JPH0821467B2 - High frequency heating equipment - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-frequency heating device, and more particularly, to a cooker capable of coping with regions having different power supply frequencies without requiring the change of parts.

Conventional Technology In Japan, there are regions where the power supply frequency is 50 Hz and regions where it is 60 Hz. To cope with this, as shown in FIG. 11, the microwave oven has two high-voltage capacitors 52, 53 and an a-contact type high-voltage relay as means for changing the capacity of the high-voltage capacitor.
54, discharge resistance 55, 56, power supply frequency is 50Hz
When the power is turned on, the control unit 57 determines the power frequency,
When a voltage is applied to the coil section 54a of the high voltage relay to close the contact 54b and the power supply clock via the low voltage transformer 58 is not input to the control section 58 for a predetermined time or longer, the voltage is applied to the coil section 54a of the voltage relay. Stop applying voltage, open the contact 54, and discharge the electric charge charged in the high-voltage capacitor 53.
The discharge charge is discharged at 56, and the charge charged in the high voltage capacitor 52 is discharged at the discharge resistor 55. Further, when the power supply frequency is 60 Hz, the high-voltage relay contact 54b is in the “open” state, and if the voltage via the high-voltage transformer 59 is not input, the charge charged in the high-voltage capacitor 52 is discharged by the discharge resistor 55. .

DISCLOSURE OF THE INVENTION Problem to be Solved by the Invention
52, 53, 1a contact type high voltage relay 54, the method of dealing with the power supply frequency 50, 60Hz using the discharge resistance 55, 56 is extremely costly, and in the case of the power supply frequency 50Hz, after the power is turned on,
Until the power supply clock is no longer input to the control unit 57 via the low-voltage transformer 59 for a predetermined time or longer, voltage is applied to the high-voltage relay coil unit 54a, and there is a problem in temperature rise of the coil unit.

Means for Solving the Problems A high-frequency heating device according to the present invention is a high-voltage circuit having a high-voltage transformer, a high-voltage diode, a high-voltage resistor for discharging, two high-voltage capacitors, a high-voltage switching relay, and an external power supply via this high-voltage circuit. A heating chamber for placing a high-frequency generator and an object to be heated, a door provided on the front surface of the heating chamber, and an input means for inputting cooking data including functional information and numerical information. A waveform shaping circuit, a microcomputer, etc., and means for determining a power supply frequency for determining that the frequency is the same at least twice.
A control means for controlling the high-frequency generator and the like, one end of the high-voltage transformer on the high-voltage output side is connected to one of the high-voltage capacitors for obtaining an output for an external power source of 60 Hz, and further for the 60 Hz The discharging high-voltage resistor is connected in parallel to a high-voltage capacitor, and the other high-voltage capacitor is connected to the high-voltage switching relay in parallel so that the 60-Hz high-voltage capacitor is parallel to the high-voltage switching relay. The contact is constituted by a normally closed contact, and is excited or de-excited by the frequency of the external power source, and signals of this excitation or de-excitation are given to the power source frequency determination means and the control means.

Function The high-frequency heating apparatus of the present invention can use only one discharging high-voltage resistor by using a 1b contact type high-voltage relay as a switch means for controlling energization of one of the high-voltage capacitors. In addition, the power supply frequency is determined immediately after the plug-in and twice after the user has entered the cooking start key after setting the cooking, and the high-voltage relay is operated after that, so the capacity of the voltage capacitor that matches the power supply frequency can be set reliably. it can. Also, the high voltage transformer is energized after the high voltage relay contacts are completely "opened", and after the high voltage transformer is de-energized, the high voltage relay contacts are "closed" without arcing. You can safely switch high voltage relays. Further, since the high voltage relay is operated until the cooking start key is received and the cooking end or cancel key is input, it is possible to suppress the temperature rise of the coil portion.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows an external perspective view of a high-frequency heating device to which the present invention is applied. A heating chamber 2 having a front opening is formed in a cabinet 1, and a door 3 provided in the heating chamber 2 so as to be freely opened and closed, The food is taken in and out of the heating chamber 2 and the leakage of high frequency energy is prevented. On the front surface of the upper part of the cabinet 1, there is provided an operation panel 4 on which various switches, setting keys for heating mode and heating time, a start key 4a for starting button cooking and the like are arranged.

FIG. 2 is a horizontal cross-sectional view of the upper part of the cabinet 1, in which a magnetron 5 for generating high frequency energy, a high voltage transformer 6 for applying a high voltage of the magnetron 5 and a high voltage capacitor 7 are arranged. In addition, a control plate 8 incorporating a microcomputer 22 (FIG. 3) having information for detecting the power supply frequency and controlling heating.
And a cooling fan that is driven by motors 9 and 10
9a and 10a are provided to cool the above circuit components. A part of the wind that has cooled the magnetron 5 by the cooling fan 10a is configured to be sent to the above-mentioned heating chamber 2 via the air duct 11.

FIG. 3 shows the basic configuration of the circuit of this high-frequency heating device. In the figure, 12 is a commercial AC power supply, and this power supply 12 includes a main relay contact (normally closed contact) 13b, a primary coil 6a of the high-voltage transformer 6. , The door switch 14 and the fuse 15 are connected in series. Also, for the power supply 12, the door monitor switch
16 are connected in parallel. Further, the lamp relay contact 42b, the interior lamp 43 for heating the room interior lighting, the magnetron cooling fan 10
The turntable motor 44 and the like are also connected in parallel.

The secondary coil 6b of the high voltage transformer 6 has a high voltage capacitor 7
The anode-cathode of the magnetron 5, which is a high-frequency generator, is connected via a half-wave voltage doubler circuit formed by the high voltage diode 17 and the high voltage diode 17. The anode of the magnetron 5 is grounded, and the heater (cathode) is connected to the secondary coil 6c of the high voltage transformer 6. The high-voltage capacitor 7 is composed of two elements 7b connected in parallel, and a discharge resistor 18 is connected in parallel to these elements. A contact 19b of a b-contact type high voltage relay 19 is provided in the middle of the electric path of the high voltage capacitors 7a and 7b.

In addition, the power source 12 includes the fuse 15 and the low voltage transformer.
The control unit 21 is connected via 20. The control unit 21 includes a microcomputer 22 and peripheral circuits thereof, has a pulse generation circuit 23 according to the power supply frequency inside, and has an operation unit 24, a display unit 25, and a coil unit of the relays 13, 19, 42 externally. 13a, 19a and 42a are connected.

In addition, the microcomputer 22 (hereinafter referred to as a microcomputer) is generally a CPU via an I / (input / output unit) 22a.
A (central information processing device) 22b is coupled, and a RAM (write / read storage device) 22c and a ROM (read-only storage device) 22d are coupled thereto.

 Next, the operation of the above configuration will be described.

 First, the determination of the power supply frequency will be described.

When AC power is turned on to this high-frequency heating device, the third
After passing through the pulse generator circuit 23 shown in the figure, as shown in FIG.
The power supply waveform 47a of Hz is shaped into a rectangular waveform 47b. Here, the period of the waveform 47a is 20 msec as shown by 47c. Further, as shown in FIG. 5, the power supply waveform 60a of 60 Hz is shaped into a rectangular waveform 60b, and its period is 16.7 msec as shown in 60c. For example, when a Fujitsu MB8851OB series microcomputer is used as the microcomputer 22, as shown in FIG.
Connect 23 to ▲ ▼ terminal. ROM part 2 of microcomputer 22
When the power supply 12 is input to 2d, the RAM frequency of the RAM 22c is all cleared, and after the initial setting of each port, the power supply frequency determination program shown in FIG. 6 is configured. Power supply frequency is 50 or less
The case of Hz will be described. In step 26, the trailing edge of ▲ ▼ is sensed (Fig. 4, 47g). Next, in steps 27 and 28, P
Set so that an internal interrupt will be generated after msec. Where P
Is an intermediate value between 50 and 60 Hz, that is, [(1/60) + (1/5
0)] / 2 is set. After Pmsec, the internal interrupt shown in Fig. 7 occurs, the program of steps 38 → 39 is executed from RAM ₂ = φ, and from Fig. 4, at 47h, ▲ ▼ = "H".
Therefore, RAM ₁ is set to 0010 at 40. Returning again to the main routine of Fig. 6, RAM ₂ is incremented and RA
M ₂ = 1 and the rising edge of ▲ ▼ is sensed in step 32 (47i in FIG. 4). The level of ▲ ▼ after Pmsec is “L” from FIG. 47j in FIG. 4, so step 3 in FIG.
The program of 8 → 45 is executed, and with the RAM ₁ = 0010, the process returns to the main routine of FIG. Since the RAM ₂ becomes 2, the step 41 is executed, the RAM ₁ becomes 1000, and the falling edge of the IRQ is sensed again in the step 26 (47k in FIG. 4). Fourth
Capturing FIG. 47I, RAM ₁ = 1010 is set, RAM ₂ = 3, and the falling edge of ▲ ▼ is sensed at step 32 (47m in FIG. 4). By capturing 47h in Fig. 4, executing step 30 in the state of RAM ₁ = 1010, and incrementing to RAM ₂ = 4, the judgment of the total of "4 times" shaped waveform is completed. Become. When the power supply frequency is 60 Hz, as can be seen from FIG. 5, RAM ₁ = 5 when the judgment of "4 times" in total is completed. Use RAM ₁ and set RAM ₃ to 1 at 34-37 and 50Hz. Here, there is a case where the process returns to the beginning of the main routine at 36, but at this time, when the determination of the same frequency for four consecutive times is not performed, a loop is made until the determination of the same frequency for four consecutive times is performed.

Next, the operation of the b-contact type high voltage relay 19 will be described. When the power is off, the all-off mode, and the cooking setting mode,
As shown in FIG. 8B, the contact portion 19b of the high voltage relay is "closed". After selecting the menu key on the operation panel 4 and setting the cooking time and the like, when the cooking start key 49 is input, the program set in the ROM section 22d of the microcomputer 22 shown in FIG. Run in order 64. Here, in step 62, check if the menu and cooking time are set correctly, and if not, step
At 63, the routine proceeds to the next routine. After confirming that the door is closed in step 64, the power frequency shown in FIG. 6 is again determined in step 65. Next, at step 66, when the result of determination immediately after plug-in to RAM ₃ and the result of determination at step 65 are equal, at step 67, driving of the high voltage relay, control of magnetron output, etc. are performed.

When the power supply frequency is 60 Hz, a voltage is applied to the coil portion 19a of the high voltage relay from the control portion, and the contact portion 19b "opens" as shown in FIG. 9 (b). As a result, in the high voltage capacitor 7 in the drive part of the magnetron 5, the element 7a (capacity
Only c ₁ ) is in the state of being incorporated in the half-wave voltage doubler circuit.
Therefore, the capacitance C ₁ is given as a capacitance adapted to the power supply frequency (60 Hz) at this time. A timing chart of the voltage applied to the coil of each relay is shown in FIG. Here, the time is set for S _{1 because} the high-voltage relay contact portion 19b completely “opens”. This is to prevent the occurrence of arcs. At the end of cooking or even when the cancel key 46 is pressed, the voltage is applied to the high-voltage relay coil unit 19a after the time S ₂ has elapsed until the main relay contact portion 13b is completely "opened" in order to prevent the occurrence of an arc. Is stopped and the contact 19b is "closed". After that, the electric charge charged in the capacitor 7a is discharged by the discharge resistor R18. Further, when the power supply frequency is 50 Hz (RAM ₃ = φ), the contact portion 19b of the high-voltage relay is "closed" even during cooking, and the high-voltage capacitor 7 has elements 7a and 7b (capacity C ₂ ). And are connected in parallel in a half-wave voltage doubler circuit,
C1 + C2 is given as the capacity that matches the power supply frequency (50Hz). And even after the cooking is completed, the contact part of the high voltage relay
Since 19b is "closed", the charges charged in the capacitors 7a and 7b are discharged by the discharge resistor R18.

Effect of the Invention According to the present invention, the following effects can be obtained.

1.1 By using the 1b contact type high voltage relay, one high voltage resistor for discharge can be deleted, resulting in cost reduction of the product.

2. Since the high voltage relay operates only during cooking, the temperature rise in the relay coil can be suppressed.

3. With respect to "2", the durability of the relay can be maintained.

4 1b contact type high-voltage relay contact is performed after the main relay is "closed" when it is "opened" and after the main relay is "opened" when it is "closed", so that no arc is generated. , Can be switched safely.

5. Judgment of the power frequency is performed twice immediately after the plug-in and when the cooking start key is input, and the actual cooking is started only when the results match. Can be set.

[Brief description of drawings]

FIG. 1 is an external perspective view of a high-frequency heating apparatus applied to an embodiment of the present invention, FIG. 2 is a horizontal cross-sectional view of the same, FIG. 3 is the same circuit diagram, FIG. 4 and FIG. Input waveform diagram of IRQ port, FIGS. 6 to 7 are flow charts of the power supply frequency determination program, FIG. 8 is a flow chart of the start key processing program, and FIG. 9 is a high voltage secondary circuit showing the operation of the high voltage relay. FIG. 10 and FIG. 10 are timing charts of the coil section of the high voltage relay, and FIG. 11 is a circuit diagram of a conventional example. 1 ... Cabinet, 2 ... Heating room, 3 ... Door, 4 ...
… Operation panel, 4a …… Cooking start key, 4b …… Cancel key,
5 ... Magnetron, 6 ... High voltage transformer, 7 ... High voltage condenser, 8 ... Control board, 9 ... Motor, 9a ... Cooling fan, 11 ... Blower duct, 12 ... Commercial AC power supply, 13
...... Main relay, 13a ...... Main relay coil section, 13b
...... Main relay contact part, 20 ...... Low voltage transformer, 21 ……
Control unit, 22 …… Microcomputer, 22a …… I /, 2
2b …… CPU, 22c …… RAM, 22C ₁ …… RAM ₁ , 22C ₂ …… RA
M ₂ , 22C ₃ ...... RAM ₃ , 22d RM, 23 ...... Pulse generation circuit, 24 ...... Operation section, 25 ...... Display section.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akinori Otsuka 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. (56) Reference JP-A-56-41689 (JP, A) JP-A-61-292883 (JP, A) JP 62-17990 (JP, A) Actually developed 63-12189 (JP, U)

Claims (1)

[Claims] 1. A high-voltage circuit having a high-voltage transformer, a high-voltage diode, a high-voltage resistor for discharging, two high-voltage capacitors, a high-voltage switching relay, etc., a high-frequency generator connected to an external power source via this high-voltage circuit, and a heated object. It consists of a heating chamber for placing items, a door provided in front of the heating chamber, an input means for inputting cooking data consisting of functional information and numerical information, a waveform shaping circuit, a microcomputer, etc. A high-voltage output side of the high-voltage transformer is provided with at least a means for determining a power supply frequency immediately after the plug-in and for determining the same frequency twice when the cooking start key is input, and control means for controlling the high-frequency generator. One side of the high-voltage capacitor for obtaining an output for the 60Hz region is connected to one end of the A high-voltage resistor for electrical connection is connected, and the other high-voltage capacitor is connected so that the high-voltage capacitor for 60 Hz is in parallel via the contact of the high-voltage switching relay, and the contact of the high-voltage switching relay is a normally closed contact. A high-frequency heating device configured to be excited or de-excited by a frequency of an external power source, and the excitation or de-excitation signal being given to the power source frequency determination means and the control means.