JP2001015260A - Microwave oven - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent sparks from being generated at a part of severance in the event of severance of any of the conductor patterns to connect one output terminal of a voltage doubling rectifier circuit with a grounding part. SOLUTION: A microwave oven includes an inverter power supply 101 to supply a high voltage to a magnetron 103, wherein the inverter power supply 101 is equipped with a switching element 110, high voltage transformer 109, voltage doubling rectifier circuit 110, and a current sensing means 116 to sense the anode current of the magnetron 103. The current sensing means 116 is configured with a plurality of elements 118a-118d, and when one of the two conductor patterns 119a and 119b of a parallel circuit in the current sensing means 116 is severed, a judgement as in failure is passed, and the operation of the inverter power supply 101 is stopped.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven having a magnetron for irradiating a heating chamber with microwaves, and an inverter power supply for supplying a high voltage to the magnetron.

[0002]

2. Description of the Related Art FIG. 4 shows an example of an electric configuration of a microwave oven of this type. In FIG. 4, the inverter power supply circuit 1
Is a circuit for receiving a commercial AC power supply 2 and supplying a high voltage to the magnetron 3. This inverter power supply circuit 1
Rectifier 4, choke coil 5, smoothing capacitor 6
, A switching element 7, a resonance capacitor 8, a high-voltage transformer 9, a voltage doubler rectifier circuit 10, and an inverter control circuit 11 for turning on and off the switching element 7. Then, the inverter power supply circuit 1
It is mounted on a printed wiring board A indicated by a chain line.

Here, the voltage doubler rectifier circuit 10 comprises a series circuit comprising a high voltage diode 12 and a high voltage capacitor 13, and this series circuit is connected to both ends of a secondary winding 9b of the high voltage transformer 9. . A common connection point B between the high voltage diode 12 and one end of the secondary winding 9b of the high voltage transformer 9 is connected to a grounding portion 14 provided on the printed circuit board A.
Is grounded to the housing of the microwave oven. And
The anode of the magnetron 3 is grounded to the housing of the microwave oven. Thereby, the common connection point B of the voltage doubler rectifier circuit 10
Is connected to the anode of the magnetron 3 via the housing of the microwave oven.

Further, both ends of the heater constituting the cathode of the magnetron 3 are connected to both ends of the secondary winding 9c of the high voltage transformer 9. A high voltage diode 15 is connected between an intermediate connection point between the high voltage diode 12 and the high voltage capacitor 13 and one end of the secondary winding 9c of the high voltage transformer 9.

On the other hand, an electric current path between the cathode of the high voltage diode 12 and the common connection point B is provided with a current detecting means 16 comprising, for example, a current transformer. Is configured to be detected. The detection signals detected by the current detection means 16 are the conductor patterns 17a and 17a.
b and the anode current detection signal lines 18a and 18b to be supplied to a control circuit 19 provided in a panel section of a microwave oven.

A control circuit 1 for a panel section of a microwave oven
Reference numeral 9 denotes a signal for controlling the inverter power supply circuit 1, which is supplied to the inverter control signal lines 20a and 20b and the conductor pattern 21.
a, 21b to the inverter control circuit 11. Incidentally, the anode current detection signal line 18a,
18b and the inverter control signal lines 20a and 20b are configured by a wire harness 21. At both ends of the wire harness 21, a connector 22 provided on a printed circuit board A of the inverter power supply circuit 1 and a printed circuit board C on which a control circuit 19 of a panel section of a microwave oven is mounted.
Is connected to the connector 23 provided at

[0007]

In the case of the above configuration, the high voltage diode 12 and the secondary winding 9 of the high voltage transformer 9 are provided on the printed circuit board A of the inverter power supply circuit 1.
b (ie, a common connection point B with one end of the voltage doubler rectifier circuit 10).
There is a situation that the length dimension of the conductor pattern 24 connecting one of the terminals (the output terminal on the low voltage side) and the ground portion 14 is considerably long. This is caused by a problem in arrangement of various electric components mounted on the printed wiring board A. And
If the conductive pattern 24 is long, there is a high possibility that the conductive pattern 24 is disconnected due to some cause (for example, the substrate is cracked or the substrate is cracked).
In this case, since a high voltage is applied to the broken portion of the conductor pattern 24, there is a possibility that a spark is generated at the broken portion.

When grounding the grounding portion 14 of the printed wiring board A to the housing of the microwave oven, a screw for mounting the board is inserted into a screw insertion hole formed in the grounding portion 14 of the printed wiring board A. In this case, the screw is fastened and fixed to the housing of the microwave oven. In the case of this configuration, the screws are loosened or come off, and
If the ground is incomplete due to the detachment of the housing 4 from the housing, a high voltage is applied to that part, and there is a possibility that a spark may occur at that part.

SUMMARY OF THE INVENTION It is an object of the present invention to reliably prevent the occurrence of a spark in a broken portion even if the conductor pattern connecting one output terminal of the voltage doubler rectifier circuit and the ground portion is broken. To provide a microwave oven that can. Another object of the present invention is to provide a configuration in which a grounding portion of a printed wiring board of an inverter power supply is grounded by screwing to a housing of a microwave oven. It is an object of the present invention to provide a microwave oven that can reliably prevent the occurrence of such a problem.

[0010]

The microwave oven according to the present invention comprises:
In a microwave oven including a heating chamber, a magnetron that irradiates microwaves into the heating chamber, and an inverter power supply that supplies a high voltage to the magnetron, the inverter power supply includes a switching device that converts DC power into high-frequency AC power. An element, a high-voltage transformer for boosting the high-frequency AC power to a high voltage necessary for driving the magnetron, a voltage doubler rectifying circuit for rectifying a high-voltage AC voltage on the secondary side of the high-voltage transformer, and a voltage doubler A current detecting means provided between the low voltage side of the rectifier circuit and the housing of the microwave oven for detecting an anode current of the magnetron; and an operation of the inverter power supply when a value detected by the current detecting means is abnormal. And first control means for controlling the current detection means to stop the current detection. Further, when any one of the two conductor patterns of the parallel circuit of the current detecting means is disconnected, an abnormality determining means for determining that an abnormality has occurred, and that the abnormality determining means has determined that an abnormality has occurred. And a second control means for controlling so as to stop the operation of the inverter power supply when the judgment is made.

According to the above configuration, the two conductor patterns of the parallel circuit of the current detecting means constitute a conductor pattern for connecting one output terminal of the voltage doubler rectifier circuit and the ground. Therefore, if any one of the two conductor patterns is broken, the abnormality determining means determines that an abnormality has occurred, and the operation of the inverter power supply is stopped by the second control means. Therefore, it is possible to reliably prevent spark from being generated at the broken portion of the conductor pattern.

Another microwave oven according to the present invention is a microwave oven comprising a heating chamber, a magnetron for irradiating the heating chamber with microwaves, and an inverter power supply for supplying a high voltage to the magnetron. A switching circuit configured by connecting a series circuit of a switching element and a series circuit of a capacitor in parallel, and a high-voltage transformer that boosts the high-frequency AC power to a high voltage required to drive the magnetron, A DC voltage is applied to a parallel connection point of the circuit, and a primary winding of the high voltage transformer is connected to each series connection point of the two series circuits of the switching circuit. A voltage doubler rectifier circuit connected to the next winding and a low voltage side of this voltage doubler rectifier circuit and a microwave oven housing. Current detecting means for detecting an anode current of the magnetron, and first control means for controlling to stop the operation of the inverter power supply when a value detected by the current detecting means is abnormal. The current detection means is constituted by a parallel circuit of a plurality of elements, and furthermore, when one of the two conductor patterns of the parallel circuit of the current detection means is disconnected, it is determined that an abnormality is present. Abnormality determining means for determining, and a second control for stopping the operation of the inverter power supply when the abnormality determining means determines that there is an abnormality.
Control means. In this configuration,
Almost the same operation and effects as those of the above-described microwave oven can be obtained.

In each of the above configurations, it is preferable that a plurality of elements of the current detecting means are formed by resistors. Further, it is further preferable that the plurality of elements of the current detecting means are arranged so as to be divided into at least two or more blocks on the substrate.

On the other hand, another microwave oven according to the present invention is a microwave oven comprising a heating chamber, a magnetron for irradiating the heating chamber with microwaves, and an inverter power supply for supplying a high voltage to the magnetron. The inverter power supply includes a switching element that converts DC power into high-frequency AC power, a high-voltage transformer that boosts the high-frequency AC power to a high voltage required for driving the magnetron, and a high voltage on the secondary side of the high-voltage transformer. And a voltage doubler rectifier circuit for rectifying the AC voltage,
On the low voltage side of the voltage doubler rectifier circuit, a grounding section for grounding the housing of the microwave oven is provided, and one side of a signal line for transmitting a signal for controlling the operation of the inverter power supply from the control section of the microwave oven. Is a line flowing through the housing via the grounding portion, and when the grounding portion is removed from the housing, a signal for controlling the inverter power supply is cut off.

In the case of the microwave oven having this configuration, after the grounding part is grounded to the housing of the microwave oven by screwing, if the grounding part is detached from the housing and the grounding becomes incomplete, the control of the inverter power supply is performed. Therefore, a high voltage is not applied to an incomplete ground portion, and therefore, generation of a spark can be reliably prevented.

According to another aspect of the present invention, there is provided a microwave oven comprising: a heating chamber; a magnetron for irradiating the heating chamber with microwaves; and an inverter power supply for supplying a high voltage to the magnetron. The inverter power supply includes a switching circuit configured by connecting a series circuit of a switching element and a series circuit of a capacitor in parallel, and a high-voltage transformer that boosts the high-frequency AC power to a high voltage necessary for driving the magnetron, A DC voltage is applied to a parallel connection point of the switching circuit, and a primary winding of the high-voltage transformer is connected to each series connection point of two series circuits of the switching circuit. And a voltage doubler rectifier circuit connected to the secondary winding of the voltage doubler rectifier circuit. On the compression side, a grounding unit for grounding the microwave oven housing is provided, and one side of a signal line that transmits a signal for controlling the operation of the inverter power supply from the microwave oven control unit is connected to the ground via the grounding unit. And the control signal of the inverter power supply is cut off when the grounding portion comes off the housing. In the case of this configuration as well, if the grounding part is detached from the housing and grounding is incomplete,
It is possible to reliably prevent a spark from being generated at the grounding portion.

Further, the signal line for transmitting the anode current detection signal of the magnetron to the control unit of the microwave oven and the signal line for transmitting the signal for controlling the operation of the inverter power supply from the control unit of the microwave oven are the same. It is a preferable configuration to configure with a wire harness connected to the connector.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a first embodiment of the present invention will be described with reference to FIG. FIG. 1 is a diagram showing an electrical configuration of the microwave oven according to the first embodiment. The microwave oven of the first embodiment is a microwave oven provided with a so-called quasi-E type inverter (inverter power supply).

As shown in FIG. 1, an inverter power supply circuit 101 constituting an inverter power supply includes a commercial AC power supply 102.
And the magnetron 10 which is a microwave oscillation tube
3 is a circuit for supplying a high voltage to the circuit 3. Magnetron 103
Has a function of generating a microwave and irradiating the microwave into a heating chamber (not shown) through a waveguide (not shown). Cooking items are accommodated in the heating chamber.

The inverter power supply circuit 101 includes a rectifier 104, a choke coil 105, and a smoothing capacitor 10.
6, switching element 107, resonance capacitor 108,
It includes a high-voltage transformer 109, a voltage doubler rectifier circuit 110, an inverter control circuit 111, and the like. The inverter power supply circuit 101 is mounted on a printed wiring board (inverter power supply board) 112 indicated by a dashed line.

The input terminal 104a of the rectifier 104,
104b is connected to the commercial AC power supply 102. A choke coil 105 and a smoothing capacitor 106 are connected in series between a positive output terminal 104c and a negative output terminal 104d of the rectifier 104. The resonance capacitor 108 and the primary winding 109a of the high-voltage transformer 109
Are connected in parallel, the parallel circuit and the switching element 107 are connected in series, and this series circuit is connected to both terminals of the smoothing capacitor 106. The switching element 107 is formed of a reverse conducting semiconductor element such as an IGBT, for example. The switching element 107 is configured to be turned on and off by an inverter control circuit 111.

The voltage doubler rectifier circuit 110 comprises a high voltage diode 113 and a high voltage capacitor 114 connected in series, and this series circuit is connected to both ends of a secondary winding 109b of the high voltage transformer 109. . In this case, the voltage doubler rectifier circuit 110 is a half-wave voltage doubler rectifier circuit. Further, both ends of the heater constituting the cathode of the magnetron 103 are connected to both ends of the secondary winding 109c of the high voltage transformer 109. Further, a high voltage diode 115 is connected between an intermediate connection point between the high voltage diode 113 and the high voltage capacitor 114 and one end of the secondary winding 109c of the high voltage transformer 109.
Is connected. Thereby, the voltage doubler rectifier circuit 110
The high voltage side of the negative voltage is connected to the cathode of the magnetron 103.

On the other hand, the low voltage side of the voltage doubler rectifier circuit 110 is connected to the anode of the magnetron 103 via a housing (for example, a metal housing) of a microwave oven. Specifically, a common connection point between the high voltage diode 113 and one end of the secondary winding 109b of the high voltage transformer 109 is connected to one end of, for example, an anode current detection circuit 116 which is current detection means. The other end of the anode current detection circuit 116 is grounded to the housing of the microwave oven via the grounding portion 117 provided on the printed wiring board 112. Further, the anode of the magnetron 103 is grounded to the housing of the microwave oven. Thus, the output terminal on the low voltage side of the voltage doubler rectifier circuit 110 is connected to the magnetron 103 via the housing of the microwave oven.
Is connected to the anode.

Here, the anode current detection circuit 116
Two or more, for example, four resistors 118a, 118
b, 118c and 118d are connected in parallel. This parallel circuit includes four resistors 118a,
It has two conductor patterns 119a and 119b for connecting 118b, 118c and 118d in parallel. These two
The conductor patterns 119a and 119b are provided on the printed wiring board 112 so that their lengths are considerably long and substantially in parallel.

The two resistors 118a and 118b are arranged at one end of the two conductor patterns 119a and 119b, and the two resistors 118c and 118d are arranged at the other end of the two conductor patterns 119a and 119b. Are located in
As a result, the four elements (resistors) of the anode current detection circuit 116
It is configured to be divided into several blocks.

Further, in the case of the above configuration, one end of one conductor pattern 119a on the resistor 118a side is connected to a common connection point between the high voltage diode 113 and one end of the secondary winding 109b of the high voltage transformer 109, and the other is connected. Conductor pattern 11
One end of the resistor 9b on the resistor 118d side is connected to the ground part 117. Here, the grounding portion 117 is formed of a conductor pattern of a predetermined shape (for example, a plurality of rods) provided on the printed wiring board 112, and has a central portion through which a mounting screw (not shown) is inserted. A hole (not shown) is formed.

Then, the mounting screws are connected to the grounding portion 11.
After being inserted through the through hole 7, it is configured to be fastened and fixed to a screw hole (not shown) provided in a housing of the microwave oven (or a mounting metal plate connected to the housing of the microwave oven). ing. Thus, the grounding portion 117 is grounded (connected) to the housing of the microwave oven, and the printed wiring board 112 is attached and fixed to the housing of the microwave oven.

One end of one conductor pattern 119a on the resistor 118d side is connected to a control circuit 122 provided on a panel portion (not shown) of the microwave oven through the conductor pattern 120 and the anode current detection signal line 121. Have been. In the anode current detection circuit 116, the magnetron 103 is provided on the conductor pattern 119a on the side opposite to the ground side.
A voltage of a level corresponding to the magnitude of the anode current is generated. The voltage, that is, the anode current detection signal is supplied to the control circuit 122 of the panel unit of the microwave oven through the conductor pattern 120 and the anode current detection signal line 121 and the housing of the microwave oven. It is configured.

On the other hand, the control circuit 1 of the panel section of the microwave oven
22 is composed of a microcomputer or the like,
It has a function to control the overall operation of the microwave oven. The control circuit 122 is connected to the inverter power supply circuit 10
1 to the inverter control signal line 123.
a, 123b and the conductor patterns 124a, 124b to the inverter control circuit 111. Further, the anode current detection signal line 121 and the inverter control signal lines 123a and 123b are configured by a wire harness 125.

At both ends of the wire harness 125, a connector 126 provided on the printed wiring board 112 of the inverter power supply circuit 101 and a connector provided on the printed wiring board 127 on which the control circuit 122 of the panel portion of the microwave oven is mounted. 128.

The electric circuit diagram of FIG. 1 mainly shows the inverter power supply circuit 101 and its peripheral circuits. Other components of the microwave oven (for example, various sensors, a cooling fan device, RT motors, interior lights, door switches, various operation switches, indicators, etc.) are not shown.

Next, the operation of the above configuration, in particular, the two conductor patterns 119a, 119 of the anode current detection circuit 116
The operation when an abnormality occurs in which one of the lines b is disconnected will be described. First, two conductor patterns 119a,
If the magnetron 103 is driven to oscillate when the magnet 119b is normal, a voltage of a level corresponding to the magnitude of the anode current of the magnetron 103 is generated in the conductor pattern 119a of the anode current detection circuit 116, and this voltage, that is, the anode The current detection signal is sent to the control circuit 122 of the panel section of the microwave oven via the conductor pattern 120 and the anode current detection signal line 121 and the housing of the microwave oven. The control circuit 122 of the panel section is configured to control the output of the magnetron 103 in response to the anode current detection signal. In this case, when the detected value of the anode current detection signal is abnormal, the magnetron 1
The operation of the magnetron 103 is stopped, and the output of the magnetron 103 is controlled to the set output.

When one of the two conductor patterns 119a and 119b of the anode current detection circuit 116 is broken, the resistance value of the anode current detection circuit 116 increases. Therefore, the voltage drop due to the anode current of the magnetron 103 increases, so that the level of the anode current detection signal (detection voltage) input to the control circuit 122 of the panel unit increases. By detecting this, the control circuit 122 of the panel unit operates the anode current detection circuit 116
It is configured to determine that an abnormality (in this case, disconnection) has occurred in any of the conductor patterns 119a and 119b, and to stop the operation of the inverter power supply circuit 101. In the case of this configuration, the control circuit 122 of the panel unit
Are configured to realize respective functions as a first control unit, an abnormality determination unit, and a second control unit.

According to this embodiment having such a configuration, the two conductor patterns 1 of the parallel circuit of the anode current detection circuit 116 are used.
19a and 119b constitute a conductor pattern for connecting one output terminal of the voltage doubler rectifier circuit 110 and the grounding portion 117. Therefore, the two conductor patterns 1
If any one of 19a and 119b is disconnected, the resistance value of the anode current detection circuit 116 increases, and the magnetron 103
Since the voltage drop due to the anode current increases, the level of the anode current detection signal (detection voltage) input to the control circuit 122 of the panel unit increases. As a result, the control circuit 122 of the panel unit determines that the operation is abnormal, and stops the operation of the inverter power supply circuit 101.
Therefore, unlike the conventional configuration (see FIG. 4), it is possible to reliably prevent the occurrence of spark at the broken portions of the conductor patterns 119a and 119b. As a result, burnout, electric shock, and the like caused by the spark can be reliably prevented.

In the above embodiment, since the anode current detection circuit 116 is constituted by a parallel circuit of four resistors 118a to 118d, the production cost of the anode current detection circuit is reduced as compared with the configuration using a current transformer. can do. Furthermore, in the above embodiment, the anode current detection signal is sent to the control circuit 122 of the panel section of the microwave oven via the anode current detection signal line 121 of the wire harness 125 and the housing of the microwave oven. , The number of signal lines constituting the wire harness 125 is determined by the conventional configuration (FIG. 4).
), And the manufacturing cost can be reduced accordingly.

In the above embodiment, the anode current detection circuit 1
Although 6 is constituted by a parallel circuit of four resistors 118a to 118d, it is not limited to this, and may be constituted by a parallel circuit of two, three, or five or more resistors. In the above embodiment, the resistors 118 a to 118 d (elements) of the anode current detection circuit 116 are connected to the printed circuit board 11.
Although the configuration is made such that it is divided into two blocks on 2, for example, it is not limited to this, and it may be configured to be divided into three or more blocks.

FIG. 2 shows a second embodiment of the present invention, and different points from the first embodiment will be described. The same parts as those in the first embodiment are denoted by the same reference numerals. In the second embodiment, a circuit in which two switching elements 129 and 130 are connected in series instead of one switching element 107 is provided.
A configuration was provided in which a full-wave voltage doubler rectifier circuit 131 was provided instead of 0.

More specifically, as shown in FIG. 2, a switching circuit 134 is formed by connecting a series circuit of the switching elements 129 and 130 and a series circuit of the resonance capacitors 132 and 133 in parallel. The DC voltage is applied to the parallel connection points 134a and 134b by connecting both terminals of the smoothing capacitor 106 to the parallel connection points 134a and 134b of the switching circuit 134. At the same time, both terminals of the primary winding 109a of the high-voltage transformer 109 are connected to respective series connection points 134c and 134d of the two series circuits of the switching circuit 134.

The full-wave voltage doubler rectifier circuit 131 is constituted by connecting two high-voltage diodes 135 and 136 connected in series and two high-voltage capacitors 137 and 138 connected in series. . Both ends of the secondary winding 109b of the high-voltage transformer 109 are connected to a series connection point 131a of the high-voltage diodes 135 and 136 and a series connection point 131b of the high-voltage capacitors 137 and 138.

Further, the parallel connection point 131c (ie, the high voltage diode 13) on the upper side in FIG.
5 and an intermediate connection point between the high-voltage capacitor 137) are connected to one end of one conductor pattern 119a of the anode current detection circuit 116 on the resistor 118a side. Also, the parallel connection point 131d on the lower side in FIG. 2 of the full wave voltage doubler rectifier circuit 131 (that is, the lower end in FIG. 2 of the high voltage diode 136 and the lower end in FIG. 2 of the high voltage capacitor 138) is connected to the cathode (high voltage transformer) of the magnetron 103. 109 (one end of the secondary winding 109c). The configuration of the second embodiment other than that described above is the same as the configuration of the first embodiment.

Therefore, in the second embodiment, substantially the same operation and effect as in the first embodiment can be obtained. In particular,
According to the second embodiment having the above-described configuration, since a so-called half-bridge type inverter (inverter power supply circuit) is used, no DC current is superimposed on the primary winding 109a of the high-voltage transformer 109. Can be miniaturized.

FIG. 3 shows a third embodiment of the present invention, and the points different from the first embodiment will be described. The same parts as those in the first embodiment are denoted by the same reference numerals. In the third embodiment, one side of a signal line for transmitting a signal for controlling the operation of the inverter power supply circuit 101 from the control circuit (control unit) 122 of the panel unit of the microwave oven is
It was configured to be a line flowing through the housing of the microwave oven via the grounding portion 117.

More specifically, a microcomputer 139 and, for example, a PNP transistor 140 which is turned on and off by the microcomputer 139 are provided in the control circuit 122 of the panel section of the microwave oven. Further, a photocoupler 141 is provided in the inverter control circuit 111, for example.
Reference numeral 41 denotes an element for transmitting a control signal transmitted from the control circuit 122 of the panel unit while insulating the circuit in the printed wiring board (inverter power supply board) 112 of the inverter power supply circuit 101 from insulation.

In the above configuration, the photocoupler 1
The anode of the light emitting diode 141a is connected to the conductor pattern 142 provided on the printed wiring board 112, the inverter control signal line 143, and the printed wiring board 12
7 is connected to the collector of the transistor 140 via a conductor pattern 144 provided on the transistor 7. Further, the cathode of the light emitting diode 141a of the photocoupler 141 is connected to the conductor pattern 145 provided on the printed wiring board 112.
Is connected to the grounding unit 117 via the. Further, the ground of the control circuit 122 of the panel section is also grounded (connected) to the housing of the microwave oven via the ground line 146.

In the case of the above configuration, the control circuit 12 of the panel section
When a control signal is output from the second microcomputer 139 to the transistor 140, the transistor 140 is turned on and off based on the control signal. Here, when the transistor 140 is turned on, the conductive pattern 14
2. Inverter control signal line 143 and conductor pattern 14
4 through the photocoupler 141 (the light emitting diode 1 of
41a), a current flows through the conductor pattern 145 and the grounding portion 117 to the housing of the microwave oven, and returns to the transistor 140 of the control circuit 122 of the panel unit through the grounding line 146 (and ground). Is configured.

Thus, the control signal output from the microcomputer 139 of the control circuit 122 of the panel section is transmitted to the photocoupler 141 of the inverter control circuit 111, and the switching element 107 is controlled based on the control signal.
Are configured to be on / off controlled. In the case of this configuration, the signal line transmitting the inverter control signal is
It is composed of one inverter control signal line 143 and a line flowing through the housing of the microwave oven via the grounding portion 117. That is, one side of the signal line for transmitting the inverter control signal is a line flowing through the housing via the grounding portion 117.

In the case of the above configuration, a wire harness 147 is constituted by the inverter control signal line 143 and the anode current detection signal line 121. Both ends of the wire harness 147 are connected to the inverter power supply circuit 101.
Connector 148 provided on the printed wiring board 112 of FIG.
And a connector 149 provided on the printed circuit board 127 of the control circuit 122 of the panel section of the microwave oven. The configuration of the third embodiment other than the above is the same as the configuration of the first embodiment.

Now, in the configuration of the third embodiment,
A case will be described in which the grounding portion 117 is detached from the housing of the microwave oven due to, for example, a loose or detached screw (for an incomplete grounding state). In this case, if the grounding portion 117 is removed from the housing,
Since one side of the signal line for transmitting the control signal from the control circuit 122 of the panel section is disconnected, the control signal of the inverter power supply does not flow (is cut off). Therefore, the inverter power supply circuit 101 does not operate,
A high voltage is not applied to the grounding portion 117 detached from the housing, and therefore, it is possible to prevent the occurrence of spark in the detached grounding portion 117.

Also in the third embodiment, the first
It is possible to obtain substantially the same operation and effects as those of the embodiment. That is, the two conductor patterns 11 of the anode current detection circuit 116
If any one of 9a and 119b is disconnected for some reason, the control circuit 122 of the panel unit determines that the disconnection abnormality has occurred and stops the operation of the inverter power supply circuit 101. Pattern 11
It is possible to reliably prevent spark from being generated at the disconnection portions 9a and 119b.

The following are the causes of the disconnection of the conductor patterns 119a and 119b. For example, during transportation, the substrate may be broken or the substrate may be cracked due to the product falling, and the conductor pattern may be broken.

In the third embodiment, since the wire harness 147 is constituted by the inverter control signal line 143 and the anode current detection signal line 121, the number of signal lines constituting the wire harness 147 can be reduced. As a result, the manufacturing cost can be reduced as compared with the conventional configuration. Further, connectors 148 and 149 for connecting the inverter control signal line 143 and the anode current detection signal line 1
Since the connectors 148 and 149 for the 21 connection are configured to be shared, the manufacturing cost can be further reduced.

In the third embodiment, the anode current detection circuit 116 is provided as a parallel circuit in which four resistors 118a to 118d are connected in parallel. However, the present invention is not limited to this. An anode current detection circuit composed of a resistor (that is, a configuration having one long conductor pattern for flowing the anode current of the magnetron) may be provided. In the case of this configuration, it is not possible to detect the disconnection of the conductor pattern, but it is possible to prevent the occurrence of sparks due to the detachment of the grounding portion 117, and to obtain a sufficiently effective effect. Further, an anode current detection circuit including a current transformer may be provided, and the same effect can be obtained.

Further, the third embodiment is different from the first embodiment in that a configuration for cutting off the control signal of the inverter power supply circuit 101 when the grounding portion 117 is removed is added. However, instead of this, a configuration (see the third embodiment) for cutting off the control signal of the inverter power supply circuit 101 when the ground portion 117 comes off is different from the configuration of the second embodiment. An additional configuration may be used. In the case of this configuration, it is possible to obtain substantially the same operation and effect as those of the second and third embodiments. Also, in this configuration, the anode current detection circuit 116 including four resistors 118a to 118d
Instead of this, an anode current detection circuit composed of one resistor may be provided, or an anode current detection circuit composed of a current transformer may be provided.

In each of the above embodiments, the present invention is applied to a microwave oven having only a range cooking function. However, the present invention is not limited to this, and has a range cooking function and an oven cooking function (grill cooking function). It may be applied to a microwave oven with a heater.

[0055]

According to the present invention, as is apparent from the above description, the current detecting means is constituted by a parallel circuit of a plurality of elements, and one of the two conductor patterns of the parallel circuit of the current detecting means is provided. An abnormality determining unit that determines that an abnormality has occurred when a disconnection has occurred, and a second control unit that controls to stop the operation of the inverter power supply when the abnormality determining unit determines that an abnormality has occurred. With this configuration, even if the conductor pattern connecting one output terminal of the voltage doubler rectifier circuit and the grounding part is disconnected, it is possible to reliably prevent sparks from being generated at the disconnected part. Play.

[Brief description of the drawings]

FIG. 1 is an electric circuit diagram showing a first embodiment of the present invention.

FIG. 2 is an electric circuit diagram showing a second embodiment of the present invention.

FIG. 3 is an electric circuit diagram showing a third embodiment of the present invention.

FIG. 4 is an electric circuit diagram showing a conventional configuration.

[Explanation of symbols]

101 is an inverter power supply circuit, 103 is a magnetron,
107 is a switching element, 108 is a resonance capacitor,
109 is a high voltage transformer, 109a is a primary winding, 109
b and 109c are secondary windings, 110 is a voltage doubler rectifier circuit, 1
11 is an inverter control circuit, 112 is a printed wiring board, 113 is a high-voltage diode, 114 is a high-voltage capacitor, 115 is a high-voltage diode, 116 is an anode current detection circuit (current detection means), 117 is a ground section, 118a, 11
8b, 118c and 118d are resistors, 119a and 119
b is a conductor pattern, 120 is a conductor pattern, 121 is an anode current detection signal line, 122 is a control circuit (first control means, abnormality determination means, second control means), 123a, 12
3b is an inverter control signal line, 124a and 124b are conductor patterns, 125 is a wire harness, 126 is a connector, 127 is a printed wiring board, 128 is a connector,
129 and 130 are switching elements, 131 is a full wave voltage doubler rectifier circuit, 132 and 133 are resonance capacitors, 134
Is a switching circuit, 134a and 134b are parallel connection points, 134c and 134d are series connection points, 135 and 136.
Are high voltage diodes, 137 and 138 are high voltage capacitors,
139 is a microcomputer, 140 is a transistor, 141 is a photocoupler, 142 is a conductor pattern,
43 is an inverter control signal line, 144 is a conductor pattern,
145 is a conductor pattern, 146 is a ground wire, 147 is a wire harness, and 148 and 149 are connectors.

Claims (8)

[Claims] 1. A microwave oven comprising: a heating chamber; a magnetron for irradiating the heating chamber with microwaves; and an inverter power supply for supplying a high voltage to the magnetron. A switching element for converting power to electric power; a high-voltage transformer for boosting the high-frequency AC power to a high voltage required for driving the magnetron; and a voltage doubler rectifying circuit for rectifying a high-voltage AC voltage on a secondary side of the high-voltage transformer. A current detecting means provided between the low voltage side of the voltage doubler rectifier circuit and the housing of the microwave oven for detecting an anode current of the magnetron; and when a value detected by the current detecting means is abnormal, And first control means for controlling so as to stop the operation of the inverter power supply. It consists of a parallel circuit of a number of elements,
Further, when any one of the two conductor patterns of the parallel circuit of the current detecting means is disconnected, an abnormality determining means for determining that an abnormality has occurred, and when the abnormality determining means has determined that the abnormality has occurred, And a second control means for controlling so as to stop the operation of the inverter power supply. 2. A microwave oven comprising a heating chamber, a magnetron for irradiating the heating chamber with microwaves, and an inverter power supply for supplying a high voltage to the magnetron, wherein the inverter power supply comprises a series circuit of switching elements. A switching circuit formed by connecting a series circuit of a capacitor and a capacitor in parallel, and a high-voltage transformer that boosts the high-frequency AC power to a high voltage necessary for driving the magnetron. A voltage is applied, and a primary winding of the high-voltage transformer is connected to each series connection point of the two series circuits of the switching circuit, and further connected to a secondary winding of the high-voltage transformer. A voltage doubler rectifier circuit, provided between the low voltage side of the voltage doubler rectifier circuit and the housing of the microwave oven; Current detection means for detecting the anode current of the above, and a first control means for controlling the operation of the inverter power supply to stop when the value detected by the current detection means is abnormal, The current detection means is configured by a parallel circuit of a plurality of elements,
Further, when any one of the two conductor patterns of the parallel circuit of the current detecting means is disconnected, an abnormality determining means for determining that an abnormality has occurred, and when the abnormality determining means has determined that the abnormality has occurred, And a second control means for controlling so as to stop the operation of the inverter power supply. 3. The microwave oven according to claim 1, wherein the plurality of elements of the current detecting means are resistors. 4. The microwave oven according to claim 1, wherein the plurality of elements of the current detection means are arranged in at least two or more blocks on the substrate. . 5. A microwave oven comprising: a heating chamber; a magnetron for irradiating the heating chamber with microwaves; and an inverter power supply for supplying a high voltage to the magnetron. A switching element for converting power to electric power; a high-voltage transformer for boosting the high-frequency AC power to a high voltage required for driving the magnetron; and a voltage doubler rectifying circuit for rectifying a high-voltage AC voltage on a secondary side of the high-voltage transformer. Further, a grounding portion for grounding the housing of the microwave oven is provided on the low voltage side of the voltage doubler rectifier circuit, and the operation of the inverter power supply is controlled from the control portion of the microwave oven. One side of a signal line for transmitting a signal for transmission is a line flowing through the housing via the grounding part, and the grounding part is the housing. A microwave oven characterized in that a signal for controlling the inverter power supply is cut off when the microwave oven comes off. 6. A microwave oven comprising a heating chamber, a magnetron for irradiating the heating chamber with microwaves, and an inverter power supply for supplying a high voltage to the magnetron, wherein the inverter power supply comprises a series circuit of switching elements. A switching circuit formed by connecting a series circuit of a capacitor and a capacitor in parallel, and a high-voltage transformer that boosts the high-frequency AC power to a high voltage necessary for driving the magnetron. A voltage is applied, and a primary winding of the high-voltage transformer is connected to each series connection point of the two series circuits of the switching circuit, and further connected to a secondary winding of the high-voltage transformer. A voltage doubler rectifier circuit, and further on a low voltage side of the voltage doubler rectifier circuit, in a housing of a microwave oven. A grounding section for grounding is provided, and one side of a signal line for transmitting a signal for controlling the operation of the inverter power supply from the control section of the microwave oven is a line flowing through the housing via the grounding section, A microwave oven characterized in that a signal for controlling the inverter power supply is cut off when the grounding portion comes off the housing. 7. A signal line for transmitting an anode current detection signal of the magnetron to a control unit of the microwave oven, and a signal line for transmitting a signal for controlling operation of the inverter power supply from the control unit of the microwave oven. 7. The microwave oven according to claim 1, wherein the microwave oven is configured by a wire harness connected to the same connector. 8. A grounding unit for grounding a housing of a microwave oven is provided on a low voltage side of the voltage doubler rectifier circuit, and a signal for controlling operation of the inverter power supply is transmitted from a control unit of the microwave oven. One side of the signal line is a line that flows through the housing via the grounding portion, and when the grounding portion is removed from the housing, a signal for controlling the inverter power supply is cut off. The microwave oven according to any one of claims 1 to 4, wherein: