KR100346977B1 - Electronic range - Google Patents

Abstract

The present invention relates to a microwave oven having a rotating plate for supporting food, wherein the control device 21 controls the inverter circuit 4 at a constant duty ratio, while the maximum current value Imax while the rotating network rotates 360 ° and The minimum current value Imin is detected, and these maximum current value Imax and minimum current value Imin are the primary side input current values of the high voltage transformer 19, and the controller 21 is the maximum current value Imax. And when the minimum current value Imin is detected, the network is stopped at the position where the maximum current value Imax or the minimum current value Imin is generated and irradiated with microwaves in the cooking chamber to place the shape of the food container or food. It is characterized by heating the food in a balanced and efficient manner without being affected by the position as much as possible.

Description

Microwave oven {ELECTRONIC RANGE}

The present invention relates to a microwave oven having a rotating plate for supporting food.

In the case of the conventional microwave oven, the strength of the electric field (the magnitude of the heating energy) is generated in the cooking chamber due to the standing wave of the microwave. For this reason, when heating relatively small foods (a bowl of air, a small amount of side dishes, etc.), heating efficiency falls, and heating imbalance occurs when heating large foods (multiple steamed buns, pizza, etc.) unfolded in the planar direction. Therefore, the food is placed on the rotating plate via a cooking plate, and the food is heated while rotating the rotating plate.

In the above configuration, the heating imbalance in the circumferential direction can be suppressed, but the heating is weak at the center portion of the rotating dish, and the heating is stronger at the outer circumference portion, especially when there is an excitation hole on the side wall of the cooking chamber. The heating imbalance in the radial direction cannot be effectively suppressed. In addition, the heating imbalance in the vertical direction in the "heating" and the like is not improved, and sufficient heating efficiency is not obtained when a small food is placed on the center portion of the rotating dish.

For this reason, although the structure of following (1) and (2) can be considered, both have some drawbacks and are not effective measures.

(1) A movable element for adjusting the impedance is installed in the waveguide, and the open impedance is adjusted to the maximum efficiency of the magnetron according to the state of the cooking chamber. In this configuration, when the impedance adjusting conductor provided in the waveguide is the cause of the spark and the occurrence of the spark is to be suppressed, the effect of adjusting the impedance is reduced.

(2) A movable exciter is installed at the bottom of the cooking chamber, and the movable exciter is moved directly under the food. In this structure, since the drive mechanism of a movable excitation hole becomes complicated, installation of a movable excitation hole is difficult and it lacks practicality.

(3) While rotating the rotating plate, move it up and down. This configuration is complicated because a drive mechanism for moving the rotary plate up and down is required.

The present applicant has proposed in Japanese Patent Application Laid-Open No. 9-298437 to stop a rotating plate made of a conductive material at an angle in accordance with food and to irradiate microwaves to the food in a stationary state of the rotating plate. This invention focuses on the characteristic electric field distribution generate | occur | produced in a cooking chamber according to the stop angle of a rotating plate, and can solve the above-mentioned problem. However, there is room for improvement in that it is not possible to cope with the difference in electric field distribution according to fluidity factors such as the dispersion of the food placing position, the shape and size of the food container, and to heat the food in a balanced and efficient manner.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and provides a microwave oven capable of heating foods in a balanced and efficient manner without being influenced by fluid factors such as the distribution of food placing positions, the shape and size of food containers, and the like. It is.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a first embodiment of the present invention (a flowchart showing the control contents of a controller);

2 is a flowchart showing the control contents of the controller;

3 is a perspective view showing an overall configuration,

4 is a view showing an electrical configuration,

5A is a perspective view showing a stop position of a rotating net when a cup is used;

5B is a view showing a stop position of a rotating net when using a bowling machine,

6 is a plan view showing a rotating network;

7a is a diagram experimentally showing the relationship between the stopping angle of the rotating network and the input current value;

7B is an experiment showing the relationship between the stopping angle of the rotating network and the heating efficiency of the food;

8 is a view corresponding to FIG. 1 showing a second embodiment of the present invention;

9 is equivalent to FIG. 2,

10 corresponds to FIG. 6 showing a third embodiment of the present invention;

11 corresponds to FIG. 6 showing a fourth embodiment of the present invention;

12 is a view corresponding to FIG. 6 showing a fifth embodiment of the present invention;

Figure 13 corresponds to Figure 6 showing a sixth embodiment of the present invention and

Fig. 14 is a diagram corresponding to Fig. 6 showing a seventh embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

2: cooking chamber 4: inverter circuit

5: Commercial AC power supply (AC power supply) 19: High voltage transformer

21: control device (control means) 23: magnetron (heating means)

35: current transformer (current detection means) 47: RT motor (motor)

51: rotating network (rotating plate) 61: automatic cooking key

65 liquid crystal display (display means) 68: opening

69: rotating plate

The microwave oven according to claim 1 includes a high-pressure transformer for pressurizing an AC power source, heating means for irradiating microwaves in the cooking chamber based on the power supplied from the high-voltage transformer, and a conductive material installed in the cooking chamber to support food. A rotating plate made of a rotating plate, a motor for rotating the rotating plate, current detecting means for detecting a primary side or secondary side current of the high-voltage transformer, and driving control of the motor in the cooking chamber in a stationary state of the rotating plate. And control means for irradiating microwaves, wherein the control means rotates the rotating plate to detect an output signal of the current detecting means, and sets a stop position of the rotating plate based on a detection result of the output signal. Have

According to the above means, when the rotating plate is rotated in a state where the food is placed, the standing wave in the cooking chamber is disturbed and the impedance in the cooking chamber changes. Then, a change occurs in the oscillation state of the heating means, and the current values on the primary side and the secondary side of the high-voltage transformer change. In this manner, since the stop position of the rotating plate is set based on the current value, the food is efficiently and efficiently heated at the stop position where dispersion, shape, etc. of the placing position of the food container are added.

The microwave oven according to claim 2 is characterized in that the rotating plate has a non-uniform shape in the rotational direction.

According to the said means, the electric field distribution in a cooking chamber changes largely according to the stop position of a rotating plate, and since a rich heating pattern is formed, it becomes easy to obtain a suitable stop position according to the shape of a food container.

The microwave oven according to claim 3 is characterized in that, in the central portion of the rotating plate, an opening having a length equal to or greater than "1/4" of the microwave wavelength is provided in both the longitudinal length and the horizontal length.

According to the said means, a microwave becomes easy to pass through an opening part of a center irrespective of the stop position of a rotating plate. For this reason, since the microwaves reflected upward by the bottom plate of the cooking chamber are irradiated to the central food through the central opening, the food is heated more efficiently.

The microwave oven according to claim 4 is characterized in that the control means stops the rotating plate at a position at which the detection result of the current detecting means is maximum.

According to the above means, the cooking time is shortened because the food on the rotating plate is heated at maximum efficiency.

The microwave oven according to claim 5 is characterized in that the control means sets the stop position of the rotating plate based on the detection result of the current detecting means after a predetermined time has elapsed from the start of driving of the heating means.

According to the means, the current value is detected in a state where the oscillation operation of the heating means is stable. For this reason, since the variation of the electric field distribution according to the rotation angle of the rotating plate is faithfully reflected in the electric current value, the electric field distribution is accurately detected as the electric current value.

The microwave oven according to claim 6 includes an inverter circuit for supplying power to the high-voltage transformer, and based on the detection result of the current detecting means in a state where the control means maintains the on / off ratio of the inverter circuit constant, It is characterized by setting the stop position.

According to the said means, a current value is detected in the state in which the power supply condition with respect to a heating means was kept constant. For this reason, since the variation of the electric field distribution according to the rotation angle of the rotating plate is faithfully reflected in the electric current value, the electric field distribution is accurately detected as the electric current value.

The microwave oven according to claim 7 is characterized in that the control means stops the rotating plate at the set position based on the elapsed time from the reference time.

According to the above means, the rotating plate can be stopped at the set position by the timekeeping function of the control means. For this reason, since a dedicated sensor which stops a rotating plate at a setting position is unnecessary, the structure is simplified.

The microwave oven according to claim 8 is characterized in that the control means rotates the rotating plate again in the stopped state to detect the output signal of the current detecting means, and resets the stop position of the rotating plate based on the detection result of the output signal.

According to the said means, since the stop position of a rotating plate is correct | amended when the electric field distribution in a cooking chamber changes with time, or there exists an error in setting of the last stop position, food is heated efficiently and efficiently.

The microwave oven according to claim 9 includes an inverter circuit for supplying power to a high voltage transformer, and the control means controls the inverter circuit based on the detection result of the current detecting means.

According to the said means, the current detection means which detects the fluctuation | variation of an electric field distribution, and the current detection means using control of an inverter circuit are combined. This simplifies the configuration because it is not necessary to separately install the current detecting means.

The microwave oven according to claim 10 is characterized in that the control means sets the stop position of the rotating plate according to the detection result of the current detecting means and the operation contents of the automatic cooking key.

According to the said means, for example, based on stopping the rotating plate at the position where the maximum current value is generated in case of "heating", when rotating the food plate at the highest efficiency or "root vegetable", the rotating plate may be The food can be heated at the lowest efficiency based on stopping at the generation position. For this reason, since the heating mode suitable for food is obtained, food is heated more efficiently and efficiently.

The microwave oven according to claim 11 includes display means for displaying cooking information, and the control means displays on the display means that the stop position of the rotating plate is detected.

According to the above means, the user can be informed that the rotating plate is detected by detecting the stop position of the rotating plate, so that the user is prevented from giving a sense of discomfort caused by the repeated rotation and stopping of the rotating plate.

The microwave oven according to claim 12 includes shape detecting means for detecting the shape of the food container placed on the rotating plate, and the control means sets the stop position of the rotating plate according to the detection result of the current detecting means and the detection result of the shape detecting means. It is characterized by

According to the above means, when a peculiar food container such as a liquor bottle is detected, the rotating plate can be stopped at a position where a current value slightly smaller than the maximum current value is generated, and the food can be heated at a rate slightly lower than the maximum efficiency. For this reason, since a strong heating energy is prevented from being concentrated in a part of food, food is heated efficiently in a balanced manner.

Embodiment of the Invention

Hereinafter, a first embodiment of the present invention will be described based on FIGS. 1 to 7. First, in FIG. 3, the cabinet 1 has a rectangular box shape with an open front surface, and the cooking chamber 2 is formed inside the cabinet 1. The cooking chamber 2 has a rectangular box shape in which the front surface is opened. The door 3 is rotatably mounted in the cabinet 1, and the front opening of the cooking chamber 2 is based on the rotational movement of the door 3. Are opened and closed.

In the cabinet 1, a machine room (not shown) is formed adjacent to the right side of the cooking chamber 2, and an inverter circuit 4 is provided in the machine room as shown in FIG. The inverter circuit 4 is provided with power from the commercial AC power supply 5 through both power supply lines 6, and is constituted as follows.

Both AC input terminals of the rectifier circuit 7 are connected to both power supply lines 6, and a power supply line 8 is connected to the DC output terminal (-) of the rectifier circuit 7. A power supply line 9 is connected to the DC output terminal + of the rectifier circuit 7, and a smoothing reactor 10 is inserted into the power supply line 9. In addition, reference numeral 11 denotes a noise removing capacitor connected between the power supply lines 6.

The series circuit of the resonant capacitor 12 and the IGBT 13 is connected between the power supply lines 8 and 9 of the rectifier circuit 7. This IGBT 13 has a feedback diode 14, and a smoothing capacitor 15 is connected in parallel to the series circuit of the resonant capacitor 12 and the IGBT 13 between the power supply lines 8 and 9. .

One terminal of the primary coil 16 is connected to the power supply line 8 of the rectifier circuit 7, and the other terminal of the primary coil 16 is connected to the power supply line 9. The primary coil 16 constitutes a high voltage transformer 19 together with the secondary coils 17 and 18. When the IGBT 13 is on, a current I1 flows in the primary coil 16. When the IGBT 13 is off, current I2 flows in the primary coil 16. In addition, the high pressure transformer 19 is installed in the machine room.

The driver IC 20 is connected to the gate terminal of the IGBT 13, and the control device 21 corresponding to the control means is connected to the driver IC 20. This control device 21 mainly comprises a microcomputer, and supplies power to the primary coil 16 of the high voltage transformer 19 based on switching control of the IGBT 13 through the driver IC 20. The inverter circuit 4 is comprised as mentioned above.

As shown in FIG. 5, an excitation port 22 for supplying microwaves in the cooking chamber 2 is provided on the right side wall of the cooking chamber 2. Is placed on. Further, a waveguide (not shown) is fixed to the circumferential edge of the excitation port 22 in the machine room. The waveguide is connected to a magnetron 24 (see Fig. 4) which is located in the machine room and generates microwaves, and both cathode terminals of the magnetron 23 are secondary to the high pressure transformer 19 as shown in Fig. 4. It is connected to both terminals of the coil 17, and the positive terminal of the magnetron 23 is earthed. In addition, the magnetron 23 corresponds to a heating means.

A double voltage rectifier circuit 24 is connected to both terminals of the secondary coil 18 of the high voltage transformer 19. The double voltage rectifying circuit 24 is formed by connecting a series circuit composed of two high voltage capacitors 25 and a series circuit composed of two high voltage diodes 26 in parallel, and the magnetron 23 is separated from the double voltage rectifying circuit 24. ), When the power is supplied, the magnetron 23 oscillates, and microwaves are irradiated from the magnetron 23 into the cooking chamber 2 through the waveguide and the excitation port 22 (range cooking). 4 denotes resistors connected in parallel to both series circuits of the double voltage rectifier circuit 24. In FIG.

Both terminals of the primary coil 28 are connected to both power lines 6 of the commercial AC power supply 5. The primary coil 28 constitutes the step-down transformer 30 together with the secondary coil 29. The center of the secondary coil 29 is earthed, and the rectifier circuit 31 is provided at both terminals of the secondary coil 29. Connected. The rectifier circuit 31 is composed of two diodes 32, and one terminal of the resistor 33 is connected to the rectifier circuit 31.

One terminal of the capacitor 34 is connected to the other terminal of the resistor 33. The other terminal of this capacitor | condenser 34 is earthed, and the control apparatus 21 detects the power supply voltage Vin of the commercial AC power supply 5 based on the terminal voltage of the capacitor | condenser 34. As shown in FIG. In addition, a current transformer (CT) 35 is provided in one power supply line 6 of the commercial AC power supply 5. This CT 35 corresponds to alternating current detection means, and the control device 21 detects the input current value Iin for the inverter circuit 4 based on the output signal from the CT 35. In addition, one terminal of the resistor 36 is connected to the double voltage rectifier circuit 24. The other terminal of the resistor 36 is earthed, and the controller 21 detects the anode current Ib of the magnetron 23 based on the voltage generated by the resistor 36.

The fan motor 39 is connected between the two power supply lines 6 of the commercial AC power supply 5 via the contact point 38 of the fan relay 37. The fan motor 39 is installed in the machine room, and the control device 21 closes the contact 38 based on supplying power to the coil 40 of the fan relay 37, and uses the commercial AC power supply 5. Power is supplied to the fan motor 39 from both power supply lines 6 through the power supply line 6. A cooling fan (not shown) is connected to the rotating shaft of the fan motor 39. When the power is supplied to the fan motor 39, the cooling fan rotates, and electrical components (high pressure transformer 19, magnetron) in the machine room are rotated. (23), etc., cooling air is injected.

The heater 43 is connected between the two power supply lines 6 of the commercial AC power supply 5 via the contact 42 of the heater relay 41. This heater 43 is installed in the ceiling in the cooking chamber 2, and the control apparatus 21 closes the contact 42 based on supplying power to the coil 44 of the heater relay 41, and uses a commercial AC power supply. The electric power is supplied to the heater 43 through the both power supply lines 6 from (5). In this way, when the power is supplied, the heater 43 generates heat, and the inside of the cooking chamber 2 is heated (heater cooking).

The RT motor 47 is connected between the two power supply lines 6 of the commercial AC power supply 5 via the contact 46 of the RT relay 45. The RT motor 47 incorporates a reduction gear mechanism, and the control device 21 closes the contact 46 based on supplying power to the coil 48 of the RT relay 45. When closed in this way, power is supplied to the RT motor 47 from the commercial AC power supply 5 through both power supply lines 6, and the rotating shaft 49 (refer FIG. 3) of the RT motor 47 rotates.

The RT motor 47 is disposed below the cooking chamber 2, and the rotating shaft 49 of the RT motor 47 passes through the bottom plate of the cooking chamber 2, as shown in FIG. 3. It protrudes inward, and the plug part 50 which has a rectangular cross section is formed in the front-end | tip part of the rotating shaft 49. As shown in FIG. The rotation shaft 49 rotates at a constant speed in a constant direction, and the time required for the rotation shaft 49 to rotate 360 ° is set to Tk seconds (10 or 12 seconds) depending on the frequency of the power supply.

As shown in FIG. 5, the rotating shaft 49 of the RT motor 47 is connected to the rotating net 51 made of steel plate in the cooking chamber 2. As shown in Fig. 6, the rotating mesh 51 is directly connected to the peripheral edge portion 52 of the annular shape, the plurality of vertical rod portions 53 extending in the front-back direction, and the vertical rod portion 53. A plurality of horizontal bar portions 54 are formed integrally, and a cylindrical boss portion 55 is provided at the center of the rotating network 51. The inner surface of the boss portion 55 is formed in a rectangular cross section, and the rotary mesh 51 has a rotating shaft based on the detachable fitting of the inner surface of the boss portion 55 to the outer surface of the plug portion 50. 49) is not rotatable. In addition, the rotating net 51 corresponds to the rotating plate.

The vertical rod portion 53 of the rotating mesh 51 is formed at equal intervals of the distance b, and the distance b is less than "1/4" of the wavelength λ (about 122 mm) of the microwave (for example, 30 mm), and most of the vertical rod portions 53 have a long shape extending continuously in the peripheral edge portion 52. In addition, the horizontal bar portion 54 is a short that does not continuously extend into the peripheral edge portion 52, and the gap size a is located at the portion except the center portion in the left and right directions of the horizontal bar portion 54 in the microwave wavelength λ. ) Is set to "1/2" or more (for example, 64 mm).

The rotating net 51 is provided with a plurality of openings 56 except for the central portion in the horizontal direction. Each of the openings 56 indicates a portion partitioned by the long vertical rod portion 53 and the short horizontal bar portion 54, and has a rectangular shape having a width of “b” and a length of “a”. The opening part 56 adjacent to the left-right direction has shifted the position about "a / 2" in the front-back direction. The rotating net 51 has a non-uniform shape with respect to the rotational direction, and the mesh shape at the time of rotation by 180 ° has the same point symmetry (180 ° rotation object) as before the rotation.

As illustrated in FIG. 5, a circular cooking dish 57 is placed on the rotating mesh 51 at the time of stove cooking. The cooking dish 57 is formed of microwave-transmissive materials such as glass and ceramics, and the cooking dish 57 is placed on the cooking dish 57. In addition, the rotating mesh 51 is formed based on press working a steel plate, and the surface of the rotating mesh 51 is subjected to the enameling process.

When microwaves are irradiated from the excitation port 22 into the cooking chamber 2, predetermined standing waves are generated depending on the size of the cooking chamber 2, the position of the excitation port 22, the shape of the rotary mesh 51, and the like. For this reason, since the electric field distribution in the cooking chamber 2 becomes nonuniform, there exists a difference in heating energy in each part in the cooking chamber 2. In particular, in the case of the rotary net 51, the wall current flowing through the rotary net 51 is rectified in the extending direction of the vertical rod part 53, and the direction of the microwave traveling and the longitudinal direction of the opening 56 intersect. When the microwave easily passes through the opening 56, and when the traveling direction of the microwave coincides with the longitudinal direction of the opening 56, the microwave becomes difficult to pass through the opening 56. A characteristic electric field distribution according to this is obtained.

As shown in FIG. 3, the operation panel 58 is fixed to the front surface of the cabinet 1 at the front of the machine room. The start key 59 is attached to the front of the operation panel 58, and the start switch 60 is provided behind the start key 59 as shown in FIG. This start switch 60 is connected to the control apparatus 21, and the control apparatus 21 detects operation of the start key 59 based on the output signal of the start switch 60. As shown in FIG.

As shown in FIG. 3, the automatic cooking key 61 is mounted on the front of the operation panel 58, and as shown in FIG. 4, the automatic cooking switch 62 is located behind the automatic cooking key 61. Is installed. This automatic cooking switch 62 is connected to the control apparatus 21, and the control apparatus 21 detects the operation content of the automatic cooking key 61 based on the output signal of the automatic cooking switch 62, and automatically Based on the operation contents of the cooking key 61, automatic cooking menus such as "heating", "fresh thaw" and "muscle vegetables" are selected.

A time dial 63 is rotatably mounted on the front of the operation panel 58 as shown in FIG. 3, and a rotary encoder 64 is installed on the back of the time dial 63 as shown in FIG. 4. It is. This rotary encoder 64 is connected to the control apparatus 21, and the control apparatus 21 detects the operation amount of the time dial 63 based on the output signal of the rotary encoder 64, The cooking time T is set based on the manipulated variable.

As shown in FIG. 3, a liquid crystal display (LCD) 65 corresponding to display means is mounted on the front surface of the operation panel 58. As shown in FIG. This liquid crystal display 65 is connected to the control apparatus 21 as shown in FIG. 4, and the control apparatus 21 supplies cooking information, such as a cooking time T and the remaining cooking time, to the liquid crystal display 65. FIG. Display.

Next, the effect | action of the said structure is demonstrated. The following operation is executed by the controller 21 based on the control program stored in advance in the ROM. The controller 21 operates the start key 59 after the cooking menu and the cooking time T are set. If it is detected, the process moves from step S1 to step S2 in FIG. 1 and the fan motor is based on supplying power to the coil 40 of the fan relay 37 and the coil 48 of the RT relay 45. (39) and RT motor 47 are driven.

The controller 21 switches the IGBT 13 through the driver IC 20 when the fan motor 39 and the RT motor 47 are driven. Then, the magnetron 23 is supplied with power from the high voltage transformer 19 to start oscillation of the microwaves. At this time, "Vin x Iin" is calculated based on the terminal voltage of the capacitor 34 and the output signal of the CT 35, and the ON time of the IGBT 13 is set so that "Vin x Iin" becomes a constant value "Pin". To control.

When the cooking apparatus starts cooking of the stove, the control unit 21 proceeds to step S3 of FIG. 1 and whether a predetermined time (for example, six seconds) has elapsed from the start of cooking of the stove until the oscillation of the magnetron 23 is stabilized. Judge. If it is determined that the predetermined time has elapsed, the process proceeds to step S4, where the input current value Iin is compared with the reference value Io. This reference value Io is stored in advance in the ROM of the control apparatus 21, and when the control apparatus 21 detects "Io> Iin" in step S4, it transfers to step S5.

When the control apparatus 21 moves to step S5, the control apparatus 21 displays an error on the liquid crystal display 65, and informs the user of the abnormality. Then, the IGBT 13 is kept in the off state, and the oscillation operation of the magnetron 23 is stopped. At the same time, the contacts 38 and 46 are opened on the basis of turning off the coil 40 of the fan relay 37 and the coil 48 of the RT relay 45 and the fan motor 39 and the RT motor 47. Stop rotation.

When the controller 21 detects "Iin? Io" in step S4 of Fig. 1, the controller 21 shifts to step S6 to switch the control mode of the IGBT 13. The IGBT 13 is switched and controlled at a constant on / off ratio (duty ratio) irrespective of "Vin x Iin". At this time, the message " Stop position detecting " is displayed on the liquid crystal display unit 65, and the flow proceeds to step S7.

In this state, since the electric field distribution in the cooking chamber 2 changes according to the rotation angle of the rotating network 51, the input current value Iin of the inverter circuit 4 fluctuates according to the rotating angle of the rotating network 51. As shown in FIG. FIG. 7A shows experimentally the relationship between the rotation angle (°) of the rotating network 51 and the input current value Iin (A). 7B shows experimentally the relationship between the rotation angle (°) of the rotating net 51 and the heating efficiency (%) of food.

In these experiments, the food is placed on the rotating net 51, and the input current value Iin and the heating efficiency are measured in the stationary state of the rotating net 51, and a container in which 150 cc of water is stored is used for the food. As apparent from FIG. 7, there is a proportional correlation between the input current value Iin and the rotation angle and between the rotation angle and the heating efficiency, and the heating efficiency is high at the rotation angle with a large input current value Iin, The rotational efficiency is small at a rotation angle with a small input current value Iin.

When the control apparatus 21 moves to step S7 of Fig. 1, the controller 21 detects the input current value Iin each time a predetermined time (for example, 0.1 second) elapses, and the input current value Iin and the input current value are detected. The detection time of (Iin) is correlated and stored. This detection time is the starting time of rotation of the rotating network 51 as reference time (= 0), and the control apparatus 21 performs time Tk (time required for the rotating network 51 to rotate in step S8). If elapsed) is detected, execution proceeds to step S9.

The control device 21 detects the maximum value Imax and the minimum value Imin in the detection result of the input current value Iin, when it transfers to step S9. Subsequently, the detection time Ta of the maximum value Imax and the detection time Tb of the minimum value Imin are detected, and the flow proceeds to step S10. Here, the stop position of the rotary net 51 is set by adding the time Tk required for the rotary net 51 to rotate one time to the detection time Ta of the maximum value Imax. At the same time, the time Tk is added to the detection time Tb of the minimum value Imin to set another stop position of the rotary network 51.

If the control apparatus 21 sets the stop position of the rotating net 51, it will transfer to step S11. Here, the control mode of the IGBT 13 is returned to its original state, and the on time of the IGBT 13 is controlled so that "Vin x Iin" becomes a constant value "Pin". The flow advances to step S12 of FIG. 2 to detect a cooking menu based on the operation contents of the automatic cooking key 61. For example, when "warming up", "warming up", "milk", etc. are selected, it progresses to step S13.

When the control apparatus 21 moves to step S13, when the cooking time T reaches the above-mentioned "Ta + Tk", the control device 21 turns off the coil 48 of the RT relay 45, and the RT motor 47 Disconnect the power. Then, the message " stopping position detection " of the liquid crystal display unit 65 is erased, and the message " Stop heating at the MAX point " The RT motor 47 has a large internal resistance (such as a reduction gear ratio of the reduction gear mechanism) set so that the motor stops rotating at the same time as the power is turned off. When the RT motor 47 is disconnected, the rotation shaft of the RT motor 47 ( 49) stops rotation, and the rotating net 51 stops at the position where heating efficiency becomes maximum.

When the control apparatus 21 stops the rotating network 51, it transfers to step S14 of FIG. When detecting that the cooking time T has elapsed, the message " stop heating to the MAX point " is erased, and the oscillation operation of the magnetron 23 is stopped. At the same time, the fan motor 39 is rotated to stop the cooking.

When the control apparatus 21 detects that a cooking menu such as "root vegetables" is selected in step S12 of Fig. 2, the control device 21 proceeds to step S15. Then, at the moment when the cooking time T reaches "Tb + Tk", the RT motor 47 is turned off, and the rotating net 51 is stopped at the position where the heating efficiency is minimum. Then, the message " stopping position detection " of the liquid crystal display unit 65 is erased, and the message " Stop heating to MIN point " is displayed on the liquid crystal display unit 65. Thereafter, at step S14, the cooking time When detecting that (T) has elapsed, the message " Stop heating to Min point "

When the control apparatus 21 detects that a cooking menu such as "fresh thaw" is selected in step S12, the control apparatus 21 proceeds to step S16. Then, when the cooking time T reaches "Ta + Tk" described above, the RT motor 47 is turned off, and the rotating network 51 is turned on for a predetermined time (for example, 10) at the position where the heating efficiency is maximized. For a second). At this time, the message of "stopping position detection" of the liquid crystal display unit 65 is erased, and the message of "stop heating at the MAX point" is displayed on the liquid crystal display unit 65.

The control apparatus 21 transfers to step S17 of FIG. 2 when the rotating network 51 is stopped for a predetermined time. Here, Ta and Tb are compared, and when "Ta <Tb", it sets to "(DELTA) T1 = Tb-Ta". If "Ta> Tb" is set, "ΔT1 = Tk- (Ta-Tb)" is set, and the flow advances to step S18.

When the control apparatus 21 moves to step S18, the control unit 21 supplies the RT motor 47 with the power ΔT1, thereby rotating the rotating network 51 to a position where the heating efficiency is minimum. 10 seconds). Then, the message &quot; stop heating at the MAX point &quot; of the liquid crystal display unit 65 is erased, and the message &quot; Stop heating at the MIN point &quot; is displayed on the liquid crystal display unit 65.

The control apparatus 21 moves to step S19 when the rotating network 51 is stopped for a predetermined time. Here, Ta and Tb are compared, and when "Tb <Ta", it sets to "(DELTA) T2 = Ta-Tb". In addition, in the case of "Tb> Ta", it is set to "(DELTA) T2 = Tk- (Tb-Ta)", and it transfers to step S20.

If the control device 21 detects that the cooking time T has not elapsed in step S20, the control unit 21 proceeds to step S16 and based on supplying power to the RT motor 47 by the time? The 51 is rotated to a position where the heating efficiency is maximum, and stopped for a predetermined time (for example, 10 seconds). Then, the message &quot; stop heating at MIN point &quot; of the liquid crystal display unit 65 is erased, and the message &quot; Stop heating at MAX point &quot; is displayed on the liquid crystal display unit 65. FIG. After that, the steps S16 to S20 until the cooking time T elapses are repeated.

In addition, the control apparatus 21 performs the processing operation of following (1)-(3) at the time of stove cooking, and prevents abnormal change of the range pressure based on the fluctuation of the power supply voltage Vin and the temperature rise of the magnetron 23. As shown in FIG. At the same time, the processing operation (4) is executed to stop cooking when an abnormality is impossible.

(1) When the terminal voltage Vin of the capacitor 34 decreases, the on time of the IGBT 13 is controlled so that the input current value Iin does not exceed a predetermined value (for example, 14.5 A).

(2) When the magnetron 23 generates heat and the voltage Eb of FIG. 4 decreases, the on time of the IGBT 13 is controlled so that the anode current value Ib does not exceed a predetermined value (for example, 315 mA).

(3) When the input power decreases under the control of (1) and (2) above, the cooking time T is corrected.

(4) When the cathode and the anode of the magnetron 23 are short-circuited or a short circuit occurs in the double-voltage rectifier circuit 24, and the anode current value Ib exceeds the predetermined value, the IGBT 13 is turned off to stop cooking.

According to the above embodiment, it is based on the detection result of the input current value Iin based on the fact that there is a proportional correlation between the primary input current value Iin of the high voltage transformer 19 and the electric field distribution in the cooking chamber 2. The stop position of the prospect 51 was controlled. For this reason, as shown in FIG. 5A, when the cup 66 is mounted on the rotating net 51 via the cooking dish 57, the shape of the cup 66, the mounting position, etc. are added. At the stop position, the microwaves are spot irradiated. In addition, as shown in FIG. 5B, when the rice bowl 67 is provided on the rotating network 51, a microwave spot spots in the stop position which added the shape of the rice bowl 67, the mounting position, etc. In this manner, the milk in the cup 66 and the rice in the rice bowl 67 are efficiently heated in a balanced manner.

In addition, since the rotating net 51 is formed in a non-uniform shape with respect to the rotation direction, the electric field distribution greatly changes depending on the stop position of the rotating net 51. For this reason, since a rich heating pattern is formed, a preferable stop position corresponding to various container shapes and cooking menus is obtained.

In addition, the rotating network 51 was stopped at the position where the input current value Iin becomes the maximum value Imax. For this reason, since the food on the rotating net 51 is heated with maximum efficiency, the set value of the cooking time T is completed shortly.

In addition, since the stop position of the rotary network 51 is set based on the input current value Iin after a predetermined time (6 seconds) has elapsed since the start of the driving of the magnetron 23, the oscillation operation of the magnetron 23 is stable. In the state, the input current value Iin is detected. For this reason, since the fluctuation | variation of the electric field distribution according to the rotation position of the rotating network 51 is reflected faithfully to the input current value Iin, the maximum current value Imax and the minimum current value Imin are detected correctly.

In addition, since the stop position of the rotary network 51 is set based on the input current value Iin while the on / off ratio (duty ratio) of the inverter circuit 4 is kept constant, the magnetron 23 The input current value Iin is detected while the power supply condition is kept constant. For this reason, since the fluctuation | variation of the electric field distribution according to the rotation position of the rotating network 51 is reflected faithfully to the input current value Iin, also in this point, the maximum current value Imax and the minimum current value Imin are detected correctly. .

In addition, the rotary net 51 was stopped at the set position based on the elapsed time "Tk + Ta" and "Tk + Tb" from the reference time. For this reason, the sensor detects the reference position of the rotary net 51 by the sensor, and it is not necessary to stop the rotary net 51 at the set position based on the elapsed time after the reference position passes through the sensor. Is unnecessary and the configuration is simplified.

In addition, in order to stop the rotating network 51 at a set position, the rotating network 51 is rotated again from detection of the maximum current value Imax and the minimum current value Imin, and the maximum current value Imax and minimum current value ( It is conceivable to turn off the RT motor 47 at the moment when Imin) is redetected. In this case, it is necessary to control the inverter circuit 4 at a constant duty ratio until the rotating network 51 is stopped at the set position, so that the time for which the stove cooking can be performed at the set output is shortened. On the other hand, if the rotating network 51 is stopped at the set position based on the elapsed time "Tk + Ta" and "Tk + Tb", the time for controlling the inverter circuit 4 at a constant duty ratio is shortened. The time which can be performed by setting output becomes long.

Further, the stop position of the rotary net 51 was set by adding the operation contents of the automatic cooking key 61 to the input current value Iin. For this reason, when performing "warming up" or the like, when food is heated at maximum efficiency based on stopping the rotating network 51 at the position where the maximum current value (Imax) occurs, and performing "root vegetable" or the like. The food can be heated with minimum efficiency based on stopping the rotating net 51 at the position where the minimum current value Imin is generated. In addition, when performing "fresh thawing" or the like, the food is stopped at maximum efficiency and on the basis of alternately stopping the rotary network 51 at the position where the maximum current value Imax and the position where the minimum current value Imin are generated. Alternate heating with minimum efficiency automatically results in a heating mode suitable for all foods, resulting in a more balanced and efficient heating of the food.

The duty ratio of the IGBT 13 was set based on the input current value Iin detected by the CT 35. For this reason, since the current detection means which detects the fluctuation | variation of an electric field distribution, and the current detection means used for the control of the inverter circuit 4 are combined, it is not necessary to provide a current detection means separately, and the structure is simplified.

In addition, the message "During stopping position detection" was displayed on the liquid crystal display part 65. For this reason, since the user can be notified that the rotating mesh 51 is detecting the stop position of the rotating mesh 51, the rotation mesh 51 is prevented from giving the user a sense of discomfort that the rotating mesh 51 rotates or stops. .

The liquid crystal display 65 also displays the message &quot; stop heating at MAX point &quot; and &quot; stop heating at MIN point &quot;. For this reason, since the user can be notified that cooking is performed in the stationary state of the rotating net 51, the user is mistaken that the rotating net 51 stops due to a breakdown or the like.

Next, a second embodiment of the present invention will be described based on FIGS. 8 and 9. When the controller 21 detects that the cooking time T has not elapsed in step S20 of FIG. 9, the controller 21 shifts to step S21 to set the cooking time T as the reference value T ₀₁ (for example, 60 seconds). ). Here, the repeated upon detection of a "T≤T ₀₁ 'proceeds to step (S16), and the cooking time (T) steps up to the time lapse (S16~21).

Control device 21 compares the phase (S21) upon detection of a "T> 60 cho" different reference value (R _02), the cooking time (T), the process proceeds to step (S22) (for example, 120 seconds) in the. When detecting "60 seconds <T <= 120 second" here, it will transfer to step S23 and the cooking elapsed time based on the cooking start time will be compared with "T-30 second." For example, when the elapsed time does not reach "T-30" second, the process proceeds to step S16 and repeats steps S16 to S23.

When the control apparatus 21 detects that the elapsed time reaches "T-30" second in step S23, it returns to step S4 of FIG. 8, and transfers to steps S6 and S7. Here, while controlling switching of the IGBT 13 at a constant on / off ratio, the input current value Iin is detected every predetermined time, and the process proceeds to S10 via S9 in step S8.

When the control apparatus 21 advances to step S10, the control apparatus 21 adds time Tk to the detection time Ta of a new maximum value Imax, and sets a new stop position of the rotating network 51. FIG. At the same time, the time Tk is added to the detection time Tb of the new minimum value Imin to set another new stop position of the rotating network 51. Then, after returning the control mode of the IGBT 13 to the original state in step S11, the process shifts to steps S16 to S23 in Fig. 9 to a new stop position and another stop position until the cooking time T elapses. The rotating mesh 53 is stopped by turns.

When the control apparatus 21 detects "T> 120 seconds" in step S22 of FIG. 9, it transfers to step S24 and changes elapsed time to "T-30 second" and "120-3 (= 90) second". Compare with For example, if the elapsed time is neither "T-30 sec" nor "90 sec", the process returns to step S16 and steps S16 to S24 are repeated.

The control apparatus 21 returns to step S4 of FIG. 8, if it detects that elapsed time reaches "90 second" in step S24. Then, in step S10, the time Tk is added to the detection time Ta of the new maximum value Imax to set a new stop position of the rotary network 51. At the same time, the time Tk is added to the detection time Tb of the new minimum value Imin to set another new stop position of the rotary network 51. Thereafter, the process proceeds to steps S16 to S24 in FIG. 9, and the rotating network 51 is stopped at a new stop position and another new stop position alternately.

The control apparatus 21 returns to step S4 of FIG. 8, when it detects that the elapsed time reached "T-30 (> 90) second" in step S24. Then, in step S10, the time Tk is added to the detection time Ta of the new maximum value Imax to set a new stop position of the rotary network 51. At the same time, the time Tk is added to the detection time Tb of the new minimum value Imin to set another new stop position of the rotary network 51. After that, the process moves to steps S16 to S24, and the rotating network 51 is stopped at a new stop position and a new stop position alternately until the cooking time T elapses.

According to the above embodiment, the rotating net 51 is rotated again, and the stop position of the rotating net 51 is reset based on the input current value Iin at the time of the re-rotating of the rotating net 51. For this reason, since the stop position is corrected when the electric field distribution in the cooking chamber 2 fluctuates or when there is an error in the setting of the previous stop position, the food is heated in a more efficient and balanced manner.

In addition, when the cooking time T is short (60 seconds or less), the stop position of the rotating net 51 is not correct | amended. This threshold value of 60 seconds is a time at which electric field concentration (concentration of heating energy) does not occur. When the cooking time is short, the effect of spot heating is obtained as much as possible within the range where electric field concentration does not occur.

In addition, when the cooking time T is long (greater than 60), since the stop position of the rotating net 51 is corrected, heating energy is dispersed and acted on the food when the rotating net 51 is rotated again. In addition, since the variation of the electric field distribution and the setting error of the stop position are corrected based on the resetting of the stop position, the food is heated in a balanced and efficient manner.

In addition, in the second embodiment, the stop position of the rotating network 51 is reset according to the cooking time T only when the cooking menu is "raw thawing." However, the cooking menu is not limited thereto. Also in the case of sake warming, milk, warming, root vegetables, etc., the stop position of the rotary net 51 may be reset in the same manner as in "fresh thawing".

In addition, in the first and second embodiments, when the maximum value Imax and the minimum value Imin of the input current value Iin are detected, the rotating network 51 is rotated 360 °, but the present invention is not limited thereto. For example, you may rotate 180 degrees. In this case, since the rotating net 51 forms the object to be rotated 180 degrees, the maximum value Imax and the minimum value Imin are detected relatively accurately only by rotating the rotating net 51 by 180 degrees.

Next, a third embodiment of the present invention will be described with reference to FIG. Four openings 68 surrounding the boss portion 55 are formed in the rotating mesh 51, and one opening 68 is formed adjacent to the upper side of the two openings 68 at the upper end, and the lower two One opening 68 is formed adjacent to the lower portion of the opening 68.

Each of the openings 68 has a square shape, and the length c in the vertical direction and the length c in the horizontal direction of each of the openings 68 are "1/4" or more of the wavelength λ of the microwave (for example, For example, 31 mm). The rotating net 51 has a non-uniform shape in the rotational direction, and has a net 90-degree rotational object shape that is substantially the same as before the rotation when the mesh is rotated 90 degrees.

According to the said embodiment, since the opening part 68 was formed in the center part of the rotating net 51, it becomes easy for a microwave to pass through the opening 68 regardless of the stop position of the rotating net 51. FIG. For this reason, the microwaves reflected upward by the bottom plate of the cooking chamber 2 are irradiated to the food placed on the center portion of the rotating network 51 through the opening 68, so that the food is heated more efficiently and the cooking time ( T) is shortened.

Next, a fourth embodiment of the present invention will be described with reference to FIG. The rotating plate 69 is connected to the rotating shaft 49 of the RT motor 47. The rotary plate 69 has three arm portions 72 connecting the peripheral edge portion 70 of the annular shape with the hub portion 71 positioned at the center portion, the peripheral edge portion 70 and the hub portion 71. It is formed by integrally forming, the cylindrical boss portion 73 is provided on the lower surface of the hub portion (71). The inner surface of the boss portion 73 has a rectangular cross section, and the rotating plate 69 is based on the detachable fitting of the inner surface of the boss portion 73 to the outer surface of the plug portion 50. ) Is non-rotatable. Moreover, the rotating plate 69 is formed of the steel plate, and the enameling process is given to the surface of the rotating plate 69. FIG.

The arm portions 72 of the rotating plate 69 are provided at equal intervals of 120 ° in the circumferential direction, and extend radially about the hub portion 71. And the rotating plate 69 has comprised the 120 degree rotation object shape which becomes the same as the shape before rotation when it rotates 120 degrees. In addition, three openings 74 are formed in the rotating plate 69. Each of the openings 74 indicates an arc-shaped portion partitioned by two arm portions 72 and the peripheral edge portion 70 adjacent to the circumferential direction, and the maximum size e of each opening 74 is It is set to "1/2" or more of the wavelength (lambda) of a microwave.

According to the above embodiment, the wall surface current is rectified in the extending direction of the arm portion 72, and the state of transmission and reflection of microwaves varies depending on the rotational position of the opening 74, and according to the stop position of the rotating plate 69. The electric field distribution in the cooking chamber 2 greatly changes. In addition, since the rotating plate 69 is in the shape of the object to be rotated by 120 degrees, approximately the same electric field distribution is obtained every time the rotating plate 69 is rotated by 120 degrees.

Next, a fifth embodiment of the present invention will be described with reference to FIG. Three openings 75 are formed in the hub portion 71 of the rotating plate 69 at equal intervals of 120 ° in the circumferential direction. Each of the openings 75 has an arc shape, and the position of the openings 75 is shifted by 60 ° in the circumferential direction with respect to the opening 74 of the outer peripheral portion.

Next, a sixth embodiment of the present invention will be described with reference to FIG. The four edge parts 72 are connected between the peripheral edge part 70 of the rotating plate 69 and the hub part 71. These arm parts 72 are arrange | positioned at equal intervals by 90 degrees in the circumferential direction, and the rotating plate 69 becomes a 90 degree rotation object shape.

Next, a seventh embodiment of the present invention will be described with reference to FIG. The circumferential edge portion 70 and the hub portion 71 of the rotating plate 69 are connected by five arm portions 72. These arm parts 72 are arrange | positioned at equal intervals of 72 degrees in the circumferential direction, and the rotating plate 69 is a 72 degree rotation object shape.

In addition, in the first to seventh embodiments, the rotating network 51 (rotating plate 69) is stopped at the position where the maximum current value Imax is generated, but the present invention is not limited thereto. For example, the side wall of the cooking chamber 2 is provided. A shape detecting means such as an optical sensor is installed in the sensor, and the quasi-maximal current value of about 80% of the maximum current value Imax is limited only when the shape detecting means detects a long food container such as a wine bottle. It may detect and stop the rotating net 51 (rotating plate 69) at the generation position of the quasi-maximal current value. In this case, since strong heating energy is prevented from concentrating on a part of liquor, such as a liquor bottle, liquor, such as a liquor bottle, is balanced and efficiently heated.

Further, in the first to seventh embodiments, the stop position of the rotary network 51 (rotating plate 69) is set based on the input current value Iin of the primary side of the high-voltage transformer 19. Instead, for example, the stop position of the rotating network 51 (rotating plate 69) may be set based on the anode current value Ib of the secondary magnetron 23 of the high-voltage transformer 19. In this case, the current detecting resistor 36 functions as a current detecting means.

In the first to seventh embodiments, the user operates the time dial 63 to manually set the cooking time T. However, the present invention is not limited thereto. It is good also as a structure which detects and automatically controls cooking time T based on the output signal of a weight sensor. Alternatively, the gas sensor may detect the amount of gas generated by the food and automatically terminate cooking based on a large increase in the output signal from the gas sensor.

Further, in the first to seventh embodiments, the input current value Iin is detected while continuously rotating the rotating network 51 (rotating plate 69). However, the present invention is not limited thereto, and for example, intermittently at predetermined angles. The input current value Iin may be detected while rotating.

In addition, in the first to seventh embodiments, it is notified that the stop position of the rotary net 51 (rotating plate 69) is detected or cooking is performed in the stationary state of the rotary net 51 (rotating plate 69). When notifying, the message "Stop position detection", "Stop heating at MAX point" and "Stop heating at MIN point" were displayed on the liquid crystal display 65, but the present invention is not limited thereto. For example, a pattern or a figure may be displayed.

In the first to seventh embodiments, the elapsed time "Ta + Tk" and "Tb + Tk" were measured using the rotation network 51 (the start time of the driving of the rotating plate 69 as the reference time (= 0). For example, the control mode of the IGBT 13 may be measured at the instant when the duty ratio is constantly switched (step S6) as the reference time (= 0).

In the first to seventh embodiments, the rotating network 51 (rotating plate 69) is stopped at a setting position based on the elapsed time "Ta + Tk" and "Tb + Tk", but the present invention is not limited thereto. For example, from the detection of the maximum current value Imax and the minimum current value Imin, the rotating network 51 (rotating plate 69) is rotated again to detect the maximum current value Imax and the minimum current value Imin again. The motor may be stopped at the set position based on turning off the RT motor 47 at the moment. In this case, it is preferable to control the inverter circuit 4 at a constant duty ratio until the rotating network 51 (rotating plate 69) is stopped at the set position.

In the first to seventh embodiments, the present invention is applied to a microwave oven having a heater cooking function, but the present invention is not limited thereto. For example, the present invention may be applied to a microwave cooking exclusive machine.

In the first to seventh embodiments, the magnetron 23 is exemplified as a heating means for irradiating microwaves into the cooking chamber 2, but the present invention is not limited thereto, and it is sufficient to generate microwaves to heat food.

As apparent from the above description, the microwave oven of the present invention has the following effects.

According to the means of claim 1, the stop position of the rotating plate is set based on the primary side or secondary side current value of the high-pressure transformer, and the microwave is irradiated into the cooking chamber while the rotating plate is stopped. It is heated efficiently and balanced without being affected by the back as much as possible.

According to the means of Claim 2, the rotating plate was provided in a non-uniform shape with respect to the rotation direction. For this reason, since a rich heating pattern is formed, the optimum stop position according to various container shapes or the like is obtained.

According to the means of Claim 3, the opening part was provided in the center part of the rotating plate. For this reason, since the microwaves reflected upward by the bottom plate of the cooking chamber are irradiated to the food through the opening, the food is more efficiently heated.

According to the means of claim 4, since the rotating plate is stopped at the position where the detection result of the current detecting means becomes the maximum value, the food is heated at maximum efficiency.

According to the means of claim 5, since the stop position of the rotating plate is set based on the current value after a predetermined time has elapsed from the start of driving of the heating means, the electric field distribution is accurately detected as the current value.

According to the means of claim 6, since the stop position of the rotating plate is set based on the current value in a state where the on / off ratio of the inverter circuit is kept constant, it is accurately detected as the current value of the electric field distribution.

According to the means of claim 7, the rotating plate is stopped at the set position based on the elapsed time from the reference time, so that a sensor for detecting the reference position of the rotating plate is unnecessary and the configuration is simplified.

According to the means of claim 8, the rotating plate was rotated again to reset the stop position. For this reason, since the stop position is corrected when the electric field distribution fluctuates with time, or when there is an error in the setting of the previous stop position, the food is heated in a more balanced and efficient manner.

According to the means of claim 9, the inverter circuit was controlled based on the detection result of the current detecting means. For this reason, since the current detection means for detecting the variation of the electric field distribution and the current detection means used for controlling the inverter circuit are combined, the configuration is simplified.

According to the means of claim 10, the stop position of the rotating plate was set by adding the operation contents of the automatic cooking key to the detection result of the current detecting means. For this reason, since a heating mode suitable for food is automatically obtained, food is heated more efficiently and more balanced.

According to the means of claim 11, since the stop position of the rotary plate is detected, the user is prevented from giving a sense of discomfort that the rotary plate rotates or stops.

According to the means of claim 12, the stop position of the rotating plate was set by adding the shape of the food container to the detection result of the current detecting means. For this reason, since a strong heating energy is prevented from being concentrated in a part of the food container of a special shape, food is heated efficiently in a balanced manner.

Claims (12)

A high voltage transformer for converting AC power to high pressure; Heating means which is urged by the high pressure imparted from the high pressure transformer and irradiates microwaves in the cooking chamber; A rotating plate made of a conductive material installed in the cooking chamber to support food; A motor for rotationally driving the rotating plate; Current detecting means for detecting a primary side or secondary side current of the high voltage transformer; And And controlling means for driving the motor while controlling microwaves in the cooking chamber to control rotation and stop of the rotating plate, The control means rotates the rotating plate to detect the output signal of the current detecting means, and determines the stop position of the rotating plate as at least one position of the maximum value or the minimum value corresponding to the detection result of the output signal as the rotation reference position. Microwave oven characterized in that. The method of claim 1, The rotating plate is a microwave oven, characterized in that the non-uniform shape in the rotation direction. The method of claim 1, The microwave oven is characterized in that an opening having a length equal to or greater than "1/4" of a microwave wavelength is provided in the center of the rotating plate in both the longitudinal length and the horizontal length. The method of claim 1, And the control means stops the rotating plate at a position at which the detection result of the current detecting means is maximum. The method of claim 1, And the control means determines the stop position of the rotating plate according to the current value of the high voltage transformer detected by the current detecting means after a predetermined time has elapsed since the start of driving of the heating means. The method of claim 1, In addition, an inverter circuit for driving a high voltage transformer at a high frequency is further provided. And the control means determines the stop position of the rotating plate according to the current value of the high voltage transformer detected by the current detection means while maintaining the on / off ratio of the inverter circuit constant. The method of claim 1, And the control means stops the rotating plate at the determined position based on the elapsed time from the reference time. The method of claim 1, And the control means re-determines the stop position of the rotating plate according to the current value of the high voltage transformer detected by the current detecting means while the rotating plate is rotated again from the stopped state. The method of claim 1, Further provided with an inverter circuit for driving the high voltage transformer at high frequency, And the control means controls the operation of the inverter circuit according to the current value of the high voltage transformer detected by the current detection means. The method of claim 1, In addition, an automatic cooking key for selecting an automatic cooking menu, And the control means determines the stop position of the rotating plate according to the current value of the high voltage transformer detected by the current detecting means and the auto cooking menu selected by the auto cooking key. The method of claim 1, Display means for displaying cooking information, And the control means displays on the display means that the stop position of the rotating plate is detected. The method of claim 1, It is provided with shape detection means for detecting the shape of the food container mounted on the rotating plate, And the control means determines the stop position of the rotating plate according to the current value of the high voltage transformer detected by the current detecting means and the microwave electric field distribution determined by the shape detecting means.