FR2856320A1 - Transmission drive forging tool for motor vehicle, has punch with base to move movable part of hob against spring, where base has groove with edge in extension of part to form external beveled edge at edging of transmission drive - Google Patents

Abstract

The tool has a punch penetrating in a motor vehicles transmission drive positioned in a hob having fixed and movable parts (10, 11). The part (11) moving with respect to a longitudinal axis (AX) of the drive surrounds the drive. The punch has a base (13) to move the part (11) against a spring (14). The base has a groove with an edge in the extension of the part (11) to form an external beveled edge at edging of the drive.

Description

The subject of the invention is a forging tool

  comprising a matrix and a punch, the punch being intended to penetrate a transmission driver for a motor vehicle by moving along a longitudinal axis of the transmission driver, this transmission driver being positioned in the matrix. The invention applies generally to the shaping by forging of an external chamfer at the edge of a workpiece.

  Such a transmission driver comprises a splined shaft extended by a shoulder intended to receive a ball bearing, this shoulder extending into a hollow part also called bowl, of larger diameter than the shoulder. The shaft, the shoulder and the bowl are coaxial being located along the longitudinal axis.

  The bowl includes a bottom which is extended by a circumferential wall defining three lobes offset by one hundred and twenty degrees around the axis. A complementary part including three rollers at one hundred and twenty degrees 20 is intended to be inserted in this bowl to form with the transmission trainer an articulated transmission joint. The drive train and the additional part are surrounded by a protective bellows made of flexible plastic or rubber. 25 Such a seal is intended to transmit mechanical power from a differential to a front wheel of the vehicle, while allowing free movement of the suspensions and the direction of these wheels.

  The circumferential wall of the bowl ends in an edge which is machined by milling or turning to form a plane surface normal to the longitudinal axis, serving as a reference surface for other machining operations carried out on the transmission driver. The machining of this flat surface generates a burr which protrudes at the inner periphery and at the outer periphery of the edge in the extension of the machined surface. A chamfer from forging is provided at the internal periphery of the edge so that the internal burr is housed in this chamfer. The burr which protrudes at the outer periphery tends to deteriorate the bellows which surrounds the transmission driver, which leads to premature wear and to rapid ruin of the latter. The removal of this burr would require a long operation and significant investment in machine tools or grinding, so that it is not possible.

  One solution is to provide a chamfer at the outer periphery of the edge of the bowl to receive this burr. Tests have shown that the external burr lodges in this chamfer and no longer protrudes from the external surface of the transmission driver, so that it does not damage the bellows which surrounds it. This solution however requires a tool capable of producing a chamfer at the outer periphery of the edge of the bowl. Conventionally, the tool comprises a punch with a base complementary to the upper part of the matrix, this base penetrating into the upper part of the matrix to shape the edge of the bowl. The modification of this base to produce a chamfer at the outer periphery of the edge, would lead to a bevelled shape intended to be inserted between the matrix and the edge to shape the chamfer at the outer periphery. Such a beveled shape of small thickness is however incompatible with the significant forces which are developed during a forging operation, so that it cannot be envisaged.

  The object of the invention is to remedy this drawback by proposing a forging tool capable of producing a chamfer at the outer periphery of the edge of the driver.

  To this end, the subject of the invention is a forging tool 35 comprising a die and a punch, the punch being intended to penetrate a transmission driver for a motor vehicle by moving along an axis, this transmission driver being positioned in the matrix, characterized in that this matrix comprises a part movable along the axis, this movable part surrounding the transmission driver, in that the punch comprises a base coming to bear against the movable part of the matrix to move it against at least one spring, and in that the base comprises at least one groove intended to form an external chamfer on the edge of the transmission driver. The edge of the transmission driver is thus shaped by a groove, which makes it possible to produce an external chamfer without having to resort to an additional forging operation. Several springs regularly spaced around the axis can be mounted between the fixed part and the mobile part of the matrix to ensure a homogeneous distribution of the forces of the base on the mobile part of the matrix.

  Advantageously, each groove has a V-shaped profile in order to produce, in the same pass, an external chamfer and an internal chamfer. The external chamfer not being indispensable at the level of the lobes, the base can include three grooves offset by one hundred and twenty degrees around the axis, each groove being intended to form an external chamfer on an edge portion situated between two lobes.

  In a preferred embodiment, the tool comprises a stripper including, for example, three fingers spaced one hundred and twenty degrees around the axis; each finger comes to bear on a lobe of the border in order to keep the power trainer in support in the die during the withdrawal of the punch.

  The invention will now be described in more detail, and with reference to the accompanying drawings which illustrate an embodiment by way of non-limiting example.

  Figure 1 is a perspective representation of a driver for motor vehicle transmission; Figure 2 is a sectional view of the tool 5 according to the invention when the punch enters the transmission driver; Figure 3 is an enlarged view of a groove of the tool according to the invention; Figure 4 is a sectional view of the tool 10 according to the invention when the punch is supported in the transmission driver.

  Figure 1, a transmission driver 1 for a motor vehicle comprises a shaft 2 extended by a shoulder 3 of larger diameter than the shaft, this shoulder being extended by a hollow part 4 called bowl of larger diameter than the shoulder. The shaft 2, the shoulder 3 and the bowl 4 are coaxial by being located along a longitudinal axis referenced by AX. The bowl 4 comprises a bottom which joins the shoulder 3, and a circumferential wall 20 surrounding the axis AX which extends this bottom. This circumferential wall seen in section in a plane normal to the axis AX defines a closed contour comprising three lobes offset by one hundred and twenty degrees around the axis AX. This closed contour has a general shape 25 which can be inscribed in a triangle, each lobe being an arc of a circle convex relative to the axis AX and having as its center the axis AX, each portion joining two lobes being formed by another arc of a circle substantially concave with respect to the axis AX and having its center outside the contour. The circumferential wall has the general shape of a generator parallel to the axis AX moved along this closed contour with three lobes. Each lobe of the bowl 4 thus defines an internal track extending parallel to the axis AX, intended to receive a roller 35 which can move along this track. The circumferential wall of the bowl 4 ends in an edge 5 which also defines a closed contour with three lobes situated in a plane normal to the axis AX. As can be seen in FIG. 1, a chamfer 7 extends over the entire internal periphery of the border 5, and in a similar manner, another chamfer 8 is produced at the external periphery 5 of the border 5, between each lobe, so as to accommodate a burr, not shown, resulting from the machining of the surface 6.

  The transmission driver 1 is obtained by several successive forging operations, each operation being carried out with a tool typically including a die and a punch. The die is for example mounted on a hydraulic press frame, the punch being moved by a jack of this press.

  FIG. 2 shows the tool carrying out one of the last 15 forging operations, this tool being designed in particular for shaping the chamfers 7 and 8. This tool comprises a matrix in two parts identified by the references 10 and 11, and a punch marked by 12 and 13 capable of sliding along the axis AX. In the figures, the die 10, 11 is at the bottom, and the punch is in the high position, so that it enters the drive train 1 down into the die. The transmission driver 1 is placed in the matrix 10, 11 so as to be held there in position with its entire outer surface in abutment against the inner surface of this matrix.

  The external shape of the punch mainly comprises an end 12 extending along the axis AX and a base 13 forming a flat surface normal to the axis AX. The end 12 has the general shape of a bar, the section of which corresponds to the internal section of the bowl 4, to penetrate this bowl in order to shape it.

  The base 13 is intended for the shaping of the edge 5. This punch consists of a rod 12a surrounded by a machined part 12b which is fixed on a support 12c, this support being moved by the press cylinder .

  According to the invention, the matrix comprises a fixed part 10 which serves as a seat for the transmission driver, and a mobile part 11 which surrounds the circumferential wall of the bowl 4 while being able to slide along the axis AX. The fixed part 10 of the matrix receives mainly the shaft 2 and the shoulder 3 as well as the bottom of the bowl 4. The movable part 11 of the matrix surrounds an upper zone of the fixed part 10 and extends it to surround the circumferential wall of the bowl 4 at 10 having a length greater than this wall along the axis AX. The movable part 11 and the punch 12, 13 are angularly indexed relative to the axis AX. The two parts 10 and 11 of the matrix are mounted in a central bore of a frame 16, the fixed part 10 being located in the lower part of this frame of which it is integral. The mobile part 11 slides in this bore which comprises a groove 16 ′ parallel to the axis AX, a key 17 fixed to the mobile part by two screws 18 slides in this groove to keep this mobile part 20 angularly indexed. The punch is also indexed around the axis AX by means not shown.

  The movable part 11 of the matrix is in fact a hollow part having an internal contour corresponding to the contour with three lobes of the coach. The base 13 has a substantially triangular outline, being offset by sixty degrees around the axis AX with respect to the movable part 11. When the punch descends, the flat part of the base 13 thus comes to bear against a flat upper zone of the movable part 11 to make it descend 30, against springs 14 which are mounted between the movable part 11 and the fixed part 10 of the matrix.

  The base 13 of the punch comprises a groove 15 intended for the shaping of the border 5 and more particularly of the external chamfer 8 which is produced in this border. This groove 15 is produced in the flat surface normal to the axis AX of the base 13 so as to receive the edge 5 of the bowl 4 when the punch enters the transmission driver. It is shown in more detail in Figure 3 which is a sectional view along a plane comprising the axis 5 AX. The use of a matrix including a movable part cooperating with the groove 15 makes it possible to produce, in the same pass, the external chamfer 8, but also the interior of the bowl 4 thanks to the end 12 of the punch.

  More particularly, the groove 15 opens onto the flat surface of the base 13, defining an external edge and an internal edge, each of these edges forming a right angle with the flat surface of the base 13. The edge external of the groove 15 is located in the extension of the internal surface of the movable part 11 15 of the matrix. When lowering the punch into the transmission driver, the flat surface of the base 13 located outside the groove 15 comes to bear against a flat upper zone of the movable part 11 of the matrix. The base 13 and the movable part 20 11 are then contiguous, the edge 5 of the driver then penetrates inside the groove 15 for the shaping of the chamfers 7 and 8, which is shown in FIG. 4 The realization of a groove having an edge located in the extension of the movable part of the die ensures that this movable part and the base are contiguous during the descent of the punch, which avoids generating a burr on the surface. external of the coach.

  Advantageously, the bottom of the groove 15 has a profile 30 close to the letter V in order to simultaneously produce the external chamfer 8 and the internal chamfer 7.

  The tool according to the invention is thus adapted to the shaping in the same pass of the external chamfer of the internal chamfer, and of the bottom of the bowl 4.

  As can be seen in FIG. 1, the internal chamfer 7 extends over the entire internal periphery of the edge 5, but the external chamfer 8 is produced only between the lobes. Indeed, the lobes of the transmission trainer have an external contour which is an arc of a circle centered on the axis AX, so that the burr can be removed by turning without any particular difficulty at the level of these lobes. It follows that the base 13 in fact comprises three grooves 15, each groove corresponding to a part of the edge 5 separating two lobes, these three grooves extending around the axis AX. These three grooves are offset by one hundred and twenty degrees with respect to each other around the axis AX, so that only one of them appears in the sectional views of Figures 2 to 4. It is not not provided with a groove in the base 13 for the parts corresponding to the lobes of the border 5, but in these parts, a shoulder is produced at the junction 15 between the end 12 and the base 13 of the punch for shaping of the internal chamfer 7 of the edge 5. Seen along the direction of the axis AX, the base 13 has a substantially triangular outline, offset by sixty degrees around the axis AX with respect to the lobes of the transmission driver 20 1. Each side of this triangular contour is flush along a lobe, and each vertex of this triangular contour corresponds to a zone separating two lobes and protrudes towards the outside of the transmission coach 1. Each groove 15 which corresponds to a zone 25 separating two lobes is produced substantially at mid-height between a vertex of this contour and the side opposite this contour, this groove having a general direction which is substantially parallel to the side opposite this vertex.

  When the punch descends into the transmission driver, the base 13 has its flat surface joined abutting on the movable part 11 in three zones corresponding to the vertices of its triangular contour. Along each side of this triangular contour, there remains a thin gap between the base 35 13 and the movable part 11 of the matrix. Each of these three interstices opens onto a lobe of border 5.

  According to a preferred embodiment of the invention, the tool includes a stripper 20 provided with a finger 22 intended to be inserted in this gap to come to bear on a lobe of the edge 5. This finger 5 holds the driver transmission in position in the die 10, 11, during the withdrawal of the punch. This stripper surrounds the base 13 of the punch along which it slides, and which guides the stripper in its movement. A channel 20 'normal to the axis AX is provided 10 in the stripper 20 for the introduction of lubricant into the contact zone between the base 13 and the stripper. This stripper is moved by a rod 21 sliding in the support of the punch 12c parallel to the axis AX, this rod being immobilized 15 in the stripper 20 by a key 21 '.

  The finger 22 extends parallel to the axis AX, and is arranged opposite a lobe of the edge 5, that is to say between two grooves 15. After lowering the punch 12, the stripper is actuated by the bar for descending, so that the end of the finger 22 bears against a lobe of the edge 5, so as to press the transmission driver 1 against the fixed part 10 of the matrix. The punch can then be ordered to be removed without the risk of the transmission driver coming out of the die with the punch. After removal of the punch, an ejector 23 sliding along the axis AX is provided to extract the transmission driver 1 from the matrix. This ejector which has the general shape of a bar slides 30 in the fixed part 10 of the matrix, being located in the extension of the shaft 2, and it can go up to push the transmission driver 1 out of the matrix . The use of this stripper prevents an untimely exit of the coach during the ascent of the punch 35, so that this exit takes place only when the ejector 13 is actuated.

  Advantageously, the stripper comprises three fingers 22 extending parallel to the axis AX and which are distributed at one hundred and twenty degrees around the axis AX. Each finger 22 is thus facing one of the lobes of the border 5. The efforts of the stripper on the transmission driver 1 are thus balanced to have a result collinear with the axis AX, which avoids a blocking of the drive trainer in the matrix by bending.

  Similarly, several springs 14 uniformly distributed around an axis AX may be provided between the mobile part 11 of the die and its fixed part 10. The forces undergone by the mobile part 11 when it is moved by the punch are thus balanced to have a result collinear with the axis AX. The risk of the mobile part 11 bracing in the frame 16 is thus reduced, which contributes to increasing the life of the tool according to the invention. Advantageously, three springs can be arranged at one hundred and twenty degrees 20 around the axis AX so as to take advantage of the substantially triangular geometry of the tool.

Claims (6)

  1. Forging tool comprising a die (10, 11) and a punch (12), the punch (12, 13) being intended to penetrate a transmission driver (1) for a motor vehicle by moving along a longitudinal axis (AX) of the transmission driver (1), this transmission driver (1) being positioned in the matrix (10, 11), characterized in that this matrix 10 (10, 11) comprises a movable part (11) along the axis (AX), this movable part (11) surrounding the transmission driver (1), in that the punch (12, 13) comprises a base (13) bearing against the movable part (11) of the matrix to move it against at least one spring (14), and in that the base (13) comprises at least one groove (15) intended to form an external chamfer (8) at the edge (5) of the transmission trainer (1).   2. Tool according to claim 1, in which at least one groove (15) has a substantially V-shaped profile for producing, in the same pass, an internal chamfer (7) and an external chamfer (8) at the edge (5) of the 'transmission drive (1).   3. Tool according to claim 1 or 2, suitable for shaping a transmission trainer (1) whose border (5) defines a closed contour with three lobes offset by one hundred and twenty degrees around the axis (AX), and in which the base (13) comprises three grooves (15) extending circumferentially around the axis (AX), these three grooves being offset by one hundred and twenty degrees one relative to the 'other, to shape the edge (5) of the drive train (1) between each lobe.   4. Tool according to claim 3, comprising a stripper (20) including at least one finger (22) able to penetrate the matrix (10, 11) along the base (13) to come to bear on the edge (5) at a lobe to hold the transmission driver (1) in the matrix (10, 11) when the punch (12, 13) is withdrawn.   5. Tool according to claim 4, comprising 5 three fingers spaced one hundred and twenty degrees around the axis (AX), each finger being positioned to come to bear on one of the three lobes.   6. Tool according to one of claims 1 to 4,   comprising several springs (14) regularly distributed around the axis (AX) to maintain the mobile part (11) of the matrix in the high position in order to ensure a homogeneous distribution of the forces when this mobile part (10) of the matrix is moved by the punch (12, 13).