JP2021042464A - Control method of continuous heat treatment facility - Google Patents

Abstract

To provide a control method of a continuous heat treatment facility capable of improving temperature uniformity in the width direction in total.SOLUTION: A continuous heat treatment facility 1 includes: a first heating section, a second heating section, and a third heating section, which are arranged along a metal member conveying direction F; a control section for controlling first output power, second output power, and third output power output to the first heating section, the second heating section, and the third heating section, respectively; and a first measurement section for measuring a first voltage and a first current in the first heating section. The first heating section, the second heating section, and the third heating section are solenoid-type induction heating, transverse-type induction heating, and resistance heating, respectively. The control section reasonably proportionally divides the output shares of each heating section, calculates an equivalent impedance in a parallel resonance circuit based on the first voltage and the first current. When the equivalent impedance becomes larger than a threshold value, the first output power is controlled so as to reduce the first output power.SELECTED DRAWING: Figure 4

Description

The present invention relates to a method for controlling a continuous heat treatment facility that continuously heat-treats a metal member.

Electromagnetic induction heating self-heats a metal member by an induced current, which enables rapid temperature rise and real-time temperature control. Electromagnetic induction heating is roughly classified into a solenoid type and a transverse type. In the solenoid type, a heating coil wound in a solenoid shape is arranged around the metal member, and an alternating current is passed through the heating coil to generate an induced current on the surface of the metal member to heat the metal member. In the transverse type, a pair of heating coils are arranged so as to sandwich the metal member so as to be separated from each other in the thickness direction of the metal member so that the alternating magnetic field generated from the heating coils penetrates in the thickness direction of the metal member. Is.

Patent Document 1 describes a solenoid type induction heating unit that compensates for temperature inhomogeneity in the width direction caused by roll cooling water during rolling, and temperature compensation for temperature inhomogeneity in the longitudinal direction. Disclosed is a heating device having a solenoid type induction heating unit to perform.

Patent Document 2 describes that the temperature is 200 ° C. or more lower than the preheating temperature (less than the Curie temperature Tc of a thin steel sheet) by each of the transverse type and solenoid type induction heating portions arranged in the pretropical zone of the continuous annealing facility. Discloses that the thin steel sheet is preheated to the preheating temperature, respectively. Then, Patent Document 2 discloses that a heating zone and an even tropics are provided on the downstream side of the pre-tropics.

Japanese Unexamined Patent Publication No. 2003-290812 Japanese Unexamined Patent Publication No. 2016-98420

The solenoid type has excellent temperature uniformity in the width direction of the metal member, but when the temperature of the metal member rises and approaches the Curie temperature of the metal member, the relative magnetic permeability of the metal member drops significantly, so that the induced current Penetration depth becomes deeper. As a result, in a thin metal member, the induced current flowing on the front surface and the induced current flowing on the back surface of the metal member cancel each other out, and the heating efficiency is significantly reduced. On the other hand, in the solenoid type, the thickness of the metal member is not easily affected, but the width of the metal member is overheated because the induced current is concentrated on the end in the width direction of the metal member. The temperature uniformity in the direction is inferior to that of the solenoid type.

In Patent Document 1, a transverse induction heating unit and a solenoid induction heating unit are used to compensate for temperature inhomogeneity, but sufficient temperature uniformity is obtained for a thin metal member. It is hard to say that it has been done.

Patent Document 2 only discloses that a thin steel sheet is rapidly heated to near the Curie temperature by a solenoid type induction heating unit, and controls for improving the temperature uniformity in the width direction in total in a continuous annealing facility. It is not disclosed.

Therefore, an object of the present invention is to provide a control method for a continuous heat treatment facility capable of improving the temperature uniformity in the width direction orthogonal to the transport direction of the metal member in total.

In order to solve the above problems, the control method of the continuous heat treatment equipment according to one aspect of the present invention is
The first heating portion, the second heating portion, and the third heating portion, which are continuously arranged in order along the transport direction of the metal member,
A control unit that controls the first output power, the second output power, and the third output power output to the first heating unit, the second heating unit, and the third heating unit, respectively.
A first measuring unit for measuring a first voltage and a first current in the first heating unit is provided.
In a continuous heat treatment facility in which the first heating unit, the second heating unit, and the third heating unit are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit calculates the equivalent impedance in the parallel resonant circuit based on the first voltage and the first current measured by the first measuring unit, and when the calculated equivalent impedance becomes larger than the threshold value. The first output power is controlled so that the first output power is reduced.

According to the present invention, the first output power is reduced when the equivalent impedance in the parallel resonant circuit of the first heating unit, that is, the solenoid type induction heating unit becomes larger than the threshold value. In other words, the first output power is reduced before the temperature of the metal member heated by the first heating unit reaches the Curie temperature of the metal member. As a result, in a state where the temperature of the metal member is lower than the Curie temperature of the metal member, heating by the solenoid type induction heating unit having excellent temperature uniformity in the width direction orthogonal to the transport direction is maintained, so that heating in the width direction is maintained. The temperature uniformity can be improved in total.

It is a perspective view schematically explaining the continuous heat treatment equipment which concerns on one Embodiment. It is a block diagram of the continuous heat treatment equipment shown in FIG. It is a flowchart at the time of determining the optimum setting value in the continuous heat treatment equipment. It is a flowchart at the time of operating a continuous heat treatment facility. It is a flowchart which concerns on the modification when operating the continuous heat treatment equipment.

Hereinafter, embodiments of the control method for the continuous heat treatment equipment 1 according to the present invention will be described with reference to the drawings.

[Embodiment]
The control method of the continuous heat treatment equipment 1 according to the embodiment will be described with reference to FIGS. 1 to 4. FIG. 1 is a perspective view schematically illustrating a continuous heat treatment facility 1 according to an embodiment. FIG. 2 is a block diagram of the continuous heat treatment equipment 1 shown in FIG. FIG. 3 is a flowchart when determining the optimum set value in the continuous heat treatment equipment 1. FIG. 4 is a flowchart when the continuous heat treatment equipment 1 is operated.

[Overall configuration of continuous heat treatment equipment]
As shown in FIG. 1, the continuous heat treatment equipment 1 includes a first heating unit 10 and a second heating unit 10 which are continuously arranged in order from the upstream side to the downstream side along the transport direction F of the metal member 3. A heating unit 20 and a third heating unit 30 are provided. The continuous heat treatment equipment 1 performs continuous heat treatment (for example, continuous annealing treatment) while transporting the metal member 3 in the transport direction F via a transport roller (not shown). The metal member 3 as a work is, for example, a thin metal piece (for example, a steel piece) or a long metal strip obtained by rolling a metal piece. The thickness of the metal member 3 is, for example, 0.1 mm to 5 mm.

A first temperature sensor 16 is arranged on the downstream side of the first heating unit 10 in the transport direction F (the exit side of the first heating unit 10). The first temperature sensor 16 is a radiation thermometer that spot-measures the exit side temperature of the central portion in the width direction W of the metal member 3, that is, the first exit side temperature. A second temperature sensor 26 is arranged on the downstream side of the second heating unit 20 in the transport direction F (the exit side of the second heating unit 20). The second temperature sensor 26 measures while scanning the exit side temperature of the metal member 3, that is, the second exit temperature in the width direction W orthogonal to the transport direction F. The second temperature sensor 26 is, for example, a scanning pyrometer. A third temperature sensor 36 is arranged on the downstream side (outside side of the third heating unit 30) in the transport direction F of the third heating unit 30. The third temperature sensor 36 measures while scanning the exit side temperature of the metal member 3, that is, the third exit temperature in the width direction W orthogonal to the transport direction F. The third temperature sensor 36 is, for example, a scanning pyrometer.

As shown in FIG. 2, the continuous heat treatment equipment 1 includes a first heating unit 10, a second heating unit 20, a third heating unit 30, a first temperature sensor 16, a second temperature sensor 26, and a third. It includes a temperature sensor 36 and a control unit 5.

The first heating unit 10 is a solenoid type induction heating unit, and includes a first heating coil 12, a first power supply 13, a first output power control unit 14, and a first measurement unit 18. The first heating coil 12 is a coil that winds around the metal member 3. The first power supply 13 outputs the first output power of high-frequency alternating current to the first heating coil 12. The first output power control unit 14 controls the first output power output to the first heating coil 12 by the first power supply 13. An induced current is generated on the front surface, the back surface, and the side surface of the metal member 3 by the alternating magnetic field generated by the first heating coil 12 so as to penetrate the longitudinal cross section of the metal member 3. Then, the metal member 3 is heated by Joule heat based on the induced current and the electric resistance of the metal member 3. The first measuring unit 18 measures the first voltage and the first current of the first output power output to the first heating coil 12. The control unit 5 acquires each measured value of the measured first voltage and the first current, and controls the storage unit 7 to store each measured value.

The second heating unit 20 is a transverse induction heating unit, and includes a second heating coil 22, a second power supply 23, and a second output power control unit 24. The second heating coil 22 is a pair of heating coils arranged so as to sandwich the metal member 3 so as to be spaced apart from each other in the thickness direction of the metal member 3. The second power supply 23 outputs the second output power of high-frequency alternating current to the second heating coil 22. The second output power control unit 24 controls the second output power output to the second heating coil 22 by the second power supply 23. The alternating magnetic field generated from the second heating coil 22 penetrates in the thickness direction of the metal member 3. An induced current is generated on the surface of the metal member 3 by this alternating magnetic field, and the metal member 3 is heated by Joule heat based on the induced current and the electric resistance of the metal member 3.

The third heating unit 30 is a resistance heating unit, and includes a heating heater 32, a third power supply 33, and a third output power control unit 34. The heating heater 32 is a resistance heating element. The third power supply 33 outputs the AC third output power to the heater 32. The third output power control unit 34 controls the third output power output to the heater 32 by the third power supply 33. In the third heating unit 30, the metal member 3 is heated by indirect resistance heating that transfers the heat energy generated by energizing the heating heater 32 to the metal member 3.

The control unit 5 controls each heating unit of the continuous heat treatment equipment 1, and more specifically, controls each of the first heating unit 10, the second heating unit 20, and the third heating unit 30. The control unit 5 is, for example, a computer, and includes an arithmetic unit (CPU: central processing unit) 6 and a storage unit (memory such as ROM or RAM) 7.

The storage unit 7 performs the following storage operation, for example. That is, the storage unit 7 stores various programs for executing the heat treatment in each of the first heating unit 10, the second heating unit 20, and the third heating unit 30. The storage unit 7 includes data on various metal members 3 to be heat-treated (for example, curry temperature, heat content, specific resistance, width, thickness, heat treatment conditions), first rated output power of the first heating unit 10, and the first rated output power of the first heating unit 10. The second rated output power of the second heating unit 20 and the third rated output power of the third heating unit 30 are stored. The storage unit 7 stores the temperature data (first output side temperature, second output side temperature, and third output side temperature) measured by each of the first temperature sensor 16, the second temperature sensor 26, and the third temperature sensor 36. Remember. The storage unit 7 is a first for calculating the first temperature unevenness in the width direction W of the first heating unit 10 from the temperature rise width (first outlet side temperature-first inlet side temperature) in the first heating unit 10. Store the calculation formula. The storage unit 7 is a second for calculating the second temperature unevenness in the width direction W of the second heating unit 20 from the temperature rise width (second outlet side temperature-second inlet side temperature) in the second heating unit 20. Store the calculation formula. The storage unit 7 is the final temperature in the width direction of the metal member 3 carried out from the third heating unit 30 based on the heat treatment conditions of the metal member 3, the third rated output power, the calculated cumulative temperature unevenness due to the induced heating, and the like. The third calculation formula for calculating the magnitude T of the unevenness (hereinafter referred to as the third temperature unevenness) is stored.

The calculation unit 6 performs the following calculation operation, for example. That is, the calculation unit 6 calculates the first output power output to the first heating unit 10, the second output power output to the second heating unit 20, and the third output power output to the third heating unit 30, respectively. calculate. The calculation unit 6 calculates an optimum set value in which the magnitude T of the third temperature unevenness becomes smaller than the permissible value based on the Curie temperature of the metal member 3 and the heat treatment conditions. Specifically, the optimum set values relate to the first output side temperature, the second output side temperature, the first output power, the second output power, and the third output power. The calculation unit 6 calculates the equivalent impedance based on the first voltage and the first current measured by the first measurement unit 18. The calculation unit 6 calculates the threshold value based on the material of the metal member 3 and the width dimension in the width direction W orthogonal to the transport direction F of the metal member 3. Thereby, the threshold value is optimized according to the material and width dimension of the metal member 3.

The solenoid type induction heating unit as the first heating unit 10 is excellent in temperature uniformity in the width direction W of the metal member 3, but when the thickness of the metal member 3 is thin, the temperature of the metal member 3 becomes the curry temperature. There is a problem that the heating efficiency is significantly lowered when approaching. That is, the penetration depth of the induced current is proportional to the square root of the intrinsic resistance of the metal member 3 and inversely proportional to the square root of the relative magnetic permeability of the metal member 3. When the temperature of the metal member 3 rises and approaches the Curie temperature of the metal member 3, the relative magnetic permeability of the metal member 3 greatly decreases, so that the penetration depth of the induced current becomes deeper. As a result, when the thickness of the metal member 3 is thin, the induced current flowing on the front surface and the induced current flowing on the back surface of the metal member 3 cancel each other out, and the heating efficiency is significantly lowered.

In the solenoid type induction heating unit as the second heating unit 20, the heating efficiency does not decrease even if the thickness of the metal member 3 becomes thin, but the induced current is concentrated at the end portion of the metal member 3 in the width direction W. Since the portion is overheated, there is a problem that the temperature uniformity in the width direction W is inferior to that of the solenoid type.

The resistance heating unit as the third heating unit 30 has excellent temperature uniformity in the width direction W of the metal member 3, and the heating efficiency does not decrease even if the thickness of the metal member 3 becomes thin, but the temperature rises and falls rapidly. It is difficult to operate.

As described above, the solenoid type induction heating unit 10, the transverse type induction heating unit 20, and the resistance heating unit 30 have advantages and disadvantages, but in order to improve the temperature uniformity in the width direction W of the metal member 3 in total. The control of the above will be described with reference to FIGS. 3 and 4.

[Control method for continuous heat treatment equipment]
FIG. 3 is a flowchart when determining the optimum set value in the continuous heat treatment equipment 1. FIG. 4 is a flowchart when the continuous heat treatment equipment 1 is operated.

In FIG. 3, prior to operating the continuous heat treatment equipment 1, a step for determining an optimum set value for heat-treating the metal member 3 of a certain material in the continuous heat treatment equipment 1 starts (step S1). In step S2, the control unit 5 calculates what temperature the first outlet temperature of the first heating unit 10 should be based on the Curie temperature of the metal member 3 stored in the storage unit 7. In step S3, the control unit 5 should be output to the first heating unit 10 based on the width and thickness of the metal member 3 stored in the storage unit 7 and the heat treatment conditions (including the difference in heat content). 1 Calculate the output power. In step S4, the control unit 5 determines the second outlet temperature (in other words, in other words) of the second heating unit 20 based on the heat treatment conditions stored in the storage unit 7 and the third rated output power of the third heating unit 30. , A temperature close to the temperature of the metal member 3 carried into the third heating unit 30) is calculated.

In step S5, the control unit 5 should be output to the second heating unit 20 based on the width and thickness of the metal member 3 stored in the storage unit 7 and the heat treatment conditions (including the difference in heat content). 2 Calculate the output power. In step S6, the control unit 5 uses the first calculation formula and the second calculation formula stored in the storage unit 7 to obtain the first temperature unevenness of the first heating unit 10 and the second of the second heating unit 20, respectively. Calculate the temperature unevenness. Then, the control unit 5 calculates the calculated square root of the sum of squares of the first temperature unevenness and the second temperature unevenness, and stores the calculated value of the sum of square roots as the cumulative temperature unevenness due to induction heating. Control to do.

In step S7, the control unit 5 should output to the third heating unit 30 based on the width and thickness of the metal member 3 stored in the storage unit 7 and the heat treatment conditions (including the difference in heat content). 3 The output power is calculated, and the magnitude T of the third temperature unevenness is calculated from the third calculation formula also stored in the storage unit 7.

In step S8, the control unit 5 determines whether or not the magnitude T of the third temperature unevenness is smaller than the permissible value.

If the magnitude T of the third temperature unevenness is equal to or greater than the permissible value in step S8, the process proceeds to step S9, and the control unit 5 sets the third output power of the third heating unit 30 to the upper limit, that is, to the third rated output power. Determine if it has been reached. If the third output power of the third heating unit 30 has not reached the upper limit in step S9, the control unit 5 sets the third output power of the third heating unit 30 to be high (step S10). Then, returning to step S4, the control unit 5 calculates the temperature of the metal member 3 carried into the third heating unit 30.

If the third output power of the third heating unit 30 has reached the upper limit in step S9, the process proceeds to step S13, and the control unit 5 determines whether or not the first output side temperature of the first heating unit 10 has reached the limit temperature. To judge. When the first outlet temperature of the first heating unit 10 has reached the limit temperature in step S13, the control unit 5 notifies the setting error and ends the setting flow (step S16). The limit temperature is a temperature lower than the Curie temperature at which the relative magnetic permeability of the metal member 3 becomes 1, and is a temperature at which the heating efficiency drops significantly.

When the first output side temperature of the first heating unit 10 has not reached the limit temperature in step S13, the control unit 5 sets the first output side temperature of the first heating unit 10 to be high, and the first The first output power is calculated according to the above paragraph number [0029] using the first output side temperature of the heating unit 10 (step S14). In step S15, the control unit 5 determines whether or not the first output power of the first heating unit 10 reaches the upper limit, that is, the first rated output power.

If the first output power of the first heating unit 10 has not reached the upper limit in step S15, returning to step S3, the control unit 5 calculates the output power of the first heating unit 10. When the first output power of the first heating unit 10 has reached the upper limit in step S15, the process proceeds to step S16, and the control unit 5 notifies the setting error and ends the setting flow.

When the magnitude T of the third temperature unevenness is smaller than the permissible value in step S8, the control unit 5 determines the calculated first output side temperature and second output side temperature, and the first output power, the second output power, and the second output power. Each optimum set value with the third output power is stored in the storage unit 7 (step S11). That is, the control unit 5 determines the first output side temperature and the second output side temperature based on the Curie temperature of the metal member 3 and the heat treatment conditions so that the magnitude T of the third temperature unevenness becomes smaller than the permissible value. Each optimum setting value for the first output power, the second output power, and the third output power is calculated in advance, and each optimum setting value is stored in the storage unit 7. As a result, the magnitude T of the third temperature unevenness can be made smaller than the permissible value by using the optimum set value calculated in advance as the initial value when the continuous heat treatment equipment 1 is operated.

Then, in step S12, the flow for determining the optimum set value in the continuous heat treatment equipment 1 is completed.

FIG. 4 shows a flowchart in which the first heating coil 12 and a capacitor (not shown) form a parallel resonant circuit.

In FIG. 4, a step for operating the continuous heat treatment equipment 1 starts (step S21). In step S22, the control unit 5 sets the optimum set values stored in the storage unit 7 (that is, the first output side temperature and the first output power for the first heating unit 10, and the second output for the second heating unit 20). The side temperature, the second output power, the third output power with respect to the third heating unit 30) and the target output side temperature of the third heating unit 30 are set. In step S23, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18. In step S24, the control unit 5 calculates the equivalent impedance based on the measured values of the first voltage and the first current measured in step S23.

In step S25, the control unit 5 determines whether or not the calculated equivalent impedance is larger than the threshold value. When the equivalent impedance calculated in step S24 is larger than the threshold value, the control unit 5 sets the temperature on the first output side of the first heating unit 10 to be low (step S26). In step S27, the control unit 5 determines the first output power of the first heating unit 10 and the second of the second heating unit 20 based on the first output side temperature of the first heating unit 10 set in step S26. Calculate each output power. Therefore, in step S26 and step 27, when the calculated equivalent impedance is larger than the threshold value, the control unit 5 controls the first output power so that the first output power of the first heating unit 10 decreases. Then, returning to step S23, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18.

When the equivalent impedance calculated in step S25 is equal to or less than the threshold value, the control unit 5 has the final temperature unevenness in the width direction of the metal member 3 carried out from the third heating unit 30, that is, the third temperature sensor 36. 3 The magnitude T of the temperature unevenness is measured (step S28). In step S29, the control unit 5 determines whether or not the magnitude T of the third temperature unevenness is smaller than the permissible value.

When the magnitude T of the third temperature unevenness is smaller than the permissible value in step S29, returning to step S23, the control unit 5 outputs to the first heating coil 12 via the first measurement unit 18. Obtain the measured values of voltage and first current.

If the magnitude T of the third temperature unevenness is equal to or greater than the permissible value in step S29, the process proceeds to step S30, and the control unit 5 sets the third output power of the third heating unit 30 to the upper limit, that is, to the third rated output power. Determine if it has been reached. If the third output power of the third heating unit 30 has not reached the upper limit in step S30, the control unit 5 sets the third output power of the third heating unit 30 to be high (step S31). As a result, the share of the third heating portion 30, that is, the resistance heating portion, which is excellent in temperature uniformity, is increased, so that the temperature uniformity in the width direction W is improved.

In step S32, the control unit 5 calculates the temperature of the metal member 3 carried into the third heating unit 30. In step S34, the control unit 5 approximates the temperature of the second exit side of the second heating unit 20 calculated in step S32 (that is, the temperature of the metal member 3 carried into the third heating unit 30). The first output power of the first heating unit 10 and the second output power of the second heating unit 20 are calculated based on the above. Then, returning to step S23, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18.

When the third output power of the third heating unit 30 has reached the upper limit in step S30, the process proceeds to step S35, and the control unit 5 determines whether or not the first output side temperature of the first heating unit 10 has reached the limit temperature. To judge. When the first outlet temperature of the first heating unit 10 has reached the limit temperature in step S35, the control unit 5 notifies that the transfer speed is slowed down (step S37). Then, returning to step S34, the control unit 5 calculates the first output power of the first heating unit 10 and the second output power of the second heating unit 20, respectively.

When the first output side temperature of the first heating unit 10 has not reached the limit temperature in step S35, the control unit 5 sets the first output side temperature of the first heating unit 10 to be high (step S36). .. As a result, the share ratio of the first heating unit 10, that is, the solenoid-type induction heating unit, which is excellent in temperature uniformity in the width direction W, is increased, so that the temperature uniformity in the width direction W is improved. Then, returning to step S34, the control unit 5 calculates the first output power of the first heating unit 10 and the second output power of the second heating unit 20, respectively.

Unless some abnormality such as a calculation error occurs, the continuous heat treatment equipment 1 is continuously operated according to the flowchart of FIG.

[Modification example]
The control method of the continuous heat treatment equipment 1 according to the modified example will be described with reference to FIG. FIG. 5 is a flowchart relating to a modified example when the continuous heat treatment equipment 1 is operated.

FIG. 5 shows a flowchart in which the first heating coil 12 and a capacitor (not shown) form a series resonant circuit.

In FIG. 5, the step for operating the continuous heat treatment equipment 1 starts (step S41). In step S42, the control unit 5 sets the optimum set values stored in the storage unit 7 (that is, the first output side temperature and the first output power for the first heating unit 10, and the second output for the second heating unit 20). The side temperature, the second output power, the third output power with respect to the third heating unit 30) and the target output side temperature of the third heating unit 30 are set. In step S43, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18. In step S44, the control unit 5 calculates the equivalent impedance based on the measured values of the first voltage and the first current measured in step S43.

In step S45, the control unit 5 determines whether or not the calculated equivalent impedance is smaller than the threshold value. When the equivalent impedance calculated in step S44 is smaller than the threshold value, the control unit 5 sets the temperature on the first output side of the first heating unit 10 to be low (step S46). In step S47, the control unit 5 determines the first output power of the first heating unit 10 and the second of the second heating unit 20 based on the first output side temperature of the first heating unit 10 set in step S46. Calculate each output power. Therefore, in step S46 and step 47, when the calculated equivalent impedance is larger than the threshold value, the control unit 5 controls the first output power so that the first output power of the first heating unit 10 decreases. Then, returning to step S43, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18.

When the equivalent impedance calculated in step S45 is equal to or greater than the threshold value, the control unit 5 has the final temperature unevenness in the width direction of the metal member 3 carried out from the third heating unit 30 via the third temperature sensor 36, that is, the third temperature unevenness. 3 The magnitude T of the temperature unevenness is measured (step S48). In step S49, the control unit 5 determines whether or not the magnitude T of the third temperature unevenness is smaller than the permissible value.

When the magnitude T of the third temperature unevenness is smaller than the permissible value in step S49, returning to step S43, the control unit 5 outputs to the first heating coil 12 via the first measurement unit 18. Obtain the measured values of voltage and first current.

If the magnitude T of the third temperature unevenness is equal to or greater than the permissible value in step S49, the process proceeds to step S50, and the control unit 5 sets the third output power of the third heating unit 30 to the upper limit, that is, to the third rated output power. Determine if it has been reached. If the third output power of the third heating unit 30 has not reached the upper limit in step S50, the control unit 5 sets the third output power of the third heating unit 30 to be high (step S51). As a result, the share of the third heating portion 30, that is, the resistance heating portion, which is excellent in temperature uniformity, is increased, so that the temperature uniformity in the width direction W is improved.

In step S52, the control unit 5 calculates the temperature of the metal member 3 carried into the third heating unit 30. In step S54, the control unit 5 approximates the temperature of the second exit side of the second heating unit 20 calculated in step S52 (that is, the temperature of the metal member 3 carried into the third heating unit 30). The first output power of the first heating unit 10 and the second output power of the second heating unit 20 are calculated based on the above. Then, returning to step S43, the control unit 5 acquires the measured values of the first voltage and the first current output to the first heating coil 12 via the first measuring unit 18.

When the third output power of the third heating unit 30 has reached the upper limit in step S50, the process proceeds to step S55, and the control unit 5 determines whether or not the first output side temperature of the first heating unit 10 has reached the limit temperature. To judge. When the first outlet temperature of the first heating unit 10 has reached the limit temperature in step S55, the control unit 5 notifies that the transfer speed is slowed down (step S57). Then, returning to step S54, the control unit 5 calculates the first output power of the first heating unit 10 and the second output power of the second heating unit 20, respectively.

When the first output side temperature of the first heating unit 10 has not reached the limit temperature in step S55, the control unit 5 sets the first output side temperature of the first heating unit 10 to be high (step S56). .. As a result, the share ratio of the first heating unit 10, that is, the solenoid-type induction heating unit, which is excellent in temperature uniformity in the width direction W, is increased, so that the temperature uniformity in the width direction W is improved. Then, returning to step S54, the control unit 5 calculates the first output power of the first heating unit 10 and the second output power of the second heating unit 20, respectively.

Unless some abnormality such as a calculation error occurs, the continuous heat treatment equipment 1 is continuously operated according to the flowchart of FIG.

Although specific embodiments and numerical values of the present invention have been described, the present invention is not limited to the above embodiments, and various modifications can be made within the scope of the present invention.

The first heating unit 10 does not necessarily have to be composed of a single heating zone, and may be divided into a plurality of heating zones so that the plurality of heating zones are arranged in series in the transport direction F. it can. Similar to the first heating unit 10, each of the second heating unit 20 and the third heating unit 30 may be configured such that a plurality of heating zones are arranged in series in the transport direction F.

The present invention and embodiments can be summarized as follows.

The control method of the continuous heat treatment equipment 1 according to one aspect of the present invention is
The first heating unit 10, the second heating unit 20, and the third heating unit 30, which are continuously arranged in order along the transport direction F of the metal member 3,
A control unit 5 that controls the first output power, the second output power, and the third output power output to the first heating unit 10, the second heating unit 20, and the third heating unit 30, respectively.
A first measuring unit 18 for measuring a first voltage and a first current in the first heating unit 10 is provided.
In the continuous heat treatment equipment 1 in which the first heating unit 10, the second heating unit 20, and the third heating unit 30 are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit 5 calculates the equivalent impedance in the parallel resonant circuit based on the first voltage and the first current measured by the first measurement unit 18, and the calculated equivalent impedance becomes larger than the threshold value. At that time, the first output power is controlled so that the first output power is reduced.

According to the above control method, the first output power is reduced when the equivalent impedance in the parallel resonance circuit of the first heating unit 10, that is, the solenoid type induction heating unit becomes larger than the threshold value. In other words, the first output power is reduced before the temperature of the metal member 3 heated by the first heating unit 10 reaches the Curie temperature of the metal member 3. As a result, in a state where the temperature of the metal member 3 is lower than the Curie temperature of the metal member 3, heating by the solenoid type induction heating unit having excellent temperature uniformity in the width direction W orthogonal to the transport direction F is maintained. , The temperature uniformity in the width direction W can be improved in total. When the temperature of the metal member 3 reaches the vicinity of the Curie temperature, the heating efficiency drops significantly. Therefore, the threshold value of the equivalent impedance is selected before reaching the Curie temperature.

The control method of the continuous heat treatment equipment 1 according to another aspect of the present invention is
The first heating unit 10, the second heating unit 20, and the third heating unit 30, which are continuously arranged in order along the transport direction F of the metal member 3,
A control unit 5 that controls the first output power, the second output power, and the third output power output to the first heating unit 10, the second heating unit 20, and the third heating unit 30, respectively.
A first measuring unit 18 for measuring a first voltage and a first current in the first heating unit 10 is provided.
In the continuous heat treatment equipment 1 in which the first heating unit 10, the second heating unit 20, and the third heating unit 30 are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit 5 calculates the equivalent impedance in the series resonance circuit based on the first voltage and the first current measured by the first measurement unit 18, and the calculated equivalent impedance becomes smaller than the threshold value. At that time, the first output power is controlled so that the first output power is reduced.

According to the above control method, the first output power is reduced when the equivalent impedance in the series resonance circuit of the first heating unit 10, that is, the solenoid type induction heating unit becomes smaller than the threshold value. In other words, the first output power is reduced before the temperature of the metal member 3 heated by the first heating unit 10 reaches the Curie temperature of the metal member 3. As a result, in a state where the temperature of the metal member 3 is lower than the Curie temperature of the metal member 3, heating by the solenoid type induction heating unit having excellent temperature uniformity in the width direction W orthogonal to the transport direction F is maintained. , The temperature uniformity in the width direction W can be improved in total.

Further, in the control method of the continuous heat treatment equipment 1 of one embodiment,
The threshold value is calculated based on the material of the metal member 3 and the width dimension in the width direction W orthogonal to the transport direction F of the metal member 3.

According to the above embodiment, the threshold value is optimized according to the material and width dimension of the metal member 3.

Further, in the control method of the continuous heat treatment equipment 1 of one embodiment,
A third temperature sensor 36 for measuring the third temperature unevenness in the width direction W orthogonal to the transport direction F of the metal member 3 carried out from the third heating unit 30 is provided.
The control unit 5 determines whether or not the magnitude T of the third temperature unevenness is equal to or greater than the permissible value, and when the magnitude T of the third temperature unevenness is equal to or greater than the permissible value, the third The third output power is controlled so that the output power increases.

According to the above embodiment, the third heating unit 30, that is, the resistance heating unit, which has excellent temperature uniformity, has a large share, so that the temperature uniformity in the width direction W is improved.

Further, in the control method of the continuous heat treatment equipment 1 of one embodiment,
The control unit 5 determines whether or not the third output power is the third rated output power of the third heating unit 30, and the third output power becomes the third rated output power. At that time, the first output power is controlled so that the output side temperature of the first heating unit 10 becomes high.

According to the above embodiment, the share ratio of the first heating unit 10, that is, the solenoid type induction heating unit, which is excellent in temperature uniformity in the width direction W, is increased, so that the temperature uniformity in the width direction W is improved.

The control method of the continuous heat treatment equipment 1 according to still another aspect of the present invention is
The first heating unit 10, the second heating unit 20, and the third heating unit 30, which are continuously arranged in order along the transport direction F of the metal member 3,
A control unit 5 that controls the first output power, the second output power, and the third output power output to the first heating unit 10, the second heating unit 20, and the third heating unit 30, respectively.
A third temperature sensor 36 for measuring the third temperature unevenness in the width direction W orthogonal to the transport direction F of the metal member 3 carried out from the third heating unit 30 is provided.
In the continuous heat treatment equipment 1 in which the first heating unit 10, the second heating unit 20, and the third heating unit 30 are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit 5 is the first outlet side of the first heating unit 10 based on the Curie temperature of the metal member 3 and the heat treatment conditions so that the magnitude T of the third temperature unevenness becomes smaller than the permissible value. It is characterized in that the optimum set values for the temperature, the second output side temperature of the second heating unit 20, the first output power, the second output power, and the third output power are calculated in advance.

According to the above control method, by using the optimum set value calculated in advance as the initial value when the continuous heat treatment equipment 1 is operated, the third temperature unevenness of the metal member 3 carried out from the third heating unit 30 is affected. The size T can be made smaller than the allowable value.

1 ... Continuous heat treatment equipment 3 ... Metal member 5 ... Control unit 6 ... Calculation unit 7 ... Storage unit 10 ... First heating unit (solenoid type induction heating unit)
12 ... 1st heating coil 13 ... 1st power supply 14 ... 1st output power control unit 16 ... 1st temperature sensor 18 ... 1st measurement unit 20 ... 2nd heating unit (transverse type induction heating unit)
22 ... 2nd heating coil 23 ... 2nd power supply 24 ... 2nd output power control unit 26 ... 2nd temperature sensor 30 ... 3rd heating unit (resistive heating unit)
32 ... Heating heater 33 ... Third power supply 34 ... Third output power control unit 36 ... Third temperature sensor F ... Transport direction T ... Third temperature unevenness (final temperature in the width direction of the metal member carried out from the third heating unit) Unevenness) Size W ... Width direction

Claims (6)

The first heating portion, the second heating portion, and the third heating portion, which are continuously arranged in order along the transport direction of the metal member,
A control unit that controls the first output power, the second output power, and the third output power output to the first heating unit, the second heating unit, and the third heating unit, respectively.
A first measuring unit for measuring a first voltage and a first current in the first heating unit is provided.
In a continuous heat treatment facility in which the first heating unit, the second heating unit, and the third heating unit are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit calculates the equivalent impedance in the parallel resonant circuit based on the first voltage and the first current measured by the first measuring unit, and when the calculated equivalent impedance becomes larger than the threshold value. , A method for controlling a continuous heat treatment facility, which controls the first output power so that the first output power is reduced. The first heating portion, the second heating portion, and the third heating portion, which are continuously arranged in order along the transport direction of the metal member,
A control unit that controls the first output power, the second output power, and the third output power output to the first heating unit, the second heating unit, and the third heating unit, respectively.
A first measuring unit for measuring a first voltage and a first current in the first heating unit is provided.
In a continuous heat treatment facility in which the first heating unit, the second heating unit, and the third heating unit are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
The control unit calculates the equivalent impedance in the series resonance circuit based on the first voltage and the first current measured by the first measurement unit, and when the calculated equivalent impedance becomes smaller than the threshold value. , A method for controlling a continuous heat treatment facility, which controls the first output power so that the first output power is reduced. The control method according to claim 1 or 2, wherein the threshold value is calculated based on the material of the metal member and the width dimension in the width direction orthogonal to the transport direction of the metal member. A third temperature sensor for measuring the third temperature unevenness in the width direction orthogonal to the transport direction of the metal member carried out from the third heating unit is provided.
The control unit determines whether or not the magnitude of the third temperature unevenness is equal to or greater than the permissible value, and when the magnitude of the third temperature unevenness is equal to or greater than the permissible value, the third output power is generated. The control method according to any one of claims 1 to 3, wherein the third output power is controlled so as to increase. The control unit determines whether or not the third output power is the third rated output power of the third heating unit, and when the third output power is the third rated output power. The control method according to claim 4, wherein the first output power is controlled so that the output side temperature of the first heating unit becomes high. The first heating portion, the second heating portion, and the third heating portion, which are continuously arranged in order along the transport direction of the metal member,
A control unit that controls the first output power, the second output power, and the third output power output to the first heating unit, the second heating unit, and the third heating unit, respectively.
A third temperature sensor for measuring the third temperature unevenness in the width direction orthogonal to the transport direction of the metal member carried out from the third heating unit is provided.
In a continuous heat treatment facility in which the first heating unit, the second heating unit, and the third heating unit are a solenoid type induction heating unit, a transverse type induction heating unit, and a resistance heating unit, respectively.
Based on the Curie temperature of the metal member and the heat treatment conditions, the control unit sets the first outlet temperature of the first heating unit and the first temperature of the first heating unit so that the magnitude of the third temperature unevenness becomes smaller than the allowable value. (2) A control method for a continuous heat treatment facility, in which optimum set values for the second output side temperature of the heating unit, the first output power, the second output power, and the third output power are calculated in advance.

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