects will be
included in the listed VMCA.
Conclusion. In the case that the propeller of an inoperativeengine is in a configuration other than used during testing for
VMCA, the actual VMCA might be much higher than the chartedVMCA, which is very unsafe if (much) thrust has to be added onthe operating engine(s) during a go-around. A suspected failedpropeller-engine should never be left idling as a 'standby source
of thrust '; the engine should be shut down or set to provide zerothrust/ drag in order for the actual VMCAto be as low as, or be-low the listed VMCA. If a propeller is not feathered (because theengine is kept idling) or if the feathering system fails (or is not
armed), the drag and, hence, actual VMCAis much higher the hanlisted (and indicated) VMCA. Loss of control will occur as soon
as (asymmetrical) thrust is increased (during approach or go-around).
Flight training with an inoperative propeller-engine should beperformed using some thrust on the simulated dead engine tosimulate zero thrust/ drag to be able to demonstrate a more rea-listic VMCA. Training the appropriate response to a sudden en-
gine failure however, requires actually shutting down an enginein-flight.
3.9. Effect of center of gravity on VMCA
Longitudinal center of gravity. The yawing moment generat-
ed by the rudder (N r), is the product of the moment arm ordistance from the center of
gravity to the aerodynamic
force Y r developed by the
rudder. If the center of gravityis at its approved aft limit, theyawing moment generated by
the vertical tail and rudder
deflection is smallest. If thecenter of gravity is more for-ward, the moment arm to the
rudder force Y r is longer andrudder deflection can be small-
er to counter NT (Figure 15below). Now the airspeed
Figure 15. Center of gravityshift, longitudinal and lateral.
NT
Arm T2T2
Arm r
N r
Y rNT
Arm T2T2
Arm r
N r
Y r
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could be further decreased until rudder deflection is again maxi-mum: actual VMCAwith a forward center of gravity is lower.
Lateral center of gravity. A lateral center of gravity shift also
affects VMCA. A lateral shift of the center of gravity into theinoperative engine for instance increases the asymmetrical thrustmoment of the live engine(s) and requires a higher counteracting
force: more rudder and aileron deflection are required, or if these
are maximum already, the airspeed needs to be higher: actualVMCA increases. Therefore, flight manuals present a maximum
allowable wing-fuel asymmetry or imbalance to avoid controlla-
bility problems after engine failure due to the lateral shift of thecenter of gravity.
Considering all possible centers of gravity for determining theVMCA would be excessively complicated. VMCA is therefore
determined with the center of gravity at the maximum approvedlateral position into t