The invention relates to a joystick for controlling an aircraft.
Conventional aircraft are known, the flight controls of which are controlled by shifting a control lever connected mechanically to the orientable flight controls of the wings.
Aircraft for which orientation of the flight controls is performed by electric and/or hydraulic actuators controlled by sensors for sensing movement of the lever are also known. On such devices, the lever is therefore not linked mechanically to the flight controls and the pilot does not sense any resistance from the lever, which lets him estimate movements of the flight controls and the forces they undergo.
But some control levers are equipped with active and/or passive devices for simulating a feedback force on the lever.
Also, in some planes equipped with electronic flight controls, the control stick has been replaced by a control device called a “joystick”. More compact than a conventional control stick, the joystick is generally integrated into a pilot's seat armrest and comprises a lever which the pilot operates solely by the movement of his wrist. Installing joysticks has freed up the space between the pilot and the dashboard so that other equipment can be installed.
The joystick generally includes a set of springs for exerting a return force on each of the axes of rotation of the lever (roll axis and pitch axis) and to return the lever to a neutral position when the pilot exerts no force on the lever.
As the joystick is controlled by way of the wrist, return forces to be generated are much weaker than return forces generated on traditional control levers.
At the same time, the sensitivity of the pilot to the performance of the joystick is increased. It is therefore important to be able to generate return forces according to a law of force defined precisely and stably (that is, reproducible). However, the existence of friction in existing mechanisms tends to deteriorate behaviour of the joystick as is sensed by the pilot.
In particular, when the joystick is equipped with force sensors, friction occurs between the pieces of the mechanism causing bias and hysteresis in the measurements made by these sensors, such that the force feedback cannot be generated precisely.
Apart from friction problems, the usual passive devices are often a source of non-linearity of the elastic force, or even of coupling force, caused by displacement of an axis on the force sensed on the normally independent second axis. There are so many phenomena which contribute to imprecision of the force feedback.
An aim of the invention is to propose a joystick for controlling an aircraft, which is simple, robust and has no risk of jamming, to create return forces with good precision and stably.
This aim is attained, within the scope of the present invention, by a joystick for controlling an aircraft, comprising:
The structure of the pivot joint used in the mechanical linking assembly guides the lever in rotation without creating friction and at the same time generates a force feedback on the lever.
Also, the structure of the joint allows integrating sensors right inside the articulation.
Also, several pivot joints can be assembled in series to produce complex laws of force feedback.
The joystick according to the invention can also have the following characteristics:
Other characteristics and advantages will emerge from the following description which is purely illustrative and non-limiting and must be considered with respect to the appended figures, in which:
The joystick 1 comprises a frame 2 intended for example to be integrated into a pilot's seat armrest, a lever 3 mounted mobile in rotation relative to the frame 2, and a mechanical linking assembly 4 of the lever on the frame for generating a return of force on the lever according to two axes of rotation X and Y.
The lever 3 has a general elongated form according to a longitudinal direction (axis Z′).
The mechanical linking assembly 4 comprises two support pieces 5 and 6 mounted fixed relative to the frame 2, an intermediate piece 7 mounted mobile in rotation relative to the support pieces 5 and 6 about the first axis X, and a connecting piece 8 on which is fixed the lever 3, the connecting piece 8 being mounted mobile in rotation relative to the intermediate piece 7 about the second axis Y. The second axis Y is perpendicular to the first axis X. Also, when the lever 3 is in neutral position, the axes X, Y and Z′ are orthogonal to each other.
The mechanical linking assembly 4 also comprises a first couple of pivot joints 9, 10 and a second couple of pivot joints 11, 12.
The intermediate piece 7 has the form of a cross. More precisely, the intermediate piece 7 comprises four arms 13 to 16 extending from a common point of attachment 17, each arm being connected at the level of its free end to a respective pivot joint 9 to 12.
The first couple of pivot joints includes a first pivot joint 9 mounted between the support piece 5 and the intermediate piece 7 and a second pivot joint 10 mounted in parallel to the first pivot joint 9, between the support piece 6 and the intermediate piece 7. The pivot joints 9 and 10 enable rotation of the intermediate piece 7 relative to the frame 2 about the axis X.
The second couple of pivot joints includes a third pivot joint 11 mounted between the intermediate piece 7 and the connecting piece 8 and a fourth pivot joint 12 mounted in parallel to the third pivot joint 11, between the intermediate piece 7 and the connecting piece 8. The pivot joints 11 and 12 enable rotation of the intermediate piece 7 relative to the frame 2 about the axis Y.
The mechanical linking assembly 4 enables rotation of the lever 3 relative to the frame 2 simultaneously about the axis X and about the axis Y, for example letting the pilot control the aircraft for roll and pitch.
The pivot joint 9 comprises a first part 91 and a second part 92 mounted mobile relative to the first part 91. The first part 91 is fixed to the support piece 5 (that is, the frame 2) and the second part 92 is fixed to the intermediate piece 7.
The first part 91 and the second part 92 each have a general cylindrical form and are positioned relative to each other with their axes of revolution combined, the two parts 91 and 92 having a cylindrical section of same internal radius relative to this common axis of revolution.
The pivot joint 9 also comprises two flexible blades 93 and 94, each flexible blade connecting the first part 91 and the second part 92 together. The two flexible blades include a first blade 94 extending parallel to a first plane and a second blade 93 extending parallel to a second plane, orthogonal to the first plane. The first plane and the second plane pass through the common axis of revolution of the parts 91 and 92.
Each flexible blade 93, respectively 94, has a first end fixed to the first part 91 and a second end fixed to the second part 92. More precisely, each end of the blade 93, respectively 94, is linked mechanically by a complete link (or housing) to one of the parts 91, 92.
The blades 93, 94 are resiliently deformable in flexion to enable rotation of the second part 92 relative to the first part 91 according to an axis of rotation corresponding to the common axis of revolution of the parts 91 and 92, and generate return torque tending to oppose rotation of the second part 92 relative to the first part 91.
So, the blades 93 and 94 ensure guiding in rotation of the second part 92 relative to the first part 91, according to a single degree of liberty (rotation according to a single axis of rotation).
The blades 93 and 94 work in pure flexion, and each blade can be used as a test body to support a sensor 950, such as a strain gauge for example. This produces measuring directly representative of the torque or travel nearest the origin and consequently, not perturbed by friction or play.
In
In
The structure of the pivot joints 10 to 12 shown in
In this variant, the pivot joint 9 comprises four blades 93 to 96. The blades include a first couple of blades 93, 94 and a second couple of blades 95, 96, the couples of blades being arranged symmetrically relative to each other.
Each couple of blades comprises a first blade 93 (respectively 96) extending parallel to a first plane and a second blade 94 (respectively 95) extending parallel to a second plane orthogonal to the first plane.
The first blades 93 and 96 (or lateral blades) extend on either side of the second blades 94 and 95 (or central blades), the second blades 94 and 95 being arranged side by side.
This first variant provides security in case of cracking of one of the blades. In case of accidental cracking of one of the blades, it is possible to retain functioning in downgraded mode by retaining the guide function of the pivot link, without loss of travel, and with functional stiffness diminished by a quarter only (one blade in four in nominal rotation mode). The blades must be separated from each other beyond their housing so that any breakage of one blade does not spread to the other blade.
In this variant, the second part 92 of the pivot joint 9 is mobile in rotation relative to the first part 91 of the pivot joint from a rest position (position of the joint when no force is applied to the joint), according to a first direction of rotation only (arrow A). For this purpose, the pivot joint 9 comprises a stop 97 arranged to prohibit rotation of the second part 92 relative to the first part 91 in a second direction of rotation (arrow B), opposite to the first direction.
In this variant, the stop 97 is arranged such that when the joint is in a rest position (that is, no force is being applied to the joint), the blades 93, 94 of the pivot joint 9 are flexed and exert on the second part 92 of the joint non-zero return torque tending to keep the second part 92 supported against the stop 97.
The position of the stop 97 can be adjusted (for example by means of a threaded element) so as to adjust the angle+θ1 to then adjust the minimal actuation torque C.
This fourth variant is here identical to the second variant, but could apply to any other variant. In the fourth variant, the pivot joint 9 also comprises an elastic element 98, such as a spring for example, connecting the first part 91 and the second part 92 together. The elastic element 98 is held elongated over the entire range of angular travel of the second part 92 relative to the first part 91.
The elastic element 98 is arranged between the central blades 94, 95 and extends in a direction forming an angle of 45 degrees relative to the blades 93, 94, 95 and 96.
As is illustrated in
Since the second part 92 is shifted in rotation relative to the first part 91, the resilient force generated by the elastic element 98 no longer passes through the axis of rotation of the pivot joint 9, and it tends to favour rotation in the same direction as that of the second part 92 relative to the first part 91.
Because of this arrangement, the elastic element 98 generates negative return torque which compensates, at least in part, the positive return torque generated by the blades 93 to 96. Selecting appropriately the characteristics of the elastic element 98 makes it possible to design a pivot joint 9 without friction and having zero stiffness near the neutral position.
Also, it is possible to provide adjusting means 980 of the tension of the elastic element 98 (for example a threaded element cooperating with the first part 91), for adjusting the resulting stiffness of the pivot joint 9.
Also, in the example shown in
The position of the stop 99 can be adjusted (for example by means of a threaded element cooperating with the first part 91 of the pivot joint 9) so as to adjust the angle +θ1 for change of stiffness of the assembly.
The resulting law of variation has a double slope. More precisely, the stiffness follows a law of variation defined by sections.
In a first range of travel between 0 and θ1, the two pivot joints 9 and 109 are driven in rotation simultaneously. The resulting return torque generated by the assembly of joints 9 and 109 is a combination of individual return torques generated by the two pivot joints 9 and 109. This resulting return torque is proportional to the angle of rotation θ of the second part 1092 of the pivot joint 109 relative to the first part 91 of the pivot joint 9 with a first stiffness resulting from the combination of individual stiffness of the two pivot joints 9 and 109 in series.
When the angle of rotation θ reaches θ1, the second part 92 of the pivot joint 9 comes into contact against the stop 99 such that the second part 92 can no longer be driven in rotation relative to the first part 91.
In a second range of travel between θ1 and θ2, the return torque generated by the assembly of the joints 9 and 109 varies in a linear manner with a second stiffness equal to individual the stiffness of the pivot joint 109 alone.
When the angle of rotation θ reaches 02, the second part 1092 of the pivot joint 109 arrives stopped against the first part 1091 of the pivot joint 109 and the second part 1092 can no longer be driven in rotation relative to the first part 1091. No rotation of the assembly is possible beyond θ2.
The same functioning can be obtained by assembling in series pivot joints 9 and 109 having the same angular travel, but different degrees of stiffness. In fact, with equal travel, the supplest pivot joint arrives stopped before the stiffest pivot joint. When the supplest pivot joint reaches its stop, the stiffness of the assembly, initially less than each of the two degrees of stiffness, will be returned to the stiffness of the stiffest pivot joint which will not yet have reached its stop.
This second embodiment is identical to the first embodiment, except that the first pivot joint 9 and the second pivot joint 10 have been replaced by a first chain of pivot joints 9, 109, 209, 309 and a second chain of pivot joints 10, 110, 210, 310 mounted between the support pieces 2 and the intermediate piece 7.
Similarly, the third pivot joint 11 and the fourth pivot joint 12 have been replaced by a third chain of pivot joints 11, 111, 211, 311 and a fourth chain of pivot joints 12, 112, 212, 312 mounted between the intermediate piece 7 and the connecting piece 8.
In the example shown in
For this purpose, the pivot joints 9, 109, 10, 110, 11, 111, 12, 112 comprise a stop 97, such as that which is shown in
Similarly, the pivot joints 209, 309, 210, 310, 211, 311, 212, 312 comprise a first stop 97, such as that which is shown in
Also, each of the pivot joints 9, 10, 11 and 12 comprises a second stop 99 limiting travel of the joint in the first direction of rotation, such as what is shown in
Similarly, each of the pivot joints 209, 210, 211 and 212 comprises a second stop 99 limiting travel of the joint in the second direction of rotation, such as that is shown in
As is illustrated in this figure, when the lever 3 is inclined in a second direction (arrow B) about the axis Y, only the pivot joints 211, 311 and 212, 312 work. The pivot joints 11, 111 and 12, 112 are stopped.
Inversely, when the lever 3 is inclined in a first direction (arrow A), opposite the second direction, only the pivot joints 11, 111 and 12, 112 work. The pivot joints 211, 311 and 212, 312 are stopped.
As is illustrated in this figure, when the lever 3 is inclined in a second direction (arrow B), only the pivot joints 209, 309 and 210, 310 work. The pivot joints 9, 109 and 10, 110 are stopped.
Inversely, when the lever 3 is inclined in a first direction (arrow A), opposite the first direction, only the pivot joints 9, 109 and 10, 110 work. The pivot joints 209, 309 and 210, 310 are stopped.
As is illustrated in
Also, the law of variation has a double slope. More precisely, the stiffness of the assembly has a law of variation by sections. In a first range of travel between 0 and θ1, the return torque generated by the chain of pivot joints has a linear variation as a function of the angle of rotation θ with a first stiffness. In a second range of travel between θ1 and θ2, the return torque generated by the chain of pivot joints has a linear variation with a second stiffness (stiffness of pivot joints 109, 309 and 110, 310 according to each of the directions of the axis X and stiffness of pivot joints 111, 311 and 112, 312 according to each of the directions of the axis Y).
In this way, combination of several pivot joints assembled in series produces laws of complex force return, the characteristics and the assembly of the pivot joints able to vary as a function of the preferred law of force feedback.
Number | Date | Country | Kind |
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12 55325 | Jun 2012 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/061794 | 6/7/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/182680 | 12/12/2013 | WO | A |
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3771037 | Bailey, Jr. | Nov 1973 | A |
5125602 | Vauvelle | Jun 1992 | A |
9242722 | Buoy | Jan 2016 | B2 |
20090314116 | Bandera | Dec 2009 | A1 |
Number | Date | Country |
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WO 2008017344 | Feb 2008 | DE |
2 136 280 | Dec 2009 | EP |
2502038 | Nov 2013 | GB |
Number | Date | Country | |
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20150128754 A1 | May 2015 | US |