FR2590560A1 - Device for mechanically controlling, by means of a cable, the spatial displacement of an object - Google Patents

Abstract

This device is of the type comprising : a frame 1; a movable element 3; a second movable element 30; a third movable element 32; a set of movable pulleys; a plurality of cables bearing on the said pulleys fixed to the object to be moved; actuators intended to drive the object via the cables. The device is characterised in that all the cables form a closed loop and have a constant length; there is at most one cable per degree of freedom of displacement; the direction of the cable strands stretched between two pulleys capable of moving with respect to each other is parallel to one of the main directions; the device is provided with a structure 33 which is made to move in a suitable manner, such as a handling arm.

Description

CABLE MECHANICAL CONTROL DEVICE
MOVING AN OBJECT INTO SPACE.

 The invention relates to a device for mechanical control by cable, in particular from a distance and in a controlled atmosphere, of the translation of an object in space, and of the animation of its own movements.

 We know devices such as overhead cranes which allow the movement in space of any object. They have a so-called on-board motorization, that is to say placed within said bridge.

These devices have drawbacks of several kinds, namely
- the actuators must be moved with the bridge, hence an increase in mobile masses, due not only to the mass of the actuators, but also to the structural reinforcements that this design makes necessary; this results in a larger overall dimensioning, hence increased construction costs, as well as an overconsumption of energy, in particular for low loads; moreover the energy supply of these actuators often presents difficulties
- when working in a hostile environment, the actuators must be protected against corrosion and contamination, and their maintenance is subject to constraints
- it is very delicate with such a device to work in a dust-free environment due to the pollution due to the activation device
The invention overcomes these drawbacks. It proposes a device intended for the mechanical control by cable of the translation of an object in space comprising
- A frame having rectilinear guide elements along one of its two main dimensions, thus constituting a first main direction;
a mobile moving in translation along said straight guide elements of the frame in said first main direction and having straight guide elements directed in a direction parallel to the other main dimension of the frame, thus constituting a second main direction, guidance on which the object moves;
- A set of movable pulleys having a support movable relative to the chassis and fixed on the mobile;
- a second set of pulleys with fixed support relative to the chassis;
- a plurality of cables resting on. the said pulleys. mobiles and pulleys with fixed support and whose ends are fixed on the object to be moved;
- actuators intended to drive the object via cables.

The invention is characterized:
- in that all the cables form a closed loop and have a constant length,
- there is at most one cable per degree of freedom of movement;
- The direction of the strands of cable stretched between two pulleys capable of moving relative to each other is parallel to one of the main directions.

In other series, the invention proposes a cable control adapted to the translation of all loads and this, in any environment and allowing the simultaneous assistance of all the cables, by the set of pulleys with the desired movement.
Another object of the invention consists in having a mechanical control by cable of the translation of an object in three-dimensional space. Such a device comprises
- a second mobile moving relative to the first mobile on said guide elements of the first mobile, in the second main direction
- a third mobile moving relative to the second mobile in a third main direction independent of the first two
Advantageously, in practice
the mechanical control device comprises three cables, each of constant length, the route for each of the cabins being similar, namely that starting from one of the ends of one of the cables fixed to the object, the said cable follows a direction parallel to the third main direction up to a movable pulley; linked to the second movable, then it follows a direction parallel to the second main direction and rests on a second movable pulley, linked to said first movable, then it follows a direction parallel to the first main direction, and is based on a first pulley with a fixed support relative to the chassis, finally it is joined by one or more pulleys whose supports are fixed relative to the chassis a last pulley with fixed support with respect to the chassis, the relative positions of the two said first and last pulleys with fixed support with respect to the chassis being linked to the desired clearance in the first two directions pri ncipales, the return to the object of the said cable in order to produce a loop operated by a similar pulley system, the other end of the cable being fixed according to the desired travel, in the third main direction
- The mechanical control device comprises two free pulleys in rotation, fixed on the third mobile, on which two references from each of the cables come to rest, these pulleys being placed in such a way that their respective position defines the desired travel according to the third. main direction ;;
the mechanical control device only comprises a single cable forming two, respectively three loops depending on whether one considers a translation along two or three degrees of freedom, one end of said cable being fixed to the object, pressing on a deflection pulley linked to the object, thus constituting the starting point of a second loop, and then ends with a point fixed on the object in the case of a displacement according to two degrees of freedom, but leaning on another return pulley, linked to the object, in the case of a displacement according to three degrees of freedom, said pulley constituting the starting point of the third loop finally ending with a fixing point on the object, thus materializing the second end of the single cable, producing by itself all of the three control loops.

the mechanical control device comprises a kinematic equivalent of the fixed points of the cables on the object to be moved, consisting of a rack actuated by a toothed wheel, itself secured to pulleys actuated by the three cables responsible for the translation of the object. -
Another object of the invention consists in providing the preceding device with a structure driven by its own movements, such as a manipulator arm.

Advantageously, in practice, this mechanical control device is characterized
- in that one or more drive shafts are coupled to one or more of the actuators
- in that we connect the two inputs of a differential respectively to one of these transmission shafts and to an auxiliary actuator
- in that a cable controlled by the output of said differential, follows a route parallel to the cable corresponding to the actuator, to which the transmission shaft is coupled
- in that the cable is connected to the object, either directly, or via a receiving member such as a pulley or a connecting rod, the said object being capable of moving according to a degree of freedom independent of two or three degrees of freedom corresponding to the three main directions
Advantageously, in practice:
the mechanical control device has as many differentials as there are degrees of freedom independent of the three degrees of freedom corresponding to the three main directions, one of the inputs of the differential being connected to one of the drive shafts and the other input being connected to as many auxiliary actuators as there are differentials
- the actuators are of the linear or rotary type
- cables can be replaced by ribbons, chains and belts.

 The manner in which the invention can be implemented and the advantages which result therefrom will emerge more clearly from the example of embodiment which follows, given by way of indication and without limitation in support of the appended figures.

 Figure 1 is a schematic representation of the device with two degrees of freedom according to the invention.

 Figure 2 is another embodiment of the invention described - in Figure 1, in which there remains only one cable.

 FIG. 3 is a perspective view of an embodiment of the invention according to three degrees of freedom, to which a manipulator arm has been added.

 Figure 4 is a partial schematic representation of one of the embodiments according to the invention.

 FIG. 5 is a partial schematic representation of the embodiment described in FIG. 4, in which the total path of a single loop of cable has been diagrammed.

Figure 6 is a schematic representation illustrating the mathematical demonstration aimed at establishing the relationship between the movement of the cables and the movement of the object
Figure 7 is a partial schematic representation of another embodiment of the invention.

 Figure 8 is a partial schematic representation of another embodiment of the invention.

 Figure 9 is a schematic representation of the operation of the device according to the invention, provided with a structure driven by its own movements in which the differentials have been shown.

FIG. 10 is a partial schematic representation of the preceding device, in which the route of a cable controlling the translation of the object is shown and the similar route of a cable controlling a movement specific to the object
Referring to Figure 1, there is a fixed frame (1) represented by a flat plate receiving a rectilinear guide element (2) according to the main dimension of the frame (1), this guide element (2) allowing the rectilinear translation of a first mobile (3) (we will call it beam), translation which takes place in a plane parallel to the chassis (1). The beam (3) itself receives a guide element (4 ) rectilinear parallel to the second main dimension of the chassis thus constituting the second main direction, this rectilinear guide element (4) allowing the rectilinear movement of the object (5) in this said second main direction. The movements of the beam (3) and the object (5) are controlled by a set of pulleys and cables arranged as follows.

 The chassis (1) receives two drive pulleys (6) and (7) and two fixed axes (8) and (9) each carrying two freely rotating pulleys (10) and (11) respectively. On the one hand and (12 ) and (13) on the other hand. The pulleys (6) and (7) and the axes (8) and (9) are arranged at the top of a parallelogram of directions parallel to said main directions. The beam (3) receives four pulleys (14,15,16 and 17), free in rotation and arranged so that the cables which pass over these pulleys have straight paths parallel to one or the other of the two translations .

 A first cable (18) starts from a fastener (19) on the object (5), then passes successively over the pulleys (14,10,12,7 and 16) and ends with a fastener (20) on the said object (5). This entire route takes place in a plane parallel to the chassis (1). A second cable (21) contained in a plane parallel to the plane of the cable (18), starts from a fastener (22), then passes successively over the pulleys (17,13,11,6 and 15), and ends. by a fastener (23) on said object (5).

 When the two drive pulleys (6j and (7), assumed to be of the same diameter, rotate in the same direction and at the same speed, the beam (3) moves on its guide (2), but the object (5) remains stationary relative to its guide element (4), the resulting trajectory for the object is therefore a straight line parallel to the guide element (2).

 When the pulleys (6) and (7) rotate at an opposite speed, the beam (3) remains stationary and the object (5) moves on its guide element (4). The resulting movement for the Object is therefore parallel to the guide (4), that is to say to the second main direction.

 When one or the other of the driving pulleys rotates alone, the two mobiles move on their respective guides and the result is for the object a displacement parallel to one or the other of the bisectors of the main directions.

 I1 thus appears that each of the drive pulleys acts independently of each other on the respective coordinates of a reference frame, the said reference frame having pivoted by a certain angle relative to the main directions. It is therefore thus possible to have the object describe any trajectory, this trajectory constituting the result of a combination of rectilinear translations.

 It is also evident that the drive pulleys could also be receiving and therefore behave as position sensors of the object (5).

 In another embodiment shown in Figure 2, we replaced the two fixed points (19) and (22) (for example), by a return of the cable on a pulley (24), free to rotate. There is then only one cable left to control the two movements. The operation remains the same. Only the hyperstatic behavior of the system is modified. Indeed, for different reasons related to. the quality of the guide elements (2) and (4) as well as the relative value of the actual forces applied (load, inertia and friction, etc.), it may be advantageous to use such a system.

 I1 it should be noted that one could easily incorporate a differential in the circuitry of the cables, so as to provide the device with a third dimension, independent of the first two. We would obtain what is commonly known in humans of art, a two-dimensional system plus one.

 In FIG. 3, an embodiment can be observed, in which the object can move according to three degrees of freedom. The device consists of a rectangular frame (1), comprising rectilinear guide elements (2), parallel to the main dimension of the chassis, which support a first mobile (3), (which will be called the beam), capable of moving along these so-called guide elements. This beam (3) also include elements of guide (4), perpendicular to the previous ones, and supporting a second mobile (30), (which will be called a carriage), capable of moving along the second main dimension of the chassis (l). A sheath (31), integral with the carriage (30), allows translations of the object (5) in a third direction, perpendicular to the plane defined by the first two, the object (5) then consisting of a column (32) which can slide in the sheath (31). A manipulator arm (33) is fixed to the column (32) by any suitable means, and is actuated by a device, which will be described in more detail later.

 Figure 4 represents the partial path of the three cables, allowing the displacement in the space of the object (5). This displacement is obtained by the conjugation of three elementary rectilinear translations. The point (35) corresponds to the point of competition of three axes (36), (37) and (38), parallel to the three elementary directions of translation, and defining a reference point. A first cable (39), starting from a point (40) located on the axis (36) , parallel to the axis (37), rests successively on the pulleys (41) and (42) parallel to the axes (36) then (38), and ends with a fastener (43) on the object (5 Similarly, a second cable (44) starting from a point (45) located on the axis (37), parallel to this axis, rests successively on the pulleys (46) and (47), parallel axes (36) and (38) and ends with a fastener (48) on the object (5) .A last cable (49), starting from a point (50), located on the axis (38) , parallel to the axis (37), rests on the pulleys (51) and (52), parallel ment to axes (36) and (38), and ends with a fastener (53) on the object (5). In this diagram, the pulleys (41), (46) and (51), of axes - parallel to the axis (38), are linked to the beam (3), and the pulleys (42), (47) and (52), with axes parallel to the axis (37), are linked to the mobile (30).

 Taking into account the fact that a cable can only work in traction, it is necessary to provide a strand of antagonistic cable for each of the cables (39), (44) and (49). Figure 5 represents the disposition of the cable (39) on its full path. It is clear that the points (40) (45) and (50) are virtual points, constituting artifices of understanding, intended to simplify the explanatory diagram t and that in fact, the cables correspondents are continued by the opposing strands of said cables. The cable (39) starts from a fastener (55) linked to the object (5), parallel to the axis (38), then successively on the pulleys (56 ), (57) and (58) with paths parallel to the axes (36) and (37) .The pulley (57) like the pulley (41) is linked to the beam (3) .The pulley (58) is a fixed support pulley from which the cable returns to the virtual point (40), based on other fixed support pulleys such as pulleys (59) and (60). It should be noted that the position da the pulley (59) in the space is absolutely arbitrary. The only constraint lies in the fact that between the pulleys (60) and (41), and between the pulleys (57) and (58.), the cable must be parallel to the axis (37 The configuration of the other counter cables is similar.

FIG. 6 makes it possible to explain the properties of this device, by showing that each of the three cables of the preceding figure acts, and this independently on the coordinates of the object (5), defined in a new reference, with respect to to that defined by the three axes (36), (37) and (38). We recognize in this figure, the path of the cable (39). Let us designate by x, y and z, the coordinates of the point (43), by relation to the axes (36), (37) and (38). The calculation of the length L1 of the cable (39) between the virtual point (40) and the point (43) is as follows L1 = Ax-r1 -r2 + y-r1 + z-r2 + a1 + a2
L1 A + au + a2 - 2 (rl + r2) - x + Y + z L1 = K-x + y + z with
A: distance separating points (35) and (40) al and a2 constant arcs wound on the pulleys (41) and (42) rl and r2: radii of the pulleys (41) and (42)
K s al + a2 - 2 (r + e), arallelism + r2) aux
1 2
If the length L1 and the parallelism of the strands to the three axes are preserved, the point (43) is subject to displacement in the plane of equation:
-x + y + z = L1 - K
If the length L1 varies, this plane remains parallel to itself: it admits as directing vector, the vector of coordinates (-1, 1, 1).

The same reasoning applies to the other two cables (44) and (49); two respective directing vector planes are obtained (1, -1, 1) and (1, 1, -1). The position in space of the object (5) in translation is therefore totally defined by the three lengths L1 , L2 and L3.

If a single length is varied, the object (5) will move in the direction of the intersection of the two fixed planes defined by the two constant lengths. The directing vector of the direction of this movement is obtained by carrying out the product vector of the direct vectors of the fixed planes. We thus observe that if the length of a single cable varies, the object (5) will move in the direction of the bisector of the two axes carrying the virtual fixed points of the two fixed length cables, i.e.
- if L1 varies alone, displacement according to the bisector
axes (37) and (38);
- if L2 varies alone, displacement according to the bisector
axes (36) and (38);
- if L3 varies alone, displacement according to the bisector
axes (36) and (37).

To obtain a displacement along one of the reference axes (36), (37) or (38), it is necessary and sufficient that the length of the cable element having its virtual fixed point on this axis varies by certain quantity and that, simultaneously, the lengths of the two other cable elements vary by the same quantity
One can observe within FIG. 7 another embodiment of the invention, in which, in addition to the device described in the preceding figures, two pulleys (61) and (62) are fixed on the third mobile of so as to ensure better stability in the movement of the object (5). These two pulleys are positioned so as to define the desired travel in the third main direction.

In another embodiment shown in Figure 8, we replaced the fixed points of the three cables (39), (44) and (49) by a kinematic equivalent, consisting of a rack (75) fixed on the object (5) .0 shows the partial path of the cable (39). This, after passing over the pulley (4l), rests on a pulley (76), parallel to the axis (36), integral with '' a toothed wheel (77) capable of cooperating with the rack (75). Then it rests on a pulley (78), coplanar with the pulley (76), the mooring distance separating the pulleys (76) and (78) being all the more important as one wishes to increase the motricity of the assembly. Then the cable (39) joined after passing over a new pulley (79), the path similar to that shown in FIGS. 1 to 7
We can observe in Figure 9, an explanatory diagram of the animation of the manipulator arm according to a number of degrees of freedom independent of the degrees of freedom defined by the three directions of elementary translations The actuating device comprises a kinematic chain (70 ) comprising a series of differentials (71) driven on the one hand by specific actuators (72), (73), (74) and (85.) of the auxiliary movements considered, and on the other hand an actuator (86) d '' one of the cables (39), (44), or (49) via a transmission axis integral with this actuator (86). The cable (87) from the differential (71) follows a path similar to cable corresponding to the actuator (86), in this case, it is the cable (39). If the specific actuator (72) is not activated, there will be no auxiliary movements. against, if this specific actuator is set in motion, an auxiliary movement, independent of the translational movements of the object (5), will be observed.

 Within FIG. 10, we can observe the device for animating an auxiliary movement, specific to the column (32), and independent of the three degrees of freedom defined by the three directions of elementary translation. This movement is controlled by via a cable (80), which follows a movement practically analogous to the cable (39), and which is actuated by a differential (not shown). This differential is itself activated by actuation of the cable (39), via a transmission shaft (not shown) and a specific actuator (also not shown). This cable (80) animates via a pulley (81), any auxiliary movement, clean in column (32).

A number of advantages emerge from the present invention, namely
- It facilitates work in a controlled atmosphere because the actuators are not on board.

Conversely, the object no longer finds itself in contact with pollution due to the motors. We therefore obtain reciprocal confinement
- The realization of any elementary translations supposes the use of the three actuators, from where a gain of power and a significant reduction of inertia;
- the actuators can be identical, while the use of an actuator for vertical translations supposes an additional power supply
- The device can advantageously be used as a tracking system, or indexing, by reversing the roles of each of the elements; ;
- the device is easily adaptable to current structures
- the tensile forces are fully carried on the object, they have no components on the rectilinear guide elements
- the device provides conditions of use with remarkable stability and balance in the transfer.

 In addition to the conventional applications of a transfer device, this invention is particularly suitable for work in a hostile environment, such as in a nuclear environment, or work in a dust-free atmosphere. In addition, due to the possibility of auxiliary movements of great precision, it lends itself to many other applications.

Claims (10)

 1 / Mechanical control device by cables, for the translation of an object in space according to at least two degrees of freedom, of the type comprising:  - a frame (1) having rectilinear guide elements (2) along one of its two main dimensions, thus constituting a first main direction;  - a mobile (3) moving along said straight guide elements (2) of the frame (l), in said first main direction and having straight guide elements (4) directed in a direction parallel to the another main dimension of the chassis (1) thus constituting a second main direction, guide on which the object (5) moves;  - a set of movable pulleys (14,15,16 and 17), having a movable support relative to the chassis (1) and fixed on the movable (3> ;;  - a second set of pulleys (6,7,10,11,12 and 13) with fixed support relative to the chassis (1);  - A plurality of cables (18,21) resting on said mobile pulleys (14,15,16, and 17) and pulleys with fixed support (6,7,10,11 and 12) and whose ends (19 , 20,22,23) are fixed on the object (5) to be moved;  - actuators intended to drive the object (5) via the cables (18,21), characterized:  - in that all cables (18,21) form a closed loop and have a constant languor  - there is at most one cable per degree of freedom of movement;  - the direction of the strands of cable stretched between two pulleys capable of moving relative to each other, is parallel to one of the main directions,  2 / Mechanical control device according to claim 1, characterized in that  - It includes a second mobile (30) moving relative to the first mobile (3) "on said guide elements (4) of the first mobile (3), in the second main direction  - It includes a third mobile (32), moving relative to the second mobile (30) in a third main direction independent of the first two  3 / A mechanical control device according to claim 2 characterized in that it comprises three cables (39,44,49), each of constant length, and that the path for each of these cables is similar, namely, that leaving d 'one end (43) of one of the cables (39), fixed on the object (5), the said cable follows a direction parallel to the third main direction to a movable pulley (42), linked to the second mobile (30), then it follows a direction parallel to the second main direction and rests on a second mobile pulley (41), linked to said first mobile (3), then it follows a direction parallel to the first main direction and rests on a first pulley (60) with a fixed support relative to the chassis (1), then it joins via one or more pulleys (59), the supports of which are fixed with respect to to the chassis (1), a last pulley (58) with a fixed support relative to the chassis (l), the relative positions of these two said first and last 1st pulleys (59,58) with fixed support relative to the chassis (1) being linked to the desired travel in the first two main directions, the return to the object (5) of said cable (39), in order to make a loop , operated by a similar pulley system, the other end (55) of the cable (39) being fixed as a function of the desired travel in the third main direction  4 / Mechanical control device according to claim 3 characterized in that two references from each of the cables (39,44,49) come to rest on two free rotating pulleys (61,62), fixed on the third mobile ( 32) so that their respective position defines the desired travel in the third main direction  5 / mechanical control device according to one of claims 1, 2 and 4, characterized in that it comprises only one cable (18) forming two, respectively three loops depending on whether one considers a displacement along two or three degrees of freedom, one of the ends (20) of said cable (18) being fixed to the object (5), resting on a return pulley (24) linked to the object (5), thus constituting the starting point of a second loop, ending then with a fixed point (23) on the object in the case of a displacement according to two degrees of freedom, but continuing on another pulley of return, linked to the object, in the case of a displacement according to three degrees of freedom, the said pulley constituting the. starting point of the third loop, finally ending with a point of attachment to the object, thus materializing the second end of the single cable, producing on its own all of the three control loops  6 / control device according to one of claims 3 to 5, characterized in that one replaces the fixed points (43,48,53,55) by a slow kinematic equiva comprising a rack (75) fixed on the object (5), and capable of cooperating with a toothed wheel (77), integral with pulleys (76) driven by the cables (39,44,49), belonging to the device for translating the object (5)  7 / .Mechanical control device according to one of claims 1 to 6, characterized  - in that one or more transmission shafts (70) are coupled to any one of the actuators (86)  - in that the two inputs of a differential (71) are connected to one of these transmission shafts and to an auxiliary actuator '(72,73,74,85),  - in that a cable (87) controlled by the output of said differential (71) follows a route parallel to the cable (39) corresponding to the actuator to which the transmission shaft is coupled  - in that this cable (87) cooperates with a receiving member (81) linked to a movable element (33) of the object (5), the said object being capable of moving according to a degree of freedom independent of the three degrees of freedom corresponding to the three main directions  8 / Mechanical control device according to claim 7, characterized in that there is as much differential (71) as independent degrees of freedom from the three degrees of freedom corresponding to the three main directions, one of the inputs of the differentials (71) being connected to the transmission axis (70), and the other input being connected to as many auxiliary actuators (72,73,74,85) as there are differentials (71).  9 / Mechanical control device according to one of claims 1 to 8, characterized in that the actuators (72,73,74,85,86) are of the linear type or of the rotary type  10 / Mechanical control device according to one of claims 1 to 9, characterized in that the cables (18,21,39,44,49,87) can be replaced by ribbons, chains, belts