FR3079767A1 - DEVICE AND METHOD FOR PRETENSION OF FLEXIBLE ELASTOMERIC BLOCK - Google Patents

Abstract

Device (10) for gripping a flexible elastomeric block (11) comprising a gripper (14) and an automated manipulator (13), the gripper (14) comprising, a bit (25) extending along an axis (26) longitudinal, and a motor (24) connected to the wick (25). According to the invention, the gripping device (10) is characterized in that the gripper (14) comprises a bearing surface (23; 30) comprising an axis of rotation around which the gripper (14) is able to pivot and at least one lever (31; 32), the bit (25), the bearing surface (23) and the lever (31; 32) cooperating in such a way that when said bit is screwed into the block (11) and when said bearing surface bears on said block, the gripper (14) is pivoted about the axis of rotation by actuating said lever by means of the manipulator (13).

Description

- 1 Device and method for gripping a flexible elastomeric block The present invention relates to an automated gripping device for handling a flexible elastomeric block, and to a method for gripping said block using such a device.

The displacement of an elastomeric block is carried out manually in a wide variety of industrial applications for which it is necessary to grasp the block on a first station and to move it to a second station, according to a manufacturing process . The blocks are often heavy, making it difficult for the operator to handle them.

It is thus possible, as described in the application JP2005297091, to stack blocks of raw rubber gum of several tens of kilograms and of parallelepiped shape on a pallet, by means of an automated transfer gantry. The gantry moves and orientates in the horizontal plane a gripper comprising two screws which are screwed into or unscrewed from the upper face of a block depending on whether one wishes to grasp or release the block.

However, the transfer gantry being located in a safety enclosure, an operator who must intervene in the workspace of the gantry must stop and then rearm the transfer gantry, which disrupts the manufacturing process. Such a device is therefore not suitable for an application in which an operator is required to intervene regularly in the workspace of the gantry.

In order to make the work of an operator less painful by the use of a robot while facilitating interactions between the robot and an operator, a collaborative robot is used in a manner known per se, such as a collaborative automated manipulator. . By collaborative, we mean the ability of an industrial robot to be installed in a workspace that is shared with an operator, therefore without an interposed safety enclosure. For example, a collaborative robot replaces or assists an operator in the repetitive handling of tasks or in the performance of tiresome tasks and / or likely to lead to the appearance of musculoskeletal disorders.

A collaborative robot is capable of lifting masses ranging from 10 to 15 kg, the mass of a block and its gripper, thus allowing the robot to move them in

-2 workspace. However, the robot can be subjected to significant resistant forces, in particular during the extraction of a block from its support taking account of the adhesion forces. The robot is then unable to provide the effort necessary to overcome the adhesion forces, as well as the forces necessary to lift the block and the gripper.

An object of the invention is to remedy the drawbacks of the state of the art, and to provide an original solution to allow a collaborative automated manipulator to lift a flexible elastomeric block linked to its support by adhesion.

This objective is achieved by the invention which provides a device for gripping a flexible elastomeric block comprising a gripper, and an automated manipulator capable of moving and orienting the gripper. The manipulator comprises a series of segments mounted sliding or articulated with respect to each other, an end segment of said series comprising a flange. The gripper comprises an upper part fixed to the manipulator flange, a lower part connected to the upper part, a wick extending along a longitudinal axis from a base to a free tip-shaped end, said wick being mounted movable in rotation relative to the lower part around said longitudinal axis, and a motor connected to the wick. The bit is movable in rotation by means of said motor, and capable of being screwed or unscrewed from the block along the longitudinal axis. The gripping device is characterized in that the gripper comprises a support surface comprising an axis of rotation around which the gripper is able to pivot, and at least one lever rigidly connecting the upper part and the lower part. The drill bit, the support surface, the lever and the manipulator cooperate in such a way that, when said drill bit is screwed into the block and when said support surface bears on said block, the gripper is caused to pivot around the axis of rotation by actuation of said lever by means of the manipulator.

The manipulator and the gripper flex the block by "leverage". Thus, the block lifts and takes off from its support. The manipulator is then able to overcome the adhesion forces between the block and its support, and the block can be manipulated in the workspace without having to use a more powerful manipulator.

-3 Preferably, the support surface is rigidly connected to the lower part of the gripper. Thus, the wick is not stressed in bending when the lever is actuated, which reduces the risk of a break in bending of the wick.

Advantageously, the lever has a length ranging from 50 to 500 mm, and preferably from 200 to 350 mm. A lever of significant length allows the manipulator to flex and take off the block more easily by multiplying the force exerted by the manipulator by a greater ratio. Thus, the efforts necessary to bend and take off the block are lower, and the capacities of the collaborative manipulator are not thwarted. In contrast, a short lever allows the gripper to be lighter, which also does not interfere with the capabilities of the manipulator.

Preferably, the bearing surface takes the form of a sole comprising one or more parts, a first part extending transversely to the longitudinal axis. An elastomeric block is easily plastically deformable. A support surface in the form of a sole increases the contact surface between the gripper and the block. Thus, the support surface does not penetrate into the block when the gripper comes to rest on it.

Advantageously, the length of the sole ranges from 50 to 1000 mm, and preferably from 300 to 700 mm. A sole of great length makes it possible to take off a block of length substantially identical to that of the sole. In contrast, a short sole allows the gripper to be lighter.

Preferably, the first part of the sole has a longitudinal section of rounded profile having a center and a radius ranging from 50 to 500 mm, and preferably from 200 to 350 mm, the wick extending from the convex side of the first part. When the wick is screwed into the upper face of the block and when the sole is resting on said block, the manipulator cooperates with the gripper so that the sole rolls on said upper face. Thus, the block peels off and gradually wraps around the sole. In addition, the leverage ratio remains constant which facilitates the handling of the manipulator.

Advantageously, the end segment of the manipulator being mounted movable in rotation relative to the previous segment around an axis orthogonal to the longitudinal axis,

-4 the orthogonal axis crosses the center of the first part of the sole. Thus, the manipulator controls the movement of the segment preceding the extreme segment, in a direction substantially parallel to the upper face of the block, which has the effect of simplifying the control of the manipulator.

Preferably, the wick is of conical shape with symmetry of revolution of longitudinal axis. Thus, the risks of fouling the bottom of the mesh of the wick by elastomeric material are reduced.

Advantageously, the wick has at least two threads to save time when screwing or unscrewing the wick.

Preferably, the gripper comprises a device for retracting the wick. The retraction device allows the manipulator to move and orient the gripper in the absence of a block, without the bit representing a risk of injury in the event of a collision between the gripper and an operator.

Advantageously, the gripper comprises a needle gripping device. The device comprises movable needles sliding with respect to the lower part of the gripper, and at least one actuator linked on the one hand to said needles and on the other hand to the lower part of gripper. The needles slide by means of said cylinder, and are able to penetrate or withdraw from the block. The needle device allows the block to be held at a second attachment point. Thus, when unscrewing the drill bit, the needle gripping device prevents rotation of the block.

The invention also provides a method of gripping a flexible elastomeric block, using a gripping device comprising a gripper and an automated manipulator able to move and orient the gripper. The manipulator comprises a series of segments mounted sliding or articulated with respect to each other, an end segment of said series comprising a flange. The gripper comprises an upper part fixed to the manipulator flange, a lower part connected to the upper part, a wick extending along a longitudinal axis from a base to a free tip-shaped end, said wick being mounted movable in rotation relative to the lower part around said longitudinal axis, and a motor connected to the wick. The bit is movable in rotation by means of said motor, and capable of being screwed or

-5 unscrew from the block along the longitudinal axis. The gripper comprises a support surface comprising an axis of rotation, and at least one lever rigidly connecting the upper part and the lower part. The gripping method is characterized in that it comprises a step of positioning the gripper during which the gripper is moved so that the wick is positioned perpendicular to an upper face of the block and at the level of one end of the block, and so that the bearing surface is positioned above the upper face of the block. The method also comprises a step of screwing the drill bit into the end of the block, a step of pressing the bearing surface of the gripper on the block and, a step of actuating the lever by means of the manipulator so that that the gripper is caused to pivot about the axis of rotation of the bearing surface.

Preferably, the gripper comprises a needle gripping device, said device comprising movable needles sliding with respect to the lower part of the gripper, and at least one jack connected on the one hand to said needles and on the other hand at the bottom of the gripper. The gripping method comprises a step of penetration of the needles into the block by means of the jack.

The invention will be better understood thanks to the following description, which is based on the following figures:

Figure 1 is a perspective view illustrating certain components of a gripping device of a flexible elastomeric block;

Figure 2 is a perspective view illustrating the wick of the gripper of the gripping device of Figure 1;

Figure 3 is a perspective view illustrating certain components of the gripper of the gripping device of Figure 1 in which the wick is retracted;

FIG. 4 is a perspective view of the gripper of the gripping device of FIG. 1.

Figure 5 is a side view illustrating certain components of the gripper of the gripping device of Figure 1 in which the wick is not screwed;

Figure 6 is a side view illustrating certain components of the gripper of the gripping device of Figure 1 in which the wick is screwed in a block;

FIG. 7 is a side view illustrating certain components of the gripper of the gripping device of FIG. 1 in which the wick is screwed in a block;

In the various figures, identical or similar elements have the same reference. Their description is therefore not systematically repeated.

As illustrated in Figure 1, the invention relates to a device 10 for gripping a flexible elastomeric block 11. The gripping device comprises a gripper 14 and a collaborative automated manipulator 13 able to move and orient the gripper 14.

The manipulator is said to be "collaborative" because it is designed to perform tasks in collaboration with an operator. In other words, the manipulator can come to a standstill when it is subjected to an unforeseen force during its movements, for example during a collision with the operator. By way of example, the manipulator at the end of which the gripper is mounted, is capable of handling loads up to 10 kg at speeds up to 1 m. s' ¹ . The collision energies admitted between the manipulator and the operator vary from about 0.2 J to 2.5 J. Collisions are detected by sensors of the manipulator which stops if necessary.

The manipulator 13 is of the anthropomorphic manipulator arm type with six axes, and comprises a series of segments of variable lengths, mounted sliding or articulated with respect to each other. An end segment 20 of the series of segments comprises a flange 21 mounted so as to pivot about an axis 22 of rotation relative to said end segment.

By block is meant a body of generally parallelepiped shape or comprising at least one substantially planar upper face 16, formed in one piece and which extends along a longitudinal dimension 17.

By elastomeric block is meant a block based on raw elastomer. By way of example, block 11 is made up of an agglomerate of scrap elastomeric profiles, said profiles being able to enter into the composition of a tire blank. A plurality of blocks is spaced apart on a non-stick support 18, such as a textile sheet covered with an anti-adhesive treatment. The non-stick support is

-7generally placed between two layers of elastomeric blocks. Thus, the blocks do not clump together.

By flexible block is meant that the block 11 has, along its longitudinal dimension 17, flexibility properties such that an operator is able to flex the block substantially. As an example, a block 20 to 80 cm in length flexes by 5 to 20 cm when it is peeled off by one of its ends 19 from the support 18, by an operator which provides a force of 5 to 10 daN.

The gripper 14 comprises an upper part 28, a lower part 29, a drill bit 25 and a motor 24. The upper part of the gripper is fixed to the flange 21 of the manipulator 13. The lower part of the gripper is connected to the part higher. The wick extends along a longitudinal axis 26 from a base 27 to a free tip-shaped end. The drill bit is rotatably mounted relative to the lower part around the longitudinal axis. The motor 24 is on the one hand fixed on the lower part, and on the other hand connected to the wick. Thus, the wick is movable in rotation by means of said motor.

According to the invention, the gripper 14 comprises a support surface 23 having an axis 33 of rotation (Figures 5 and 6) around which the gripper is able to pivot, and at least one lever 32 rigidly connecting the part 28 upper and lower part 29. The drill bit, the support surface 23 and the lever 32 cooperate in such a way that, when the drill bit is screwed into the block 11 and when the support surface bears on the block, the gripper 14 is caused to pivot around the axis 33 of rotation by the actuation of the lever by means of the manipulator 13.

The support surface 23 of the gripper 14 is able to come into simple unilateral support on the block 11, and preferably on the upper face 16 of the block. The axis 33 of rotation is orthogonal to the longitudinal axis 26 of the drill bit 25. By way of example, part of the external surface of the drill bit 25 forms the bearing surface which includes an axis 33 of rotation orthogonal to the longitudinal axis 26 of the drill bit. Indeed, when the wick is screwed into the block, said part bears on the block and the gripper is able to pivot around the axis 33 of rotation by the actuation of the lever.

- 8 In a preferred embodiment of the invention, the support surface 23 is rigidly connected to the lower part 29 of the gripper 14. For example, the support surface 23 takes the form of '' a cylinder capable of coming to bear by its side wall on the block 11, of a sphere, or of a shape comprising a flat face, said shape being connected with the lower part of the gripper and the flat face being in a plan support on the block.

As illustrated in Figure 2, the wick 25 includes a rod 42 extending along the longitudinal axis 26 from the base 47 in the opposite direction to the free end of the tip of the wick. The free end of the wick is for example made by a threaded rod or a helical twist, made of a metallic material. The drill bit 25 is introduced by rotation into the upper face 16 of the block 11 and, in other words, is capable of being screwed or unscrewed from the block along the longitudinal axis 26.

The wick 25 is of conical shape with symmetry of revolution with a longitudinal axis 26, and comprises at least one thread of triangular section. When the wick is unscrewed from block 11, the wick comes off from the orifice it created in the block by screwing itself without tearing off elastomeric material, as is the case with a cylindrical wick. Thus, the risks of fouling the bottom of the mesh of the wick by elastomeric material are reduced. Preferably, the wick has two threads to save time when screwing or unscrewing the wick.

The manipulator 13 exerts a force on the upper part 28 of the gripper 14 which is transmitted directly to the lever 32. This results in an effort of lifting the block 11 where the wick 25 is screwed. The lifting effort is multiplied by a certain ratio, by "leverage".

This ratio is the ratio between, on the one hand, the distance between the place where the force of the manipulator 13 is exerted and the support surface 23 on the block 11 and, on the other hand, the distance between the bearing surface on the block and the end 19 of the block into which the drill bit is screwed or else, the place where the result of the adhesion forces is applied between the fulcrum of the pivot and the end of the block.

In a preferred embodiment of the invention, the support surface 23 takes the form of a sole 30. By sole means a piece capable of coming to bear

-9on block 11 either in whole or in part. A support surface in the form of a sole increases the contact surface between the gripper and the block.

A sole 30 has one or more parts extending, preferably, continuously. A first part extends transversely to the longitudinal axis 26. The sole 30 has an orifice 38 traversed by the wick 25 which allows the sole 30 to take support in the immediate vicinity of the wick and to limit the requests in rod bending 42 the wick by allowing its base 27 to come to bear on orifice 38.

The first part of the sole 30 can thus have a form of symmetry of revolution with a longitudinal axis 26. The first part of the sole, for example, has a hemisphere, cone or flange shape. In other words, the profile of the longitudinal section of said shape is straight or rounded. By longitudinal section is meant a section with a plane containing the longitudinal axis 26. Said form with symmetry of revolution is capable of coming into contact in whole or in part with the block along said profile. When said profile of the sole is straight, the gripper 14 is made to pivot about an axis 33 of rotation situated at the end of the sole 30.

In a preferred embodiment of the invention, a sole has a strip shape, the profile of which corresponds to the longitudinal section of said shape of revolution, namely a straight or rounded profile.

In a preferred embodiment of the invention, the profile of the sole 30 is rounded. The drill bit 25 extends from the convex side of the rounded profile. The instantaneous center of rotation of the gripper relative to the block 11 moves along the sole. In other words, when the wick 25 is screwed into the upper face 16 of the block 11 and when the sole 30 is in abutment on said block, the manipulator 13 cooperates with the gripper 14 so that the sole 30 rolls on the upper face 16 of the block. Thus, the block peels off and gradually wraps around the sole. In addition, the leverage ratio remains constant which facilitates the handling of the manipulator.

The first part of the rounded profile of the sole 30 has a center 34 and a given radius R (Figure 7).

- 10 Preferably, the gripper 14 comprises two levers 31, 32 of concurrent axes, each connecting the lower part 29 and the upper part 28. Thus, the upper and lower parts of the gripper, the support surface 23 and the levers 31, 32 provide a more rigid closed contour than an assembly comprising a single lever.

For example, the levers 31, 32, the upper 28 and lower 29, and the sole 30 are made of a light and rigid metallic material, such as aluminum, or a composite material. The face of the sole 30 which is able to come into contact with the upper face 16 of the block 11, is covered with a material with low adhesion to an elastomer, such as polyamide.

For example, a lever 31 (or 32) has a length L1 ranging from 50 to 500 mm and, preferably, from 200 to 350 mm. The sole length 30 ranges from 50 to 1000 mm and preferably from 300 to 700 mm. The radius R of the first rounded profile part of the sole ranges from 50 to 500 mm and, preferably, from 200 to 350 mm.

Indeed, the lifting effort must be sufficient to allow to flex the block 11 and to take it off its support 18. The effort that can be provided by the collaborative manipulator 13 being limited, the radius of curvature and length of the sole 30, as well as the length of the levers 31, 32 result from the following compromises.

If a sole 30 has a large radius of curvature, then the force exerted by the manipulator 13 on the gripper 14 to flex the block 11 will be lower than in the case of a sole having a radius low curvature. Since the effort required to flex the block is low, the capabilities of the collaborative manipulator are not thwarted. In addition, the flexibility characteristics of an elastomeric block can vary significantly from one block to another, and the effort required to flex a block which is not very flexible is greater. A large radius of curvature therefore makes it possible to take off blocks having more varied flexibility characteristics.

A sole 30 of significant length allows to gradually take off a block 11 more extended according to its longitudinal dimension 17. A lever 31 (or 32) of considerable length allows the manipulator 13 to flex and take off the block more easily by multiplying the force exerted by the manipulator by a greater ratio. The efforts required to bend and take off the block being weak, the capacities of the manipulator

- 11 collaborative are not upset. Conversely, the shorter the lengths of the sole 30 and the levers 31, 32, the lighter the gripper 14, which also does not interfere with the capabilities of the manipulator.

The extreme segment 21 of the manipulator 13 is mounted so that it can rotate about an axis 37 orthogonal to the longitudinal axis 26 of the drill bit 25, relative to a segment 36 which precedes it in the series of segments. By orthogonal is meant that there is a straight line parallel to the axis 26 and perpendicular to the axis 37.

Preferably, the orthogonal axis 37 passes through the center 34 of the first part of the sole 30. The manipulator 13 then controls the segment 36, the rotation between the segment 36 and the extreme segment 21 being left free. Thus, the trajectory of the segment 36 exerting a force on the gripper 14, in order to gradually take off a block 11, is substantially parallel to the longitudinal dimension 17 of the block. The handling of the manipulator is thereby simplified.

FIG. 3 illustrates more particularly the gripper 14 which comprises a device 35 for retracting the wick 25. The device 35 for retracting comprises a jack 39 of the pneumatic single-acting type, and a spring 40. The body of the jack 39 is fixed to the lever 32. The cylinder rod is in simple support on the end of the rod 42 of the drill bit. The spring 40 is mounted coaxially with the rod 42 of the drill bit, and is compressed between, on the one hand, the end of the rod 42 and, on the other hand, the motor housing 24.

The cylinder 39 and the spring 40 cooperate with the rod 42 so that, when the wick is not retracted, the cylinder 39 is controlled, the rod of the cylinder 39 is extended and the spring 40 is more compressed, and when the wick is retracted, the jack 39 is no longer piloted, the spring is less compressed and the rod of the jack is retracted.

The wick 25 passes through the sole and is retracted above the sole 30, which allows the manipulator 13 to move and orient the gripper 14 in the absence of block 11, without the wick 25 representing risk of injury in the event of a collision between the gripper and an operator.

Figure 4 illustrates the gripper 14 which comprises a device 43 for gripping needles. The device 43 comprises needles 44 movable to slide relative to the lower part 29, and at least one jack 45, of the double pneumatic type

- 12 effect. The device 43 also includes a drawer 46 and a base 47. The drawer 46 is movable to slide relative to the base 47, and supports the needles. The base 47 is fixed to the lower part 29. The rod of the jack 45 is connected on the one hand to the needles 44 by means of the drawer 46 and, on the other hand, to the lower part 29 by means of the base 47.

The needles 44 are movable to slide in a direction 49 which forms an angle between 15 ° and 75 ° with a direction which passes through the center 34 of the first part of rounded profile and the sole 30. The jack 45 cooperates with the needle drawer 46 in such a way that the jack 45 is piloted, the rod of the jack 45 is extended and the needles 44 are deployed or, the jack 45 is piloted, the rod of the jack 45 is retracted and the needles 44 are not deployed. The needles 44 are able to penetrate or withdraw from the block 11.

Preferably, the device 43 for gripping needles comprises two cylinders 45 and two drawers 46 with needles disposed on either side of the sole 30 opposite the wick 25, so that the directions of sliding of the two drawers and needles 44 intersect. Such an arrangement improves the grip of the block 11.

The device 43 with needles 44 keeps the block 11 at a second attachment point. As an example, one could also have used a drill bit or pliers. The masses of the block 11 and of the gripper 14 are thus substantially balanced on either side of the axis 22 of rotation of the flange 21 which avoids the problems of cantilevering when handling the block. In addition, when the wick 25 is unscrewed, the needle gripping device 43 prevents the block 11 from rotating.

Finally, a function of the needle device is the gripping of the non-stick support 18 alone. To this end, the sole 30 of the gripper bears on the support 18 at the height of the needle device 43, then the needles 44 are deployed so that the support is crossed by the needles and can be moved in the space of job.

For example, the base 47 and the drawer 46 are made of a rigid and light metallic material, such as aluminum, or of a composite material. The needles 44 are made of a metallic material such as steel.

- 13 The gripping device 10 comprises a control device (not shown) of the manipulator. The control device comprises a camera oriented towards the elastomeric block or blocks 11 and their support 18, and a controller of the microprocessor type. The camera communicates images to the controller. The controller is running pattern recognition software. From the images and the software, the controller produces a three-dimensional modeling of the blocks 11 and selects a block on the support. The controller then determines the coordinates of an end 19 of the block in which the wick 25 will be screwed, a direction perpendicular to the upper face 16 of the block and crossing the end 19 of the block according to which the wick will be screwed in said upper face , and the longitudinal dimension 17 of the block along which the sole 30 will come to bear.

Operation of the gripping device 10 [0063] Figures 5 and 6 illustrate the gripper 14 during different stages of its operation. The piloting device controls the manipulator 13 so that the gripper is moved and oriented in the workspace of the manipulator in an operating mode called "position". The manipulator is also capable of exerting a force 50 (or 51) on the gripper 14 so that the gripper exerts a given force on the block, in an operating mode called "force".

The gripping device 10 is used for handling flexible elastomeric blocks 11. The blocks are previously arranged on a non-stick support 18.

Prior to a positioning step, the controller selects a block 11, determines the coordinates of one end 19 of the block 11, a direction along the longitudinal dimension 17 of the block and a direction perpendicular to the upper face 16 of the block. Said coordinates and directions are communicated to a manipulator 13. The manipulator 13 is then in the "position" operating mode.

During the positioning step, the manipulator 13 positions the gripper 14 so that the wick is screwed into the end 19 of the block, perpendicular to the upper face 16 of the block, and directs the gripper 14 of so that the sole

- 14 30 is positioned above the upper face 16 of the block and, preferably, aligned with the longitudinal dimension 17.

During a screwing step, the wick 25 is rotated by means of the motor 24, and screwed into the block in the direction of the longitudinal axis 26 of the wick 25.

The manipulator switches to the "force" operating mode.

During a support step, the support surface 23 is supported on the end of the block 11 by the manipulator 13 (Figure 5). Thus, the manipulator exerts a first force 50 on the gripper 14 perpendicular to the upper face 16 of the block. The gripping force of the gripper on the block is approximately 100 N.

During a step of actuating the lever 32 (or 31), a second force 51 is applied by the manipulator 13 to the gripper 14 so that the gripper is caused to pivot about the axis 33 of rotation of the bearing surface. The force 51 is applied in a direction orthogonal to the axis of 33 of rotation. Thus, the sole 30 rolls on the upper face 16 of the block 11. The block flexes and its end 19 is raised at the place where the wick is screwed (Figure 6). The second force 51 is substantially parallel to the longitudinal direction 17 of the block.

The block 11 is gradually peeled off from the support 18 and is wound around the sole 30 until the block comes to bear at the height of the device 43 with needles. The needles are deployed and penetrate the block.

The manipulator 13 returns to "position" operating mode, and the manipulator 13 positions the gripper 14 so that the axis 22 of rotation of the end segment 20 is vertical.

The block 11 is manipulated by the gripping device 10 in the workspace until reaching a station on which one wishes to deposit the block. The wick 25 is unscrewed from the block then the needles 44 are withdrawn from the block.

Other variants and embodiments of the invention can be envisaged without departing from the scope of these claims.

Claims (13)

1. Device (10) for gripping a flexible elastomeric block (11) comprising: - a gripper (14), and an automated manipulator (13) able to move and orient the gripper (14), said manipulator comprising a series of segments mounted sliding or articulated with respect to each other, an extreme segment (20) of said series comprising a flange (21), the gripper (14) comprising: - an upper part (28) fixed to the flange (21) of the manipulator (13), - a lower part (29) connected to the upper part, - a wick (25) extending along a longitudinal axis (26) from a base (27) to a free tip-shaped end, said wick being mounted movable in rotation relative to the part (29 ) lower around said longitudinal axis, and - A motor (24) connected to the wick (25), the wick (25) being movable in rotation by means of said motor (24), and capable of being screwed into or unscrewing from the block (11) along the axis (26) longitudinal, the gripping device (10) being characterized in that the gripper (14) comprises: - a support surface (23) comprising an axis (33) of rotation about which the gripper (14) is able to pivot and at least one lever (31; 32) rigidly connecting the upper part (28) and the part ( 29) lower, the wick (25), the support surface (23) and the lever (31; 32) cooperating in such a way that, when said wick is screwed into the block (11) and when said support surface is supported on said block, the gripper (14) is made to pivot about the axis (33) of rotation by the actuation of said lever by means of the manipulator (13). 2. Device according to claim 1 wherein the support surface (23) is rigidly connected to the lower part (29) of the gripper (14). 3. Device according to one of claims 1 or 2 wherein the lever (31; 32) has a length ranging from 50 to 500 mm, and preferably from 200 to 350 mm. 4. Device according to one of claims 1 to 3 wherein the support surface (23) takes the form of a sole (30) comprising one or more parts, a first part extending transversely to the axis ( 26) longitudinal. 5. Device according to claim 4 wherein the length of the sole (30) ranges from 50 to 1000 mm, and preferably from 300 to 700 mm. 6. Device according to one of claims 4 or 5 in which the first part of the sole (30) has a longitudinal section of rounded shape comprising a center (34) and a radius (R) ranging from 50 to 500 mm, and preferably from 200 to 350 mm, the drill bit (25) extending from the convex side of the first part. 7. Device according to claim 6 wherein, the end segment (20) of the manipulator (14) being mounted movable in rotation relative to the preceding segment (36) about an axis (37) orthogonal to the axis (26) longitudinal, the orthogonal axis (37) crosses the center (34) of the first part of the sole. 8. Device according to one of claims 1 to 7 wherein the wick (25) is conical in symmetry of revolution of axis (26) longitudinal. 9. Device according to one of claims 1 to 8 wherein the wick (25) comprises at least two threads. 10. Device according to one of claims 1 to 9 wherein the gripper comprises a device (35) for retracting the wick (25). 11. Device according to one of claims 1 to 9 in which the gripper (14) comprises a device (43) for gripping needles, said device comprising: needles (44) movable to slide relative to the lower part (29) of the gripper, and at least one actuator (45) linked on the one hand to said needles and on the other hand to the lower part (29) of gripper, the needles (44) sliding by means of the jack (45), and being able to penetrate or withdraw from the block (11). 12. Method for gripping a flexible elastomeric block (11), using a gripping device (10) according to claims 1 to 11 comprising: - a gripper (14), - an automated manipulator (13) able to move and orient the gripper (14), - 17 said manipulator comprising a series of segments mounted sliding or articulated with respect to each other, an end segment (20) of said series comprising a flange (21), the gripper (14) comprising: - an upper part (28) fixed to the flange (21) of the manipulator (13), - a lower part (29) connected to the upper part, - a wick (25) extending along a longitudinal axis (26) from a base (27) to a free tip-shaped end, said wick being mounted movable in rotation relative to the part (29 ) lower around said longitudinal axis, and - a motor (24) connected to the wick (25), - a support surface (23) comprising an axis (33) of rotation around which the gripper is able to pivot, and at least one lever (31; 32) rigidly connecting the upper part (28) and the part (29) lower, the gripping process being characterized in that it comprises: - a gripper positioning step (14) during which the gripper is moved and oriented so that the drill bit (25) is positioned perpendicular to an upper face (16) of the block (11) and at the level of one end (19) of the block (11), and so that the bearing surface (23) is positioned above said block, - a step of screwing the drill bit (25) into the end (19) of the block (11), a step of pressing the surface (23) of pressing on the block (11), - A step of actuating the lever (31, 32) by means of the manipulator (13) so that the gripper (14) is caused to pivot around the axis (33) of rotation. 13. The method as claimed in claim 12, in which the gripper (14) comprises a device (43) for gripping needles, said device comprising: needles (44) movable to slide relative to the lower part (29) of the gripper, and at least one actuator (45) linked on the one hand to said needles and on the other hand to the lower part (29) of gripper, - 18 the gripping method comprising a step of penetration of the needles (44) in the block (11) by means of the jack (45).