KR100443816B1 - Microwave oven - Google Patents

Abstract

The present invention relates to a microwave oven, comprising: connecting a rectifier circuit (2) for full-wave rectification of this AC power to a commercial AC power supply (1), and connecting an inverter circuit (3) between output terminals of the rectifier circuit (2). The magnetron 6 is connected to the inverter circuit 3 via the high frequency transformer 4 and the high voltage rectification circuit 5, and the zero cross detection circuit 9 is connected to the commercial AC power supply 1 to detect the zero cross. The circuit 9 outputs a pulse signal of the "H" level to the counter circuit 10 when detecting the zero cross of the commercial AC power supply 1, and the counter circuit 10 counts the pulse signal to produce 18 pulses L / 2. The signal of "H" and "L" is output to the stop circuit 7a of the inverter control circuit 7 by the ratio of the pulse H, and the ISM band propagates even if the magnetron is operated in both phases of a commercial AC power supply. It is characterized by suppressing as much as possible to interfere with the communication using.

Description

Microwave oven {MICROWAVE OVEN}

The present invention relates to a microwave oven having a configuration for controlling the driving of a microwave generator through an inverter circuit.

In recent years, mobile devices, wireless devices, peripheral devices, mobile devices, home appliances, and the like have been wirelessly connected at home. In such a home network, a communication technology using relatively weak radio waves with small power consumption is used because of a short communication distance.

One of the communication technologies used in such a home network is a wireless network such as Bluetooth (registered trademark of " Bluetooth ^TM " Blue pitcher communicates using 2.4GHz radio waves, one of the industrial, chemical and medical frequency bands (ISM bands) assigned internationally by the Radio Law. While the ISM band is a relatively free and readily available frequency band, there are many radio wave disturbances.

For example, microwave ovens are configured to dielectrically heat food by microwave at 2450 MHz, one of the ISM bands. In this case, the amount of radio wave leakage in the microwave is regulated by the radio wave method in order to prevent the radio communication or the TV from receiving a disturbance or adversely affecting the human body due to radio waves leaking from the microwave main body. Therefore, the amount of radio wave leakage from the microwave oven main body is suppressed below a regulated value.

However, as described above, since Bluetooth is a communication technology using a weak radio wave, a small amount of radio waves leaking from the microwave oven body by the distance between the microwave oven and Bluetooth or the output of the magnetron becomes a disturbing wave.

In particular, recently, a power source having an inverter circuit for boosting the voltage after converting a commercial frequency to 20 to 30 kHz as a magnetron driving power source has been used. In this case, the magnetron is operated in both phases of the commercial AC power supply. For this reason, microwaves are almost always emitted when the magnetron is driven, which is a great obstacle for communication using weak radio waves.

For example, Fig. 7 shows the relationship between the distance between the microwave oven and Bluetooth and the communication capability of the above configuration. In FIG. 7, the solid line A shows the case where the magnetron output is 500W, and the solid line B shows the case where the magnetron output is 800W. As shown in Fig. 7, the communication capacity when the distance between the microwave oven and the Bluetooth is 0.5m is 50KB / s when the heating output is 500W, and about 0KB / s when the 800W is used. In addition, even when the heating output is 500W, when the distance between the microwave oven and the Bluetooth is 0.25m, the communication capacity is about 0KB / s.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a microwave oven capable of maximally suppressing communication interference using radio waves of the ISM band even if the magnetron is operated in both phases of a commercial AC power supply. Is in.

1 is an electrical circuit diagram showing a first embodiment of the present invention and showing a schematic configuration of a microwave oven,

2 is a waveform diagram of each part, (a) is an input voltage of a commercial AC power supply, (b) is an output signal of a zero cross detection circuit, (c) is an output signal of a counter circuit, and (d) is a magnetron. Operating current,

3 is a diagram showing a relationship between heating output and communication capability;

Figure 4 corresponds to Figure 1 showing a second embodiment of the present invention,

5 is a view corresponding to FIG. 1 showing a third embodiment of the present invention;

6 is a waveform diagram of each part, (a) shows a rectified output voltage waveform of the rectifier circuit, (b) shows a voltage waveform given to the inverting input terminal and the non-inverting input terminal of the comparator, and (c) the output pulse of the comparator. Waveform, (d) shows the operating current waveform of the magnetron and

FIG. 7 is a diagram illustrating a problem to be solved by the present invention and illustrates a relationship between a distance between a microwave oven and Bluetooth and a communication capability.

* Explanation of symbols for the main parts of the drawings

1: commercial AC power supply 2: rectifier circuit

3: inverter circuit 6: magnetron (microwave generator)

7: Inverter control circuit (control means) 8: Range control circuit (control means)

11: Bluetooth (wireless communication) 21: Bluetooth detection circuit (communication detection means)

The invention of claim 1 is a rectifier circuit for full-wave rectifying AC power of a commercial AC power supply, an inverter circuit connected between an output terminal of the rectifier circuit, and driven by the inverter circuit for heating and cooking to generate microwaves. A microwave oven comprising a microwave generating device and a control means for controlling the driving of the microwave generating device through the inverter circuit, and an intermittent stop mode for intermittently stopping the microwave generating device during heating and cooking is provided. It is done.

According to the above configuration, even when heated and cooked, a period during which microwaves do not occur occurs, and this period can be set as a time slot for wireless communication using a 2.4GHz ISM band such as Bluetooth.

In this case, a communication detecting means for detecting wireless communication using an ISM band of 2.4 GHz may be provided, and the control means may be configured to execute an intermittent stop mode when wireless communication is detected by the communication detecting means (claims). 2) invention. According to the above configuration, the intermittent stop mode is executed only when there is a concern that the microwaves may become a disturbing wave of communication, so that the microwave generator does not need to be stopped unnecessarily.

It is also preferable that the control means is configured to execute the intermittent stop mode when the output of the microwave generator is greater than or equal to a predetermined value (invention of claim 3). The effect of microwaves from the microwave generator on wireless communication is almost proportional to the output of the microwave generator. Thus, by executing the intermittent stop mode only when the output of the microwave generator is equal to or greater than a predetermined value affecting wireless communication, as described above, the microwave generator does not need to be stopped unnecessarily.

The stop period of the microwave generator in the intermittent stop mode is preferably set to a short time in which a heat run is unnecessary when the microwave generator is restarted (invention of claim 4). According to the above configuration, since the microwave generator can be restarted immediately after stopping, it is possible to suppress the extension of the heating time as much as possible by stopping the microwave generator.

Further, the stop period of the microwave generator in the intermittent stop mode may be set to an integer multiple of the period of the commercial AC power supply (invention of claim 5), or the period for stopping the microwave generator may be synchronized with the period of the commercial AC power supply (claim 6). Invention). According to the above configuration, the stop period of the microwave generator can be set in a relatively simple configuration.

Further, an instruction means for instructing execution of the intermittent stop mode may be provided (invention of claim 7). According to the above configuration, it is convenient to use whether or not to execute the intermittent stop mode according to the installation environment of the microwave oven.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. First, FIG. 1 shows the configuration of a microwave oven according to the present embodiment, and a commercial AC power supply 1 is connected with a rectifying circuit 2 for full-wave rectifying the AC power. An inverter circuit 3 is connected between the output terminals of the rectifier circuit 2. Although the detailed illustration is abbreviate | omitted, the said inverter circuit 3 is comprised with the resonant circuit which consists of the primary side transformer 4a and the resonant capacitor of the high frequency transformer 4 as a resonant coil, switching elements, such as IGBT, and a freewheel diode.

In addition, a magnetron 6 as a microwave generator is connected to the secondary side transformer 4b of the high frequency transformer 4 via a high voltage rectifier circuit 5. Although not shown, the high voltage rectifying circuit 5 has a capacitor and a diode.

The switching element of the inverter circuit 3 is configured to be controlled on and off by the inverter control circuit 7. The command signal from the range control circuit 8 is input to the inverter control circuit 7. The range control circuit 8 includes a microcomputer and the like, and is configured to receive input signals from a cooking menu (heating intensity) setting switch, a cooking time setting switch, a start switch (not shown), and the like. .

Therefore, when the inverter control circuit receives a command from the range control circuit 8, the inverter control circuit 3 operates the inverter circuit 3 by determining the on-period of the switching element in accordance with the input heating intensity. The commercial AC power is supplied to the magnetron 6 through the rectifier circuit 2, the inverter circuit 3, and the high voltage rectifier circuit 5.

On the other hand, a zero cross detection circuit 9 is connected to the commercial AC power supply 1, and the output S1 of the zero cross detection circuit 9 is provided to the counter circuit 10. As shown in Figs. 2A and 2B, the zero cross detection circuit 9 outputs a pulse signal of the "H" level when the zero cross of the commercial AC waveform 1 is detected.

In addition, the output S2 of the counter circuit 10 is configured to be provided to the stop circuit 7a of the inverter control circuit 7. As shown in FIG. 2C, when the number of pulses from the zero cross detection circuit 9 reaches 18, the output S2 of the counter circuit 10 is switched to the "H" level and the count value is reset. Then, when the number of pulses is 2, the signal is switched to the "L" level and the count value is reset.

When the "H" level signal is applied to the stop circuit 7a, the inverter control circuit 7 is configured to turn off the switching element and stop the supply of the voltage to the magnetron 6. When the "L" level signal is applied to the stop circuit 7a, the inverter control circuit 7 controls the inverter circuit 3 based on the command from the range control circuit 8 to operate the magnetron 6. Drive. That is, in this embodiment, the inverter control circuit 7 and the range control circuit 8 function as control means.

Therefore, during heating and cooking, the inverter control circuit 3 executes the intermittent stop mode in which the operation of driving the magnetron 6 and the operation of stopping the magnetron 6 are alternately repeated. In this embodiment, the driving period for driving the magnetron 6 is set to nine cycles of the commercial AC power supply 1, and the stopping period for stopping the magnetron 6 is for one cycle of the commercial AC power supply 1. It is set to (16 to 20 ms). If the stop period of the magnetron 6 is about 40 ms or less, there is no need for a heat run when the magnetron 6 is driven again, and it can be operated immediately.

As a result, the operating current waveform of the magnetron 6 is as shown in Fig. 2D. In addition, there is a period (about 1 to 2 ms) in which the operating current of the magnetron 6 becomes zero even in the driving period. This is because the magnetron 6 does not operate in the valley portion of the pulse current output voltage of the rectifier circuit 2.

Here, FIG. 3 shows the results of experiments carried out by the present inventor on the relationship between the heating output of the microwave oven and the communication capability with the Bluetooth. This experiment was carried out by installing the microwave oven according to the present embodiment and the microwave oven (a configuration in which the magnetron is always operated at the time of heating cooking) according to the present embodiment, respectively, 0.5m away from Bluetooth. 3, the broken line shows the experimental result of the microwave oven which concerns on a present Example, and the solid line shows the experimental result of the microwave oven of a conventional structure. As shown in Fig. 3, the microwave side of this embodiment has a smaller influence on the communication by Bluetooth than the microwave oven of the conventional configuration.

The communication method of Bluetooth is a frequency hopping spread spectrum method (hereinafter referred to as frequency hopping) in which 79 communication spectrums existing in 1 MHz units in the 2402 to 2480 MHz band are randomly changed every 625 Hz, that is, 1600 times per second. Is adopted. In other words, the minimum communication unit (time slot) of Bluetooth is 625 kHz, which is 1.25 ms (625 kHz x 2) in transmission and reception. Therefore, if there is a time slot of 1.25 ms 2 = 2.5 ms, transmission and reception can be reliably performed.

In contrast, in the present embodiment, the magnetron 6 is intermittently stopped during heating and cooking, and the stop period is set to 16 to 20 ms. Therefore, by using the stop period of the magnetron 6 as a time slot, communication of Bluetooth can be maintained even when heated.

In this embodiment, the stop period of the magnetron 6 is configured to be one cycle of the commercial AC power supply 1 and is synchronized with the period of the commercial AC power supply 1. For this reason, the intermittent stop mode can be configured relatively simply. In addition, since the length of the stop period with respect to the drive period of the magnetron 6 is set to 1/9, the fall of the heating efficiency by providing the stop period can be suppressed as much as possible.

In addition, as shown in Fig. 3, when the heating output is smaller than 500W, even a microwave oven of the conventional configuration can sufficiently maintain communication of Bluetooth. Therefore, in the present embodiment, the range control circuit 8 executes the intermittent stop mode via the inverter control circuit 7 when the output of the magnetron 6 is set to 500 W or more, and intermittently when the output is smaller than 500 W. It may be configured to execute the stop mode. According to such a structure, when the radio wave leaking from the microwave main body is low output which does not become a disturbing wave of communication, it is not necessary to stop the magnetron 6 unnecessarily.

4 shows a second embodiment of the present invention, and describes a difference from the first embodiment. In addition, the same code | symbol is attached | subjected to the part same as 1st Example. This second embodiment is equipped with a Bluetooth 11, is configured to enable two-way communication with a mobile device (not shown) and executes the intermittent stop mode when it is detected that communication by the Bluetooth 11 is being performed. It is characteristic in that it is comprised so that it may be.

The Bluetooth 11 includes a transmission / reception switching circuit 13 having a communication antenna 12, a reception circuit 14, a transmission circuit 15, a transmission / reception control circuit 16, a reception signal processing circuit 17, and a microwave generation. The timing circuit 18, the microwave generation circuit 19, and the Bluetooth control circuit 20 are comprised. In addition, the transmission and reception control circuit 16 is connected with a Bluetooth detection circuit 21 serving as communication detection means. The output S3 of the Bluetooth detection circuit 21 is at the "H" level when it detects that communication by the Bluetooth 11 is being made.

On the other hand, the output S2 of the counter circuit 10 is applied to one input terminal of the AND circuit 22, and the output S3 of the Bluetooth detection circuit 21 is the other of the AND circuit 22. It is configured to be assigned to the input terminal. The stop circuit 7a is connected to the output terminal of the AND circuit 22. Therefore, when the output S3 of the Bluetooth detection circuit 21 and the output S2 of the counter circuit 10 are both at the "H" level, the output of the AND circuit 22 is at the "H" level. That is, in this embodiment, when the communication by the Bluetooth 11 is being performed, the inverter control circuit 7 alternately performs the operation of controlling the inverter circuit 3 to drive the magnetron 6 and the operation of stopping it. Invoke Intermittent Stop Mode.

According to this embodiment of such a configuration, when the communication by the Bluetooth 11 is not performed, and when the microwaves generated by the magnetron 6 are not likely to interfere with the communication, the magnetron 6 does not need to stop unnecessarily. good.

In addition, the structure of that excepting the above is the same as that of the first embodiment, and therefore, the same operation and effect as in the first embodiment can be obtained in this embodiment as well.

5 and 6 show a third embodiment of the present invention and explain what is different from the first embodiment. In addition, the same code | symbol is attached | subjected to the part same as 1st Example. This third embodiment is characterized in that a stop period is provided in the valley portion of the pulse current output voltage of the rectifier circuit 2. That is, as shown in Fig. 5, the inverting input terminal of the comparator 32 is connected to the constant output terminal of the rectifier circuit 2 through the resistor 31, and the output of the comparator 32 (S4). ) Is provided to the stop circuit 7a. In addition, resistors 33 and 34 and a capacitor 35 are connected between the constant output terminal of the rectifier circuit 2 and the resistor 31, and the voltage Vc of the capacitor 35 is connected to the comparator ( 32) to be provided to the non-inverting input terminal.

As shown in FIG. 6B, when the input voltage Vb of the inverting input terminal of the comparator 32 exceeds the input voltage Vc of the non-inverting input terminal, the output S4 of the comparator 32 is output. Becomes "L" level, and becomes "H" level when it becomes below input voltage Vc. The inverter control circuit 7 is configured to turn off the switching element of the inverter circuit 3 when the output S4 is "H". As a result, an operating current flows in the magnetron 6 at the timing shown in Fig. 6D, and a stop period occurs in the valley portion of the pulse current output voltage of the rectifier circuit 2. In this case, each stop period is set to be about 2.5 ms.

Even in such a configuration, since the magnetron 6 is intermittently stopped at the time of heating and cooking, communication by Bluetooth can be maintained by making this stop period into the time slot.

In addition, this invention is not limited to the above-mentioned embodiment, For example, the following deformation | transformation and expansion are possible.

In the first and third embodiments, the magnetron is always stopped intermittently during heating and cooking. However, an instruction means for instructing execution of the intermittent stop mode, for example, a Bluetooth-compatible switch is provided on the operation panel. The magnetron may be intermittently stopped when pressed.

According to such a configuration, the intermittent stop mode can be set only when the communication by the Bluetooth is performed in the vicinity of the microwave oven, so that the magnetron is not stopped unnecessarily.

In the second and third embodiments, the intermittent stop mode may be executed only when the heating output is 500 W or more.

As apparent from the above description, since the microwave oven of the present invention has been provided with an intermittent stop mode for intermittently stopping the microwave generator during heating and cooking, a period in which microwaves do not occur even during heating and cooking occurs. Communication can be maintained by setting the time slot for wireless communication using the 2.4GHz ISM band such as Bluetooth.

Claims (7)

Rectification circuit for full-wave rectifying AC power of commercial AC power supply, An inverter circuit connected between output terminals of the rectifier circuit, A microwave generator driven by the inverter circuit for heating and generating microwaves; In a microwave oven having control means for intermittently stopping the microwave generating device through the inverter circuit, And the intermittent stop period of the microwave generator by the control means is set in a valley portion of the pulse current output voltage of the rectifier circuit. The method of claim 1, Communication detecting means for detecting wireless communication using an ISM band of 2.4 GHz, And the control means executes the intermittent stop mode when wireless communication is detected by the communication detecting means. The method of claim 1, And the control means is configured to execute the intermittent stop mode when the output of the microwave generator is greater than or equal to a predetermined value. The method according to any one of claims 1 to 3, The microwave oven is characterized in that the stop period of the microwave generator in the intermittent stop mode is set to a short time in which a heat run is unnecessary when the microwave generator is restarted. The method of claim 1, A microwave oven characterized in that the stopping period of the microwave generator in the intermittent stop mode is set to an integer multiple of the period of a commercial AC power supply. The method of claim 1, A microwave oven in which the microwave generator is stopped in the intermittent stop mode is synchronized with a cycle of a commercial AC power supply. The method of claim 1, And an instruction means for instructing execution of the intermittent stop mode.