KR101151338B1 - System and control method for induction heating with power controller for control of standby power - Google Patents

Abstract

PURPOSE: An induction heater and a control method thereof are provided to transfer a stand-by signal to a power supply part from an upper controller, thereby blocking unnecessary power supply in a stand-by state. CONSTITUTION: An induction heating operation unit(20) supplies power in order to generate inductive magnetic fields. A power supply unit(30) supplies power to the induction heating operation unit. A stand-by power control part(31) controls the power supplied to the induction heating operation unit. An upper controller(40) transmits an operation signal. A power supply signal processing unit(41) transmits a stand-by power supply signal to the power supply unit. An induction heating signal processing unit(42) transmits an output signal for generating the inductive magnetic fields.

Description

Induction heating apparatus equipped with an upper controller for standby power control and its control method {SYSTEM AND CONTROL METHOD FOR INDUCTION HEATING WITH POWER CONTROLLER FOR CONTROL OF STANDBY POWER}

The present invention relates to an induction heating apparatus, and more particularly, to transmit standby signals from an upper controller to a power supply unit in order to efficiently operate standby power. The present invention relates to an induction heating apparatus equipped with an upper controller of standby power control to reduce power consumption.

In general, as a heating method, a method of burning fossil fuel, wood, etc. by heating, and in recent years, a heating method using electricity has been applied. Among them, a method of heating a pot, a pot, a kiln, and the like by heating a coil in which electric current flows in a method using electricity has traditionally been used.

A hot plate type microwave oven is used as a heat generation of the coil, and a highlight stove for heating with far-infrared rays generated from a coil inside the transparent ceramic is used.

However, all of these conventional methods have a high risk of burns because the plate is heated to a high temperature, and in particular, in the combustion method such as gas, the flame is visible to the naked eye. In the highlight-type stove, it is difficult to easily distinguish between high and low temperatures, and therefore, considerable care is required for the image.

In recent years, an induction heating cooking apparatus for generating an induction magnetic field and placing a heating object for cooking (pot, pot, etc.) in the induction magnetic field to be heated by the induction magnetic field has been commercialized.

Such an induction heating cooker operates only when an induction magnetic field is generated, so it is easy to operate and control the heating and stopping, and thus, the induction heating cooker itself is easy to use while the heating object for cooking is heated. Since there is no part which forms a high temperature, the risk of a burn is remarkably reduced.

However, when the heating action for the generation of induction magnetic field is always consumed a lot of power consumption, the situation that requires more efficient use and management of power. Therefore, there is an urgent need for a technique for efficiently operating power consumption in induction heating devices to reduce the consumption of unnecessary waste.

The present invention for solving the above problems is an object of the configuration of the upper controller to reduce unnecessary power consumption in the standby state.

Another object of the present invention is to transmit the standby signal from the upper controller to the power supply in order to efficiently operate the standby power to cut off the unnecessary power source in the standby state at the source.

In particular, the power supply receiving the standby signal is configured to reduce the power consumption due to unnecessary high voltage by forming a low voltage in the induction heating operation unit driven by a high voltage.

Another object of the present invention is to provide a predetermined safety time to the induction heating operation is supplied to the power supply after the standby time, the members of the induction heating operation by the predetermined stabilization time before the heating action to set the initialization is ready for operation It is to ensure that the induction heating operation unit is stable by making it enough.

Furthermore, another object of the present invention is to allow the standby time and the power supply time to be repeated with a predetermined period, but in particular by the multiple of the pulse signal period of the full-wave rectification of the input power supply, device controller, host controller, power supply, induction The signal transmission and reception between each member of the induction heating device, such as the heating operation unit is to be made stably and efficiently.

The present invention for achieving the above object, the working coil 12 is an induction magnetic field is generated; Induction heating operation unit 20 for controlling the output so that the induction magnetic field is generated in the working coil 12; A power supply unit 30 for supplying power to the induction heating operation unit 20; And an upper controller 40 which transmits an operation signal to the power supply unit 30 and the induction heating operation unit 20, and the power supply unit 30 receives the standby power signal from the upper controller 40 to induce it. Provided is an induction heating apparatus provided with an upper controller for standby power control, characterized in that it comprises a standby power control unit 31 for controlling power supplied to the heating operation unit 20.

The upper controller 40 of the present invention includes a power supply signal processor 41 for transmitting a standby power signal to the power supply unit 30; Induction heating signal processing unit 42 for transmitting the output signal for the generation of the induction magnetic field to the induction heating operation unit 20, the standby power control unit 31 of the power supply unit 30 is an upper controller ( The induction heating operation unit 20 receives the standby power signal from 40 so that the induction heating power supply terminal having a voltage lower than the voltage supplied to the induction heating operation unit 20 and the voltage of the standby terminal is connected to the induction heating operation unit 20. Provided is an induction heating apparatus provided with a higher level controller for standby power control, characterized in that the power supply is interrupted.

In another aspect, the present invention, the warm-up signal receiving step of receiving the warm-up command signal from the upper controller 40 from the device controller (S01); Thermal insulation operation signal transmission step of transmitting a thermal insulation operation signal from the upper controller 40 to the induction heating operation unit 20 and the power supply unit 30 (S02); The working coil is connected to the induction heating operation unit 20 as a power source is supplied to the induction heating operation unit 20 from the power supply unit 30 receiving the warm operation signal and the oscillation for generating the induction magnetic field in the induction heating operation unit 20. And a heating step (S03) for generating an induction magnetic field at (12), wherein the warming operation signal transmission step (S02) is a standby signal for temporarily stopping power supply for a predetermined waiting time to the induction heating operation unit 20. A standby signal transmission step (S21) of transmitting the upper controller 40 to the power supply unit 30; Power supply signal transmission step of transmitting a power supply control signal from the upper controller 40 to the power supply unit 30 to supply power for a predetermined power supply time from the power supply unit 30 to the induction heating operation unit 20 ( S22); there is provided a control method of an induction heating apparatus equipped with a higher level controller for standby power control, comprising a.

Accordingly, the present invention is characterized in that the power supply control signal for forming the power supply time is transmitted from the upper controller 40 to the power supply unit 30 at predetermined intervals while the standby time continues continuously. Provided is a control method of an induction heating apparatus equipped with an upper controller for power control.

In addition, the heating step (S03) of the present invention receives the standby signal from the power supply unit 30 from the upper controller 40 to supply power for a predetermined waiting time from the power supply unit 30 to the induction heating operation unit 20. Standby power supply standby step (S31); Power supply step (S32) for receiving a power supply control signal from the upper controller 40 from the power supply unit 30 so that power is supplied from the power supply unit 30 to the induction heating operation unit 20 for a predetermined power supply time. ; Receives a control signal from the upper controller 40 in the induction heating operation unit 20 and receives power from the power supply unit 30 to transmit the power for generating the induction magnetic field to the working coil 12 for a predetermined heating time Provided is a control method of an induction heating apparatus provided with an upper controller for standby power control, characterized in that it comprises an operation step (S33).

And the heating operation step (S33) of the present invention is induction heating for a predetermined stabilization time before the heating time after the power supply is supplied from the power supply unit 30 to the induction heating operation unit 20 after the start of the power supply time has elapsed Provided is a control method of an induction heating apparatus provided with an upper controller for standby power control, further comprising a stabilization step (S34) of stopping power supply from the operating unit 20 to the working coil 12.

In another aspect, the present invention, the standby time of the standby signal transmission step (S21) and the power supply time of the power supply signal transmission step (S22) is a multiple of the full-wave rectified pulse signal cycle for the input voltage for standby power control, Provided is a control method of an induction heating apparatus provided with an upper controller.

Further, the present invention provides a standby power control, characterized in that the sum of the stabilization time, heating time, and standby time before and after the heating time after receiving the heating operation start signal is a multiple of the full-wave rectified pulse signal cycle with respect to the input voltage. Provided is a control method of an induction heating apparatus provided with an upper controller.

The present invention configured as described above is to reduce the consumption of unnecessary power in the standby state by the configuration of the upper controller, in order to efficiently operate the standby power by transmitting a standby signal from the upper controller to the power supply in the power supply unit It is possible to cut off unnecessary power source in standby state so that power use efficiency is excellent.

In particular, in the power supply receiving the standby signal, a low voltage is formed in the induction heating operation unit driven by a high voltage, thereby reducing power consumption due to unnecessary high voltage formation.

In addition, a predetermined safety time is given to the induction heating operation unit to which the power is supplied after the standby time, so that the members of the induction heating operation unit are initialized by a predetermined stabilization time before the heating operation to induce sufficient operation preparation. The heating operation part has an effect to operate stably.

In addition, the standby time and the power supply time are repeated with a predetermined period, but in particular, by the multiple of the pulse signal period of full-wave rectification of the input power, induction heating devices such as device controller, host controller, power supply unit, induction heating operation unit Signal transmission and reception between each member of the is made stable and efficient.

1 is a control block diagram of an induction heating apparatus according to the present invention.
2 is an exemplary view of a power supply unit of an induction heating apparatus according to the present invention.
3 is a control flowchart of the induction heating apparatus according to the present invention.
4 is a diagram illustrating an exemplary embodiment of a pulse signal transmitted for each device in the induction heating apparatus according to the present invention.
Figure 5 is an illustration of the power that may appear in one embodiment of the induction heating apparatus according to the present invention.
6 is an exemplary view for explaining the operation of the induction heating apparatus according to the present invention.
Figure 7 is an illustration of the saving power that can be calculated due to the operation of the induction heating apparatus according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

That is, the induction heating apparatus 10 equipped with the upper controller 40 of the standby power control according to the present invention supplies the working coil 12 and the electric power generated with the induction magnetic field, as shown in FIGS. Induction heating operating unit 20 for controlling the output such that the induction magnetic field is generated in the working coil 12 is configured.

And an upper controller 40 for transmitting an operation signal to the power supply unit 30 and the induction heating operation unit 20 together with the power supply unit 30 for supplying power to the induction heating operation unit 20. It is composed.

Thus, the induction heating apparatus 10 according to the present invention is not only a method of directly applying heat to a heating target like fossil fuel, but also uses a magnetic field, so it is not only superior in terms of energy efficiency but also pollution after combustion as in fossil fuel. It is an eco-friendly heating method that does not generate any substances.

In addition, because only the heating target is heated by the induction magnetic field, the risk of burns to other users or other users is reduced, and the heating is performed only when the magnetic field is applied, so that automatic adjustment and control of heating are easy to use. There are many ways to gain in various areas, such as having a convenient advantage.

In particular, induction heating apparatus employing a high frequency induction magnetic field has been researched and utilized in recent years, and the induction heating apparatus using the high frequency induction magnetic field can be conveniently used for heating cookware, as well as various other industries. It is a trend that the field is gradually expanded to be applied to the field, domestic heating device.

Among the various fields described in the present invention, the cooking utensils are described as an example to provide an easier embodiment, but are not only applicable to the cookware described above but also applied to various fields such as various industrial fields and living appliances. Of course, it can be applied.

Thus, the induction heating device 10 is provided with a working coil 12 for heating by generating an induction magnetic field on the heating target, and the induction heating inverter as a member for supplying power for generating the induction magnetic field to the working coil 12. (14) is provided.

Of course, the induction heating inverter 14 receives the general power supplied from the outside (or the power supplied in various ways, such as charging power, rechargeable battery) can be supplied to supply power to each member of the induction heating device 10 The power supply unit 30 is provided, and may also include an induction heating operation unit 20 for supplying power to the working coil 12 by receiving power for generating an induction magnetic field from the power supply unit 30. will be. As the detailed configuration of the induction heating operation unit 20, an oscillation circuit, a resonance configuration, a resonance frequency control member, a signal processing member, and the like may be provided, and at least one of members such as BJT, FET, IGBT, and GTO. It may also be included.

The power supply unit 30 may be provided as a multi-output power supply (eg, SMPS, Switching Mode Power Supply) that can supply power to a plurality of members in a variety of power supply methods. This is because the various components of the induction heating apparatus 10 may be different in strength of power suitable for each operation, so that a plurality of outputs to the power suitable for each member, thereby making the power supply efficiency.

Therefore, as shown in FIG. 2, power is individually supplied to various components of the induction heating apparatus 10 by various types of output power. 2 shows an example of the output of the power supply unit 30, it is shown that the output to 5.2V, 7.8V, 15V, 20V, etc., respectively, it is shown that the individual members are operated by the appropriate power supply.

Usually, the induction heating apparatus 10 receives a start signal of the heating operation by a user's operation, and then performs the heating operation according to a predetermined control procedure. That is, the operation signal of the user is input through an operation panel (not shown) to operate the device controller 50, and the operation signal of the device controller 50 is the power supply unit 30 and the induction heating operation unit 20. It is finally delivered to the induction magnetic field is generated by the control method determined in the working coil 12.

However, the shape and position of the heating object to be heated may be changed according to the strength of the magnetic field generated in the working coil 12, and the intensity of the induction magnetic field generated in the working coil 12 should also be changed accordingly. In order to control this, a control operation such as changing the oscillation frequency is performed.

In addition, the command of the warming operation is transmitted from the device controller 50 to the upper controller 40, and in the upper controller 40 to transmit the control signal for the operation to the power supply unit 30 and the induction heating operation unit 20. do.

In particular, the upper controller 40 transmits a control command to the power supply unit 30 so that the standby time is maintained so that the heating is waited only for a predetermined time and the heating is waited when the heating operation is not performed. In other words, the host controller 40 transmits a standby signal to the power supply unit 30 to temporarily wait (stop) application of power supplied to the induction heating operation unit 20.
That is, as shown in FIGS. 4 and 6, if the warming command for the heating operation is performed, the warming operation is performed. The warming operation has a predetermined warming cycle time Ta, and the predetermined warming cycle time Ta is a predetermined heating time ( Tb) and a predetermined waiting time (Tc), and the repeated predetermined warming cycle time (Ta) including the predetermined heating time (Tb) and the predetermined waiting time (Tc) is repeated at regular intervals, whereby the warming operation is performed. will be. Of course, a predetermined stabilization time Td may be provided before and after the predetermined heating time Tb in the predetermined warming cycle time Ta.

In order to process the signal for this, the power supply unit 30 receives a standby power signal from the upper controller 40 is provided with a standby power intermittent 31 to control the power supplied to the induction heating operation unit 20. Will be.

That is, the standby power control unit 31 of the power supply unit 30 receives the standby power signal from the upper controller 40 and has a voltage lower than the voltage supplied to the induction heating operation unit 20 (for example, 5.2V). The standby terminal ("5.2P" portion of Figure 4) and the induction heating power supply terminal ("20P" portion of Figure 4) higher than the voltage of the standby terminal (for example, 20V) is connected to the induction heating operation unit ( 20) Interrupt the power to the power supply. That is, the induction heating power supply terminal to achieve a low voltage of 5.2V, the operation of the induction heating operation unit 20 is temporarily suspended by the formation of a voltage lower than the voltage required for operation in the induction heating operation unit 20, It also reduces unnecessary power.

As a result, the standby signal of the upper controller 40 is received by the standby power control unit 31 of the power supply unit 30 to stop the power supply to the induction heating operation unit 20 temporarily.

When the power supply control signal for supplying power is transmitted from the upper controller 40 to the power supply unit 30, the standby power control unit 31 operates by the received signal to supply power to the induction heating operation unit 20. It is authorized. Therefore, the induction heating operation unit 20 is to generate an induction magnetic field by supplying power to the working coil 12 by the oscillation.

The generation of such a standby signal and a power supply control signal are repeated at regular intervals, such that the heating operation by the power supply control is performed in a warm state with a cycle.

The upper controller 40 has a power supply signal processor 41 for transmitting a standby power signal to the power supply unit 30 and an output signal for generation of an induction magnetic field to the induction heating operation unit 20. It is configured to include an induction heating signal processor 42 for transmitting the. Therefore, the upper controller 40 transmits a control signal to the power supply unit 30 through the power supply signal processing unit 41, and a standby signal and a power supply control signal are transmitted. In addition, the control signal is transmitted to the induction heating operation unit 20 through the induction heating signal processing unit 42, and the control includes a heating operation start signal (or a termination signal), or in some embodiments, a start signal of stabilization. The signal is sent.

In the induction heating apparatus 10 according to the present invention provided in this way is to control the power supply and the generation of the induction magnetic field by the upper controller 40, in particular, the control of the standby time during the warm-up operation to the upper controller 40 It is characterized by that.

Looking at the embodiment of the control method in the induction heating apparatus 10 provided with the upper controller 40 of the standby power control according to the present invention as described above are as follows.

First, a warm signal receiving step (S01) of receiving a warm command signal from the device controller 50 from the upper controller 40 is performed.

Processing the signal of this warming operation will be carried out according to the general processing procedure in the induction heating apparatus. That is, the user inputs a signal of an operation through an input member (not shown), which becomes an operation panel of the induction heating apparatus 10, and the signal of thermal insulation is connected to the device controller 50 through an input member (not shown). ) And stored in a memory (not shown) provided together. The warming signal is processed by a processing processor stored in a memory (not shown), and an indication of the warming state will be displayed on a display device (not shown), and the set temperature in the induction heating device 10 will be described. In some embodiments, the operation step or the current temperature may be displayed on a separate display device (not shown). Detailed descriptions of the operation member and the processing processor in the general induction heating apparatus will be omitted.

The control signal for the warm operation is transmitted from the device controller 50 to the upper controller 40, and processing the signal of the operation control such as the supply of power or the oscillation, the resonance, etc., and the control signal to the respective members. It is sent from the controller 40.

That is, the warm operation signal transmission step S02 of transmitting the warm operation signal from the upper controller 40 to the induction heating operation unit 20 and the power supply unit 30 is performed.

Then, the power is supplied from the power supply unit 30 receiving the warm operation signal to the induction heating operation unit 20, and the induction heating operation unit 20 is connected to the induction heating operation unit 20 as an oscillation for generating an induction magnetic field. The heating step S03 is performed to generate an induction magnetic field in the coil 12.

In particular, the warm operation signal transmission step (S02), the standby signal for transmitting the standby signal for stopping the power supply for a predetermined waiting time to the induction heating operation unit 20 from the upper controller 40 to the power supply unit 30 side. Transmitting step (S21) and the power supply control signal to the power supply to the induction heating operation unit 20 in a predetermined power supply time for a predetermined power supply time from the upper controller 40 to the power supply unit 30 side. This is performed by the power supply signal transmission step (S22).

That is, while the standby time continues continuously, the standby signal and the power supply control signal are predetermined from the upper controller 40 to the power supply unit 30 so that the power supply control signal in which the power supply time is formed forms a predetermined period. It will be sent to have a cycle.

On the other hand, in the heating step (S03), receiving the standby signal from the power supply unit 30 from the upper controller 40, the power supply from the power supply unit 30 to the induction heating operation unit 20 for a predetermined standby time temporarily Standby power supply standby step (S31) is to be performed.

In addition, the power supply step of receiving the power supply control signal from the power supply unit 30 from the upper controller 40 to supply power for a predetermined power supply time from the power supply unit 30 to the induction heating operation unit 20 (S32). ) Is performed.

As described above, the upper controller 40 repeatedly transmits the standby signal and the power supply control signal to the power supply unit 30 with a predetermined period, and the power repeatedly received the standby signal and the power supply control signal with the predetermined period. The supply unit 30 waits for power supply or supplies power to the induction heating operation unit 20.

According to an embodiment of the preferred operation, the upper controller 40 will transmit the operation signal of the thermal insulation to the power supply unit 30, in particular through the power supply signal processing unit 41 of the upper controller 40, the standby signal ( When the standby signal is transmitted, the standby signal is received by the standby power control unit 31 of the power supply unit 30.

2 and 4, when a signal of a standby signal is transmitted from the upper controller 40 to the power supply unit 30, the standby of the power supply unit 30 is performed. The power interruption unit 31 receives a standby signal (for example, a standby signal in the area D of FIG. 4) to receive a low voltage and a terminal (point 20P) for supplying power to the induction heating operation unit 20. The standby terminals (5.2P points) are operated to be connected to each other. Of course, the standby time and the power supply time which are repeated at predetermined intervals are provided, and the power supply control signal of the power supply time (for example, the standby signal portion corresponding to the "A + B + C" region of FIG. 4) is transferred from the upper controller 40. It will be sent to the power supply 30.

When the induction heating operation unit 20 is set to a voltage for operation, the standby signal (Standby signal) of the power supply terminal (20P point) and the standby state of the induction heating operation unit 20 having a high voltage Standby terminals (5.2P point, when implemented at a low voltage of 5.2V) to maintain the state is energized with each other, so the power supply terminal (20P point) of the induction heating operation unit 20 is also low voltage (5.2V) In the embodiment) will be formed. Therefore, the induction heating operation unit 20 must be supplied with a high voltage (for example, 20 V) to operate, but the induction heating operation is performed in the standby state because it is energized with a low voltage (for example, 5.2 V) of the standby terminal. The unit 20 is not operated.

In addition, in the induction heating apparatus 10 according to the present invention, the induction heating power supply terminal (20P point) for supplying a standby terminal (5.2P point, eg 5.2V) and induction heating operation unit 20 having a low voltage In addition, it is used as a multi-output power supply formed with a plurality of output terminals (for example, 15P point (15V), 7.8P point (7.8V), etc.) for supplying power to the other components of the induction heating device 10. Will be. Therefore, when the standby terminal (5.2P point) and other output terminals (20P, 15P, 7.8P, etc.) forming a low voltage is connected during the standby time, the standby power consumed during the standby time can be reduced.

In most cases, there are many members that do not need much power in the standby time, so that the power supply terminals connected to these members are connected to the low voltage standby terminals so as not to operate for a predetermined standby time, thereby eliminating unnecessary waste of standby power. Could be reduced. In this example, although there may be a slight difference depending on the specifications, installation conditions, etc. of the installation components of the induction heating apparatus 10 to be installed, the voltage of the output terminal in the power supply unit 30 is a multi-output power supply 20V, In case of 15V, 7.8V, 5.2V, etc., when power is supplied to each output terminal even during heating time, if the power consumption is about 5W, relatively high voltage terminals are low voltage standby terminals. When the standby state is maintained in connection with the system, only about 0.3W of standby power is consumed, such that unnecessary power consumption in standby time can be greatly reduced.

That is, since the rest of the terminals are applied with the low voltage (eg 5.2V) of the standby terminal during the standby time, the members operating at the high voltage pause the operation during the standby time to reduce unnecessary power consumption.

The heating operation step by the induction heating operation unit 20 in the heating step S03 together with the operation of the upper controller 40 and the power supply unit 30 will be performed.

That is, the induction heating operation unit 20 receives a control signal from the upper controller 40 and receives power from the power supply unit 30 to transmit power for generating an induction magnetic field to the working coil 12 for a predetermined heating time. The heating operation step (S33) is to be performed.

Accordingly, while power (eg, 20V) is being supplied from the power supply unit 30, the induction heating operation unit 20 receives a heating operation start signal from the upper controller 40 (eg, a signal in the area “B” in FIG. 4). Resonance frequency is oscillated by the constituent members for the operation such as oscillation, resonance by receiving the, and the induction magnetic field is generated in the supplied working coil 12. Of course, heating objects (cooking utensils, pots, etc.) are placed in the induction magnetic field region generated by the working coil 12, and thus heating will be performed.

In addition, a configuration is provided in which the induction heating operation unit 20 temporarily suspends the power supply during the standby time, and then provides the induction heating operation unit 20 with a time for stabilization before the power is supplied again to perform the heating operation. Can be.

In other words, the heating operation step (S33) is the induction heating operation unit for a predetermined stabilization time before the heating time after the start of the power supply time is supplied from the power supply unit 30 to the induction heating operation unit 20 A stabilizing step (S34) for stopping the power supply to the working coil 12 in 20) may be further included.

According to this stabilization step (S34) (for example, "A", "C" portion of FIG. 4), the power supply unit through the power supply time (power supply signal transmission step, power supply step) by the power supply unit 30 Power is supplied to the induction heating operation unit 20 at 30, whereby the induction magnetic field generation may be performed in the induction heating operation unit 20 through a process such as oscillation and resonance. However, while the initial power is supplied, the process of initializing the other members of the induction heating operation unit 20 is required by the power supply, and the optimal induction magnetic field can be generated while the initialization process is made stable, thereby inducing the induction magnetic field generation. The efficiency may be further improved. Of course, given a predetermined stabilization time (for example, the "C" portion of Figure 4) even after the heating operation, it is possible to perform the preliminary processing of the next operation, it is preferable to switch to the standby time when the power supply is paused in this state. will be.

The stabilization step may be performed by a suitable member according to the implementation and installation of the induction heating apparatus 10. That is, the heating time (eg, the portion of "B" of FIG. 4) may be set shorter than the power supply time (eg, the portion of "A + B + C" of FIG. 4) except for the standby time, and thus the remaining time range. May be applied as a stabilization time (eg, “A” and “C” portion of FIG. 4).

When set to such an operation time, the standby signal of the standby time, the power supply control signal of the power supply time, etc. will be transmitted from the upper controller 40 to the power supply unit 30. In the state where power is supplied to the induction heating operation unit 20, the heating operation start signal is transmitted from the upper controller 40 to the induction heating operation unit 20, so that the induction heating operation is performed by generating resonance.

Therefore, the implementation of the stabilization time may have a variety of control signal transmission aspects.

In the first embodiment of the present invention, by transmitting the power supply control signal from the upper controller 40 to the power supply unit 30, it is also transmitted to the induction heating operation unit 20, in the induction heating operation unit 20 It may be arranged to count the start time of the power supply time. In the induction heating operation unit 20 may be performed so that the heating operation is performed after the stabilization time has elapsed by calculating the stabilization time (such as a delay element) after the start time of the power supply time. In this case, the heating operation start signal transmitted from the upper controller 40 to the induction heating operation unit 20 is transmitted simultaneously with the power supply control signal transmitted to the power supply unit 30, and then the stabilization time is induced. After the calculation in the unit 20 will perform the heating operation. That is, the calculation for the stabilization time may be performed to be performed by the induction heating operation unit 20.

Referring to the second embodiment, the power supply control signal is transmitted from the upper controller 40 to the power supply unit 30 so that power is supplied to the induction heating operation unit 20. After the power is supplied to the induction heating operation unit 20, the upper controller 40 counts the stabilization time, and then transmits a heating operation start signal to the induction heating operation unit 20, thereby stabilizing the induction heating operation unit. After the elapsed time, the heating operation is received by receiving the control signal of the heating step. That is, in the second embodiment, the operation for the stabilization time may be performed by the upper controller 40.

Calculation of the stabilization time according to other installation situation or if necessary can be carried out using a variety of members, accordingly, after the power is supplied to the induction heating operating unit 20, through the stabilization time by the stabilization step (S34) By induction heating operation to be made, it is provided to ensure a stable operation while preventing the members of the induction heating operation unit 20 is damaged.

An embodiment of the induction heating apparatus 10 having the higher level controller of standby power control according to the present invention provided as described above will be described with reference to the accompanying drawings.

In the present invention, the signal transmitted and received between the device controller 50, the host controller 40, the power supply unit 30, the induction heating operation unit 20, etc. is preferably used as a pulse signal, in particular input power (eg It is desirable to use a pulse signal of full wave rectification for 120V, or 220V, 60Hz). Therefore, as shown in FIG. 4, when the full wave rectification pulse signal of the input power becomes 120 Hz, the period will be 8.3 ms. Accordingly, the signal transmission of each member is performed in multiples of the period of the full wave rectification pulse signal. Could be 4, the upper pulse signal Fosc (oscillation frequency) shows the pulse signal (8.3 ms) of full-wave rectification with respect to the input side power source. In the middle of FIG. A pulse signal is shown for a standby signal (Example 1s) and a power supply control signal (approximately 15s) transmitted to the supply unit 30. 4 illustrates a pulse signal of a heating operation start signal and an end signal (approximately 800 ms) transmitted from the upper controller 40 to the induction heating operation unit 20. 4, the stabilization time between the heating time of the induction heating operation part 20 after the end of the standby time of the power supply unit 30, and the stabilization time between the start of the standby time of the power supply unit 30 after the heating time is terminated It was set to the same 100ms, it is natural that the stabilization time before and after the heating time may be set differently as necessary.

In addition, the pulse signal (e.g., 8.3ms) of full-wave rectification of the input power may be approximately 12 times during one stabilization time (e.g., 100ms), and the pulse signal of full-wave rectification of the input power may be approximately 12 times during the heating time (e.g., 800ms). (E.g. 8.3ms) may be approximately 96 times. Therefore, although the pulse signal interval of the full wave rectification of the input power source shown in FIG. 4 is shown to be somewhat different, this is one period (one period consisting of "A", "B", "C", and "D" in FIG. 4). And the pulse signal of full-wave rectification of the input power supply have a multiple relationship.

That is, the standby time of the standby signal transmission step S21 and the power supply time of the power supply signal transmission step S22 may be made in multiples of the full-wave rectified pulse signal period with respect to the input voltage.

Similarly, the sum of the stabilization time, heating time, and standby time before and after the heating time after receiving the heating operation start signal may be implemented to be a multiple of the full-wave rectified pulse signal cycle with respect to the input voltage.

That is, the signal transmission from the induction heating apparatus 10 including the upper controller 40, the power supply unit 30, the induction heating operation unit 20, and the device controller 50 is performed by the pulse signal of the full wave rectification of the input power. It can be implemented to increase the efficiency of the signal control by being made in multiples.

By this example, after the initial warm signal reception step (S01), in the warm operation signal transmission step (S02), the standby signal for the waiting time is transmitted from the upper controller 40 to the power supply, in the middle of FIG. "Standby Signal" (approximately 15 seconds) is applicable, whereby the operation of the standby power intermittent unit 31 receives the standby signal (Standby signal) in Figure 2, the terminal of the low voltage (5.2P part, for example: 5.2V) and the terminal (20P part, for example, 20V) that is applied to the induction heating operation unit 20 is connected to each other is not a power supply suitable for operation with the induction heating operation unit 20. At the same time, power consumption is reduced due to the low voltage of other unnecessary terminals.

After that, the upper controller 40 transmits a power supply control signal (first part of “1s” of FIG. 4) to the power supply unit 30 to the power supply unit 30, thereby inducing the heating unit 20 from the power supply unit 30. ) Is supplied with power.

In the upper controller 40, after the predetermined stabilization time ("A" region of FIG. 4) has passed to the induction heating operation unit 20, the heating operation start signal for heating after approximately 100 ms has elapsed (Fig. 4) transmits the pulse signal for the "B" region to the heating operation is performed in the induction heating operating unit (20).

After the predetermined heating operation time has elapsed, the upper controller 40 transmits a signal for terminating the heating operation (rear end portion of the “B” region of FIG. 4) to the induction heating operation unit 20 to temporarily stop the heating operation. Done.

The host controller 40 counts a predetermined stabilization time (" C " portion of FIG. 4) after the heating operation, and then waits for the waiting time (" 1s " in the middle of FIG. 4) to the power supply unit 30. Transmits the standby signal for the latter part of.

As a result, the induction heating apparatus 10 is switched to the standby time again, and is operated by the standby power control unit 31 of FIG. 2 to the low voltage terminal (5.2P portion of FIG. 2) and the induction heating operation unit 20. Terminals to which power is supplied (20P part of FIG. 2) are connected to each other to temporarily stop power supply to the induction heating operation unit 20. Of course, as described above, the power supply to the members not used during the standby time is also temporarily suspended, thereby reducing unnecessary power consumption.

In addition, such a standby time-the power supply time (heating time) is implemented to be repeatedly operated with a predetermined period (about 16 seconds), which can be unnecessaryly consumed in the standby time belonging to a relatively large time zone compared to the heating operation time It has the advantage of reducing power consumption.
Referring to the configuration operation example as a description of the embodiment that can be exemplified once again with reference to the exemplary drawings shown in FIG. 4, FIG. 6, etc., the warming operation is performed when there is a warming command for the heating operation. It has a predetermined warming cycle time (Ta), the predetermined warming cycle time (Ta) is composed of a predetermined heating time (Tb) and a predetermined waiting time (Tc), such a predetermined heating time (Tb) and a predetermined waiting time ( Repeated predetermined warming cycle time (Ta) including the Tc is repeated at a predetermined period to perform the warming operation. Of course, a predetermined stabilization time Td may be provided before and after the predetermined heating time Tb in the predetermined warming cycle time Ta.
4, the predetermined warming cycle time Ta of one cycle is made of "A + B + C + D", and the predetermined heating time Tb is made of "B". It can be seen that the predetermined waiting time Tc is "D", and the predetermined stabilizing time Td is "A" and "C". In addition, an example of the predetermined warming cycle time Ta (“A + B + C + D”) of one cycle may be implemented to be 16 seconds as shown in FIG. 6, and the predetermined heating time Tb is approximately 0.8 seconds. The predetermined waiting time Tc is approximately 15 seconds, and each predetermined stabilizing time Td may be performed at about 0.1 seconds each.
Description of the above example, the predetermined warming cycle time Ta ("A + B + C + D"), the predetermined heating time Tb, "B", and the predetermined waiting time Tc in FIGS. , "D"), the above exemplary numerical time for the predetermined stabilization time (Td, "A", "C") and the like are the numerical values in the embodiment when preferably performed to explain the present invention, the induction heating is carried out In the case where the environmental configuration is different, such as the object, the installation situation of the present invention, and other components such as electric power or elements, it is natural that the above example configuration times will be changed and processed accordingly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The technical idea of the present invention should not be construed as being limited.

10: induction heating device 12: working coil
14: induction heating inverter 20: induction heating operating unit
30: power supply unit 31: standby power control unit
40: upper controller 41: power supply signal processing unit
42: induction heating signal processor 50: device controller

Claims (8)

Induction heating operation unit for supplying power to generate an induction magnetic field in the working coil;
A power supply unit supplying power to the induction heating operation unit;
And an upper controller which transmits an operation signal to the power supply unit and the induction heating operation unit.
In the induction heating apparatus including a standby power interrupting unit for receiving the standby power signal from the upper controller to interrupt the power supplied to the induction heating operation unit,
The host controller is:
A power supply signal processing unit for transmitting a standby power signal to the power supply unit;
And an induction heating signal processor for transmitting an output signal for generating an induction magnetic field to the induction heating operation unit.
The standby power control unit of the power supply unit receives a standby power signal from an upper controller to connect an induction heating power supply terminal having a voltage lower than a voltage supplied to the induction heating operation unit and a voltage higher than that of the standby terminal. Induction heating apparatus having a higher controller for standby power control, characterized in that to interrupt the power supplied to the operating unit.
delete Receiving a warm command signal from a device controller at a higher controller;
A thermal insulation operation signal transmission step of transmitting a thermal insulation operation signal from an upper controller to an induction heating operation unit and a power supply unit;
A heating step in which power is supplied from the power supply unit receiving the warm operation signal to the induction heating operation unit and the induction magnetic field is generated in the working coil connected to the induction heating operation unit as the oscillation for generating the induction magnetic field in the induction heating operation unit; and,
The warm operation signal transmission step is:
A standby signal transmission step of transmitting a standby signal for stopping a power supply for a predetermined waiting time to an induction heating operation unit from a higher controller to a power supply side;
A power supply signal transmitting step of transmitting a power supply control signal from the upper controller to the power supply unit for supplying power for a predetermined power supply time from the power supply unit to the induction heating operation unit; Control method of induction heating apparatus equipped with a controller.
The method of claim 3, wherein
Induction with higher controller for standby power control, characterized in that the power supply control signal to form the power supply time is transmitted from the upper controller to the power supply unit at a predetermined interval while the standby time continues continuously. Control method of heating device.
The method of claim 3, wherein
The heating step is:
A power supply standby step of receiving a standby signal from the upper controller from the power supply unit and temporarily suspending the power supply for a predetermined waiting time from the power supply unit to the induction heating operation unit;
A power supply step of receiving a power supply control signal from a higher level controller from a power supply unit to supply power from the power supply unit to the induction heating operation unit for a predetermined power supply time;
A heating operation step of receiving a control signal from an upper controller in an induction heating operation unit and receiving power from a power supply unit to transmit power for generating an induction magnetic field to a working coil for a predetermined heating time; Control method of induction heating apparatus having a higher level controller for control.
6. The method of claim 5,
The heating operation step is a stabilization step of supplying power from the power supply to the induction heating operation unit to stop the power supply to the working coil in the induction heating operation unit for a predetermined stabilization time before the heating time after the start of the power supply time has elapsed Control method of the induction heating apparatus provided with a higher controller for standby power control, characterized in that it further comprises.
The method of claim 3, wherein
The standby time of the standby signal transmission step and the power supply time of the power supply signal transmission step are controlled by an induction heating apparatus equipped with an upper controller for standby power control, characterized in that the multiple of the full-wave rectified pulse signal period for the input voltage. Way.
The method according to claim 6,
After receiving the heating operation start signal, the stabilization time before the heating time, the heating time, the stabilizing time after the heating time, and the sum of the standby time are multiples of the full-wave rectified pulse signal cycle with respect to the input voltage. Control method of induction heating apparatus equipped with a higher level controller.

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