JP5443121B2 - Hydraulic press - Google Patents

Description

  The present invention relates to a hydraulic press. More specifically, the present invention relates to a compact hydraulic press that has a high working efficiency.

  The basic frame structure of the press includes a crown as an upper frame, a bed as a lower frame, and a columnar upright between them. And when a press is a hydraulic type, the pressurization cylinder which can output a desired pressurizing force is attached to a crown.

Patent Document 1 describes an example of such a hydraulic press.
As shown in FIG. 13, in the hydraulic press of Patent Document 1, a pressure cylinder 106 is attached to the crown 101, and the slide 107 is lowered by the operation of the pressure cylinder 106. The pressure cylinder 106 is a large capacity ram cylinder. Since the ram cylinder cannot be contracted by itself, a pulling cylinder 108 is connected to the slide 107. By contracting the pulling cylinder 108, the pressurizing cylinder 106 and the slide 107 are raised. Yes.

In the hydraulic press, in order to improve the working efficiency, it is necessary to move the slide down and up at high speed.
However, since the pressurizing cylinder 106 has a large capacity, in order to cover the oil amount of the entire stroke with the pump P, a pump capable of discharging a large flow rate is required. Furthermore, since the valves and pipes having a considerably large size are required in accordance with the large flow rate pump, the equipment cost becomes high.

  On the other hand, the pressurizing cylinder 106 is lowered by the weight of the rod, the slide 107, etc., and a large amount of hydraulic oil necessary for the lowering is replenished from the prefill tank 112, so that even a small flow rate pump P can operate at high speed. It is known to be able to descend. In this case, the work is pressurized by supplying pressure oil from the pump P to the pressure cylinder 106 while the slide 107 is lowered, and the slide 107 is raised by contracting the pulling cylinder 108. Is called. Then, as the slide 107 rises, the hydraulic oil in the pressure cylinder 106 is returned to the prefill tank 112.

However, there is a problem that the larger the prefill tank 112 is required as the stroke of the pressurizing cylinder 106 becomes larger, the equipment scale becomes larger and a large amount of hydraulic oil is required.
Further, when the size is increased, the amount of compressed oil in the pressurizing cylinder 106 increases, and a shock at the time of depressurization increases. Therefore, there is a problem that problems such as loosening of piping and oil leakage are likely to occur due to vibration.

Japanese Patent No. 4295601

  In view of the above circumstances, an object of the present invention is to provide a compact hydraulic press with good working efficiency.

A hydraulic press according to a first aspect of the present invention includes a mold clamping cylinder that applies a mold clamping force to a slide, and a slide lifting cylinder that raises and lowers the slide, and the mold clamping cylinder is a double-acting cylinder. and it possesses the necessary stroke, and has insertion holes are provided on the rod of the die clamping cylinder, the slide, and inserted freely stretch rod is provided in the insertion hole, for opening and closing the insertion hole And a shutter that transmits the clamping force of the clamping cylinder to the extension rod in the closed state .
Hydraulic press of the second invention, in the first shot bright, the mold clamping cylinder is a double rod type cylinder, the outer diameter of the upper rod is thin, and wherein the outer diameter of the lower rod is thick.
Hydraulic press of the third invention, in the first or second shot bright, has a pin for supporting the shutter rotatably, said shutter along the pin in the stroke direction of the clamping cylinder It is slidable and is biased upward by an elastic body.
A hydraulic press according to a fourth invention is characterized in that, in the third invention, the shutter is openable and closable by a hydraulic cylinder.
The hydraulic press according to a fifth aspect of the present invention is the hydraulic press according to the first, second, third or fourth aspect of the invention, wherein hydraulic oil is supplied and discharged in each of the mold clamping hydraulic circuit of the clamping cylinder and the lifting hydraulic circuit of the slide lifting cylinder. The pump for use is a bidirectional pump.
The hydraulic press according to a sixth aspect of the present invention is the hydraulic press according to the fifth aspect , wherein the pump of the hydraulic circuit for clamping is composed of a plurality of bidirectional pumps connected in parallel.
A hydraulic press according to a seventh aspect of the present invention includes, in the fifth or sixth aspect , a circuit switching valve that switches a supply destination and a suction source of the pressure oil of the bidirectional pump between the mold clamping cylinder and the slide lifting cylinder. It is characterized by that.

According to the first invention, the following effects are obtained.
a) The slide is moved up and down by the operation of the slide lifting cylinder, and it is not necessary to move the mold clamping cylinder. Therefore, the slide can be lowered and raised at high speed, and the working efficiency of the hydraulic press is good. Further, the mold clamping cylinder only needs to have a stroke required for mold clamping, and the oil chamber of the mold clamping cylinder can be reduced in capacity, so that a prefill tank is not required and the hydraulic press can be made compact. And since the amount of hydraulic fluid in a mold-clamping cylinder is small, the shock at the time of pressure relief can be reduced.
b) Since the clamping force of the clamping cylinder is transmitted to the extension rod when the shutter is closed, the clamping force of the clamping cylinder can be transmitted to the slide, and clamping can be performed. Further, when the shutter is opened, the extension rod can be inserted into the insertion hole, so that the slide can be moved up and down with a long stroke by the slide lifting cylinder without being affected by the clamping cylinder. Furthermore, since the extension rod is inserted into the insertion hole, the hydraulic press can be made compact.
According to the second invention, since the outer diameter of the upper rod is thin and the effective sectional area of the upper oil chamber is wide, a large mold clamping force can be output. Further, since the outer diameter of the lower rod is large and the effective cross-sectional area of the lower oil chamber is narrow, the rod of the clamping cylinder can be raised quickly. And the area which the bottom rod bottom face and a shutter contact becomes large, the pressure with respect to a shutter can be disperse | distributed, and a deformation | transformation etc. of a rod and a shutter can be made hard to produce.
According to the third invention, the insertion hole can be opened and closed by rotating the shutter around the pin. Since the shutter is slidable along the pin and is urged upward, it can follow the movement of the rod while being in contact with the bottom surface of the rod of the clamping cylinder.
According to the fourth invention, the shutter can be automatically opened and closed at a desired timing.
According to the fifth invention, since the bidirectional pump is used, a large-capacity oil tank becomes unnecessary. As a result, the hydraulic press can be made compact and the amount of hydraulic oil in the hydraulic system can be reduced.
According to the sixth invention, since a plurality of bidirectional pumps are connected in parallel, the flow rate can be increased even with a small flow bidirectional pump, and a large mold clamping cylinder can be operated.
According to the seventh invention, the bidirectional pumps used in the mold clamping cylinder and the slide elevating cylinder can be made common, and the number of bidirectional pumps can be reduced, so that the hydraulic press can be made compact.

It is a front view of the hydraulic press concerning one embodiment of the present invention, and is a figure showing when a slide is located in the upper limit. It is a front view of the same hydraulic press, and is a diagram showing a slide after a high speed descent. It is a front view of the same hydraulic press, and is a view showing when the mold is clamped. It is a front view of the same hydraulic press, and is a figure showing the time of pressure release. It is a stroke diagram of a mold clamping cylinder and a slide raising / lowering cylinder. FIG. 4 is a front sectional view of the mold clamping cylinder and the shutter in a closed state, in which FIG. (A) is a view when the mold clamping cylinder is located at the upper limit, and (B) is a view showing when the mold clamping cylinder is located at the lower limit. is there. It is a VII line arrow directional view in Drawing 6 (A). It is a hydraulic circuit diagram of the hydraulic press concerning one embodiment of the present invention, and is a figure showing at the time of high-speed fall of a slide. It is the same hydraulic circuit diagram, and is a diagram showing mold clamping. It is the same hydraulic circuit diagram, and is a figure which shows the time of pressure relief. It is the same hydraulic circuit diagram, and is a diagram showing a slide at high speed. It is a hydraulic-circuit figure of the hydraulic press which concerns on other embodiment. It is a hydraulic circuit diagram of the hydraulic press of a prior art.

Next, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, a hydraulic press A according to an embodiment of the present invention includes a crown 11 that is an upper frame, a bed 12 that is a lower frame, and a columnar upright 13 located therebetween. It has a frame structure. A mold clamping cylinder 20 and a slide lifting cylinder 30 are attached to the crown 11, and the slide 40 is lifted and lowered by their operation. An upper mold 51 is installed on the bottom surface of the slide 40, and a lower mold 52 is installed on the upper surface of the bed 12, and the mold can be clamped by applying a clamping force to the workpiece between the lower mold 52 and the upper mold 51. it can.

  The mold clamping cylinder 20 mainly plays a role of applying a mold clamping force to the slide 40. The mold clamping cylinder 20 is a large double-acting double rod cylinder and has only a stroke necessary for mold clamping as will be described later. And the outer diameter of the upper rod 21 is thin, and the outer diameter of the lower rod 22 is thick. Further, the rods 21 and 22 are provided with insertion holes 23 in the stroke direction. An extension rod 41 is provided on the upper surface of the slide 40, and the extension rod 41 can be inserted into the insertion hole 23.

The slide elevating cylinder 30 mainly plays a role of moving the slide 40 up and down at high speed. Two slide elevating cylinders 30 are provided on both sides of the mold clamping cylinder 20, are smaller than the mold clamping cylinder 20, and have a stroke capable of operating the entire stroke of the slide 40. The rod end of the slide elevating cylinder 40 is coupled to the slide 40.

  As shown in FIG. 6, a shutter 60 that opens and closes the insertion hole 23 is provided on the bottom surface of the mold clamping cylinder 20. A pin 61 is vertically provided on the bottom surface of the cylinder portion of the mold clamping cylinder 20, and the shutter 60 is rotatably supported around the pin 61. The pin 61 is longer than the thickness of the shutter 60, and the shutter 60 can slide along the pin 61. The pin 61 is provided in parallel with the stroke direction of the mold clamping cylinder 20, so that the shutter 60 can slide in the stroke direction of the mold clamping cylinder 20. Further, a spring 62 is inserted into the pin 61 below the shutter 60, and the shutter 60 is biased upward by the spring 62. Therefore, when the clamping cylinder 20 is operated in a state where the shutter 60 is in contact with the bottom surface of the lower rod 22, the shutter 60 can follow the movement of the rod while being in contact with the bottom surface of the lower rod 22.

  As shown in FIG. 7, a shutter opening / closing cylinder 63 is connected to the shutter 60, and the shutter 60 rotates around the pin 61 by opening / closing the shutter opening / closing cylinder 63, thereby opening / closing the insertion hole 23.

Next, the operation of the hydraulic press A will be described with reference to FIGS.
(1) High-speed descent FIG. 1 shows a state in which the slide 40 has reached the upper limit. From this state, the slide elevating cylinder 30 extends, and the slide 40 descends at a high speed (see FIG. 5A). The slide 40 is lowered to a stroke position before mold clamping, that is, a position just before the work is sandwiched between the dies 51 and 52 by the high speed descent. During the high speed lowering, the mold clamping cylinder 20 is not operated while being located at the upper limit, and the extension rod 41 is lowered in the insertion hole 23. The slide 40 is lowered only by the operation of the slide raising / lowering cylinder 30, and it is not necessary to move the mold clamping cylinder 20, so that the slide 40 can be lowered at high speed.

(2) Shutter closed As shown in FIG. 2, the upper end of the extension rod 41 comes out of the insertion hole 23 after being lowered at high speed. In this state, the shutter 60 is inserted between the bottom surface of the lower rod 22 and the upper end of the extension rod 41 (see FIG. 5B). When the shutter 60 is inserted and the insertion hole 23 is closed, the lower rod 22 and the extension rod 41 are connected, and the mold clamping force of the mold clamping cylinder 20 is transmitted to the slide 40 via the extension rod 41.
Note that the position of the lower rod 22 and the slide 40 is detected by a position detection device and a control device (not shown), and the opening / closing timing of the shutter 60 is controlled.

(3) Mold Clamping Next, as shown in FIG. 3, the rods 21 and 22 of the mold clamping cylinder 20 are lowered, and the mold clamping force is transmitted to the shutter 60, the extension rod 41, the slide 40, and the upper mold 51. Is performed (see FIG. 5 (3)). The mold clamping cylinder 20 can output a large mold clamping force because the outer diameter of the upper rod 21 is thin and the effective sectional area of the upper oil chamber 24 is wide. In addition, since the outer diameter of the lower rod 22 is thick, the area where the lower rod bottom surface 22 and the shutter 60 are in contact with each other is widened so that the pressure applied to the shutter 60 can be dispersed and the lower rod 22 and the shutter 60 are less likely to be deformed. be able to.

(4) Depressurization When the mold clamping is finished, as shown in FIG. 4, the rods 21 and 22 of the mold clamping cylinder 20 are lifted to perform the depressurization (see FIG. 5 (4)). Since the outer diameter of the lower rod 22 is large and the effective sectional area of the lower oil chamber 25 is narrow, the mold clamping cylinder 20 can ascend the rods 21 and 22 quickly.

(5) Shutter opening Since the lower rod 22 and the extension rod 41 are only connected via the shutter 60, the force is not transmitted when the mold clamping cylinder 20 moves up, and the slide 40 remains at the lower limit. It is. That is, there is a gap between the shutter 60 and the extension rod 41. When the mold clamping cylinder 20 reaches the upper limit, the shutter 60 is retracted and the insertion hole 23 is opened (see FIG. 5 (5)).

(6) High-speed rise Next, the slide elevating cylinder 30 contracts and the slide 40 rises at high speed (see FIG. 5 (6)). At this time, as shown in FIG. 1, since the shutter 60 is opened, the extension rod 41 can be inserted into the insertion hole 23, and the slide 40 is raised by a long stroke without being affected by the mold clamping cylinder 20. be able to. The slide 40 is raised only by the operation of the slide raising / lowering cylinder 30, and it is not necessary to move the mold clamping cylinder 20, so that the slide 40 can be raised at a high speed.

In this manner, the slide 40 is moved up and down by the operation of the slide lifting cylinder 30 and it is not necessary to move the mold clamping cylinder 20. Therefore, the slide 40 can be moved up and down at high speed, and the working efficiency of the hydraulic press is good.
Further, as shown in FIG. 5, the mold clamping cylinder 20 only needs to have a stroke necessary for mold clamping, in other words, a stroke for applying a mold clamping force across the workpiece, and the oil chamber of the mold clamping cylinder has a small capacity. Therefore, the prefill tank is unnecessary and the hydraulic press A can be made compact. Since the amount of hydraulic oil in the mold clamping cylinder 20 is small, it is possible to reduce a shock at the time of depressurization, and troubles such as loosening of pipes and oil leakage due to vibration hardly occur.
Further, since the extension rod 41 is inserted into the insertion hole 23, the hydraulic press A can be made compact.

  In this embodiment, the insertion hole 23 is provided so as to penetrate the rods 21 and 22 of the mold clamping cylinder 20. However, due to the relationship between the vertical position of the mold clamping cylinder 20 and the stroke of the slide 40, the rods 21 and 22 are attached. It is good also as the insertion hole 23 which does not penetrate. When it is not necessary to penetrate the insertion hole 23 up to the upper rod 21, the mold clamping cylinder 20 may be a piston type in which the rod projects downward. In this case, the effective cross-sectional area of the upper oil chamber 24 becomes wider, and a larger mold clamping force can be output. As a result, the mold clamping cylinder 20 itself can be made smaller.

  Further, the form of the shutter 60 is not limited to this embodiment, and the opening / closing mechanism, the mounting position, and the like should be suitable for the form of each hydraulic press as long as the insertion hole 23 can be opened and closed. Can do.

Next, the hydraulic circuit of the hydraulic press A will be described.
As shown in FIG. 8, the hydraulic circuit of the present embodiment includes a mold clamping circuit 70 that operates the mold clamping cylinder 20 and a lifting circuit 80 that operates the slide lifting cylinder 30. Bi-directional pumps 71a, 71b, 81 are used for both hydraulic circuits 70, 80 in order to supply pressure oil to the respective circuits. Since the bidirectional pumps 71a, 71b, 81 are used, both the hydraulic circuits 70, 80 are closed circuits, and the amount of hydraulic oil to be taken in / out from the oil tank T becomes small, so that a large-capacity oil tank becomes unnecessary. Therefore, the hydraulic press A can be made compact, and the amount of hydraulic oil in the hydraulic system can be reduced.

  In addition, two bidirectional pumps 71a and 71b are connected to the mold clamping circuit 70 in parallel. In general, there are two-way pumps for hydraulic presses having a relatively small capacity of several hundred tons class, but none have a capacity applicable to hydraulic presses of several thousand tons class or more. Thus, by connecting a plurality of bidirectional pumps in parallel in this way, the flow rate can be increased even with a small flow bidirectional pump, and the large mold clamping cylinder 20 can be operated.

The mold clamping circuit 70 is configured as follows.
The forward discharge port of the bidirectional pumps 71a and 71b and the upper oil chamber 24 of the clamping cylinder 20 are connected by an oil passage 72, and the reverse discharge port and the lower oil chamber 25 are connected by an oil passage 73. . An open / close valve 78 is interposed in the oil passage 73. This on-off valve 78 has two positions, an open position and a discharge prevention position, and is normally a discharge prevention position by spring biasing, but is a control valve that switches to the open position when the solenoid is excited. When the on-off valve 78 is in the discharge prevention position, the hydraulic oil is prevented from being discharged from the lower oil chamber 25 to the bidirectional pumps 71a and 71b.

  An oil tank T is connected between the oil passage 72 and the oil passage 73 via check valves 74 and 75 and relief valves 76 and 77. The check valve 74 is for supplying hydraulic oil during the forward rotation of the bidirectional pumps 71a and 71b. The relief valve 77 is for returning the excess oil at the time of reverse rotation to the oil tank T. In addition, a safety valve 79 is interposed in the oil passage 73 so that the pressure in the oil passage does not rise above a specified level.

The lifting / lowering circuit 80 is configured as follows.
The forward discharge port of the bidirectional pump 81 and the piston side oil chamber 31 of the slide elevating cylinder 30 are connected by an oil passage 82, and the reverse discharge port and the rod side oil chamber 32 are connected by an oil passage 83. . An open / close valve 88 is interposed in the oil passage 83. This on-off valve 88 has two positions, an open position and a discharge prevention position, and is normally a discharge prevention position by spring biasing, but is a control valve that switches to an open position when solenoid is excited. When the on-off valve 88 is in the discharge prevention position, the hydraulic oil is prevented from being discharged from the rod-side oil chamber 32 to the bidirectional pump 81.

  An oil tank T is connected between the oil passage 82 and the oil passage 83 via check valves 84 and 85 and relief valves 86 and 87. The check valve 84 is for supplying hydraulic oil when the bidirectional pump 81 is rotating forward. The relief valve 87 is provided to return excess oil during reverse rotation to the oil tank T. The check valve 85 and the relief valve 86 serve as a hydraulic oil flow path when the slide 40 is lowered by the mold clamping cylinder 20. In addition, a safety valve 89 is interposed in the oil passage 83 so that the pressure in the oil passage does not rise above a specified level.

Next, the operation of both hydraulic circuits 70 and 80 will be described with reference to FIGS.
(1) High-speed descent FIG. 8 shows a state in which the slide 40 has reached the upper limit. In this state, the bidirectional pump 81 connected to the lifting / lowering circuit 80 is rotated forward, and the on-off valve 88 is set to the open position. The pressure oil discharged from the bi-directional pump 81 is supplied to the piston-side oil chamber 31 of the slide elevating cylinder 30, and when the piston of the slide elevating cylinder 30 is lowered, the hydraulic oil in the rod-side oil chamber 32 is discharged. It is sucked into the pump 81.

  Here, the rod-side oil chamber 32 of the slide elevating cylinder 30 is smaller in capacity than the piston-side oil chamber 31 by the rod volume. Therefore, the amount of hydraulic oil discharged from the rod side oil chamber 32 is smaller than the amount of hydraulic oil supplied to the piston side oil chamber 31. Therefore, hydraulic oil is supplied from the oil tank T to the suction side through the check valve 84 so that the discharge amount and the suction amount of the bidirectional pump 81 are the same.

During this time, the on-off valve 78 provided in the mold clamping circuit 70 is in the discharge prevention position, and the back pressure is applied to the mold clamping cylinder 20 so as to keep it at the upper limit.
With these operations, the slide 40 is lowered at a high speed (see FIG. 5A).

(2) Shutter closing When the slide 40 finishes moving at a high speed, the bidirectional pump 81 is stopped and the shutter 60 is closed (see FIG. 5B).

(3) Mold Clamping Next, as shown in FIG. 9, the bidirectional pumps 71a and 71b connected to the mold clamping circuit 70 are rotated forward to open the on-off valve 78. The pressure oil discharged from the bidirectional pumps 71a and 71b is supplied to the upper oil chamber 24 of the clamping cylinder 20, and when the rods 21 and 22 are lowered, the hydraulic oil in the lower oil chamber 25 is discharged and the bidirectional pump 71a. , 71b.

  Here, since the outer diameter of the lower rod 22 is larger than the outer diameter of the upper rod 21, the lower oil chamber 25 has a smaller capacity than the upper oil chamber 24. Therefore, the amount of hydraulic oil discharged from the lower oil chamber 25 is smaller than the amount of hydraulic oil supplied to the upper oil chamber 24. Therefore, hydraulic oil is replenished from the oil tank T to the suction side through the check valve 74 so that the discharge amount and the suction amount of the bidirectional pumps 71a and 71b become the same.

During this time, in the lift circuit 80, although the bidirectional pump 81 is stopped, the slide 40 is lowered by the mold clamping cylinder 20, so that the piston of the cylinder lift cylinder 30 is also lowered. Therefore, the hydraulic oil is supplied from the tank T to the piston side oil chamber 31 through the check valve 85, and the working oil discharged from the rod side oil chamber 32 is returned to the tank T through the relief valve 86.
Clamping is performed by these operations (see FIG. 5 (3)).

(4) Depressurization When the mold clamping is finished, as shown in FIG. 10, the bidirectional pumps 71a and 71b are reversed to bring the on-off valve 78 into the discharge prevention position. The pressure oil discharged from the bidirectional pumps 71a and 71b is supplied to the lower oil chamber 25 of the mold clamping cylinder 20, and the hydraulic oil in the upper oil chamber 24 is discharged by the rods 21 and 22 descending, whereby the bidirectional pump. Inhaled into 71a and 71b.

Here, since the capacity of the upper oil chamber 24 is larger than that of the lower oil chamber 25, the amount of hydraulic oil discharged from the upper oil chamber 24 is larger than the amount of hydraulic oil supplied to the lower oil chamber 25. Therefore, by returning excess hydraulic oil to the tank T through the relief valve 77, the discharge amount and the suction amount of the bidirectional pumps 71a and 71b are adjusted to be the same.
During this time, the lifting / lowering circuit 80 does not operate, and the slide 40 remains at the lower limit.
The pressure is released by these operations (see FIG. 5 (4)).

(5) Shutter opening When the pressure release is finished, the bidirectional pumps 71a and 71b are stopped and the shutter 60 is opened (see FIG. 5 (5)).

(6) High-speed rise Next, as shown in FIG. 11, the bidirectional pump 81 is reversed, and the on-off valve 88 is set to the discharge prevention position. The pressure oil discharged from the bi-directional pump 81 is supplied to the rod side oil chamber 32 of the slide elevating cylinder 30, and the hydraulic oil in the upper oil chamber 31 is discharged when the piston of the slide elevating cylinder 30 moves up and down. It is sucked into the pump 81.

Here, since the piston-side oil chamber 31 has a larger capacity than the rod-side oil chamber 32, the amount of hydraulic oil discharged from the piston-side oil chamber 31 is larger than the amount of hydraulic oil supplied to the rod-side oil chamber 32. . Therefore, the excess hydraulic oil is returned to the tank T through the relief valve 87, so that the discharge amount and the suction amount of the bidirectional pump 81 are adjusted to be the same.
During this time, the on-off valve 78 of the mold clamping circuit 70 is in the discharge prevention position, and a back pressure is applied to the mold clamping cylinder 20 to keep it at the upper limit.
With these operations, the slide 40 is raised at a high speed (see FIG. 5 (6)).

(Other embodiments)
In the hydraulic circuit described above, a bidirectional pump used separately for the mold clamping circuit 70 that operates the mold clamping cylinder 20 and the lifting circuit 80 that operates the slide lifting cylinder 30 is provided separately. The mold clamping cylinder 20 and the slide elevating cylinder 30 may be operated with one bidirectional pump.

That is, as shown in FIG. 12, circuit switching valves 92 and 93 are provided on the discharge side and suction side of the bidirectional pump 91, and the supply and suction sources of the pressure oil of the bidirectional pump 91 are set as the lift circuit 70 and the mold clamping circuit 80. And switch between them.
By doing so, the number of bidirectional pumps necessary for the hydraulic press can be reduced, so that the hydraulic press can be made compact.

  The circuit switching valves 92 and 93 are connected to the mold clamping circuit 70 while the mold clamping cylinder 20 is moved up and down, and to the lift circuit 80 while the cylinder lifting cylinder 30 is moved up and down. Specifically, the above-described (2) switching from the lifting / lowering circuit 80 to the clamping circuit 70 may be performed when the shutter is closed, and (5) the switching from the clamping circuit 70 to the lifting / lowering circuit 80 may be performed when the shutter is opened.

  The hydraulic press of the present invention is mainly used for a large mold clamping apparatus. Further, in addition to a press as an independent processing machine such as a mold clamping device, it is also used as a small press incorporated in another processing machine.

A hydraulic press 20 mold clamping cylinder 23 insertion hole 30 slide lifting cylinder 40 slide 60 shutter 70 mold clamping circuit 80 lifting circuit

Claims (7)

A clamping cylinder that applies a clamping force to the slide;
A slide lifting cylinder for lifting and lowering the slide;
The mold clamping cylinder is double acting cylinder, which have a stroke required for clamping, and has insertion holes are provided on the rod of the die clamping cylinder,
The slide is provided with an extension rod that can be inserted into the insertion hole,
A hydraulic press , comprising: a shutter that opens and closes the insertion hole and transmits a clamping force of the clamping cylinder to the extension rod in a closed state . The clamping cylinder is a double rod cylinder;
The outer diameter of the upper rod is thin,
Hydraulic press according to claim 1 Symbol mounting, wherein the outside diameter of the lower rod is thick. It has a pin that rotatably supports the shutter,
The shutter, the mold clamping is slidable along the pin in the stroke direction of the cylinder, according to claim 1 or 2 SL placing hydraulic press, characterized in that it is upwardly urged by an elastic member. 4. The hydraulic press according to claim 3, wherein the shutter is openable and closable by a hydraulic cylinder. Claims 1 to 4, characterized in that the pump for the hydraulic fluid supply and discharge in each of the elevating hydraulic circuit of the hydraulic circuit for clamping cylinder mold clamping and the slide elevating cylinder is bi-directional pump The hydraulic press as described. 6. The hydraulic press according to claim 5 , wherein the pump of the mold clamping hydraulic circuit is composed of a plurality of bidirectional pumps connected in parallel. The hydraulic press according to claim 5 or 6 , further comprising a circuit switching valve for switching a supply destination and a suction source of the pressure oil of the bidirectional pump between the mold clamping cylinder and the slide elevating cylinder.

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