Data processing: vehicles – navigation – and relative location – Vehicle control – guidance – operation – or indication – Aeronautical vehicle
Reexamination Certificate
2001-03-22
2002-09-17
Cuchlinski, Jr., William A. (Department: 3661)
Data processing: vehicles, navigation, and relative location
Vehicle control, guidance, operation, or indication
Aeronautical vehicle
C340S945000, C244S075100, C244S05300R
Reexamination Certificate
active
06453221
ABSTRACT:
The present invention relates to a method for determining, on an aircraft equipped with a number of engines, a minimum control speed when at least one engine is shut down.
In the context of the present invention, the expression minimum control speed is to be understood as meaning the minimum speed at which it is possible to hold the aircraft, for example a civilian transport airplane, on a constant heading with, simultaneously:
at least one engine shut down, for example an engine which has failed or an engine which has been deliberately shut down;
the rudder hard over; and
a lateral inclination of the aircraft less than or equal to 5°.
It is known that minimum control speeds VMC may impose on the aircraft limits particularly on the permissible characteristic speeds on take-off and therefore on the performance of said aircraft. This is because, for safety reasons, it is necessary in particular:
for the rotational speed Vr on take-off to be greater than or equal to 1.05 VMCA, the speed VMCA being the minimum control speed on take-off;
for the minimum speed V2 at the second segment to be greater than or equal to 1.1 VMCA; and
for the minimum speed Vref on approach to be greater than or equal to VMCL, the speed VMCL being the minimum control speed on approach.
Of course, a minimum control speed is a characteristic of the type of aircraft considered. In consequence, to guarantee the required level of safety, without in any way being penalized by adopting excessively large margins with respect to its actual value, it is necessary to determine this minimum control speed as accurately as possible.
A method for determining, on an aircraft equipped with a number of engines, the minimum control speed with at least one engine shut down is known. According to that known method:
a) during a number of flights (known as test flights) of said aircraft, the values of predefined parameters are measured on said aircraft;
b) on the basis of said measurements and of at least one predefined certification value, a certification value Cnfcertif for the yaw moment cnf created by the shutting down of the engine is determined;
c) on the basis of said certification value Cnfcertif, the value of a parameter K is calculated to allow the forming of a first relationship
&Dgr;fn=K.Vc
2
,
in which:
&Dgr;fn illustrates the asymmetry of thrust due to the shutting down of the engine; and
Vc represents the speed of the aircraft; and
d) on the basis of said relationship and of engine thrust curves, said minimum control speed is determined.
In addition, according to this known method, in order to make the measurements on the aircraft, the rudder is brought hard over. As the value of the angle of turn &dgr;n of the rudder is then known, the aforementioned step b) is carried out, resolving a linear model of the behavior of the aircraft.
In order to do this, there are two different known models which can be written, respectively:
*
Ny
·
Cz
δ
n
=
A
·
Cnf
δ
n
+
B
*
sin
Φ
·
Cz
=
A
·
Cnf
+
B
In these models:
Ny is the lateral acceleration;
Cz is the coefficient of lift;
Cnf is the yaw moment created by the shutting down of the engine;
&PHgr; is the roll angle; and
A and B are two coefficient determined by means of a straight line in linear regression over the measured values.
This known method presents several drawbacks. In particular:
it is not very accurate;
because of the spread on the measurements and of the difficulty of obtaining perfectly stabilized points, the quality of said linear regression is low. Also, a number of test flights are needed in order to obtain from the measurements taken, a sufficiency of points to allow an appropriate selection of said points, this being with a view to obtaining sufficient quality for the linear regression; and
the reliability of this known method is low. Specifically, because of the low quality of the linear regression, different minimum control speeds are sometimes obtained for one and the same aircraft each time said known method is carried out.
An object of the present invention is to overcome these drawbacks. The invention relates to a reliable and effective method for determining, on an aircraft equipped with a number of engines, the minimum control speed with at least one engine shut down, either deliberately by a pilot or as the result of a failure.
To this end, said method whereby:
a) during at least one flight of said aircraft, the values of predefined parameters are measured on said aircraft;
b) on the basis of said measurements and of at least one predefined certification value, a certification value Cnfcertif for the yaw moment cnf created by the shutting down of the engine is determined;
c) on the basis of said certification value Cnfcertif, the value of a parameter K is calculated to allow the forming of a first relationship:
&Dgr;fn=K.Vc
2
,
in which:
&Dgr;fn illustrates the asymmetry of thrust due to the shutting down of the engine; and
Vc represents the speed of the aircraft; and
d) on the basis of said first relationship and of engine thrust curves, said minimum control speed is determined,
is noteworthy, according to the invention, in that, in said step b):
b1) on the basis of simultaneously measured values of, respectively, the sideslip &bgr; and the lateral force Cy, a second relationship between said sideslip &bgr; and said lateral force Cy is deduced;
b2) on the basis of said second relationship and of a certification value Cycertif of said lateral force Cy, a corresponding certification value &bgr;certif is determined for the sideslip &bgr;;
b3) on the basis of the simultaneously measured values of, respectively, said sideslip &bgr;, said lateral force Cy and said yaw moment Cnf, a third relationship between said sideslip &bgr;, said lateral force Cy and said yaw moment Cnf is deduced; and
b4) on the basis of said third relationship and of said certification values Cycertif and &bgr;certif, said certification value Cnfcertif is determined.
Thus, by virtue of the invention, said method is particularly effective and reliable. Indeed, when said second and/or third relationships are advantageously obtained by means of linear regressions over the measurements made on the aircraft, in particular:
said linear regressions are of much better quality than those of the aforementioned known method, with the same measurements (test points);
said regression straight lines are independent of the thrust level of the aircraft and are less sensitive to the dynamics or to less rigorous selection of the test points.
It will be noted that the aforementioned advantages of the method according to the invention over the customary procedures are due to better modeling of the behavior of the aircraft (introduction of sideslip, elimination of the turn angle &dgr;n). Schematically speaking, it may be said that with the old methods, the cluster of test points was considered from the worst possible viewpoint (Cy/Cnf) from the point of view of modeling, whereas with the method according to the invention, the plane in which this cluster is located is identified and projected onto a plane (Cy/&bgr;) in which the cluster appears in a very stretched-out form, which is favorable to linear regressions. Because of the better modeling, the spread on the measurement is reduced.
In consequence, by virtue of the invention:
it is possible to improve safety during test flights, that is to say during flights carried out in the aforementioned step a) because, as the curves of test points no longer depend on the asymmetry of the thrust, said test flights can be carried out, not with an engine shut down, but now simply with one engine at idle;
the number of test flights can be reduced, because of the following characteristics: better use of the test points, broader selection, independence of the configuration, of the level of thrust and of the mass, which means that it is not necessary to repeat the test flights for different configurations a
Cuchlinski Jr. William A.
Eads Airbus SA
Hernandez Olga
Stevens Davis Miller & Mosher LLP
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