EP0318353A1 - Grinding arrangement for the crankpins of a crankshaft - Google Patents

Abstract

Grinding arrangement for the crankpins of a crankshaft having the same pitch between bearings and crankpins and the same crankpin width, comprising a grinding machine (1) equipped with two part-carrying heads (4), each equipped with a part-carrying mounting element (6) driven in rotation and equipped with connection means for a shell (10) on which is fixed one of the bearings (11a) of a crankshaft to be machined. This arrangement furthermore comprises a device for loading and unloading the shells (10), which comprises a support (19) for arms (22) for loading and unloading the shells, and a store (23) of shells which can move with respect to the supports and is capable of presenting the appropriate shells (10) to the arms. The shells (10) are provided with means for fastening onto the crankshaft which are independent of the part-carrying mounting elements (6). <IMAGE>

Description

Current technology of internal combustion engines leads, from a basic cylindrical block characterized essentially by the spacing of the cylinders, to design a large number of particular engines, of different powers, by varying, in particular, the stroke of the crankshaft . The variation in power generally causes the diameter of the crankshaft bearings to also vary. This creates a family of crankshafts differing both in their bearing diameter and their stroke.

In the current state of the art, there is no known crankpin grinding machine which allows large-scale machining of parts with different bearing diameters. Regarding racing, however, several solutions have been pro asked but they all lead to complicated mechanics, therefore unreliable, and lead to a decrease in rigidity and therefore in precision. For all these reasons they are only very little used in large automobile series where it is preferred to interpose, between the bearings of the crankshafts and the workpiece heads of the grinding machine, shells which are changed manually when modifying the type of crankshaft, which leads to campaigns whose duration is at least a few hours.

The present invention relates to a rectification assembly which allows, on the contrary, to machine in a random distribution, crankshafts which have not even between bearings and crankpins and same crankpin width but whose strokes and bearing diameters are different .

This set includes:
- a grinding machine provided with two workpiece support heads each equipped with a workpiece support mounting element, driven in rotation and provided with fastening means for a shell on which is fixed one of the bearings of a crankshaft to machine so that the latter rotates around the axis of its crankpins.
- a parts conveyor
- and a gantry for loading and unloading crankshafts
and is characterized in that it further comprises a device for loading and unloading the shells which comprises a support for arms for loading and unloading the shells and a shell magazine which is movable relative to the support and suitable for present the appropriate shells to the arms, and in that the shells are provided with fixing means on the crankshafts which are independent of the workpiece mounting elements.

When using this assembly, shells are used with each crankshaft such that, on the one hand, they blend with the diameter of the bearings, and on the other hand, they position the axis of the crank pin (s) on the machine. to be substantially corrected on the axis of rotation of the workpiece heads.

• La Figure 1 est une vue en élévation de cet ensemble;
• La Figure 2 montre, à plus grande échelle, un vilebrequin monté et serré sur la machine à rec­tifier;
• La Figure 3 est une coupe suivant III-III de la Figure 1 et montre en position de repos un bras du dispositif de chargement et de déchargement des coquilles;
• La Figure 4 est une vue semblable à la Figure 3, une coquille étant en cours de transfert par le bras du magasin au vilebrequin ou inversement;
• La Figure 5 est une vue semblable aux Figures 3 et 4, la coquille étant serrée sur un palier du vilebrequin alors que le bras de chargement s'ap­prête soit à l'enlever du vilebrequin, soit à l'y abandonner;
• La Figure 6 est une vue en coupe suivant VI-VI de la Figure 2 et montre un vilebrequin serré sur la machine;
• La Figure 7 est une vue en coupe suivant VII-VII de la Figure 6.

An embodiment of the rectification assembly according to the invention has been described below, by way of non-limiting example, with reference to the appended drawings in which:

• Figure 1 is an elevational view of this assembly;
• Figure 2 shows, on a larger scale, a crankshaft mounted and tightened on the grinding machine;
• Figure 3 is a section along III-III of Figure 1 and shows in the rest position an arm of the device for loading and unloading the shells;
• Figure 4 is a view similar to Figure 3, a shell being transferred by the arm of the magazine to the crankshaft or vice versa;
• Figure 5 is a view similar to Figures 3 and 4, the shell being clamped on a bearing of the crankshaft while the loading arm is about to either remove it from the crankshaft, or to abandon it;
• Figure 6 is a sectional view along VI-VI of Figure 2 and shows a crankshaft tightened on the machine;
• Figure 7 is a sectional view along VII-VII of Figure 6.

As shown in Figure 1, the grinding assembly includes a grinding machine 1 comprising a frame 2, a table 3 and two workpiece heads 4 fixed on the table 3. In each of these heads is mounted rotationally a spindle 5 secured a mounting element 6; the two pins are connected to a drive motor not shown by means of a common drive shaft 7 and sets of gears 8 and 9. Means described below in detail make it possible to secure each of the elements mounting 6 a shell 10 itself fixed to one of the bearings 11 a of a crankshaft 11 so that the axis of the pins 5 is coincident with one or the other of the axes XX ′ and YY ′ of crank pins 11 b of this crankshaft: the pitch between bearings and crank pins is equal to a and each crank pin has a width b .

The assembly also includes a gantry 12 for loading and unloading the crankshafts 11 from a conveyor 13 to the grinding machine 1. This gantry comprises a beam 14 which rests on feet 15 and on which a handling trolley can move 16 provided with two clamps 17 and two supports 18.

Finally, the assembly includes a support 19 on which are fixed bearings 20 for an axis 21 integral with two loading arms 22 and with respect to which a magazine 23 for shells 10 can move in the direction of the arrow f-f ′. A motor 24 makes it possible to pivot the axis 21, therefore the arms 22.

The assembly makes it possible to machine crankshafts which have not even a between bearings and crankpins and same width b of crankpins, but the other dimensions of which, in particular the half-stroke c , can vary by a few millimeters.

The shells 10 have a dimension d = h + c, h being a constant of the machine, and a cavity diameter equal to the diameter of the bearings 11 a (see Figure 6). The magazine 23 contains four shells per type of crankshaft programmed, the homologous shells being spaced by the distance e between the two arms 22.

As seen in Figures 3 to 5, each shell 10 can be fixed to one of the bearings 11 a of a crankshaft 11 by a dog 25 pivotally mounted at 26 relative to the shell. This has a well 27 on the bottom of which is supported by a helical spring 28 pressing, by means of a pusher 29, on a beak 30 of the dog 25 and thus tending to maintain the latter in the closed position. The shell carries a stop 31 which ensures the correct angular orientation of the shell relative to the crankshaft.

For its part, each loading arm 22 is integral with a double-acting hydraulic cylinder 32, the chambers of which can be brought into communication with a source of hydraulic pressure by holes 33 and 34. The piston 35 of this cylinder can, when arm 22 occupies the position of Figure 4, engage in the well 27 and push the spout 30 against the action of the spring 28 to open the dog 25 and release the shell 10 from the crankshaft. The arm 22 is also provided with a pin 36 suitable for engaging in a bore 37 of the shell perpendicular to the axis of the well 27.

As seen in Figures 6 and 7, each shell 10 has two bearing faces 10 a by which it can rest in a recess in one of the mounting elements 6. A jaw 38 pivotally mounted on the mounting element 6 around an axis 39 housed in an ovalized housing 40 of the mounting element, can be pressed on the dog 25 to hold the shell 10 in the recess of the mounting element; this jaw is guided laterally by rollers 41 supported in the mounting element 6. To ensure the displacement of the jaw 38, there is provided a roller 42 whose axis is integral with the jaw and a roller 43 which can be interposed between the roller 42 and a flange 44 carried by the fixing element 6. The axis of this roller 43 is carried by a piston 45 which is movable in a chamber 46 of the mounting element 6. A pressurized liquid can be admitted into the chamber 46 by holes 47 and 48 opening on either side of the piston 45. When the jaw arrives in the clamping position, it is positioned in front of the dog 25 by a stop screw 49 applied against the mounting element by a spring 50 tending to rotate the jaw relative to the mounting element. A piston 51 movable in a chamber 52 of the mounting element can be applied against the jaw 38 by admitting a pressurized liquid into the chamber 52 by a bore 53, to loosen the jaw. The rectification assembly which has just been described operates in the following manner. The gantry 12 takes a crude crankshaft on the conveyor 13 at A, raises it at B, and translates to bring it to C where the two arms 22 load it with two shells 10 taken from the store 23. The gap e between the arms 22 is equal to a in the case of the rectification of the central crank pins 11 b and to 3 a in the case of the extreme crank pins. The arms 22 being at rest, as indicated in solid lines in Figure 3, come to take the desired shells in the magazine 23; the piston 35 is then brought into the extended position so as to open the hammer 25 and secure the shell with the arm, the force reaction of the piston 35 being absorbed by the pin 36 (Figure 4). Then the arms continuing to move deposit the shells on the bearings 11b of the crankshaft; the pistons 35 are brought into position retracted so that the jaws 25 secure the shells to the crankshaft (Figure 5).

The entire crankshaft with its two shells is then translated into D, then loaded into E on the grinding machine 1. Liquid under pressure is then admitted into the chambers 46 through the holes 47 so that the jaws 38 grip the dogs 25 on the bearing surfaces 11 a of the crankshaft 11. The latter is thus fixed, by its shells 10, on the mounting elements 6 and its crank pins 11 b which are then coaxial with the pins 5 can be corrected.

After rectification, the crankshaft follows a reverse path. It is first released from the mounting elements 6 by admitting fluid through the holes 48 and 53, then brought back to D and C; in this position, it is released from its shells by admitting fluid into the jacks 32 through the holes 33, so that the pistons 35 push back the beaks 30 of the dogs 25. The shells 10 released are brought back into the magazine 23 by the arms 22 while the crankshaft returns to the conveyor 13 to be evacuated.

It goes without saying that the present invention should not be considered as limited to the embodiment described and shown, but on the contrary covers all variants thereof.

Claims (7)

1. Crankshaft crankpin rectification assembly having not even between bearings and crankpins and same crankpin width, comprising
- a grinding machine (1) provided with two workpiece support heads (4) each equipped with a workpiece holder mounting element (6), driven in rotation and provided with fastening means for a shell (10) on which one of the bearings (11 a ) of a crankshaft to be machined is fixed, so that the latter rotates around the axis of its crankpins,
- a parts conveyor (13),
- and a gantry (12) for loading and unloading the crankshafts (11),
characterized in that it further comprises a device for loading and unloading the shells (10) which comprises a support (19) for arms (22) for loading and unloading the shells and a magazine (23) for shells which is movable relative to the supports and suitable for presenting the appropriate shells (10) to the arms, and in that the shells (10) are provided with fixing means on the crankshaft which are independent of the mounting elements (6) rooms. 2. Rectification assembly according to claim 1,
characterized in that the means for fixing the co pins (10) on the crankshaft (11) comprise, for each shell, a dog (25) pivotally mounted on the shell (10) and subjected to the action of a spring (28) tending to maintain it in the closed position. 3. Rectification assembly according to claim 2,
characterized in that the spring (28) is disposed in a well (27) of the shell (10). 4. Rectification assembly according to claim 3,
characterized in that each arm (22) carries a hydraulic piston (35) suitable for engaging in the well (27) and for bringing the dog into its open position, against the spring (28). 5. Rectification assembly according to claim 3 or 4,
characterized in that each arm (22) is provided with a pin (36) suitable for engaging in a bore (37) of the shell arranged perpendicular to the axis of the well (27). 6. Rectification assembly according to one of claims 1 to 5,
characterized in that the means for securing a shell (10) with a mounting element (6) comprise a jaw (38) pivotally mounted on the mounting element and means for pressing this jaw on the shell the (10) or an element thereof, for example on the dog (25) with which it is provided. 7. Rectification assembly according to claim 6,
characterized by a hydraulic piston (51) for pivoting the jaw (38) and bringing it into its released position.

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