DE19508952C2 - Press device for producing a molded part and corresponding molded part - Google Patents

Description

The invention relates to a by pressing metal powder and subsequent sintering produced molded part with molded recesses lying transversely to the pressing direction, as well as the device for its manufacture and the associated manufacturing process, with the features presented in the claims.

Shaped bodies, which are made of metal powder by pressing, can in one Variety of shapes need not be produced, in particular like products other manufacturing processes, be built axially symmetrical. Shapes in which the body Has had depressions in the outer or inner surfaces, but so far were only producible if the depressions at the beginning or at the end of the body (in Press direction seen) were. Undercuts or other part recesses, such as for example cross holes, grooves for keys, notches and the like can be not produce in the pressing process and, if necessary, had to be created subsequently either by machining or chemical processing, hot caulking or by assembling several molded parts that are opposite to each other Areas were set accordingly. One such molded part is, for example known from DE-OS 37 34 002.

Also the development of multi-part pressing tools, the parts of which during the pressing process mechanically, hydraulically, pneumatically or electrically against each other At first, there was no improvement in this condition.

In DE 94 05 774 U1 a molded part is one associated device and a manufacturing method described with which it is possible To press undercuts. For this purpose, the pressing tool has additional Form jaws, which form the undercuts during the pressing process and so on are arranged so that the finished molded part after it is out of the outer Overall form-forming die was lifted, laterally from the mold can slide out. However, this design has the inevitable disadvantage that the Undercuts on the molded part cannot be freely arranged. In particular, they cannot be uniform on the outer circumference of a cylindrical one or similar molded part position, which is desirable in many applications is. Bores and similar recesses that engage deeper into the molded part are behind the method described cannot be produced, nor can such depressions the inner surfaces.

DE-OS 15 52 997 shows a stored in the ram Punch. But this is only movable in the pressing direction, so it does not cause any Deformation of the powder column across the press axis. The movement of the punch becomes  not created from the core stamp. The punch is at one end attached, which is located outside the ram.

DE 28 52 429 A1 does have a cross to the pressing direction slidable core, which serves to powder material from the bale chamber oust. However, it is fixed in relation to the die during the pressing process, so that an active influence on the powder column during the pressing process is not possible is.

The object of the present invention is to eliminate the disadvantages shown and thus creating a molding process from which molded parts can be arranged as desired and indentations, undercuts or recesses to be designed can; The invention solves this problem with the features in the factual and Device claims.

According to the prior art, the molded part according to the invention consists of Metal powder, preferably made of iron, aluminum, copper and the like Alloys. It is made by compacting in a pressing device in one pressing operation generated and does not have to be composed of several parts or after sintering to be edited. It has the well-known manufacturing and cost advantages of Sintered parts.

In order to enable the indentations to be formed, the pressing tool has Segment elements or plungers that advance and radially approximately in the tool can be moved back. At the beginning of the pressing process they are in withdrawn position in the die. After filling the die cavity with the initially still loose powder, u. Maybe also during or only after one or several partial presses, they become approximately in the direction of the die center shifted and thus displace the powder from the later recesses. While of the following compression process, they are fixed in the final position reached thereby also by lower stamp and additional load-bearing components of the Press tool are supported so that they are protected against breakage. After full or partial completion of the compression process, they will be back in the Starting position returned. The excavation of the u. U. only after further partial Pressing of the molded part is then possible without difficulty. The Arrangement of the segment elements or plunger in the die is within the limits that are through the outer press and tool design, freely possible. Both the Use of a segment element or plunger as well as several, in any Distances from one another are conceivable, as is the arrangement of such segment elements or plunger in multi-part tools, where several punches and the die are moved relative to each other in the axial direction to produce stepped moldings. The segment elements or plungers can also be outside the die, e.g. B. over or be arranged below it. The devices that the segment elements or plunger Moving in the radial direction are known from the corresponding devices  selected, they work mechanically, hydraulically, pneumatically or electrically. The Axes of the movements of the segment elements or plungers can be right or right lie at an acute angle to the pressing direction, also tangential to a circle around the pressing axis, whose radius can also be inclined against this.

Shaped parts of the type described often have recesses on the inside. This are formed by means of core punches which can be moved in the pressing direction within the die. In such cases, it may also be desirable to be transverse or oblique to Indentations, bores etc. in the pressing direction in the inner wall of the part to attach. The method described above can also be used here, if the segment elements or plungers are arranged in the core stamp and from here from the outside. The prerequisite is that the core stamp is a suitable one has sufficient size.

In FIGS. 1-4, the treated mold part is associated with devices and methods described below using the example of a base plate, as is used for mounting of interior rear-view mirrors on the windscreen of motor vehicles.

Fig. 1 shows the base plate in plan view and cross-section in the previous design,

Fig. 2 shows the same part manufactured by the inventive method,

FIGS. 3a to 3c a longitudinal section through the press tool in the positions

• - die filled with powder, before pressing ( 3 a),
• - during the pressing process ( 3 b),
• - After lifting the molded part ( 3 c), and

Fig. 4 shows a cross section through the pressing tool in the plane BB of Fig. 3b.

In Fig. 1a and 2a, the distribution of the undercuts ( 1 ) on the circumference of the central elevation of the part ( 2 ) can be seen, which, since they are offset by 120 ° to each other, do not allow the finished part laterally from the mold remove if the press parts forming the undercuts are firmly arranged in the press tool. FIG. 1b shows the production of the part according to the previous procedure: The flat base member (3) and the average elevation resulting part (2) are joined together at the interface (4) by known methods of welding, soldering or gluing. The indentation formed on part ( 2 ), which results in the undercut ( 1 ) when parts ( 2 ) and ( 3 ) are joined together, can be formed in a conventional type of tool when part ( 2 ) is produced separately.

FIGS. 2a and 2b differ from Fig. 1a and 1b only in that the part has more no interface (4), since it can be produced by the novel process in a pressing operation.

In FIGS . 3a to 3c, the die ( 5 ) can be seen in each case, which has in its upper part the hollow mold ( 6 ) in which the powder to be pressed to the molded part ( 20 ) is received.

Fig. 3a shows the state after filling the powder into the mold. The lower limit of the hollow shape is formed by the inner part of the lower punch ( 7 ), which in turn can be moved back and forth by the piston ( 8 ). The inner part of the lower stamp ( 7 ) is surrounded by outer stamp parts, the segment lower stamps ( 9 ), which can be moved relative to the lower stamp ( 7 ) by means of the piston ( 10 ). The lower punches are carried by the base plate ( 11 ); it and the die are held by the tool supports ( 12 ), only indicated by dashed lines, on which the die can itself slide up and down. Arranged in the die are the segment slides or plungers ( 13 ) which can be moved towards or away from the die axis ( 15 ) by the segment pistons ( 14 ) which slide tangentially to the die axis.

In the first pressing state, which is shown in Fig. 3a, the cavity ( 6 ) is filled with the powder to be compressed in bulk. The segment slides ( 13 ) are in the starting position, ie they do not engage in the powder column. The inner part of the lower punch ( 7 ) is in the (retracted) starting position, the segment lower punches ( 9 ) with their upper boundary surface ( 16 ) are at the same height as the lower boundary surface of the protruding nose ( 17 ) of the segment slide ( 13 ).

FIG. 3b shows in addition the upper part of the tool the inner punch (18) and the surrounding outer upper punch (19).

After filling the cavity 6 , the outer upper punch ( 19 ) first dips into the die and moves downward in the pressing direction in synchronism with the die until the powder forms between the inner upper punch ( 18 ) and the outer upper punch ( 19 ) Filled in space by powder transfer. Then the segment slides ( 13 ) are brought into the inner end position by the tangential displacement of the segment pistons ( 14 ), in which they protrude into the powder column in the cavity ( 6 ) as far as this to produce the undercut (in other parts: the bore or other specialization) is desired. The inner upper punch ( 18 ) is then moved at a higher speed than the die ( 5 ) and the outer upper punch ( 19 ) so that on the one hand the powder column in the cavity ( 6 ) from above, on the other hand, through the counter-held inner part of the lower punch ( 7 ), is compressed from below.

The segment slides ( 13 ) are then moved back into their starting position by tangentially displacing the segment piston ( 14 ). It can now the almost finished molded part under load of the upper punches ( 18 ) and ( 19 ), which protect the collar area of the part against deformation, molded with the downward movement of the die ( 5 ) and then ejected through the inner lower punch ( 7 ). This state can be seen in Fig. 3c. The molded part ( 20 ) is already outside the mold and can be removed from there by mechanical means or by hand.

FIG. 4 shows a cross section on the plane BB through the die ( 5 ) from FIG. 3b. The segment slides ( 13 ) are in their engaged position, ie they are advanced towards the middle of the die. Accordingly, the segment pistons ( 14 ) are in the position in which the bulge ( 21 ) towards the die center rests on the part of the segment slide ( 13 ) closer to the die center. The device by means of which the segment piston ( 14 ) can be moved back and forth is shown as a hydraulic or pneumatic piston / cylinder device ( 22 ). The fluid required for its actuation is supplied or discharged through the feed lines ( 23 ) provided in the die. At this point, however, an electrical or mechanical device can also be arranged as an effective element.

In order to bring the segment slides ( 13 ) back into the starting position, the segment pistons ( 14 ) are displaced such that the bulge ( 24 ) facing the outside of the die lies against the part of the segment slider ( 13 ) which lies in the direction of the outside of the die. The state is then reached as shown in another section in FIGS . 3a and 3c.

The arrangement of the segment slides ( 13 ) in the die depends on the shape of the molded part to be produced. It is obvious that their number, shape, arrangement and size of movement - within the limits of technical feasibility - can be freely selected. This also applies to the arrangement seen at different heights or in relation to the axis of the die. The part of the segment slide ( 13 ) which forms the undercut or other recess of the molded part is of any shape, corresponding to the shape which is desired for the undercut or other recess. It can have designs which have a favorable effect on the pressing technology, in particular the filling of the surrounding spaces and the movement of the segment slide ( 13 ) in the form of a blank, in particular thus bevels, chamfers etc. The part of the segment slide running in the longitudinal guide can be round, rectangular or be polygonal. If it is designed round and the longitudinal movement in rotation about the longitudinal axis of the segment slide ( 13 ) generated, for. B. by the arrangement of a conventional worm gear instead of the segment piston ( 22 ), the formation of a helical contour in the recess of the molded part is possible.

In the case of an adhesive plate such as that described above, a core stamp is not available. The application of the method according to the invention to a molded part However, design with a core stamp is certainly easy for the specialist to do that there is no detailed description in this case.

It should also be noted that the invention is not limited to the production of Parts made of metal powder. It can also be used for parts that are comparable Processes are made from ceramic or plastic powders.

Claims (11)

1. Press device with a die ( 5 ) and a plurality of punches ( 7 ), ( 9 ), ( 18 ) and ( 19 ) for producing a molded part from metal powder with at least one segment slide ( 13 ) arranged in the die, which is transverse or oblique to Pressing direction can be shifted and has at its end facing the die axis a design corresponding to the counter-contour of an undercut, recess, bore or other recess, which is to be formed in the molded part, characterized in that the segment slide ( 13 ) by means of appropriate feed and retraction devices can also be moved during the pressing process for the molded part after closing the mold. 2. Press device according to claim 1, which additionally at least one core stamp to form cavities or holes in the molding parallel to Press axis, characterized in that the segment slide in the core punch is located in this substantially transverse to the pressing direction in Direction can be moved to an inner surface of the molded part. 3. Press device according to one of claims 1 or 2, characterized in that the axis of movement of the segment slide ( 13 ) tangential to one around the axis of the die ( 5 ) or, if such is not present because of the design of the molded part ( 20 ), runs around a circle drawn in the center of the pressing tool in the pressing direction. 4. Press device according to at least one of claims 1 to 3, characterized in that the movement axis of the segment slide ( 13 ) extends at right angles to the pressing direction. 5. Press device according to at least one of claims 1 to 3, characterized in that the axis of movement of the segment slide ( 13 ) is inclined at an acute angle upwards or downwards to the pressing direction. 6. Press device according to claim 1, characterized in that the segment slide ( 13 ) outside of the die is arranged above or below it and so inclined to the die axis that its die end facing the middle during feed through corresponding recesses in the die in the Immersed molding cavity ( 6 ). 7. Press device according to claim 1 and / or one of the following, characterized in that the segment slide ( 13 ) has a round, oval, rectangular, trapezoidal or cross-section combined from the geometric figures mentioned. 8. Press device according to claim 1 and / or one of the following, characterized in that for the displacement of the segment slide ( 13 ) in the transverse direction to its sliding direction, a segment piston ( 14 ) is present, which has increases on both sides, depending on the position of the segment piston ( 14th ) move the segment slide ( 13 ) in the direction of the die center or the edge of the die, or if the segment slide is arranged in the core punch in reverse directions. 9. Press device according to claim 8, characterized in that the segment piston ( 14 ) is displaceable pneumatically, hydraulically, mechanically or electrically with conventional devices of the corresponding type. 10. Press device according to one of claims 1 or 2, characterized in that the segment slide ( 13 ) rotates by a screw device or by ent speaking hydraulic, pneumatic or electrical devices during the longitudinal movement. 11. molded part made of metal powder, in particular sintered molded part, in the Press device according to at least one of claims 1 to 10, characterized characterized in that at least one in the molded part transverse to the pressing direction protruding undercut, hole, groove or other recess any place of the pressed part outer or inner surface arranged and during the pressing process is generated, from which the molded part emerges.