FR2722443A1 - SURFACE TREATMENT DEVICE - Google Patents

Abstract

A surface treatment device, for an aircraft (1), including a vehicle (2) and a working head (25) mounted on said vehicle through a positioning mechanism (4-24), a computer, proprioceptive sensors for detecting the attitude of said positioning mechanism, beacons (31) which may be arranged at predetermined points on said aircraft, and a bearing sensor (30) capable of localising the bearing of said beacons relative to the vehicle. The computer is programmed for determining the position of the surface treatment device in relation to the aircraft on the basis of information provided by the proprioceptive sensors and the bearing sensor, and for displaying said relative position to the user.

Description

SURFACE TREATMENT DEVICE
The invention relates to a surface treatment device, and more particularly to a device for treating a surface of a large object, which is positioned on level ground, this device comprising a vehicle on the ground and a head. work mounted on the vehicle by means of a positioning mechanism of large clearance capable of positioning and moving the working head on the surface of the object to be treated, and also comprising a control system provided with computer processing means.

 A device of this type is disclosed, for example, in document CA-A-2,071,162.

 The large object whose surface must be treated can be in particular an airplane.

 The surface treatment envisaged here may in particular be a pickling, but also a cleaning, a treatment preparatory to polishing, a polishing, or a non-destructive inspection, etc.

 In surface treatment devices of the type defined above, the relative positioning of the vehicle, of the positioning mechanism and of the working head relative to the object to be treated is generally controlled by an operator, from the vehicle. This positioning is delicate.

 On the one hand, the large dimensions of the object to be treated mean that the working head must generally be placed at a location on the surface of the object to be treated which is distant from the operator, so that direct visual control of the positioning by the operator is not possible or insufficient.

 On the other hand, the large dimensions of the object to be treated also imply large dimensions for the positioning mechanism of the working head as well as numerous degrees of freedom for this positioning mechanism, so that it is particularly difficult for an operator to control movements of the vehicle or of the positioning mechanism while controlling that there is no risk of a collision between the vehicle, the positioning mechanism or the working head and the object to be treated.

 The present invention aims in particular to remedy these drawbacks.

To this end, according to the invention, a surface treatment device of the kind in question is essentially characterized in that it further comprises
- proprioceptive sensors to detect the attitude of the positioning mechanism,
- beacons intended to be placed at predetermined points relative to the object to be treated,
- a deposit sensor capable of identifying a deposit of each tag relative to the vehicle,
- And a memory comprising the geometric shape of the object to be treated, as well as geometric data relating to the vehicle, the positioning mechanism and the working head, and in that the processing means are connected to the proprioceptive sensors, to the deposit and memory sensor, the processing means being programmed to determine the relative position of the vehicle, the positioning mechanism and the working head relative to the object to be treated from information provided by the proprioceptive sensors and the field sensor, and from the information contained in the memory.

 Thus, when the device is controlled at least in part by an operator from the vehicle, it is possible to present to this operator the relative position of the surface treatment device and of the object to be treated, for example on one or more screens. . In this way, the operator can more easily control the movements and the positioning of the surface treatment device relative to the object to be treated, so as to obtain a precise positioning of this device and to avoid collisions between the device and the object to be treated. In addition, in this case, the processing means can help the operator by guiding him in the operation of the surface treatment device, or else the treatment means can automatically take over part of the operation and operation. of the surface treatment device.

 It would also be possible to conceive that the device according to the invention operates without an operator, although this is not a preferred solution, for reasons of cost and complexity.

In preferred embodiments, use is also made of one and / or the other of the following arrangements.
an interface is connected to the processing means for presenting to an operator the relative position of the vehicle, of the positioning mechanism and of the working head relative to the object to be treated
the processing means are also programmed to determine the movements of the positioning mechanism to be carried out in order to place the device in a configuration determined relative to the object to be treated, and also programmed to indicate these movements to the operator by the interface intermediary; if necessary, the movements of the vehicle to be carried out to place the device in a determined configuration with respect to the object to be treated can also be determined by the processing means and indicated to the operator via the interface.

the control system also comprises stop means for immobilizing the device, these stop means being connected to the processing means, and the processing means being programmed to
constantly check whether a collision is likely to occur
produce between the device and the object to be treated,
partly a function of the relative position of the device
and of the object, and on the other hand the movements in progress of the
device,
and immobilize at least part of the device by
through stop means when such a risk of
collision is detected, which further improves safety
of the device according to 1 invention with regard to collisions;
each of the beacons transmits coded signals which are specific to it, and the field sensor is able to receive said coded signals remotely and to transmit them to the processing means, which are programmed to recognize each beacon according to the signals received by the field sensor, which facilitates the calculation of the relative positioning of the device relative to the object to be treated
- the beacons emit infrared signals;
- at least three beacons are intended to be arranged at predetermined points relative to the object to be treated
the positioning mechanism comprises at least one distance sensor which is connected to the processing means and which is carried by a part of this mechanism located near the working head, in order to refine the positioning of this working head relative to the surface of the object to be treated; despite the slight inaccuracies (of the order of a few centimeters) induced in the control of the position of the working head relative to the object to be treated by means of the beacons and the bearing sensor (inaccuracies due in particular to the resolution of the proprioceptive sensors of the positioning mechanism, with possible slight faults in positioning the beacons relative to the predetermined points where they must be placed, or even at an abnormal position of the object to be treated relative to the ground, in particular an inclination of this object when said object is a plane loaded asymmetrically), it is thus possible to know the relative position of the working head relative to the surface of the object to be treated with great precision, for example of the order of a few millimeters;
the positioning mechanism comprises a guide beam which has a longitudinal direction in which a carriage can move, this carriage supporting the working head by means of an articulated arm, the guide beam being mounted on a carried boom by the vehicle and being able to pivot with respect to this arrow along at least a first axis, which is perpendicular to the longitudinal direction of the guide beam, said guide beam having a front face intended to be disposed facing the surface of the object to be treated, the guide beam comprising at least two distance sensors disposed on its front face, in different locations along its longitudinal direction: the operator or the processing means can thus position the guide beam with its longitudinal direction arranged parallel to the surface of the object to be treated, by pivoting of said guide beam around said first axis until the two distance sensors give identical measurements; thanks to this positioning of the guide beam, the movements imposed on all or part of the organs of the articulated arm are minimized when the carriage moves along the guide beam while the working head is kept in contact on the surface of the the object to be treated
the guide beam is also mounted on the boom by means of at least one second axis, which is horizontal and perpendicular to the first axis: the operator or possibly the processing means can thus have the front face of the guide beam parallel, that is to say tangentially to the surface of the object to be treated, by seeking an angular position of the beam around the horizontal axis which minimizes the distance measurements of the two distance sensors carried by the guide beam, by an angular displacement of the guide beam around said horizontal axis
- the distance sensor is an ultrasonic sensor
the working head comprises peripheral obstacle detection means which are connected to the processing means, these processing means being connected to control means for automatically controlling the movement of the working head over the surface of the object to be processed, and said processing means being programmed to immobilize the working head when the peripheral obstacle detection means detect an obstacle;
the working head is a pickling head and comprises vision means connected to the processing means, these processing means being connected to control means for automatically controlling the movement of the pickling head on the surface of the object to be treated, and said processing means being programmed to detect the limit of a previously pickled area on the surface of the object to be treated, and to move the working head without exceeding said limit during operation of the working head, thus avoiding additional stripping of the previously stripped area
the processing means are programmed to calculate a positioning of the object to be treated with respect to the ground, as a function of an inclination of this object relative to a normal position, this inclination being previously noted by an operator and transmitted to the means processing through an interface.

 Other characteristics and advantages of the invention will appear during the following description of one of its embodiments, given by way of nonlimiting example, with reference to the accompanying drawings.

On the drawings
FIG. 1 is a perspective view of an aircraft stripping device according to one embodiment of the invention,
FIG. 2 is a schematic plan view showing the principle of positioning of the stripping device of FIG. 1 with respect to three beacons placed on the landing gear of the aircraft,
FIG. 3 is a block diagram illustrating the control system of the stripping device of FIG. 1, and
- Figure 4 is a schematic sectional view of the working head of the stripping device of Figure 1.

 In the different figures, the same references designate identical or similar elements.

 In the particular embodiment of the invention which is shown in the drawings, the device of the invention aims to strip the paint on the surface of an aircraft 1, although other surface treatments can be envisaged in the context of the invention and that other large objects, for example a ship's hull, can be treated using the device of the invention, as explained above.

 As shown in FIG. 1, the airplane 1 rests on a flat ground, for example an airport parking area, and the stripping device comprises a vehicle 2 traveling on the same flat ground, preferably horizontal.

 The vehicle 2 comprises a mobile base 3 mounted on wheels, and an articulated positioning mechanism which makes it possible to position and move a working head 25 on the surface of the aircraft 1.

 In the example shown, the positioning mechanism comprises a turret 4 including a cabin 4a in which an operator can take place, an arrow 5-10 which is carried by the turret 4 and at the distal end of which a beam is mounted 16 transverse guide on which a carriage 17 can move longitudinally, this carriage 17 supporting a working head 25 by means of an articulated arm 19-23.

 The arrow 5-10 comprises a first segment 5 whose first end is pivotally mounted on the turret 4 about a horizontal axis (not shown), a second segment 7 whose first end is pivotally mounted at the second end of the first segment 5 around a horizontal axis 6, a third segment 9 of which a first end is pivotally mounted at the second end of the second segment 7 around a horizontal axis 8, and a fourth segment 10 sliding telescopically at the second end of the third segment 9.

 The guide beam 16 is mounted on the arrow 510 by means of two rigid arms 12 and 14, the arm 12 having a first end pivotally mounted at the distal end of the fourth segment 10 of the arrow, around an axis horizontal 11, the arm 14 having a first end which is pivotally mounted at the second end of the arm 12, about a horizontal axis 13, the guide beam 16 being pivotally mounted at the second end of the arm 14, around a axis 15 perpendicular to the arm 14 and to the longitudinal direction of the guide beam 16.

 In the example shown, the articulated arm comprises a first segment 19 whose first end is pivotally mounted on the carriage 17, around an axis 18, a second segment 21 whose first end is pivotally mounted at the second end of the first segment 19 by means of an axis 20, and a third segment 23 of which a first end is pivotally mounted at the second end of the second segment 21, around an axis 22, the three axes 18, 20, 22 all being parallel to the longitudinal axis of the guide beam 16. Finally, the working head 25 is mounted at the second end of the third segment 23 by means of a connection 24 similar to a ball joint, this connection 24 preferably comprising elastic elements such that air jacks able to maintain the working head 25 in contact with the surface of the aircraft 1 and to detect this contact.

The base 3, the turret 4 with the exception of the cabin 4a, the arrow 5-10, the two arms 12 and 14 as well as the axis 15 can be derived for example from the nacelle lifting device marketed by the company GROVE ( SHADY GROVE,
PENSYLVANIA, USA), under the reference AMZ 86 or AMZ 86XT.

 As shown in FIG. 4, the working head 25 can comprise an enclosure 25a having an open front face which is intended to be disposed against the surface of the aircraft 1. The enclosure 25a comprises a pickling nozzle 27a which is supplied in compressed air charged with solid particles by a supply duct 27, and it is also connected to suction means by a suction duct 28.

 In addition, the pickling head comprises a video camera 39 provided with lighting means for viewing the state of the surface of the aircraft 1 inside the enclosure 25a of the working head.

 Finally, the enclosure 25a has at its periphery a bead 40 of rubber provided with contact sensors, or any other peripheral obstacle detectors, the usefulness of which will be seen later.

 The supply 27 and suction 28 conduits are connected to an auxiliary assembly 26 (FIG. 1) via a flexible conduit 26a. In the example shown, the auxiliary assembly 26 is mounted on a carriage independent of the vehicle 2 but can preferably be controlled from this vehicle.

 The auxiliary assembly 26, supplied with compressed air and electrical energy, comprises a reserve of solid particles intended to be projected onto the surface of the aircraft by the nozzle 27a, suction means, and a receptacle for collecting particles. solids and paint residue from the suction duct 28. Optionally, the auxiliary assembly 26 may also include means for recycling the solid particles collected by suction.

 From the cab 4a of the vehicle, the operator manually controls the movement of the base 3 of the vehicle, the rotation of the cab 4, the positioning of the different segments of the boom 5-10, the positioning of the two arms 12 and 14 and the positioning of the guide beam 16. I1 is helped for this by a control system 33, shown diagrammatically in FIG. 3.

 This control system comprising a microcomputer central unit 34 which is connected to a mass memory 35, for example a magnetic hard disk, and to an interface 36 allowing dialogue between the operator and the central unit, for example one or more screens and a keyboard possibly associated with a mouse or the like.

 The central unit 34 is connected to proprioceptive sensors C1-C2, ... Cn distributed in the positioning mechanism of the pickling head, which indicate to the central unit 34 the relative position of each part of this positioning mechanism with respect to another part, as soon as there is a possible movement between these two parts. The memory 35 contains all the geometric data relating to the vehicle 2, to the positioning mechanism and to the working head, so that the data coming from the proprioceptive sensors Cl-Cn allow the central unit to reconstruct the exact configuration of the surface treatment and to present this configuration to the operator on the screen or screens of the interface 36.

 On the other hand, the central unit 34 is also connected to a deposit sensor 30, which can optionally be arranged on the front of the cabin 4, as shown in FIG. 1. This deposit sensor 30 makes it possible to locate the deposit, in horizontal projection, of several beacons 31 arranged at predetermined points on the aircraft, for example on its landing gear. These beacons 31 can also be placed on supports secured to the airplane 1 at predetermined points, and in general they are arranged at predetermined points relative to the airplane 1.

 The beacons 31 may possibly be beacons emitting infrared signals, these signals possibly being coded with a separate code for each beacon, the field sensor then being adapted to transmit the code of each infrared signal to the central unit, and l the central unit being programmed to recognize the code specific to each beacon.

 The deposit sensor 30 is preferably provided for locating the deposit of beacons 31 at close time intervals.

According to an exemplary embodiment, the beacons 31 and the deposit sensor 30 may be of the type marketed under the brand SIRRAH by the company MICROMAINE, LE MANS,
FRANCE.

 As shown in FIG. 2, the deposit sensor 30 transmits the deposits 61, 62, 03 of the three beacons 31 to the central unit 34, these deposits being measured with respect to a reference axis 2a integral with a part of the vehicle 2 or of the positioning mechanism, this axis possibly being for example the projection on the ground of the longitudinal axis of the arrow 5-10.

 The memory 35 contains the geometric shape of the airplane 1, as well as the coordinates of the predetermined points of this airplane where the beacons 31 are fixed.

 From this geometrical data and from the three fields o 2, 83, the central unit 34 is programmed to calculate the position of the field sensor 30 relative to the airplane 1. The arrangement in space of the pickling device being moreover known, as explained above, the central unit 34 is therefore able to reconstruct the relative positioning of the pickling device with respect to the airplane 1, to within a few centimeters or tens of centimeters. This relative positioning can therefore be indicated to the operator, for example by one or more graphic displays on the screen or screens of the interface 36. The operator is therefore able to very precisely control this positioning.

 Optionally, for the calculation of the relative positioning of the pickling device with respect to the aircraft, the central unit 34 can take into account an inclination of the aircraft relative to its normal position, in particular if the aircraft is loaded so asymmetrical. This inclination is in this case indicated to the central unit 34 by the operator, before the positioning operations.

 In addition, the central unit 34 is also connected to stop means 37, for example electromagnetic contactors or solenoid valves, which make it possible to stop one or more movements of the pickling device when the central unit detects that the movement in progress may cause a collision between a part of the stripping device and the aircraft.

 According to a particularly advantageous embodiment, the central unit 34 is programmed to indicate to the operator via the interface 36, the various movements which it must cause the vehicle 2 or the positioning mechanism to place the device in a configuration determined in relation to the airplane 1, when the operator indicates to the central unit 34 which part of the surface of the airplane he wishes to strip. The indications of movement given to the operator are preferably sequential, so that the operator has only one instruction to follow at a time, the order of the movements can also be important to avoid collisions. These movements could however be automated in whole or in part.

 When the operator has placed the guide beam 16 in a given position relative to the airplane 1, the central unit 34 first of all proceeds to readjust the position of the guide beam relative to the airplane .

 For this, the front face of said guide beam, that is to say its face which is directed towards the plane and on which slides the carriage 17, comprises at each of its longitudinal ends an ultrasonic sensor 32 which allows to precisely measure the distance between the guide beam 16 and the surface of the aircraft 1. Thanks to these distance sensors 32, the position of the guide beam 16 is known with respect to the aircraft with great precision, on the order of a few millimeters, and therefore the position of the working head 25 is also known with precision, since this working head 25 is mounted on the guide beam 16 by means of a relatively short mechanism, including a little generator imprecision.

 In addition, thanks to these distance sensors 32, the operator can place the front face of the guide beam 16 in a parallel (tangential) arrangement relative to the surface of the aircraft. This positioning is effected on the one hand by rotation of the guide beam 16 around its axis 15 so that the distances measured by the two sensors 32 are equal, and on the other hand, by rotation around the axis 13 so as to minimize the distance measured by the sensors.

 Following this precise positioning of the guide beam 16, the central unit 34 positions the working head 25 on the surface of the aircraft 1, triggers the operation of the auxiliary assembly 26 by means of control 38, in particular solenoid valves or electromagnetic contactors, and also controls the movement of the working head 25, also by means of control means 38. The movement of the working head 25 takes place by means of the movement of the carriage 17 and the articulated arm which connects the working head to this carriage.

 During this movement of the working head 25, when the peripheral flange 40 of the working head detects an obstacle on the surface of the aircraft 1, for example an antenna which has not been located in the memory 35 of the control system, the central unit 34, which is connected to the sensors of the bead 40, stops the movement of the working head 25 and the course of the stripping procedure.

 In addition, the video camera 39 is preferably connected to the central unit 34, and this central unit is programmed to process the image captured by the camera 39, in order on the one hand to control the advancement speed of the head. work 25 as a function of the actual stripping efficiency, and on the other hand detect the possible limits of an area 1a of the surface of the aircraft which has already been stripped.

 The central unit 34 can thus be programmed to move the working head 25 in operation without exceeding the limit of the previously scoured area 1a, thereby avoiding additional scouring of said area 1a, which could be harmful.

 Optionally, the central unit 34 can also be programmed to position the working head 25 on the edge of the previously stripped area, during the initial positioning of said working head 25 after a displacement of the guide beam 16 controlled by the operator, when changing the pickling area.

Claims (14)

 1. Device for treating a surface of an object (1) of large dimensions which is positioned on a flat floor, this device comprising a vehicle (2) on the ground and a working head (25) mounted on the vehicle by means of '' a positioning mechanism (4-24) of large clearance able to position and move the working head on the surface of the object to be treated, and also comprising a control system (33) provided with processing means (34 ) IT, the device being controlled at least in part by an operator from the vehicle, characterized in that it further comprises  - proprioceptive sensors (Cl-Cn) to detect the attitude of the positioning mechanism (4-24),  - tags (31) intended to be arranged at predetermined points relative to the object (1) to be treated,  a deposit sensor (30) capable of identifying a deposit (0 2, 03) of each beacon relative to the vehicle,  - And a memory (35) comprising the geometric shape of the object to be treated, as well as geometric data relating to the vehicle (2), to the positioning mechanism (4, 24) and to the working head (25), and in that the processing means (34) are connected to the proprioceptive sensors (Cl-Cn), to the reservoir sensor (30) and to the memory (35), the processing means (34) being programmed to determine the relative position of the vehicle, of the positioning mechanism and of the working head with respect to the object to be treated on the basis of the information provided by the proprioceptive sensors and the bearing sensor, and on the basis of the information contained in the memory.  2. Device according to claim 1, in which an interface (36) is connected to the processing means for presenting to an operator the relative position of the vehicle, of the positioning mechanism and of the working head relative to the object to be treated. .  '3. Device according to claim 2, in which the processing means (34) are further programmed to determine the movements of the positioning mechanism (424) to be carried out in order to place the device in a determined configuration relative to the object to be treated, and also programmed to indicate these movements to the operator via the interface (36).  4. Device according to any one of the preceding claims, in which the control system (33) further comprises stop means (37) for immobilizing the device, these stop means being connected to the processing means (34 ), and the processing means (34) being programmed to  - permanently check whether a collision is likely to occur between the device and the object (1) to be treated, depending on the one hand on the relative position of the device and the object, and on the other hand on the movements in course of the device,  - And immobilize at least part of the device via the stop means when such a risk of collision is detected.  5. Device according to any one of the preceding claims, in which each of the beacons (31) transmits coded signals which are specific to it, and in which the field sensor (30) is able to receive said coded signals remotely and to transmitting them to the processing means (34), which are programmed to recognize each beacon (31) as a function of the signals received by the field sensor (31).  6. Device according to any one of the preceding claims, in which the beacons (31) emit infrared signals.  7. Device according to any one of the preceding claims, comprising at least three tags (31) intended to be arranged at predetermined points relative to the object to be treated.  8. Device according to any one of the preceding claims, in which the positioning mechanism (4-24) comprises at least one distance sensor (32) which is connected to the processing means (33) and which is carried by a part of this mechanism located near the working head (25), to refine the positioning of this working head relative to the surface of the object (1) to be treated.  9. Device according to claim 8, wherein the positioning mechanism comprises a guide beam (16) which has a longitudinal direction in which can move a carriage (17), this carriage supporting the working head (25) by l 'via an articulated arm (19-23), the guide beam (16) being mounted on an arrow (5-10) carried by the vehicle (2) and able to pivot relative to this arrow according to at least a first axis (15), which is perpendicular to the longitudinal direction of the guide beam, said guide beam having a front face intended to be placed facing the surface of the object (1) to be treated, and in which the beam guide comprises at least two distance sensors (32) arranged on its front face, in different locations along its longitudinal direction.  10. Device according to claim 9, wherein the guide beam (16) is also mounted on the boom (5-10) via at least one second axis (13), which is horizontal and perpendicular to the first axis.  11. Device according to any one of claims 8 to 10, in which the distance sensor (32) is an ultrasonic sensor.  12. Device according to any one of the preceding claims, in which the working head comprises peripheral obstacle detection means (40) which are connected to the processing means (34), these processing means being connected to means. control (38) for automatically controlling the movement of the working head (25) on the surface of the object (1) to be treated, and said processing means being programmed to immobilize the working head (25) when the means obstacle detection device (40) detects an obstacle.  13. Device according to any one of the preceding claims, in which the working head (25) is a pickling head and comprises vision means (39) connected to the treatment means (33), these treatment means being connected control means (38) for automatically controlling the movement of the pickling head (25) on the surface of the object (1) to be treated, and said treatment means being programmed to detect the limit of an area ( la) previously stripped on the surface of the object to be treated, and to move the working head (25) without exceeding said limit during the operation of the working head, thus avoiding additional stripping of the area (la) previously pickled.  14. Device according to any one of the preceding claims, in which the processing means (34) are programmed to calculate a positioning of the object (1) to be treated relative to the ground, as a function of an inclination of this object. relative to a normal position, this inclination being previously raised by an operator and transmitted to the processing means via an interface (36).