JP5458903B2 - Induction heating cooker and program thereof - Google Patents

Description

  The present invention relates to an induction heating cooker having multiple mouths.

  Conventionally, this type of induction heating cooker causes a high-frequency current of several tens of kilohertz to flow through a heating coil for induction heating below the top plate, and generates eddy current loss in the cooking vessel placed on the top plate. By heating.

  FIG. 4 shows a block diagram of a conventional induction heating cooker.

  As shown in FIG. 4, a rectifier circuit 107 (107a, 107b) that converts AC power into DC, an inverter 103 (103a, 103b) that is connected to the rectifier circuit 107 and converts it into a high-frequency current, and a high-frequency by the high-frequency current. A heating coil 102 (102a, 102b) that generates a magnetic field and heats the article to be heated 108 (108a, 108b), a power input current detection circuit 104 (104a, 104b) that detects a power input current of the inverter 103, and the inverter The control means 105 (105a, 105b) for controlling the operating frequency 103 is present for each inverter and controls the heating of each inverter. Then, while heating the input current, the heating coil current, and the heating coil voltage, the optimum heating heating power is applied to the object to be heated.

  For the purpose of miniaturization, there is a common rectifier circuit for multiple ports, and each inverter has a power supply current detection circuit that detects the input current of the inverter. A method for sharing the rectifier circuit and choke coil, etc. Has been proposed (see, for example, Patent Documents 1 and 2).

JP 2004-165127 A JP 2008-210743A

  However, in the conventional configuration, as the number of units increases, the number of parts such as a rectifier circuit, a choke coil, or a power supply current detection circuit increases in the same manner, and there is a problem that the size increases.

  The present invention solves the above-described conventional problems, and can reduce the cost and size by sharing a rectifier circuit and a power input detection circuit for multiple ports, and can control individual inverters. An object is to provide a cooking device.

In order to solve the conventional problems, an induction heating cooker according to the present invention includes a top plate, a plurality of heating coils including a first heating coil and a second heating coil provided below the top plate, A first inverter that includes one switching element and supplies a high-frequency current to the first heating coil; a second inverter that supplies a high-frequency current to the second heating coil; and an input current of the first inverter and a second inverter A power supply current detection circuit for detecting a power supply current flowing in a current path on which an input current is superimposed; and the first power supply current is set to a first output set value when only the first heating coil is heating. A first control unit that controls on / off of the switching element, and a control so that the power supply current becomes the second output set value when only the second heating coil is heating. When the first heating coil starts a heating operation when the second heating coil is heating at the second output set value, the first control unit The drive time of the first switching element is controlled so that the increase amount of the power supply current with respect to when the heating coil is stopped becomes a value corresponding to the first output set value, and the first heating coil and the When the power supply current decreases by a predetermined value or more when the second heating coil is operating together, the drive time of the first switching element is changed for a predetermined time alone, and the amount of change in the magnitude of the power supply current at that time Is less than the first predetermined value for determination, the heating operation of the first heating coil is stopped, and when the amount of change in the power supply current is larger than the first predetermined value, the heating of the first heating coil is stopped. Continue operation Further, the second control unit independently changes the driving time of the second switching element for a predetermined time, and when the amount of change in the magnitude of the power supply current at that time becomes equal to or less than a second predetermined value for determination, (2) The control unit stops the heating operation of the second heating coil, and continues the heating operation of the second heating coil when the amount of change in the magnitude of the power supply current is larger than the second predetermined value. It is.

  As a result, in the case of controlling the heating of the plurality of inverters, the first or second control unit corresponding to each of the plurality of heating coils is configured so that the increase amount of the power supply current due to the heating operation of each heating coil is the respective output set value. When the first heating coil and the second heating coil are both operating and the power supply current decreases by a predetermined value or more, the driving time of the switching element of the first or second inverter is controlled. By independently changing the power supply current for a predetermined time and stopping or continuing the heating operation of the heating coil from the amount of change in the power supply current at that time, a common power supply current is not used for each inverter. Heating control is possible with the detection circuit.

  In the induction heating cooker of the present invention, the circuit configuration is simplified, and the cost can be reduced and the size can be reduced by reducing the number of parts.

The block diagram of the induction heating cooking appliance in Embodiment 1 of this invention The figure which shows the heating operation | movement of the some heating coil of the induction heating cooking appliance in Embodiment 1 of this invention, and the change of input current. The flowchart of the induction heating cooking appliance in Embodiment 1 of this invention Block diagram of a conventional induction heating cooker

A first invention includes a top plate, a plurality of heating coils including a first heating coil and a second heating coil provided below the top plate, a first switching element, and a high frequency current to the first heating coil. A first inverter for supplying, a second inverter for supplying a high-frequency current to the second heating coil, and a power supply current flowing in a current path in which the input current of the first inverter and the input current of the second inverter are superimposed. A power supply current detection circuit for detecting, and a first control unit for controlling on / off of the first switching element so that the power supply current becomes a first output set value when only the first heating coil is heated. A second control unit that controls the power supply current to be a second output set value when only the second heating coil is heating, and the second heating coil When heating is performed at the second output set value and the first heating coil starts a heating operation, the first control unit increases the power supply current with respect to when the first heating coil is stopped. When the drive time of the first switching element is controlled so that becomes a value corresponding to the first output set value, and the first heating coil and the second heating coil are both operating, Is decreased by a predetermined value or more, the driving time of the first switching element is independently changed for a predetermined time, and when the amount of change in the magnitude of the power supply current at that time becomes a first predetermined value or less for determination, the first heating is performed. When the heating operation of the coil is stopped and the amount of change in the power supply current is larger than the first predetermined value, the heating operation of the first heating coil is continued, and the second control unit further controls the second control unit. Switching When the driving time of the child is changed for a predetermined time alone, and the amount of change in the magnitude of the power supply current at that time becomes equal to or less than a second predetermined value for determination, the second control unit heats the second heating coil. When the operation is stopped and the amount of change in the power supply current is larger than the second predetermined value, the heating operation of the second heating coil is continued, whereby the input current of the first inverter and the first current 2 The power supply current detection circuit for detecting the power supply current flowing in the current path where the input current of the inverter is superimposed can set the heating output of the first heating coil and the second heating coil, so that the detection circuit configuration is simplified and the number of parts is reduced. The cost can be reduced and the size can be reduced by reducing the cost. Further, when both the first heating coil and the second heating coil are operating, it is possible to detect that the power source current is decreased by a predetermined value or more, so that an object to be heated of any heating coil is displaced from the heating coil. Can be detected. In the first control unit and the second control unit, when the drive time of the first switching element and the second switching element is independently changed for a predetermined time, the amount of change in the power supply current becomes a predetermined value or less. By detecting this, it can be determined whether the object to be heated has shifted from the first heating coil or whether the object to be heated has shifted from the second heating coil. That is, when the object to be heated deviates from the first heating coil being heated, the magnetic coupling between the first heating coil and the object to be heated decreases, so that the first control unit reduces the drive time of the first switching element. The amount of change in the magnitude of the power supply current when each of them is changed for a predetermined time is not more than a predetermined value. The same applies when the object to be heated deviates from the second heating coil being heated.

  In particular, according to the second invention, in the first invention, since the power source current detection circuit is provided after the rectifier circuit for converting the AC power source into DC, the common rectifier is not used for each inverter. Control using a circuit and a common power supply current detection circuit is possible, and the cost can be reduced and the size can be reduced by further reducing the number of components.

  In the third invention, in particular, the control unit of the first or second invention switches the predetermined value for determination according to the AC power supply voltage value. Since the difference in the amount of change can be corrected, the detection accuracy with respect to the deviation of the object to be heated is improved, unnecessary heating stop is reduced, and user convenience can be improved.

  According to a fourth aspect of the invention, in particular, in any one of the first to third aspects of the invention, the temperature detection means for detecting the temperature of the object to be heated is provided by a signal from the temperature sensor, and the control unit is responsive to the temperature. By switching the predetermined value for judgment, the influence on the amount of change in the power supply current due to the temperature characteristics of the object to be heated can be mitigated, so the detection accuracy for the deviation of the object to be heated is improved and unnecessary heating is stopped. Can be reduced and user convenience can be improved.

  In particular, the fifth aspect of the invention includes the operation unit that outputs a signal to the control unit so as to change the set thermal power in any one of the first to fourth inventions, and the control unit is a combination of the set thermal powers. By switching the predetermined value for determination according to the above, it is possible to reduce the influence on the amount of change in the magnitude of the power supply current due to the setting of the thermal power, so that the detection accuracy for the deviation of the object to be heated is improved and unnecessary heating is stopped. As a result, the user's convenience can be improved.

  In the sixth aspect of the invention, in particular, in the fifth aspect of the invention, when the setting thermal power is changed in the operation section, the inverter with change side is temporarily stopped and the output power of the inverter without change is set to output. After setting the value, the output power of the inverter with change is set to the output setting value, so that the distribution of the power supply current is made in the correct state, there is no deviation from the output setting for each inverter, and cooking can be performed according to the set heating power Therefore, safety can be improved.

In particular, the seventh invention is at least one of the induction heating cookers according to any one of the first to sixth inventions.
A program for causing a computer to execute one of them is provided. Since it is a program, at least a part of the induction heating cooker of the present invention can be easily realized by cooperating hardware resources such as an electric / information device, a computer, and a server. In addition, the program can be distributed / updated and installed easily by recording on a recording medium or distributing the program using a communication line.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a block diagram of an induction heating cooker according to the first embodiment of the present invention, and FIG. 2 is a heating operation and input of a plurality of heating coils of the induction heating cooker according to the first embodiment of the present invention. It is a figure which shows the change of an electric current.

  In FIG. 1, a top plate 1, a plurality of heating coils including a first heating coil 2a and a second heating coil 2b provided below the top plate 1, and a first switching element including the first heating coil 2a. The first inverter 3a for supplying high-frequency current to the second inverter 3b for supplying high-frequency current to the second heating coil 2b, the input current of the first inverter 3a and the input current of the second inverter 3b are superimposed. A power source current detection circuit 4 for detecting a power source current flowing in a current path, and the first switching element so that the power source current becomes a first output set value when only the first heating coil 2a is heating. When only the first control unit 5a for controlling on / off and the second heating coil 2b are heating, the power supply current becomes the second output set value. It constitutes a second controller 5b controls the.

  Further, in FIG. 2, when the second heating coil is heating at the second output set value (I1), the first control unit 5a and the second control unit 5b start the heating operation (T1). Then, the first control unit controls the drive time of the first switching element so that the increase amount of the power supply current with respect to when the first heating coil is stopped becomes a value corresponding to the first output set value. Thereby, the heating output of the first heating coil and the second heating coil can be set.

  The induction heating cooker configured as described above will be described below using its operation and action.

  FIG. 3 shows a flowchart of the induction heating cooker in the first embodiment of the present invention.

  In FIG. 3, when an operation means (not shown) for performing cooking selection or heating off / on operation is selected, cooking on the first heating coil 2a side is selected, and when the heating key is pressed, a signal is sent to the first control unit 5a. The heating of the first heating coil 2a is started (step S1).

  The first controller 5a increases the drive time until the power supply current value of the power supply current detection circuit 4 reaches the output set value (step S2).

  After the output of the first heating coil 2a reaches the output set value, when cooking on the second heating coil 2b side is selected and the heating key is pressed, a signal is transmitted to the second control unit 5b, and the heating of the second heating coil 2b is performed. Is started (step S3).

The second controller 5b increases the drive time of the switching element until the power supply current value of the power supply current detection circuit 4 reaches the output set value (step S4). Even if the cooking on the first heating coil 2a side and the cooking on the second heating coil 2b side receive a heating start instruction at the same time, the heating coil side that has received the heating start command earlier reaches the output set value first. Then, the output setting is performed in order such that the other heating coil side is made to reach the output set value next.

  In addition, the position of the object to be heated may be shifted from the beginning, and the power supply current value may not reach the output set value. In this case, control cannot be performed when determining whether the output set value has been reached (the object to be heated is not heated). If it cannot be controlled, heating is stopped.

  For example, if the first heating coil 2a side cannot be controlled, cooking on the first heating coil 2a side is stopped, and if the second heating coil 2b side cannot be controlled, cooking on the second heating coil 2b side is stopped.

  If control is possible, the output can be limited by the switching element drive time, the heating coil current, the heating coil voltage, and the like. Let S4 pass.

  Next, in the state where both the first heating coil 2a and the second heating coil 2b are heated, in order to know the state of the object to be heated 8a on the first heating coil 2a, the driving time of the first switching element is set independently. It is changed for a predetermined time (step S5), and the amount of change in the magnitude of the power supply current at that time is acquired (step S6).

  It is determined whether or not the amount of change in the magnitude of the power supply current is equal to or less than a first predetermined value for determination (step S7). In the following cases, it is determined that control is not possible, and heating cooking of the first heating coil 2a is stopped. (Step S8).

  When the amount of change in the power supply current is larger than the first predetermined value, it is determined that the first heating coil 2a can be controlled, and this time to know the state of the object to be heated 8b on the second heating coil 2b. The drive time of the second switching element is changed for a predetermined time alone (step S9), and the amount of change in the power supply current at that time is acquired (step S10).

  It is determined whether or not the amount of change in the magnitude of the power supply current is equal to or less than a second predetermined value for determination (step S11). In the following cases, it is determined that control is not possible, and heating cooking of the second heating coil 2b is stopped. (Step S12).

  If the amount of change in the magnitude of the power supply current is larger than the second predetermined value, it is determined that the second heating coil 2b can be controlled, and step S5 can be performed.

  After stopping the first heating coil 2a in step S8, it is confirmed whether or not the first heating coil 2a can be heated (controllable state) (step S13). If heating is possible, the heating of the first heating coil 2a is performed. Is started (step S14).

  The first controller 5a increases the drive time of the switching element until the power supply current value of the power supply current detection circuit 4 reaches the output set value (step S15). After the output of the first heating coil 2a reaches the output set value, step S5 can be performed.

  After stopping the second heating coil 2b in step S12, it is confirmed whether or not the second heating coil 2b can be heated (controllable state) (step S16). If the heating is possible, the second heating coil 2b is heated. Is started (step S17).

The second controller 5b increases the drive time until the power supply current value of the power supply current detection circuit 4 reaches the output set value (step S18). After the output of the second heating coil 2a reaches the output set value, step S5 can be performed.

  In the determination based on the amount of change in the power supply current, a step of performing determination when the power supply current value is equal to or less than a predetermined value with respect to the first output set value + the second output set value immediately before step S5. In order to check whether heating is possible (controllable state), the operation of changing the switching element drive time independently for a predetermined time is prevented from being frequently performed and used. It is possible to remove the influence of the fine adjustment of the position of the person to be heated and the vibration.

  In the determination based on the change amount of the power supply current, the change amount of the power supply current when the drive time of the first switching element is changed for a predetermined time when the output set value of the first inverter 3a is reached. Next, when the output set value of the second inverter 3b is reached, the amount of change in the magnitude of the power supply current when the drive time of the second switching element is changed for a predetermined time alone is obtained, The continuation or stop of the heating operation can be determined based on the difference between the change amount and the current change amount of the first and second power supply currents.

  As described above, in the present embodiment, the top plate 1, the plurality of heating coils including the first heating coil 2a and the second heating coil 2b provided below the top plate 1, and the first switching element are provided. A first inverter 3a for supplying a high-frequency current to the first heating coil 2a, a second inverter 3b for supplying a high-frequency current to the second heating coil 2b, an input current of the first inverter 3a, and the second inverter A power supply current detection circuit 4 for detecting a power supply current flowing in a current path on which an input current of 3b is superimposed, and the power supply current becomes a first output set value when only the first heating coil 2a is heating. When only the first control unit 5a for controlling on / off of the first switching element and the second heating coil 2b are heating, the power supply current is And a second control unit 5b that controls the output value to be a two-output set value, and when the second heating coil 2b is heated at the second output set value, the first heating coil 2a starts a heating operation. Then, the first control unit 5b is configured so that the amount of increase in the power supply current when the first heating coil 2a is stopped becomes a value corresponding to the first output set value. While controlling the driving time, and when the first heating coil 2a and the second heating coil 2b are operating together, if the power supply current decreases by a predetermined value or more, the driving time of the first switching element is set independently. If the amount of change in the magnitude of the power supply current at that time is less than or equal to a first predetermined value, the heating operation of the first heating coil 2a is stopped, and the amount of change in the magnitude of the power supply current is the first amount. Predetermined When larger than the first predetermined value, the heating operation of the first heating coil 2a is continued, and the driving time of the second switching element is changed for a predetermined time independently, and the power source at that time When the change amount of the current becomes equal to or smaller than the second predetermined value, the second control unit 5b stops the heating operation of the second heating coil 2b, and the change amount of the power supply current becomes the second change amount. When larger than a predetermined value, by continuing the heating operation of the second heating coil 2b, the power source that flows through the current path in which the input current of the first inverter 3a and the input current of the second inverter 3b are superimposed Since the power output of the first heating coil 2a and the second heating coil 2b can be set by the power supply current detection circuit 4 that detects current, the detection circuit configuration is simplified and the cost is reduced by reducing the number of parts. And downsizing.

  When both the first heating coil 2a and the second heating coil 2b are operating, by detecting that the power supply current has decreased by a predetermined value or more, the heated object of any heating coil is displaced from the heating coil. Can be detected.

The first control unit 5a and the second control unit 5b are configured such that the amount of change in the power supply current when the drive times of the first switching element and the second switching element are each changed for a predetermined time is not more than a predetermined value. By detecting this, it can be determined whether the object to be heated 8a is displaced from the first heating coil 2a or whether the object to be heated 8b is displaced from the second heating coil 2b.

  That is, when the object to be heated 8a deviates from the first heating coil 2a being heated, the magnetic coupling between the first heating coil 2a and the object to be heated 8a is reduced, so that the first controller 5a performs the first switching. This is because the amount of change in the magnitude of the power supply current when the element drive time is independently changed for a predetermined time is not more than a predetermined value. The same applies when the object to be heated 8b deviates from the second heating coil 2b being heated.

  Further, in the present embodiment, the power supply current detection circuit 4 is provided after the rectifier circuit that converts the alternating current power supply into direct current, so that a common rectifier circuit and a common rectifier circuit are not used for each inverter. Control using the power supply current detection circuit becomes possible, and the cost can be reduced and the size can be reduced by further reducing the number of parts.

  In the present embodiment, the control unit corrects the difference in the amount of change in the power supply current due to the difference in the power supply voltage by switching the predetermined value for determination according to the AC power supply voltage value. As a result, the detection accuracy with respect to the deviation of the object to be heated is improved, and unnecessary heating stops are reduced, so that the convenience of the user can be improved.

  In the present embodiment, a temperature detection means (not shown) for detecting the temperature of the object to be heated by a signal from the temperature sensor is provided, and the control unit sets a predetermined value for determination according to the temperature. By switching, the influence on the amount of change in the power supply current due to the temperature characteristics of the heated object can be mitigated, so the detection accuracy for the deviation of the heated object is improved and unnecessary heating stops are reduced. User convenience can be improved.

  In the present embodiment, an operation unit that outputs a signal to the control unit so as to change the set thermal power, and the control unit sets a predetermined value for determination according to the combination of the set thermal powers. By switching, the influence on the amount of change in the power supply current due to the thermal power setting can be mitigated, so the detection accuracy for the deviation of the object to be heated is improved and unnecessary heating stops are reduced. Can be improved.

  Further, in the present embodiment, when the setting thermal power is changed in the operation unit, the change-side inverter is temporarily stopped, and the output power of the change-free inverter is set to the output set value. By setting the output power of the inverter with change to the output setting value, the power supply current is distributed correctly, there is no deviation from the output setting for each inverter, cooking can be performed according to the set heating power, and safety is improved. be able to.

  In the present embodiment, the operation of the target to be changed for the predetermined time at the place of “change the drive time of the switching element alone for the predetermined time” has been described in the drive cycle, but the drive on-time is changed. Alternatively, the driving off time may be changed.

  The means described in this embodiment cooperates with hardware resources such as a CPU (or microcomputer), a RAM, a ROM, a storage / recording device, an electric / information device including an I / O, a computer, a server, and the like. You may implement with the form of the program to be made. In the form of a program, new functions can be distributed / updated and installed easily by recording them on a recording medium such as magnetic media or optical media or distributing them using a communication line such as the Internet.

  As described above, the induction heating cooker according to the present invention is a power supply current detection circuit that detects a power supply current flowing in a current path in which the input current of the first inverter and the input current of the second inverter are superimposed. Since the heating output of the heating coil and the second heating coil can be set and the detection circuit configuration can be simplified, it is not limited to induction heating cookers, but for general equipment with a plurality of heat sources based on induction heating. Is also applicable.

DESCRIPTION OF SYMBOLS 1 Top plate 2a, 2b Heating coil 3a, 3b Inverter 4 Power supply current detection circuit 5a, 5b Control part 6 AC power supply 7 Rectifier circuit 8a, 8b

Claims (7)

A first inverter that includes a top plate, a plurality of heating coils including a first heating coil and a second heating coil provided below the top plate, and a first inverter that includes a first switching element and supplies a high-frequency current to the first heating coil. And a second inverter for supplying a high-frequency current to the second heating coil, and a power supply current detection for detecting a power supply current flowing in a current path in which the input current of the first inverter and the input current of the second inverter are superimposed A circuit, a first control unit for controlling on / off of the first switching element so that the power supply current becomes a first output set value when only the first heating coil is heating, and the second heating A second control unit that controls the power supply current to be a second output set value when only the coil is heating, wherein the second heating coil is the second output. When heating is performed at a constant value, when the first heating coil starts a heating operation, the first control unit determines that the amount of increase in the power supply current relative to when the first heating coil is stopped is the first output. The driving time of the first switching element is controlled so as to become a value corresponding to a set value, and when the first heating coil and the second heating coil are operating together, the power supply current decreases by a predetermined value or more. Then, the drive time of the first switching element is independently changed for a predetermined time, and the heating operation of the first heating coil is performed when the amount of change in the magnitude of the power supply current at that time becomes a first predetermined value or less for determination. When the amount of change in the magnitude of the power supply current is larger than the first predetermined value, the heating operation of the first heating coil is continued, and the second control unit further drives the second switching element. When the amount of change in the magnitude of the power supply current at that time becomes equal to or less than a second predetermined value for determination, the second control unit stops the heating operation of the second heating coil. The induction heating cooker that continues the heating operation of the second heating coil when the amount of change in the magnitude of the power supply current is greater than the second predetermined value. The induction heating cooker according to claim 1, wherein the power source current detection circuit is provided after a rectifier circuit that converts an alternating current power source into a direct current. The induction heating cooker according to claim 1 or 2, wherein the control unit switches a predetermined value for determination according to an AC power supply voltage value. The temperature detection means which detects the temperature of a to-be-heated object with the signal from a temperature sensor is provided, The said control part switches the predetermined value for determination according to temperature, The any one of Claims 1-3 Induction heating cooker. The operation part which outputs a signal to the said control part so that a setting thermal power may be changed is provided, The said control part switches the predetermined value for determination according to the combination of a setting thermal power, The any one of Claims 1-4 The induction heating cooker according to item 1. When the setting thermal power is changed in the operation section, the inverter with change side is temporarily stopped, the output power of the inverter without change is set to the output set value, and then the output power of the inverter with change side is changed. The induction heating cooker according to claim 5, wherein the output set value is set. The program for making a computer perform at least 1 of the induction heating cooking appliance in any one of Claim 1 to 6.

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