KR101760297B1 - A cooking apparatus - Google Patents

Abstract

According to an aspect of the present invention, there is provided a microwave cooking apparatus including a microwave generating unit for generating microwave and outputting the microwave into the cavity, and an antenna unit for radiating the generated microwave into the cavity Wherein the antenna portion includes at least one variable support portion and at least one antenna, and the antenna corresponds to a change in the shape of the variable support portion. Thereby, it is possible to design an antenna optimized for the state according to the state, and the heating efficiency can be increased.

Description

[0001] The present invention relates to a cooking apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cooking device, and more particularly, to a cooking device capable of adjusting the length of an antenna using a shape memory alloy.

Generally, the food is stored and sealed in the cooking device. When the operation button is pressed, a voltage is applied to the high-voltage generator, and a commercial voltage applied to the high-voltage generator is boosted to apply power to the magnetron generating microwaves. The generated microwave is transmitted to the cavity through a waveguide or the like.

At this time, the cooker is to heat the food by the frictional heat generated by vibrating the molecules constituting the food by vibrating 2.45 billion times per second by irradiating the microwave generated from the magnetron to the food.

Such a cooking device is widely used in general households due to various advantages such as easy temperature control, saving cooking time, and convenience of operation.

On the other hand, the shape of the antenna inside the cooking device varies greatly depending on the load. For example, the characteristics of the antenna for defrosting the load and the characteristics of the antenna for cooking are different.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a cooking appliance which can connect a shape memory alloy to an antenna and change the frequency of the antenna while varying the length of the antenna.

According to an aspect of the present invention, there is provided a cooking apparatus including a microwave generating unit for generating microwave and outputting the generated microwave into the cavity, and an antenna unit for radiating the generated microwave into the cavity, The portion includes at least one variable support and at least one antenna, wherein the antenna corresponds to a change in the shape of the variable support.

According to the embodiment of the present invention, it is possible to design an antenna optimized for a corresponding state according to the state of a load with one antenna, thereby improving heating efficiency.

Further, it is possible to design an antenna having a plurality of characteristics by using a plurality of different shape memory alloys.

Further, by using a metal having a thermal expansion coefficient different from that of the antenna, a bimetal structure can be formed to control the flexure of the antenna.

That is, by designing the antenna using a shape memory alloy or a metal having a different thermal expansion coefficient, it is possible to design a cooking appliance satisfying the optimum cooking condition according to the state of the load.

FIG. 1 is a partial perspective view of a cooking apparatus according to an embodiment of the present invention, and FIG. 2 is a sectional view of the cooking apparatus of FIG.
3 is a block diagram schematically showing an example of the interior of the cooking apparatus of FIG.
Fig. 4 is a block diagram schematically showing another example of the inside of the cooking apparatus of Fig. 1. Fig.
5 is a circuit diagram briefly showing the inside of the solid state power oscillator of FIG.
6 is a view schematically showing an antenna unit according to an embodiment of the present invention.
7 is a view schematically showing an antenna unit according to an embodiment of the present invention.
8 to 9 are views illustrating an antenna unit 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 suffix "module" and " part "for components used in the following description are given merely for convenience of description, and do not give special significance or role in themselves. Accordingly, the terms "module" and "part" may be used interchangeably.

FIG. 1 is a partial perspective view of a cooking apparatus according to an embodiment of the present invention, and FIG. 2 is a sectional view of the cooking apparatus of FIG.

The cooking apparatus 100 according to the embodiment of the present invention includes a door 106 to which a cooking window 104 is attached on a front portion of a main body 102 to be opened and closed, 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. 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 portion 107 for operating the operation of the cooking appliance and a display portion 105 for displaying the operation of the cooking appliance and the like.

The interior of the body 102 is provided with a cavity 134 having a receiving space of a predetermined size so that the object to be heated 140, for example, food is received and cooked by microwaves.

The cavity 134 can be formed in a substantially rectangular parallelepipedal shape in which at least one surface of the plate members is joined to each other and the front surface is opened.

For example, the cavity 134 includes an upper plate that forms a ceiling, a rear plate that forms the rear surface of the cavity 134, a bottom plate that forms the bottom surface of the cavity 134, A bottom plate, and a side plate that forms a side surface of the cavity 134. [ On the other hand, a door 106 may be disposed on the front surface of the cavity 134. At this time, a front plate forming the front surface of the cavity 134 may be formed in an area other than the door 106.

A microwave generator 110 for generating a microwave is installed on an outer surface of the cavity 134. A microwave generated by the microwave generator 110 is supplied to an output side of the microwave generator 110, And a microwave transfer unit 112 for guiding the microwave to the inside of the microwave oven 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.

The solid state power amplifier (SSPA) has the advantage of occupying less space than the magnetron. The SSPO does not have a voltage controlled oscillator (VCO) and a voltage controlled attenuator (VCA) as compared with a solid state power amplifier (SSPA) And the circuit configuration is simplified.

On the other hand, a solid state power amplifier (SSPA) or a solid state power oscillator (SSPO) may be a hybrid microwave integrated circuit (hereinafter, referred to as " solid state power amplifier ") having separate passive elements (capacitors and inductors, etc.) and active elements HMIC), or monolithic microwave integrated circuits (MMIC) in which passive elements and active elements are implemented as a single substrate.

The microwave generator 110 may be implemented as a single module of a solid state power amplifier SSPA or a solid state power oscillator SSPO and may be referred to as a solid state power module .

Meanwhile, according to the embodiment of the present invention, the microwave generating unit 110 can generate and output a plurality of microwaves. The frequency range of such microwaves may be in the vicinity of approximately 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 by the microwave generator 110 to the cavity 134. The microwave transmitting unit 112 may include a transmission line. The transmission line may be implemented by a waveguide, a microstrip line, or a coaxial cable. In order to transmit the generated microwave to the microwave transmitting unit 112, a feeder 142 may be connected as shown in the figure.

Meanwhile, the microwave transmitting unit 112 can be realized as an opening having an opening 145 into the cavity 134 as shown in the drawing.

Meanwhile, the opening 145 may be formed in various shapes such as a slot shape. Through the opening 145, the microwave is emitted to the cavity 134.

Although the opening 145 is shown as being disposed on the upper side of the cavity 134, the opening 145 may be disposed on the lower side or the side of the cavity 134, and a plurality of openings may be disposed It is also possible.

It is also possible that an antenna is coupled to the end of the microwave transmitting unit 112. The antenna structure will be described later with reference to FIG. 6 and the following figures.

A power supply 114 is provided below the microwave generator 110 to supply power to the microwave generator 110.

The power supply 114 may include a high voltage transformer that boosts the power supplied to the cooking appliance 100 to a high voltage and supplies the power to the microwave generator 110, And an inverter for supplying a high output voltage of about 3500 V or more to the microwave generator 110.

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

On the other hand, although not shown in the drawing, a resonance mode conversion unit (not shown) for resonance mode conversion in the cavity 134 can be disposed. An example of the resonance mode converter (not shown) may be at least one of a stirrer, a rotary table, a sliding table, and a field adjusting element (FAE). The rotary table and the sliding table can be disposed under the cavity 134, and the stirrer can be disposed at various positions such as a lower portion, a side surface, and an upper portion of the cavity.

The above-described cooking apparatus 100 is configured such that the user closes the door 106 or closes the door 106 after the door 106 is opened and the heating object 140 is placed in the cavity 134, ), In particular, by pressing the start button (not shown) by operating the operation unit 107. [

That is, the power supply unit 114 in the cooking apparatus 100 boosts the input AC power to a high-voltage DC power and supplies the boosted power to the microwave generation unit 110. The microwave generation unit 110 generates the corresponding microwave And the microwave transmitting unit 112 transmits the generated microwave to the cavity 134 to emit the generated microwave. As a result, the heating object 140, for example, the food inside the cavity 134 is heated.

3 is a block diagram schematically showing an example of the interior of the cooking apparatus of FIG.

3, the cooking apparatus 100 according to the embodiment of the present invention includes a microwave generating unit 110, a microwave transmitting unit 112, a cavity 134, a control unit 310, And may include a power supply 114.

The microwave generator 110 includes a frequency oscillator 332, a level controller 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 illustrates the case of a solid state power amplifier (SSPA).

When such components are implemented in practical applications, two or more components may be combined into one component, or one component may be divided into two or more components as necessary.

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

The level adjusting unit 334 can oscillate the frequency signal oscillated by the frequency oscillating unit 332 so as to output a microwave at a power corresponding to the power control signal. The level adjuster 334 may include a voltage controlled attenuator (VCA).

In accordance with the voltage level of the power control signal, the voltage control attenuator VCA performs the correction operation so that the microwave is outputted at the 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 attenuator VCA.

The amplifying unit 336 amplifies the oscillated frequency signal based on the frequency signal oscillated in the frequency oscillating unit 332 and the power control signal in the level adjusting unit 334 to output a microwave.

 The directional coupler (DC) 338 transfers the microwave amplified by the amplifying unit 336 to the microwave transmitting unit 112. The microwave outputted from the microwave transmitting unit 112 heats the object in the cavity 134.

On the other hand, the microwave that is not absorbed by the object in the cavity 134 and is reflected can be input to the directional coupler 338 through the microwave transfer unit 112 again. The directional coupler 338 transmits the reflected microwave to the microwave controller 350.

On the other hand, the directional coupler 338 may include a first power detector 342 that detects the power of the output microwave, and a second power detector 346 that detects the power of the reflected microwave. The first power detection unit 342 and the second power detection unit 346 may be disposed between the directional coupler 338 and the microwave control unit 350 and may be disposed over the directional coupler 338 in a circuit.

The first power detecting unit 342 detects the output power of the microwave amplified by the amplifying unit 336 and output to the microwave transmitting unit 112 via the directional coupler 338. The detected power signal is input to the microwave control unit 350 and used for the heating efficiency calculation. Meanwhile, the first power detector 342 may be implemented as a resistor, Schottky diode, or the like for power detection.

On the other hand, the second power detector 346 detects the power of the reflected microwave reflected by the cavity 134 and received by the directional coupler 338. The detected power signal is input to the microwave control unit 350 and used for the heating efficiency calculation. Meanwhile, the second power detector 346 may be implemented as a resistor, Schottky diode, 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 generation unit 110. The microwave control unit 350 can communicate with the control unit 310 to control the operation of the components of the microwave generation unit 110. [

The microwave control unit 350 can calculate the heating efficiency based on the microwave reflected into the cavity 134 without being absorbed by the object in the microwave.

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, and he represents the heating efficiency of the microwave.

According to the above-described expression (1), the heating efficiency he becomes smaller as the power of the reflected microwave becomes larger.

On the other hand, when a plurality of microwaves are emitted into the cavity 134, the microwave controller 350 calculates the heating efficiency he for each frequency of a plurality of microwaves. This heating efficiency calculation can be performed during the whole cooking section, in accordance with the embodiment of the present invention.

On the other hand, for efficient heating, the entire cooking section can be divided into a scan section and a heating section. During the scan period, a plurality of microwaves are sequentially output into the cavity 134, and the heating efficiency can be calculated based on the reflected microwaves. During the heating period, the output periods of the respective microwaves are output differently based on the heating efficiency calculated in the scan period, or only the microwaves of the predetermined frequency are output. It is preferable that the power of the microwave in the heating section is significantly higher than the power of the microwave in the scan section.

The microwave control unit 350 generates and outputs a frequency control signal so as to vary the output period of the microwave in accordance with the calculated heating efficiency. The frequency oscillator 332 oscillates at a frequency corresponding 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 sweeping the plurality of microwaves sequentially, the output period of each microwave can be varied according to the calculated heating efficiency. That is, the higher the heating efficiency (he), the smaller the corresponding output period is. As a result, microwaves can be uniformly absorbed by the heating object in the cavity 134 by frequency, and the heating object can be uniformly heated.

On the other hand, the microwave control unit 350 can control to output a microwave of the corresponding frequency only when the heating efficiency he calculated for each frequency is equal to or higher than the set target heating efficiency. That is, by excluding the microwave having a low heating efficiency (he) from the actual heating period, the heating object can be uniformly heated efficiently.

The directional coupler 338 includes a microwave controller 350, a power supply 360, a frequency oscillator 332, a level controller 334, and an amplifier 336 in the microwave generator 110. The first power detecting unit 342, the second power detecting unit 346, and the like may be implemented as a single module. That is, they are all arranged on one substrate, and can be implemented as one module.

The microwave controller 350 calculates the heating efficiency for each microwave based on the microwave output from the interior of the cavity 134 and reflected from the cavity 134 without being absorbed into the cooking cavity, It is possible to calculate the microwave whose frequency is higher than the target heating efficiency with the heating efficiency set. Then, the heating time can be calculated based on the calculated heating efficiency of the microwave. For example, the heating efficiency is higher than the set target heating efficiency, and the higher the heating efficiency, the smaller the heating time of the microwave at the frequency can be set. Thereby, uniform heating of the object can be performed.

The microwave controller 350 controls the frequency oscillator 332 and the level adjuster 334 to output the microwave for heating the food in the cavity 134 to the cavity 134 based on the calculated heating efficiency. . At this time, it is desirable that the power of the microwave outputted to the cavity 134 during heating is considerably larger than the power of the microwave outputted to the cavity 134 when the heating efficiency is measured.

On the other hand, in the heating section, when the heating efficiency based on the microwave reflected from the inside of the cavity 134 is less than the reference efficiency in the heating section, the microwave control section 350 stops outputting the microwave of the frequency, It is possible to control the microwave generator 110 to output the microwave of the next frequency. Thereby, efficient heating can be performed.

The microwave control unit 350 calculates the heating efficiency for each of the plurality of microwaves based on the microwave reflected from the inside of the cavity 134 among the microwaves outputted by the amplifying unit 336, Depending on the heating efficiency, the heating time for each microwave can be set during the heating period.

In this case, if the heating efficiency of the first microwave of the plurality of microwaves is higher than that of the second microwave, for example, the microwave controller 350 may control the heating time of the first microwave to be longer than the heating time of the second microwave It can be set shorter.

The microwave controller 350 may output the same power control signal to the microwave generator 110 for each microwave upon heating. Also, the level adjuster 334 can output a constant power level according to the input power control signal.

The power supply unit 360 supplies driving power for the components inside the microwave generation unit 110. And supplies driving power to the microwave control unit 350 and the amplification unit 336. And supplies power to the inside of the microwave generating unit 110 by regulating the external power supplied from the power supply unit 114.

The isolation portion 364 is disposed between the amplification portion 336 and the directional coupler 338. When the microwave amplified by the amplification portion 336 is transmitted to the cavity 134, Thereby blocking the microwave reflected from the microwave oscillator 134. The isolation portion 364 may be implemented as an isolator. The microwave reflected from the cavity 134 is absorbed by the resistance inside the isolation portion 364 and can not enter the amplification portion 336. [ Thereby preventing reflected microwaves from flowing into the amplification unit 336.

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

In order to transmit the generated microwave to the microwave transmitting unit 112, a feeder 142 may be connected as shown in the figure.

The control unit 310 controls the entire system of the cooking appliance in response to the signal input 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 the internal components of the microwave generator 110. The control unit 310 can control the display unit 105 to display the current operation of the cooking apparatus, the remaining cooking time, the type of cooking, and the like externally.

The power supply 114 may include a high voltage transformer that boosts the power supplied to the cooking appliance 100 to a high voltage and supplies the power to the microwave generator 110, And an inverter for supplying a high output voltage of about 3500 V or more to the microwave generator 110. The power supply 114 supplies a driving voltage to the controller 310.

Meanwhile, the block diagram of the cooking apparatus 100 shown in FIG. 3 is a block diagram for an embodiment of the present invention. Each component of the block diagram can be integrated, added, or omitted depending on the specifications of the cooking appliance 100 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.

Fig. 4 is a block diagram schematically showing another example of the inside of the cooking apparatus of Fig. 1. Fig.

3 is a block diagram of a cooking device, which is different from the microwave generating unit 110 shown in FIG. 3, and comprises a solid state power oscillator (SSPO).

The same components as those described above with reference to FIG. 3 will not be described.

The microwave generator 110 may include a microwave controller 350, a power supply 360, a phase shifter 362, an amplification unit 336, an isolation unit 364, and a directional coupler 338.

The directional coupler 338 may include a first power detector 342 and a second power detector 346 as described above.

There is no frequency oscillating unit 322 and a level adjusting unit 334 existing in the microwave generating unit 110 of FIG. 3 and a phase shifter 362 is added. 3, the microwave control unit 350 controls the amplification unit 336 to output microwaves for heating the food in the cavity to the cavity 134 based on the calculated heating efficiency he .

The amplification unit 336 receives the DC power from the power supply unit 360 and performs self oscillation and amplification. That is, without performing a separate frequency oscillation section for generating and outputting the frequency oscillation signal, the frequency oscillation itself is performed according to the input of the DC power supply, and the amplification operation is performed.

The amplifying unit 336 may include at least one RF power transistor. When a plurality of RF power transistors are used, the amplifying unit 336 may be configured to be multi-stage amplification by being configured in series, parallel, serial, or parallel mixing. The amplifier 336 may be, for example, an RF power transistor. On the other hand, the output of the amplification unit 336 may be approximately 100 to 1000W.

Next, the phase shifter 362 may shift the phase by feeding back the output of the amplifying unit 336. [ The amount of phase shift can be adjusted according to the phase control signal of the microwave controller 350. As described above, the microwave of various frequencies can be generated by phase-shifting the amplified signal of the predetermined frequency outputted from the amplifier. For example, the frequency may increase in proportion to the phase shift amount.

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

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

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

Since the amplifying unit 336 performs self oscillation and amplification in this way, the microwave generating unit 110 can be simplified. Further, by using the phase shifter 362, it is possible to generate and output a plurality of microwaves.

5 is a circuit diagram briefly showing the inside of the solid state power oscillator of FIG.

5, the solid state power oscillator SSPO includes an amplification unit 336, a phase shifter 362, a first isolation unit 366, and a second isolation unit 364 .

The amplification unit 336 receives the DC power from the power supply unit 360 and performs self oscillation and amplification. That is, without performing a separate frequency oscillation section for generating and outputting the frequency oscillation signal, the frequency oscillation itself is performed according to the input of the DC power supply, and the amplification operation is performed.

The amplifying unit 336 may include at least one RF power transistor. When a plurality of RF power transistors are used, the amplifying unit 336 may be configured to be multi-stage amplification by being configured in series, parallel, serial, or parallel mixing. The amplifier 336 may be, for example, an RF power transistor. On the other hand, the output of the amplifying unit 336 may be approximately 100 to 1000W.

Next, the phase shifter 362 may shift the phase by feeding back the output of the amplifying unit 336. [ The phase shift amount may be adjusted according to the phase control signal of the control unit 310. [ As described above, the microwave of various frequencies can be generated by phase-shifting the amplified signal of the predetermined frequency outputted from the amplifier. For example, the frequency may increase in proportion to the phase shift amount.

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

The first isolation portion 364 is located between the amplification portion 336 and the directional coupler 338. When the microwave amplified by the amplification portion 336 is transmitted to the cavity 134, The microwave reflected from the cavity 134 is blocked. The first isolation portion 364 may be implemented as an isolator. The microwave reflected from the cavity 134 is absorbed by the resistance inside the first isolation portion 364 and can not enter the amplification portion 336. Thereby preventing reflected microwaves from flowing into the amplification unit 336. Specifically, the first isolation portion 364 allows the amplified microwaves to be supplied to the microwave transfer portion 112 via the directional coupler 338. Meanwhile, when the signal level of the microwave supplied from the amplifying unit 336 is lower than the set value, the first isolating unit 364 may supply the microwave to the grounding end instead of the microwave transmitting unit 112.

Next, the second isolation unit 366 supplies the phase shifted signal in the phase shifter 362 to the amplification unit 336 again. On the other hand, when the level of the phase-shifted signal in the phase shifter 362 is less than the set value, the second isolation unit 366 may supply the phase-shifted signal to the ground stage instead of the amplification unit 336.

The signal supplied from the second isolator 366 is amplified again by the amplifier 336. As a result, a plurality of microwaves having different frequencies are sequentially output.

The feedback transmission line 390 is a transmission line connecting the output end of the amplification unit 336 and the phase shifter 362. The phase shifter 362 is located in the feedback transmission line 390 and may be constituted by an impedance element such as a switch and / or a diode.

6 is a view schematically showing an antenna unit according to an embodiment of the present invention.

The antenna unit 600 may include an antenna housing 610, an antenna 620, a variable support portion 630, a first interface 640, and a guide 650.

The antenna housing 610 includes an antenna 620 having a predetermined internal space therein and capable of transmitting and receiving microwaves to and from the internal space, a variable support portion 630 capable of adjusting the length of the antenna 620, A first interface 640 positioned between the antenna 620 and the variable support portion 630 and a guide portion 650 for guiding the movement of the antenna 620 and the variable support portion 630.

The antenna housing 610 may have either a cylindrical shape or a polygonal shape, and is not limited to the drawings. The shape of the antenna 620, the variable support portion 630, and the first interface 640 may correspond to the shape of the antenna housing 610.

For example, if the antenna housing 610 is cylindrical as shown, the shape of the antenna 620 and the variable support portion 630 may be a spring shape, and the first interface 640 may be a disc shape.

The antenna 620 and the variable support portion 630 may not include the antenna housing 610. The antenna 620 and the variable support portion 630 are connected to the guide portion 650 in the longitudinal direction, The length of the antenna 620 can be changed together with the change of the length of the antenna 630.

The antenna housing 610 should be made of a material through which microwaves can pass.

The antenna 620 radiates the microwave generated by the microwave generator 110 to the cavity 134. [ The antenna 620 may be located in the inner space of the antenna housing 610 and abuts the variable support portion 630 with the first interface 640 therebetween.

When the antenna housing 610 is provided with a cylindrical shape, the antenna housing 610 has a spring shape, and the length of the antenna can be variable. In one embodiment, the antenna 620 may be a helical antenna. 6A, the length of the antenna 620 may be d1 and the length of the antenna 620 may be varied to d3 according to the length of the variable supporting portion 630. [ The antenna 620 can use a metal that is easily deformed by heat.

On the other hand, if the total length d of the antenna 620 and the variable supporting portion 630 is constant and the length of the variable supporting portion 630 is increased according to temperature or other factors, the length of the antenna 620 is reduced, Or the length of the variable support portion 630 is reduced according to other factors, the length of the antenna 620 is increased.

The antenna 620 generally resonates at a frequency having a wavelength twice as long and the input reflection coefficient S11 of the antenna 620 at the resonance has the lowest value. Depending on the temperature change inside the cavity 134, the length of the antenna 620 may vary. By varying the length of the antenna 620, it is possible to radiate a microwave having a resonance frequency at the lowest S11 characteristic value.

That is, the characteristic of the antenna 620 changes according to the change of the length of the antenna 620, and the microwave having the best heating efficiency can be emitted.

That is, an antenna including both characteristics of an antenna for defrosting a load in a cavity and an antenna for cooking can be designed and implemented. For example, in the case of a defrosting antenna, a microwave having a uniform frequency is required. In the cooking antenna, a microwave having a strong field is required in a load center that can penetrate deeply into a load. It is possible to vary the length, and it is possible to radiate microwaves appropriately in both thawing and cooking.

The variable support portion 630 may be formed by abutting the antenna 620 with the first interface 640 interposed therebetween. The variable support portion 630 may vary in length depending on temperature or other environmental changes.

For example, the variable support portion 630 may be formed of a shape memory alloy (SMA) that can vary according to a temperature change inside the cavity 134. [ That is, the antenna unit 600 may be made of a double metal or a metal of a space inside the antenna housing 610. [

The shape memory alloy (SMA) is a metal having a shape memory effect (SME: Shape Memory Effect). When a general metal material is deformed by external stress at a relatively low temperature, it exhibits elastic behavior at an initial stage, . However, in the shape memory alloy system, when the material is heated to a specific temperature or more after the external stress is applied and the permanent shape is deformed, the original shape is restored to its original shape before the deformation occurs. Such an effect is called a shape memory effect. This occurs in metals whose crystal structure is changed by martensite phase transformation.

For example, it may be a nickel-titanium (Ni-Ti) alloy or a copper-aluminum-zinc (Cu-Al-Zn) alloy. But the present invention is not limited thereto, and may include all the materials for forming the shape memory alloy.

Specifically, as the length of the variable support portion 630 made of the shape memory alloy changes, the length of the antenna 620 may also vary. The antenna 620 and the variable support portion 630 are fixed together by the guide 650, so that the lengths of the antenna 620 and the variable support portion 630 are complementary. That is, when the length of the variable supporting portion 630 is increased, the length of the antenna 620 is reduced. When the length of the variable supporting portion 630 is decreased, the length of the antenna 620 is increased.

When the temperature inside the cavity 134 becomes equal to or higher than a predetermined temperature by using the cavity heat generated by the heater when the cavity 134 is cooked or thawed, the shape memory alloy constituting the variable support portion 630 has a length So that the length of the antenna 620 also changes. The S11 characteristic value and the heating efficiency also change according to the change of the length of the antenna 620, so that the optimized uniform heating can be performed.

In addition, a plurality of variable supports 630 in the inner space of the antenna unit 600 may be provided. The antenna unit 600 may further include a second interface 642 between the variable supports 630 when there are a plurality of the variable supports 630. This will be described later with reference to FIG.

The first interface 640 may be positioned between the antenna 620 and the variable support 630. When the antenna housing 610 is cylindrical and the antenna 620 and the variable support portion 630 are spring-shaped, the first interface 640 may be in the form of a disk, as shown in the figure. However, the present invention is not limited to this, and may have various shapes corresponding to the shape of the antenna housing 610, the antenna 620, or the variable supporting portion 630. The first interface 640 only blocks the gap between the antenna 620 and the variable support portion 630 and can move in response to a change in length of the variable support portion 630 within the antenna housing 610. [

The guide 650 fixes the antenna 620 and the variable supporting portion 630 located in the inner space of the antenna portion 600 so that the antenna 620 and the variable supporting portion 630 are not separated from each other except for a predetermined path, So that the length relationship between the antenna 620 and the variable support portion 630 can be complementarily changed.

7 is a view schematically showing an antenna unit according to an embodiment of the present invention.

The description overlapping with FIG. 6 will be omitted. 7, the antenna unit 700 includes two variable supports 730 and 735, and a second interface 642 is positioned between the first variable support 730 and the second variable support 735 .

The first variable supporting portion 730 and the second variable supporting portion 735 may be made of different shape memory alloys. Therefore, the lengths of the first variable supporting portion 730 and the second variable supporting portion 735 may be different from each other depending on the temperature. Accordingly, the length of the antenna 620 can be changed to three. For example, as the temperature changes from room temperature to a temperature at which the shape memory alloy constituting the first variable supporting portion 730 changes and a shape at which the shape memory alloy constituting the second variable supporting portion 735 changes, the antenna 620 ) Can have three kinds of lengths. Therefore, if the number of the variable supports 730 and 735 is N according to the number of the variable supports 730 and 735, the antenna 620 can be changed into N + 1 kinds of lengths. If the length of the antenna 620 can be varied, the number of frequencies that can be resonated also increases, and the heating efficiency can be increased.

For example, if the lengths of the antenna 620, the first variable supporting portion 730 and the second variable supporting portion 735 before the heating of the cavity 134 are d5, d6, and d7, respectively, , d5 and d7 are changed, and when the temperature becomes a predetermined temperature at which d7 can change, d5 and d6 may change. However, the sum of the lengths of the antenna 620, the first variable supporting portion 730 and the second variable supporting portion 735 is constant d.

8 to 9 are views illustrating an antenna unit according to an embodiment of the present invention.

The cooking apparatus according to the embodiment includes a microwave generating unit 110 for generating a microwave and outputting the microwave into the cavity 134 and an antenna unit 800 for radiating the generated microwave into the cavity 134, The antenna unit 800 may include an antenna 810 and a variable support portion 820.

The antenna unit 800 includes an antenna 810 and a variable support portion 820 disposed on an upper surface or a lower surface of the antenna 810. The thermal expansion coefficient of the antenna 810 is different from the thermal expansion coefficient of the variable support portion 820 and has a bimetallic structure as the antenna 810 and the variable support portion 820 are bonded.

Bimetal is a rod-shaped part made up of two sheets of thin metal plates with very different thermal expansion coefficients and made into a single piece, which can be controlled according to the temperature by utilizing the bending properties when heat is applied.

The antenna portion 810 and the light supporting portion 820 can be bent up and down by the heat generated as the interior of the cavity 134 is heated by forming the antenna portion 800 in a bimetal form.

As the temperature rises, the larger the thermal expansion coefficient, the more it swells and turns to the opposite side. And when the temperature drops again, it returns to its original state. The metal which can not be inflated is an alloy of nickel (Ni) and iron (Fe), and the metal which is swollen well is an alloy of nickel-manganese-iron, an alloy of nickel-molybdenum-iron, Copper alloy and so on.

For example, when a metallic plate-shaped variable support portion 820 made of a metal having a coefficient of thermal expansion larger than that of the metal constituting the antenna 810 is located on the upper portion of the metal plate type antenna 810, The antenna 810 is bent toward the antenna 810. As shown in Fig.

Conversely, when the metal plate type variable supporting portion 820 made of a metal having a coefficient of thermal expansion larger than that of the metal constituting the antenna 810 is located below the metal plate type antenna 810, the temperature inside the cavity 134 And is bent toward the variable supporting portion 820 according to the rising.

In other words, the shape of the antenna can be changed in accordance with the temperature change inside the cavity 134, and the microwave having the high heating efficiency can be emitted corresponding to the change of the S11 characteristic value. Therefore, the food can be uniformly heated and energy efficiency can be increased.

Specifically, the capacitance value changes according to the bending of the antenna, and the resonance point changes accordingly.

Meanwhile, although the cooking apparatus according to the embodiment of the present invention has been described mainly with reference to a microwave cooking apparatus, the present invention is not limited thereto and various cooking apparatuses can be combined with each other. For example, a cooking appliance using microwave according to the embodiment of the present invention may be incorporated into an oven-type cooking appliance using a heater as a heating source. As another example, a cooking appliance using microwave according to the embodiment of the present invention may be incorporated into a cooking appliance using an induction heating heater as a heating source. As another example, as a heating source, a cooking device using microwaves according to an embodiment of the present invention may be combined with a cooking device using a magnetron.

The cooking apparatus according to the present invention is not limited to the configuration and the method of the embodiments described above, but the embodiments may be modified so that all or some of the embodiments are selectively combined .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

100, 600: Cooking appliance 110: Microwave generator
112: microwave transmission unit 114: power supply unit
134: cavity 310:
338: directional coupler 342: first power detector
346: second power detecting section 364: second isolating section
350 microwave control unit 336 amplification unit
360: Power section 362: Phase shifter
610: antenna housing 620, 810: antenna
630, 820: variable support 640: first interface
650: guide portion 642: second interface
800:

Claims (17)

A microwave generating unit for generating a microwave and outputting the generated microwave into the cavity;
And an antenna unit for radiating the generated microwave into the cavity,
Wherein the antenna portion includes at least one variable support portion, at least one antenna, and a first interface between the variable support portion and the antenna, wherein the antenna corresponds to a change in the shape of the variable support portion. The method according to claim 1,
The antenna unit includes:
Further comprising: an antenna housing having the antenna and the variable support portion therein. 3. The method of claim 2,
The antenna housing includes:
Wherein the microwave is one of a cylindrical or a polygonal column. delete The method according to claim 1,
The antenna unit includes:
And a second interface between the variable support portions when the variable support portion is a plurality of the variable support portions. The method of claim 3,
Wherein the shape of the antenna, the variable support, and the first interface is a microwave corresponding to the shape of the antenna housing. The method according to claim 1,
Wherein the variable supporting portion has a variable length depending on the temperature. The method according to claim 1,
Wherein the sum of the lengths of the antenna and the variable supporting portion is constant. The method according to claim 1,
The length of the antenna,
And the length of the variable support portion varies depending on the length of the variable support portion. The method according to claim 1,
Wherein the antenna is a helical antenna. The method according to claim 1,
The variable-
Wherein the shape memory alloy is a shape memory alloy. 12. The method of claim 11,
In the shape memory alloy,
Nickel-titanium alloy or copper-aluminum-zinc alloy. The method according to claim 1,
The antenna includes:
Wherein the heating element is any one of zinc, aluminum, and copper, or an alloy thereof. The method according to claim 1,
The antenna unit includes:
And a guide portion for guiding movement of the antenna and the variable support portion. The method according to claim 1,
Wherein the antenna unit is a bimetal. The method according to claim 1,
Wherein the variable support portion is disposed at an upper portion or a lower portion of the antenna. 17. The method of claim 16,
The coefficient of thermal expansion of the variable-
Wherein the coefficient of thermal expansion of the antenna is larger than the thermal expansion coefficient of the antenna.

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