KR101115691B1 - Microwave oven having hood - Google Patents

Abstract

The present invention relates to a microwave oven. In the present invention, the heater is directly cooled by a heater cooling fan, and the heater cover that shields the heater is indirectly cooled by being placed on an airflow formed by a vent pan assembly for the hood function. Therefore, according to the present invention, there is an advantage that the cooling of the heating source can be made more efficiently.

Microwave Oven, Heater, Heater Cooling Fan, Band Fan

Description

Microwave oven having hood {Microwave oven having hood}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a microwave oven, and more particularly, to a hood-use microwave oven including a cooling system for cooling components constituting the microwave oven.

A microwave oven is a cooking apparatus that heats food using microwaves and / or heater heat. Such a microwave oven is provided with various parts including a heating source such as a magnetron for oscillation of microwaves, and a heater for generating heater heat. In addition, in the microwave oven, an air flow for cooling the components such as the magnetron and the heater is formed.

In particular, a microwave oven including a hood function including a hood function for discharging the air containing contaminants generated during the cooking of food in a cooking apparatus installed under the microwave oven to the outside or filtering and discharging the air to the interior It is called a microwave oven or OTR type microwave oven. In such a microwave oven for hood, an air flow for a hood function is formed.

However, the following problems occur in the microwave oven according to the prior art.

First, in recent microwave ovens, various heating sources are provided for quick and efficient cooking. However, the conventional microwave oven is disadvantageous in that it is not efficient for cooling such a variety of heating sources, in particular cooling of a high-power heater.

In the microwave oven, in the case of a high power heater, a high power fan or a plurality of fans is used to cool the heater. Therefore, as the size of the pan increases, the volume of the cooking chamber may decrease or the number of parts may increase.

The present invention is to solve the conventional problems as described above, it is an object of the present invention to provide a hood combined microwave oven that can be more efficiently cooled parts.

It is another object of the present invention to provide a hood-use microwave oven in which cooling of a relatively low heat generating component is not affected by a relatively high heat generating component.

According to an embodiment of the present invention, a combined microwave oven includes: a heater installed on an upper surface of a cavity in which a cooking chamber is provided and generating a heater heat provided into the cooking chamber; A heater cover to shield the heater; A front plate forming a front surface of the cavity and having an indoor exhaust vent for discharging air containing contaminants into the room; A base plate provided at a lower portion of the cavity and having an inlet for a hood through which air containing contaminants are sucked; A vent fan assembly installed on an upper surface of the cavity corresponding to the rear of the indoor exhaust port for the hood, and configured to form an air flow sucked through the hood inlet port and discharged through the indoor exhaust port for the hood; An indoor exhaust passage provided in the center of the upper surface of the cavity and through which the air discharged through the indoor exhaust vent for the hood is flown by the vent pan assembly; A cooling fan forming an air flow partitioned from an air flow formed by the vent fan assembly to cool the heater; And a first air duct for cooling the heater guiding the air flow formed by the cooling fan to the heater. The heater is indirectly cooled by cooling the outside of the heater cover is an air flow formed by the vent fan assembly, the air flow formed by the cooling fan is in the first air duct for cooling the heater It is directly cooled by being guided to the heater.

According to the present invention, there is an advantage that the cooling of the heating source can be performed more efficiently.

Hereinafter, with reference to the accompanying drawings, the configuration of an embodiment of a microwave oven according to the present invention will be described in more detail.

1 is an exploded perspective view showing an embodiment of a microwave oven according to the present invention, Figure 2 is a plan view showing an embodiment of the present invention.

1 and 2, the cooking chamber 101 is formed inside the cavity 100 of the microwave oven. The cooking chamber 101 is a space in which food is cooked. An electrical equipment chamber 103 is provided inside the cavity 100 corresponding to the opposite side of the cooking chamber 101. The electrical component room 103 is provided with various electrical components.

Meanwhile, the front plate 110 forms the front surface of the cavity 100. The upper plate 120 forms the upper surface of the cavity 100, and the bottom plate 130 forms the bottom surface of the cavity 100. Inner plates 140 form both side surfaces and rear surfaces of the cavity 100.

The back plate 150 is fixed to the rear of the cavity 100, and the base plate 160 is fixed to the lower side of the cavity 100. At this time, the back plate 150 is in close contact with the inner plate 140 forming the rear surface of the cavity 100. The base plate 160 is spaced downward from the bottom plate 130. In addition, the outer case 170 shields the upper and both sides of the cavity 100. The outer case 170 is formed in a substantially U shape.

The front plate 110 is formed with a plurality of vents. The vent is where the air flowing into and out of the microwave flows. In FIG. 1, from the right side of the upper end of the front plate 110 to the left side, the intake port 111 for cooling electric parts, the indoor exhaust port 113 for the hood, the exhaust port 115 for cooling, and the intake port 115 for cooling the heater are shown. Are located in turn.

The intake port 111 for cooling the electric component is configured to allow the air to be sucked into the microwave oven for cooling the electric component. The hood exhaust pipe 113 is an outlet through which air containing contaminants which are generated in the process of cooking food in a cooking apparatus installed under the microwave and sucked into the microwave are filtered and discharged into the room. Play a role. The cooling exhaust port 115 serves as an outlet for discharging the electrical components and the air cooled by the upper heater 191 to be described later into the room. In addition, the inlet 115 for cooling the heater serves as an inlet zone through which air is sucked into the microwave oven for cooling the upper heater 191.

In addition, a cooking chamber intake port (not shown) is formed in the inner plate 140 corresponding to the cooking chamber 101 and the electric chamber 103. A cooking chamber exhaust port 121 is formed at one side of the upper plate 120 corresponding to the rear of the cooling exhaust port 115. The cooking chamber intake port is an entrance area through which a part of the air flowing through the electrical equipment chamber 103 is sucked into the cooking chamber 101. The cooking chamber exhaust port 121 serves as an outlet through which the air circulated inside the cooking chamber 101 through the cooking chamber inlet is discharged to the outside of the cooking chamber 101.

The upper plate 120 has a porous portion 123 is formed. In the present embodiment, the porous part 123 is formed by cutting a rectangular portion in which a portion of the upper plate 120 is inclined at a predetermined angle. The porous part 123 is for transmitting the heater heat of the upper heater 191 into the cooking chamber 101.

In the present embodiment, the porous portion 123 is disposed to be inclined at a predetermined angle with respect to the front surface of the cooking chamber 101 so as to be positioned on an imaginary straight line A that bisects the cooking chamber 101 to the left and right. At this time, the porous portion 123 is located on the indoor exhaust passage (P8) for the hood at least a portion of which will be described later.

In addition, a hood inlet 161 is formed on the base plate 160. The hood inlet 161 may be an entrance area through which air containing contaminants generated in a process of cooking food in a cooking appliance is sucked into the microwave oven.

The outdoor case 171 for the hood is formed in the outer case 170. The hood outdoor exhaust 171 serves as an outlet through which air containing contaminants sucked into the microwave oven is discharged to the outside. The hood outdoor exhaust port 171 is formed by cutting a portion of the outer case 170 that shields the upper portion of the cavity 100.

The cavity 100 is provided with an extension plate 181 and a partition plate 183. The extension plate 181 extends to the opposite side of the cooking chamber 101 to be positioned on the same plane as the inner plate 140. The partition plate 183 extends upward from the rear end of the extension plate 181. The extension plate 181 forms the bottom surface of the electric chamber 103. The partition plate 183 forms a rear surface of the electric compartment 103.

On the other hand, examples of the electric component installed in the electric chamber 103 may include a magnetron 185 and a high voltage transformer. The magnetron 185 serves to oscillate the microwaves into the cooking chamber 101. The high voltage transformer 186 applies a high voltage current to the magnetron 185.

In addition, the electric component chamber 103 is provided with an electric component cooling fan 187. The electric component cooling fan 187 forms an air flow for cooling the electric component installed in the electric chamber 103. In more detail, the electric component cooling fan 187 is sucked into the electric component chamber 103 through the electric component cooling inlet 111 to cool the electric component, and through the cooking chamber inlet. Suctioned into the cooking chamber 101 to circulate the inside of the cooking chamber 101 and discharged to the outside of the cooking chamber 101 through the cooking chamber exhaust port 121 to be discharged into the room through the cooling exhaust port 115. Form an airflow.

The cavity 100 is provided with a wave guide 189. The wave guide 189 serves to guide the microwaves oscillated by the magnetron 185 into the cooking chamber 101. To this end, the wave guide 189 extends from the upper surface of the cavity 100, that is, from one side of the upper plate 120 to the electric chamber 103 to shield the antenna of the magnetron 185.

In addition, an upper heater 191 is installed on the upper plate 120 corresponding to the upper portion of the porous part 123. The upper heater 191 generates a heater heat transmitted to the inside of the cooking chamber 101. In the present exemplary embodiment, the two upper heaters 191 of the bar type are disposed to be inclined at a predetermined angle to the upper plate 120 in the long side direction of the porous part 123. As the upper heater 191, for example, a high output halogen heater, a carbon heater or a ceramic heater may be used.

A heater supporter 192 is provided to support the upper heater 191. A reflector 193 is installed to surround the upper heater 191 supported by the heater supporter 192. The reflector 193 reflects the heater row of the upper heater 191 into the cooking chamber 101 through the porous part 123.

An upper heater cover 194 is installed above the reflector 193. The upper heater cover 194 prevents a phenomenon in which the heater heat of the upper heater 191 leaks to the upper portion of the cavity 100 by shielding the porous part 123 and the upper heater 191. Do it. The upper heater cover 194 is formed in a rectangular shape corresponding to the shape of the porous part 123. And both ends of the upper heater 191 extends to the outside of the upper heater cover 194.

As described above, the upper heater cover 194 shields the porous portion 123. Therefore, a portion of the upper heater cover 194 is substantially positioned on the indoor exhaust passage P8 for the hood. In addition, the upper heater cover 194 is disposed to be inclined at a predetermined angle with respect to the front surface of the cooking chamber 101, similar to the porous portion 123 described above, a part of which is on the virtual straight line (A). Is located.

A heater cooling fan 195 is installed on the upper plate 120. The heater cooling fan 195 is disposed at one side of the upper plate 120 corresponding to the rear of the upper heater cooling inlet 117. The heater cooling fan 195 forms an air flow for direct cooling of the upper heater 191. In more detail, the heater cooling fan 195 is sucked through the upper heater cooling inlet 117 to cool the upper heater 191 and is discharged into the room through the cooling exhaust port 115. Form an airflow.

The vent plate assembly 196 is installed on the upper plate 120. The vent pan assembly 196 is configured to supply air containing contaminants sucked into the microwave oven through the hood inlet 161 to the indoor exhaust port 113 for the hood or the outdoor exhaust port 171 for the hood. Through indoors or outdoors. To this end, the vent pan assembly 196 is disposed at one side of the upper plate 120 corresponding to the rear of the indoor exhaust vent 113 for the hood and below the outdoor exhaust vent 171 for the hood.

The vent fan assembly 196 includes one vent motor 197 and first and second vent fans 198 and 199 positioned at both sides of the vent motor 197. The vent motor 197 provides a driving force for driving the first and second vent fans 198 and 199. The first and second vent fans 198 and 199 are provided with intake portions 198A and 199A for sucking air and exhaust portions 199B and 199B for discharging air, respectively.

In the present exemplary embodiment, the first vent fan 198 is disposed on the left side of the drawing and the second vent fan 199 is disposed on the right side of the drawing based on the vent motor 197. The intake portion 198A of the first vent pan 198 faces the left side of the drawing, and the intake portion 198A of the second vent pan 199 faces the right side of the figure. Of course, although the intake portion is provided on the right side of the drawing of the first vent fan 198 and the left side of the drawing of the second vent fan 199, the intake amount of air through this is relatively small, so Ignore it and explain it.

In addition, the exhaust parts 198B and 199B of the first and second vent fans 198 and 199 may face forward or upward in the drawing. For example, when air containing contaminants is discharged into the room through the hood exhaust duct 113, the exhaust parts 198B and 199B of the first and second vent fans 198 and 199. ) Is placed forward. When the air containing the contaminant is discharged to the outside through the hood outdoor exhaust port 171, the exhaust parts 198B and 199B of the first and second vent fans 198 and 199 are upward. It is arranged to face.

In the present embodiment, the exhaust 198B of the first vent fan 198 is disposed at the front and rear sides of the upper heater cover 194, that is, the exhaust 198B of the first vent fan 198. Are superimposed in the direction of discharge. In other words, a part of the upper heater cover 194 is positioned on the air flow formed by the first vent fan 198. This is to allow the upper heater 191 to be indirectly cooled by the first vent fan 198 that flows a relatively large amount of air, as will be described later.

On the other hand, the first air duct 210 for cooling the electric component is installed in the upper portion of the electric chamber (103). The first air duct 210 for cooling the electric component is supplied with the air sucked through the inlet 111 for cooling the electric component by the driving of the electric component cooling fan 187 into the electric chamber 103. It serves to guide the inhalation. In the present embodiment, the first air duct 210 for cooling the electric component is provided above the electric chamber 103 corresponding to the upper portion of the wave guide 189. The front end of the first air duct 210 for cooling the electric component is in communication with the inlet 111 for cooling the electric component. In addition, the first air duct 210 for cooling the electric component is provided with a communication opening 211 for flowing air into the electric chamber 103. In addition, a guide seating portion 213 is formed in the first air duct 210 for cooling the electric component to avoid interference with the wave guide 189. The guide seating portion 213 is formed by recessing a portion of the bottom surface of the first air duct 210 for cooling the electric component substantially upward. In addition, a part of the wave guide 189 is seated on the guide seating part 213 in a state where the first air duct 210 for cooling the electric component is installed on the upper part of the electric compartment 103.

A second air duct 220 for cooling electrical components is installed at one side of the upper plate 120 corresponding to the upper side of the cooking chamber exhaust port 121. The second air duct 220 for cooling the electric component plays a role of guiding the air discharged through the cooking chamber exhaust port to be discharged into the room through the cooling exhaust port 115. In the present embodiment, the second air duct 220 for cooling the electric component is shielded the cooking chamber exhaust port 121, the front end of the second air duct 220 for cooling the electric component is the cooling exhaust port 115 In communication with some of the.

In addition, the upper plate 120 is provided with a first air duct 230 for cooling the heater. The first air duct 230 for cooling the heater guides the air sucked through the heater cooling inlet 115 to the inside of the upper heater 191 and substantially the upper heater cover 191. Do it. To this end, in the present embodiment, the heater cooling first air duct 230 shields the heater cooling fan 192, and the front and rear ends of the heater cooling first air duct 230, respectively, the heater cooling. The air intake port 115 and the upper heater cover 191 is in communication with. The first air duct 230 for cooling the heater substantially shields the heater cooling fan 192. In other words, the heater cooling fan 192 is positioned in the space between the upper plate 120 and the first air duct 230 for cooling the heater.

The upper plate 120 is provided with a second air duct 240 for cooling the heater. The second air duct 240 for cooling the heater discharges air that cools the upper heater 191, that is, air that flows inside the upper heater cover 191 through the cooling exhaust port 115. It serves as a guide. In the present embodiment, the front and rear ends of the second air duct 240 for cooling the heater communicate with the rest of the cooling exhaust port 115 and the upper heater cover 191, respectively.

In this embodiment, substantially the second air duct 240 for cooling the heater is provided to shield the second air duct 220 for cooling the electrical component. Therefore, it may be said that the cooling exhaust port 115 is partitioned by the first air duct 220 for cooling the electric component and the second air duct 240 for cooling the heater. Of course, the cooling exhaust port in the form in which one of the second air duct 220 for cooling the electric component and the second air duct 240 for cooling the heater is shielded by the other as in the present embodiment. It is not necessary to partition 115.

Meanwhile, the microwave oven includes a plurality of flow paths through which airflow formed by the electric component cooling fan 187, the heater cooling fan 192, the motor cooling fan 194, and the vent fan assembly 196 flows. . Such a flow path includes an intake flow passage P1 for electric component cooling, an exhaust flow passage P2 for electric component cooling, an intake passage P3 for heater cooling, an exhaust flow passage P4 for heater cooling, an intake flow passage for hood, and a hood. Indoor exhaust passage (P8).

More specifically, the intake flow path P1 for cooling the electric parts is a place where air sucked into the microwave oven flows to cool the electric parts, that is, the magnetron 185 and the high-pressure transformer 186. to be. In this embodiment, the intake flow path P1 for cooling the electric component is substantially formed between the first air duct 210 for cooling the electric component and the outer case 170. In addition, the intake flow paths P1 for cooling the electric component are respectively connected to the indoor and electrical chambers 103 through the communication openings 211 of the inlet 111 for cooling the electric component and the first air duct 210 for cooling the electric component. ).

The exhaust passage P2 for cooling the electric component is a place where the air discharged to cool the electric component and to the outside of the microwave oven, i.e., the room. Substantially, the electric parts are cooled and the air circulated through the cooking chamber 101 will flow through the exhaust path P2 for cooling the electric parts. In the present embodiment, the exhaust path for cooling the electric component P2 is formed between the upper plate 120 and the second air duct 220 for cooling the electric component. The second air duct 220 for cooling the electric component is communicated with the cooking chamber 101 and the room through the cooking chamber exhaust mechanism 121 and the cooling exhaust port 115.

The intake flow path P3 for cooling the heater is a place where air sucked into the microwave oven flows to cool the upper heater 191. In this embodiment, the heater cooling intake passage P3 is formed between the upper plate 120 and the heater cooling first air duct 230. The front end of the heater cooling intake passage P3 communicates with the room through the heater cooling intake passage 115, and the rear end of the heater cooling intake passage P3 communicates with the upper heater cover 191. do.

In addition, the heater cooling exhaust passage P4 is a place where the air discharged to cool the upper heater 191 and flows into the room. In this embodiment, the heater cooling exhaust passage P4 is formed between the upper plate 120 and the second air duct 240 for cooling the heater. The front end of the heater cooling exhaust passage P4 communicates with the room through the cooling exhaust port 115, and the rear end of the heater cooling intake passage P3 communicates with the upper heater cover 191.

The intake flow path for the hood is a place where air containing contaminants sucked into the microwave oven flows. The hood intake passages include hood first to third intake passages P6, P7, and P8.

The hood first intake passage P6 is formed in a space between the bottom plate 130 and the base plate 160. Substantially, the hood first intake passage P6 is formed in a space between the bottom plate 130 and the base plate 160 except for the motor cooling passage P5. Accordingly, the hood first intake passage P6 and the motor cooling passage P5 may be substantially partitioned by the fifth air duct 250. The hood first intake passage P6 communicates with a room, that is, a space below the microwave oven, through the hood intake 161.

The hood second intake passage P7 is formed between the inner plate 140 and the outer case 170 corresponding to the opposite sides of the electric chamber 103. The hood second intake passage P7 is in communication with the hood first intake passage P6 and the vent fan assembly 196. At this time, the second intake passage P7 for the hood is substantially the second air duct 220 for cooling the electric component, the first air duct 230 for cooling the heater, and the second air duct 240 for cooling the heater. By this, the electric component cooling exhaust passage P2, the heater cooling intake passage P3, and the heater cooling exhaust passage P4 are partitioned.

The third intake passage P8 for the hood is formed between the back plate 150 and the partition plate 183. The hood third intake passage P8 communicates with the hood first intake passage P6 and the vent fan assembly 196. The hood third intake passage P8 is formed by the first air duct 210 and the partition plate 183 for cooling the electric component, and the air intake passage P1 for cooling the electric component and the electric compartment 103. And is compartmentalized.

In this embodiment, the flow cross section of the hood second intake passage P6 is formed relatively larger than the flow cross section of the hood third intake passage P8. Therefore, the first vent fan 198 will allow a relatively large amount of air to flow compared to the second vent fan 199.

On the other hand, the indoor exhaust passage (P9) for the hood, where the air containing the pollutants discharged into the room after being sucked into the microwave oven and filtered. The hood indoor exhaust passage P9 is between the upper plate 120 and the outer case 170, substantially, an intake passage P1 for cooling the electric component, an intake passage P3 for cooling the heater, and Except the heater cooling exhaust passage (P4) is formed in the upper plate 120 and the outer case (170). Therefore, the hood indoor exhaust path P8 includes the first air duct 210 for cooling the electric parts, the second air duct 220 for cooling the electric parts, the first air duct 230 for cooling the heater, and the heater cooling. The second air duct 240 allows the intake flow path P1 for cooling the electric parts, the exhaust flow path P2 for cooling the electric parts, the intake flow path P3 for the heater cooling, and the exhaust flow path P4 for the heater cooling. It can be said to be partitioned. The front end of the hood indoor exhaust passage P8 communicates with the room through the hood indoor exhaust passage 113, and the rear end of the hood indoor exhaust passage P8 is connected to the vent fan assembly 196. Communicating. In addition, although not shown, a filter for filtering contaminants contained in the air may be installed on the indoor exhaust passage P8 for the hood.

In addition, a portion of the upper heater cover 194 is located on the indoor exhaust channel P8 for the hood, as described above. The upper heater cover 194 overlaps the exhaust portion 198B of the first vent fan 198 in a direction in which air is discharged from the exhaust portion 198B of the first vent fan 198. That is, a portion of the upper heater cover 194 is positioned on the air flow formed by the air discharged from the exhaust portion 198B of the first vent fan 198, thereby flowing a relatively large amount of air. Indirect cooling is performed by the first vent fan 198.

Hereinafter, the operation of the embodiment of the hood-use microwave oven according to the present invention will be described in more detail.

Figure 3 is a plan view showing the flow of air in an embodiment of the microwave oven according to the present invention, Figures 4 and 5 are side views showing the flow of air in an embodiment of the present invention.

First, referring to FIG. 3, when the electric component cooling fan 187 is driven, indoor air (solid line) passes through the intake flow path P1 for cooling the electric parts, and the inside of the microwave oven, that is, the intake flow path for cooling the electric parts ( Inhalation into P1). The air sucked into the intake passage P1 for cooling the electronic component flows through the intake passage P1 for cooling the electrical component by continuously driving the electrical component cooling fan 187, thereby It flows inside.

The air flowing into the interior of the electric field chamber 103 cools the electric parts, that is, the electric parts such as the magnetron 185 and the high pressure transformer 186. A portion of the air cooled by the electric component is transferred into the cooking chamber 101 through the cooking chamber inlet.

The air delivered to the inside of the cooking chamber 101 circulates inside the cooking chamber 101. In this case, the air circulating in the cooking chamber 101 may contain contaminants, for example, oil or water, generated during cooking of the food inside the cooking chamber 101. It is discharged to the outside of the cooking chamber 101 through.

The air discharged to the outside of the cooking chamber 101 through the cooking chamber exhaust port 121 flows through the exhaust passage P2 for cooling electrical components. The air flowing in the electrical component cooling exhaust flow path P2 is discharged into the room through the cooling exhaust port 115.

On the other hand, when the heater cooling fan 192 is driven, indoor air (dashed line) is sucked into the heater cooling intake flow path P3 through the heater cooling inlet 117. The air sucked into the heater cooling intake flow path P3 flows through the heater cooling intake flow path P3 and is transferred into the upper heater cover 191.

The air delivered into the upper heater cover 191 directly cools the upper heater 191 while flowing inside the upper heater cover 191. The air cooled by the upper heater 191 is transferred to the exhaust channel P4 for heater cooling. The air delivered to the heater cooling exhaust passage P4, that is, the air cooled by the upper heater 191 flows through the heater cooling exhaust passage P4, and passes through the cooling exhaust port 115. Is discharged.

4 and 5, when the vent pan assembly 196 is driven, food is cooked in a cooking apparatus installed below the microwave oven, for example, a gas oven range, through the hood inlet 161. Air containing the pollutants generated in the process (two dashed lines) is sucked into the inside of the microwave oven, that is, the first intake passage P6 for the hood. The air flowing through the hood first intake passage P6 is transferred to the hood second and third intake passages P7 and P8 by the continuous driving of the vent fan assembly 196.

That is, as shown in FIG. 4, a part of the air flowing through the first intake channel P6 for the hood is transferred to the second intake channel P7 for the hood. The air flowing through the hood second intake passage P7 is sucked into the intake portion 198A of the first vent fan 198. In addition, as shown in FIG. 5, the remainder of the air flowing through the first intake passage P6 for the hood flows through the third intake passage P8 for the hood to intake the second vent fan 199. Is sucked into the portion 198A.

Referring to FIG. 3 again, the air sucked into the intake portions 198A and 199A of the first and second vent fans 198 and 199, that is, the second and third intake passages P7 for the hood ( The air flowing through P8 is discharged to the exhaust sections 198B and 199B of the first and second vent fans 198 and 199. The air discharged to the exhaust parts 198B and 199B of the first and second vent pans 198 and 199 flows through the hood indoor exhaust passage P8, and the hood indoor exhaust port 113 is opened. Through the room. At this time, the air discharged into the room through the indoor exhaust port 113 for the hood is discharged into the room with the contaminants filtered by the filter.

In addition, the air discharged to the exhaust parts 198B and 199B of the first and second vent fans 198 and 199, in particular, the air discharged to the exhaust part 198B of the first vent fan 198. The upper heater 191 is indirectly cooled. In other words, a portion of the upper heater cover 194 is positioned on the air flow formed by the first vent fan 198, whereby the upper heater 191 is indirectly cooled.

Therefore, the upper heater 191 is directly cooled by the air flow formed by the heater cooling fan 195, and indirectly cooled by the air flow formed by the first vent fan 198. As such, since the upper heater 191 is directly and indirectly cooled, the cooling efficiency of the upper heater 191 may be substantially increased. In particular, in the case of a relatively high output heater such as a halogen heater or a carbon heater, the space required for the installation of the fan by not using a single fan or by using a high output fan for sufficient cooling of the heater is used. This can be increased to bring about a relative decrease in the volume of the cooking chamber 101. In this embodiment, the upper heater 191 is cooled directly and indirectly, it is possible to prevent such a problem.

In addition, in the present embodiment, the indirect cooling of the upper heater 191 is made by the vent fan assembly 196 for the hood function. Therefore, by not requiring an additional fan for indirect cooling of the upper heater 191, the number of parts can be reduced.

On the other hand, in the case of discharging air containing the pollutant generated in the cooking process in the cooking appliance to the outside, the exhaust fan of the vent pan assembly 196 and the outdoor exhaust vent 171 for the hood (see FIG. 1) and It is installed to communicate. Therefore, the air discharged from the exhaust part of the vent fan assembly 196 is discharged through the hood outdoor exhaust port 171 and flows through a duct (not shown) to be discharged to the outside.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art in light of the above teachings. will be.

According to the hood-use microwave oven according to the present invention as described above, the following effects can be expected.

First, in the present invention, the upper heater is directly cooled by the cooling fan, and indirectly cooled by the vent fan assembly for the hood function. Therefore, when the upper heater, in particular high output heater is used as the upper heater, by cooling it efficiently, it is possible to improve the operation reliability of the product.

In the present invention, the vent fan assembly is used for indirect cooling of the upper heater. Therefore, since a separate fan for indirect cooling of the upper heater is omitted, the upper heater can be cooled with a simpler configuration.

1 is an exploded perspective view showing an embodiment of a microwave oven according to the present invention.

2 is a plan view showing an embodiment of the present invention.

     3 is a plan view showing the flow of air in the embodiment of the microwave oven according to the present invention.

Claims (9)

A heater installed on an upper surface of a cavity in which a cooking chamber is provided and generating a heater heat provided into the cooking chamber; A heater cover to shield the heater; A front plate forming a front surface of the cavity and having an indoor exhaust vent for discharging air containing contaminants into the room; A base plate provided at a lower portion of the cavity and having an inlet for a hood through which air containing contaminants are sucked; A vent fan assembly installed on an upper surface of the cavity corresponding to the rear of the indoor exhaust port for the hood, and configured to form an air flow sucked through the hood inlet port and discharged through the indoor exhaust port for the hood; An indoor exhaust passage provided in the center of the upper surface of the cavity and through which the air discharged through the indoor exhaust vent for the hood is flown by the vent pan assembly; A cooling fan forming an air flow partitioned from an air flow formed by the vent fan assembly to cool the heater; And A first air duct for cooling the heater guiding the air flow formed by the cooling fan to the heater; Including, The heater is indirectly cooled by the air flow formed by the vent fan assembly cooling the outside of the heater cover, and the air flow formed by the cooling fan is transferred to the heater by the first air duct for cooling the heater. Hooded microwave oven that is directly cooled by guiding. The method of claim 1, The heater is a hood combined microwave oven which is any one of a bar type halogen heater and a carbon heater. delete The method of claim 1, The cooling fan is located between the front plate and the heater, the hood is combined with a hood to form an air flow is sucked through the inlet formed in the front plate and discharged through the exhaust port formed in the front plate after cooling the heater Microwave. The method of claim 1, And a second air duct for cooling the heater to guide the air cooled by the heater to be discharged through an exhaust hole formed in the front plate. The method of claim 1, And the heater and the heater cover are disposed to be inclined at a predetermined angle with respect to the front and rear surfaces of the cooking chamber so that at least a portion thereof is positioned on an imaginary straight line bisecting the cooking chamber left and right. The method of claim 1, The vent fan assembly, 1 vant motor; And First and second vent fans respectively driven by the vent motor to form an air flow; Hooded microwave oven including a. The method of claim 7, wherein And a flow path through which air is sucked into the first vent pan has a larger flow cross-sectional area than a flow path through which air is sucked into the second vent fan. The method of claim 8, At least a portion of the heater cover, the hood combined microwave disposed on the air flow formed by the first vent pan.

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