EP0275561A2 - Method and apparatus for making bevel gears - Google Patents

Abstract

In existing forging processes for bevel gears, a blank is forged between two dies, the deformation already taking place while the forming die is being closed. As a result, material penetrates into the closing gap, with the consequence that the toothed gaps of the bevel gear are bounded by flash walls. The dies are also highly stressed. They are therefore made in such a way that the die cavity is oversized. This oversize which reduces with increasing wear of the dies is removed from the finished bevel gear by machining. In the process according to the invention, the forming die is closed substantially without force. A press ram (19) is advanced in order to press the blank (22) in the direction of a spike (21) on the opposite die (11). The dies are relieved by the press ram (19) and the spike (21). Since the closing gap is sealed during the entire pressing step, no flash is formed. The bevel gear shape is produced by the forging process in one working step, without an aftertreatment being necessary. <IMAGE>

Description

The invention relates to a method for producing bevel gears according to the preamble of patent claim 1 and a corresponding device according to the preamble of patent claim 7.

It is known to manufacture bevel gears, which are used in the differential gear of motor vehicles, by precision forging. Such bevel gears are currently only mass-produced for some commercial vehicles and sports cars. Commercial vehicles have a longer service life than bevel gears manufactured by machining; in sports car construction, forged bevel gears allow an increase in vehicle drive power with the same transmission dimensions. Forged bevel gears have so far not been used in series production of passenger cars because they are compared are more expensive to cut wheels. The reason for the higher manufacturing costs is that forged bevel gears still require post-treatment. In differential gears, the bevel gears have spherical back surfaces to achieve a compact size. In the currently used forging processes on single-acting presses, the material of the blank flows through the closing movement of the dies. This creates a ridge between the back surfaces of the teeth, so that the gaps on the back are closed off by the ridge. In the area of the ridge path, the ribs of the dies that produce the tooth gaps are subject to high wear due to the particularly high flow velocities and contact pressures. In order to be able to achieve a high tool life despite wear, the gears are forged with an oversize in the tip diameter and in the back taper angle. This excess, the size of which changes as the dies wear out, is removed when the forging burr is subsequently turned off, and the dome-shaped back surface is shaped at the same time.

The known methods for forging bevel gears are complex and expensive due to the required post-treatment. Because of the amount of material to be removed later, waste material is created, which increases the costs even more.

The invention has for its object to provide a method of the type specified in the preamble of claim 1, which enables the dimensional manufacture of bevel gears by forging with little material and rework.

This object is achieved according to the invention with the features specified in the characterizing part of patent claim 1.

In the method according to the invention, the die cavity enclosed by the dies, in which the blank is arranged, is closed largely without force. This means that the two dies are placed against one another before the blank is substantially deformed or before any deformation takes place. It is important that the material flow of the blank has not yet reached the closing gap when it is already completely closed. When the closing gap is closed, no material can flow into it, so that any burr formation at the ends of the tooth gaps is avoided. On the other hand, a material flow into the closing gap is avoided as a result of the completely closed closing gap, so that no narrow flow paths arise in which high flow speeds occur, with the result of high wear. The generation of the teeth, ie the filling of the corresponding spaces between the ribs of the die, takes place only after the die cavity has been completely closed. For this purpose, the press ram is advanced after the die is closed. The press ram moves the blank in the direction of the tooth engraving, as a result of which the material of the blank penetrates into all the mold cavities. It is particularly advantageous that the die that contains the press die is largely relieved of the pressure of the blank by the press die. This reduces the frictional shear stresses acting on the die, which makes it easier to fill the engraving and reduces die wear.

Claims 2 to 7 relate to advantageous developments of the method according to the invention.

With the feature of claim 2 it is achieved that the blank provides enough material for filling the die cavity so that this mold cavity can be completely filled and the shape of the bevel gear produced corresponds exactly to that of the die cavity. This not only fills the gearing engraving in the correct shape, but also the back surface of the bevel gear is made to size, so that post-processing is not necessary. Machining may be necessary in the center channel of the bevel gear to prepare it for the assembly of a shaft, e.g. a broaching operation to produce a spline profile. When using a press ram with a non-circular cross-section (e.g. spline profile), the center channel already has a cross-section suitable for the rotationally fixed reception of a shaft in the region of the blind hole created as a result of the pressing process.

The press ram should be advanced so far that its front end lies approximately in the plane in which the die cavity has the largest diameter. In the case of bevel gears with a spherical back surface, this plane is located approximately in the middle of the length of the die cavity. Such a maximum feed position of the press ram ensures that the outermost regions of the die cavity can be completely filled with the material of the blank.

The blank is preferably supported with a mandrel in relation to the press ram. Together with the press ram, the mandrel creates a flow gap from which the material of the blank is pressed out laterally. The mandrel is either stationary during the feed movement of the press ram, or it is pushed towards it by a separate drive in addition to the feed movement of the press ram. Its cross-section can be non-round to create a non-circular blind hole (eg spline profile) to receive a shaft in a rotationally fixed manner. By adjusting the end position of the mandrel in the longitudinal direction, the lateral flow movements can be adjusted so that the flow sheath runs approximately in the plane of the greatest lateral extent of the die cavity, so that it is completely filled. On the other hand, there is the possibility of using either the mandrel or the press ram as an ejector to eject the finished workpiece from the opened die. Between the mandrel and the press ram, an intermediate floor (mirror) is created on the workpiece, which separates two blind holes arranged on opposite sides. During the finishing of the bevel gear, only the intermediate bottom needs to be pierced in a hole operation, and in the case of non-circular blind holes on the resulting channel, a wedge groove or the like corresponding to the profile of the blind holes. can be attached. This can be done in a single operation. In this operation, only a relatively small amount of material is removed because the bevel gear is already spiked at both ends. That he The method according to the invention is therefore particularly suitable for the production of bevel gears with an internal opening.

The process is preferably carried out as hot pressing, the blank being heated to approximately 1100 ° C. in an inert gas atmosphere. This scale-free heating of the forming, cutting by sintering or casting produces an average roughness depth of less than 8 µm. When the blank is inserted into the die, the blank is briefly exposed to the atmosphere, which forms an oxide film on its surface that acts as a release agent between the tool and the workpiece. After the punching operation for ejecting the intermediate floor, a heat treatment can be carried out using the forging heat. By quenching the areas close to the surface and controlled dissipation of the residual heat, the edge zone of the back surface and running gear can be martensitically transformed and the core areas can be kept in a soft structural state. Since the areas to be hardened, namely the back surface and the toothing, no longer have to be reworked after forming, it is also possible to use case hardening of the bevel gear using the forging heat. All that is required is a covering of the perforated wall surface that may need to be machined.

The invention further relates to a device for the production of bevel gears with the features of claim 7. This device offers, in addition to the advantages already mentioned above, the further advantage that the dies do not require any complex and mechanically strong guidance relative to one another, because the main part of the Deformation occurs when the die is completely closed.

In the following an embodiment of the invention will be explained with reference to the drawings.

• Fig. 1 einen Längsschnitt durch die Gesenkform nach dem Einsetzen des Rohlings,
• Fig. 2 einen Schnitt durch die geschlossene Gesenk­form zu Beginn des Preßvorgangs und
• Fig. 3 einen Schnitt durch die geschlossene Gesenk­form nach Beendigung des Preßvorgangs.

Show it:

• 1 shows a longitudinal section through the die shape after inserting the blank,
• Fig. 2 shows a section through the closed die shape at the beginning of the pressing process and
• Fig. 3 shows a section through the closed die shape after completion of the pressing process.

With the die shape shown, bevel gears can be produced, the back surface of which has the shape of a spherical cap. Such bevel gears are used, for example, for the differential gear of motor vehicles.

The die form consists of a lower die 10 and an upper die 11. Both dies 10, 11 have flat closing surfaces 12, which are pressed flat against each other when the die form is closed and surround the die cavity in an annular manner. Part of the die cavity is formed in the lower die 10. This cavity part 13 has the shape of a spherical cap, which is open to the closing surface 12. The upper die 11 forms the tooth engraving. In its cavity part 14 inwardly projecting ribs 15 are formed, which the tooth gaps between the teeth of the to be manufactured Shape bevel gear. The ribs 15 are frustoconical and their height increases in the direction of the lower die 10. The end faces 15a of the ribs 15 protrude beyond the closing surface 12 of the upper die 11 and have a spherical contour which is matched to that of the wall of the cavity part 13, so that the end faces 15a close and cover the entire surface of the cavity part 13 when the die shape is closed invest. Provided on one closing surface 12 is a guide web 16 running annularly around the associated cavity part 14, which can engage in a suitable manner in a guide groove 17 in the closing surface 12 of the lower die 10. The guide web 16 and the guide groove 17 form interlocking guide means to hold the dies 10, 11 in the final phase of the closing movement and in the closed state in a fixed mutual association. The press used to close the die therefore does not need to have a large linear guide.

In a channel 18 of the lower die 10, a press ram 19 can be displaced along the central axis of the die cavity 13, 14 and transversely to the closing surfaces 12. A mandrel 21 is displaceable in a channel 20 of the upper die 11 that is axially aligned with the channel 18. The mandrel 21 has essentially the same diameter as the press ram 19, but the diameter of the mandrel 21 can also be somewhat smaller if the base points of the ribs 15 which surround the mandrel 21 make this necessary.

The blank 22 is inserted into the lower die. This blank has a frustoconical section 22a with a spherical back surface 22b and a shaft 22c adjoining the back surface 22b. The diameter of the shaft 22c is roughly matched to that of the channel 18 which receives the shaft. The back surface 22b lies completely on the surface of the cavity part 13. The conical part 22a in the present exemplary embodiment is of such a shape and size that it fills the die cavity 13, 14 when the die is closed (FIG. 2), with the exception of the spaces between the Ribs 15. The lateral surface of the conical part 22a therefore bears against the tips of the teeth 15, while the back 22b bears against the wall of the cavity part 13. The front of the blank 22 has a blind hole 22d, into which the front end of the mandrel 21 dips when the mold is closed. The die form 10, 11 can be closed without force when the blank 22 is inserted, that is to say without any deformation of the blank taking place. As a result, the closing gap 23 formed by the closing surfaces 12 is reduced to zero before the start of the deformation of the blank.

At the beginning of the deformation process, the press ram 19 is in the retracted position, in which it rests on the end face of the shaft 22c. During the entire process, the mandrel 21 remains in the same position in which its front end projects into the die cavity 13, 14.

During the deformation process, the press ram 19 is advanced in the direction of the die cavity 13, 14 (FIG. 3), namely deep into the die cavity 13, 14. In the end position, the front end of the press ram 19 is at a short distance from the front end of the mandrel 21, and between the press ram 19th and mandrel 21, an intermediate base 24 forms inside the bevel gear 25 to be produced. Due to the pressure between the press ram 19 and the mandrel 21, the material of the blank 22 deviates laterally during the advance of the press ram 19. A flow movement of this material begins, whereby the gaps between the ribs 15 are filled. Not only the material of the shaft 22b, but also material from the inside of the blank is pressed outwards in order to completely fill all areas of the die cavity 13, 14. Vent holes (not shown) are provided on the die shape. The intermediate floor 24, which results after the end position of the press ram 19 has been reached, is located approximately at the height of the largest diameter of the die cavity. At the level of the intermediate floor 24, a flow sheath is formed, from which the flow directions indicated by arrows in FIG. 3 branch off laterally. At the level of the intermediate floor 24, the material flow has the greatest lateral reach.

Following the forging process shown in FIG. 3, the die mold is opened and the bevel gear 25 is ejected from the upper die 11 by advancing the mandrel 21. The intermediate base 24 can then be removed in a hole operation and the through hole formed can be processed. Deviating from this, an out-of-round press ram and mandrel can also be used, with which blind holes with a spline cross section can be produced, for example, so that the introduction of a spline profile after the intermediate floor has been punched out can be omitted by machining processes.

Deviating from the above exemplary embodiment, it is also possible to use a blank 22 without the blind hole 22b. In this case, the mandrel 21 penetrates into the blank 22 when the die shape is closed. The blank 22 does not have to be designed in its conical surface so that the die shape can be closed without force. It is only important that the material flow has not yet reached the closing gap 23 when the fully closed state has been reached.

In the exemplary embodiment described above, the diameter of the channel 18 is significantly smaller than the maximum diameter of the die cavity 13, 14. The high pressing forces exerted by the ram are laterally deflected inside the blank by the mandrel 21. The diameter of the press ram 19 should be a maximum of 0.4 times, preferably 0.3 times the largest diameter of the die cavity.

Although the mandrel 21 is fixed during the forging process, its position relative to the upper die 11 should be changeable in order to be able to influence the thickness of the intermediate floor 24 which results and in particular to be able to change the position of the flow sheath. Such changes are useful for optimizing the forging process.

When the die 19 is pushed forward, the wall of the cavity part 13 is relieved of the blank 22. The frictional shear stresses are reduced by this pressure relief.

The bevel gears manufactured in the die form have received their outer contour from the die shape. Machining the outer contour is no longer necessary.

Claims (14)

1. A method for producing bevel gears by die forging, in which a blank (22) is deformed between two dies (10, 11), one of which has a tooth engraving,
characterized by
that the dies (10, 11) are brought into the closed position before the material flow has started or has reached the closing gap (23) between the dies and that a press ram (19) is advanced in a channel (18) of the one die (10) , which presses the blank (22) towards the other die (11). 2. The method according to claim 1, characterized in that a blank (22) is used which has a shaft (22c) projecting into the channel (18). 3. The method according to claim 1 or 2, characterized in that the press ram (19) is advanced into the die cavity (13, 14) enclosed by the dies (10, 11). 4. The method according to any one of claims 1 to 3, characterized in that the blank (22) is supported with a mandrel (21) relative to the press ram (19). 5. The method according to claim 4, characterized in that the mandrel (21) is pushed into the die cavity (13, 14) after the closing of the dies (10, 11). 6. The method according to claim 4 or 5, characterized in that a blank (22) is used which has a hole (22d) for receiving the end of the mandrel (21). 7. The method according to any one of claims 1 to 6, characterized by its application for the production of bevel gears (25) with a dome-shaped back, wherein a die (11) with a dome-shaped cavity part (13) is used. 8. Device for producing bevel gears by die forging, with two opposing dies (10, 11), which enclose a die cavity (13, 14) and of which the first die (11) has a tooth engraving,
characterized by
that the second die (10) has an engraving which corresponds to the back contour of the bevel gear (25) to be produced and that one of the dies has a press ram (19) which is displaceable in a channel (18) leading into the die cavity (13, 14) is. 9. The device according to claim 8, characterized in that the first die (11) in axial alignment with the press ram (19) has a mandrel (21). 10. The device according to claim 9, characterized in that the mandrel (21) is adjustable to different positions to the first die (11). 11. The device according to one of claims 8 to 10, characterized in that the press ram (19) has a diameter which is substantially smaller than the largest diameter of the die cavity (13, 14). 12. Device according to one of claims 8 to 11, characterized in that the press ram (19) and / or the mandrel (21) has a non-circular cross section and produces a hole which is suitable for the rotationally fixed insertion of a non-circular shaft end. 13. Device according to one of claims 8 to 12, characterized in that the press ram (19) can be pushed into the die cavity (13, 14) up to approximately the level of the closing gap (23). 14. Device according to one of claims 8 to 13, characterized in that both dies (10, 11) have interlocking guide means (16, 17).

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