JP2001143855A - Method of detecting pinch of induction heating apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reliably detect pinch phenomenon, thus prevent hot metal from being separated and power source trip from occurring when heating the hot metal in the metal mixer using an induction heating apparatus. SOLUTION: In an apparatus for controlling groove type induction heating apparatus which generates an inductive current flowing a path in the hot metal by conducting the coil which occurs magnetic flux for interlinking hot metal path formed under the mixed metal furnace and hot metal path of loop shape formed by the hot metal path formed under the furnace and hot metal, the voltage and current of the coil are detected and stored, the voltage and current of the coil are detected after a predetermined time, the voltage and current are compared with the above voltage and current, and if the voltage increases and the current decreases simultaneously, pinch generation signal is outputted and the occurrence of the pinch phenomenon are detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pinch detection method in a groove type induction heating apparatus, and more particularly to a pinch detection method in a molten metal heating induction heating apparatus attached to a container for storing molten metal.

[0002]

2. Description of the Related Art For example, a mixed iron furnace is located between a mixed iron wheel and a converter and is intended to temporarily store hot metal of the mixed iron wheel. The temperature drop is caused by heat removal from the object. Therefore, as shown in FIGS. 1 and 2, the induction heating device 2 is provided in the mixed iron furnace 1, thereby performing hot metal heating. This induction heating device 2
A refractory case 4 forming a passage 3 is combined with a core 7 having a coil 6 for generating a magnetic flux interlinking a loop-shaped hot metal passage formed of the passage 3 and the hot metal 5 below the mixed-iron furnace 1. The coil 6 is energized so that the magnetic flux linked to the loop-shaped hot metal passage changes to generate an induced current passing through the passage 3 in the hot metal in the loop-shaped hot metal passage. The hot metal is heated by Joule heat based on the hot metal. In FIGS. 1 and 2, a loop-shaped hot metal passage made up of the passage 3 and the hot metal 5 is provided on both sides to form eyeglasses, but there may be only one side.

However, when a certain amount of electric power is supplied to the coil 6 of the induction heating device 2 for heating the hot metal, when the amount of hot metal in the mixed-iron furnace 1 is small or when the cross-sectional area of the hot metal in the passage 3 is reduced for some reason, Then, the pinch force due to the secondary induction current flowing through the passage 3 becomes relatively large compared to the hot metal static pressure, and the pinch phenomenon in the passage 3 becomes remarkable, and sometimes the hot metal in the passage 3 is disconnected and the induction current is interrupted. Sometimes. When the pinch phenomenon becomes remarkable, the coil 6
The fluctuation of the current flowing through the hot metal becomes so severe that it becomes impossible to stably supply the electric power necessary for heating the hot metal, and sometimes the power supply trips. Further, when the energization is stopped, the hot metal in the passage 3 starts to change from a liquid phase to a solid phase, and if it takes a long time to recover the power supply, the hot metal passage in the passage 3 may be interrupted and the reheating may not be performed.

Therefore, conventionally, the power supplied to the coil 6 is monitored by an operator via a power meter, and when the power fluctuates greatly continuously, it is determined that the above-mentioned remarkable pinch phenomenon has occurred, and the tap transformer of the tap transformer is determined. The output voltage is reduced, thereby reducing the power supplied to the coil 6 to suppress the pinch phenomenon and prevent the power supply from tripping.

FIG. 3 shows the configuration of such a conventional energizing circuit. The primary side of a tap transformer 10 is connected to a three-phase AC power source, and a coil 6 is connected between two phases on the secondary side having a tap function.
Are connected. Reactor 11a and capacitor 11 for flowing current in a balanced manner in each phase of tap transformer 10
b and a capacitor 12 for power factor improvement are connected. In order to detect the current flowing through the coil 6 and the voltage applied to the coil 6, an ammeter 15 and a voltmeter 16 are connected via a current transformer 13 and a voltage transformer 14, respectively.
3 and a power meter 17 for displaying power from the current and voltage by the voltage transformer 14 are connected.

Conventionally, as described above, the operator monitors the indication of the wattmeter 17 and operates the tap transformer 10 by judging that a remarkable pinch phenomenon has occurred in the passage 3 when it continuously fluctuates greatly. , Thereby lowering the output voltage. However, such a conventional method has a problem that the operator must constantly monitor the power meter 17 and a power supply trip occurs before the voltage of the tap transformer 10 is adjusted due to individual differences of the judgment by the operator. Or excessive adjustment of the voltage of the tap transformer 10 causes a problem that the temperature of the hot metal drops and causes a decrease in operation.

In order to solve the various problems described above, Japanese Utility Model Publication No. Hei 1-16311 calculates the impedance from the current and voltage of the coil, sets the allowable change range of the impedance in advance, and sets the allowable change range. When it is determined that a pinch phenomenon has occurred when it deviates, the power supplied to the coil is sometimes reduced.However, since the allowable change range of the impedance is determined by actual results and experiments, the allowable change range of the impedance for new equipment is easily and appropriately set. There is a problem that can not be determined. In addition, even in a normal use state in which a remarkable pinch phenomenon does not occur, there is a problem that it is difficult to determine the pinch phenomenon only by a change in the impedance because the impedance changes due to erosion or blockage of the molten steel passage.

Further, Japanese Utility Model Laid-Open No. 62-59993 discloses a method of catching a pinch phenomenon by a change in power factor. There is a problem that the power factor cannot be detected accurately and the pinch phenomenon cannot be detected accurately, that is, it cannot be applied when the power is largely changed. In addition, since the power factor of the coil itself is not detected, there is a problem that it is not possible to cope with a change in the power factor other than the coil.

[0009]

The problems in the conventional methods described in the above two publications are caused by not catching the primary phenomenon caused by the pinch phenomenon. The methods disclosed in the two publications have a disadvantage that the occurrence of the pinch phenomenon cannot be accurately grasped.

SUMMARY OF THE INVENTION The present invention has been made to solve such problems of the prior art. When the molten metal in a molten metal container such as a mixed-iron furnace is heated by an induction heating device,
An object of the present invention is to provide a pinch detection method that can prevent disconnection of a molten metal and a power supply trip due to a pinch phenomenon.

[0011]

When the pinch force due to the secondary induced current flowing through the molten metal passage becomes relatively larger than the static pressure of the molten metal, the cross-sectional area of the molten metal passage is reduced, and the current flowing through the molten metal passage is reduced. However, when the current density of the current flowing through the molten metal passage increases, the pinch force due to the secondary induction current flowing through the molten metal passage increases, and further, the cross-sectional area of the molten metal passage decreases and the molten metal passage decreases. The positive feedback acts that the current density of the current flowing through the molten metal further increases, and finally, the molten metal in the molten metal passage is separated, and a pinch phenomenon that the current cannot be supplied occurs. When this pinch phenomenon occurs, the impedance of the molten metal passage increases, and the current flowing through the coil decreases,
At the same time as the magnetic flux passing through the coil decreases, an electromotive force is generated by electromagnetic induction based on Lenz's law, and a transient phenomenon occurs in which the voltage applied to the coil increases. This transient phenomenon usually appears when a pinch phenomenon occurs with a sudden change in circuit constant.

The present invention regards this transient phenomenon as a pinch phenomenon, and comprises a molten metal loop-shaped passage formed below in a molten metal container, and a coil for generating a magnetic flux linked to the passage. In the pinch detection method of the groove-type induction heating device, in which the molten metal in the container of the molten metal is heated by Joule heat based on the induction current flowing through the passage by energizing the coil, the voltage applied to the coil and Detects the current flowing through the coil, calculates the change speed of the voltage and the current, and monitors the calculated change speed.If the voltage change speed is positive and the current change speed is negative, pinch occurrence By judging,
Detecting the occurrence of the pinch phenomenon (claim 1), detecting the voltage applied to the coil and the current flowing through the coil at a fixed period, storing the voltage and current values, and calculating the average change speed of each; If the calculated average change rate of the voltage is positive and the average change rate of the current is negative,
It is characterized in that occurrence of a pinch phenomenon is detected by determining that a pinch has occurred (claim 2).

That is, when the pinch phenomenon does not occur, the current flowing through the coil is directly proportional to the voltage applied to the coil. That is, when the voltage applied to the coil is increased by operating the tap of the tap transformer, the current flowing through the coil increases. Conversely, when the voltage applied to the coil is reduced, the current flowing through the coil decreases. However, when the pinch phenomenon occurs, an inverse proportional phenomenon occurs in which the voltage applied to the coil increases and the current flowing through the coil decreases without operating the tap of the tap transformer. Therefore, the voltage applied to the coil and the current flowing through the coil are detected, the voltage and the current value are stored, the voltage applied to the coil and the current flowing through the coil are detected after a predetermined time, and the voltage and the current are converted into the voltage and the current. When an inverse proportional phenomenon in which the voltage increases and the current decreases at the same time occurs, it is determined that the pinch phenomenon has occurred.

As a control method of the induction heating device, a pinch phenomenon is detected by the pinch detection method according to claim 1 and a pinch generation signal is output, and the tap of the tap transformer is automatically turned by a predetermined tap. To reduce the power supplied to the coil to the specified power that does not cause the separation of the molten metal and the trip of the power supply, thereby preventing the separation of the molten metal and the trip of the power supply due to the pinch phenomenon. It is.

[0015]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 4 is a circuit diagram showing an example of the configuration of an apparatus for performing the method of the present invention, which is applied to the induction heating apparatus 2 shown in FIGS. In this example, the primary side of the tap transformer 10 is connected to a three-phase AC power supply, and the coil 6 is connected between two phases on the secondary side having a tap function. A load balancer 11 composed of a reactor 11a and a capacitor 11b for flowing a current in balance with each phase of the tap transformer 10 and a capacitor 12 for improving a power factor are connected. In order to detect the current flowing through the coil 6 and the voltage applied to the coil 6, the current transformers 13
And an ammeter 15 and a voltmeter 16 via a voltage transformer 14
Are connected, and a power meter 17 for displaying power from the current and voltage by the current transformer 13 and the voltage transformer 14 is connected.

In this embodiment, the current detected by the ammeter 15 is converted into a voltage by the current-voltage converter 18, and the voltage detected by the voltmeter 16 is converted into a voltage by the voltage-voltage converter 19. Based on the voltage corresponding to the current flowing through the coil 6 and the voltage corresponding to the voltage applied to the coil 6, the arithmetic circuit 20 calculates the change in the current flowing through the coil 6 and the voltage applied to the coil 6, and the calculation result The tap of the tap transformer 10 is controlled by the control circuit 21 on the basis of the
The power supplied to the system is controlled.

That is, if a pinch phenomenon occurs in the passage 3 at time To while a certain amount of power is being supplied to the coil 6, the voltage applied to the coil 6 increases after time To as shown in FIG. When the rate of change of the voltage becomes positive, the current flowing through the coil 6 decreases (the rate of change of the current becomes negative). Therefore, in this example, the current flowing through the coil 6 and the voltage applied to the coil 6 are sampled at appropriate time intervals in the arithmetic circuit 20 via the current-voltage converter 18 and the voltage-voltage converter 19, and , The voltage applied to the coil 6 rises, and the current flowing through the coil 6 decreases. That is, in the arithmetic circuit 20, as shown in FIG.
m), I (tm), the voltage and current at time tn are V (tn), I (tn), and the allowable change range of the voltage is ΔV,
When the allowable change range of the current is ΔI, ΔV (tn) −V
(Tm)]> 2 × ΔV and ΔI (tn) −I (tm)] <− 2
It is determined whether or not × ΔI is satisfied at the same time, and when it is satisfied, it is determined that the pinch phenomenon has occurred.

In FIG. 6, when it is determined that a pinch phenomenon has occurred, a pinch occurrence signal is output to the control circuit 21, and the control circuit 21 controls the tap of the tap transformer 10 to control the output voltage. As a result, the power supplied to the coil 6 is automatically reduced, thereby preventing the separation of the molten metal and the occurrence of a power trip due to the pinch phenomenon.

As described above, according to the present invention, the arithmetic circuit 20 calculates the current flowing through the coil 6 and the change in the voltage applied to the coil 6.
The control circuit 21 controls the tap of the tap transformer 10 to control its output voltage, thereby automatically lowering the power supplied to the coil 6, thereby causing the pinch phenomenon in the passage 3. Can be effectively prevented, and therefore, the molten metal in the mixed iron furnace 1 can always be effectively heated without causing a power supply trip, and the operation can be stably performed. Also, since it is not necessary for the operator to monitor or judge the voltage adjustment,
It is also advantageous in terms of labor saving.

Next, a flow chart until the occurrence of the pinch phenomenon is detected according to the present invention will be described with reference to FIG. When heating the molten metal by supplying a constant power to the coil of the induction heating device, the voltage V and the current I applied to the coil are sampled at predetermined intervals, and the voltage V and the current I are stored. . Since the measurement of voltage and current includes a measurement error including process noise (small fluctuation of voltage and current), a change of a predetermined value or less that does not exceed the measurement error cannot be detected. The minimum value of the sampling interval is determined by how long a change exceeding this fixed value is detected, but is usually set in the range of 1 to 10 seconds. In storing V and I, the oldest is discarded and the latest is stored.

Based on the voltage V and the current I detected and stored as described above, the respective average changing speeds are calculated.
This calculation is performed by, for example, the above-described arithmetic circuit. The average change speed is calculated for each of 1 to n, and each time a pinch is determined. When the pinch is determined, the change rate of the voltage is positive and the allowable change range (ΔV:
(1% to 2% of the rated voltage) or the allowable change range (Δ
I: 1-2% of the rated current) when these two conditions are satisfied at the same time, ie,
Change rate of voltage V> 2 × ΔV and change rate of current I <−
When 2 × ΔI, it is determined that a pinch phenomenon has occurred.

FIG. 8 shows a part of a chart in which actual measurements of voltage and current are recorded when hot metal is heated by a grooved induction heating device installed in a mixed iron furnace. Pv, P in FIG.
The position of i schematically shows a state in which the pinch phenomenon has occurred, and it can be seen that the voltage suddenly increases and the current sharply decreases. This pinch phenomenon is automatically detected, and the tap of the tap transformer is controlled to reduce the power to the coil, thereby preventing the hot metal from being disconnected. By changing the sampling interval, it is possible to reliably grasp not only a sudden change in the change speed but also a gradual change in the change speed.

[0023]

As described above, according to the present invention, it is possible to automatically and reliably detect the occurrence of the pinch phenomenon that may cause the molten metal to be cut off. Accordingly, based on this detection, the power supplied to the induction heating device can be automatically reduced to a predetermined power at which the molten metal does not separate, so that the molten metal does not separate or a power trip does not occur due to a pinch phenomenon. In this way, the molten metal can always be heated effectively, so that it can operate stably.

[Brief description of the drawings]

FIG. 1 is a sectional view of an induction heating device of a mixed iron furnace.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is a configuration diagram of a conventional energizing circuit of the induction heating device.

FIG. 4 is a circuit diagram showing a configuration of an example of an apparatus for implementing the present invention.

FIG. 5 is a diagram showing an example of a pinch phenomenon.

FIG. 6 is a diagram for explaining the operation of the circuit diagram shown in FIG. 4;

FIG. 7 is a diagram showing a flowchart of a detection method according to the present invention.

FIG. 8 is a schematic diagram of a chart recording actual voltage and current measurements when hot metal is heated by a groove-type induction heating device.

[Explanation of symbols]

1: Mixed iron furnace 2: Induction heater 3: Passage 4: Case 5: Hot metal 6: Coil 7: Core 10: Tap transformer 11: Load balancer 11a: Reactor 11b: Capacitor 12: Capacitor 13: Current transformer 14: Voltage transformation Unit 15: Ammeter 16: Voltmeter 17: Wattmeter 18: Current-voltage converter 19: Voltage-voltage converter 20: Operation circuit 21: Control circuit

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) // C22B 9/22 C22B 9/22 F27D 11/06 F27D 11/06 B F term (Reference) 3K059 AA08 AB07 AB14 AB16 AC03 AC07 AC09 AC15 AC44 AC54 AC76 AD03 AD15 AD22 AD24 AD28 BD23 CD13 CD14 CD18 4K001 AA10 GA17 GB11 4K014 AD03 AD21 4K046 AA01 BA01 CD02 CD20 EA01 4K063 AA04 BA02 CA09 FA35 FA48

Claims (2)

[Claims] 1. A molten metal loop-shaped passage formed below a molten metal container, and a coil for generating a magnetic flux interlinking with the passage. In the pinch detection method of the groove-type induction heating device configured to heat the molten metal by Joule heat based on the induction current flowing through the passage, a voltage applied to the coil and a current flowing through the coil are detected, and a change in the voltage and the current is detected. Calculate the speed, monitor the calculated change speed, and if the change speed of the voltage is positive and the change speed of the current is negative, determine that the pinch has occurred by detecting the occurrence of the pinch phenomenon. A method for detecting a pinch of an induction heating device. 2. A molten metal loop-shaped passage formed below the inside of the molten metal container, and a coil for generating a magnetic flux interlinking with the passage, the coil being energized to allow the molten metal inside the container. In the pinch detection method of the groove-type induction heating device that is configured to heat the molten metal by Joule heat based on the induction current flowing through the passage, the voltage applied to the coil and the current flowing through the coil are detected at regular intervals, and the voltage and While storing the value of the current, calculate the average change speed of each, the calculated average change speed of the voltage is positive,
A pinch detection method for an induction heating device, characterized by detecting occurrence of a pinch phenomenon by determining occurrence of a pinch when an average change speed of current is negative.