KR20120023448A - A cooking apparatus using microwave - Google Patents

Abstract

PURPOSE: A microwave cooking machine is provided to easily output a wide band of microwave, thereby evenly heating an object in a cavity. CONSTITUTION: A microwave cooking machine comprises a plate(634), a microwave transmission line, a first metal part(620), a second metal part, and a third metal part. The plate forms a cavity(134) into which microwave is transmitted through the microwave transmission line. The first metal part is connected to one end of the transmission line and extended in a specific direction to be parallel with the plate. The second metal part is connected to one end of the transmission line and extended in a specific direction. The third metal part is connected to one end of the first metal part and extended toward the plate.

Description

Cooking apparatus using microwaves {A cooking apparatus using microwave}

The present invention relates to a cooking appliance using a microwave, and more particularly, to a cooking appliance using a microwave having an antenna with improved efficiency.

In general, when a microwave oven uses a microwave oven to store food and seals the food, and then presses an operation button, a voltage is applied to the high pressure generator, and a commercial voltage applied to the high pressure generator is boosted to apply power to the magnetron that generates the microwave. The microwave generated by the magnetron is transmitted to the cavity through a wave guide or the like.

In this case, the cooking apparatus using the microwave is to heat the food with friction heat generated by irradiating the microwaves generated from the magnetron to the food and vibrating the molecules constituting the food 245 million times per second.

Cooking apparatus using such a microwave is a situation that is widely spread in the general home due to various advantages such as easy temperature control, saving of cooking time, ease of operation.

However, when cooking food using microwaves, there is a problem that a temperature difference occurs partially in the food without being uniformly heated by the surface deviation of the food. In addition, there is a problem that the temperature deviation during cooking also varies depending on the type of food stored in the cooking apparatus.

It is an object of the present invention to provide a cooking device using a microwave having an antenna with improved efficiency.

In order to solve the above problems, a cooking apparatus using a microwave according to an embodiment of the present invention, the plate forming the cavity, the microwave transmission line for transmitting the microwaves into the cavity, and connected to one end of the transmission line And a first metal part extending in one direction and parallel to the plate.

According to an embodiment of the present invention, by using a metal portion extending in parallel with the cavity to emit microwaves in the cavity, the operation efficiency can be improved.

In particular, it is possible to easily output a broadband microwave.

In addition, the antenna can be implemented in a small size, and impedance matching is facilitated.

On the other hand, while outputting a microwave of a wide band, by selectively outputting the microwave according to the calculation efficiency, uniform heating of the object in the cavity is performed.

1 is a partial perspective view of a cooking apparatus using a microwave according to an embodiment of the present invention.
2 is a cross-sectional view of the cooking appliance of FIG.
3 is a block diagram schematically illustrating an example of the inside of the cooking appliance of FIG. 1.
4 is a block diagram schematically illustrating another example of the inside of the cooking appliance of FIG. 1.
FIG. 5 is a circuit diagram schematically illustrating the interior of the solid state power oscillator of FIG. 4.
6 to 15 are diagrams illustrating various examples of an antenna of a cooking appliance using microwaves according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The suffixes "module" and "unit" for components used in the following description are merely given in consideration of ease of preparation of the present specification, and do not impart any particular meaning or role by themselves. Therefore, the "module" and "unit" may be used interchangeably.

1 is a partial perspective view of a cooking appliance using a microwave according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the cooking appliance of FIG.

Referring to the drawings, the cooking appliance 100 using the microwave according to an embodiment of the present invention, the door 106 is attached to the cooking window 104 in the front portion of the main body 102 is coupled to open and close. The operation panel 108 is coupled to one side of the front surface of the main body 102.

The door 106 opens and closes the cavity 134, and although not shown in the drawing, a door choke (not shown) for shielding microwaves may be disposed inside the door 106.

The operation panel 108 includes an operation unit 107 for operating the operation of the cooking appliance, and a display unit 105 for displaying the operation of the cooking appliance, and the like.

The inside of the main body 102 is provided with a cavity 134 having an accommodation space of a predetermined size so that the heating target 140, for example, food is accommodated and cooked by a microwave.

The cavity 134 may be formed in a tubular shape of an approximately rectangular parallelepiped having at least one surface joined to each other and having an open front surface.

For example, the cavity 134 may include an upper plate forming a ceiling, a rear plate forming a rear surface of the cavity 134, and a bottom forming a bottom surface of the cavity 134. It can be formed by a bottom plate (side plate) and the side plate (side plate) forming the side of the cavity (134). On the other hand, the door 106 may be disposed on the front of the cavity 134. In this case, a front plate that forms the front surface of the cavity 134 may be formed in an area other than the door 106.

The microwave generator 110 for generating a microwave is installed on the outer surface of the cavity 134, the microwave generated from the microwave generator 110 on the output side of the microwave generator 110, the cavity A microwave transmitter 112 is disposed for guiding the inside of 134.

The microwave generator 110 may include a magnetron, a solid state power amplifier (SSPA) using a semiconductor, or a solid state power oscillator (SSPO) using a semiconductor. have.

Solid-state power amplifiers (SSPAs) have the advantage of taking up less space than magnetrons. On the other hand, SSPOs do not have a voltage controlled oscillator (VCO) and a voltage controlled attenuator (VCA) as compared to a solid state power amplifier (SSPA), thereby providing space. It occupies less and has the advantage of simplifying the circuit configuration.

Meanwhile, the solid state power amplifier (SSPA) or the solid state power oscillator (SSPO) may include hybrid microwave integrated circuits including passive elements (capacitors and inductors) and active elements (transistors, etc.) for amplification; HMIC), or passive elements and active elements may be implemented as single high frequency integrated circuits (MMICs) implemented with one substrate.

The microwave generator 110 may implement a solid state power amplifier (SSPA) or a solid state power oscillator (SSPO) as one module, which may be referred to as a solid state power module (SSPM). .

Meanwhile, according to the exemplary embodiment of the present invention, the microwave generator 110 may generate and output a plurality of microwaves. The frequency range of such microwaves may be around 900 MHz to 2500 Hz. In particular, it may be within a predetermined range around 915 MHz or within a predetermined range around 2450 MHz.

The microwave transmitter 112 transmits the microwave generated and output by the microwave generator 110 to the cavity 134. The microwave transmitter 112 may include a transmission line. The transmission line may be implemented by a waveguide, a microstrip line, a coaxial cable, or the like. In order to send the generated microwaves to the microwave transmitter 112, as shown in the figure, the feeder 142 may be connected.

On the other hand, the microwave transmission unit 112, as shown in the drawing can be implemented in the form of opening with the opening 145 into the cavity 134.

On the other hand, the opening 145 may be formed in various forms such as a slot form. Through the opening 145, the microwaves are released to the cavity 134.

Meanwhile, although one opening 145 is illustrated above the cavity 134 in the drawing, the opening 145 may be disposed below or on the side of the cavity 134, and a plurality of openings may be disposed. It is also possible.

In addition, an antenna may be coupled to the end of the microwave transmitter 112. The antenna structure will be described later with reference to FIG. 6 and below.

Below the microwave generator 110, a power supply 114 for supplying power to the microwave generator 110 is provided.

The power supply unit 114 may include a high voltage transformer for supplying power to the microwave generator 110 by boosting the power input to the cooking apparatus 100 to a high pressure, or generated by one or more switching elements performing a switching operation. An inverter for supplying a high output voltage of about 3500V or more to the microwave generator 110 may be provided.

Meanwhile, a cooling fan (not shown) for cooling the microwave generator 110 may be installed around the microwave generator 110.

Although not shown in the figure, a resonance mode converter (not shown) for resonant mode conversion in the cavity 134 may be disposed. Examples of the resonance mode converter (not shown) may include at least one of a stirrer, a rotation table, a sliding table, and a field adjustment element (FAE). Among them, the rotary table and the sliding table may be disposed under the cavity 134, and the stirrer may be disposed at various positions such as the lower, side, and upper portions of the cavity.

In the cooking apparatus 100 using the microwave, the user opens the door 106, puts the heating object 140 into the cavity 134, and then closes the door 106 or closes the door 106. When the start button (not shown) is operated by operating the operation panel 108, especially the operation unit 107, the operation is performed.

That is, the power supply unit 114 in the cooking apparatus 100 boosts the input AC power to a high-pressure DC power supply to supply the microwave generator 110, and the microwave generator 110 supplies the corresponding microwave. It generates and outputs, the microwave transmitter 112 transmits the generated microwave to be emitted to the cavity 134. Accordingly, the heating target 140, for example, the food inside the cavity 134 is heated.

3 is a block diagram schematically illustrating an example of the inside of the cooking appliance of FIG. 1.

Referring to the block diagram of FIG. 3, the cooking apparatus 100 according to the embodiment of the present invention may include a microwave generator 110, a microwave transmitter 112, a cavity 134, a controller 310, and It may include a power supply 114.

The microwave generator 110 includes a frequency oscillator 332, a level adjuster 334, an amplifier 336, a directional coupler 338, a first power detector 342, and a second power detector 346. , A microwave control unit 350, a power supply unit 360, and an isolation unit 364. This exemplifies a case composed of a solid state power amplifier (SSPA).

Such components may be configured by combining two or more components into one component, or by dividing one or more components into two or more components as necessary when implemented in an actual application.

The frequency oscillator 332 oscillates to output a microwave of a corresponding frequency by a frequency control signal from the microwave control unit 350. The frequency oscillator 322 may include a voltage controlled oscillator (VCO). According to the voltage level of the frequency control signal, the voltage controlled oscillator VCO oscillates a corresponding frequency. For example, the greater the voltage level of the frequency control signal, the greater the frequency generated by oscillation in the voltage controlled oscillator VCO.

The level adjuster 334 may oscillate the frequency signal oscillated by the frequency oscillator 332 to output a microwave at a corresponding power according to the power control signal. The level adjuster 334 may include a voltage controlled attenuator (VCA).

According to the voltage level of the power control signal, the voltage control attenuation unit VCA performs a correction operation so that microwaves are output at a corresponding power. For example, the greater the voltage level of the power control signal, the greater the power level of the signal output from the voltage control attenuation unit VCA.

The amplifier 336 amplifies the oscillated frequency signal based on the frequency signal oscillated by the frequency oscillator 332 and the power control signal by the level adjuster 334 to output a microwave.

 The directional coupler (DC) 338 transmits the microwaves amplified by the amplifier 336 to the microwave transmitter 112. The microwave output from the microwave transmitter 112 heats the object in the cavity 134.

Meanwhile, microwaves that are not absorbed and reflected by the object in the cavity 134 may be input to the directional coupler 338 through the microwave transmitter 112 again. The directional coupler 338 delivers the reflected microwaves to the microwave control unit 350.

On the other hand, the directional coupler 338 may include a first power detector 342 for detecting the power of the microwave output, and a second power detector 346 for detecting the power of the reflected microwaves. The first power detector 342 and the second power detector 346 may be disposed between the directional coupler 338 and the microwave controller 350 and may be disposed on the directional coupler 338 in a circuit.

The first power detector 342 detects the output power of the microwaves amplified by the amplifier 336 and output to the microwave transmitter 112 via the directional coupler 338. The detected power signal is input to the microwave control unit 350 to be used for calculating the heating efficiency. The first power detector 342 may be implemented with a resistor, a Schottky diode device, or the like for power detection.

Meanwhile, the second power detector 346 detects the power of the reflected microwaves reflected by the cavity 134 and received by the directional coupler 338. The detected power signal is input to the microwave control unit 350 to be used for calculating the heating efficiency. The second power detector 346 may be implemented with a resistor, a Schottky diode device, or the like for power detection.

The microwave control unit 350 operates by receiving driving power from the internal power supply unit 360 constituting the microwave generating unit 110. The microwave control unit 350 may communicate with the control unit 310 to control the operation of the components of the microwave generation unit 110.

The microwave controller 350 may calculate the heating efficiency based on the microwaves reflected without being absorbed by the object among the microwaves emitted into the cavity 134.

Here, Pt represents the power of the microwave emitted into the cavity 134, Pr represents the power of the microwave reflected from the cavity 134, he represents the heating efficiency of the microwave.

According to Equation 1, the heating efficiency he becomes smaller as the power of the microwave to be reflected increases.

On the other hand, when a plurality of microwaves are emitted into the cavity 134, the microwave control unit 350 calculates the heating efficiency (he) for each frequency of the plurality of microwaves. This heating efficiency calculation, according to an embodiment of the present invention, can be performed during the entire cooking period.

On the other hand, for efficient heating, the entire cooking section may be performed by dividing the scan section and the heating section. During the scan period, the plurality of microwaves may be sequentially output into the cavity 134 and the heating efficiency may be calculated based on the reflected microwaves. During the heating section, based on the heating efficiency calculated in the scan section, the output period of each microwave is outputted differently, or only a microwave of a predetermined frequency is output. The power of the microwave in the heating section is preferably significantly higher than the power of the microwave in the scan section.

The microwave controller 350 generates and outputs a frequency control signal to vary the output period of the microwave according to the calculated heating efficiency. The frequency oscillator 332 oscillates a corresponding frequency according to the input frequency control signal.

The microwave control unit 350 generates a frequency control signal so that the output period of the microwave is shortened when the calculated heating efficiency he is high. That is, while sequentially sweeping a plurality of microwaves, the output period of each microwave can be varied according to the calculated heating efficiency. In other words, the higher the heating efficiency he, the smaller the corresponding output period. Accordingly, the microwaves can be uniformly absorbed by the heating object in the cavity 134 for each frequency, and the heating object can be uniformly heated.

On the other hand, the microwave control unit 350, it is also possible to control to output the microwave of the corresponding frequency only when the heating efficiency (he) calculated for each frequency is more than the set target heating efficiency. That is, the microwave of low frequency heating efficiency (he) is excluded from the actual heating period, it is possible to efficiently heat the heating object efficiently.

Meanwhile, the directional coupler 338, including the microwave control unit 350, the power supply unit 360, the frequency oscillator 332, the level control unit 334, and the amplifier 336 in the microwave generation unit 110 described above. The first power detector 342, the second power detector 346, and the like may be implemented as one module. That is, it is possible to be all disposed on one substrate, to be implemented as one module.

The microwave control unit 350 calculates the heating efficiency for each microwave based on the microwaves reflected from the inside of the cavity 134 without being absorbed by the food among the microwaves output into the cavity 134. The microwave of the frequency whose heating efficiency is more than the set target heating efficiency can be calculated. The heating time can be calculated based on the calculated heating efficiency of the microwave. For example, the heating efficiency is higher than or equal to the set target heating efficiency, and the higher the heating efficiency is, the smaller the heating time of the microwave of the corresponding frequency can be set. Thereby, uniform heating of the object can be performed.

Meanwhile, the microwave control unit 350 outputs a microwave for heating the food in the cavity 134 to the cavity 134 based on the calculated heating efficiency. To control. At this time, when heating, the power of the microwave output to the cavity 134 is preferably significantly greater than the power of the microwave output to the cavity 134 when measuring the heating efficiency.

On the other hand, the microwave control unit 350, in the heating section, when the heating efficiency based on the microwaves reflected from the inside of the cavity 134 of the output microwaves is less than the reference efficiency, and stops the output of the microwave of the frequency, The microwave generator 110 may be controlled to output the microwave of the next frequency. By this, efficient heating can be performed.

In addition, the microwave controller 350 calculates heating efficiency for each of the plurality of microwaves based on the microwaves reflected from the inside of the cavity 134 among the microwaves output by the amplifier 336. Depending on the heating efficiency, it is possible to set the heating time for each microwave during the heating period.

At this time, the microwave control unit 350, for example, when the first microwave of the plurality of microwaves has a higher heating efficiency than the second microwave, the heating time of the first microwave than the heating time of the second microwave It can be set shorter.

When heating, the microwave control unit 350 may output the same power control signal to the microwave generating unit 110 for each microwave. In addition, the level adjusting unit 334 may output a constant power level according to the input power control signal.

The power supply unit 360 supplies the driving power for the components inside the microwave generating unit 110. The driving power is supplied to the microwave control unit 350 and the amplifier 336. The external power is supplied from the power supply unit 114 to regulate power to the inside of the microwave generator 110.

The isolation unit 364 is disposed between the amplifier 336 and the directional coupler 338, and passes the microwaves when passing the microwaves amplified by the amplifier 336 to the cavity 134. The microwaves reflected from 134 block. The isolation unit 364 may be implemented as an isolator. The microwaves reflected from the cavity 134 are absorbed by the resistance inside the isolation 364 and cannot enter the amplifier 336. The reflected microwaves are prevented from entering the amplifier 336.

The microwave transmitter 112 transmits the microwave generated and output by the microwave generator 110 to the cavity 134. The microwave transmitter 112 may include a transmission line. The transmission line may be implemented by a waveguide, a microstrip line, a coaxial cable, or the like.

Meanwhile, in order to transmit the generated microwaves to the microwave transmitter 112, the feeder 142 may be connected as shown in the drawing.

The control unit 310 controls the entire system of the cooking appliance in response to the signal received from the operation unit 107. The controller 310 may communicate with the microwave controller 350 of the microwave generator 110 to control the operation of internal components of the microwave generator 110. The controller 310 may control the display unit 105 to externally display the current operation of the cooking appliance, the remaining cooking time, the type of cooking, and the like.

The power supply unit 114 may include a high voltage transformer for supplying power to the microwave generator 110 by boosting the power input to the cooking apparatus 100 to a high pressure, or generated by one or more switching elements performing a switching operation. An inverter for supplying a high output voltage of about 3500V or more to the microwave generator 110 may be provided. In addition, the power supply unit 114 supplies a driving voltage to the control unit 310.

Meanwhile, a block diagram of the cooking appliance 100 shown in FIG. 3 is a block diagram for one embodiment of the present invention. Each component of the block diagram may be integrated, added, or omitted according to the specifications of the cooking apparatus 100 that is actually implemented. That is, two or more constituent elements may be combined into one constituent element, or one constituent element may be constituted by two or more constituent elements, if necessary. In addition, the functions performed in each block are intended to illustrate the embodiments of the present invention, and the specific operations and apparatuses do not limit the scope of the present invention.

4 is a block diagram schematically illustrating another example of the inside of the cooking appliance of FIG. 1.

Referring to the drawings, unlike the microwave generation unit 110 described above with reference to FIG. 3, it is a block diagram of a cooking apparatus using a microwave composed of a solid power oscillator (SSPO).

The same components as those described above in FIG. 3 will be omitted.

According to the exemplary embodiment of the present invention, the microwave generator 110 may include a microwave controller 350, a power supply unit 360, a phase shifter 362, an amplifier 336, an isolation unit 364, and a directional coupler. 338 may be included.

As described above, the directional coupler 338 may include a first power detector 342 and a second power detector 346.

There is a difference in that the frequency oscillator 322 and the level adjuster 334 existing in the microwave generator 110 of FIG. 3 are not included, and a phase shifter 362 is added. Referring to the difference from FIG. 3, the microwave control unit 350 outputs the microwave unit 336 to output the microwave for heating the food in the cavity to the cavity 134 based on the calculated heating efficiency he. To control.

The amplifier 336 receives the DC power from the power supply unit 360 and performs its own frequency oscillation and amplification. That is, without an additional frequency oscillator for generating and outputting a frequency oscillation signal, it performs frequency oscillation by itself according to the input of the DC power supply and performs an amplification operation.

The amplifier 336 may include at least one RF power transistor, and when a plurality of RF power transistors are used, the amplifier 336 may be implemented in series, parallel, serial, or parallel mixing to implement multistage amplification. The amplifier 336 may be, for example, an RF power transistor. On the other hand, the output of the amplifier 336 may be approximately 100 to 1000W.

Next, the phase shifter 362 may feed back the output of the amplifier 336 to shift the phase. The amount of phase shift may be adjusted according to the phase control signal of the microwave controller 350. By phase shifting the amplified signal of the predetermined frequency output from the amplifier in this way, it is possible to generate microwaves of various frequencies as described above. For example, the frequency may increase in proportion to the amount of phase shift.

On the other hand, it is preferable that a signal corresponding to approximately 1 to 2% of the amplified signal level at a predetermined frequency is sampled and input to the phase shifter 362. This is considered to be amplified by the amplifier 336 again after the feedback.

Next, the isolation unit 364 supplies the phase shifted signal from the phase shifter 362 to the amplifier 336 again. On the other hand, when the level of the phase shifted signal by the phase shifter 362 is less than the set value, the isolation unit 364 may supply the phase shifted signal to the ground terminal instead of the amplifier 336.

The signal supplied from the isolation unit 364 is amplified again by the amplifier 336. Accordingly, a plurality of microwaves having different frequencies are sequentially output.

As such, since the amplifier 336 performs oscillation and amplification of itself, the microwave generator 110 may be simply implemented. In addition, a plurality of microwaves can be generated and output using the phase shifter 362.

FIG. 5 is a circuit diagram schematically illustrating the interior of the solid state power oscillator of FIG. 4.

Referring to the drawings, the solid state power oscillator SSPO of FIG. 5 includes an amplifier 336, a phase shifter 362, and an isolation unit 366.

The amplifier 336 receives the DC power from the power supply unit 360 and performs its own frequency oscillation and amplification. That is, without an additional frequency oscillator for generating and outputting a frequency oscillation signal, it performs frequency oscillation by itself according to the input of the DC power supply and performs an amplification operation.

The amplifier 336 may include at least one RF power transistor, and when a plurality of RF power transistors are used, the amplifier 336 may be implemented in series, parallel, serial, or parallel mixing to implement multistage amplification. The amplifier 336 may be, for example, an RF power transistor. On the other hand, the output of the amplifier 336 may be approximately 100 to 1000W.

Next, the phase shifter 362 may feed back the output of the amplifier 336 to shift the phase. The amount of phase shift may be adjusted according to the phase control signal of the controller 310. By phase shifting the amplified signal of the predetermined frequency output from the amplifier in this way, it is possible to generate microwaves of various frequencies as described above. For example, the frequency may increase in proportion to the amount of phase shift.

On the other hand, it is preferable that a signal corresponding to approximately 1 to 2% of the amplified signal level at a predetermined frequency is sampled and input to the phase shifter 362. This is considered to be amplified by the amplifier 336 again after the feedback.

Next, the third isolation unit 366 supplies the phase shifted signal from the phase shifter 362 to the amplifier 336 again. On the other hand, when the phase shifted signal level of the phase shifter 362 is less than the set value, the third isolation unit 366 may supply the phase shifted signal to the ground terminal instead of the amplifier 336.

The signal supplied from the third isolation unit 364 is amplified again by the amplifier 336. Accordingly, a plurality of microwaves having different frequencies are sequentially output.

The feedback transmission line 390 is a transmission line connecting the output terminal of the amplifier 336 and the phase shifter 362. The phase shifter 362 is located on the feedback transmission line 390. According to an embodiment of the present invention, the phase shifter 362 may be configured as an impedance element such as a switch and / or a diode.

6 to 15 are diagrams illustrating various examples of an antenna of a cooking appliance using microwaves according to an embodiment of the present invention.

First, referring to FIG. 6, a cooking apparatus using microwaves according to an embodiment of the present invention includes an antenna. In FIG. 6A, an antenna having the first metal part 620 protrudes into the cavity 134.

The first metal part 620 provided in the antenna is connected to one end of the microwave transmission line 610 for transmitting microwaves into the cavity 134 and extends in one direction. In particular, it may extend in parallel with the plate 634 forming the cavity 134. For example, when the antenna is formed on the ceiling of the cavity 134, the first metal part 620 may be formed parallel to the rear plate that forms the ceiling of the cavity 134. Alternatively, when the antenna is formed on the ceiling of the cavity 134, the first metal part 620 may be formed parallel to the bottom plate forming the bottom surface of the cavity 134. In addition, the first metal part 620 may be formed in parallel with the plate at various positions such as a rear plate or a side plate.

6 (b) illustrates a side view of the antenna structure. As described above, when the first metal part 620 provided in the antenna extends in parallel with the plate 634 forming the cavity 134, a magnetic field rotating around the first metal part 620. ) Is formed, and an electric field is formed between the first metal part 620 and the plate 634 formed of the metal.

On the other hand, as shown in the drawing, when the end of the first metal portion 620 is not connected to the plate 634, since the first metal portion 620 and the plate 634 do not form a loop like a coil, the magnetic field ( magnetic field is not concentrated. Accordingly, the electric field component is relatively stronger than the magnetic field component. Accordingly, such an antenna structure may be referred to as an electric antenna.

Meanwhile, the frequency band of the microwave which can be output may be set according to the length L1 of the first metal part 620 and the distance d1 from the plate 634.

The antenna structure as shown in FIG. 6 is formed in parallel with the plate 634, unlike the conventional monopole antenna structure formed by protruding into the cavity. It can form small.

And, in relation to the frequency band of the microwave, adjustment elements such as the length L1 of the first metal part L1 and the distance d1 to the plate 634 are increased, which is considerably wider than the monopole antenna. Wide band microwave output is possible. In addition, impedance matching may be easy.

Although not shown in FIG. 6, an antenna cover covering the antenna structure of FIG. 6 may be formed. As a result, during operation of the cooking appliance, the antenna can be protected by debris and the like flowing out of the object. In particular, since the projecting degree is smaller than in the related art, the antenna can be easily protected. The antenna cover may be formed in the same manner as in the antennas described with reference to FIGS. 7 to 13.

In addition, unlike the drawing, it is possible to form a plurality of such antennas. 7 to 15, the antennas described in the following may be formed in plural numbers as well.

Next, referring to FIG. 7, the antenna structure of FIG. 7 includes a first metal portion 620 and additionally includes a second metal portion 710, similarly to the antenna structure of FIG. 6. In FIG. 7A, an antenna including the first metal part 620 and the second metal part 710 protrudes into the cavity 134. The following description focuses on the differences.

The second metal part 710 provided in the antenna is connected to one end of the microwave transmission line 610 for transmitting microwaves into the cavity 134 and extends in one direction. In particular, it extends in parallel with the plate 634 forming the cavity 134. In the drawing, the first metal part 620 has an angle formed in the opposite direction, that is, between 180 degrees.

7 (b) illustrates a side view of the antenna structure. According to the length L1 of the first metal part 620, the distance d1 from the first metal part 620, and the length L2 of the second metal part 710, the frequency band of the microwave which can be output is set. Can be.

Similar to FIG. 6, when the end of the first metal part 620 and the end of the second metal part 710 are not connected to the plate 634, the first metal part 620 and the second metal part ( 710 and plate 634 do not form a loop like a coil so that the magnetic field is not concentrated. Accordingly, the electric field component is relatively stronger than the magnetic field component. Accordingly, such an antenna structure may be referred to as an electric antenna.

Next, referring to FIG. 8, the antenna structure of FIG. 8 includes a first metal part 620 and a second metal part 710, similar to the antenna structure of FIG. 7. However, there is a difference that the angle between the first metal part 620 and the second metal part 710 is formed at 90 degrees rather than 180 degrees as shown in FIG. 7.

The electric antenna structure described with reference to FIGS. 7 and 8 has a 90 degree angle between the magnetic fields generated by the first metal part 620 and the magnetic fields generated by the second metal part 710 in order to minimize the cancellation of the magnetic fields. It is preferable to set to 180 degrees. For example, if it is within 90 degrees, the magnetic field generated by the first metal part 620 and the magnetic field generated by the second metal part 710 may be cancelled, thereby degrading the original function of the antenna. do.

Next, referring to FIG. 9, similar to the antenna structure of FIG. 6, the antenna structure of FIG. 9 includes a first metal portion 620, and further includes a third metal portion 910. In FIG. 9A, an antenna including the first metal part 620 and the third metal part 910 protrudes into the cavity 134. The following description focuses on the differences.

The third metal portion 910 provided in the antenna is connected to one end of the first metal portion 620 described above and extends in the direction of the plate 634.

9B illustrates a side view of the antenna structure. Microwave capable of outputting according to the length L1 of the first metal part 620, the distance d1 between the plate 634 and the first metal part 620, and the length L3 of the third metal part 910. The frequency band of can be set.

In order to increase the intensity of the electric field generated by the first metal part 620, the length L1 of the first metal part 620 is preferably larger than the length L3 of the third metal part 910.

Next, referring to FIG. 10, the antenna structure of FIG. 10 includes a first metal part 620 and a third metal part 1010 similarly to the antenna structure of FIG. 9. However, there is a difference in the structure of the third metal part 1010. As shown in FIG. 10A, one end of the third metal part 1010 in the direction of the plate 634 may have a plate shape. Meanwhile, the antenna structure of FIG. 10 may further include a dielectric 1020 disposed between the third metal portion 1010 and the plate 634.

10 (b) illustrates a side view of the antenna structure. The length L1 of the first metal part 620, the distance d1 between the plate 634 and the first metal part 620, the length L3 of the third metal part 1010, and the dielectric constant of the dielectric 1020. And the frequency band of the microwave which can be output, according to the distance d2 between the dielectric 1020 or the third metal part 1010 and the plate 634.

In particular, the antenna structure of FIG. 10 may partially strengthen the electric field component among the magnetic field component and the electric field component due to the dot or the arrangement of the dielectric 1020 having one end of the third metal part 1010.

Next, referring to FIG. 11, similar to the antenna structure of FIG. 9, the antenna structure of FIG. 11 includes a first metal part 620, a second metal part 710, and a third metal part 910. In addition, a fourth metal part 1110 is further provided. In FIG. 11A, an antenna having a first metal part 620, a second metal part 710, a third metal part 910, and a fourth metal part 1110 protrudes into the cavity 134. Illustrates that. The following description focuses on the differences.

The fourth metal part 1110 provided in the antenna is connected to one end of the second metal part 720 described above and extends in the direction of the plate 634.

11 (b) illustrates a side view of the antenna structure. The length L1 of the first metal part 620, the distance d1 between the plate 634 and the first metal part 620, the length L3 of the third metal part 910, and the second metal part 710. The frequency band of the microwave which can be output may be set according to the length L2 of the λ and the length L4 of the fourth metal part 1110.

In order to increase the intensity of the electric field generated by the second metal part 710, the length L2 of the second metal part 710 may be larger than the length L4 of the fourth metal part 1110.

Next, referring to FIG. 12, similar to the antenna structure of FIG. 11, the antenna structure of FIG. 12 includes a first metal part 620, a second metal part 710, a third metal part 910, and The fourth metal part 1210 is provided. In FIG. 11A, an antenna having a first metal part 620, a second metal part 710, a third metal part 910, and a fourth metal part 1210 protrudes into the cavity 134. Illustrates that. The following description focuses on the differences.

Unlike FIG. 11, the difference is that the fourth metal part 1210 is connected to the plate 634.

12 (b) illustrates a side view of the antenna structure. As shown in the drawing, the fourth metal part 1210 is connected to the plate 634, so that the second metal part 710, the fourth metal part 1210, and the plate 634 are like a coil as described above. Since a loop can be formed, the magnetic field can be concentrated in a specific direction (eg, ahead of the ground). Accordingly, the magnetic field component is strengthened more than the electric field component formed by the metal parts 710 and 1210. Such an antenna structure may be referred to as a magnetic antenna.

Meanwhile, the antenna structure of FIG. 12 includes an electric antenna formed by the first metal part 620 and the third metal part 910, and a magnetic antenna formed by the second metal part 710 and the fourth metal part 1210. As a combination, it may be referred to as a hybrid antenna.

Next, FIG. 13 illustrates an antenna structure in which an opening is formed. Referring to the drawings, similar to the antenna structure of FIG. 7, the antenna structure of FIG. 13 includes a first metal part 620 and a second metal part 710, and includes at least one of the metal parts 620 and 710. An opening is formed.

In FIG. 13A, one opening 1310 and 1320 are formed in the first metal part 620 and the second metal part 710, respectively. As a result, the magnetic field component of the first metal part 620 is weaker than the electric field component, and the magnetic field component of the second metal part 710 is weaker than the electric field component, thereby operating as an electric antenna.

Next, in FIG. 13B, one opening 1310 and 1320 are formed in the first metal part 620 and the second metal part 710, and cutouts 1315 and 1325 are formed. Illustrate that. Similar to the forming effects of the openings 1310 and 1320, the formation of the cutouts 1315 and 1325 causes the magnetic field component to be weaker than the electric field component, thereby operating as an electric antenna.

On the other hand, the formation of such openings or cutouts is also applicable to the respective antenna structures of FIGS. 6 to 12 described above.

14-15 illustrate various examples in which bends are formed in the plate. First, referring to FIG. 14, the antenna may be formed in the bent portion 1415 formed in the plate 634. As a result, the antenna 134 can be protected without being directly exposed to the cavity 134.

In addition, an antenna cover 1460 may be further formed to cover the antenna formed in the bent portion 1415. This makes it possible to protect the antenna more safely.

FIG. 14A illustrates an antenna including a first metal part 1420 having one end connected to the microwave transmission line 1410 as shown in FIG. 6.

FIG. 14B illustrates an antenna including the first metal part 1420 and the second metal part 1425 as shown in FIG. 7, and FIG. 14C shows the first metal as shown in FIG. 9. An antenna including a portion 1420 and a third metal portion 1430 is illustrated, and FIG. 14D illustrates a third metal portion having a first metal portion 1420 and one end of a plate shape as shown in FIG. 10. An antenna including 1440 and a dielectric 1450 is illustrated.

Next, referring to FIG. 15, the antenna may be formed in the bent portion 1515 formed in the plate 634. In particular, unlike FIG. 14, the microwave transmission line 1510 protrudes in a direction parallel to the plate 634, and the first metal part 1520 is disposed in the same direction as the extension direction of the microwave transmission line 1510. Connected and extended. In addition, an antenna cover 1560 may be further formed to cover the antenna formed in the bent portion 1515. This makes it possible to protect the antenna more safely.

FIG. 15A illustrates an antenna including a first metal part 1520 having one end connected to the microwave transmission line 1510, similar to FIG. 6. FIG. 15B illustrates an antenna including a first metal part 1520 and metal parts 1530 and 1535 having one end connected to the first metal part 1520, respectively.

Microwave cooking apparatus according to the present invention is not limited to the configuration and method of the embodiments described as described above, the embodiments are all or part of each embodiment so that various modifications can be made It may alternatively be configured in combination.

In addition, while the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (14)

A plate forming a cavity;
A microwave transmission line for transmitting microwaves into the cavity;
And a first metal part connected to one end of the transmission line and extending in one direction and parallel to the plate. The method of claim 1,
And a second metal part connected to one end of the transmission line and extending in one direction. The method according to claim 1 or 2,
And a third metal part connected to one end of the first metal part and extending in the plate direction. The method of claim 3,
And a fourth metal part connected to one end of the second metal part and extended to be connected to the plate. The method of claim 3,
Dielectric disposed between the third metal portion and the plate; Cooking apparatus using a microwave further comprising a. The method of claim 3,
One end of the third metal portion in the plate direction is a plate-shaped cooking apparatus using a microwave. The method of claim 2,
Cooking angle using a microwave, characterized in that the angle between the first metal portion and the second metal portion is 90 to 180 degrees. The method of claim 2,
At least one of the first metal portion and the second metal portion, at least one opening is formed cooking apparatus characterized in that the microwave. The method of claim 1,
The bent portion is formed on the plate,
The cooking device using a microwave, characterized in that the first metal portion is formed in the bent portion. The method of claim 2,
The bent portion is formed on the plate,
The cooking device using a microwave, characterized in that the first metal portion and the second metal portion is formed in the bent portion. The method of claim 2 or 10,
And the first metal part and the second metal part extend in a direction crossing the transmission line. The method of claim 2 or 10,
At least one of the first metal portion and the second metal portion, the microwave cooking apparatus, characterized in that extending in the same direction as the direction in which the transmission line extends. The method of claim 2 or 10,
And a cover covering the first metal part and the second metal part so as not to protrude into the cavity. The method of claim 13,
And a second dielectric formed between the cover and the transmission line.

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