JP6205284B2 - microwave - Google Patents

Description

  The present invention relates to a microwave oven.

  Conventionally, there is a microwave oven that cooks food in a heating chamber with microwaves from a magnetron (see, for example, JP 2010-107110 A (Patent Document 1)).

  By the way, when a microwave oven having the above-described configuration is mounted on an aircraft, the microwaves from the magnetron are periodically generated to prevent interference between the microwaves and the in-flight wireless LAN (local area network). ing.

JP 2010-107110 A

  In such a microwave oven mounted on an aircraft, the power supply frequency fluctuates greatly depending on the flight state or the like depending on the aircraft model (for example, in the Boeing Model 787, the frequency of the AC power supply is 360 Hz to 800 Hz). For this reason, in the microwave oven, if the frequency of the power supply voltage deviates from the normal operation range of the microwave oven body during the microwave heating operation, there is a problem that the magnetron oscillation operation is not normally performed.

  Specifically, in the above microwave oven, the frequency of the power supply voltage becomes lower than the lower limit of the normal operating range during the heating operation, the magnetron oscillation stops abnormally, or the frequency of the power supply voltage is higher than the upper limit of the normal operating range. As a result, the magnetron is overheated and damaged by the temperature rise.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a microwave oven that can prevent abnormal operation of a magnetron even when the frequency of a power supply voltage fluctuates greatly in a microwave heating operation.

In order to solve the above problems, the microwave oven of the present invention is
A microwave oven mounted on an aircraft and supplied with a power supply voltage whose frequency varies,
A magnetron that generates microwaves by the power supply voltage supplied from the aircraft ;
A frequency detector for detecting the frequency of the power supply voltage;
A frequency determination unit that determines whether or not the frequency of the power supply voltage detected by the frequency detection unit is within a preset frequency range;
A controller for controlling the magnetron based on the determination result of the frequency determination unit,
When the frequency determination unit determines that the frequency of the power supply voltage is not within a preset frequency range during the heating operation in which the object to be heated is heated by the microwave generated from the magnetron, the magnetron The oscillation is stopped.

In one embodiment of the microwave oven,
The control device oscillates the magnetron and resumes the heating operation when the frequency determination unit determines that the frequency of the power supply voltage is within the frequency range after stopping the oscillation of the magnetron in the heating operation. To do.

In one embodiment of the microwave oven,
An oscillation stop time measuring unit that measures the oscillation stop time of the magnetron in the heating operation;
After the oscillation of the magnetron is stopped in the heating operation, when the frequency determination unit determines that the frequency of the power supply voltage is within the frequency range and restarts the heating operation, the measurement is performed by the oscillation stop time measurement unit. And a heating time correction unit for correcting the remaining heating time of the heating operation based on the oscillation stop time of the magnetron.

In one embodiment of the microwave oven,
A load capacity determination unit for determining the load capacity of the microwave;
When the load capacity determination unit determines that the load capacity of the microwave is equal to or less than a preset load capacity determination value, the control device causes a first oscillation mode to periodically generate a microwave from the magnetron. On the other hand, when it is determined that the load capacity of the microwave detected by the load capacity determination unit is larger than the load capacity determination value, the second oscillation mode for continuously generating the microwave from the magnetron; To do.

In one embodiment of the microwave oven,
Based on the heating time for heating the object to be heated and the duty ratio when the microwave from the magnetron is periodically turned on / off, the consumption time representing the degree of consumption due to the oscillation operation of the magnetron is calculated for each heating operation. A consumption time calculation unit to perform,
A consumption time integration unit for integrating the consumption time of the magnetron calculated by the consumption time calculation unit;
A depletion time determination unit that determines whether or not the accumulated value of the depletion time of the magnetron accumulated by the depletion time accumulation unit exceeds a predetermined depletion time determination value;
When the consumption time determination unit determines that the accumulated value of the consumption time of the magnetron has exceeded the consumption time determination value, a notification unit for notifying that it is time to replace the magnetron.

  As is apparent from the above, according to the present invention, in the heating operation in which the object to be heated is heated by the microwave generated from the magnetron, the oscillation of the magnetron is performed when the frequency of the power supply voltage is not within the preset frequency range. By stopping the operation, it is possible to realize a microwave oven that can prevent abnormal operation of the magnetron even if the frequency of the power supply voltage fluctuates greatly in the microwave heating operation.

FIG. 1 is a front view of a microwave oven according to a first embodiment of the present invention. FIG. 2 is a sectional view taken along line II-II in FIG. FIG. 3 is a block diagram showing a schematic configuration of the microwave oven control apparatus. FIG. 4 is a timing chart of the heating operation by the microwave of the microwave oven. FIG. 5 is a timing chart when the oscillation of the magnetron is stopped by the frequency fluctuation of the power supply voltage during the heating operation of the microwave oven. FIG. 6 is a block diagram showing a schematic configuration of a control device for a microwave oven according to the second embodiment of the present invention. FIG. 7 is a block diagram showing a schematic configuration of a microwave oven control apparatus according to a third embodiment of the present invention. FIG. 8 is a block diagram showing a schematic configuration of a control device for a microwave oven according to a fourth embodiment of the present invention.

  Hereinafter, the microwave oven of the present invention will be described in detail with reference to the illustrated embodiments.

[First Embodiment]
FIG. 1 shows a front view of a microwave oven 1 according to the first embodiment of the present invention. The microwave oven 1 according to the first embodiment is mounted on an aircraft equipped with a wireless LAN (local area network).

  As shown in FIG. 1, the microwave oven 1 according to the first embodiment has an operation unit 3 installed at the upper part of the front surface of the rectangular parallelepiped cabinet 2, and a left end on the lower side of the operation unit 3 on the front surface of the cabinet 2. A door 4 is provided that rotates around the side edge to open and close the heating chamber 10 (shown in FIG. 2). A handle 5 is provided on the right side of the door 4 and a heat-resistant glass window 6 is fitted in the door 4. Further, a liquid crystal display unit 7 is provided on the left side of the operation unit 3 in the figure. By operating the keys of the operation unit 3, the content corresponding to the operation is displayed on the liquid crystal display unit 7 by the control device 100.

  Here, the microwave oven 1 heats an object to be heated placed in the heating chamber 10 by a microwave generated by a magnetron 11 (shown in FIG. 2). Note that the heating structure of the object to be heated by the microwave is the same as that of a conventional microwave microwave oven.

  FIG. 2 shows a sectional view taken along line II-II in FIG. In FIG. 2, the same components as those in FIG. 1 are denoted by the same reference numerals. Also, reference numeral 27 in FIG. 2 denotes a dust receiver.

  As shown in FIG. 2, the heating chamber 10 is disposed in the cabinet 2, and the magnetron 11 is disposed on the rear surface side of the lower portion of the heating chamber 10 in the cabinet 2. The microwave generated in the magnetron 11 is guided to the lower center of the heating chamber 10 by the waveguide 12, and is rotated upward by the rotating antenna 14 driven by the rotating antenna motor 13 toward the upper side in the heating chamber 10. The object to be heated on the bottom tray 30 is radiated and heated.

  An outside air inflow duct 16 in which a cooling fan 15, a waveguide 12, and a magnetron 11 are arranged is provided below the heating chamber 10 in the cabinet 2. An external air flow inlet 17 is provided at a position facing the cooling fan 15 on the lower surface of the external air inflow duct 16, and external air is taken into the external air inflow duct 16 from the external air flow inlet 17 by driving the cooling fan 15.

  FIG. 3 shows a schematic configuration of the control device 100 of the microwave oven 1 (shown in FIG. 1). The control device 100 includes a microcomputer, an input / output circuit, and the like, and includes a timer 100a for measuring the heating time and the like, and a frequency determination unit 100b for determining the frequency of the power supply voltage detected by the frequency detection unit 23.

  The frequency detector 23 includes a conversion circuit (not shown) that converts an AC voltage signal of a power supply voltage supplied from the outside into a zero cross pulse, and a counter (not shown) that counts the zero cross pulse. .

  The frequency detector is not limited to this, and estimates the frequency of the power supply voltage based on the primary side input current or the secondary side output current of the magnetron high-voltage transformer 21 that applies a high voltage to the magnetron 11. May be. Specifically, since there is a correlation between the primary side input current (or secondary side output current) of the magnetron high-voltage transformer 21 and the frequency of the power supply voltage, its characteristics are obtained in advance through experiments and used. This makes it possible to estimate the frequency of the power supply voltage.

  The control device 100 applies a high voltage to the liquid crystal display unit 7, the rotating antenna motor 13, and the magnetron 11 based on signals from the operation unit 3, the door open / close detection switch 20 and the frequency detection unit 23. It controls the high voltage transformer 21, the magnetron heater transformer 22 that applies a voltage to the filament 11 a of the magnetron 11, the cooling fan 15, the power cutoff unit (not shown), and the like.

  The magnetron high-voltage transformer 21 and a first switch unit (not shown) for turning on and off the AC voltage applied to the input side of the magnetron high-voltage transformer 21 constitute a magnetron driving unit. The magnetron heater transformer 22 and a second switch unit (not shown) for turning on and off the AC voltage applied to the input side of the magnetron heater transformer 22 constitute a filament driving unit.

  FIG. 4 is a timing chart of the heating operation by the microwave of the microwave oven 1. In FIG. 4, t1, t2, T1, T2, and T3 are different from the real time in order to make the drawing easier to see.

  First, when the user opens and closes the door 4 in order to place the article to be heated in the heating chamber 10, the door opening and closing detection switch 20 detects the opening and closing of the door 4. In response to the signal indicating that the door 4 is opened from the door opening / closing detection switch 20, the control device 100 starts to apply a voltage to the filament 11 a via the magnetron heater transformer 22. At this time, the control device 100 drives the cooling fan 15.

  Next, the heating operation is started by turning on the start key of the operation unit 3, and the object to be heated is heated by the microwave generated periodically from the magnetron 11. Here, the magnetron 11 repeats the oscillation (t1 = 2.5 seconds) and the stop (t2 = 0.5 seconds) of the microwave. The period of the microwave oscillation at this time is 3.0 seconds, and the duty ratio is t1 / t2 (= 2.5 seconds / 3.0 seconds). This periodic microwave oscillation can prevent a wireless LAN communication failure in the aircraft.

  When the heating time T1 ends, first, the oscillation of the magnetron 11 is stopped, and the voltage application to the magnetron heater transformer 22 is stopped after the first stop time T2 after the oscillation of the magnetron 11 is stopped. The cooling fan 15 is stopped after the second stop time T3 has elapsed from the time when the voltage application to the filament 11a is stopped, and the power supply voltage is shut off (shut down) by a power shut-off unit (not shown).

  FIG. 5 is a timing chart when the oscillation of the magnetron 11 is stopped by the frequency fluctuation of the power supply voltage during the heating operation of the microwave oven 1. 5 is the same as the heating operation shown in FIG. 4 except for the operation of stopping the oscillation of the magnetron 11. In FIG. 4, t1, t2, t3, T1, T2, T3, and Td are different from the real time in order to make the drawing easier to see.

  Here, it is assumed that the frequency of the power supply voltage of the aircraft in which the microwave oven 1 is mounted fluctuates within a range of 360 Hz to 800 Hz.

  As shown in FIG. 5, the frequency of the power supply voltage is detected by the frequency detection unit 23 during the heating operation in which the object to be heated is heated by the microwaves periodically generated from the magnetron 11, and the frequency of the power supply voltage is set to a predetermined value. When the frequency determination unit 100b determines that the frequency is not within the frequency range (680 Hz ± 10%), the control device 100 stops the voltage application to the magnetron high-voltage transformer 21 and the magnetron heater transformer 22, and the magnetron 11 oscillates. Stop.

  Next, after the oscillation of the magnetron 11 is stopped, when the frequency determination unit 100b determines that the frequency of the power supply voltage detected by the frequency detection unit 23 is within the predetermined frequency range (680 Hz ± 10%) again, the control The apparatus 100 starts preheating by applying a voltage to the filament 11a via the magnetron heater transformer 22, and after a predetermined preheating time t3, applies a high voltage to the magnetron 11 via the magnetron high voltage transformer 21.

  Thereby, even if the frequency of the power supply voltage fluctuates greatly in the microwave heating operation, it is possible to stop the oscillation of the magnetron 11 and prevent abnormal operation. If the frequency determination unit 100b determines that the frequency of the power supply voltage is within a predetermined frequency range (680 Hz ± 10%) after the oscillation of the magnetron 11 is stopped, the magnetron 11 can be normally re-oscillated.

  In addition, by preheating the filament 11a before oscillating by applying a high voltage to the magnetron 11, the frequency of the power supply voltage falls within a predetermined frequency range from the state where the oscillation of the magnetron 11 is stopped, and then the magnetron 11 is operated. It oscillates reliably without going into a ding state.

  Further, according to the microwave oven 1, when the frequency determination unit 100b determines that the frequency of the power supply voltage is within the predetermined frequency range (680 Hz ± 10%) after the oscillation of the magnetron 11 is stopped in the heating operation, the control is performed. Since the apparatus 100 oscillates the magnetron 11 and restarts the heating operation, the cooking can be completed even if the frequency of the power supply voltage fluctuates greatly and the magnetron 11 is stopped.

[Second Embodiment]
FIG. 6 shows a schematic configuration of a microwave oven control apparatus 1100 according to the second embodiment of the present invention. The microwave oven of the second embodiment has the same configuration as the microwave oven of the first embodiment except for the oscillation stop time measuring unit 24 and the control device 1100, and FIGS. 1 and 2 are used.

  The control device 1100 includes a microcomputer and an input / output circuit, and includes a timer 100a for measuring the heating time, a frequency determination unit 100b for determining the frequency of the power supply voltage detected by the frequency detection unit 23, and an oscillation. A heating time correction unit 100c that corrects the remaining heating time based on the oscillation stop time Td measured by the stop time measurement unit 24 is provided.

  The oscillation stop time measuring unit 24 measures the oscillation stop time Td when the frequency of the power supply voltage deviates from a predetermined frequency range (680 Hz ± 10%) during the heating operation to stop the oscillation of the magnetron 11. As the oscillation stop time measuring unit, the timer 100a of the control device 1100 may be used, or a timer provided separately in the control device may be used.

  The control device 100 includes a liquid crystal display unit 7, a rotating antenna motor 13, and a magnetron 11 based on signals from the operation unit 3, the door open / close detection switch 20, the frequency detection unit 23, and the oscillation stop time measurement unit 24. The magnetron high-voltage transformer 21 for applying a high voltage to the magnetron, the magnetron heater transformer 22 for applying a voltage to the filament 11a of the magnetron 11, the cooling fan 15, and a power shut-off unit (not shown) are controlled.

  According to the microwave oven of the second embodiment, after the oscillation of the magnetron 11 is stopped in the heating operation, the frequency determination unit 100b determines that the frequency of the power supply voltage is within the frequency range (680 Hz ± 10%) and is heated. When the operation is resumed, the remaining heating time of the heating operation is corrected by the heating time correction unit 100c based on the oscillation stop time Td of the magnetron 11 measured by the oscillation stop time measuring unit 24. At this time, the heating time correction unit 100c increases the remaining heating time because the object to be heated cools as the oscillation stop time increases. The correction of the heating time by the heating time correction unit 100c may be performed not only based on the oscillation stop time but also based on conditions such as a microwave load capacity and the oscillation stop time.

  As a result, even if the microwave oscillation stops during the heating operation due to the frequency fluctuation of the power supply voltage, the remaining heating can be performed with the heating time corrected according to the oscillation stop time Td, and the heating operation is performed without degrading the heating quality. Can be completed.

  Further, by determining the preheating time t3 based on the oscillation stop time Td measured by the oscillation stop time measuring unit 24, an optimal preheating time corresponding to the degree of temperature decrease of the filament 11a is set. Thereby, the temperature of the filament 11a when the magnetron 11 is again oscillated from the oscillation stopped state can be set to the optimum temperature.

  Moreover, the microwave oven of the said 2nd Embodiment has an effect similar to the microwave oven of 1st Embodiment.

[Third Embodiment]
FIG. 7 shows a schematic configuration of a control apparatus 2100 for a microwave oven according to a third embodiment of the present invention. The microwave oven of the third embodiment has the same configuration as that of the microwave oven of the second embodiment except for the control device 2100, and FIGS.

  The control device 2100 includes a microcomputer and an input / output circuit, and includes a timer 100a for measuring the heating time, a frequency determination unit 100b for determining the frequency of the power supply voltage detected by the frequency detection unit 23, and an oscillation. A heating time correction unit 100c that corrects the remaining heating time based on the oscillation stop time Td measured by the stop time measurement unit 24, and a load capacity determination unit 100d that determines the load capacity of the microwave.

  The load capacity determination unit 100d determines whether or not the microwave load capacity set by the user operating the operation unit 3 is equal to or less than a predetermined load capacity determination value.

  Note that the load capacity of the microwave is not limited to what is input by the user.For example, a load capacity detection unit that optically or mechanically detects the size of the object to be heated (or the container including the object to be heated) is used. Or by using a load capacity detector that detects the weight of the object to be heated by a weight sensor provided near the bottom tray, and the load capacity of the microwave from the size of the container containing the object to be heated and the weight of the object to be heated May be estimated.

  In the microwave oven configured as described above, when the load capacity determination unit 100d determines that the microwave load capacity is equal to or less than a predetermined load capacity determination value at the start of cooking, the control device 2100 transmits microwaves from the magnetron 11. The first oscillation mode is generated periodically. As a result, when the microwave oven is mounted on an aircraft, interference between the microwave and the in-flight wireless LAN (local area network) can be prevented.

  Moreover, in the said microwave oven, the amount of unnecessary radiation of the microwave which leaks outside from the cabinet 2 reduces, so that the load capacity of a microwave becomes large. Therefore, when it is determined that the microwave load capacity detected by the load capacity determination unit 100d at the start of cooking is larger than the load capacity determination value, the controller 2100 continuously generates microwaves from the magnetron 11. The second oscillation mode is set. As a result, even an object to be heated having a high load capacity that requires a high output can be heated without affecting the wireless LAN in the apparatus. Therefore, in a heating operation such as rice cooking that requires a high output microwave, it is possible to continuously oscillate the microwave and heat it with the maximum output, thereby shortening the cooking time and improving the cooking finish.

  Moreover, the microwave oven of the said 3rd Embodiment has an effect similar to the microwave oven of 2nd Embodiment.

[Fourth Embodiment]
FIG. 8 shows a schematic configuration of a control apparatus 3100 for a microwave oven according to a fourth embodiment of the present invention. The microwave oven of the fourth embodiment has the same configuration as the microwave oven of the third embodiment except for the control device 3100, and FIGS.

  The control device 3100 includes a microcomputer and an input / output circuit, and includes a timer 100a for measuring the heating time, a frequency determination unit 100b for determining the frequency of the power supply voltage detected by the frequency detection unit 23, and an oscillation. A heating time correction unit 100c that corrects the remaining heating time based on the oscillation stop time Td measured by the stop time measurement unit 24, a load capacity determination unit 100d that determines the load capacity of the microwave, and the oscillation operation of the magnetron 11 The consumption time calculation unit 100e for calculating the consumption time indicating the degree of consumption by the wear time, the consumption time integration unit 100f for integrating the consumption time of the magnetron 11 calculated by the consumption time calculation unit 100e, and the consumption time integration unit 100f are integrated. In addition, a wear time determination unit 100g for determining an integrated value of the wear time of the magnetron 11 is provided.

  The consumption time calculation unit 100e generates a magnetron based on a heating time T1 that is a cooking time and a single oscillation time T ′ of microwaves periodically generated in the heating operation (corresponding to t1 in FIG. 4). The consumption time indicating the degree of consumption due to the 11 oscillation operations is calculated.

  Here, the heating time T1, which is the cooking time, is set by the operation unit 3 at the start of the heating operation.

When the period of the microwave generated periodically from the magnetron 11 is Tc (3 seconds in this embodiment) and the duty ratio is D, the microwave oscillation time T ′ is
T ′ = Tc × D
It is obtained by. In this embodiment, the duty ratio D is set to 2.5 seconds / 3.0 seconds. However, the duty ratio D can be changed according to the setting condition of the microwave output.

In addition, the number of oscillations n of the microwave in the heating time T1, which is one cooking time, is
n = T1 / Tc
In the heating time T1, which is the cooking time, the actual total oscillation time Tw of the microwave is
Tw = T ′ × n
It becomes. At this time, the consumption time Ts indicating the degree of consumption by the oscillation operation of the magnetron 11 calculated by the consumption time calculation unit 100e is:
Ts = T1 + c × Tw (c is a coefficient)
= T1 + c × T ′ × n
It is said. Here, the coefficient c is set according to the duty ratio D of the microwave.

  When the magnetron 11 operates continuously, the consumption time Ts of the magnetron 11 calculated by the consumption time calculation unit 100e is the heating time T1 that is the cooking time.

  In the microwave oven having the above-described configuration, the consumption time Ts of the magnetron 11 calculated by the consumption time calculation unit 100e is not the actual time of the oscillation operation of the magnetron 11 when the microwave is periodically oscillated. Since the life of the magnetron 11 becomes shorter as the duty ratio when turning on and off periodically becomes shorter than during continuous oscillation, the consumption time calculation unit is longer than the consumption time (= heating time T1) during continuous oscillation operation of the magnetron 11. The consumption time Ts calculated by 100e becomes longer.

  In this way, the consumption time Ts of the magnetron 11 calculated by the consumption time calculation unit 100e is integrated by the consumption time integration unit 100f. When the wear time determination unit 100g determines that the accumulated value of the wear time of the magnetron 11 accumulated by the wear time accumulation unit 100f exceeds a preset wear time determination value (1250 hours in this embodiment), It is notified to the user by displaying on the liquid crystal display unit 7 as an example of a notification unit that it is time to replace the magnetron 11.

  The notification unit is not limited to the liquid crystal display unit 7, and may notify the user of the replacement time of the magnetron by voice or a combination of the display unit and the like,

  As a result, when cooking is performed by periodically turning on and off the microwave from the magnetron 11, it is possible to accurately notify the replacement time of the magnetron 11 even if the cooking is performed with different duty ratios.

  Moreover, the microwave oven of the said 4th Embodiment has an effect similar to the microwave oven of 3rd Embodiment.

  In the first to fourth embodiments, the microwave oven mounted on the aircraft has been described. However, the present invention is not limited to this and can be applied to microwave ovens used in various environments.

  Although specific embodiments of the present invention have been described, the present invention is not limited to the first to fourth embodiments, and various modifications can be made within the scope of the present invention.

  That is, the present invention and the embodiment are summarized as follows.

The microwave oven of this invention is
A magnetron 11 that generates a microwave by a power supply voltage supplied from the outside;
A frequency detector 23 for detecting the frequency of the power supply voltage;
A frequency determination unit 100b for determining whether or not the frequency of the power supply voltage detected by the frequency detection unit 23 is within a preset frequency range;
Control devices 100, 1100, 2100, 3100 for controlling the magnetron 11 based on the determination result of the frequency determination unit 100b,
The controller 100, 1100, 2100, 3100 is a frequency range in which the frequency determination unit 100b sets the frequency of the power supply voltage in advance in the heating operation in which the object to be heated is heated by the microwave generated from the magnetron 11. If it is determined that it is not within, the oscillation of the magnetron 11 is stopped.

  According to the above configuration, in the heating operation in which the object to be heated is heated by the microwave generated from the magnetron 11, when the frequency determination unit 100b determines that the frequency of the power supply voltage is not within the preset frequency range, the control device Since the oscillation of the magnetron 11 is stopped by 100, 1100, 2100, 3100, the abnormal operation of the magnetron 11 can be prevented even if the frequency of the power supply voltage fluctuates greatly in the microwave heating operation. If the frequency determination unit 100b determines that the frequency of the power supply voltage is within a preset frequency range after the oscillation of the magnetron 11 is stopped, the magnetron 11 can be normally re-oscillated.

In one embodiment of the microwave oven,
When the control device 100, 1100, 2100, 3100 stops the oscillation of the magnetron 11 in the heating operation, and the frequency determination unit 100b determines that the frequency of the power supply voltage is within the frequency range, the magnetron 11 is oscillated and the heating operation is restarted.

  According to the above embodiment, when the frequency determination unit 100b determines that the frequency of the power supply voltage is within the frequency range after the oscillation of the magnetron 11 is stopped in the heating operation, the controller 100, 1100, 2100, 3100 causes the magnetron to 11 is oscillated and the heating operation is resumed, so that the cooking can be completed even if the frequency of the power supply voltage greatly fluctuates and the magnetron 11 is once stopped.

In one embodiment of the microwave oven,
An oscillation stop time measuring unit 24 for measuring the oscillation stop time of the magnetron 11 in the heating operation;
After the oscillation of the magnetron 11 is stopped in the heating operation, when the frequency determination unit 100b determines that the frequency of the power supply voltage is within the frequency range and restarts the heating operation, the oscillation stop time measurement unit And a heating time correction unit 100c for correcting the remaining heating time of the heating operation based on the oscillation stop time of the magnetron 11 measured by 24.

  According to the above-described embodiment, when the frequency determination unit 100b determines that the frequency of the power supply voltage is within the frequency range after restarting the magnetron 11 in the heating operation and restarts the heating operation, the oscillation stop time measuring unit. Since the remaining heating time of the heating operation is corrected by the heating time correction unit 100c based on the oscillation stop time of the magnetron 11 measured by 24, even if the microwave oscillation stops during the heating operation, the oscillation stop time The remaining heating can be performed with the heating time corrected according to the above. For example, the longer the oscillation stop time, the more the object to be heated cools. Therefore, by increasing the remaining heating time, the heating operation can be completed without degrading the heating quality.

In one embodiment of the microwave oven,
A load capacity determination unit 100d for determining the load capacity of the microwave;
When the load capacity determination unit 100d determines that the load capacity of the microwave is equal to or less than a preset load capacity determination value, the control devices 2100 and 3100 periodically generate microwaves from the magnetron 11 On the other hand, when it is determined that the load capacity of the microwave detected by the load capacity determination unit 100d is larger than the load capacity determination value, the microwave is continuously transmitted from the magnetron 11. The second oscillation mode to be generated is set.

  According to the above-described embodiment, when the load capacity determination unit 100d determines that the microwave load capacity is equal to or less than a preset load capacity determination value, the controller 2100, 3100 causes the magnetron 11 to transmit a period of microwaves. By setting the first oscillation mode to be generated automatically, when this microwave oven is mounted on an aircraft, interference between the microwave and the wireless LAN (local area network) in the aircraft can be prevented.

  Also, as the microwave load capacity increases, the amount of unnecessary microwave radiation that leaks from the microwave oven body decreases, so the microwave load capacity detected by the load capacity determination unit 100d is greater than the load capacity determination value. When it is determined that the frequency is large, the control devices 2100 and 3100 set the second oscillation mode in which microwaves are continuously generated from the magnetron 11. By doing so, it becomes possible to heat even an object to be heated having a high load capacity that requires high output without affecting the wireless LAN in the apparatus.

In one embodiment of the microwave oven,
Based on the heating time for heating the object to be heated and the duty ratio when the microwave from the magnetron 11 is periodically turned on / off, the consumption time indicating the degree of consumption due to the oscillation operation of the magnetron 11 for each heating operation. Consumption time calculation unit 100e for calculating
A consumption time integration unit 100f that integrates the consumption time of the magnetron 11 calculated by the consumption time calculation unit 100e;
A depletion time determination unit 100g for determining whether or not the accumulated value of the depletion time of the magnetron 11 accumulated by the depletion time accumulation unit 100f exceeds a preset depletion time determination value;
When the depletion time determination unit 100g determines that the integrated value of the depletion time of the magnetron 11 has exceeded the depletion time determination value, the depletion time determination unit 100g includes a notification unit 7 for notifying that it is time to replace the magnetron 11.

  According to the above embodiment, the degree of wear due to the oscillation operation of the magnetron 11 is determined for each heating operation based on the heating time for heating the object to be heated and the duty ratio when the microwave from the magnetron 11 is periodically turned on / off. The consumption time represented is calculated by the consumption time calculation unit 100e. Here, the consumption time of the magnetron 11 calculated by the consumption time calculation unit 100e is not the actual time of the oscillation operation of the magnetron 11 when the microwave is periodically oscillated, and the microwave is periodically turned on and off. As the duty ratio becomes smaller, the lifetime becomes shorter than during continuous oscillation, so the consumption time calculated by the consumption time calculation unit 100e becomes longer than the actual time of continuous oscillation operation of the magnetron 11. In this way, the consumption time of the magnetron 11 calculated by the consumption time calculation unit 100e is integrated by the consumption time integration unit 100f, and the integrated value of the accumulated consumption time of the magnetron 11 is determined as a predetermined consumption time determination. When the consumption time determination unit 100g determines that the value has been exceeded, the notification unit notifies that it is time to replace the magnetron 11. As a result, when cooking is performed by periodically turning on and off the microwave from the magnetron 11, it is possible to accurately notify the replacement time of the magnetron 11 even if the cooking is performed with different duty ratios.

DESCRIPTION OF SYMBOLS 1 ... Microwave oven 2 ... Cabinet 3 ... Operation part 4 ... Door 5 ... Handle 6 ... Heat-resistant glass window 7 ... Liquid crystal display part 10 ... Heating chamber 11 ... Magnetron 11a ... Filament 12 ... Waveguide 13 ... Motor for rotary antenna DESCRIPTION OF SYMBOLS 14 ... Rotating antenna 15 ... Cooling fan 16 ... Outside air inflow duct 17 ... Outside air flow inlet 20 ... Door opening / closing detection switch 21 ... Magnetron high pressure transformer 22 ... Magnetron heater transformer 23 ... Frequency detection part 24 ... Oscillation stop time measurement part 27 ... Dust receiver 30 ... Bottom tray 100,1100,2100,3100 ... Control device 100a ... Timer 100b ... Frequency determination unit 100c ... Heating time correction unit 100d ... Load capacity determination unit 100e ... Consumption time calculation unit 100f ... Consumption time integration unit 100g ... Depletion time judgment unit

Claims (5)

A microwave oven mounted on an aircraft and supplied with a power supply voltage whose frequency varies,
A magnetron that generates microwaves by the power supply voltage supplied from the aircraft ;
A frequency detector for detecting the frequency of the power supply voltage;
A frequency determination unit that determines whether or not the frequency of the power supply voltage detected by the frequency detection unit is within a preset frequency range;
A controller for controlling the magnetron based on the determination result of the frequency determination unit,
When the frequency determination unit determines that the frequency of the power supply voltage is not within a preset frequency range during the heating operation in which the object to be heated is heated by the microwave generated from the magnetron, the magnetron Microwave oven characterized by stopping the oscillation of. The microwave oven according to claim 1, wherein
The control device oscillates the magnetron and resumes the heating operation when the frequency determination unit determines that the frequency of the power supply voltage is within the frequency range after stopping the oscillation of the magnetron in the heating operation. A microwave oven characterized by that. The microwave oven according to claim 2, wherein
An oscillation stop time measuring unit that measures the oscillation stop time of the magnetron in the heating operation;
After the oscillation of the magnetron is stopped in the heating operation, when the frequency determination unit determines that the frequency of the power supply voltage is within the frequency range and restarts the heating operation, the measurement is performed by the oscillation stop time measurement unit. A microwave oven comprising: a heating time correction unit that corrects the remaining heating time of the heating operation based on the oscillation stop time of the magnetron. In the microwave oven according to any one of claims 1 to 3,
A load capacity determination unit for determining the load capacity of the microwave;
When the load capacity determination unit determines that the load capacity of the microwave is equal to or less than a preset load capacity determination value, the control device causes a first oscillation mode to periodically generate a microwave from the magnetron. On the other hand, when it is determined that the load capacity of the microwave detected by the load capacity determination unit is larger than the load capacity determination value, the second oscillation mode for continuously generating the microwave from the magnetron; A microwave oven characterized by that. In the microwave oven according to any one of claims 1 to 4,
Based on the heating time for heating the object to be heated and the duty ratio when the microwave from the magnetron is periodically turned on / off, the consumption time representing the degree of consumption due to the oscillation operation of the magnetron is calculated for each heating operation. A consumption time calculation unit to perform,
A consumption time integration unit for integrating the consumption time of the magnetron calculated by the consumption time calculation unit;
A depletion time determination unit that determines whether or not the accumulated value of the depletion time of the magnetron accumulated by the depletion time accumulation unit exceeds a predetermined depletion time determination value;
An electronic device comprising: an informing unit for informing that it is time to replace the magnetron when the depletion time determination unit determines that the accumulated value of the depletion time of the magnetron exceeds the depletion time determination value range.

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