HORIZONTAL STABILISER ACTUATOR WITH FREEPLAY DETECTING FEATURES AND METHOD THEREOF

Abstract

A screw (20) assembly for an actuator (10) is described comprising: a screw (20); a nut (22) threaded on said screw (20), such that rotation of said screw (20) causes axial movement of said nut (22); a stop located at an end of said screw (20) and defining an axial limit of said nut (22); a first feature located on said nut (22); and a second feature located on said stop; wherein said first and second features are configured to cooperate with one another substantially upon contact of said nut (22) with said stop so as to indicate an amount of free movement between said nut (22) and said screw (20).

Claims

1. The screw assembly for an actuator, comprising: a screw; a nut threaded on said screw, such that rotation of said screw causes axial movement of said nut; a stop located at an end of said screw and defining an axial limit of said nut; a first feature located on said nut; and a second feature located on said stop; wherein said first and second features are configured to cooperate with one another substantially upon contact of said nut with said stop so as to indicate an amount of free movement between said nut and said screw.

2. The screw assembly as claimed in claim 1, wherein said first feature comprises a first visual or tactile feature, for example a first mark, and said second feature comprises a second visual or tactile feature, for example a second mark.

3. The screw assembly as claimed in claim 1, wherein said first and second features are positioned or configured such that their relative positions upon contact of said nut with said stop provide a measure of free movement between said nut and said screw.

4. The screw assembly as claimed in claim 1, wherein a limit of acceptable free movement between said nut and said screw is determined, and said first and second features are configured such that, upon contact of said nut with said stop, said first and second features substantially align with one another if the free movement between said nut and said screw is within said limit, and do not substantially align with one another if the free movement between said nut and said screw is outside of said limit.

5. The screw assembly as claimed in claim 1, wherein a rotational position of said second feature upon contact of said nut with said stop is adjustable by adjusting the rotational position of the stop with respect to the nut.

6. The screw assembly as claimed in claim 1, wherein one of said nut and stop comprises a first lug configured to contact a lug on the other of said nut and stop to define an initial axial limit of said nut.

7. The screw assembly as claimed in claim 6, wherein said one of said nut and stop comprises a second lug configured to contact said lug on the other of said nut and stop before said first lug upon a predetermined increase in free movement between said nut and said screw.

8. The screw assembly as claimed in claim 7, wherein said contact between said second lug and said lug on the other of said nut and stop defines a subsequent, different axial limit of said nut.

9. The screw assembly as claimed in claim 8, wherein said first and second lugs are located at the same radial position, but different circumferential positions on said one of said nut and stop.

10. The screw assembly as claimed in claim 8, wherein said first and second lugs are located at different circumferential positions on said one of said nut and stop, and the rotational position of said nut and/or said stop is configured such that a predetermined clearance is provided between said second lug and said lug on the other of said nut and stop in the final turn of said screw.

11. The screw assembly as claimed in claim 10, wherein said predetermined clearance corresponds to a predetermined limit of acceptable free movement between said nut and said screw, such that said first lug contacts said lug on the other of said nut and stop if the free movement between said nut and said screw is within said limit, and said second lug contacts said lug on the other of said nut and stop if the free movement between said nut and said screw is outside of said limit.

12. The screw assembly as claimed in claim 6, wherein said predetermined clearance is calculated from a predetermined or predicted wear of said nut and/or screw during use.

13. The screw assembly as claimed in claim 6, wherein: said nut comprises said first and second lugs, and said first and/or second lugs comprise said first feature, and said lug on said stop comprises said second feature; or said stop comprises said first and second lugs, and said first and/or second lugs comprise said second feature, and said lug on said stop comprises said first feature.

14. An actuator for an aircraft comprising a screw assembly as claimed in claim 1.

15. The method comprising: providing a screw assembly for an actuator, said screw assembly comprising: a screw; a nut threaded on said screw, such that rotation of said screw causes axial movement of said nut; and a stop located at an end of said screw and defining an axial limit of said nut; wherein said stop or said nut comprises a first lug and a second lug; marking said nut and/or said stop so as to indicate an amount of free movement between said nut and said screw upon contact between said nut and said stop.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0057] Various embodiments will now be described, by way of example only, and with reference to the accompanying drawings in which:

[0058] FIG. 1 shows a horizontal stabiliser actuator;

[0059] FIGS. 2A-2C show cross sections of the screw/nut arrangement of the actuator;

[0060] FIG. 3 shows a flow diagram of an overstroke check;

[0061] FIG. 4 shows the screw/nut arrangement of the actuator;

[0062] FIGS. 5A and 5B show the backlash between the nut and the screw of the actuator.

DETAILED DESCRIPTION

[0063] FIG. 1 shows a horizontal stabiliser actuator 10.

[0064] The actuator 10 is connected to a fuselage structure 12 of an aircraft (not shown). A moveable component 14 is driven by the actuator 10. Specifically, the actuator 10 comprises a mechanical screw assembly comprising a screw 20, as well as a nut 22 threaded to the screw 20 and coupled to the moveable component 14. The screw 20 may be fixed in its longitudinal, or axial direction, such that rotation of said screw 20 causes the nut 22 to move up and down its length in the longitudinal, or axial direction. This in turn drives the moveable component 14 as required.

[0065] The screw 20 may be a ballscrew such that movement of said nut 22 is caused due to the presence of balls (not shown) between the nut 22 and the shaft of the screw 20.

[0066] The screw 20 is rotated by means of one or more motors 16 that drive a gear assembly 18, which gears cause said screw 20 to rotate. Upon rotation of the screw 20, the nut 22 moves between an upper stop 24 and a lower stop 26. The upper stop 24 and the lower stop 26 define the limits of the nut 22 and are rotatable with the screw 20.

[0067] FIGS. 2A-2C show the mechanical screw arrangement of the actuator 10.

[0068] FIG. 2A shows the nut 22 in its maximum retracted position, i.e. as it is retracted against the upper stop 24, and a retracted distance 30 is defined between the nut 22 and its attachment 28 to the fuselage 12.

[0069] FIG. 2B shows the nut 22 in its maximum extended position, i.e. as it is retracted against the lower stop 26, and an extended distance 32 is defined between the nut 22 and its attachment 28 to the fuselage 12.

[0070] FIG. 2C illustrates a differential distance 34 that the nut 22 moves as it travels from its maximum retracted position to its maximum extended position.

[0071] The differential distance 34 may be known as the maximum stroke of the nut 22 and/or the actuator 10. The maximum stroke includes what is known as an “overstroke”, which is a portion of the stroke just preceding the contact between the nut 22 and the upper stop 24 and/or lower stop 26. During normal operation, the nut 22 is not extended into the overstroke. Thus, the overstroke is present to avoid contact between the nut 22 and the upper stop 24 and/or lower stop 26.

[0072] The overstroke is calculated to take into account a given amount of free movement between the nut 22 and the screw 20. This free movement is otherwise known as backlash, or clearance, and is due to, for example, the free axial movement of the nut relative to the screw shaft. This might be caused in part by the movement of balls that may be present between the nut and the shaft of the screw (in the form of a ballscrew). Thus, the overstroke value is chosen such that during normal operation the nut 22 cannot contact the upper stop 24 and/or lower stop 26 due to this free movement.

[0073] FIG. 3 shows a flow diagram corresponding to the steps an aircraft computer might take to check and verify the overstroke.

[0074] To calculate the overstroke at a given point in time (“test overstroke”), a first initiated built-in test (“IBIT”) may be performed by the aircraft computer. A first step 3012 orders extension of the actuator 10 until the nut 22 contacts the lower stop 26 at 3013, and the position of the nut 22 in this maximum extended position is stored in memory 3014. The actuator 10 may then be retracted until the nut 22 contacts the upper stop 24 at 3015, and the position of the nut 22 in this maximum retracted position may be stored in memory 3017. An overstroke value is calculated at 3018 and output as the test overstroke.

[0075] A procedure 3021 may be carried out to provide a reference value for overstroke when an actuator 10 is fitted (“reference overstroke”). The reference overstroke may be calculated at 3022 using the same procedure as in steps 3012-3018. This reference overstroke may be stored in memory at 3023.

[0076] An overstroke comparison 3050 may be made between the reference overstroke and the test overstroke at a given point in time. This comparison outputs the difference between the reference overstroke and the test overstroke, and outputs state corresponding to the outcome of this comparison. For example, if this difference is lower than a given value then the outcome of the test may be positive, indicating that the current overstroke is within predefined limits.

[0077] If the difference is higher that a given value then the outcome may be negative, indicating that the nut 22 travel is shorter than previously. This may be due, for example, an increase in the free movement between the nut 22 and the screw 20 that causes the nut 22 to contact the upper stop 24 and/or lower stop 26 earlier in the stroke. In such a case, an inspection of the actuator may be required to check for wear.

[0078] FIG. 4 shows in more detail the nut 22 of the present disclosure. The nut 22 comprises a primary nut body 221, which forms the main part of the nut 22. A secondary nut body 222 is provided to act as a failsafe and provide a force to the moveable component 14 in case the primary nut body 221 fails, for example due to failure of the thread between the nut 22 and the primary nut body 221. Fuse pins 223 are provided between the primary nut body 221 and the secondary nut body 222. It is important to be able to provide a measure of the wear of the screw assembly during use, and this is the aim of the present disclosure.

[0079] FIG. 5A shows a schematic of the lower end stop 26 and the nut 22. It will be appreciated that the upper end stop 24 may have the same features as described below for the lower end stop 26. The nut 22 is shown in solid line at the start of the overstroke, and in a dotted line at the end of the overstroke. The screw (not shown), and hence the lower end stop 26, rotates a given number of times, for example in the illustrated case 1.5 times, between the start of the overstroke and the end of the overstroke.

[0080] The lower end stop 26 comprises a lug 50 that provides the contact surface for the nut 22. The axial travel of the nut 22 corresponding to a full turn of the screw may be less than the height of the lug 50, ensuring that the lug 50 is optionally the only contact surface of the lower end stop 26 with the nut 22.

[0081] The nut 22 comprises a first lug 52 and a second lug 54. The first lug 52 comprises a mark 53 and is configured to contact the lug 50 of the lower end stop 26 to define the initial axial limit of the nut 22. The second lug 54 does not comprise a mark, or may be marked differently, such that the first lug 52 and the second lug 54 are visually differentiable from one another.

[0082] FIG. 5B shows a schematic of the lower end stop 26 and the nut 22 in the middle of the overstroke, that is after 1 turn from the start. The dimensions are exaggerated and the schematic is not to scale. At this point in the rotation of the screw and lower end stop 26 the second lug 54 is travelling past the lug 50 of the lower end stop 26 and will not contact it due to the axial clearance 55 between the lug 50 and the second lug 54. It is apparent that if this axial clearance 55 is reduced then the second lug 54 will contact the lug 50 on the lower end stop 26 instead of, and prior to the first lug 52.

[0083] Upon an increase in free movement, or backlash between the nut 22 and the screw the axial clearance 55 shown in FIG. 5B will decrease. Therefore, the axial clearance 55 may be configured such that it corresponds to an acceptable amount of free movement between the nut 22 and the screw. Once the free movement between the nut 22 and the screw falls below this acceptable amount, the second lug 54 will contact the lug 50 on the lower end stop 26 instead of, and prior to the first lug 52.

[0084] This means that instead of the mark 53 on the first lug 52 showing next to the mark 51 on the lug of the lower end stop 26, there will be no mark showing. This allows a very easy indication of the amount of free movement between the nut and the screw. For example, an inspector can run the screw assembly to the end of the overstroke, and check whether the marks are aligned, or not.

[0085] The axial clearance 55 may be adjustable by adjusting the rotational position of the nut 22, or by adjusting the rotational position of the lower end stop 26. For example, the lower end stop 26 could be fixed to the screw by means of splines, and the lower end stop 26 could be removed from the screw assembly, rotated, and then inserted back into the screw assembly at a different rotational position.

[0086] It is possible to vary the structure described above whilst achieving the result of providing an indication of the amount of free movement between the nut and the screw using features provided on the nut and the stop.

[0087] It will be appreciated that the first and second lugs could be provided on the stop, rather than the nut, and a cooperating lug could be provided on the nut.

[0088] Instead of providing two lugs on the nut, for example, a single lug having a grading could be provided. A corresponding or cooperating mark could be provided on the lug on the stop such that the amount of free movement is indicated by the point at which the mark stops on the grading.

[0089] A plurality of lugs could be provided on the nut and/or stop, wherein the amount of free movement between the nut and the screw could be indicated by which of the plurality of lugs contacts a cooperating lug on the other of the nut and/or stop.

[0090] It will be appreciated that further arrangements are contemplated that achieve the effect of indicating an amount of free movement between said nut and said screw using features provided on the nut and the stop, and although the present disclosure has been described with reference to the embodiments described above, it will be understood by those skilled in the art that various changes in form and detail may be made without departing from the scope of the accompanying claims.