JPH07116802A - Device for oscillating mold in continuous casting equipment - Google Patents

Abstract

PURPOSE:To execute a stable control having very good precision by adopting a feed forward compensation and having a learning function in consideration of the difference between an aimed waveform and the actual oscillating waveform. CONSTITUTION:In an oscillating device for oscillating a mold 1 with an electrohydraulic stepping cylinder 5 through link mechanism 3, at the time of outputting a driving signal to a driving unit 26 of the electrohydraulic stepping cylinder 5, compensating signals for cancelling an operating delay of the electrohydraulic stepping cylinder 5 and a moving transferring delay caused by the deformation of the link mechanism 3, etc., are added to the aimed waveform signal of the mold 1 to execute the feed forward compensation. Further, the actual oscillating waveform of the mold 1 is periodically detected and also, the difference with the aimed waveform is obtd. and a learning circuit 35 for adding this difference signal to the aimed waveform signal is provided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mold vibrating device for continuous casting equipment.

[0002]

2. Description of the Related Art A mold in a continuous casting facility is vibrated by a vibrating device. Conventionally, a vibrating device of this type is disclosed in Japanese Patent Laid-Open No. 63-63562.

That is, in this Japanese Laid-Open Patent Publication No. 63-63562, the mold is supported by a four-sided link and a beam so that it can be moved up and down in a vertical plane.
A hydraulic cylinder for vibrating the mold is connected to the tip of the beam, and a hydraulic circuit for the hydraulic cylinder includes a servo valve and a control circuit for controlling the servo valve.

In this control circuit, the rod position of the hydraulic cylinder and the acceleration of the mold are respectively detected by the sensors, and the detected values are fed back so that the vibration of the mold becomes a predetermined vibration waveform. Therefore, the vibration transmission characteristic is improved.

The reason why it is necessary to improve the vibration transmission characteristics in this way is as follows. That is, recently, in order to improve the quality of the surface of a slab produced by continuous casting, it has been attempted to generate a sawtooth-like vibration waveform in the mold in which the mold rises slowly and the mold descends quickly. . In addition, such a sawtooth-shaped non-sine waveform includes second-order, third-order, and other harmonic components, and under certain vibration conditions, this harmonic component
A mechanical supporting structure such as a beam that supports the entire mold resonates and a predetermined vibration waveform cannot be obtained. This is to prevent this.

[0006]

According to the above configuration,
Although the rod position of the hydraulic cylinder and the acceleration of the mold itself are detected and these detected values are fed back to obtain a predetermined vibration waveform, the control target is complicated and the sensor mounting location However, there is a problem that it is difficult to obtain a predetermined vibration waveform.

Further, in continuous casting equipment, the environmental conditions are poor, so the sensor is prone to failure. Therefore, when the sensor fails, the hydraulic cylinder runs out of control, so vibration is stopped, that is, casting is stopped. It is necessary, and there is a problem that the pot is returned and scraps are generated, resulting in waste.

Therefore, it is an object of the present invention to provide a mold vibrating device in a continuous casting facility which can solve the above problems.

[0009]

In order to solve the above-mentioned problems, a mold vibrating device in a continuous casting facility of the present invention comprises a support structure for mechanically supporting the mold, and a vibration to the mold via the support structure. And a hydraulic unit that supplies hydraulic oil to the hydraulic actuator via a hydraulic circuit, and a control unit for outputting a drive control signal to the drive unit of the hydraulic actuator. , A target waveform signal generator for generating a target waveform signal of the mold, and a target waveform signal output from the target waveform signal generator, a mechanical system compensation waveform for canceling a motion transmission delay due to elastic deformation of the support structure. Signal and the hydraulic system compensating waveform signal for improving the waveform disturbance due to the operation delay of the hydraulic actuator. Of the feed forward signal generator and the displacement detector for detecting the displacement of the mold, and calculates the difference between this detection signal and the target waveform signal output from the target waveform signal generator. And a learning circuit for adding the subtracted deviation signal to the target waveform signal.

[0010]

According to the above construction, when a predetermined vibration waveform is applied to the mold by the hydraulic actuator via the support structure, the motion transmission delay due to the elastic deformation of the support structure and the operation delay of the hydraulic actuator are canceled. The feed-forward compensation control that adds the compensation waveform signal of is adopted and the learning circuit that corrects the difference between the actual vibration waveform of the mold and the target waveform signal is provided, so the deviation of the actual vibration waveform of the mold is corrected. Therefore, accurate control that is strong against disturbance can be performed.

Further, since the position sensor in the hydraulic actuator is not used for control, there is no need to worry about the runaway of the hydraulic actuator which occurs when the position sensor fails.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. In FIG. 1, 1 is a mold in a continuous casting facility, which is placed on a table 2. And
The mold 1 is swingably supported on a gantry 4 in a vertical plane via a table 2 and a link mechanism 3, and is connected to the link mechanism 3 by an electrohydraulic stepping cylinder (an example of a hydraulic actuator). ) 5 vibrates vertically.

That is, the link mechanism 3 is composed of an upper link 11 and a lower link 12, one end of each of the upper and lower links 11, 12 is pin-connected to the table 2 side, and the upper link 11 has the same structure. The other end and the intermediate portion of the lower link 12 are supported on the gantry 4 side via pins, respectively, and the other end of the lower link 12 is pin-connected to the rod portion 5a of the electrohydraulic stepping cylinder 5. .

A hydraulic unit 21 for supplying hydraulic oil is connected to the electro-hydraulic stepping cylinder 5 via a hydraulic pipe 22, and the hydraulic unit 21 is connected to the hydraulic unit 21.
An electric stepping motor (an example of a driving unit) 25 for moving a spool 24 for supplying a predetermined amount of hydraulic oil from the inside of the cylinder chamber 23 is provided, and a drive unit 26 for driving the stepping motor 25 is further provided. It is equipped.

Then, a control unit (a high speed digital controller is used) 27 for controlling the drive unit 26 of the electrohydraulic stepping cylinder 5
Is provided.

That is, the control unit 27 uses the target waveform signal generator 31 for generating the target waveform signal of the mold 1, the target waveform signal output from the target waveform signal generator 31, the link mechanism 3 and the table 2. And a mechanical system compensation signal generator 32 for adding a compensation waveform signal for canceling the motion transmission delay due to elastic deformation in the mechanical support structure including the mechanical system compensation signal generator 32.
Mounted on the mold 1 and a hydraulic system compensation signal generator 33 for adding a compensation waveform signal for improving the waveform disturbance due to the operation delay of the electrohydraulic stepping cylinder 5 to the waveform signal from the mold 1 (for example, a table). It may be attached to the second side) A detection signal from a displacement detector (for example, an acceleration sensor, a position sensor or the like is used) 34 that detects the displacement of the mold 1 is input and converted into a position signal, and the target A learning circuit 35 that subtracts the position signal from the target waveform signal output from the waveform signal generator 31 and adds the deviation signal obtained by this subtraction to the target waveform signal, and outputs from the target waveform signal generator 31. The compensation signals output from the compensation signal generators 32 and 33 are added to the target waveform signal and the addition component waveform signal obtained by learning. Enter a motion signal and a pulse converter 36 for outputting a pulse signal to the drive unit 26. The mechanical system compensation signal generator 32 and the hydraulic system compensation signal generator 33 constitute a feedforward signal generator.

The learning circuit 35 samples the detection signal (for example, the acceleration signal or the position signal) from the displacement detector 34 attached to the mold 1 for every predetermined period, for example, for two to three cycles. The data reading unit 41 to be read and the detection signal read by the data reading unit 41 are converted into position signals (however, conversion is performed in the case of acceleration signals) and frequency analysis of the position signals (specifically, Data analysis unit 42 for performing Fourier series conversion)
It consists of and.

Incidentally, in the middle of the output system from the data analysis unit 42, an abnormality judgment unit 43 for judging an abnormality of the signal output from the data analysis unit 42, and this abnormality judgment unit 43.
A signal switch 44 is provided for shutting off the output of the signal when it is determined that the signal is abnormal.

In the above configuration, the target waveform signal output from the target waveform signal generator 31 of the mold 1 is (x
₀ ), the deviation signal output from the learning circuit 35 is (Δx
₀ ), the waveform signal (x) input to the feedforward signal generator, that is, the mechanical system compensation signal generator 32 is (x ₀ + Δx ₀ ). For example, the waveform signal (x) is represented by a function such as Fourier series.

Further, in the feedforward signal generator, in order to improve the compensation signal (Δx ₁ ) for canceling the signal transmission delay due to the elastic deformation in the mechanical support structure and the operation delay of the electrohydraulic stepping cylinder 5. The compensation signal (Δx ₂ ) is calculated. The compensation signal (Δx ₁ + Δx ₂ ) is a compensation component that is theoretically obtained so that the mold 1 has the same waveform as the predetermined target vibration waveform, and is the input of the electrohydraulic stepping cylinder 5 and the mechanical support structure. It can be obtained by the reciprocal of the transfer function between the output from and. This compensation component is also given by a function such as Fourier series, and a time value is given and output as position data.

Therefore, the drive unit 26 for actually driving the electrohydraulic stepping cylinder 5 is described.
The drive signal input to is given by (x + Δx ₁ + Δx ₂ ).

Here, the feedforward control will be specifically described. First, regarding the mechanical support structure,
Since the output waveform component of the rod portion 5a of the electrohydraulic stepping cylinder 5 includes a higher-order component because it is not a completely rigid body, the mechanical support structure, for example, the link mechanism 3 or the like may cause a resonance phenomenon due to the component. Wake up.

In particular, when the signal waveform is a non-sine waveform such as a sawtooth shape, the target waveform signal itself contains a considerable amount of high-order components, so that resonance is likely to occur. Therefore, the electro-hydraulic stepping cylinder 5 is made to output a waveform signal containing a signal component that cancels the resonance of the mechanical support structure including the link mechanism 3, the table 2, and the like.

Next, in the electrohydraulic stepping cylinder 5, the operation delay of the hydraulic system is compensated. That is,
The movement of the rod portion 5a is controlled by controlling the movement of the valve and the spool 24.
In order to move at a predetermined speed, it is necessary that the opening degree of the valve be equal to or larger than a certain value, so that an operation delay (phase delay) occurs between the input and the output. This operation delay is eliminated, and the input waveform is compensated so that the output waveform of the electro-hydraulic stepping cylinder 5 has the same phase and the same waveform as the predetermined waveform.

That is, in the compensation signal (Δx ₁ )
The compensation signal (Δx ₂ ) includes a signal component for canceling the resonance generated in the mechanical support structure such as the link mechanism 3 and the table 2, and the compensation signal (Δx ₂ ) includes an operation delay generated by the electrohydraulic stepping cylinder 5. A signal component for improvement is included.

2 to 6 show comparative examples of the vibration waveforms of the mold with and without the feedforward compensation and learning circuit described above. 2 shows a case without feedforward compensation, FIG. 3 shows a case with feedforward compensation and no learning, FIG. 4 shows a case where learning is performed once, and FIG. 5 shows learning three times. FIG. 6 shows the case where the learning is performed 6 times. The vibration conditions in this case were an amplitude of 1 mm and a frequency of 340 cpm.

Further, in the curves of each figure, the solid line shows the displacement of the mold, the broken line shows the displacement of the rod portion of the electrohydraulic stepping cylinder, and the chain double-dashed line shows the shaft rotation angle of the stepping motor.

As is apparent from FIGS. 2 to 6, the mold displacement is saw-toothed in the case where the feedforward compensation is provided, as compared with the case where the feedforward compensation is not provided, and as the learning progresses, It can be seen that the waveform signal indicating the displacement of the mold has a more beautiful sawtooth waveform.

As described above, since the feedforward compensation is adopted and the learning circuit 35 for correcting the deviation based on the actual displacement (position) of the mold 1 is provided, for example, as described in the conventional example. In addition, a position detection sensor for detecting the position of the rod portion of the electro-hydraulic stepping cylinder can be made unnecessary, and the deviation between the actual vibration waveform of the mold 1 and the target waveform that cannot be solved only by the feedforward compensation can be corrected. Can
Therefore, it is possible to perform accurate control that is resistant to disturbance.

Further, since the position sensor for detecting the position of the electro-hydraulic stepping cylinder can be dispensed with, there is no need to worry about the runaway of the electro-hydraulic stepping cylinder, which may occur when the position sensor fails.

When the displacement detector for detecting the displacement of the mold fails, the abnormality judging section 43 detects it and activates the signal switch 44 to stop the function of the learning circuit 35. The vibration of the mold is continued only by the feedforward compensation function.

Further, in the above embodiment, since the detected signal is subjected to digital processing such as Fourier series expansion, it becomes easier to remove the noise component as compared with the analog signal as in the conventional feedback control.

By the way, in the above-mentioned embodiment, the mold is explained to vibrate through the table and the link mechanism. However, for example, a table supporting the mold is directly connected to a hydraulic actuator such as a hydraulic cylinder. May be. In this case, a table is considered as the mechanical support structure for signal transmission.

Further, in the above embodiment, the electro-hydraulic stepping cylinder is used as the hydraulic actuator and the electric stepping motor is used as the driving unit. However, instead of the electric stepping motor, for example, an electric servo is used. An electric oil cylinder using a motor may be used. Further, a hydraulic servo cylinder using a hydraulic servo valve may be used.

Furthermore, in the above embodiment, the displacement detector 34 is explained as being attached to the mold 1, but it may be attached to the table 2 side, for example, and as shown by the phantom line in FIG. You may make it attach to the edge part of 3.

[0036]

As described above, according to the configuration of the present invention, when a predetermined vibration waveform, that is, a target waveform is applied to the mold by the hydraulic actuator via the support structure, the operation delay of the hydraulic actuator and the support structure are provided. Since the feedforward compensation that adds the compensation signal for canceling the motion transmission delay due to the elastic deformation of is adopted, and the learning circuit that periodically corrects the difference between the actual vibration waveform of the mold and the target waveform signal, The deviation of the actual vibration waveform of the mold can be corrected, and therefore accurate and stable control that is strong against disturbance can be performed.

Further, since the position sensor in the hydraulic actuator is not necessary, it is not necessary to worry about the hydraulic actuator going out of control, which would occur if the position sensor were to fail, thus preventing the occurrence of scrap or the like due to casting stoppage. You can

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of a mold vibrating device according to an embodiment of the present invention.

FIG. 2 is a diagram showing an output waveform of a mold when there is no feedforward compensation in the embodiment.

FIG. 3 is a diagram showing an output waveform of a mold when there is only feedforward compensation of the embodiment.

FIG. 4 is a diagram showing an output waveform of a mold when the feedforward compensation and learning functions of the embodiment are provided.

FIG. 5 is a diagram showing an output waveform of a mold when the feedforward compensation and learning functions of the embodiment are provided.

FIG. 6 is a diagram showing an output waveform of a mold in the case where the feedforward compensation and learning functions of the embodiment are provided.

[Explanation of symbols]

 1 Mold 2 Table 3 Link Mechanism 5 Electro-hydraulic Stepping Cylinder 21 Hydraulic Unit 25 Stepping Motor 26 Drive Unit 27 Control Unit 31 Target Waveform Position Signal Generator 32 Mechanical System Compensation Signal Generator 33 Hydraulic System Compensation Signal Generator 34 Displacement Detector 35 Learning circuit

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Masato Aoki 5-3-8 Nishikujo 5-chome, Konohana-ku, Osaka City, Osaka Prefecture Hitachi Shipbuilding Co., Ltd.

Claims (1)

[Claims] 1. A support structure for mechanically supporting a mold, a hydraulic actuator for vibrating the mold via the support structure, and a hydraulic unit for supplying hydraulic oil to the hydraulic actuator via a hydraulic circuit. , A control unit for outputting a drive control signal to the drive unit of the hydraulic actuator, and the control unit includes a target waveform signal generating unit for generating a target waveform signal of the mold and the target waveform signal generating unit. A mechanical system compensation waveform signal for canceling the motion transmission delay due to elastic deformation of the support structure and a hydraulic system compensation waveform signal for improving the waveform disturbance due to the operation delay of the hydraulic actuator are added to the output target waveform signal. Detection signal from the displacement detector that detects the displacement of the mold and the feedforward signal generator for A learning circuit for inputting, calculating the difference between the detection signal and the target waveform signal output from the target waveform signal generating section, and adding the subtracted deviation signal to the target waveform signal. Mold vibration device for continuous casting equipment.