EP2384834A2 - Hydraulic cylinder for a hydraulic die cushion - Google Patents

Abstract

The hydraulic cylinder has a cylinder housing (30), in which multiple hydraulic working chambers (47,48,53) are provided. A piston rod (33) is provided for connecting drawing press with a blank holder ring. The piston surfaces (49,50) are adjacent to the respective working chambers.

Description

The invention relates to a hydraulic cylinder for a hydraulic drawing cushion of a drawing press.

During the drawing process, the drawing press clamps a sheet between an upper tool and a lower tool. By a relative movement between the upper tool and lower tool, the sheet is pulled over a lower molding and pressed between two moldings. The sheet holding force required for drawing is provided by the die cushion.

A drawing pad for a drawing press, for example, in the EP 0 069 201 A2 described. The die cushion has a cylinder comprising three working chambers. Two of the working chambers operate pneumatically, while the third working chamber is designed as a hydraulic working chamber. The hydraulic working chamber serves to lock the die cushion in the lower end position and to control the upward movement of the piston rod. The two pneumatic working chambers are separated by a differential piston. During the upward movement of the piston rod, the two pneumatic working chambers are connected to each other, so that the surface difference of the differential piston is effective and moves the piston for ejecting the molded sheet metal part upwards. This movement can be controlled by the oppositely acting hydraulic pressure in the hydraulic working chamber.

Based on this, it is an object of the invention to provide a compact hydraulic cylinder for a die cushion, with which both the position of the piston rod and the force exerted by the piston rod force can be controlled or regulated.

This object is achieved by a hydraulic cylinder with the features of claim 1. The hydraulic cylinder has a cylinder housing with a plurality of working chambers. In the cylinder housing, a piston rod is slidably mounted, which protrudes on an end side of the cylinder housing. At the outer free end of the piston rod, a floating plate is fixed, on which a sheet holding ring sits. The sheet metal holding ring exerts the necessary pulling force on the sheet metal part to be formed during the drawing process.

The hydraulic cylinder has three hydraulically separated working chambers. The first and second working chamber each adjoin a first and second piston surface, respectively. Preferably, the two working chambers are separated by an annular piston. The first and second working chamber have only a small volume and serve to bring the piston rod and thus the floating plate of the lower tool in a desired position. In particular, the movement and / or the position of the piston rod is controlled or regulated by the hydraulic loading of the first and second working chambers. Because of the small first and second piston surfaces only a small volume of fluid is necessary for this purpose.

In the cylinder housing, a third piston surface is preferably provided on the inner end face of the piston rod, which is significantly larger than the first piston surface and the second piston surface. For example, the third Piston area by a factor of 3 to 10 be greater than the other two piston surfaces. The third piston surface adjoins a third working chamber, via which a sheet-metal holding force transmitted by the piston rod to the sheet-metal holding ring is set. For this purpose, the hydraulic pressure in the third working chamber is controlled or regulated to a predetermined pressure setpoint.

Both the position and / or the movement of the piston rod, as well as the sheet-holding force can be adjusted very accurately via the hydraulic working chambers, because the hydraulic medium is incompressible in contrast to gaseous media. The position or movement control of the piston rod and the regulation of the plate holding force are assigned to different working chambers. The piston area or chamber volume of the three working chambers is therefore adapted to the function associated with the working chamber. In this case, a compact construction of the hydraulic cylinder is achieved with a small diameter. An economical operation of the die cushion is ensured.

Preferably, the piston rod receiving cylinder interior of the cylinder housing is divided into two coaxial with each other arranged cylindrical sections, which merge into one another via an annular step. The first cylindrical portion of the interior has a larger diameter than the subsequent second cylindrical portion. Preferably, in the upper cylindrical portion of the annular piston is arranged, which separates this upper cylindrical portion in the first and second working chamber. In the lower cylindrical portion, the end face of the piston rod can limit the third working chamber. With such a construction, the piston rod as a compact cylindrical member can be manufactured very easily. Likewise, let the two cylindrical sections by coaxial bores with little effort in the cylinder housing bring. Since all working chambers work with the same hydraulic medium, even small leakage flows between the working chambers can be tolerated, which can be adjusted for example during prolonged operation by a certain wear of the piston seals.

The third working chamber is preferably hydraulically connected to a Nachsaugventil, which is arranged in particular parallel to a pressure control device. About the suction valve is supplied with an increase in volume of the third working chamber during the upward movement of the piston rod hydraulic medium with a low Nachsaugbetriebsdruck, for example, about 5 to 15 bar, so as not to hinder the movement of the piston rod. The suction valve locks at a pressure pickup in the third working chamber or at a reduction in volume of the third working chamber, so that then automatically connected in parallel pressure control device is effective. When the suction valve is blocked, the pressure in the third working chamber rises significantly above the secondary suction operating pressure.

A drawing press equipped with the hydraulic cylinder according to the invention can operate very economically, because only slight hydraulic volume changes in the first and second working chamber are necessary for the movement of the piston rod. About the much larger third piston surface, the necessary large Blechhaltekräfte be provided. The required pressure in the third working chamber is automatically generated by the retraction movement of the piston rod. The floating plate of the drawing press can be held by a plurality of hydraulic cylinders according to the invention. The position and / or the movement of the piston rods and / or the hydraulic pressure in the third working chambers can in the different hydraulic cylinders are independently controlled or controlled.

• Figur 1 eine schematische Darstellung einer Ziehpresse mit hydraulischem Ziehkissen,
• Figur 2 eine schematische Darstellung eines Hydraulikzylinders des Ziehkissens mit einem vereinfacht dargestellten Hydraulikkreis,
• Figur 3 ein Ausführungsbeispiel für einen an die dritte Arbeitskammer des Hydraulikzylinders angeschlossenen Hydraulikkreis in Form eines Blockschaltbilds,
• Figur 4 ein abgewandeltes Ausführungsbeispiel des an die dritte Arbeitskammer des Hydraulikzylinders angeschlossenen Hydraulikkreis in Form eines Blockschaltbilds,
• Figur 5 ein weiteres Ausführungsbeispiel des an den Hydraulikzylinder des Ziehkissens angeschlossenen Hydraulikkreises mit einem abgewandelten Druckregelventil in Form eines Blockschaltbilds und
• Figur 6 das abgewandelte Druckregelventil aus Figur 5 in Form eines Blockschaltbilds.

Advantageous embodiments of the invention will become apparent from the dependent claims and the description. The description is limited to essential features of the invention and other conditions. The drawing is to be used as a supplement. Show it:

• FIG. 1 a schematic representation of a drawing press with hydraulic drawing cushion,
• FIG. 2 a schematic representation of a hydraulic cylinder of the die cushion with a hydraulic circuit shown simplified,
• FIG. 3 an exemplary embodiment of a hydraulic circuit connected to the third working chamber of the hydraulic cylinder in the form of a block diagram,
• FIG. 4 a modified embodiment of the connected to the third working chamber of the hydraulic cylinder hydraulic circuit in the form of a block diagram,
• FIG. 5 a further embodiment of the connected to the hydraulic cylinder of the die cushion hydraulic circuit with a modified pressure control valve in the form of a block diagram and
• FIG. 6 the modified pressure control valve FIG. 5 in the form of a block diagram.

In FIG. 1 a drawing press with a press frame 11 is shown in a schematic side view. On the press frame 11, a plunger 12 is slidably mounted in a working direction A and in particular in the vertical direction. A press drive 13 serves to move the plunger 12 in the working direction A. The plunger 12, the upper tool 14 is arranged.

In the working direction A at a distance from the upper tool 14, the lower tool 15 is provided on a press table 16 of the press frame 11.

Below the press table 16, the drawing press 10 has a hydraulic die cushion 20. This comprises a floating plate 21, which is mounted in the working direction A displaceable on a cylinder assembly 22 of one or more hydraulic cylinders 23. On the cylinder assembly 22 opposite side of the floating plate 21, this is connected via push rods 24 with a blank holder ring 25. The sheet metal holding ring 25 can thus be moved together with the push rods 24 and the floating plate 21 by the action of the cylinder assembly 22. Each hydraulic cylinder 22 of the cylinder assembly 23 is connected via a first hydraulic line 26, a second hydraulic line 27 and a third hydraulic line 28 to a hydraulic circuit 29, so that hydraulic medium can be supplied to the hydraulic cylinder 22 and discharged from the hydraulic cylinder 22.

One of the hydraulic cylinders 23 of the die cushion 20 and a greatly simplified schematic representation of the connected hydraulic circuit 29 are in FIG. 2 shown. The hydraulic cylinder 23 has a cylinder housing 30 which delimits a cylinder interior 31. The cylinder interior 31 has a cylindrical passage opening 32 through which a piston rod 33, which is displaceably mounted in the cylinder housing 30, protrudes with its outer free end 34 out of the cylinder housing 30. At the outer end 34 of the piston rod 33, the floating plate 21 is attached. In the region of the passage opening 32, a first sealing arrangement is provided for the fluidic sealing of the cylinder interior 31. The passage opening 32 also serves to guide the movement of the piston rod 33 in the working direction A.

The cylinder interior 31 has, subsequent to the passage opening 32, a first cylindrical section 40 with a first diameter D1. The first cylindrical portion 40 is adjoined by a second cylindrical portion 41 having a second diameter D2. The second diameter D2 is smaller than the first diameter D1. In the preferred embodiment, the second diameter D2 corresponds to the diameter of the through-opening 32. Preferably, the piston rod 33 at least in the axial portions associated with the through-hole 32 and the second cylindrical portion 41 has a diameter that corresponds to the second diameter D2 apart from the necessary play.

The two cylindrical sections 40, 41 are connected to each other via an annular step 42. Both cylindrical sections 40, 41 are arranged coaxially to the longitudinal axis of the piston rod 33. Subsequent to the annular step 42, a second sealing arrangement 43 is provided in the inner wall of the second cylindrical section 41, which rests against the piston rod 33 in a fluid-tight manner.

In the first cylindrical portion 40, an annular piston 45 is fixed to the piston rod 33. The annular piston 45 has a piston seal 46 sealingly abutting the inner wall of the first cylindrical portion 40, whereby the first cylindrical portion 40 is fluidly divided into a first working chamber 47 and a second working chamber 48. By moving the annular piston 45, the volumes of the two working chambers 47, 48 may change, the sum of these volumes remaining constant.

The annular piston 45 has, adjacent to the first working chamber 47, a first piston surface 49 and, adjacent to the second working chamber 48, a second piston surface 50. The first and second piston surfaces 49, 50 are the same size.

In the second cylindrical portion 41, a third working chamber 53 is provided. The end face of the piston rod 33 located in the cylinder housing 30 forms a third piston surface 54, which adjoins the third working chamber 53. The surface area of the third piston surface 54 is greater than the surface area of the first and second piston surfaces 49, 50. In the exemplary embodiment, the third piston surface 54 is three to ten and preferably five times as large as the first piston surface 49 or the second piston surface 50 Radial direction measured thickness d of the annular piston 45 corresponds to the difference between the two diameters D1, D2 corresponds.

To the hydraulic circuit 29, the first working chamber 47 via the first hydraulic line 26, the second working chamber 48 via the second hydraulic line 27 and the third working chamber 53 via the third hydraulic line 28 is connected. With the first and second working chamber 47, 48, a first hydraulic circuit 55 and the third working chamber 53, a second hydraulic circuit 56 is hydraulically connected. The two hydraulic subcircuits 55, 56 are in the embodiment described here fluidly completely separated from each other.

The first hydraulic circuit 55 has a reservoir 57, from which a motor-pump unit 58 sucks in hydraulic fluid and provides via a pressure line 59. To the pressure line 59, a pressure accumulator 60 is connected, so that in the pressure line 59 is always a sufficient amount of pressurized hydraulic fluid is available. Via a connected to the pressure line 59 electrically controllable control valve 61, the pressure line 59 can be selectively connected to the first hydraulic line 26 or the second hydraulic line 27. Accordingly, a guided from the control valve 61 to the reservoir 57 return line 62 via the control valve 61 selectively connected to the first or the second hydraulic line 26 and 27 hydraulically. The second hydraulic line 27 is also connected via a pressure control valve 63 to the reservoir 57. When the pressure in the second working chamber 48 and thus in the second hydraulic line 27 exceeds a predetermined threshold, the pressure control valve 63 opens so that the hydraulic medium from the second working chamber 48 can be conveyed into the reservoir 57.

The control valve 61 is configured in the embodiment as a 4/3-way valve. It can also be replaced by other arrangements, such as 2-way cartridge valves.

In a first switching position I, the first working chamber 47 is connected via the first hydraulic line 26 to the pressure line 59, while the second working chamber 48 is connected via the second hydraulic line 27 to the return line 62. In a second switching position II the control valve 61 closes the pressure line 59 and a branch connection 27a to the second hydraulic line 27 and connects the first hydraulic line 26 to the return line 62. The third switching position III provides a hydraulic connection of the first working chamber 47 with the return line 62 and the second working chamber 48 with the Pressure line 59 ago.

The second hydraulic circuit 56 includes a hydraulic reservoir 65 connected to the third hydraulic line 28, which can be designed as a low-pressure accumulator. Via the hydraulic reservoir 65 hydraulic medium is provided under low pressure of about 5 to 15 bar. The hydraulic reservoir 65 is fluidly connected to the third hydraulic line 28 via a suction valve 66. The Nachsaugventil 66 allows in Nachsaugbetrieb a fluid flow from the hydraulic reservoir 65 into the third working chamber 53. In the reverse direction, the Nachsaugventil 66 locks in pressure control operation. Parallel to the suction valve is connected to the third hydraulic line 28, an electrically controllable pressure control device 67, via which in the third hydraulic line 28 and thus in the third working chamber 53 prevailing pressure can be controlled or regulated in pressure control mode. The pressure regulating device 67 may connect the third hydraulic line 28 for a return line 68 with a reservoir 69. For controlling the pressure control device 67 and the control valve 61 and the motor pump unit 58 is a control device 70th

In modification to the in FIG. 2 illustrated embodiment may be used for both hydraulic circuits 55, 56, a common reservoir.

About the first hydraulic circuit 55, the situation and / or the movement, for example, the position and / or the speed and / or the acceleration of the piston rod 33 controlled or regulated. In the first switching position I, the first working chamber 47 is connected to the pressure line 59, while the second working chamber 48 is connected without pressure to the reservoir 57. Due to the pressure difference on both sides of the annular piston 45, a force is exerted on the piston rod 33, which causes the piston rod 33 of the cylinder 23 to retract. In order to enable the retraction movement of the piston rod 33, the third working chamber 53 is connected by means of the controllable pressure control device 67 to the reservoir 69, so that hydraulic medium from the third working chamber 53 can be moved out.

A movement extending the piston rod 33 is effected in the third switching position III of the control valve 61. The higher pressure in the second working chamber 48 relative to the first working chamber 47 exerts on the annular piston 45 and thus the piston rod 33 in the direction of extension of the piston rod 33 directed force. As a result of the increase in volume of the third working chamber 53 taking place in this process, hydraulic medium is sucked in from the hydraulic reservoir 65 via the third hydraulic line 28 and the suction valve 66 so as not to block the movement of the piston rod 33 (re-suction operation). Because of the small first and second piston surfaces 49, 50, the volume flows necessary for moving the piston rod 33 into the first working chamber 47 and out of the second working chamber 48 or vice versa are also very low. The position or movement control of the piston rod 33 can thus be very economical. For example, pre-accelerations of the sheet-metal holding ring 25 can be generated via the control valve 61 and the first hydraulic circuit 55 in order to determine the relative speed between the upper tool 15 and Sheet holder 25 to reduce before the clash. An ejection movement of the shaped sheet metal part is also carried out via this first hydraulic circuit 55 and the first two working chambers 47, 48.

During the drawing process, the sheet metal part B to be formed has to be clamped between the sheet metal holding ring 25 and the upper tool 14 with a predetermined sheet holding force. In this clamped state, the sheet metal part B is pulled by a continued movement of the plunger 12 to the lower tool 15 over the shape of the lower tool 15 and simultaneously formed by the substantially complementary shape of the upper tool 14. The sheet holding force must be adhered to in order to ensure the quality of the forming. If the sheet holding force is too large, the sheet can enter. On the other hand, wrinkles may form in the sheet during forming when the sheet holding force is too low.

The setting of the desired and required plate holding force is performed by the second hydraulic circuit 56 and the third working chamber 53 of the hydraulic cylinder 23. First, the cylinder 23 of the cylinder assembly 22 are brought into their original position. This is done by moving the annular piston 45 by supply or removal of hydraulic medium into or out of the first and second working chamber 47, 48. The Ziekissen 20 operates in the position and / or movement control. Shortly before the upper tool 14 comes to rest with the sheet metal part B located on the sheet metal holding ring 25, an inward movement of the piston rods 33 can be brought about in order to reduce the relative speed between the ram 12 and the sheet metal holding ring 25.

As soon as the upper tool 14 rests on the sheet metal part B, the hydraulic die cushion 20 switches to a control or control of the sheet holding force. For this purpose, the control valve 61 is brought into its second switching position II, in which the first working chamber 47 connected to the return line 62 and thus is depressurized. The branch connection 27a from the second hydraulic line 27 to the control valve 61 is blocked, so that the second working chamber 48 is connected to the reservoir 57 via the pressure regulating valve 63. The press drive 13 tries to move the upper tool 14 further in the working direction A to the lower tool 15. The pressure in the second and third working chamber 48, 53 increases. Due to this pressure increase opens the pressure control valve 63, so that hydraulic medium from the second working chamber 48 can drain into the Vorrastbehälter 57. The sheet holding force is adjusted by means of the pressure control device 67 in the second hydraulic circuit 56. The pressure control device 67 is controlled via the control device 70 so that a desired pressure in the third working chamber 53 sets, which leads to the setting of the desired sheet holding force. In this way, the Blechhaltekraft remains constant even with a continued retraction of the piston rod 33. This means that during the forming of the sheet metal part B between the upper tool 14 and lower tool 15 always the desired sheet holding force is exerted by the sheet metal holding ring 25.

In a modification to this, the first hydraulic line 26 and the first working chamber 47 can be shut off in the second switching position II. In this embodiment, the pressure in the second working chamber 48 is regulated by the pressure regulating valve 63. Then a Nachsaugleitung must be connected to the first working chamber to allow a piston rod movement.

Once the forming process has been completed, the upper tool 14 can be moved away again from the lower tool 15. The Ziekissen 20 and the hydraulic cylinder 23 is then no longer regulated to set the desired sheet holding force, but is operated again in a position or position control. The first control valve 61 switches either to carry out a retraction movement of the piston rod 33 in the first switching position I or to carry out an ejection movement in its third switching position III, in which the piston rod 33 is extended and hydraulic medium is sucked into the third working chamber 53. For a sufficient Nachsaugbewegung only a low suction pressure in the range of 5 to 15 bar in the second hydraulic circuit 56 is necessary. In contrast, the pressure accumulator 60 in the first hydraulic circuit 55 for movement of the piston rod 33 a pressure in the range of about 200 bar ready to perform sufficiently fast piston rod movements can.

In the Figures 3 and 4 two embodiments for the realization of the second hydraulic circuit 56 are shown greatly simplified, with only the most important components are shown.

The second hydraulic subcircuit 56 can have its own motor-pump unit 72 for storing the hydraulic reservoir 65. The pressure control device 67 is in the embodiment according to FIG. 3 formed by a 2/2-way valve 73, which can be electrically switched by the controller 70. If the pressure in the third hydraulic line 28 and thus in the third working chamber 53 increases to a variably predefinable threshold value, the 2/2-way valve 73 is briefly opened in order to discharge hydraulic medium to the reservoir 69 and lower the pressure again. The threshold corresponds to pressure control mode the sheet metal holding force to be set. When the piston rod 33 is retracted during attitude or motion control, the pressure regulator 67 opens to permit piston rod movement.

The suction valve 66 is preferably realized by a pressure-controlled safety valve 74. Via an input 81, the suction pressure of the hydraulic reservoir 65 is applied to the plunger 75 of the safety valve 74. An output 76 of the safety valve 74 is connected to the third hydraulic line 28. The hydraulic pressure at the outlet 76 is supplied via a control line 77 to a control chamber 78 which is delimited by a control surface 79 of a piston 80 connected to the plunger 75. If the pressure in the control line 77 and thus at the output 75 is sufficiently large, the plunger is displaced by the pressure in the control chamber 78 in a closed position, whereby the input 81 is separated from the output 76 of the safety valve 74. If the pressure in the control line 77 decreases, the plunger 75 releases a connection between the inlet 81 and the outlet 76, so that pressurized hydraulic fluid can flow from the reservoir 65 via the inlet 81 and the outlet 76 into the third hydraulic line 28. If the pressure then increases sufficiently at the output 76 and thus in the control line 77, the safety valve 74 closes again. In this way, the suction of hydraulic fluid is realized in an extension movement of the piston rod 33 in the third working chamber. During pressure control, the hydraulic pressure in the third working chamber 53 is sufficiently great to maintain the safety valve 74 in the closed position. Hydraulic fluid can from the second hydraulic line 28 then only via the pressure control device 77 and beispielsgemäß the 2/2-way valve 73 off.

In FIG. 4 a modified embodiment of the second hydraulic circuit 56 is shown, in which an energy recovery by a generator operation of the motor-pump unit 72 is provided. Instead of the 2/2-way valve, for example, a 4/2-way valve 82 can be used as a pressure control device 67. The motor-pump unit 72 sits in the return line 68. The return line 68 branches at the 4/2-way valve 82 and is connected to two terminals. On the other side of the 4/2-way valve 82, a supply line 83 is led to the input 81 of the safety valve 74 and simultaneously to the hydraulic reservoir 65, while the other terminal is connected to the third hydraulic line 28. In a switching position, the supply line 83 is connected to the motor-pump unit 72, whereas the connection to the third hydraulic line 28 is shut off. In the other switching position, the connection between the supply line 83 and the motor-pump unit 72 is interrupted while the motor-pump unit is connected to the third hydraulic line 28.

When established connection between the motor-pump unit 72 and the supply line 83, the hydraulic reservoir 65 can be stored with pressurized hydraulic medium. From the third working chamber 53, no hydraulic medium can flow off via the third hydraulic line 28, since the connection to the return line 68 is shut off and the safety valve 74 does not allow any hydraulic return flow. In the other switching position, the connection of the motor-pump unit 72 with the hydraulic reservoir 65 and the safety valve 74 is inhibited and hydraulic medium can be used to reduce the pressure in the third working chamber 53 via the third hydraulic line 28, the Drain line 68 and the pump of the motor-pump unit 72 back into the reservoir 69. The backflowing hydraulic medium drives the pump. The motor designed as an electric motor can thereby generate electricity in the generator mode and store for example in a battery. In this way, the energy efficiency of the die cushion 20 and the drawing press 10 is further improved.

In modification to the in FIG. 4 In the embodiment shown, a connecting line with a regulating valve between the third hydraulic line 28 and the reservoir 69 may be present in parallel with the pressure regulating device 67, as shown in FIG FIG. 3 is shown. The fluid flow from the third working chamber 53 can then be controlled independently of the motor-pump unit.

If the cylinder arrangement 22 of the die cushion 20 has a plurality of hydraulic cylinders 23, these can be controlled independently of one another. In this way it is possible to adjust 25 different positions and / or movement and / or Blechhaltekräfte at different points of the sheet metal retaining ring. This may be required in complex forming processes, for example in automotive body parts.

In FIG. 5 a modified embodiment of the first hydraulic circuit 55 is illustrated. The hydraulic cylinder and the second hydraulic circuit 56 correspond to the embodiment according to FIG. 2 , Instead of the pressure regulating valve 63, a pressure regulating device 64 is provided, which is inserted into a connecting line 85 between the first hydraulic line 26 and the second hydraulic line 27. The pressure control device 64 is actuated via the control device 70. A detailed illustration of the pressure control device 63 is shown in FIG FIG. 6 to see. In the connecting line 85 between the first and second hydraulic line 26, 27, a main valve, such as cartridge valve 86 is interposed, with its input 87 to the second hydraulic line 27 and its output 88 is connected to the first hydraulic line 26. A pressure limiting valve 89 is connected on the input side to the second hydraulic line 27 and on the output side to the reservoir 57. The control input 90 of the pressure relief valve 89 is fluidly shorted to its input side. The input side of the pressure relief valve 89 is further connected to a control input 91 of the cartridge valve 86. If the pressure in the second working chamber 48 rises due to a retraction movement of the piston rod 33 via the switching threshold of the pressure limiting valve 89, the cartridge valve 86 is opened via the control input 91 and the connection in the connecting line 85 is released. As a result, the hydraulic fluid is diverted from the second working chamber 48 via the connecting line 85 into the first working chamber 47. A supply of hydraulic fluid is not required here. The control valve 61 is located in a modified second switching position II, in which all lines are shut off by the control valve 61 (see FIG. 5 ).

Optionally, parallel to the pressure limiting valve 89, an additional directional valve 92 may be connected, which is controlled by the control device 70. This directional control valve 92 is in the preferred embodiment after FIG. 6 designed as a 4/2-way valve. The directional control valve could alternatively be designed as a 2/2-way valve. In its rest position locks the directional control valve 92, while it short-circuits the pressure limiting valve 89 between its input and output in its activated switching position. Such a fluidic short circuit leads to a reduction the pressure at the control input 91 of the cartridge valve 86 and establishes the fluidic connection of the two working chambers 47, 48 via the then open connection line 85. By opening the directional valve 92, the influence of the plate holding force by occurring pressures in the working chambers 47, 48 can be significantly reduced during the drawing process. The control signal for activating the directional control valve 92 and thus for establishing the hydraulic connection between the two working chambers 47, 48 takes place by means of a triggering event. By way of example, the triggering of a pressure gradient threshold value in the second working chamber 48 can be used as a triggering event. Alternatively or additionally, one or more position values of the press ram can also represent a triggering event.

The hydraulic cylinder 23 has a first working chamber 47, a second working chamber 48 and a third working chamber 53. An annular piston 45 with a first piston surface 49 and a second piston surface 50 separates the first Working chamber 47 of the second working chamber 48. The first and the second piston surface 49, 50 are the same size. An end face of the piston rod 33 arranged in the cylinder housing 30 forms a third piston surface 54, which is larger than the first and the second piston surfaces. The third piston surface 54 bounds the third working chamber 53 of the hydraulic cylinder 23. The first and the second working chamber 47, 48 are provided for controlling the position and / or the movement of the piston rod 33. The third working chamber 53 serves to control or regulate the set on the piston rod 33 on the drawing press 10 Blechhaltekraft. The sheet holding force is set by the control of the hydraulic pressure in the third working chamber 53. This results in a compact hydraulic cylinder 23 with two working chambers 47, 48 for position and / or movement control of the piston rod 33 and with a pressure-controlled further working chamber 53 for setting a sheet holding force. All functions of the die cushion 20 are therefore combined in a hydraulic cylinder 23 and by the separation into different working chambers 47, 48 and 53, respectively, simple and economically feasible.

LIST OF REFERENCE NUMBERS

10

drawing press

11

press frame

12

tappet

13

press drive

14

upper tool

15

lower tool

16

press table

20

hydraulic cushions

21

floating plate

22

cylinder arrangement

23

hydraulic cylinders

24

push rods

25

Sheet holding ring

26

first hydraulic line

27

second hydraulic line

27a

branch connection

28

third hydraulic line

29

hydraulic circuit

30

cylinder housing

31

Cylinder interior

32

cylindrical passage opening

33

piston rod

34

outer free end v. 33

35

first seal arrangement

40

first cylindrical section v. 31

41

second cylindrical section v. 31

42

annular step

43

second seal arrangement

45

annular piston

46

piston seal

47

first working chamber

48

second working chamber

49

first piston surface

50

second piston surface

53

third working chamber

54

third piston area

55

first hydraulic circuit

56

second hydraulic subcircuit

57

reservoir

58

Motor-pump unit v. 55

59

pressure line

60

accumulator

61

control valve

62

Return line

63

Pressure control valve

64

Pressure control device

65

hydraulic reservoir

66

cavitation valve

67

Pressure control device

68

Return line

69

reservoir

70

control device

72

Motor-pump unit v. 56

73

2/2 way valve

74

safety valve

75

tappet

76

output

77

control line

78

control chamber

79

control surface

80

piston

81

entrance

82

4/2-way valve

83

supply line

85

connecting line

86

cartridge valve

87

Entrance v. 86

88

Output v. 86

89

Druckbegnezungsventil

90

Control input v. 89

91

Control input v. 86

92

way valve

A

working direction

B

sheet metal part

D1

first diameter

D2

second diameter

d

Thickness v. 45

I

first switching position v. 61

II

second switching position v. 61

III

third switching position v. 61

Claims (10)

Hydraulic cylinder for a hydraulic drawing cushion (20) of a drawing press (10),
with a cylinder housing (30) in which a plurality of hydraulic working chambers (47, 48, 53) are provided,
a piston rod (33) for connection to a sheet-metal holding ring (25) of the drawing press (10),
with a first piston surface (49) adjoining a first working chamber (47) and a second piston surface (50) adjoining a second working chamber (48), wherein the first piston surface (49) and the second piston surface (50) are substantially equal .
and a third piston surface (54) larger than the first and second piston surfaces (49, 50) and adjacent to a third working chamber (53). Hydraulic cylinder according to claim 1,
characterized in that the third piston surface (54) is larger by a factor in the range of 3 to 10 than the first and second piston surfaces (49, 50). Hydraulic cylinder according to claim 1,
characterized in that an end face of the piston rod (33) forms the third piston surface (54). Hydraulic cylinder according to claim 1,
characterized in that between the first working chamber (47) and the second working chamber (48) an annular piston (45) is arranged, which surrounds the piston rod (33) in an annular manner. Hydraulic cylinder according to claim 1,
characterized in that the cylinder housing (30) defines a cylinder interior (31) having a first diameter (D1) having a first cylindrical portion (40) and a second diameter (D2) having a second cylindrical portion (41). Hydraulic cylinder according to claim 5,
characterized in that the first and second working chambers (47, 48) in the first cylindrical portion (40) and the third working chamber (53) in the second cylindrical portion (41) is arranged. Hydraulic cylinder according to claim 1,
characterized in that the third working chamber (53) is hydraulically connected to an electrically controllable pressure regulating device (67). Hydraulic cylinder according to claim 1,
characterized in that the third working chamber (53) is hydraulically connected to a suction valve (66). Hydraulic cylinder according to claim 1,
characterized in that the Nachsaugventil (66) is hydraulically connected to a hydraulic reservoir (65) which provides a pressure in the range of 5 bar to 15 bar. Hydraulic drawing cushion of a drawing press (10), for one,
with a hydraulic cylinder (23), which is a cylinder housing (30) and a piston rod (33) which is connected to a sheet metal holding ring (25) of the drawing press (10),
with a plurality of hydraulic working chambers (47, 48, 53) provided in the cylinder housing (30),
wherein a first piston surface (49) abuts a first working chamber (47) and a second piston surface (50) abuts a second working chamber (48), and wherein the first piston surface (49) and the second piston surface (50) are substantially equal in size are,
and a third piston surface (54) larger than the first and second piston surfaces (49, 50) and adjacent to a third working chamber (53).

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