JPH01156018A - Control method of hydraulic press - Google Patents

Abstract

PURPOSE:To manufacture a molded product of high strength and high accuracy by applying sufficiently pressurizing force of a press to a work, by a method wherein inner pressure of a cavity is detected and control of a hydraulic press is changed over to a pressure control from speed control. CONSTITUTION:Mold clamping of a top and bottom forces 11, 12 is performed by controlling a dropping speed of a slide 6 and an SMC material filled into a cavity 13 is pressurized. A pressurizing value of the cavity 13 is detected by a mold pressure sensor 14 and changed over to pressure control at a point of time when the pressure becomes coincident with the value which is preset. Pressure of the SMC material is detected by the mold pressure sensor 14 and pressurization control is performed stepwise, in the pressure control. Control instructions are issued by a control device 28.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a method of controlling a hydraulic press for compression molding a workpiece.

(Prior Art) Hydraulic presses are well known in which a slide is moved by a hydraulic cylinder to compression mold a workpiece. This hydraulic press can be used in a variety of models depending on the material and shape of the workpiece.

-1ding compound),
For example, a hydraulic press described in JP-A-60-15119 has been used.

This conventional hydraulic press includes a base, an applied installed on the base, a crown provided on the upper part of the applied, a hydraulic cylinder provided on the crown, and supported by the lower end of the iron of the hydraulic cylinder. It has a slide that moves up and down guided by the applied, a lower mold is fixed to the upper surface of the base, an upper mold is fixed to the lower surface of the slide, and the resin is compression molded in the cavity between the upper and lower molds. It was something.

In the conventional hydraulic press, a hydraulic cylinder is controlled as shown in FIG. 7 to compression mold the SMC material. In other words, during the period from when the slide descends from top dead center to when the mold is closed (t, tz, t+), speed control is adopted in which the speed of the hydraulic cylinder is controlled in multiple stages, and the material fills the mold cavity. After that, until the compression molding is completed (
t4. ts), pressure control is adopted to keep the pressurizing force of the hydraulic cylinder constant, and the period from completion of molding to mold opening (t6.
b) had been switched to speed control again.

The switching from speed control to pressure control was performed by setting up a timer.

(Problems to be Solved by the Invention) The conventional control switching using a timer has the following problems.

□ That is, in order to perform pressure control within the range of t5 shown in Figure 7 and achieve results, it is necessary that the mold is completely filled with resin (SMC), but when switching control with a timer, Whether the mold is filled with resin or not,
Sufficient results were not obtained because the system switched to pressure control using only external (timer) control.

For example, when the setting of 13.14 shown in Fig. 7 is short, the pressure is controlled before the material is filled into the mold, so no pressure is applied to the resin in the mold, and in severe cases, short shots occur. Otherwise, problems such as chipping occurred.

On the other hand, if j3 + t4 is set too long, the resin will begin to heat and solidify after filling the mold, and some of it will have already begun to solidify, so no pressure will be applied to the resin, and molding will not be possible. In some cases, it was not possible to obtain products with sufficient strength.

SUMMARY OF THE INVENTION Accordingly, the present invention provides a control method for a hydraulic press that enables switching from speed control to pressure control at an appropriate time depending on the filling status of the workpiece in compression molding using a hydraulic press. It is characterized by

(Means for Solving the Problems) In order to solve the above problems, the present invention takes the following measures. That is, the feature of the present invention is that when at least one of a pair of molds is moved by a hydraulic cylinder and a workpiece is compression molded in a cavity between the molds, until the pressurization of the workpiece starts. In a hydraulic press control method that controls the moving speed of a hydraulic cylinder and controls the pressurizing force of the hydraulic cylinder after the start of pressurization, the switching from the speed control to pressure control is performed by detecting the pressure inside the cavity and using the detected pressure. The point is that the process is performed when the pressure and the set pressure match.

(Function) According to the present invention, the workpiece is filled into the cavity of the opened mold, the molds are brought close to each other using a hydraulic cylinder, the mold is clamped, and then the workpiece is compression molded by applying pressure. do.

The movement of the hydraulic cylinder up to the mold clamping is speed controlled,
When pressurizing, pressure control is performed.

This switching from speed control to pressure control is performed by detecting the cavity internal pressure and when this detected value matches a preset set pressure. This set value is the pressure at the time when the cavity is filled with the workpiece, and this set value is determined in advance through experiments or the like.

According to the invention, therefore, speed control is switched to pressure control once the mold cavity is filled with the workpiece.

(Example) Embodiments of the present invention will be described below based on the drawings.

What is shown in Fig. 2 is a hydraulic press for SMC, which includes a bed 1 fixed to the floor, uprights 2 erected at the four corners of the bed 1, and the upper ends of these four uprights 2. It has a crown 3 that connects and fixes the. A single-acting main cylinder 4 is attached to the center of the crown 3. A piston rod 5 of the main cylinder 4 protrudes below the crown 3, and a slide 6 is connected to the lower end of the piston rod 5. This slide 6 is guided by the four uprights 2 and is movable up and down. Also, double-acting sub-cylinders 7 are provided on both the left and right sides of the crown 3.
A piston rod 8 of this sub-cylinder 7 is connected to the slide 6.

Leveling cylinders 9 are provided at the four corners of the bed 1, and the upper end surface of the piston rod 1° of the cylinder 9 abuts on the lower surface of the slide 6 so as to be able to move toward and away from it.

An upper mold 11 is detachably attached to the lower surface of the slide 6, and a lower mold 12 is detachably attached to the upper surface of the bed 1.

The upper and lower molds 11 and 12 are configured such that a cavity 13 is formed at the mating portion of the two when the molds are clamped, and the lower mold 12 is equipped with a mold pressure sensor 14 that detects the pressure inside the cavity 13. is built-in.

A rotary encoder 15 is attached to the side surface of the bed 1, and a chino 18 is installed between a sprocket 16 attached to the input shaft of the encoder 15 and a sprocket 17 rotatably attached to the side surface of the crown 3. Both ends of the chino 18 are locked to brackets 19 attached to the slide 6. However,
The encoder 15 detects the position and moving speed of the slide 6.

An oil tank 20 is placed on the crown 3, and the oil tank 20 and the main cylinder 4 are connected via a lubricating valve 21. Further, the main cylinder 4 and the sub-cylinder 7 are connected to a pressurized cylinder hydraulic unit 25 via hydraulic pipes 22, 23, 24. Further, the leveling cylinder 9 is connected to a leveling hydraulic unit 27 via a hydraulic pipe 26.

The pressure cylinder hydraulic unit 25, the leveling hydraulic unit 27, the mold pressure sensor 14, and the row reencoder 15 are electrically connected to a control means 28.

In addition, 29 is a mold carry-out stand.

What is shown in FIG. 3 is a hydraulic circuit diagram within the pressure cylinder hydraulic unit 25.

In the same figure, 30 is an oil tank, Ml+M2
are the first and second motors for driving the hydraulic pump.

The first motor 1 drives the two speed control first and second servo pumps P and Pt, and the second motor M2 drives the third and fourth hydraulic pumps Pal and P4 and the servo hydraulic pump P. It's driving.

The discharge ports of the first to fourth pumps (pt to P4) are the first to fourth pumps (pt to P4).
They are connected to hydraulic lines 31, 32, 33, 34, respectively. The first to fourth hydraulic lines 31, 32, 33.34 are the fifth
The fifth hydraulic line 35 is connected to the sixth hydraulic line 35.
and a seventh hydraulic line 36,37. The sixth hydraulic line 36 branches into the hydraulic pipe 22 connected to the main cylinder 4 and the hydraulic pipe 23 connected to the head side of the sub cylinder 7. The seventh hydraulic line 37 is connected to the hydraulic pipe 24 connected to the rond side of the sub-cylinder 7.

A pilot hydraulic pipe 38 connected to the discharge port of the servo hydraulic pump P is indicated by a dotted line in the figure.

Remote control relief valves 39.40, 41.42 are interposed in the first to fourth hydraulic lines 31.32.33.34, respectively, and each relief valve 39.40, 41.42 is connected to a drain line 43. ing. A cooler 44 is interposed in the drain line 43.

The sixth hydraulic line 36 includes first to third on/off valves 45.
．． 46.47 are interposed. First on/off valve 45
The sixth hydraulic line 36 can be opened and closed. 2nd on
Off valve 46 opens sixth hydraulic line 36 to oil tank 30 . The third on/off valve 47 allows the main cylinder piping 22 to be opened and closed. Each of these on/off valves 45,
46 and 47 are operated by the hydraulic pressure of the pilot hydraulic pipe 38. This operation is performed by a command from the control means 28.

A sixth valve between the first on-off valve 45 and the third on-off valve 47
A pressure control valve 48 is interposed in the hydraulic line 36 . The pressure control valve 48 is capable of changing its set pressure steplessly or stepwise in response to a command from the control means 28.

The seventh hydraulic line 37 also has fourth to sixth on/off valves 49.
50.51 are interposed. Each of these on/off valves 4
9, 50, and 51 are also opened and closed by commands from the control means 28.

A check valve 52 is built into the lubricant valve 21, and the check valve 52 is turned ON and OFF by the hydraulic pressure of the pilot hydraulic pipe 38. This operation is also performed by the control means 2.
It is carried out by the command of 8.

FIG. 4 is a hydraulic circuit diagram of the leveling hydraulic unit 27, and the hydraulic oil in the oil tank 53 is supplied by a hydraulic pump P6,
It is connected to the hydraulic piping 26 which is connected to the leveling cylinder 9 through an eighth hydraulic line 54 . This eighth
A servo valve 55 is interposed in the hydraulic line 54, and the servo valve 55 is operated by a command from the control means 28. Four servo valves 55 are provided corresponding to each leveling cylinder 9.

What is shown in FIG. 5 is an operational flow diagram of the hydraulic press having the above configuration, and what is shown in FIG. 1 is an operational diagram thereof.

In these figures, 5TEP 1 indicates the starting point when the slide 6 is at the top dead center position. In this state, the cavity 13 of the lower mold 12 is filled with the SMC material 56.

Next, 5TEP 2 shows a state in which the slide 6 descends at high speed. At this time, in the hydraulic circuit diagram in Figure 3,
Hydraulic oil from the first to fourth pumps pl+Pz+P3+Pa is supplied to the first to fourth hydraulic lines 31, 32, 33, 34 and the fifth pump.
, through the hydraulic line 35, and further through the sixth hydraulic line 36, the hydraulic piping 22 of the main cylinder 4 and the sub cylinder 7.
．． 23, the main cylinder 4 and the sub cylinder 7
is supplied to At this time, the 1.3.5.6 on-off valves 45, 47, 50.51 are open, and the second and fourth on-off valves 46, 49 are closed. At this time, the oil on the rond side of the sub-cylinder 7 is returned to the tank 30 through the fifth on-off valve 5°.

5TEP 3 indicates a medium speed descending state of the slide 6, and the discharge amount of the speed control servo pumps p, , p2 is controlled by the control means 28.
By controlling this, the descending speed of the slide 6 is set to a medium speed. This switching from 5TEP 2 to 5TEP 3 is performed based on the position detection of the slide 6 by the low reencoder 15.

In 5TEP 4, speed control and leveling control are performed simultaneously. That is, based on the position detection of the slide 6 by the rotary encoder 15, 5TEP 3 to 5TEP 4
At this time, the lower surface of the slide 6 softly touches the upper end surface of the rod 1o of the leveling cylinder 9.

After that, the slide 6 is moved to the rod 1 of the leveling cylinder 9.
Descend while pressing 0. This leveling cylinder 9
Each servo valve 55 is controlled so that all four servo valves are at the same level, and the horizontality of the slide 6 is maintained with high precision.

In this 5TEP 4, speed control servo pump PI
+P2 is controlled, and the descending speed of the slide 6 is controlled in multiple stages. At the end of this 5TEP 4, the upper mold 11
When the clamping of the lower mold 12 is completed, the SM in the cavity 13 is closed.
C material 56 fills the cavity 13.

When the cavity 13 is filled with the SMC material 56, the internal pressure of the cavity 13 reaches a peak value, as shown in FIG. This pressure inside the mold is detected by a mold pressure sensor 14.

When this detected value and a preset value match, the speed control is switched to the next pressure control. This control switching is indicated by 5TEP5.

5TEP 6 indicates a state in which pressure control and leveling control are performed simultaneously.

That is, the discharge amount from the hydraulic pump is kept constant, and the pressure in the hydraulic circuit is controlled by the pressure control valve 48.

In this pressure control, a change in the state of the SMC material 56 in the cavity 13 is detected by the mold pressure sensor 14, and the pressurizing force is controlled in multiple stages (including stepless) in response to the change in state. This control command is issued by the control means 28.

When the state change of the SMC material 56 in the cavity 13 over time is known in advance, the multi-step pressure control is performed to adjust the pressure to a predetermined set pressure at predetermined intervals. This can also be achieved by multi-stage control.

In the pressure control, the leveling cylinder 9 is controlled in response to pressure changes in the main cylinder 4 and the sub cylinder 7 to maintain the slide 6 horizontally.

When the compression molding is completed, the slide 6 is slightly raised through a pressure release step, and in-mold coating is performed. This step is designated as 5TEP 7. The speed of this 5TEP 7 is controlled by a servo valve 55. When the slide is raised, the 2.3.5 on-off valves 46, 47.50 are closed, and the 1.4.6 on-off valve 45.49.51 is opened. Thus, the hydraulic fluid flows from the fifth hydraulic line 35 to the sixth and seventh hydraulic lines 36.
37, it is supplied to the cylinder side and the rond side of the sub-cylinder 7, and the sub-cylinder 7 becomes free. The oil in the main cylinder 4 is allowed to flow into the oil tank 2o via the lubricating valve 21 by operating the check valve 52 with pilot pressure.

Then, by raising the leveling cylinder 9 via the servo valve 55 of the level cylinder 9, the slide 6
is raised.

Even when the slide 6 is raised, the leveling cylinder 9 is controlled to maintain the horizontal state and raise the slide 6.

The rising speed and position of the slide 6 are detected by the low-return encoder 15 and fed back to the speed control.

When the in-mold coating is completed, the slide 6 descends again, and when it reaches a predetermined position, speed control is switched to pressure control. This switching is also performed based on pressure detection by the mold pressure sensor 14. This step is shown in 5TEP 8.

In 5TEP 8, multi-stage pressure control is performed as in 5TEP 6, including in-mold coating,
Compression molding is completed. Thereafter, after the pressure is released, the slide 6 is raised to its original top dead center. This rising process is shown after 5TEP 9, and this 5TEP9
From now on, it will be speed control. When the slide is raised after 5TEP9, the 1.3.5 on-off valves 45, 47, and 50 are closed, and the 2.4.6 on-off valves 46, 49.51 are opened. However, the hydraulic oil
The oil is supplied from the hydraulic line 35 to the rond side of the sub-cylinder 7 through the seventh hydraulic line 37 .

The oil on the cylinder head side of the sub cylinder 7 is returned to the tank 30 through the second on/off valve 46 of the sixth hydraulic line 36, and the oil in the main cylinder 4 is returned to the tank 30 by operating the check valve 52 with pilot pressure. The oil is returned to the oil tank 20 via the lubricant valve 21.

Thus, the entire process of the hydraulic press is completed.

Note that the present invention is not limited to the above embodiments,
For example, it is also possible to detect changes in the state of the material in the mold by changes in the hydraulic pressure of the main cylinder, and control the pressing force in multiple stages. Furthermore, although the position of the slide is detected using an encoder, it may also be performed using a limit switch or the like. Further, the pressure control valve may be controlled in multiple stages by using a large number of control valves with different set pressures.

(Effects of the Invention) According to the present invention, the switching from speed control to pressure control becomes appropriate, and in the subsequent pressure control, the pressing force acts sufficiently on the workpiece, improving the strength, dimensional accuracy, and It is possible to improve the performance, etc.

[Brief explanation of the drawing]

Fig. 1 is a press operation diagram showing an embodiment of multi-stage pressure control of the present invention, Fig. 2 is a partial cross-sectional front view of a hydraulic press showing an embodiment of the invention, and Fig. 3 is a hydraulic circuit of the main cylinder. Figure 4 is a hydraulic circuit diagram of the leveling cylinder, Figure 5 is an operation flow diagram of the hydraulic press according to the embodiment of the present invention, Figure 6 is a graph showing the pressure inside the mold, and Figure 7 is a conventional constant pressure. 2 is a graph showing pressure control of FIG. 4... Main cylinder, 6... Slide, 7...
Sub cylinder, 11...upper mold, 12...lower mold,
13...Cavity, 14...Mold pressure sensor, 28...
...Control means, 48...Pressure control valve, p,, p2...
・Speed control pump. Figure 6 - 1'lA- Figure 7
l, 'I IS R1, Indication of the case 1962 Patent Application No. 3164682, Name of the invention Method for controlling a hydraulic press 3, Relationship with the amended person case Patent applicant Takeda Pharmaceutical Co., Ltd. ( 1 idiot) 4. Agent ◎577 Address 1013 Mikuriya, Higashiosaka City, Osaka Prefecture March 29, 1988 6. Subject of amendment/drawing procedure amendment, spontaneous) April 26, 1988 )

Claims (1)

[Claims] (1) When at least one of a pair of molds is moved by a hydraulic cylinder and a workpiece is compression molded in the cavity between the molds, the moving speed of the hydraulic cylinder is controlled until the start of pressurization of the workpiece, In a hydraulic press control method that controls the pressurizing force of a hydraulic cylinder after pressurization starts, the switch from speed control to pressure control is performed by detecting the pressure inside the cavity and when the detected pressure and the set pressure match. A method for controlling a hydraulic press, characterized in that: