KR100710234B1 - Microwave heating device - Google Patents

Abstract

The present invention relates to a heating device configured to heat an object using microwaves. The heating apparatus according to the present invention comprises: a case having a heating chamber to which microwaves are irradiated and having a front panel surrounding an inlet of the heating chamber; A door for opening and closing the heating chamber; A stepped portion formed on the front panel and having a front portion facing the inner surface of the door and a side portion facing the side of the door; And a filter formed at the side of the door, the inlet of which is disposed toward the side of the step part to attenuate the leaked microwaves. According to the present invention, the cleaning property of the door is improved, the microwave shielding performance is also improved, and the microwave shielding performance can be kept constant regardless of the movement of the door.

Heating device, microwave, door, filter, shielded, glass, groove, LC circuit, resonant

Description

Heating device using microwaves {Microwave heating device}

1 is a perspective view showing an open state of a door of a heating apparatus using microwaves according to the present invention;

2 is a perspective view showing a state in which the door of the heating device of Figure 1 is closed;

3 is a partial sectional view showing a first embodiment of a filter of a heating apparatus according to the present invention;

4 is a partial sectional view showing a second embodiment of a filter of a heating apparatus according to the present invention; And

Fig. 5 is a partial sectional view showing a third embodiment of a filter of the heating apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

100: case 110: heating chamber

120: front panel 140: microwave supply device

150: heater 160: stepped portion

161: front portion 163: side portion

200: doors 250a, 250b: glass

260, 270: extension 300: filter

310: home 311: inner wall

311a, 315a: protrusion 313: bottom

315: outer wall

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 includes a heating chamber formed inside the case, a door provided at the front of the microwave oven to open and close the front surface of the heating chamber, a magnetron that oscillates microwaves, and guide the microwaves generated by the magnetrons into the heating chamber. It consists of a waveguide to irradiate. 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. .

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. Therefore, the door is provided with a filter for preventing the leakage of microwaves irradiated into the heating chamber.

The filter, for example, is formed along the inner edge of the door and is disposed to face the front panel of the case surrounding the heating chamber when the door is closed. The filter is provided with a groove into which the microwave is incident, and the microwave incident into the groove is attenuated by a kind of LC circuit formed by a structural feature of the filter.

On the other hand, contaminants such as oil or seasoning that evaporate when the food is heated may be attached to the filter. However, since the filter has the groove, it is difficult to clean, and thus the hygiene and aesthetics of the heating device are not good. In addition, when a large amount of contaminants are caught in the filter, the microwave shielding performance of the filter may be reduced.

Therefore, in order to increase the cleaning property of the door, a glass may be mounted on the inner surface of the door to cover the entire surface of the door and the filter. However, in this case, the gap between the door and the front panel is increased by the thickness of the glass, so that the filter cannot effectively reduce the leakage of microwaves.

When the glass is mounted on the door as described above, the middle portion of the glass directly contacts the inside of the high temperature heating chamber, and the edge portion of the glass faces the front panel of the case. Therefore, the temperature difference between the middle part and the edge part of the glass is large, and the glass is easily deformed. When the glass is deformed, the gap between the door and the front panel of the case may be further widened. In this case, the microwave shielding performance of the filter may be further deteriorated.

The present invention has been made to solve the above problems, and an object thereof is to improve the cleanability of the door and the microwave shielding performance.

In one embodiment of the present invention for achieving the above object, a case having a heating chamber to which microwaves are irradiated is provided, and having a front panel surrounding an inlet of the heating chamber; A door for opening and closing the heating chamber; A stepped portion formed on the front panel and having a front portion facing the inner surface of the door and a side portion facing the side of the door; And it is provided on the side of the door, the inlet is disposed toward the side of the step portion provides a heating device using a microwave comprising a filter for attenuating the leaked microwave.

Here, the plurality of filters may be continuously formed on the side of the door in the direction in which the door is opened and closed. The filter may be installed to directly face the front portion of the stepped portion with a narrow gap therebetween.

The heating device may further include a glass mounted on an inner surface of the door. Here, the glass may be installed so that the edge thereof faces the heating chamber. The filter may be installed such that the sealed portion faces the front portion of the stepped portion with a narrow gap therebetween without interposing the glass. The heating device may further include an extension part extending from the filter to hold and fix the edge of the glass.

The heating device may further include an extension part extending from the filter to face the inner wall of the heating chamber to reduce leakage of the microwaves.

On the other hand, in another embodiment of the present invention for achieving the above object, a heating chamber to which microwaves are irradiated; A door for opening and closing the heating chamber; A front part extending from an inner wall of the heating chamber and facing an inner surface edge of the door; A side portion extending from the front portion substantially parallel to the opening and closing direction of the door; And provided in the door, the closed portion facing the front portion and the inlet is provided toward the side portion to provide a heating apparatus using a microwave comprising a filter for attenuating the leaked microwave.

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.

As shown in FIG. 1, a heating chamber 110 in which a heating object, for example, foods, is accommodated is provided in the case 100 that forms the exterior of the heating apparatus. 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.

As shown in FIG. 1, the front panel 120 of the case 100 includes a stepped portion 160 formed to be recessed into the heating chamber 110 to surround the entrance of the heating chamber 110. For example, the stepped portion 160 has an approximately "L" shape. The front portion 161 of the stepped portion 160 extends in a substantially vertical bent state on the inner wall 110a of the heating chamber 110 and is disposed to face the front surface of the heating device. The side portion 163 of the stepped portion 160 extends in a substantially vertical bent state at the end of the front portion 161 and is disposed substantially parallel to the inner wall 110a of the heating chamber 110.

The outer surface of the case 100 is provided with a control panel 130 for controlling the heating device, as shown in Figures 1 and 2, the control panel 130, for example of the case 100 It can be located above the front. The control panel 130 is not limited to the positions shown in FIGS. 1 and 2, and may be disposed in other positions in consideration of the installation position 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 in the frequency band of 2.4 GHz to 2.5 GHz, preferably 2.45 GHz.

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 the side surface, the rear surface, or the 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.

As shown in FIGS. 1 and 2, the door 200 may be provided with a viewing window 205 so that a user may see the inside of the heating chamber 110. The see-through window 205 is formed at the center of the door 200, and a porous screen (not shown) is disposed on the see-through window 205 so that microwaves radiated into the heating chamber 110 do not leak to the outside through the see-through window 205. Is installed. Therefore, the user may look inside the heating chamber 110 even during the heating of the heating object through the plurality of holes formed in the screen.

The door 200 includes, for example, an outer frame 210 and an inner frame 220 as shown in FIG. 1. As illustrated in FIG. 2, the outer frame 210 forms the front surface of the heating device together with the control panel 130 when the door 200 is closed.

The inner frame 220 of the door 200 is smaller in size than the outer frame 210 as shown in FIG. 1, and protrudes toward the heating chamber 110 from the rear surface of the outer frame 210. A central portion of the inner frame 220 faces the heating chamber 110 when the door 200 is closed, and an edge of the inner frame 220 is closed when the door 200 is closed. 3 to 5 are accommodated in the free space formed by the stepped portion 160 of the front panel 120.

In the state in which the door 200 is closed, an inner surface of the door 200, more specifically, an inner edge of the inner frame 220 faces the front part 161 of the stepped part 160, and The side of the door 200, more specifically, the side of the inner frame 220 faces the side portion 163 of the stepped portion 160. The front portion 161 of the stepped portion 160 is disposed substantially perpendicular to the direction in which the door 200 is opened and closed, while the side portion 163 of the stepped portion 160 has the door 200 It is arranged substantially parallel to the opening and closing direction. Accordingly, the gap between the front part 161 and the inner surface of the door 200 is sensitively changed according to the movement of the door 200, while the gap between the side part 163 and the side surface of the door 200 is changed. The gap remains substantially the same regardless of the movement of the door 200.

In order to maintain a constant performance of shielding microwaves, the filter 300 of the heating apparatus according to the present invention, as shown in Figures 3 to 5, the side of the door 200, more specifically the inner frame ( It is formed on the side of the 220 and the inlet 320 is disposed to face the side portion 163 of the step portion (160). Hereinafter, the structure of the filter 300 according to the present invention will be described in more detail with reference to FIGS. 3 to 5.

The filter 300 has a groove 310 formed concave along the side surface of the door 200, more specifically, the circumferential surface of the inner frame 220. The groove 310 is defined by an inner wall 311, a bottom 313, and an outer wall 315 as shown in FIG. 3. Here, the inner wall 311 extends horizontally with the inner surface of the door 200 at the edge of the inner surface of the door 200, more specifically at the edge of the inner frame 220. The bottom 313 of the groove 310 extends perpendicularly to the inner surface of the door 200 and the inner wall 311 of the groove 310 at the edge of the inner frame 220. The outer wall 315 of the groove 310 extends at the bottom 313 perpendicular to the bottom 313, ie parallel to the inner wall 311.

As described above, the inner wall 311, the bottom 313, and the outer wall 315 forming the groove 310 are sealed, and the opposite side of the bottom 313 forms the inlet 320 of the groove 310. . When the door 200 is closed, the inner wall 311 of the sealed groove 310 faces the front portion 161 of the stepped portion 160, as shown in FIG. The inlet 320 of the side facing the side portion 163 of the step portion 160.

At the end of the inner wall 311, as shown in FIGS. 1 and 3, a plurality of protrusions 311a extend in parallel with the side portion 163 toward the outer wall 315 so that the entrance of the groove 310 is formed. Partial submission of 320. At the end of the outer wall 315, a plurality of protrusions 315a extend in parallel with the side portion 163 toward the inner wall 311 to partially cover the inlet of the groove 310. Here, the protrusions 311a and 315a are arranged at equal intervals along the longitudinal direction of the groove 310 as shown in FIG. 1, and there are slots through which microwaves can pass between two adjacent protrusions.

If the filter 300 has the above structure, the filter 300 has an ability to shield microwaves. In addition, the filter 300 may maintain a constant ability to shield microwaves regardless of the movement of the door 200. This will be described in more detail below.

A portion of the microwave incident to the heating chamber 110 is incident to a gap between the inner wall 311 of the filter 300 and the front portion 161 of the stepped portion 160. However, since the inner wall 311 of the filter 300 is sealed as described above, the microwaves introduced into the gap between the front portion 161 and the inner wall 311 may be the groove 310 of the filter 300. It does not enter directly into the space to form.

In addition, only a part of the microwaves introduced between the front part 161 and the inner wall 311 enters the gap between the side part 163 of the step part 160 and the protrusion 311 a, and then the slot and the groove. Through the inlet 320 of the 310 is incident into the inner space of the groove 310. Accordingly, the filter 300 having the above-described structure can significantly reduce the amount of microwaves incident into the grooves 310 than before, thereby improving the shielding performance of the microwaves.

On the other hand, the microwave incident into the inner space of the groove 310 is attenuated by the LC circuit formed by the structural characteristics of the filter 300. Here, when the filter 300 has one groove 310, the microwave is attenuated once by resonation. However, the filter 300 according to the present invention may have a structure in which the microwave is attenuated by resonating several times.

To this end, as shown in FIG. 3, the filter 300 extends in parallel with the inner wall 311 and the outer wall 315 at the bottom 313 of the groove 310. The partition plate 330 is further provided to divide the internal space into two independent spaces. Here, at the end of the partition plate 330, a protrusion 330a for partially covering the inlet 320 of the groove 310 may extend toward the outer wall 315.

When the partition plate 330 is provided as above, the same effect as the plurality of filters 300 are continuously formed along the direction in which the door 200 is opened and closed on the side of the door 200, By resonating and attenuating the microwave several times, the amount of leakage of the microwave can be greatly reduced. Thus, filter 300 according to the present invention provides improved microwave shielding performance over conventional filters.

On the other hand, when the gap between the door 200 and the case 100 is opened by slightly pulling the door 200 or deformation of parts, the inner wall of the front portion 161 and the filter 300 ( The large gap between 311) can introduce a large amount of microwaves. However, even in this case, the size of the gap between the side portion 163 and the protrusion 311a that is substantially parallel to the direction in which the door 200 is opened and closed does not change. Therefore, the amount of microwaves incident into the inner space of the groove 310 of the filter 300 is kept constant regardless of the gap between the door 200 and the case 100. As a result, the filter 300 according to the present invention has an advantage of maintaining a constant performance of shielding microwaves compared to the conventional filter structure.

On the other hand, the filter 300 according to the present invention, as described above, can provide an improved microwave shielding performance, can maintain a constant microwave shielding performance, as well as provide improved cleaning of the door 200. This will be described in more detail below.

A part of the pollutant generated in the heating chamber 110 flows into a narrow gap between the front part 161 of the step part 160 and the inner wall 311 of the filter 300. However, since the inner wall 311 of the filter 300 is sealed as described above, the contaminants introduced into the gap between the front portion 161 and the inner wall 311 may be formed in the grooves of the filter 300. 310 is not directly introduced into the inside is attached to the front surface 161 or the surface of the inner wall 311 facing the front surface 161. The front surface 161 and the surface of the inner wall 311 facing the front surface 161 is easy to clean. Therefore, according to this invention, cleaning property improves compared with the conventional heating apparatus.

In order to further improve the cleaning property of the door 200 of the heating apparatus according to the present invention, a glass 250a may be further provided on the inner surface of the door 200. For example, as shown in FIG. 3, the glass 250a may be installed such that the edge thereof covers the inner wall 311 of the filter 300. In this case, since the glass 250a covers the entire inner surface of the door 200, the cleaning property of the door 200 is further improved.

3, the edge of the glass 250a is interposed between the inner wall 311 of the filter 300 and the front portion 161 of the stepped portion 160. Therefore, the gap between the inner wall 311 of the filter 300 and the front portion 161 may be widened by the thickness of the glass 250a. In addition, the glass 250a may be deformed by the temperature difference between the center portion and the edge portion of the glass apparatus when the heating apparatus is operated, whereby the inner wall 311 of the filter 300 and the stepped portion 160 may be deformed. The gap between the front portion 161 may be wider.

However, even if the gap between the front portion 161 and the inner wall 311 is widened by the interposition and deformation of the glass 250a, the protrusion 311a and the filter 300 of the filter 300 are described as described above. The gap between the side portions 163 of the step portion 160 is almost unchanged. Therefore, the microwave shielding performance of the filter 300 according to the present invention is hardly degraded.

On the other hand, unlike the embodiment of Figure 3, the glass 250b may be installed so that the edge facing the heating chamber 110 without covering the inner wall 311 of the filter 310. That is, as shown in FIG. 4, the glass 250b is disposed so that its edge is not interposed between the inner wall 311 of the filter 300 and the front portion 161 of the stepped portion 160. Is provided only in the central part of 200).

In order to fix the glass 250b provided only at the central portion of the door 200, for example, an extension 260 may be a portion of the door 200, more specifically, as shown in FIG. 4. It may extend from the filter 300 to hold the edge of the glass 250b. However, the glass 250b may be fixed to the door 200 by means other than the extension 260. As another example, the glass 250b may be fixed to the inner surface of the door 200 by an adhesive.

When the glass 250b is installed as shown in FIG. 4, the filter 300 may include a sealed portion, that is, the inner wall 311 may have a front surface of the stepped portion 160 without interposing the glass 250b. The unit 161 may be installed to face each other with a very narrow gap therebetween. In this case, not only the cleaning property of the inner surface portion of the door 200 facing the heating chamber 110 can be improved, but the amount of microwaves incident on the filter 300 can be considerably reduced, so that the filter ( The microwave shielding performance of 300) can also be improved. And, in the case of the embodiment of Figure 4, the inner space of the groove 310 can be extended by the thickness of the glass (250b), in this case, when the inner space of the groove 310 is widened, the desired amount of microwave attenuation is more There is an advantage that can be obtained in a wide frequency band.

Meanwhile, the extension part 270 extending from the filter 300 to hold and fix the glass 250b may have a curved shape unlike that of FIG. 4. In more detail, as shown in FIG. 5, the extension part 270 is bent inwardly of the heating chamber 110 to face the inner wall of the heating chamber 110 in the filter 300. After extending back bent toward the door 200 may be installed to hold the edge of the glass (250b) fixed.

The extension part 270 formed as described above is disposed in front of a gap between the front part 161 of the step part 160 and the inner wall 311 of the filter 300 such that the contaminant and the microwave are separated from the step part ( It prevents entry into the gap between the front portion 161 of the 160 and the inner wall 311 of the filter 300. In addition, the extension part 270 is a contaminant and microwave through the gap between the front portion 161 and the inner wall 311 by bending a path in which the pollutant and the microwave in the heating chamber 110 leaks to the outside. Makes it difficult to pass. As a result, contamination of the filter 300 can be effectively prevented to improve the cleaning property of the door 200, and the leakage of the microwave can be effectively suppressed.

In the heating device according to the invention, the extension 270 may be provided independently of the glass 250b, although not shown. For example, the glass 250b may be provided at a central portion of the door 200, and the extension 270 may extend from the filter 300 irrespective of the glass 250b. In this case, the glass 250b may be fixed to the door 200 by the extension part 260 or the adhesive of FIG. 4.

In addition, although not shown, the glass 250b may not be provided in the door 200, but only the extension 270 may be provided. In this case, the extension part 270 effectively prevents the contaminants from moving toward the filter 300, thereby improving the cleaning property of the door 200 and effectively reducing the leakage of microwaves. You will be able to successfully achieve your goals.

On the other hand, the door 200 includes an outer frame 210 and an inner frame 220 protruding from the rear of the outer frame 210, and the inner door 200 is closed when the door 200 is closed. Embodiments have been described in which an edge of the frame 220 is accommodated in the stepped part 160. However, the present invention is not limited thereto.

As another example, the door 200 may be configured as one flat frame, and the side surface, that is, the circumferential surface of the door 200 may be configured to be accommodated in the stepped part 160. In this case, the inner edge of the door 200 faces the front portion 161 of the stepped portion 160, and the circumferential surface of the door 200 has a side portion 163 of the stepped portion 160. Will be placed facing each other. In addition, it may be preferable that the outer surface of the door 200 forms the same surface as the front panel 120 when the door 200 is closed to improve the aesthetics of the heating device.

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.

According to the present invention as described above, the stepped portion is formed in the front panel of the case and the filter of the door is arranged to face the side portion of the stepped portion. Therefore, it is difficult to introduce contaminants in the heating chamber into the filter, thereby improving the cleanability of the door. In addition, since the amount of microwaves introduced into the filter is small, the microwave shielding performance is also improved. Furthermore, the microwave shielding performance can be kept constant regardless of the movement of the door.

On the other hand, when glass is provided in the door of the heating apparatus which concerns on this invention, the cleaning property of a door will further improve. In addition, when the extension is extended from the filter to face the inner wall of the heating chamber, leakage of contaminants and microwaves generated in the heating chamber can be suppressed, thereby further improving the cleaning property of the door and the microwave shielding performance.

Claims (9)

A case in which a heating chamber to which microwaves are irradiated is formed, and having a front panel surrounding an inlet of the heating chamber; A door for opening and closing the heating chamber; A stepped portion formed on the front panel and having a front portion facing the inner surface of the door and a side portion facing the side of the door; And And a filter formed on the side of the door, the inlet of which is disposed toward the side of the step portion to attenuate the leaked microwaves. The method of claim 1, The filter is a heating device using a microwave, characterized in that a plurality of continuously formed on the side of the door in the direction in which the door is opened and closed. The method of claim 1, Microwave heating device further comprises a glass mounted on the inner surface of the door. The method of claim 3, wherein And the glass is installed so that its edge faces the heating chamber. The method of claim 3, wherein The filter is a heating device using a microwave, characterized in that the sealed portion is provided facing each other with a narrow gap between the front portion of the step portion without the interposition of the glass. The method according to claim 3 or 5, And an extension part extending from the filter to hold and fix the edge of the glass. The method of claim 1, And an extension part extending from the filter so as to face an inner wall of the heating chamber to reduce leakage of the microwaves. The method of claim 1, The filter is a heating device using a microwave, characterized in that the sealed portion is directly facing the front portion of the stepped portion with a narrow gap therebetween. A heating chamber to which microwaves are irradiated; A door for opening and closing the heating chamber; A front part extending from an inner wall of the heating chamber and facing an inner surface edge of the door; A side portion extending from the front portion substantially parallel to the opening and closing direction of the door; And And a filter formed in the door, the sealed part facing the front part, and the inlet of the inlet being disposed toward the side part to reduce the leaked microwaves.

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