KR100739542B1 - Heating device using microwave - Google Patents

Abstract

A heating device using microwaves is provided to improve a door filter structure to effectively deal with a push leak of the heating device, and to make a door filter for shielding the microwaves compact. A heating device using microwaves includes a case(100), a heating chamber(110), and a front panel(120). The case contains the heating chamber for accommodating foods. The heating chamber has an opening formed at its front surface and through which the foods enter. The front panel is installed at a front surface of the case to surround the opening of the heating chamber. The case includes a control panel(130) installed at an outer surface thereof to control the heating device. A microwave supply device is installed between the case and the heating chamber to radiate microwaves into the heating chamber.

Description

Heating device using microwaves {Heating device using microwave}

1 is a schematic view showing the configuration of a heating apparatus using microwaves according to an embodiment of the present invention;

FIG. 2 is a perspective view showing the door of the heating device of FIG. 1 closed; FIG.

3 is a cross-sectional view taken along line II ′ of FIG. 2;

4A is a partial perspective view of a filter according to an embodiment of the present invention;

4B is a side view of FIG. 4A;

5A is a partial perspective view of a filter according to another embodiment of the present invention; And

5B is a side view of FIG. 5A.

Explanation of symbols on the main parts of the drawings

100: case 110: heating chamber

120: front panel 130: control panel

140: microwave supply device 150: heater

200: door 230: viewing window

240: porous screen 250: glass

300: filter 310: groove

320: main cavity 330: first choke seal

340: second choke seal 350: auxiliary cavity

360: dielectric 370: partition plate

The present invention relates to a heating device, and more particularly to a heating device configured to heat an object using microwaves.

A typical electric device configured to heat an object using microwaves is a microwave oven. A typical microwave oven is irradiated by guiding a heating chamber formed therein, a door provided at the front of the microwave oven to open and close the front of the heating chamber, a magnetron that oscillates microwaves, and microwaves generated by the magnetrons into the heating chamber. Which comprises a waveguide. Microwaves irradiated into the heating chamber by the magnetron and the waveguide cause vibration of water molecules of an object located in the heating chamber, for example, food, and the heating object is heated by the kinetic energy of the vibrating water molecules. .

In order to allow a user to look into the heating chamber, the door is generally provided with a see-through window, and the see-through window is provided with a screen for preventing leakage of microwaves. The screen has a plurality of holes smaller than a predetermined size, for example less than one quarter of the wavelength of the microwave, so that the user can look inside the heating chamber through the small holes of the porous screen mounted to the viewing window. have.

Meanwhile, when the heating object is heated using the microwave, the microwave may leak through a gap between the door and the case of the heating device. Accordingly, a filter for preventing leakage of microwaves irradiated into the heating chamber is provided around the door. The filter typically uses a cavity and LC circuit system to prevent leakage of microwaves between the door and the front panel.

A typical filter is arranged between, for example, a plurality of choke seals, which extend from a door frame of conductor material to form the cavity between the door frame, and between the choke seals. Slots are included. An inductance "L" is formed in the choke seal surrounding the cavity, between the choke seal and the front panel of the microwave oven, between the choke seals, and at the end of the choke seal and the door frame. The capacitance "C" (capacitance "C") is formed in between. Accordingly, the microwaves incident on the filter are attenuated by resonance by the cavity and the LC circuit system, thereby suppressing the leakage of microwaves through the gap between the case and the door.

Recently, glass is mounted on the inner surface of the door to improve the cleaning property of the inner surface of the door. In this case, the gap between the door and the front panel is increased by the thickness of the glass. Therefore, it is difficult to effectively cope with the microwave leakage of the heating device having a large gap between the door and the front panel by the conventional filter structure alone.

On the other hand, the filter for shielding the microwave using the cavity and the LC circuit system as described above shows a normal shielding performance when the door is normally closed. However, when the door is pulled slightly, the gap between the door and the front panel is increased, so that the amount of leakage of microwaves through the enlarged gap increases. This is commonly referred to as "pull leakage," and it is difficult to effectively cope with such pull leakage with a conventional filter structure.

In order to effectively reduce the microwave leakage of the heating device with a large gap between the door and the front panel, and to effectively cope with the "pull leakage", a filter having a plurality of cavities arranged in parallel is required. However, if the filter has a plurality of cavities as described above, the size thereof is inevitably large.

The present invention has been made to solve the above problems, and an object thereof is to improve a door filter structure of a heating apparatus using microwaves so that it can be effectively applied to a product having a large gap between the door and the front panel.

Another object of the present invention is to improve the door filter structure of a heating apparatus using microwaves so as to effectively cope with pull leakage.

Another object of the present invention is to compact a door filter for shielding microwaves.

In one embodiment of the present invention for achieving the above object, a door for opening and closing the heating chamber to which the microwave is irradiated; At least one main cavity disposed in the door so as to surround the entrance of the heating chamber when the door is closed, and resonating and attenuating the microwaves; The present invention provides a heating apparatus using microwaves, which includes an auxiliary cavity filled with a dielectric and disposed inside the main cavity to resonate and attenuate the microwaves independently of the main cavity.

The auxiliary cavity may be disposed a predetermined height away from the bottom of the main cavity. In addition, the auxiliary cavity may have a smaller width and height than the main cavity. Preferably, the inside of the main cavity and the inside of the auxiliary cavity are isolated from each other. A plurality of main cavities may be arranged in parallel to the door. The auxiliary cavity may be provided in each of the main cavities.

According to another aspect of the present invention for achieving the above object, a door for opening and closing a heating chamber to which microwaves are irradiated; An elongated groove formed in the door to surround the entrance of the heating chamber when the door closes the heating chamber; A first choke seal extending from the door to cover a portion of the opening of the groove so that a main cavity for resonance of the microwave is formed in the groove; A second choke seal extending from one wall of the groove to form an auxiliary cavity for resonance of the microwaves in the main cavity; And it provides a heating device using a microwave including a dielectric provided in the auxiliary cavity.

According to another aspect of the present invention for achieving the above object, a door for opening and closing the heating chamber in the case to which the microwave is irradiated; An elongated groove formed in the door to surround the entrance of the heating chamber when the door closes the heating chamber; A partition plate disposed in the groove to divide the inner space of the groove into two main cavities for continuous resonance of the microwaves; A first choke seal extending from the wall of the groove or the partition plate to cover a portion of the openings of the main cavities; A second choke seal extending from a wall of the groove or the partition plate and forming an auxiliary cavity for resonance of the microwaves in at least one of the main cavities; And it provides a heating device using a microwave including a dielectric provided in the auxiliary cavity.

The second choke seal may have a curved shape after extending toward the opposite side in the middle of at least one of the wall of the groove or the partition plate. Preferably, the second choke seal is continuously formed along the longitudinal direction of the groove to isolate the main cavity and the auxiliary cavity from each other. The first choke seal and the second choke seal may be disposed to face each other.

DETAILED DESCRIPTION Hereinafter, embodiments of the present invention in which the above object can be specifically realized are described with reference to the accompanying drawings. In describing the embodiments, the same names and symbols are used for the same components, and additional description thereof will be omitted below.

1 is a schematic view showing a heating apparatus using a microwave according to an embodiment of the present invention, Figure 2 is a perspective view showing a state in which the door of the heating device of Figure 1 is closed. Hereinafter, a structure of a heating apparatus using microwaves according to an embodiment of the present invention will be described with reference to these drawings.

Inside the case 100 forming the exterior of the heating device is provided with a heating chamber 110 for receiving a heating object, for example, food. An inlet for accessing the inside of the heating chamber 110 is formed on one surface, for example, the heating chamber 110, and the front of the case 100 surrounds the inlet of the heating chamber 110. The front panel 120 is provided.

The outer surface of the case 100 is provided with a control panel 130 for controlling the heating device, the control panel 130 is, for example, as shown in Figures 1 and 2 the case 100 It can be located above the front of the. Without being limited to this, the control panel 130 may be disposed at another location in consideration of the installation location of the heating device and the user's convenience.

Between the case 100 and the heating chamber 110, a microwave supply device 140 for irradiating microwaves into the heating chamber 110 is provided. The microwave supply device 140 includes, for example, a magnetron 141 for generating microwaves, and a waveguide 143 for guiding and irradiating the microwaves generated by the magnetron 141 to the heating chamber 110. Can be done. Here, the magnetron 141 oscillates microwaves, for example, in the frequency band between 2.4 GHz and 2.5 GHz, preferably in the 2.45 GHz frequency band.

Microwaves oscillated by the magnetron 141 are irradiated into the heating chamber 110 through the waveguide 143. The microwave may be irradiated into the heating chamber 110 in a simple pattern. In this case, the heating object located in the heating chamber 110 may not be evenly heated.

In order to compensate for this, a rotating tray (not shown) may be provided at the bottom of the heating chamber 110. Then, the heating object is placed on the tray is rotated can be more evenly heated. Furthermore, a stirrer fan may be further provided in the waveguide 143 or the heating chamber 110 to scatter microwaves to be irradiated. Then, the microwave is irradiated into the heating chamber 110 in a more complex and various patterns, it is possible to evenly heat the heating object.

The microwave supply device 140 is not limited to the structure described above, and any other modification or technique currently available that can be irradiated into the heating chamber 110 after generating the microwave may be employed.

The microwave irradiated into the heating chamber 110 vibrates water molecules included in the heating object to heat the heating object. Such a heating method alone is difficult to provide an optimal cooking service for each of the various types of food. Therefore, the heating apparatus according to the present invention may not only provide an optimal cooking service for each of various kinds of foods but also be further provided with additional heating means for increasing the types of cookable dishes.

An example of the additional heating means is a heat source for providing radiant heat to the heating chamber 110, for example a heater 150. 1 illustrates an example in which the heater 150 is disposed on the ceiling side of the heating chamber 110, but is not limited thereto. As another example, the heater 150 may be selectively provided on a side surface, a rear surface, or a bottom surface of the heating chamber 110. When additional heat sources providing radiant heat are provided, not only can additional cooking services such as baking and confectionery baking be provided, but also optimum cooking service can be provided by appropriately combining the supply of microwave and the amount and time of radiant heat. It may be provided.

A door 200 for opening and closing the inlet of the heating chamber 110 is mounted to the case 100 by the hinge assembly 101. FIG. 1 shows an example in which the door 200 is configured to open and close while rotating downwardly about a hinge assembly 101 fixed to a lower side of the case 100. However, the position of the hinge assembly 101 and the rotation direction of the door 200 may be changed in consideration of the user's convenience. For example, the hinge assembly 101 may be fixed to the side surface of the case 100 and the door 200 may be configured to be opened or closed while rotating the door assembly 200 in the left and right directions with respect to the hinge assembly 101. 3 illustrates the structure of the door 200 according to the present invention in detail. Hereinafter, the door 200 will be described in detail with reference to the door 200.

The outer surface of the door 200 forms a front surface of the heating device together with the control panel 130 when the door 200 is closed, and the door 200 is closed to improve the aesthetics of the heating device. When pressed, it forms substantially the same plane as the control panel 130. A handle 201 for a user may be provided on an outer surface of the door 200.

In the center portion of the door 200 facing the heating chamber 110 when the door 200 closes the heating chamber 110, a user heats the heating object 110 when the door 200 is heated. A viewing window 230 is provided to look inside. The viewing window 230 is provided with a screen 240 made of a conductor material for preventing microwaves in the heating chamber 110 from leaking to the outside through the viewing window 230. Since a plurality of holes are formed in the screen 240 as shown in FIG. 3, the user can see the inside of the heating chamber 110 through the holes of the screen 240. Since the hole of the screen 240 has a predetermined size, for example, a size equal to or less than one quarter of the wavelength of the microwave, the microwave irradiated into the heating chamber 110 may cause the hole of the screen 240 to break. It does not leak outside.

When the door 200 is closed, the inner edge of the door 200 faces the front panel 120 of the case 100 with a predetermined gap therebetween as shown in FIG. 3. Even when the door 200 is closed, microwaves irradiated into the heating chamber 110 may leak to the outside through the gap with the door 200. Therefore, the heating apparatus according to the present invention is provided with a filter 300 for suppressing the leakage of the microwaves. The filter 300 is disposed to surround the inlet of the heating chamber 110 when the door 200 closes the heating chamber 110, and the microwaves are formed using a cavity and an LC circuit system. By resonating and attenuating, leakage of the microwaves is prevented.

Effectively preventing contaminants generated when the heating object, for example, food, is heated by microwaves from being caught on the screen 240 and the filter 300 of the door 200 and cleaning the inner surface of the door 200. In order to improve the performance, the glass 250 may be provided on the inner surface of the door 200. The glass 250 forms an inner surface of the door 200 as shown in FIG. 3. The central portion of the glass 250 covers the screen 240 as shown in FIG. 3, and the edge portion of the glass 250 covers the filter 300. Therefore, since the screen 240 and the filter 300 are protected from the contaminants of the heating chamber 110 by the glass 250, the screen 240 and the filter 300 may be always kept clean. In addition, even if the pollutant generated when the heating object is heated moves to the door 200 and is attached to the glass 250, it may be easily cleaned.

When the glass 250 is provided as above, the gap between the door 200 and the front panel 120 is increased. In addition, the gap between the door 200 and the front panel 120 increases even when the door 200 is slightly pulled out. Accordingly, the present invention provides a filter 300 having an improved structure that can be effectively applied to the above cases.

The filter 300 according to the present invention comprises a main cavity and a secondary cavity. The main cavity is disposed along the inner edge of the door 200 to surround the entrance of the heating chamber 110 when the door 200 is closed, and resonates and attenuates the microwaves. The auxiliary cavity is disposed inside the main cavity and occupies a portion of the main cavity. The auxiliary cavity is filled with a dielectric therein and attenuates the microwaves independently of the primary cavity.

The dielectric may be formed, for example, of a synthetic resin having a high dielectric constant. When the dielectric is installed in the auxiliary cavity, the size of the auxiliary cavity can be reduced. For reference, when a microwave passes through a dielectric having a higher dielectric constant than air, the wavelength is known to be shortened, thereby reducing the size of the resonant cavity whose size is determined according to the wavelength of the microwave.

Since a conventional filter generally has one cavity, the gap between the door 200 and the front panel 120 is vulnerable to a large product or pull leakage. Therefore, the conventional filter was also designed to have two cavities arranged in parallel to compensate for this. That is, the amount of microwave leakage is reduced by resonating the microwaves traveling outside through the gap in the heating chamber 110 using two cavities. However, this has the problem that the size of the filter becomes large as described above.

On the other hand, according to the present invention, as described above, the auxiliary cavity is provided inside the main cavity. Since the dielectric is provided inside the auxiliary cavity, the size of the auxiliary cavity is considerably smaller than that of the main cavity, so that the auxiliary cavity is substantially different from that of the conventional door filter. It can be located within the cavity. Microwaves are attenuated by resonating through the main cavity and attenuated by resonating secondary through the auxiliary cavity. Therefore, according to the present invention, even a filter having substantially the same size as a conventional filter can be attenuated by a double resonance of the microwave. As a result, it is possible to implement a compact filter structure while effectively coping with a large gap between the door and the front panel and preventing pull leakage.

4A and 4B show a filter 300 according to an embodiment of the present invention having the primary cavity and the secondary cavity. Hereinafter, the structure of the filter 300 according to an embodiment of the present invention will be described with reference to these drawings.

As shown in Figure 4a, the inner surface of the door 200 is provided with a groove 310 formed along the edge. The groove 310 surrounds the entrance of the heating chamber 110 as well as facing the front panel 120 of the case 100 when the door 200 closes the heating chamber 110. The inner space of the groove 310 forms the main cavity 320, and the inner wall and the bottom of the groove 310 made of a conductor have an inductance "L" (inductance), which is one element for resonance of the microwave. Form.

In the door 200, the first choke seal 330 extends to partially cover the inner space of the groove 310, that is, the opening of the main cavity 320. The first choke seal 330 extends from the top of one wall of the groove 310 toward the opposite wall, for example, to cover a portion of the opening of the groove 310 so that the main choke seal 330 is in the interior of the groove 310. The cavity 320 is formed. In addition, the first choke seal 330 made of a conductor itself forms the inductance. An end of the first choke seal 330 may be bent downward toward the bottom of the groove 310 as shown in FIGS. 4A and 4B.

The first choke seal 330 is discontinuously formed along the longitudinal direction of the groove 310, for example, as shown in FIG. 4A. More specifically, the slots 335 are disposed at equal intervals between the first choke seals 330 along the longitudinal direction of the groove 310. The slot 335 forms a capacitance "C" (capacitance) which is another factor for resonating the microwaves.

For reference, the capacitance may be formed between two conductors disposed apart from each other. Thus, the capacitance may be formed between the first choke seal 330 and the front panel 120 when the door 200 is closed, and the first choke seal 330 and the groove 310 It may also be formed between the inner wall of the). On the other hand, although not shown, the first choke seal 330 may be continuously formed along the longitudinal direction of the groove 310 without the slot 335.

In the inner wall of the groove 310, for example, a wall facing the first choke seal 330, a second choke seal 340 extends to allow the dual resonance of the microwave inside the main cavity 320. The auxiliary cavity 350 is formed. The dielectric 360 is filled in the auxiliary cavity 350. The second choke seal 340 extends from the middle of the wall of the groove 310 to the opposite side and has a shape bent upwardly, for example, an “L” shape, the inner surface of the groove 310 and the groove 310. The auxiliary cavity 350 is defined by the wall of the.

As shown in FIGS. 4A and 4B, the auxiliary cavity 350 is disposed at a predetermined height away from the bottom of the main cavity 320, that is, the bottom of the groove 310. In addition, the width and height of the auxiliary cavity 350 are designed to be much smaller than the width and height of the main cavity 320 by the dielectric 360. Meanwhile, the primary cavity 320 and the secondary cavity 350 may be isolated from each other so that the microwaves resonate independently of each other. To this end, as illustrated in FIG. 4A, the second choke seal 340 is continuously formed along the longitudinal direction of the groove 310.

After being irradiated to the heating chamber 110, microwaves moving through the gap between the door 200 and the front panel 120 may be formed in the groove 310, the first choke seal 330, and the second microwave. The primary cavity is resonated through the main cavity 320 defined by the choke seal 340. The microwave then resonates once more in the auxiliary cavity 350. As a result, leakage of microwaves through the gap is effectively prevented. Since the resonance principle of the microwave itself is known, a description thereof will be omitted.

4A and 4B, the first choke seal 330 is disposed adjacent to the heating chamber 110 when the door 200 is closed, and the second choke seal 340 is disposed in the heating chamber 110. An example away from is shown. Therefore, the microwave of the heating chamber 110 passes through the main cavity 320 and proceeds toward the auxiliary cavity 350. However, although not shown, the positions of the first choke seal 330 and the second choke seal 340 may be interchanged. In this case, the microwave of the heating chamber 110 will resonate first through the auxiliary cavity 350, and then proceed toward the main cavity 320 to resonate secondarily.

As described above, the filter 300 shown in FIGS. 4A and 4B can resonate microwaves twice while having substantially the same size as a conventional filter with one cavity. Therefore, the gap between the door 200 and the front panel 120 can be effectively applied to a large product and to prevent pull leakage.

The above describes a filter with one main cavity. However, the present invention is not limited thereto and may be implemented in embodiments having a plurality of main cavities. Of course, even in this case, the filter according to the present invention has a structure capable of resonating microwaves multiple times while having substantially the same size as a conventional filter having a plurality of cavities.

In this embodiment, at least two primary cavities are disposed in parallel along the inner edge of the door 200, and the auxiliary cavities are provided inside at least one of the plurality of primary cavities. Of course, the secondary cavity may be provided to each primary cavity, respectively. The structure of the filter 300 according to the second embodiment of the present invention having such a structure is shown well in Figs. 5A and 5B. Hereinafter, the structure of the filter according to the second embodiment of the present invention will be described with reference to the figure.

The grooves 310 of FIGS. 4A and 4B provide an interior space for one main cavity, while the grooves 310 of FIGS. 5A and 5B have a plurality of, for example, two main cages arranged in parallel. Provide an interior space for vertices 320. A partition plate 370 is installed inside the groove 310, and the partition plate 370 is, for example, as shown in FIGS. 5A and 5B, along the longitudinal direction of the groove 310. Disposed at the center of 310. The groove 310 disposed as described above divides the internal space of the groove 310 into two independent main cavities 320.

The first choke seal 330 and the second choke seal 340 are provided on both sides of the partition plate 370 so as to have symmetrical structures as shown in FIG. 5B. For example, when the door 200 is closed, a structure substantially the same as the structure described with reference to FIGS. 4A and 4B may be implemented on the side adjacent to the heating chamber 110, and the heating chamber 110 may be implemented. On the far side with respect to the partition plate 370 may be implemented a structure symmetrical with the side adjacent to the heating chamber 110.

In the above case, the microwave of the heating chamber 110 resonates in quadruple while sequentially passing through the main cavity 320, the auxiliary cavity 350, the auxiliary cavity 350, and the main cavity 320. Will be attenuated. However, the above structure can be changed. As another example, the filter 300 such that the microwave is attenuated in quadruple while sequentially passing through the auxiliary cavity 350, the main cavity 320, the main cavity 320, and the auxiliary cavity 350. May be designed. As another example, the filter 300 may be designed such that both attenuation structures of the partition plate 370 are not symmetrical with respect to each other, and one of the two main cavities 320 may have the auxiliary cavity. 350 may not be provided. Of course, the width of the groove 310 is formed to be wider, and two or more partition plates 370 are installed in the groove 310 such that at least three or more main cavities 320 are disposed in parallel. May be designed.

Although some embodiments have been described above by way of example, it will be apparent to those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope thereof. Accordingly, the described embodiments are to be considered as illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are included within the scope of the present invention.

As described above, according to the present invention, a microwave having a filter substantially the same size as a conventional filter can resonate microwaves multiplely. Therefore, the gap between the door and the front panel of the case can be effectively applied to the product and can effectively cope with the pull leakage prevention. Yet a compact filter can be realized.

Claims (13)

A door for opening and closing a heating chamber to which microwaves are irradiated; At least one main cavity disposed in the door so as to surround the entrance of the heating chamber when the door is closed, and resonating and attenuating the microwaves; And And an auxiliary cavity filled with a dielectric and disposed inside the main cavity to resonate and attenuate the microwaves independently of the main cavity. The method of claim 1, The auxiliary cavity is a microwave heating device, characterized in that arranged in a predetermined height away from the bottom of the main cavity. The method of claim 1, And the auxiliary cavity has a width and a height smaller than that of the main cavity. The method of claim 1, And the inside of the main cavity and the inside of the auxiliary cavity are separated from each other. The method of claim 1, The main cavity is a heating device using a microwave, characterized in that a plurality of arranged in parallel to the door. The method of claim 5, The auxiliary cavity is a heating device using a microwave, characterized in that each provided in the main cavity. A door for opening and closing a heating chamber to which microwaves are irradiated; An elongated groove formed in the door to surround the entrance of the heating chamber when the door closes the heating chamber; A first choke seal extending from the door to cover a portion of the opening of the groove so that a main cavity for resonance of the microwave is formed in the groove; A second choke seal extending from one wall of the groove to form an auxiliary cavity for resonance of the microwaves in the main cavity; And Heating device using a microwave including a dielectric provided in the auxiliary cavity. A door for opening and closing a heating chamber in a case to which microwave is irradiated; An elongated groove formed in the door to surround the entrance of the heating chamber when the door closes the heating chamber; A partition plate disposed in the groove to divide the inner space of the groove into two main cavities for continuous resonance of the microwaves; A first choke seal extending from the wall of the groove or the partition plate to cover a portion of the openings of the main cavities; A second choke seal extending from a wall of the groove or the partition plate and forming an auxiliary cavity for resonance of the microwaves in at least one of the main cavities; And Heating device using a microwave including a dielectric provided in the auxiliary cavity. The method of claim 7, wherein And the second choke seal extends to the opposite side in the middle of one wall of the groove and is bent. The method of claim 8, And the second choke seal has a shape that is bent after extending in the middle of at least one of the wall of the groove or the partition plate. The method according to claim 7 or 8, And the second choke seal is continuously formed along the longitudinal direction of the groove to isolate the main cavity and the auxiliary cavity from each other. The method according to claim 7 or 8, And the first choke seal and the second choke seal are disposed to face each other. The method according to any one of claims 1, 7, and 8, And a glass forming the inner surface of the door and covering the main cavity and the auxiliary cavity.

Images