JP2004134107A - Induction heating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an induction heating device capable of determining heating object movement caused by buoyancy and artificial heating object movement to execute control according to the respective causes, in an induction heating device for heating a heating object having low magnetic permeability and high electric conductivity. <P>SOLUTION: This induction heating device can distinguish the artificial movement from inartificial movement by executing multiple times of movement detection operations by a heating object movement detection means to change control according to inverter output in every movement detection operation. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an induction heating device used in general homes, offices, restaurants, factories, and the like, and more particularly, to an object to be heated made of a material having low magnetic permeability and high electrical conductivity such as aluminum and copper by electromagnetic induction. The present invention relates to an induction heating device such as a cooker or a heating device that heats using a principle.
[0002]
[Prior art]
Hereinafter, as an example of the induction heating device, an induction heating cooker that generates a high-frequency magnetic field from an induction heating coil and heats an object to be heated such as a pan by eddy current due to electromagnetic induction will be described.
[0003]
An example of a conventional induction heating cooker will be described with reference to FIG. In the figure, reference numeral 3 denotes a cooking pot to be heated, and reference numeral 5 denotes a power plug for inputting a commercial AC power. The commercial AC power is rectified, and the rectified DC is input to the inverter circuit 1 and converted into a high-frequency current. The heat is supplied to the heating coil 2, and the heating coil 2 generates a high-frequency magnetic field. Reference numeral 4 denotes a top plate which is an electric insulator, specifically, a plate having a thickness of 4 mm made of a ceramic material, on which the cooking pot 1 is placed.
[0004]
In this configuration, a high-frequency magnetic field is generated from the heating coil 2, and the cooking pot 1 is heated due to eddy current due to electromagnetic induction. When the cooking pot 1 is made of a material having a low magnetic permeability and a high electric conductivity such as aluminum or copper, the suction force from the heating coil 2 is used as in the case where the cooking pot 1 is made of a material having a high magnetic permeability such as iron. Does not work, buoyancy acts on the cooking pot 1 due to the repulsive magnetic field from the cooking pot 1, and depending on the weight of the cooking pot 1 (when the weight is light), the heated object 1 shifts due to buoyancy, or the heated object 1 There is a possibility that the member 1 may float from the mounting surface.
[0005]
This phenomenon is remarkable in the case of aluminum or copper. That is, even with the same low magnetic permeability material, in the case of a material having a lower electric conductivity than aluminum or copper such as non-magnetic SUS, sufficient heat generation can be obtained even if the current flowing through the heating coil 2 is small. The repulsion magnetic field becomes small. FIG. 11 shows an example of the correlation between input power and buoyancy when heating the cooking pot 1 made of aluminum. In the graph of FIG. 11, the horizontal axis represents input power, and the vertical axis represents buoyancy. As described above, as the input power increases, the buoyancy also increases, and if the buoyancy exceeds the total weight of the cooking pot and its contents, the cooking pot 1 shifts and floats.
[0006]
Against such a background, there are those detecting the movement of the object to be heated using a weight sensor, those using a magnetic sensor, those using a resonance frequency detecting means, and the like. Further, there is disclosed a technology of detecting a gradient of a power supply current or a heating coil current to detect floating or movement of an object to be heated under the influence of a magnetic field of the heating coil (for example, see Patent Document 1).
[0007]
[Patent Document 1]
JP 2001-332375 A
[0008]
[Problems to be solved by the invention]
However, in any of the techniques, when it is detected that the object moves due to buoyancy caused by the magnetic field of the object to be heated, the heating power is suppressed or the heating is stopped so as not to move, and the cooking pot 1 is moved artificially. In such a case, the heating power may be suppressed or the heating may be stopped. For example, when the user shakes the cooking pot 1 during cooking of a stir-fry using a frying pan, the heating power is unnecessarily suppressed or stopped, and the heating cannot be performed well. was there.
[0009]
SUMMARY OF THE INVENTION The present invention solves the above-mentioned conventional problems. When the power to be supplied to the heating coil (including the object to be heated) should not be suppressed, for example, the user moves the object to be heated up and down in small increments. Or when the object to be heated is artificially moved during cooking, such as a cooking operation performed by moving the object horizontally, or when the power to be supplied to the heating coil should be suppressed, that is, the upper part of the heating coil. The object to be heated left for heating is distinguished from the movement due to floating due to the action of the magnetic field generated by the heating coil. It is an object of the present invention to eliminate or alleviate the inconvenience and realize a convenient induction heating device.
[0010]
[Means for Solving the Problems]
In order to solve the conventional problem, in the induction heating apparatus of the present invention, the control unit performs an output suppression operation when the movement detection unit detects the movement, so that the movement of the object to be heated is prevented from continuing. Can be.
[0011]
Further, after that, the output suppression operation is released, the output is gradually increased again, and the movement detection operation of performing the output suppression operation is repeated one or more times, so that the object to be heated floats and moves due to the magnetic field of the heating coil. If it is detected, the repetition of the movement detection operation is repeated with substantially the same output change. Since the control means detects the output change, the control means can discriminate the movement of the object to be heated due to the irregular output change.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
The invention according to claim 1 includes an inverter including a heating coil that generates a high-frequency magnetic field and heats an object to be heated, a control unit that gradually increases an output of the heating coil from a low output to a predetermined output, Movement detecting means for detecting an operation state of the inverter until the output of the heating coil increases to the predetermined output to detect movement of the object to be heated, and wherein the control means is configured such that the movement detecting means When the movement of the object to be heated is detected, an output suppression operation for suppressing or stopping the heating to an output smaller than the output of the heating coil at the time of detecting the movement is performed, and then the output suppression operation is released and the output is gradually reduced again. In addition to repeating the movement detection operation of performing the output suppressing operation by increasing the number of times at least once, and detecting that the movement detection operation is repeated with substantially the same output change, It is determined that the movement of the object to be heated due to the high-frequency magnetic field generated by the heating coil is occurring, and the output of the heating coil thereafter is suppressed to an output smaller than the output detected by the movement detection unit to perform heating. With this configuration, the control unit performs the output suppressing operation when the movement detection unit detects the movement, so that the movement of the object to be heated can be prevented from continuing.
[0013]
Further, after the movement detecting means detects the movement and performs the output suppression operation, the output suppression operation is released, the output is gradually increased again, and the movement detection operation of performing the output suppression operation is repeated one or more times. When it is detected that the object to be heated is lifted or moved by the magnetic field of the heating coil, the movement detection operation is repeated with substantially the same output change. Since the control means detects this output change, it can be identified as an artificial movement of the object to be heated in which the output change is irregular.
[0014]
Also, performing the movement detection operation slightly moves the object to be heated, and if this operation is continued without limitation, the object to be heated may move little by little. When it is determined that the object to be heated that is left is moving, the detection of the movement is stopped, and such a situation can be avoided.
[0015]
According to a second aspect of the present invention, in the control means, the movement detecting means detects the movement of the object to be heated a plurality of times, samples the output value of the inverter when the movement is detected, Since it is determined whether or not the movement of the object to be heated has occurred based on a plurality of output values obtained by the above, it is accurately and easily that the repetition of the movement detection operation is repeated with substantially the same output change. Can be detected.
[0016]
That is, based on the detection result of the movement detecting means, the timing at which the movement of the object to be heated is detected and the output is suppressed is determined by the control means. The output value monitors the input current of the inverter and the current flowing through the heating coil. By doing so, it can be easily measured because it can also be used for other control operations.
[0017]
According to a third aspect of the present invention, when the control means according to the second aspect compares or calculates a plurality of output values obtained by sampling and determines that the output values are substantially the same as each other, Since it is determined that the object to be heated is moving due to the high-frequency magnetic field generated by the heating coil, the determination when suppressing the output of the heating coil can be easily realized using a microcomputer.
[0018]
According to a fourth aspect of the present invention, in particular, the control means according to the first or second aspect detects a time required for repetition of the movement detection operation, and the movement of the object to be heated occurs according to a change in the time. Since it is determined whether or not the movement is detected, it is possible to accurately and easily detect that the movement detection operation is repeated with substantially the same output change.
[0019]
That is, based on the detection result of the movement detecting means, the timing at which the movement of the object to be heated is detected and the output is suppressed is determined by the control means, and the time required for repeating the movement detecting operation can be easily measured. May be measured to measure the time required for repetition.
[0020]
According to a fifth aspect of the present invention, in particular, the control means according to the fourth aspect measures the time required for repeating the movement detection operation a plurality of times, compares or calculates a plurality of obtained values, and calculates When it is determined that they are substantially the same as each other, it is determined that the object to be heated is moving by the high-frequency magnetic field generated by the heating coil. And can be easily realized.
[0021]
According to a sixth aspect of the present invention, in particular, the control means according to any of the first to fifth aspects is characterized in that after the control means performs the output suppressing operation based on the detection result of the movement detecting means, the control means artificially heats the object. When it is detected that the movement by the object has occurred, the movement detection operation is canceled, and the output of the heating coil is increased to a predetermined output. When such an artificial movement of the object to be heated occurs, power suppression for preventing the movement of the object to be heated is continued and it is possible to avoid a decrease in cooking performance. When the user moves the object to be heated at the start of cooking such as cooking of stir-fry, it is possible to secure a sufficient output of the heating coil. Moreover, in this case, the problem of moving the object to be heated (such as moving naturally) is not so serious because the user holds the object to be heated.
[0022]
The invention according to claim 7 includes, in particular, display means for performing a display corresponding to a predetermined output set by a user, wherein the display means is a control means according to any one of claims 1 to 5, Even if the output suppression operation based on the detection result of the movement detecting means is started, the display corresponding to the set output is continuously displayed, and the control means moves the object to be heated by the high-frequency magnetic field generated by the heating coil. After determining that the output has occurred, the output value to be displayed is lowered from the display corresponding to the predetermined output, so that the output corresponding to the inverter output (corresponding to the heating coil output or the power consumption) set by the user. It is possible to provide an easy-to-use induction heating device that does not needlessly change the display and does not give the user an unnecessary feeling of anxiety.
[0023]
According to an eighth aspect of the present invention, in particular, the movement detecting means according to any one of the first to seventh aspects is configured to detect the movement of the object to be heated in accordance with the time change of the inverter output. The movement of the object to be heated can be detected with a simple configuration.
[0024]
【Example】
Hereinafter, embodiments of the present invention will be described with reference to the drawings, taking an induction heating cooker as an example.
[0025]
(Example 1)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic sectional configuration diagram of an induction heating cooker according to the present embodiment, and FIG. 2 is a circuit block diagram of the induction heating cooker. 1 and 2, a top plate 10 made of ceramic is arranged on an upper portion of a housing 12, and a cooking pot 9 to be heated is placed on the top plate 10. The power plug 19 is connected to the commercial power supply 11. The commercial power supply 11 is input to the rectifying / smoothing unit 13 inside the housing 12. The rectifying / smoothing unit 13 is connected to a full-wave rectifier 13a composed of a bridge diode and a first smoothing capacitor 13b between its DC output terminals.
[0026]
An inverter circuit 7 is connected to both ends of the first smoothing capacitor 13b, and an induction heating coil 8 is connected to the inverter circuit 7. The inverter circuit 7 and the induction heating coil 8 constitute a high-frequency inverter. The inverter circuit 7 is provided with a series connection of a first switching element 7c (IGBT in the present embodiment) and a second switching element 7d (IGBT in the present embodiment). The first diode 7e is connected in anti-parallel to the first switching element 7c, and the second diode 7f is connected in anti-parallel to the second switching element 7d. A second smoothing capacitor 7b is connected to both ends of the series connection of the IGBT 7c and the IGBT 7d.
[0027]
A choke coil 7a is connected between a connection point of the series connection body and a positive terminal of the full-wave rectifier 13a. The low potential terminal of the series connection is connected to the negative terminal of the full-wave rectifier 13a. A series connection of an induction heating coil 8 and a resonance capacitor 7g is connected between a connection point of both switching elements of the series connection and a negative terminal of the full-wave rectifier 13a.
[0028]
The current transformer 14 detects a power supply current input from the commercial power supply 11 of the inverter circuit 7 and outputs a detection signal to the power supply current detection circuit 15. The power supply current detection circuit 15 outputs a detection signal proportional to the magnitude of the power supply current to the control circuit 18 serving as control means and the power supply current change detection circuit 16.
[0029]
The power supply current change detection circuit 16 outputs a detection signal to the change determination circuit 17, and the change determination circuit 17 outputs a determination signal to the control circuit 18. The current transformer 14, the power supply current detection circuit 15, the power supply current change detection circuit 16, and the change determination circuit 17 constitute a movement detection unit. The control circuit 18 drives the first switching element 7c and the second switching element 7d in the inverter circuit 7.
[0030]
An input unit 19 having an input key operated by a user for setting heating output or starting or stopping heating is connected to the control circuit 18, and an output signal of the input unit 19 is output to the control circuit 18. The display means 20 is connected to the control circuit 18 and displays the heating output setting contents and the like set by the input unit 19 to the user.
[0031]
The operation of the induction cooking device configured as described above will be described. The commercial power supply 11 is rectified by the full-wave rectifier 13a, and the first smoothing capacitor 13b supplies power to the high-frequency inverter having the inverter circuit 7 and the induction heating coil 8.
[0032]
FIG. 3 shows waveforms at various points in this embodiment. Waveform (a) shows current waveform Ic2 flowing through second switching element 7d and diode 7f. A waveform (b) shows a current waveform Ic1 flowing through the first switching element 7c and the diode 7e. The waveform (c) shows the voltage Vce2 generated between the collector and the emitter of the second switching element 7d. The waveform (d) shows the voltage Vce1 generated between the collector and the emitter of the first switching element 7c. The waveform (e) shows the current IL flowing through the induction heating coil 8.
[0033]
When the first switching element 7f is turned on, a resonance current is generated in a closed circuit of the first switching element 7f (or the second diode), the induction heating coil 8, and the resonance capacitor 7g, and the choke coil is generated. 4 stores energy. When the second switching element 7f turns off, the stored energy is released to the second smoothing capacitor 7b via the first diode 7e.
[0034]
After the second switching element 7f is turned off, the first switching element 7c is turned on. Therefore, after a current flows through the first diode 7e, the first switching element 7c (or the first diode 7e) is turned on. , A resonance current flows through a closed circuit including the induction heating coil 8, the resonance capacitor 7g, and the second smoothing capacitor 7b.
[0035]
The driving frequency of the first switching element 7c and the second switching element 7d is changed in the vicinity of about 20 kHz, and the driving time ratio is changed in the vicinity of about 1/2 as shown in FIG. The impedance of the induction heating coil 8 and the resonance capacitor 7g is such that the cooking pot 9 is made of a specified material (for example, a high conductivity such as aluminum, a non-magnetic material) and a standard pot (a pot having a diameter equal to or greater than the diameter of the induction heating coil). When placed on a designated place of the plate 10 (for example, a place shown as a heating part), the generated resonance frequency is set to be about three times the drive frequency. Therefore, in this case, the resonance frequency is set to be about 60 kHz.
[0036]
Since the induction heating coil 8 generates a high-frequency current of about 60 kHz therewith, even if the cooking pot 9 is made of aluminum, it can be efficiently heated. The high-frequency inverter of the present embodiment has high heating efficiency because the regenerative current flowing through the first diode 7e and the second diode 7f does not flow through the first smoothing capacitor 13b but is supplied to the second smoothing capacitor 7b.
[0037]
Further, since the second smoothing capacitor 7b smoothes the envelope of the high-frequency current supplied to the induction heating coil 8 compared with the conventional cooking device, the commercial frequency of the vibration sound generated from the pot or the like during heating is reduced. The components are reduced.
[0038]
Further, the high-frequency inverter according to the present embodiment has a characteristic that when the magnetic coupling between the cooking pot 9 and the induction heating coil 8 is reduced, the input power is reduced when operated under the same driving conditions (frequency, driving time ratio, etc.).
[0039]
Since the control circuit 18 receives an output signal proportional to the magnitude of the power supply current from the power supply current detection circuit 15, the first switching element 7c and the second switching element 7d supply the input power (the output value of the high-frequency inverter) to the first switching element 7c and the second switching element 7d. The control is performed by varying the drive frequency or varying the drive time ratio of both switching elements so as to control to a predetermined value.
[0040]
At the time of startup, the control circuit 18 gradually increases the output of the high-frequency inverter from the low output to the set power by gradually changing the drive frequency or the drive time ratio as shown by the solid line and the broken line A in FIG. . At this time, the power supply current similarly increases until the power supply current reaches the set current corresponding to the set power, as shown by the line A ′ in FIG.
[0041]
When the cooking pot 9 is made of a highly conductive nonmagnetic material such as aluminum, the current flowing through the induction heating coil 8 increases, so that the current induced in the cooking pot 9 also increases, and the interaction occurs. May lift or shift due to the repulsive force.
[0042]
At the time of startup, if such a floating or displacement of the heated pan 9 occurs from the low input power to the set power, the rate of increase of the input power decreases as shown by the line B in FIG. Similarly, as shown by line B 'in FIG. 4B, the rate of increase of the power supply current also decreases.
[0043]
The power supply current change detection circuit 16 measures the rate of change of the power supply current value from the signal output from the power supply current detection circuit 15 and outputs it to the change determination circuit 17. When the change rate of the power supply current value is within the first predetermined range and continues for a predetermined time or more, the change determination circuit 17 determines that the cooking pot 9 has moved by the repulsive force, and sends a signal to that effect to the control circuit 18. Output. When this signal is input, the control circuit 18 stops the operation of the inverter circuit 7 or controls the output of the inverter circuit 7 so that the cooking pot 9 does not move.
[0044]
FIG. 5 shows an example of this control. FIG. 5 shows a time change of the input power and the input current at the start of heating, as in FIG. As shown in FIG. 5, after detecting a change in the slope of the input current caused by the occurrence of lifting or displacement due to the repulsive force of the cooking pot 9 in about 0.1 second after the change, the current is lower than the current when the change is detected. It is held by the value.
[0045]
When the response speed of the power control of the inverter circuit 7 is fast, the control circuit 18 changes the driving condition in the direction of increasing the input power immediately following the above-mentioned coupling change. May not be detected. Therefore, in the present embodiment, the rate of increase per unit time when the control circuit 18 performs power control is set to a value near or below a value at which a change in the power supply current can be detected.
[0046]
Further, in the present embodiment, a part or all of the change determination circuit 17, the control circuit 18, and the power supply current detection circuit 15 are configured by using a microcomputer, so that the change determination circuit 17 starts detecting the misalignment and the floating. It has been experimentally confirmed that the time required to determine this (hereinafter referred to as “floating detection time”) can be reduced to about 0.1 second as described above.
[0047]
By setting the floating detection time to about 0.1 second, it is possible to make it difficult to visually recognize the displacement and the floating of the cooking pot 9. However, depending on the size and shape of the cooking pot 9, there may be a case where a slight lifting or misalignment is easily recognized at the time of detection. For example, in a light frying pan, the center of gravity is located closer to the handle than the center of the pot, and the pot bottom on the opposite side to the handle floats and tilts with a little buoyancy.
[0048]
When the movement of the cooking pot 9 is detected as described above after the inverter 7 is started, the output value is kept at a lower output value (for example, about 800 W lower than the set output) than the output (for example, 2 kW) set by the user. If the low output is continued as it is, cooking that requires a strong heating output cannot be performed. Therefore, the user moves the cooking pot 9 until the output is stabilized at the time of startup, and when the change determination circuit 17 erroneously detects that the cooking pot 9 has floated and moved by this operation, the power consumption is kept low. As a result, sufficient heating cannot be performed as described above, resulting in poor usability.
[0049]
On the other hand, the output control operation of the control circuit 18 of the present embodiment is as shown in FIG. As shown in FIG. 6, when reaching the set current value (10 A), the cooking pot 10 starts to float at time t1 and the change determination circuit 17 detects the movement of the cooking pot 9 for the first time at time t2. The circuit 18 measures the output value (in this case, the power supply current value) I11 (in this case, 8 A) at that time (time t2) based on the detection result of the power supply current detection circuit 15. Then, the control circuit 18 reduces the heating output to an output value I21 (6A) lower by 2A than the output value I1 (8A) of the movement detection.
[0050]
After holding the heating output at the value I21 for the predetermined time T1 (for example, 1 second), the control circuit 18 releases the output suppression operation at time t3 and gradually increases the heating output (input current) again. Then, when the change determination circuit 17 detects the movement of the cooking pot 9 again from the time point t4 to the time point t5, the control circuit 18 measures the output value I12 at the time point t5 when the change determination circuit 17 detects the second movement. The output is reduced to I22 and the above operation is repeated.
[0051]
When the cooking pot 9 is left unattended, the connection between the induction heating coil 8 and the cooking pot 9 does not change, so that the change determination circuit 17 detects the power supply current value I11 when the movement is detected for the first time and the cooking pot 9 for the second time. Output value I12 at the time when the movement is detected is substantially the same value. As described above, the control circuit 18 performs the movement detection by the repetition change determination circuit 17 and performs the sampling operation of sampling the output value each time the movement is detected a predetermined number of times (in this case, three times). The measured value of the power supply current at the time of detection is compared and calculated, and if they are substantially the same (for example, if the measured value is within the range of a predetermined width (ΔI in FIG. 6)), the cooking pot 9 is left floating. And the movement detection operation is stopped thereafter (release of the output suppression state after it is determined that the movement has been made is prohibited), and a power value lower than the output I11 or I12 for performing the movement detection (in this case, Since I21, I22, and I23 (suppressed after the third movement is detected) are substantially the same, heating is continued at that value.
[0052]
If the movement detection operation is not stopped as described above, the predetermined time (the holding time (in this case, 1 second) in the output suppression state after the movement detection) and the time until the cooking pot 9 rises again after the cancellation is released. Every time the floating detection time (in this case, the sum of about 0.1 seconds) elapses, the cooking pot 9 floats slightly. When the cooking pot 9 is a frying pan, since the center of gravity of the cooking pot 9 is deviated and the balance is poor, only a part of the cooking pot 9 may be lifted and rotated when floating. Since the change in the magnetic coupling between the induction heating coil 8 and the cooking pot 9 due to the rotation of the cooking pot 9 is small, the above-described movement detection operation may not be performed. For example, the cooking pot 9 is largely displaced from the induction heating coil 8. In some cases, the rotation operation becomes larger. If this operation is repeated, it is assumed that the motor rotates every time it floats up. Therefore, it is preferable that the number of movement detection operations be as small as possible. Also, it is better that the time from floating to detection is short.
[0053]
The operation of the output display means at this time will be described with reference to FIGS. When the heating output is set to “strong” (2 kW) by the input unit 19, the control circuit 18 outputs a signal to the output display means 20 to display a signal up to “strong” as shown in FIG. All the elements (LEDs) are turned on to indicate that the "strong" output setting has been made.
[0054]
For example, when heating is started in a state where the aluminum cooking pot 9 is left, the output gradually increases as shown in FIG. 6, and at time t2, the cooking pot 9 floats due to buoyancy at time t2 in FIG. (At this time, the heating output is 1800 W), the heating output is reduced by about 400 W to 1200 W. At this time, the display of the output display means 20 continues the state of FIG. 9A, and the display does not change from the state at the time of output setting even if the output value is suppressed.
[0055]
Then, the control circuit 18 repeats the movement detection operation of the cooking pot 9 three times, monitors the state of the repetition operation as described above at time t7 in FIG. 6, and moves the cooking pot 9 by buoyancy, If it is determined that the movement has not been detected by an artificial operation, the output display means 20 blinks the display elements corresponding to “5” and “strong” (see FIG. 9A). This display allows the user to recognize that the heating output has been suppressed to “4”, that is, to 1200 W. This display mode indicates that the buoyancy detection function has been activated (by the partial blinking operation of the element), the set output (by the sum of the lit and blinking parts), and the movement detection function (by the lit part). The forcibly suppressed output values are displayed to the user, and the effect is not limited to a display form, such as notifying the fact in words by voice, and the same effect can be obtained by other methods. Can be done.
[0056]
As described above, the cooking pot 9 moves due to buoyancy by flashing or voice, and the movement is not detected by the manual operation of the cooking pot 9 without displaying that the movement has not been detected by the manual operation. After confirming that the output has not been performed, a change in output may be simply displayed. This is because such information is not directly necessary for cooking work, and such display may cause confusion, depending on the user.
[0057]
A control operation performed when the user moves the cooking pot 9 when performing the above-described movement detection operation will be described with reference to FIG. Similar to the movement of the cooking pot 9 based on the operation of the cooking pot 9 by a human, the change in the power supply current when the movement of the cooking pot 9 is detected is random, and when the current value when detecting the movement is high as shown in FIG. There are times when it is low. This state can be determined by comparing a plurality of output values at the time of movement detection obtained by sampling of the movement detection. In such a case, the movement detection operation, that is, the operation of releasing the output suppression operation after detecting the movement and increasing the output to the set value again is repeated. As a result, when the cooking pot 9 is moved based on an artificial operation, it is possible to prevent the output value from being unnecessarily suppressed.
[0058]
The control circuit 18 determines from the change determination circuit 17 that the cooking pot 9 has moved due to buoyancy and has been abandoned. When the movement detection operation is stopped and the value is lower than the set power, the user can use the cooking pot 9 The operation when the object 9 is moved artificially will be described with reference to FIG. This situation is, for example, a case in which a lightweight frying pan made of aluminum is first left for preheating, the change determination circuit 17 detects this, suppresses electric power, and then the user holds and starts cooking. It is supposed to occur in In the inverter 7 of FIG. 2, since the heating output depends on the magnetic coupling between the cooking pot 9 and the induction heating coil 8, as described above, when the cooking pot 9 is floated by the user or the like, the power supply current is temporarily reduced. It becomes smaller (point A in the figure).
[0059]
The change judging circuit 17 detects this time change of the power supply current (in this case, it detects that the output decreases as time elapses), and the control circuit 18 cancels the output suppression operation and gradually increases the output. Set to the set power.
[0060]
For example, at the time of preheating, even if the control circuit 18 detects that the user is actually holding and cooking even if the cooking pot 9 is floating due to buoyancy and is in the output suppression state, the output suppression operation is automatically performed. Since the heating output increases from the output suppressed and set to the set output, the usability is improved. The control circuit 18 performs the display as shown in FIG. 9A in the output suppression state, but when the change determination circuit 18 detects the artificial movement of the cooking pot 9, the hour output display means 20 The output is changed to the initial setting output, as shown in FIG.
[0061]
As described above, in the present embodiment, the induction heating coil 8 and the inverter circuit 7, which are inverters that generate a high-frequency magnetic field and heat the cooking pot 9, and the output of the induction heating coil 8 is changed from a low output to a predetermined output. The control circuit 18 is a control means for gradually increasing the output of the induction heating coil 8, and the movement detecting means detects the operation state of the high-frequency inverter until the output of the induction heating coil 8 increases to a predetermined output to detect the movement of the cooking pot 9. The control circuit 18 includes a power supply current change detection circuit 16 and a change determination circuit 17. The control circuit 18 detects the output of the induction heating coil 8 based on the detection result of the movement detection means, and detects the movement when the movement detection means detects the movement. An output suppressing operation for suppressing the output to I21 or I22 smaller than the output I11 or I12 is performed, and then the output suppressing operation is released and the output is gradually increased again to suppress the output. When the movement detection operation is repeated three times and it is detected that the movement detection operation is repeated with substantially the same output change, the movement of the object to be heated by the high-frequency magnetic field generated by the induction heating coil 8 occurs. It is determined that the cooking pot 9 has been moved, and the output of the heating coil thereafter is suppressed to an output smaller than the output detected by the movement detecting means to perform the heating, whereby the movement of the cooking pot 9 can be prevented from continuing. .
[0062]
Further, since the control circuit 18 detects that the cooking pot 9 has been lifted by the magnetic field of the induction heating coil 8 by an output change in which the repetition of the movement detection operation is repeated with substantially the same output change, the output change is irregular. It can be identified as an artificial movement of the object to be heated. Further, when the control circuit 18 determines that the cooking pot 9 that has been left is moving, the detection of the movement is stopped, so that the heated object can be prevented from moving little by little.
[0063]
Further, in this embodiment, the movement detecting means detects the movement of the cooking pot 9 a plurality of times (three times), and samples a power supply current which is an output value of the inverter circuit 7 and the induction heating coil 8 at the time of detecting the movement. Based on a plurality (three in this case) of the output values obtained by the sampling, it is determined whether or not the movement of the object to be heated has occurred (in this case, whether the three output values are within a predetermined range). Therefore, it is possible to accurately and easily detect that the repetition of the movement detection operation is repeated with substantially the same output change.
[0064]
That is, based on the detection result of the movement detecting means, the timing of detecting the movement of the cooking pot 9 and suppressing the output is determined by the control circuit 18, and the output value is determined by the input current (power supply current) of the inverter circuit 7, By monitoring the current of the induction heating coil 8, the circuit configuration can be simplified because it can be used for other control operations such as output control by the control circuit 18.
[0065]
In the present embodiment, the control circuit 18 compares or calculates the output values of a plurality (8 in this case, three) obtained by sampling and determines that the output values are substantially the same as each other. Since it is determined that the motor 9 is moving due to the high-frequency magnetic field generated by the induction heating coil 8, the determination when suppressing the output of the induction heating coil 8 can be easily realized using a microcomputer.
[0066]
Further, in the present embodiment, the control circuit 18 performs the output suppression operation based on the detection result of the movement detection means and then detects the movement of the cooking pot 9 artificially. Is released, and the output of the induction heating coil 8 is increased to a predetermined output, whereby the movement of the cooking pot 9 left unattended can be suppressed as much as possible, and the movement of the object to be heated related to the cooking operation occurs. In addition, the output suppression operation is automatically canceled, and it is possible to prevent the suppression of the electric power for preventing the movement of the cooking pot 9 from being continued and a decrease in the cooking performance.
[0067]
For example, when the user moves the cooking pot 9 at the start of cooking such as stir-fry cooking, it is possible to secure a sufficient heating output of the induction heating coil 8. Moreover, in this case, the problem of the normal movement of the cooking pot 9 (for example, the movement of the cooking pot 9 naturally) does not cause much problem since the user holds the cooking pot 9.
[0068]
Further, in the present embodiment, the output display means 20 for performing the display corresponding to the predetermined output set by the user is set even if the control circuit 18 starts the output suppression operation based on the detection result of the movement detection means. The display corresponding to the output is continuously displayed, and after the control circuit 18 determines that the movement of the cooking pot 9 due to the high-frequency magnetic field generated by the induction heating coil 8 has occurred, the output value to be displayed is predetermined. Is lower than the display corresponding to the output of the inverter circuit 7, so that the output display of the output display means 20 corresponding to the output of the inverter circuit 7 set by the user (corresponding to the output of the induction heating coil 8 or the power consumption or the power supply current) is unnecessary. It is possible to provide an easy-to-use induction heating device that does not give a user an unnecessary feeling of anxiety.
[0069]
Further, in the present embodiment, the configuration in which the movement of the object to be heated is detected in accordance with the time change of the output of the inverter circuit 17 or the induction heating coil 8 makes it possible to use a simple configuration by using a microcomputer. 9 can be detected.
[0070]
In the above-described embodiment, whether or not the movement of the cooking pot 9 has occurred is determined by measuring a plurality of power supply current values at the time of detecting the movement and determining whether the values are substantially the same. Even when the time required for repetition is measured a plurality of times, and the obtained values are compared or calculated, and it is determined that they are substantially the same, the same operation and effect can be obtained. Then, the input / output waveform (voltage or current) of the inverter may be measured instead of the power supply current to measure the time required for repetition.
[0071]
When the output after movement detection is suppressed to a predetermined value, the predetermined value may be set to zero, that is, heating may be stopped.However, the higher the output suppression value, the quicker the detection of an artificial movement. can do.
[0072]
In this embodiment, the two-pole type SEPP inverter is used. However, any configuration can be used as long as the input current changes due to a change in magnetic coupling with a load (heated object) such as a one-pole voltage resonance type inverter. Alternatively, a control type inverter may be used. Further, the power is varied using the frequency. However, the present invention is not limited to this. Needless to say, a method in which the conduction ratio of the two switching elements is changed at a constant frequency may be used.
[0073]
Although the time change of the power supply current is used for detecting the movement of the object to be heated, the change may be detected by using, for example, a resonance frequency detecting means. Further, sound or vibration generated during movement may be detected.
[0074]
【The invention's effect】
As described above, according to the invention as set forth in claims 1 to 8, particularly in an induction heating apparatus in which the object to be heated has low magnetic permeability and high electric conductivity, the object to be heated moves or moves due to buoyancy. When occurs, it is possible to distinguish between artificial movement and non-artificial movement and to perform power control and display suitable for each of them, thereby realizing a convenient induction heating device.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of an induction heating device according to a first embodiment of the present invention.
FIG. 2 is a circuit block diagram of the induction heating device according to the first embodiment of the present invention.
FIG. 3 is a diagram showing operation waveforms of a high-frequency inverter of the induction heating device according to the first embodiment of the present invention.
FIG. 4A is a diagram showing a change over time of the input power of the induction heating device according to the first embodiment of the present invention;
(B) The figure which shows the time change of the power supply current of the induction heating apparatus in the 1st Example of this invention.
FIG. 5A is a diagram showing a change over time of the input power of the induction heating device according to the first embodiment of the present invention.
(B) The figure which shows the time change of the power supply current of the induction heating apparatus in the 1st Example of this invention.
FIG. 6 is a diagram showing a change over time of a power supply current of the induction heating device according to the first embodiment of the present invention (when a movement detection operation is performed while an object to be heated is left unattended).
FIG. 7 is a diagram showing a change over time of the power supply current of the induction heating device (when the object to be heated is artificially moved) in the first embodiment of the present invention.
FIG. 8 is a diagram showing a change over time of a power supply current of the induction heating device according to the first embodiment of the present invention (when an object to be heated is artificially moved in an output suppression state by movement detection).
FIG. 9A is a diagram showing a display state of the output display means of the induction heating device when the output is set in the first embodiment of the present invention.
(A) A diagram showing the display state of the output display means after it is confirmed that the object to be heated of the induction heating apparatus according to the first embodiment of the present invention is left unattended.
FIG. 10 is a sectional view of a conventional induction heating device.
FIG. 11 is a correlation diagram between input power and buoyancy of a conventional induction heating device.
[Explanation of symbols]
7. Inverter circuit (high frequency inverter)
8 Induction heating coil (heating coil)
9 Cooking pot (heated object)
14 Current transformer (movement detection means)
15 Power supply current detection circuit (movement detection means)
16 Power supply current change detection circuit (movement detection means)
17 Change determination circuit (movement detection means)
18 control circuit (control means)
20 Output display means (display means)

Claims (8)

An inverter including a heating coil that generates a high-frequency magnetic field and heats an object to be heated; a control unit that gradually increases the output of the heating coil from a low output to a predetermined output; and an output of the heating coil outputs the predetermined output. Movement detecting means for detecting the movement of the object to be heated by detecting the operation state of the inverter until it increases, the control means, when the movement detecting means detects the movement of the object to be heated, Performing an output suppression operation of suppressing or stopping heating to an output smaller than the output of the heating coil when the movement is detected, and then releasing the output suppression operation and gradually increasing the output again to perform the output suppression operation. Is performed at least once, and when it is detected that the repetition of the movement detection operation is repeated with substantially the same output change, the generation of the heating coil is performed. Wherein by the high frequency magnetic field is determined that the movement of the object to be heated is awake induction heating apparatus for heating the output of subsequent said heating coil to suppress the output is less than output the movement detection means detects movement. The control means detects the movement of the object to be heated a plurality of times by the movement detecting means, samples an output value of the inverter at the time of the movement detection, and detects the movement of the object to be heated based on the plurality of output values obtained by the sampling. 2. The induction heating device according to claim 1, wherein it is determined whether or not it is awake. The control means compares or calculates a plurality of output values obtained by sampling, and when it is determined that the plurality of output values are substantially the same as each other, the object to be heated moves by the high-frequency magnetic field generated by the heating coil. The induction heating device according to claim 2, wherein the induction heating device is determined to be present. The induction heating apparatus according to claim 1, wherein the control unit detects a time required to repeat the movement detection operation, and determines whether or not the movement of the object to be heated has occurred according to a change in the time. The control means measures the time required for repetition of the movement detection operation a plurality of times, compares or calculates a plurality of obtained values, and when the values are substantially the same, the object to be heated moves by the high-frequency magnetic field generated by the heating coil. The induction heating device according to claim 4, wherein the induction heating device determines that the heating is performed. The control means, after performing the output suppression operation based on the detection result of the movement detection means and detecting that the movement by the object to be heated has occurred artificially, cancels the movement detection operation and outputs a predetermined output. The induction heating device according to any one of claims 1 to 5, wherein the output of the heating coil is increased up to the maximum. Display means for performing a display corresponding to a predetermined output set by a user, wherein the display means sets the predetermined output which is set even when the control means starts an output suppression operation based on a detection result of the movement detection means. The display corresponding to the above is continuously displayed, and after the control means determines that the movement of the object to be heated by the high-frequency magnetic field generated by the heating coil has occurred, the output to be displayed is changed to the predetermined output. The induction heating device according to claim 1, wherein the output is lower than a corresponding display output. The induction heating device according to any one of claims 1 to 7, wherein the movement detecting means detects a movement of the object to be heated in accordance with a time change of an inverter output.

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