FR3020000A1 - FLOATING CONNECTION FOR TOOL - Google Patents

Abstract

The present invention relates to a floating connection for a tool comprising: - an axial structure whose first end (2a) provides a connection interface (3a) with a torque interface part (4), characterized in that the connection interface (3a) with the torque interface piece (4) is made by a male structure intended to cooperate with a female structure of the torque interface piece (4), the section of the female structure being wider than the section of the male structure so as to allow a displacement of the axial structure in at least two different directions, and in that the floating connection also comprises: a cutting support interface (3b) for carrying a structure cutter mounted at a second end (2b) of the axial structure.

Description

The present invention relates to the field of tool connections and more particularly to the field of floating connections for tools. During a boring operation by a cutting tool, it is common to mount it in the form of a cutting head at the end of an axis to facilitate the boring operation. it happens that the axis which carries the cutting head is itself mounted on a floating tool holder. On a machine comprising a motor in rotation, such a floating tool holder allows a displacement of the axial structure that it carries in directions perpendicular to the axis which carries the cutting head. During a boring, it is common that a pre-hole is already done. The cutting head of the boring tool is then aligned to be disposed vis-à-vis the pre-hole and inserted therein to carry out the boring operation.

However, the alignment of the boring tool with respect to the pre-hole may not be properly performed. The presence of a floating tool holder then makes it possible to correct this positioning defect by allowing an offset between the drive shaft of the rotating motor and the working axis of the cutting head of the boring tool. . The floating tool holder, thanks to the clearance it allows, thus facilitates the boring work by allowing a tolerance of the positioning of the rotating drive shaft. This relative flexibility thus facilitates the alignment in position of the cutting head and avoids the realization of a bore that is offset from the pre-hole or greater than the latter. However, the mechanisms of such floating tool holders are particularly complex to build and to achieve. In addition, such floating tool holders quickly have limitations in their implementations at low profile structure levels. Such a situation is found in particular in the context of use in the field of turning lathes. The object of the present invention is to overcome these drawbacks by proposing a simplified mechanism in its construction and its implementation which can be implemented at the level of smaller space-saving structures than those over which it is possible to intervene floating tool holders. The invention thus relates to a floating connection for a tool comprising: an axial structure whose first end forms a connection interface with a torque interface piece, characterized in that the connection interface with the workpiece torque interface is provided by a male structure intended to cooperate with a female structure of the torque interface piece, the section of the female structure being wider than the section of the male structure so as to allow a displacement of the structure axial in at least two different directions, and in that the floating connection also comprises: a cutting support interface for carrying a cutting structure mounted at a second end of the axial structure. The invention also relates to a boring device comprising a motor means for actuating in rotation, characterized in that it integrates at least one floating connection according to the invention. The invention will be better understood from the following description, which refers to a preferred embodiment, given by way of non-limiting example, and explained with reference to the appended diagrammatic drawings, in which: FIG. 1 is a diagrammatic representation of a first exemplary embodiment of a device according to the invention, FIG. 2 is a schematic representation of a first embodiment of a device according to the invention without a cutting tool, FIG. 3 is a schematic representation of a section of a first exemplary embodiment of a device according to the invention; FIG. 3bis is a schematic representation of a detail of the adjustment element of the device presented; FIG. 4 is a schematic representation of a second exemplary embodiment of a device according to the invention; FIG. 5 is a schematic representation of a second example of realization; According to the invention, without the use of a cutting tool, FIG. 6 is a diagrammatic representation of a section of a second exemplary embodiment of a device according to the invention. FIG. 7a is a schematic representation in transparency of a cardan-type connection of a second exemplary embodiment of a device according to the invention; - FIGS. 7b, 7c and 7d are different schematic representations of sections detailing a cardan-type connection; of a second embodiment of a device according to the invention, - Figure 8 is a schematic representation of a section of a third embodiment of a device according to the invention. The present invention relates to a floating connection 1 for 10 comprising: - an axial structure 2, a first end 2a of which provides a connection interface 3a with a torque interface part 4, characterized in that the connection interface 3a with the torque interface piece 4 is made by a male structure intended to cooperate with a female structure of the torque interface piece 4, the section of the female structure being wider than the section of the male structure of so as to allow a displacement of the axial structure 2 in at least two different directions, and in that the floating connection 1 also comprises: - a cutting support interface 3b for carrying a cutting structure 5 mounted at a second end 2b of the axial structure 2. The realization of such a floating connection 1 thus involves jointly, on the one hand, an association with the coupling interface piece 4 e and, on the other hand, a bearing and a torque transmission to the cutting structure 5 which is mounted on the axial structure 2. Such a construction also makes it possible to retain the deflection properties of the axial structure 2 relative to the torque interface piece 4. Furthermore, the positioning of the floating connection 1 near the cutting structure 5 allows implementation of the floating connection 1 of the invention at the compact structure level. According to a particular embodiment, the floating connection 1 is characterized in that the tool holder also comprises at least one centering element 6 mounted on the periphery of the male structure of the connection interface 3a with a part 4 of torque interface and intended to be in contact with the inner wall of the female structure of the torque interface piece 4. This centering element6, while being in contact with the inner wall of the female structure of the torque interface piece 4, makes it possible, on the one hand, to maintain a spacing between the surface of the male structure and the inner surface. of the female structure and, on the other hand, to ensure a coaxial repositioning of the male structure with the female structure of the part 4. However, the elastic characteristics of this centering element6 allow a displacement of the male structure structure axial 2 of the tool holder 1 in the female structure of the torque interface piece 4 in at least one direction perpendicular to the axis of the axial structure 2. This centering element 6 thus allows a centering of the axial structure 2 on the axis of rotation of the torque interface piece 4 while allowing a displacement of this axial structure 2 relative to the axis of rotation. Moreover, thanks to its elastic properties, this centering element 6 can also act as a damper during the displacement of the male axial structure 2 in the female structure of the part 4. According to a preferred embodiment, this element of centering 6 is made by a resilient ring disposed at the connection interface 3a with a torque interface piece 4. It should be noted that the floating connection 1 of the invention may comprise a plurality of elastic rings positioned juxtaposed on the same portion of the connection interface 3a. According to a specific feature of this particular embodiment, the floating connection 1 is characterized in that at least one centering element 6 is disposed in a groove 7 carried by the periphery of the male structure 2a or the internal face of the female structure 4 of the connection interface 3a with a torque interface piece 4. This groove 7 keeps the centering element 6 in position during repeated movements of the axial structure 2 in the torque interface part 4. This groove 7 can be positioned on the periphery of the male axial structure 2 or alternatively on the internal face of the female structure of the part 4. According to another specificity complementary to this particular embodiment, the floating connection 1 is characterized in that at least one centering element 6 is positioned at the connection interface 3a, close to the opening 4a of the female structure of the torque interface piece 4. This particular arrangement makes it possible to obtain a refocusing, or even a damping, on the part of the male structure whose deflection has the greatest amplitude inside the female structure of the piece. indeed, when the end of the male structure formed by the axial structure 2 is fixed inside the female structure formed by the torque interface piece 4, this zone or this point of attachment makes a fixed point around which A pivotal displacement of the axial structure 2 is effected. According to a particular embodiment of the floating connection 1 of the invention, the latter also comprises at least one adjustment element 8 for the displacement of the axial structure 2. a preferred embodiment of this feature, the adjustment element 8 of the deflection is formed by a rigid annular structure mounted on the axial structure 2 and comprising at least a portion 8a intended to be inserted, at the opening 4a of the female structure 15 of the torque interface piece 4, between the peripheral surface of the axial structure 2 and the internal surface of the female structure of the piece 4 of torque interface. This insertion of a portion 8a of the adjustment element 8 allows a reduction in the displacement amplitude of the axial structure 2 inside the female structure of the torque interface piece 4. The inserted part 8a of the adjusting element 8 being positioned on the peripheral surface of the axial structure 2 makes it possible to reduce the space of displacement between this peripheral surface of the axial structure 2 and the internal face of the female structure of the piece 4 of torque interface.

According to a specific embodiment, the adjusting element 8 comprises a portion 8a intended to be inserted which has a portion 8b of conical or beveled shape to be inserted between the peripheral surface of the axial structure 2 and the internal surface of the structure female of the torque interface piece 4 and limit the deflection of the axial structure 2, the portion 8b of conical or beveled shape being capable of interacting with a flange 4b adapted to the opening 4a of the female structure of the piece 4 of torque interface. This portion 8b of conical or beveled shape is oriented towards the opening of the workpiece 4 to facilitate the insertion of the adjustment element 8. This portion 8b conically shaped or bevel of the workpiece 4 of torque interface preferably comprises a face in contact with the peripheral surface of the axial structure 2 against which the adjusting element 8 - 6 - bears. In a complementary manner, the inner edge of the opening 4a of the torque interface piece 4 has a surface inclined relative to the internal surface of the female structure of the torque interface piece 4. This inclination of the surface is then adapted to present an angle substantially identical to that of the bevel carried by the part intended to be inserted in the adjusting element 8. According to another specificity of complementary embodiment, the adjusting element 8 comprises a annular structure concentrically mounted on a portion of the axial structure 2 and interacting at least 10 in sliding relative to the axial structure 2. According to a first construction feature, the sliding of the adjustment element 8 is operated via a threaded interface 2c with a threaded portion 8c of the annular structure. This interaction of screw-nut type thus allows axial displacement of the adjusting element 8 along the axial structure 2 by a simple pivoting of the adjusting element 8 about the axis of the axial structure 2. sliding of the adjusting element 8 along the axis of the axial structure 2 by means of axial pivoting thus allows controlled displacement of the adjusting element 8 when it is inserted into the interval between the axial structure 2 of the inner surface of the female structure of the torque interface piece 4. According to a feature of alternative construction, the sliding of the adjusting element 8 is operated via a continuous adjustment mechanism or stepwise. This continuous or stepwise adjustment mechanism according to an example of known type may involve a removable part associated with the adjustment element 8 and intended to interact with housings on the surface of the axial structure 2 and respectively arranged at the of incrementation corresponding to the different possible positions of the adjustment element 8.

With regard to the connection of the axial structure 2 with a torque interface part 4, according to a first embodiment, the end of the connection interface of the axial structure 2 with a torque interface part 4 makes intervene a rigid connection (tight). According to a first exemplary embodiment, this rigid (tight) connection 35 may comprise a threaded surface 9a of the axial structure 2 intended to interact with a threaded interface of the female structure of the driving part 4. According to alternative examples of tight connection, the axial structure 2 is mounted by hooping with the torque interface piece 4 or by welding. The connection interface thus preferably interacts the axial structure 2 with a portion of the torque interface piece 4 away from the opening 4a of this part 4. This remote connection interface 4a of the opening allows a fixing which allows a deflection by bending and or pivoting of the axial structure 2 in the opening of the female structure of the drive part 4. In the context of this type of tight fitting, the displacement is then essentially due to the axial flexibility of the axial structure 2. According to a second embodiment of this connection of the axial structure 2 with the torque interface piece 4, the connection involves an elastic intermediate structure 11. This elastic intermediate structure 11 allows attachment which allows a movement by pivoting but also by radial displacement of the axial structure 2 in the opening of the female structure of the drive part 4. Such a displacement is then essentially due to the elastic properties of the intermediate structure 11 which allows its deformation during a displacement of the axial structure 2 relative to the torque interface part 4. According to a non-limiting embodiment, this elastic intermediate structure 11 may be made of elastomer. According to an alternative embodiment, the end of the connection interface with a torque interface part 4 involves a cardan type connection 9b with the female structure of the torque interface part 4. This cardan-type connection 9b allows fixation of the axial structure 2 at a double point of articulation. The deflection of the axial structure 2 is then authorized thanks to this gimbal 9b, a first portion of which forms the body of the axial structure 2 and a second part is mounted fixed in translation and rotation with the torque interface piece 4. According to a further embodiment of the invention, the axial structure 2 comprises a duct 10 adapted for the flow of a fluid through its structure 2 from the connection end 9a, 9b in contact with the torque interface piece 4 towards the end carrying the cutting tool 5. Such a conduit 10 thus ensures a supply of lubricant at the cutting surface, or alternatively a supply of a cooling liquid. According to a non-limiting constructional feature of the invention, when the connection end is of the cardan type 9b, the orifice of the duct 10 near the gimbal 9b is formed by one or more grooves arranged on the side and side. other gimbal 9b and open towards the bottom of the female structure of the torque interface piece 4. The invention also relates to a boring device comprising a motor means for actuating in rotation, characterized in that it integrates at least one floating connection 1 according to the invention. According to a feature of non-limiting construction of the invention, the motor means is associated with the torque interface piece 4. Of course, the invention is not limited to the embodiment described and shown in the accompanying drawings. Modifications are possible, particularly from the point of view of the constitution of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.

Claims (15)

REVENDICATIONS1. Floating connection (1) for a tool comprising: - an axial structure (2) whose first end (2a) provides a connection interface (3a) with a torque interface part (4), characterized in that the interface connection (3a) with the torque interface piece (4) is made by a male structure intended to cooperate with a female structure of the torque interface piece (4), the section of the female structure being wider the section of the male structure so as to allow a displacement of the axial structure (2) in at least two different directions, and in that the floating connection (1) also comprises: - a cutting support interface (3b) for carrying a cutting structure (5) mounted at a second end (2b) of the axial structure (2). 2. floating connection (1) according to claim 1, characterized in that the tool also comprises at least one centering element (6) mounted on the periphery of the male structure of the connection interface (3a) with a piece (4) torque interface and intended to be in contact with the inner wall of the female structure of the torque interface piece (4). 3. Floating connection (1) according to claim 2, characterized in that at least one centering element (6) is disposed in a groove (7) carried by the periphery of the male structure (2a) or the inner face of the female structure (4) of the connection interface (3a) with a torque interface part (4). 4. floating connection (1) according to one of claims 2 or 3, characterized in that at least one centering element (6) is positioned at the connection interface (3a), near the opening (4a). ) of the female structure of the torque interface piece (4). 5. Floating connection (1) according to one of the preceding claims, characterized in that the floating connection (1) also comprises at least one adjusting element (8) of the displacement of the axial structure (2). 6. Floating connection (1) according to claim 5, characterized in that the adjusting element (8) of the displacement is formed by a rigid annular structure mounted on the axial structure (2) and comprising at least a part (8a) to be inserted at the opening (4a) of the female structure of the torque interface piece (4) between the peripheral surface of the axial structure (2) and the inner surface of the female structure of the torque interface piece (4). 7. Floating connection (1) according to claim 6, characterized in that the adjusting element (8) comprises a portion (8a) intended to be inserted which has a portion (8b) conical or beveled to be inserted between the peripheral surface of the axial structure (2) and the internal surface of the female structure of the torque interface piece (4) and limit the deflection of the axial structure (2), the portion (8b) of conical shape or beveled being capable of interacting with a flange (4b) adapted to the opening (4a) of the female structure of the piece (4) of torque interface. 8. floating connection (1) according to one of claims 6 and 7, characterized in that the adjusting element (8) comprises an annular structure mounted concentrically on a portion of the axial structure (2) and interacting at least slidingly by relation to the axial structure (2) 9. Floating connection (1) according to claim 8, characterized in that the adjusting element (8) comprises an annular structure mounted concentrically on a portion of the axial structure (2) and interacting at least slidingly via a threaded interface (2c) with a threaded portion (8c) of the annular structure. 10. Floating connection (1) according to claim 8, characterized in that the adjusting element (8) comprises an annular structure mounted concentrically on a portion of the axial structure (2) and interacting at least slidingly via a continuous or step-by-step adjustment mechanism. 11. floating connection (1) according to one of claims 1 to 10, characterized in that the connection of the end of the connection interface of the axial structure (2) with a piece (4) of torque interface involves a rigid and or tight connection. 12. Floating connection (1) according to one of claims 1 to 10, characterized in that the end of the connection interface with a torque interface piece (4) involves a cardan type connection (9b). with the female structure of the torque interface piece (4). 13. Floating connection (1) according to one of claims 1 to 10, characterized in that the connection of the end of the connection interface of the axial structure (2) with a piece (4) of torque interface makes intervening an elastic intermediate structure (11). Floating connection (1) according to one of the preceding claims, characterized in that the axial structure (2) comprises a duct (10) adapted for the flow of a fluid through its structure (2) from the end connection piece (9a, 9b) in contact with the torque interface piece (4) towards the end carrying the cutting structure (5). 15. Boring device comprising a motor means for actuating in rotation, characterized in that it integrates at least one floating connection (1) according to one of claims 1 to 11.