EP0333052A2 - Drawing apparatus for shaping sheet metal blanks - Google Patents

Abstract

The motion of the blank holder (15) can be converted by a hydraulic unit of the drawing apparatus into a simultaneous but opposite motion of the drawing punch (17). The hydraulic unit has a central working piston (12), an annular piston (13) surrounding the latter, and a cylinder (10d) surrounding the annular piston. The working piston (12) and the annular piston (17) can be pressurised from hydraulically separated cylinder spaces (51, 52; 48) which communicate with one another via at least two alternative flow paths (lines 20; 20a; 20b). Due to their different hydraulic design, the flow paths entail a pressure variation on a different pressure level in the intercommunicating cylinder spaces (51, 52; 48). A pressure transducer (21) detecting the pressure of the hydraulic fluid in the cylinder spaces (51, 52; 48) connects up the alternative flow paths when limiting pressures are exceeded. It is thereby possible to manufacture even drawn components which are extremely difficult as regards deformation profile and/or material and/or drawing depth without the necessity to sacrifice the cost- and space-saving construction of the drawing apparatus. <IMAGE>

Description

The invention relates to a drawing tool according to the preamble of claim 1.

For a known drawing tool of this type, it is characteristic that the drawing process is broken down into a partial pull determined by the externally driven drawing ring and into a simultaneous, but opposite partial pull caused by the punch, in that the working piston is driven in the opposite direction to the sheet metal holder by the pressure medium displaced by the annular piston. A common cylinder space is provided for the ring piston and the drive piston. After the drawing process, the drawing tool can be returned to its starting position by acting on a differential surface of the drive piston (DE-OS 36 20 876 - see also US Pat. No. 2,609,775 and AU-OS 132,028). In addition, it is also known to change the drawing force and the sheet metal holding force in each case with the aid of hydraulic control elements in a drawing tool of another type, in that pressure medium is discharged from the relevant cylinder spaces into a reservoir. The volumes of pressure medium required for the usual drawing process in the cylinder spaces mentioned can be reproduced by refilling from a pressure accumulator. The drawing tool can only be operated in large presses due to the size of the 'drawing cushion' (DE-OS 36 03 107).
Based on the prior art mentioned, the invention has for its object to develop a drawing tool of the type mentioned in such a way that with respect to the deformation profile and / or material and / or drawing depth also extremely difficult drawn parts can be produced without the cost and space-saving structure would have to be revealed.

This object is achieved by the features mentioned in the characterizing part of claim 1.

With such a design, the hydraulic separation of the cylinder spaces adjoining the annular piston and the working piston opens up numerous possibilities for influencing the sequence of the drawing process, the space-saving structural principle of coaxially intermeshing several pistons (central piston 10c; working piston 12; annular piston 13) basically being retained can be; Likewise, a simple interchangeability of the drawing ring, sheet holder and / or drawing punch for adaptation to different drawn parts. In the solution according to the invention, the pulling process taking place with the energy-saving pulling movement of the pulling ring and the pulling punch can be adapted to the respective drawing requirements by the need-dependent, pressure-dependent flow path change. Every change is triggered by a negative criterion, such as the risk of tearing on the drawing part, that the drawing speed is too low and brings the corresponding hydraulic elements into or out of action. Changes in the sheet holding force, the pulling force and the pulling speed can also be alternated in order to achieve a rapid and at the same time energy-saving pulling process during this pulling process. Otherwise, the basic requirements for a controlled discharge of pressure medium from the cylinder spaces of the hydraulic unit into a pressure accumulator or into the pressure medium reservoir as well as for re-feeding into the cylinder spaces from a pressure accumulator are present, whereby further possibilities of influencing the drawing process can be developed. In particular, a drawing process or a time segment thereof can take place with the drawing ring stationary or with the drawing punch stationary. On the other hand, it is also possible to manufacture very simple drawn parts without changing the flow path with a relatively rapid cycle sequence by switching on a flow path with the lowest possible flow resistance (first flow path). Overall, the control engineering requirements exist for the fact that almost exclusively energy-saving process of an opposite movement of the drawing ring and drawing punch can be used. This means that only in the case of extremely difficult drawn parts or in critical drawing sections of a drawing process, when the punch or drawing ring is at a standstill. In an embodiment according to claim 2, despite the separation of the cylinder chambers for the working piston and the annular piston, the hydraulic unit has a particularly compact structure, which means that the drawing tool is used in different presses that supply the external driving force, especially in small presses.

A further embodiment according to claim 3 ensures that, with the construction of the hydraulic unit being favorable in terms of production engineering, the drawing tool can be returned to its starting position from the cylinder space delimited by the central piston after the drawing process has been completed. In addition, during the drawing process, the oil which is necessarily displaced from this cylinder chamber can be fed into the rear cylinder chamber of the working piston to accelerate the drawing process.

In a further development according to claim 4, relatively simple drawn parts can be manufactured when the first flow path (line 20) is switched on.

With the second flow path (line 20a), the sheet holding force can be adjusted in accordance with the respective drawing technical requirements before the start and during the drawing process by appropriately presetting the pressure of the pressure limiting valve 36, the optimum initial sheet holding force having been empirically determined beforehand. At the transition to the third flow path (line 20b), the pressure in the hydraulic system is reduced thanks to the pressure booster if there is a risk of the pulling part tearing off. A flow path change corresponding to the respective drawing technical requirements leads to an optimization of the drawing process with regard to energy saving and drawing speed, while avoiding any risk of tearing off, the limiting pressures or cross sections to be preset on the pressure limiting valve and on the throttle valve generally being empirically determined beforehand.

According to claim 5, the drawing speed can be increased with a corresponding adjustment of the sheet holding force.

In one embodiment according to claim 6, the drawn part can be produced by opening the third flow path to the pressure accumulator while the drawing piston is stationary. If the flow path is only opened temporarily, there is a corresponding temporary pressure drop via the hydraulic system.

According to claim 7, the drawing process can take place with the ring piston at a standstill.

In a further embodiment according to claim 8, it is possible to exactly reproduce the pressure medium fillings in the cylinder spaces of the hydraulic unit if pressure medium has previously been discharged from these cylinder spaces into the left storage space of the piston accumulator from these cylinder spaces.

In a further embodiment according to claims 9 and 10, excessive stresses on the drawing tool when bending the remaining blank from the edge of the drawn part are avoided.

The invention is described below with reference to the drawing.

• Fig. 1 Das Ziehwerkzeug im Schnitt durch seine Symmetrieachse mit den zugehörigen hydraulischen Steuerorganen und
• Fig. 2-8 das Ziehwerkzeug in einer Darstellung gemäß Fig. 1 in unterschiedlichen Arbeitspositionen bzw. bei unter­schiedlichen Arbeitsweisen, wobei die Fig. 1,2,4 das Ziehwerkzeug bei Beginn und die Fig. 3,5-8 bei Ende des Ziehvorganges zeigen.

In a schematic representation:

• Fig. 1 The drawing tool in section through its axis of symmetry with the associated hydraulic control elements and
• 2-8 the drawing tool in a representation according to FIG. 1 in different working positions or with different working methods, wherein FIGS. 1,2,4 show the drawing tool at the beginning and FIGS. 3,5-8 at the end of the drawing process .

The drawing tool is used for forming preferably flat sheets, for example in containers, pots, sinks and the like. An external driving force A acts on the drawing tool from outside for forming. It usually comes from a hydraulic press, the press head of which drives the drawing ring 18 of the drawing tool. Together with the drawing ring 18, a sheet metal holder 15 is moved during the forming process. A circuit board 47 is clamped between the drawing ring and the sheet metal holder at the beginning of the drawing process. To deform the circuit board 47, a drawing die arranged coaxially in the sheet metal holder can be moved into the drawing ring 18. The movement of the movement unit 18, 15 carrying the respective circuit board 47 can be converted into a simultaneous but opposite movement of the drawing punch 17 with the aid of a hydraulic unit H of the drawing tool. The hydraulic unit H comprises a central working piston 12, an annular piston 13 enclosing it and a cylinder 10d enclosing the annular piston, which is part of a cylinder housing 10 of the hydraulic unit H. The annular piston 13, which can be driven indirectly by the driving force A, can be supported on the pressure medium of a cylinder space 48. The working piston 12, which is designed as a differential piston, can be acted upon with pressure medium on both sides. The pressure medium displaced from the cylinder space 48 during the drawing process by the annular piston 13 drives the working piston at least temporarily during the drawing process. Cylinder spaces 51, 52 and 48 delimited from the base of the cylinder housing 10 are hydraulically separated from one another by a separation sleeve 10a projecting from this base. The annular piston 13 guided on the cylinder 10d of the cylinder housing 10 is guided on the working piston 12 by means of a radial flange 13a which overlaps the separating sleeve 10a. The inner circumferential surface 13b of the annular piston 13 is located at a distance from the outer circumferential surface of the separating sleeve 10a. The working piston 12 which can be acted upon from the rear from the cylinder space 51 can be acted upon in the opposite manner from a cylinder space 49 which lies in a central recess of the cup-shaped working piston 12. The cylinder chamber 49 is delimited by a central piston 10c anchored in the base of the cylinder housing 10 and an annular part 12b screwed to the working piston 12. The ring part 12b encloses the shaft 10b of the central, stationary piston 10c sealing. The rear cylinder space 51 communicates with a further cylinder space 52. This is delimited by the bottom 12a of the working piston 12 and by the central piston 10c. As can be seen from Figure 1, the drawing punch 17 is received by the working piston 12 via a cylindrical intermediate piece 17a. An adapter ring 14 between the sheet metal holder 15 and the upper edge of the annular piston 13 serves to transmit the driving force from the sheet metal holder 15 to the annular piston 13. In the sheet metal holder 15, a knife ring 16 is arranged to be displaceable to a limited extent. When the remaining blank is bent from the edge of the finished drawn part, this knife ring 16 interacts with stationary stops 16a. These are supported on the end edge of the cylinder 10d of the cylinder housing 10 and, when the sheet metal holder moves downward, plunge into corresponding bores in this sheet metal holder.

Working pistons 12 and annular pistons 17 can be acted upon from the hydraulically separated cylinder spaces 51, 52 on the one hand and 48 on the other hand. In the exemplary embodiment shown in the drawing, the cylinder spaces mentioned can be connected to one another via three alternative flow paths, which are each designed differently hydraulically. The first flow path is via line 20. The second flow path is via line 20a. The third flow path is formed by line 20b.

Due to the different hydraulic design, the alternative flow paths in the cylinder spaces 51, 52 and 48 (which communicate with one another via the connecting channel 50) necessitate a pressure curve at a different pressure level during the drawing process. The flow path change can be triggered by a pressure sensor 21 which detects the pressure of the pressure medium in the communicating cylinder spaces 51, 52; 48 and which delivers switching impulses when preset limit pressures are exceeded. A 2-way valve 34 and the pressure sensor 21 are arranged in the line 20 of the first flow path. In line 20a of the second flow path there is a controllable pressure limitation that can be set to different limit pressures valve 36 with an upstream check valve 35. A 2-way valve 40, a throttle valve 22 and a piston accumulator 24 acting as a hydraulic pressure intensifier are inserted in line 20b of the third flow path. The pressure medium introduced into the cylinder spaces 51, 52 under pressure during the drawing process via the three alternative flow paths acts on the working piston 12 via an action surface which is larger than the cross-sectional area of the piston head 12a. In this respect, the working piston acts as a pressure intensifier, which is possible in that the stationary piston 10c projects radially beyond its shaft 10b, which results in the enlargement of the pressure area. With this design, the driving force A can be converted into a larger force of the drawing piston (with a smaller drawing path).

In order to increase the speed of the drawing process, the pressure medium filling of the cylinder space 49 delimited by the ring part 12b and by the central piston 10c can be introduced into the rear cylinder space 51 of the working piston 12. When the directional control valve 19 is open, the pressure medium displaced from the cylinder space 49 during the drawing process reaches the line 45 into the cylinder spaces 51, 52 via channel 11. For the purpose of resetting the drawing tool in the starting position after the drawing process, the empty cylinder space 49 is refilled from a pressure accumulator 26. With this reset, a volume of pressure medium corresponding to the volume of the cylinder space 49 can be displaced from the cylinder spaces 50, 51, 48 into the pressure medium reservoir 27. The right cylinder space 24b of the piston accumulator 24 can be connected to the pressure accumulator 26 via a line 41 provided with a 2-way valve 25, which in turn can be connected to all cylinder spaces of the hydraulic unit for recharging or for pressure relief. The pressure accumulator 26 itself can be reloaded from the pressure medium reservoir 27 by means of a feed pump 39.

Finally, the working piston 12 can be driven by means of a pressure source P when the annular piston 13 is stationary, that is to say when the driving force A is switched off. That from the cylinder chamber 49 displaced pressure medium is discharged into the pressure medium reservoir 27 via a 2-way valve 28. The discharge can also take place via a valve 30 which opens when an upper pressure limit is exceeded.

The 2-way valve 40 and the throttle valve 22 in the line 20b of the third flow path can be bridged by means of a bypass line 20b. A check valve 23 which releases a predetermined pressure in the flow direction in the flow direction is arranged in this. The mass moved when folding the rest of the blank from the edge of the finished drawn part, which is represented in the illustrated embodiment by the drawing ring 18, the sheet metal holder 15, the adapter ring 14 and the annular piston 13, can be eliminated by throttling the outflow of the pressure medium from the bending resistance Cylinder chamber 48 are stopped. This is done with the help of the throttle valve 22 arranged in the line 20b of the third flow path in dependence on and the pressure drop triggered by the elimination of the folding resistor. The pressure medium passes through the piston accumulator 24 into the pressure accumulator 26, the 2-way valve 33 being controlled in the closed position and the 2-way valve 25 in the open position.

Fig. 1 shows the out of operation drawing tool with the entire associated hydraulic system with the board inserted.

The figures 2-8 are used to explain specific different procedures in the operation of the drawing tool, which correspond to the different drawing requirements. The lines and rooms through which the respective process flows are emphasized by a stronger line. All organs not included in the process sequence, in which there is consequently no pressure, are omitted.

2: To produce simple drawn parts with a relatively fast cycle sequence, the drawing tool is switched to the first flow path. During the drawing process, the pressure medium flows from the cylinder space 48 via the line 20 with a two-way valve 34 into the cylinder space 51 and additionally via the connecting channel 50 into the cylinder space 52.

Fig. 3: In this figure, the drawing tool is switched to the second flow path. The pressure medium is displaced from the cylinder space 48 with the partial inclusion of the line 20 of the first flow path via a check valve 35 and an adjustable pressure relief valve 36 in a line 20a into the cylinder spaces 51, 52 in order to drive the drive piston 12. The switching of this flow path makes sense if an adjusted setting of the sheet holding force is important before the drawing process begins or if a control of the sheet holding force is indicated during the drawing process. The drawing process only begins when the sheet metal holding force, that is to say the pressure in the cylinder space 48, exceeds the limit pressure set in the pressure relief valve 36. This limit pressure is adjustable or changeable depending on the pressure sensor 21, so that the sheet metal holder force can be adapted to the respective drawing requirements during the drawing process.

Fig. 4: When switching the third flow path according to Fig. 4, the pressure medium coming from the cylinder space 48, including the line 20 of the first flow path, via line 20b, via a two-way valve 40, a throttle valve 22 and via a piston accumulator 24 and via Another directional control valve 33 is pressed into the cylinder spaces 51, 52 in order to drive the working piston 12. As can be seen from the figure, the piston accumulator 24 is designed as a pressure intensifier. When switching to the third flow path, the pressure in the hydraulic system is therefore reduced (and the drawing speed is reduced accordingly) when this pressure has exceeded an upper limit, which, with respect to the drawing part in work, entails the risk of tearing off. The pressure sensor therefore switches at a critical limit pressure previously determined empirically.

• 1. Das Druckmedium kann zur Beschleunigung des Ziehvorgangs über das Wegeventil 19 in der Leitung 45 in die Zylinder­räume 51,52 eingespeist werden. In diesem Falle wird nach dem Ziehvorgang bei Rückstellung des Ziehwerkzeuges in Ausgangsstellung (welche Rückstellung weiter unten erläutert wird) aus den Zylinderräumen 51, 52 ein Volumen an Druckmedium in das Druckmittel-Reservoir 27 verdrängt, das dem zuvor beim Ziehvorgang in die Zylinderräume 51, 52 eingespeiste Volumen an Druckmedium entspricht. Dabei gelangt das Druckme­dium aus den vorgenannten Zylinderräumen 51, 52 über einen Abschnitt der Leitung 20 und über das Wegeventil 28 in das Druckmittel-Reservoir 27.
• 2. Das beim Ziehvorgang aus dem Zylinderraum 49 verdrängte Druckmedium gelangt über die Leitungen 43,42,46 mit Wege­ventilen 32,37,28 direkt in das Druckmittel-Reservoir 27.

Regardless of whether the pressure medium flows into the cylinder spaces 51, 52 via the first, second or third flow path, the pressure medium displaced from the cylinder space 49 during the drawing process can be discharged in different ways. These different paths correspond to the respective drawing requirements:

• 1. To accelerate the drawing process, the pressure medium can be fed into the cylinder spaces 51, 52 in the line 45 via the directional valve 19. In this case, a volume of pressure medium is displaced from the cylinder spaces 51, 52 into the pressure medium reservoir 27 after the drawing process when the drawing tool is returned to the starting position (which provision will be explained below), which volume previously was during the drawing process into the cylinder spaces 51, 52 volume of pressure medium fed corresponds. In this case, the pressure medium passes from the aforementioned cylinder spaces 51, 52 via a section of the line 20 and via the directional valve 28 into the pressure medium reservoir 27.
• 2. The pressure medium displaced from the cylinder chamber 49 during the drawing process passes directly into the pressure medium reservoir 27 via the lines 43, 42, 46 with directional valves 32, 37, 28.

Fig. 8: It shows how the drawing tool is returned from its end position to the starting position after the drawing process. In this course of the process, pressure medium passes from a pressure accumulator 26 via the initial section of a line 42 and via line 43 and the directional control valve 32 as well as the channel 11 in the shaft 10b into the initially empty cylinder space 49, in order to drive the working piston 12 in one direction from there. which is opposite to the direction of pull. The pressure medium displaced from the cylinder spaces 51, 52 when the working piston is returned to its starting position can, for example return to the cylinder space 48 via the first flow path. In this context, the following should be pointed out: If, as explained above (S. ¹⁰, Zn⁸⁻¹⁰), the pressure medium is fed from the cylinder space 49 into the cylinder spaces 51, 52 during the drawing process to accelerate the drawing process, then when the drawing tool is reset, a to displace volume corresponding to the injected volume from the cylinder spaces 51, 52 into the pressure medium reservoir 27. This means that part of the pressure medium located in the cylinder spaces 50, 51, 48, that is to say in an internal communicating system, is exchanged during each drawing process. Such a partial exchange is advantageous because it prevents the temperature of the pressure medium in the cylinder spaces from rising above a critical limit and enables the pressure medium to be kept clean by filtering the portion that is exchanged.

FIGS. 5, 6 illustrate process sequences in which the drawing process takes place with the drawing punch 17 (FIG. 5) or with the sheet holder 15 stationary, so that there is no opposite movement of the sheet holder and drawing punch. Such a procedure may be required for certain difficult drawn parts. It may also be necessary to allow such a procedure to take place only in a particularly critical section of the entire drawing process, with switching between the first, second or third flow path before and after this section of the drawing process in order to save energy and to accelerate the drawing process Flow paths are changed.

5, the drawing process, driven by the external force A, is effected exclusively by the movement of the drawing ring 18, sheet metal holder 15, adapter ring 14 and annular piston 13, while the working piston is not being acted upon. This is achieved in that the pressure medium displaced from the cylinder space 48 reaches the left storage space 24a of the pressure accumulator 24 via the line 20b, the directional control valve 40 and the throttle valve 22. As a result of this feed, the piston 24c becomes after shifted to the right and displaces pressure medium from the right storage space 24b of the piston accumulator. The displaced pressure medium passes through the directional control valve 25, the line 41 into the pressure accumulator 26. If required, this can be reloaded from the pressure medium reservoir by means of the feed pump 39 via the check valve 38. With this procedure, it is necessary to refill the cylinder space 48 after each drawing operation. This is brought about in the course of a resetting process in which the pressure accumulator 26 feeds via line 41 and directional control valve 25 into the right-hand storage space 24b of the piston accumulator 24. As a result, the piston 24c is returned to its starting position under the pressure of the pressure medium on the pressure accumulator in order to displace a volume of pressure medium from the left storage space 24a which corresponds exactly to the volume of pressure medium fed there previously during the drawing process. This makes it possible to reproduce the original pressure medium volume in the cylinder space 48 when the annular piston is reset. 6, the sheet metal holder is stopped during the drawing process by shedding off the external force A, while the working piston 12 and thus the drawing punch 17 are driven and effect the drawing process. In this procedure, pressure medium is pressed into the initially empty cylinder spaces 51, 52 from a separate pressure medium source P via a check valve 53 and via a line section of line 20 of the first flow path, in order to drive the working piston 12 in the direction of pull. The pressure medium displaced from the cylinder chamber 49 reaches the pressure accumulator 26 via the directional valve 32.

The drawing tool is reset to the starting position, as described above, by introducing pressure medium from the pressure accumulator 26 into the initially empty cylinder space 49.

Fig. 7 illustrates the process for folding the remaining board 47 from the edge of the finished drawn part. For folding, the drawing punch 17 with the working piston on the one hand and the moving unit consisting of drawing ring, sheet metal holder 15 adapter ring 14 and annular piston 13 are used moved down synchronously. Here, the knife ring 16, which is arranged to be displaceable to a limited extent in the sheet metal holder 15, runs onto bolt-shaped stationary stops 16a in order to be moved over a slight distance for the work process relative to the aforementioned movement unit and thus relative to the drawn part or to the plate 47. After folding, the bending resistance in the hydraulic system suddenly disappears, which equates to a sudden drop in pressure. To dampen vibrations of the drawing tool in this regard, the outflow of the pressure medium from the cylinder 48 is throttled with the aid of the throttle valve 22 at the moment of the pressure drop as a function of the pressure sensor 21, as described above.

In the working methods shown in FIGS. 5, 6, the pressure medium filling of the cylinder space 48 (FIG. 5) or the pressure medium filling of the cylinder space 49 (FIG. 6) is displaced into the pressure accumulator 26, specifically against the pressure prevailing there. The pressure accumulator 26 is raised to a correspondingly higher pressure level. This means that the energy additionally required for pressing the pressure medium into the pressure accumulator is stored in the pressure accumulator 26 and is available again for a subsequent operation (e.g. for an operation according to FIGS. 7 and 8).

In the event of incorrect control of the directional control valves 19 or 32 or 28, a safety valve 30 in the line 44 (provided with check valves 31, 29) allows the pressure medium filling of the cylinder chamber 49 to flow into the pressure medium reservoir 27, so that no damage to the hydraulic System can arise. In conclusion, it should be pointed out that the construction shown in the illustrative embodiment can be substantially shortened by omitting the cylindrical intermediate piece 17a and / or by omitting the adapter ring 14 in the direction of the axis of symmetry. In this sense, it may also be expedient under certain circumstances to design the drive piston 12 as such at the same time as a drawing punch, so that a separate drawing punch 17 is omitted.

A major advantage of the drawing tool according to the invention is that the external force A acting on the drawing ring can be converted into a substantially larger, opposing drawing force. This results from the fact that the pressure medium displaced by the annular piston can act on the working piston 12 via an action surface which is larger than the cross section of the working piston, because the central stationary piston 10c radially engages over the surface which can be acted upon from the rear cylinder space 51 of the working piston 12. In this respect, the entire pressure surface of the working piston 12 is composed of a pressure surface on the rear and the end face of the central piston 10c. This also provides the prerequisite for the fact that, if necessary, the external force A can be converted into an opposing pulling force of the same size, but which pulling force acts on a smaller drawing piston or a smaller drawing tool.

The specific computer program initially determined empirically for each drawn part according to shape, material and depth of drawing gives the drawing device the endeavor to work at the highest possible drawing speeds without the risk of tearing. The pulling part can be torn off by means of the pressure sensor 21 by transitioning to one of the numerous flow alternatives of lower pressure or lower pulling speed (e.g. from the second flow path to the first or third flow path or from the first flow path to the third flow path) or by partially releasing pressure medium from the Avoid cylinder space 48 or 51.52 or by stopping external force A or the plunger. If, after the pressure drop occurs, the pressure in the system rises again up to the critical pressure limit due to increasing drawing resistance (forming resistance), the hydraulic system can switch from the current flow alternative to a flow alternative of even lower pressure. However, if the pressure in the system falls below a pressure limit preset in the pressure sensor 21, the system goes back to a flow alternative of higher pressure or higher drawing speed over. This can lead to a relatively rapid change in the flow alternatives as a prerequisite for a rapid cycle sequence when pulling the drawn parts.

Finally, the following should also be pointed out: in the illustrated embodiment of the hydraulic unit H, the central, stationary piston 10c is enclosed by the annular piston 13 and this by a cylinder housing 10, which cylinder housing 10 also as a cylinder block in the sense of the embodiment of FIGS. 3.4 of the generic DE-OS 36 20 876 (= US-PS 4,796,453) can be formed, which cylinder block encloses at least two ring pistons. In any case, the interconnection of stationary pistons 10c, annular piston 13 and cylinder housing 10 or cylinder block leads to such a space-saving construction of the drawing tool that it can also be operated in extremely small presses, in particular in injection molding machines. For this purpose, the hydraulic unit H is clamped in the one mold clamping plate of the injection molding machine and another unit of the drawing tool comprising the drawing ring and the sheet metal holder on the second mold clamping plate of the injection molding machine. The drawing tool therefore works with a horizontal drawing axis.

Claims (10)

1. Drawing tool for forming preferably flat sheets (plates 47) with a drawing ring (18) which can be driven by an external driving force (A), a sheet metal holder (15) which can be moved together with the drawing ring (18) as a movement unit (18, 15) and one for the deformation of the blanks (47) into the drawing ring (18) retractable drawing die (17) and with a hydraulic unit, by means of which the movement of the movement unit (18, 15) carrying the respective board (47) into a simultaneous but opposite movement of the drawing die (17) can be implemented, which hydraulic unit comprises a central working piston (12), an annular piston surrounding this (13) as well as a cylinder housing enclosing the annular piston, which can be driven indirectly by the driving force (A) and supported on the pressure medium of a cylinder chamber (48) Ring piston (13) on one side and the working piston (12) designed as a differential piston (ring part 12b) can be acted upon with pressure medium on both sides, and there s pressure medium displaced from the cylinder chamber (48) during the drawing process by the annular piston (13) drives the working piston (12) at least temporarily,
characterized in that the working piston (12) and the annular piston (17) can be acted upon from hydraulically separated cylinder spaces (51, 52 on the one hand and 48 on the other hand), via at least two alternative flow paths (first flow path via line 20; second flow path via line 20a; third) Communicate flow path via line 20b) (at least temporarily) with each other and which due to the different hydraulic design in the communicating cylinder spaces (51, 52; 48) Pulling a pressure curve at a different pressure level requires that a pressure sensor (21) is provided, which detects the pressure of the pressure medium in at least one of the two cylinder spaces (51, 52; 48) and delivers switching impulses when preset limit pressures are exceeded, and that the alternative flow paths through the switching impulses of the Pressure sensor (21) are switchable. 2. Drawing tool according to claim 1, characterized in that the cylinder spaces (51, 52; 48) delimited from the bottom of a cylinder housing (10) are hydraulically separated from one another by a separating sleeve (10a) projecting from this bottom and that the cylinder (10d) of the cylinder housing (10) guided annular piston (13) is guided by means of a radial flange (13a) overlapping the separating sleeve (13a) on the working piston (12), the inner lateral surface (13b) of the annular piston (13) being spaced from the outer lateral surface of the Separation sleeve (10a) is located. 3. Drawing tool according to claim 1 or 2, characterized in that the rear from the cylinder space (51) acted upon piston (12) can be acted upon in opposite directions from a cylinder space (49) which is located in a central recess of the cup-shaped working piston (12) and a central piston (10c) anchored in the base of the cylinder housing (10) and a ring part (12b) connected to the working piston (12), the rear cylinder space (51) communicating with a further cylinder space (52) which is connected to the base ( 12a) of the working piston (12) and the central piston (10c). 4. Drawing tool according to one of the preceding claims, characterized in that in the line (20) of the first flow path, a directional valve (34) and a pressure sensor (21), in the line (20a) of the second flow path, a controllable to different limit pressures Pressure relief valve (36) with upstream check valve (35) and in A line valve (40), a throttle valve (22) and a piston accumulator (24) acting as a hydraulic pressure intensifier are arranged in the line (20b) of the third flow path. 5. Drawing tool according to one of the preceding claims, characterized in that (to increase the speed of the drawing process) the pressure medium filling of the ring part (12b) and the central piston (10c) limited cylinder space (49) via a directional valve (19) provided line (45) can be fed into the rear cylinder space (51) of the working piston (12) and the empty cylinder space (49) can be refilled from a pressure accumulator (26) for the purpose of resetting the drawing tool in the initial position, with which resetting a volume corresponding to the volume of the cylinder space (49) Volume of pressure medium from the cylinder spaces (50, 51; 48) can be displaced into a pressure medium reservoir (27). 6. Drawing tool according to claim 5, characterized in that the right cylinder chamber (24b) of the piston accumulator (24) via a directional valve (25) provided line (41) with the connectable to all cylinder chambers of the hydraulic unit pressure accumulator (26) can be connected Which pressure accumulator (26) can be reloaded from the pressure medium reservoir (27) by means of a feed pump (39). 7. Drawing tool according to one of the preceding claims, characterized in that the working piston (12) can be driven by means of a pressure source (P) when the annular piston (13) is at a standstill and the pressure medium displaced from the cylinder space (49) via a directional valve (32) into the pressure accumulator (26) can be removed (Fig. 6). 8. Drawing tool according to one of claims 4 to 7, characterized in that the directional valve (40) and the throttle valve (22) in the line (20b) of the third flow path by means a bridging line (20b ') can be bridged, in which bridging line a check valve (23) which releases the flow in the flow direction at a predetermined pressure is arranged. 9. Drawing tool according to one of the preceding claims with a in the sheet metal holder (15) limited displaceable folding knife (16) for folding the rest of the blank from the edge of the finished drawn part, characterized in that the parts moving during the folding process (drawing ring 18, sheet metal holder 15, ring piston 13) if the bending resistance is eliminated by throttling the outflow of the pressure medium from the cylinder space (48) of the annular piston (13) into the pressure accumulator (26), it can be stopped (FIG. 7). 10. Drawing tool according to claim 9, characterized in that the outflow of the pressure medium from the cylinder chamber (48) with the aid of the throttle valve (22) arranged in the line (20b) of the third flow path as a function of the pressure drop triggered by the elimination of the folding resistor when the valve is closed Directional control valve (33) and can be throttled when the directional control valve (25) is open.

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