KR20000003789U - Reflective Structure of Halogen Lamp for Microwave Oven - Google Patents

Abstract

The present invention relates to a structure for minimizing the amount of light reflected back to the surface of the halogen lamp while increasing the cooling efficiency of the reflector in a microwave oven equipped with a halogen lamp.

According to the present invention, a reflector 24 having a halogen lamp 12 for generating light having a predetermined wavelength and a plurality of embossings 26 whose outer surface is convexly formed by reflecting the light from the halogen lamp into the cavity. And an airflow generating means for generating a cooling airflow toward the reflecting plate. In addition, the inner surface of the embossing 26 is formed to be concave to minimize the amount of light reflected from the light emitting lamp is reflected back to the light emitting lamp.

Description

Reflective Structure of Halogen Lamp for Microwave Oven

The present invention relates to a reflective structure of a halogen lamp used in a microwave oven, and more particularly, the light reflected from the reflector is not reflected back toward the halogen lamp and at the same time the reflection plate is configured to increase the cooling efficiency of the reflector. To a reflective structure.

Various kinds of apparatuses have been proposed to date as heating apparatuses for heating foods. The most primitive heating mechanism is a container of a predetermined shape in direct contact with a heat source, and the contents to be cooked are placed in such a container, and the desired cooking is performed by applying heat.

In addition, many types of cooking apparatuses have been developed that use electric energy directly or indirectly. As an example, a microwave oven using microwaves as a heating source may be cited. A microwave oven is a cooking apparatus in which microwaves are generated using electricity, and the microwaves penetrate the object to be cooked, causing molecular motion inside the object, and thereby heating. Such microwave ovens are widely used for simple heating, for example, a thawing process for dissolving frozen food or a device for heating food such as milk to a predetermined temperature due to its simple configuration and ease of use. It is used.

However, the microwave oven cannot be said to be suitable for heating various objects due to the disadvantages in use due to the heating method and the limitation of its output. That is, the conventional microwave oven using only microwaves as a heating source is pointed out that there is a problem in that it is not possible to provide fast and high-quality cooking because of the unity of the heating method by the microwave and its output. . For example, when heated by microwave, the object is heated both inside and outside together, but this advantage is a significant disadvantage depending on the cooking object. When cooking pizza as described later, it is judged that heating by microwaves is not suitable due to the properties of the object. In addition, it is also pointed out that in the case of heating by a microwave oven, too much moisture is removed from the object.

For these current microwave ovens, various types of microwave ovens using different heat sources have been developed and commercialized. For example, a microwave oven capable of performing appropriate heating on various cooking objects may be mentioned by attaching a convection heater, which can be said to be another heat source, separately from the microwave. In this way, however, even in a microwave oven in which the heater is built, it is true that such a heater does not have various functions as a whole because it only serves as another heat source.

In conclusion, when heating by the conventional microwave only, the limitation of the heating method of the single method of heating by the microwave, the disadvantages of the output, and various disadvantages due to the evaporation of water have been pointed out. Even in the case of installation, the above-mentioned disadvantages cannot be sufficiently solved.

In order to solve the above-mentioned problems of the conventional microwave oven, a microwave oven using light waves as a heating source has been proposed. That is, by using a lamp having a wavelength of at least 90% of the radiant energy of 1 μm or less as a heating source, by appropriately using the visible light and infrared rays emitted from such a lamp, the characteristics of the surface and the inside of the heating object can be adjusted. It is to be able to perform heating while keeping enough power. Halogen lamps are mentioned as such a heating source.

The difference between the wavelengths of the infrared light and the visible light is represented by the difference in the heating method by the different wavelengths applied to the object, and the outside and the inside of the object are heated in different forms by this difference. Using such a halogen lamp, for example, in the case of pizza, it is possible to obtain a cooking state in which the outside has a crisp heating degree and the inside is sufficiently heated and softly heated with a predetermined moisture. .

1 shows a microwave oven using such a halogen lamp as another heating source. As shown in the figure, a halogen lamp 12 is provided on the upper surface 10 of the cavity 2 of the microwave oven. The use of the light waves emitted from the halogen lamp 12 as a heating source for heating the heating object and the properties of the light waves generated from the halogen lamp are as described above.

The reflection plate 14 is installed above the halogen lamp 12 to reflect the light waves generated upward from the halogen lamp 12 into the lower cavity 2. A plurality of transmission holes 16 are formed on the upper surface of the cavity 2 in which the halogen lamp 12 is provided.

Next, the structure of the conventional reflector will be described with reference to FIGS. 2 and 3. As described above, the reflector 14 is for reflecting light generated from the halogen lamp 12 into the cavity 2. As shown in the figure, the upper surface 14a has a planar shape, and the two side surfaces 14b have a predetermined inclination so that the light incident upwardly from the halogen lamp 12 can be reflected again toward the lower cavity. Molded.

The upper surface 14a may have a predetermined planar shape as shown in the figure, or may have a curved surface according to another conventional configuration example, but the reflecting plate 14 has a symmetrical shape substantially.

Therefore, as shown in FIG. 3, for example, light incident vertically upward from the halogen lamp 12 is reflected by the center surface of the reflector 14 and is incident on the surface of the halogen lamp 12 again. Light emitted from the filament located inside the halogen lamp 12 is a light energy having a predetermined wavelength as described above, the surface of the halogen lamp may be damaged when reflected back to the surface of the halogen lamp. Light that is reincident to the surface of the halogen lamp damages the surface of the halogen lamp, shortening the life of the halogen lamp itself, and at the same time, the reliability of the microwave oven equipped with the halogen lamp. Therefore, it is most desirable to avoid reincarnation to the surface of the halogen lamp 14 whenever possible.

When the halogen lamp 12 emits light, the surface of the halogen lamp 12 and the surroundings of the reflecting plate 14 are at a considerable high temperature. Therefore, the portion that generates heat at a high temperature, including the halogen lamp 12 and the reflector 14, should be cooled as efficiently as possible. Therefore, cooling air flow as shown by F in FIG. 2 is generated, and the reflection plate 14 and the halogen lamp 12 are cooled.

However, according to the structure of the conventional reflecting plate 14, the upper surface 14a and the both side surfaces 14b constituting the reflecting plate 14 substantially have a planar state as shown, so that the cooling air flow F Cooling by supply has a limitation. In order to cool using the cooling airflow F, the larger the area exposed to the cooling airflow F is, the greater the effect of cooling becomes. However, each surface of the reflector plate 14 has a conventional structure. Since it has a planar shape, it is inevitably limited by such a shape.

In order to increase the efficiency of cooling it can be considered to attach a separate cooling fin to the reflector, but this configuration has a disadvantage in that it is complicated in the part and assembly process because the configuration is complicated.

The present invention is to solve the above problems, and an object of the present invention is to provide a reflective structure that can further increase the cooling efficiency of the reflecting plate.

Another object of the present invention is to provide a reflecting plate capable of ensuring the life of the halogen lamp and the reliability of the product by preventing light reflected by the reflecting plate from being incident again on the surface of the halogen lamp.

1 is an exemplary configuration diagram of a microwave oven equipped with a halogen lamp.

Figure 2 is a partial perspective view showing the structure of a conventional reflector.

3 is a cross-sectional view showing a conventional reflective structure.

Figure 4 is a partial perspective view showing the structure of a reflecting plate according to the present invention.

Figure 5 is an exemplary side view showing a reflective structure according to the present invention.

Explanation of symbols on the main parts of the drawings

12 ..... Halogen lamp 24 ..... Reflector

26 ..... Embossing F ..... Cooling air flow

According to the present invention for achieving the above object, a light emitting lamp for generating light of a predetermined wavelength; A reflecting plate for reflecting light from the light emitting lamp into the cavity and having a plurality of embossings whose outer surface is convex; The technical gist of the present invention is a microwave oven including an airflow generating means for generating a cooling airflow toward the reflector.

In addition, the inner surface of the embossing is concave, so that the light emitted from the light emitting lamp minimizes the amount of light reflected back to the light emitting lamp.

According to the present invention, by improving the cooling efficiency by the outer surface of the embossing, by minimizing the amount of light reflected back toward the light emitting lamp on the inner surface, it can be expected to minimize the damage of the light emitting lamp, Hereinafter, the present invention will be described in more detail with reference to FIG. 3 showing an embodiment of the present invention.

First, the reflective structure according to the present invention will be described with reference to FIG. 4. As shown in the drawing, the reflector 24 according to the present invention includes a plurality of embossings 26 formed convexly upward.

As shown in the figure, the embossing 26 is formed by press work or the like from the inside of the reflecting plate 24 to the upper portion thereof, and is configured such that a concave groove corresponding to the embossing is formed on the lower surface thereof.

By shaping the embossing 26, the outer surface of the reflecting plate 24 substantially increases the surface area. Therefore, the surface area in contact with the cooling airflow (refer to FIG. 2) formed toward the reflector 24 is widened, thereby improving the cooling efficiency of the reflector 24.

According to the present invention, the surface area of the reflecting plate 24 is increased by forming the convex embossing 26 on the surface of the reflecting plate 24, and the contact with the cooling airflow supplied by the widening of the surface area is thus made. The area becomes larger, and thus the cooling efficiency can be improved.

Next, the reflection of the halogen lamp 12 by the embossing 26 according to the present invention will be described based on FIG. 5.

As described above, the light emitted from the halogen lamp 12 is reflected from the lower surface of the reflector 24 and enters the cavity of the microwave oven. At this time, according to the conventional structure, the light reflected from the portion corresponding to the upper portion of the halogen lamp 12 is substantially reflected back to the halogen lamp 12, damaging the surface of the halogen lamp 12 Was supposed to be.

However, since the embossing 26 is formed in the reflecting plate 24 according to the present invention, when viewed from the inside of the reflecting plate 24, a concave groove is formed, and this structure is shown in FIG. As shown in the example of the luminous flux, the reflection angle of the light emitted from the halogen lamp 12 is different by forming the embossing 26 directly on the halogen lamp 12. That is, in the past, the reflected light from the upper portion of the halogen lamp 12 was reflected directly to the halogen lamp 12 side. According to the present invention, the upper surface of the reflector 24 corresponding to the upper portion of the halogen lamp 12 is Since a plurality of embossings 26 are formed on the inner surface of the embossings 26, the reflection angle is formed in a direction different from that of the prior art, and thus the amount of light reflected to the halogen lamp 24 side is significantly reduced.

In addition, since the area of the inner surface of the reflector increases with the outer surface, the light generated from the halogen lamp causes more diffuse reflection, and thus the light entering the cavity and the accompanying heat will be uniformly supplied to the heating object. .

As described above, according to the present invention, it can be seen that by forming a plurality of embossings on the reflecting plate 24, the surface area of the reflecting plate 24 is widened. When the surface area of the upper surface of the reflector is widened in this manner, the area in contact with the supplied cooling airflow becomes large, which means that the reflector can be cooled more efficiently. The efficient cooling of the halogen lamp and the reflector plate can solve the problems caused by thermal damage while extending the life of the halogen lamp and the adjacent parts.

And according to the present invention, the inner surface of the embossed to be formed on the reflecting plate is formed concave. By the structure of the embossing, it is possible to significantly reduce the amount of light reflected back from the reflecting plate toward the halogen lamp. Therefore, it is expected to reduce the damage of the halogen lamp surface to extend the life.

As described above, the light reflected into the cavity is further supplied through the diffuse reflection to provide more uniform light to the heating object, and the effect of enabling uniform cooking as a whole can be expected.

Claims (3)

A light emitting lamp for generating light having a predetermined wavelength; A reflecting plate for reflecting light from the light emitting lamp into the cavity and having a plurality of embossings whose outer surface is convex; And a light emitting lamp including air flow generating means for generating cooling air flow toward the reflecting plate. The microwave oven according to claim 1, wherein an inner surface of the embossing is concave to minimize the amount of light reflected from the light emitting lamp to the light emitting lamp. 3. The microwave oven according to claim 2, wherein the embossing is formed directly on the light emitting lamp.