KR20130036415A - Microwave oven having hood - Google Patents

Abstract

PURPOSE: A combined microwave oven and hood is provided to install an exhaust fan assembly under a cavity, and maintain a distance between a cooking appliance installed under the oven and a cooking chamber, thereby prevent a user's injury due to heat from the cooking appliance. CONSTITUTION: A combined microwave oven and hood includes a cavity(110), a base plate(120), an out casing(140), an exhaust fan assembly, and multiple air guides(181,183). The cavity has an indoor exhaust port(113). The base plate separated from the bottom of the cavity has an inlet port(121). The out casing has an outdoor exhaust port(141). The exhaust fan assembly is installed on the upper surface of the base plate. The exhaust fan assembly sucks air inside the oven through the inlet port, and discharges the air indoors or outdoors through the indoor exhaust port or the outdoor exhaust port. The air guides guide the air run by the exhaust assembly.

Description

Microwave oven having hood {Microwave oven having hood}

The present invention relates to a microwave oven.

A microwave oven is a home appliance which cooks food using a microwave. Among such microwave ovens, a hood-use microwave oven is provided with a hood function for sucking and discharging a gas containing contaminants generated in a process of cooking food in a cooking apparatus installed below the microwave oven. Such microwave ovens are sometimes called wall-mounted microwave ovens or over-range (OTR) type microwave ovens. 1 is a longitudinal sectional view schematically showing a microwave oven according to the prior art.

Referring to FIG. 1, a cooking chamber 3 in which food is cooked is provided in the cavity 2 of the microwave oven 1. An intake port 5 is formed in the base plate 3 which forms the bottom of the microwave oven 1. The exhaust fan assembly 6 is installed on the upper surface of the cavity 2 corresponding to the upper side of the cooking chamber 3.

Conventionally, air containing contaminants generated in a cooking appliance, for example, an oven range installed below the microwave oven 1 by the driving of the exhaust fan assembly 6, causes the intake port 5 to be opened. It is sucked into the inside of the microwave oven 1 through. The air sucked into the microwave oven 1 flows through the flow path 7 provided at the lower and rear ends of the microwave oven 1. In addition, the air flowing through the flow path 7 is discharged into the room through the indoor exhaust port 8 provided in the front of the microwave oven 1, or the outdoor exhaust port 9 provided on the upper surface of the microwave oven 1. ) Is discharged to the outdoor (substantially hood).

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

In the prior art, the exhaust fan assembly 6 is provided on the upper surface of the cavity 2. Therefore, the cooking chamber 3 is adjacent to the cooking apparatus installed below the microwave oven 1 by a volume corresponding to the volume of the exhaust fan assembly 6 and substantially the height of the exhaust fan assembly 6. do. Therefore, in the process of dispensing food into and out of the cooking chamber 3, the user may be affected by heat generated by the cooking apparatus.

Also conventionally, the exhaust fan assembly 6 is positioned substantially adjacent to the indoor exhaust port 8 or the outdoor exhaust port 9 as compared to the intake port 5. That is, the exhaust fan assembly 6 is designed to have an installation position more advantageous for the discharge of the air through the indoor exhaust port 8 or the outdoor exhaust port 9 than the suction of the air through the intake port 5. Accordingly, a disadvantage is that the actual suction performance is lower than the output of the exhaust fan assembly 6 or the magnitude of noise generated by the operation of the exhaust fan assembly 6.

The present invention is to solve the problems caused by the prior art as described above, an object of the present invention is to provide a hood-use microwave oven configured to minimize the influence from the cooking apparatus installed below.

It is another object of the present invention to provide a hood-use microwave oven capable of improving air intake performance.

One aspect of an embodiment of a hood-use microwave oven according to the present invention for achieving the above object is a hood-use microwave oven provided with a hood function: a cooking chamber is provided, the indoor exhaust port for discharging air into the room Cavity being; A base plate which forms a bottom of the microwave oven, is spaced apart from the bottom of the cavity, and has an inlet for sucking air; An outer casing which forms an outer surface of both sides of the microwave oven and is provided with an outdoor exhaust port for discharging air to the outside; A back plate forming a rear surface of the microwave oven, the back plate being spaced apart from the rear surface of the cavity; An exhaust fan assembly installed on an upper surface of the base plate and configured to suck air into the microwave oven through the inlet port and discharge the air to the indoor or outdoor area through the indoor exhaust port or the outdoor exhaust port; And a plurality of air guides for guiding air flowing by the exhaust fan assembly. The exhaust fan assembly includes at least two exhaust fans, and the air guide partitions the air flowing by the exhaust fan.

According to another aspect of a microwave oven with a hood according to an embodiment of the present invention, in a hood microwave oven with a hood function: a cavity having a cooking chamber, the interior exhaust port for discharging air into the room; A base plate defining an intake flow path between the bottom and the bottom of the cavity; A back plate defining a rear surface of the cavity and a first exhaust flow path; An out casing defining an upper surface of the cavity and a second exhaust flow path; A first installed on the intake flow path and configured to flow the intake flow path and the first and second exhaust flow paths to be discharged indoors, or to form a flow of air discharged to the outside by flowing the intake flow path and the first exhaust flow path And a second exhaust fan assembly; And a plurality of air guides disposed on the first exhaust flow path and partitioning air flowing by the first and second exhaust fan assemblies. Wherein the first and second exhaust fan assemblies each include one exhaust motor, and two exhaust fans respectively coupled to both sides of the exhaust motor, wherein the air guide is flown by the exhaust fan. Partition the air.

According to the embodiment of the hood-use microwave oven according to the present invention, an exhaust fan assembly is provided below the cavity. Therefore, the distance between the cooking appliance and the cooking compartment that is substantially installed below the microwave oven is maintained, so that the user can be prevented from injury due to heat generated in the cooking apparatus in the process of dispensing food into and out of the cooking chamber. do.

Also in an embodiment of the invention, the exhaust fan assembly is positioned relatively adjacent to the inlet port. Therefore, the suction efficiency of the air through the intake port can be relatively improved.

In an embodiment of the present invention, the exhaust fan assembly includes a plurality of fans, and the air sucked and discharged by the fans is partitioned and flows so as not to interfere with each other. Therefore, a plurality of fans can be used to intake and exhaust air more efficiently.

1 is a longitudinal sectional view schematically showing a microwave oven according to the prior art.
Figure 2 is a longitudinal sectional view showing a first embodiment of a hood-use microwave oven according to the present invention.
Figure 3 is an exploded perspective view showing a first embodiment of the present invention.
Figure 4 is a front view showing the main part of the first embodiment of the present invention.
5 is a front view showing the main part of a second embodiment of a hood-use microwave oven according to the present invention;

Hereinafter, with reference to the accompanying drawings a first embodiment of a hood-use microwave oven according to the present invention will be described in more detail.

2 is a longitudinal sectional view showing a first embodiment of a hood-use microwave oven according to the present invention, Figure 3 is an exploded perspective view showing a first embodiment of the present invention, Figure 4 is a main part of the first embodiment of the present invention It is a front view shown.

2 to 4, the cooking chamber 111 is provided inside the cavity 110 of the hood-use microwave oven 100 (hereinafter referred to as a “microwave oven” for convenience of description). The cooking chamber 111 is a place where food is cooked.

An indoor exhaust port 113 is formed on the front surface of the cavity 110. The indoor exhaust port 113 is a place where the air sucked into the inside of the microwave oven 100 by the exhaust fan assembly 150, 160 to be described later is discharged to the room. The indoor exhaust port 113 is formed by cutting a portion of the front upper end of the cavity 110 corresponding to the upper side of the cooking chamber 111.

The base plate 120 is coupled to a lower portion of the cavity 110 corresponding to the lower side of the cooking chamber 111. The base plate 120 substantially forms the bottom of the microwave oven 100. The base plate 120 is positioned so that an upper surface thereof is spaced apart from a bottom surface of the cavity 110. Hereinafter, a space between the bottom surface of the cavity 110 and the top surface of the base plate 120 is called an intake flow path Pi.

An intake port 121 is formed in the base plate 120. The inlet 121 is formed by cutting a portion of the bottom surface of the base plate 120. The intake port 121 sucks air containing contaminants generated during cooking of food in a cooking apparatus installed below the microwave oven 100, for example, a gas oven or an electric oven. It serves as an entrance. And a filter 123 is provided on the inlet 121. The filter 123 serves to remove contaminants, for example, oil or the like contained in the air sucked through the inlet 121.

The back plate 130 is coupled to the rear end of the cavity 110. The back plate 130 substantially forms a rear surface of the microwave oven 100. At this time, the back plate 130, the front side is positioned to be spaced apart from the rear of the cavity (110). Hereinafter, a space between the rear surface of the cavity 110 and the front surface of the back plate 130 is referred to as a first exhaust flow path Po1. Therefore, the lower end of the first exhaust flow path Po1 communicates with the rear end of the intake flow path Pi.

In addition, the outer casing 140 is coupled to the cavity 110, the base plate 120, and the back plate 130. The out casing 140 forms an upper surface and both side surfaces of the microwave oven 100. On the other hand, the upper surface of the out casing 140 is spaced apart from the upper surface of the cavity 110 by a predetermined distance.

An outdoor exhaust port 141 is formed on an upper surface of the out casing 140 forming the upper surface of the microwave oven 100. The outdoor exhaust port 141 is located substantially above the first exhaust flow path Po1. And the size and location of the outdoor exhaust port 141 is defined by the standard. The outdoor exhaust port 141 is substantially bisected by an imaginary straight line bisecting the upper surface of the microwave oven 100 to the left and right, and has a smaller size than the cross section of the first exhaust passage Po1. The outdoor exhaust port 141 may be in communication with a hood (not shown).

The microwave oven 100 is provided with a plurality of exhaust fan assembly (). The exhaust fan assembly 2 sucks air containing contaminants into the microwave oven 100 through the inlet 121, and sucks the air into the indoor exhaust port 113 or the outdoor exhaust port 141. It serves to discharge indoors or outdoors. In the present embodiment, the exhaust fan assembly 150, 160 is composed of two. Hereinafter, for convenience of description, the exhaust fan assembly 150 on the left side of the drawing is referred to as a first exhaust fan assembly 150 in FIGS. 3 and 4, and the exhaust fan assembly 160 on the right side of the drawing is referred to as a second exhaust fan assembly ( 160).

The first and second exhaust fan assemblies 160 include one exhaust motor 151, 161, and two exhaust fans 153, 155, 163, and 165, respectively. Substantially, the exhaust motors 151 and 161 provide a driving force for the rotation of the exhaust fans 153, 155, 163 and 165. The exhaust fans 153, 155, 163, and 165 are coupled to both sides of the exhaust motors 151 and 161. The first and second exhaust fan assemblies 160 have a portion defined by a rear end of the base plate 120 and a lower end of the back plate 130, that is, the intake flow path Pi is disposed at a rear end of the exhaust fan ( Any one of 153, 155, 163, and 165 is disposed left and right to be adjacent to each other. Hereinafter, for convenience of description, the exhaust fan 153 of the first exhaust fan assembly 150 of the exhaust fan 153 and 155 of FIG. 3 and FIG. Among the exhaust fans 153 and 155 of the first exhaust fan assembly 150, the exhaust fan 155 on the right side of the drawing in FIGS. 3 and 4 is replaced by the first inner exhaust fan 155 and the second exhaust fan assembly. 3 and 4 of the exhaust fan 163 and 165 of the exhaust fan 160 of the 160, the exhaust fan 163 of the second outer exhaust fan 163, the exhaust fan of the second exhaust fan assembly 160 3 and 4, the exhaust fan 165 on the left side of the drawing is referred to as a second inner exhaust fan 165. Accordingly, the first and second outer exhaust fans 153 and 163 are positioned substantially further apart from the outdoor exhaust port 141 than the first and second inner exhaust fans 155 and 165. do.

In addition, the partition member 170 is provided above the first and second exhaust fan assemblies 160. The partition member 170 serves to partition the intake flow path Pi and the first exhaust flow path Po1. To this end, the partition member 170 may be formed in a plate shape having a shape and a size corresponding to a cross section of the first exhaust channel Po1. Also, the first and second exhaust fan assemblies 160 are substantially fixed to the partition member 170. Accordingly, the partition member 170 may be referred to as a fan mount for fixing the first and second exhaust fan assemblies 160.

In addition, a plurality of exhaust openings 171 and 173 are formed in the partition member 170. The exhaust openings 171 and 173 are configured to provide air from the intake flow path Pi to the first exhaust flow path Po1 by the first and second exhaust fan assemblies 160 and substantially the exhaust fan. Acts as an outlet through which is discharged. The exhaust openings 171 and 173 are configured in plural numbers, and are substantially positioned directly above the exhaust fan 각각, respectively. For convenience of explanation, hereinafter, the leftmost and rightmost ones in the drawings are referred to as the inner exhaust opening 173 between the outer exhaust opening 171 and the outer exhaust opening 171.

In addition, a plurality of air guides 181 and 183 are provided on the second flow path (). The air guide 180 partitions the air discharged into the first exhaust flow path Po1 through the outer exhaust openings 171 and 173 and the inner exhaust openings 171 and 173. In addition, the air guide 180 guides the air flowing through the first exhaust flow path Po1 to the second exhaust flow path Po2 to be described later, or guides the air to the outdoor exhaust port 141.

In this embodiment, the air guide 180 partitions the air discharged through the outer exhaust openings 171 and 173 and the inner exhaust openings 171 and 173. The air guide 180 includes two first and second air guides 181 and 183, respectively. The first and second air guides 181 and 183 extend inclined at a predetermined angle with respect to the vertical direction so that upper and lower ends thereof are positioned on the outdoor exhaust port 141 and the partition member 170, respectively. Substantially, the first air guide 181 is spaced apart from side to side, and the second air guide 183 is spaced from side to side between the first air guide 181.

In more detail, an upper end of the first air guide 181 is in contact with both end portions of the outdoor exhaust port 141, respectively. A lower end of the first air guide 181 is in contact with an upper surface of the partition member 170 corresponding to the outer side of the outer exhaust openings 171 and 173, respectively. An upper end of the second air guide 183 is located inside the outdoor exhaust port 141. In this case, an upper end of the second air guide 183 may be positioned to be relatively adjacent to both end portions of the outdoor exhaust port 141 as compared with the point of dividing the outdoor exhaust port 141 into three parts. A lower end of the second air guide 183 is in contact with an upper surface of the partition member 170 corresponding to the outer exhaust openings 171 and 173 and the inner exhaust openings 171 and 173. Therefore, as the space corresponding to the first and second air guides 181 and 183, the outer and outer exhaust openings 171 and 173 are formed by the first and second outer exhaust fans 153 and 163. Air discharged through each flows. In addition, the air discharged through the inner exhaust openings 171 and 173 by the first and second inner exhaust fans 155 and 165 may be a space corresponding to the second air guide 183. Flow together.

However, due to the size and position of the outdoor exhaust port 141, the first and second outer exhaust fans 153 and 163 are compared with the air flowing by the first and second inner exhaust fans 155 and 165. Air flowing by) flows relatively inclinedly. In other words, the air flowing by the first and second inner exhaust fans 155 and 165 is relatively linear compared to the air flowing by the first and second outer exhaust fans 153 and 163. Flows into. Accordingly, the flow resistance of the air flowing by the first and second outer exhaust fans 153 and 163 is greater than that of the first and second inner exhaust fans 155 and 165. In the present embodiment, in order to solve such a problem, at the same height, the left and right distance between the second air guide 183 is equal to 2 of the left and right distance between the first and second air guides 181 and 183. It is set to a value less than twice. In other words, at the same height, the flow cross-sectional area between the second air guides 183 is set to a value less than the sum of the flow cross-sectional areas between the first and second air guides 181 and 183.

Meanwhile, an exhaust duct 190 is provided on the upper surface of the cavity 110. The exhaust duct 190 defines a second exhaust flow path Po2 together with an upper surface of the out casing 140. The second exhaust flow path Po2 serves to guide the air flowing through the first exhaust flow path Po1 to the indoor exhaust port 113. To this end, a rear end of the second exhaust flow path Po2 communicates with an upper end of the first exhaust flow path Po1. The front end of the second exhaust flow path Po2 communicates with the indoor exhaust port 113.

Although not shown, a damper member may be provided on the exhaust duct 190. The damper member selectively opens and closes the second exhaust flow path Po2. That is, when the air flowing through the first exhaust flow path Po1 is discharged into the room through the indoor exhaust port 113, the damper member opens the first exhaust flow path Po1. When the air flowing through the first exhaust flow path Po1 is discharged to the outside through the outdoor exhaust port 141, the damper member shields the first exhaust flow path Po1.

In addition, a filter member (not shown) may be provided on the exhaust duct 190. The filter member removes contaminants contained in the air discharged through the indoor exhaust port 113 after the second exhaust flow path Po2 flows.

Although not shown, the microwave oven 100 is provided with a heating source for cooking food in the cooking chamber 111. For example, a magnetron for irradiating microwaves into the cooking chamber 111, a heater for providing heater heat into the cooking chamber 111, and circulating hot air into the cooking chamber 111. A convection device may be provided.

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

First, contaminants, that is, moisture or oil, and odorous substances are generated in the process of cooking food in a cooking apparatus installed below the microwave oven 100. When the first and second exhaust fan assemblies 160 operate, air containing such contaminants is sucked into the microwave oven 100.

More specifically, when the first and second exhaust fan assembly 160 is operated, air containing contaminants is sucked through the inlet port 121 and flows through the inlet flow path Pi. However, in the present exemplary embodiment, the first and second exhaust fan assemblies 160 are positioned adjacent to the intake port 121 relative to the conventional installation of the exhaust fan assembly on the upper surface of the cavity. Accordingly, when the first and second exhaust fan assemblies 150 and 160 operate, the suction efficiency of the air through the inlet 121 may be improved as compared with the related art. In addition, by concentrating the suction efficiency of the air, it is possible to substantially prevent the diffusion of air containing contaminants generated in the cooking process in the cooking appliance.

On the other hand, the air flowing through the intake flow path Pi is transferred from the intake flow path Pi to the first exhaust flow path Po1 by the continuous operation of the first and second exhaust fan assemblies 160. However, in the present exemplary embodiment, a plurality of exhaust fans constituting the first and second exhaust fan assemblies 160, that is, the first outer exhaust fan 153, the second outer exhaust fan 163, and the first and second exhaust fans are formed. Air delivered from the first exhaust flow path Po1 to the second exhaust flow path Po2 by the two inner exhaust fans 155 and 165 is divided by the first and second air guides 181 and 183. do. In addition, a cross sectional area of a space in which air flows by the first and second outer exhaust fans 153 and 163 in which the flow of air is relatively inclined is determined by the first and second inner exhaust fans 155 ( 165) is relatively large compared to that of the space in which air flows. Therefore, the flow resistance of the air flowing by the first and second exhaust fan assembly 160 can be relatively reduced.

Meanwhile, the air flowing through the first exhaust flow path Po1 is discharged to the indoor or outdoor through the indoor exhaust port 113 or the outdoor exhaust port 141. That is, the air flowing through the first exhaust channel Po1 is selectively discharged indoors or outdoors.

More specifically, when air is discharged to the room through the indoor exhaust port 113, the second exhaust flow path Po2 is opened by the damper member, and the outdoor exhaust port 141 is shielded. Therefore, the air flowing through the first exhaust flow path Po1 is transferred to the second exhaust flow path Po2. In addition, the air flowing through the second exhaust flow path Po2 is discharged to the room through the indoor exhaust port 113. At this time, in the process of air flowing through the second exhaust flow path (Po2), the pollutant contained in the air is removed by the filter member.

On the other hand, when air is discharged to the outside through the outdoor exhaust port 141, the second exhaust flow path Po2 is shielded by the damper member, and the outdoor exhaust port 141 is opened. Therefore, the air flowing through the first exhaust channel Po1 is transferred to the hood through the outdoor exhaust port 141 and discharged to the outside.

Hereinafter, with reference to the accompanying drawings a second embodiment of a hood-use microwave oven according to the present invention will be described in more detail.

5 is a front view showing the main part of a second embodiment of a hood-use microwave oven according to the present invention. For the same components as those of the first embodiment of the present invention described above among the components of the present embodiment, reference numerals of FIGS. 1 to 4 are used, and detailed description thereof will be omitted.

Referring to FIG. 5, in the present embodiment, the air guide 180 ′, that is, the first and second air guides 181 ′ and 183 ′ is bent a plurality of times at a predetermined angle. Therefore, in the case of a relatively upstream side in the flow direction of air, the flow cross-sectional area of the space between the first and second air guides 181 'and 183' and the space between the second air guide 183 'is increased. This is relatively increased compared to the first embodiment of the present invention described above. However, in the case of a relatively upstream side in the flow direction of air, since it is relatively adjacent to the first and second exhaust fan assembly 160, it can be said that the flow rate of air is also faster. Therefore, according to the shape of the first and second air guides 181 'and 183', substantially the first and second exhaust fan assemblies 160, that is, the first and second outer exhaust fans 153 and 163. ) And the air flowing by the first and second inner exhaust fans 155 and 165 may collide with the first and second air guides 181 ′ and 183 ′ to prevent vortex generation. . In particular, the air flowing by the first and second outer exhaust fans 153 and 163 may be prevented from hitting the first air guide 181 ′. Therefore, according to this embodiment, more efficient air flow can be expected than in the first embodiment of the present invention.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. .

In the above-described embodiments, the exhaust fan assembly is described as being composed of two, but only one exhaust fan assembly may be provided. In this case, the air guide will also be composed of three.

Claims (15)

In a hooded microwave oven with hood function:
A cavity having a cooking chamber and having an indoor exhaust port for exhausting air into the room;
A base plate which forms a bottom of the microwave oven, is spaced apart from the bottom of the cavity, and has an inlet for sucking air;
An outer casing which forms an outer surface of both sides of the microwave oven and is provided with an outdoor exhaust port for discharging air to the outside;
A back plate which forms a rear surface of the microwave oven and whose front surface is spaced apart from the rear surface of the cavity;
An exhaust fan assembly installed on an upper surface of the base plate and configured to suck air into the microwave oven through the inlet port and discharge the air to the indoor or outdoor area through the indoor exhaust port or the outdoor exhaust port; And
A plurality of air guides for guiding air flowing by the exhaust fan assembly; Including,
The exhaust fan assembly comprises at least two exhaust fans,
The air guide is a hood, microwave oven that partitions the air flowing by the exhaust fan.
The method of claim 1,
And the air guide is disposed between the rear of the cavity and the front of the back plate.
The method of claim 1,
The upper ends of the air guides are positioned apart from each other on the exhaust port,
And a lower end of the air guide is disposed between the exhaust fan.
The method of claim 1,
And the exhaust fan assembly is installed in a partition member that divides a space defined by a bottom surface of the cavity and an upper surface of the base plate and a space defined by a rear surface of the cavity and a front surface of the back plate.
The method of claim 4, wherein
The partition member is formed with a number corresponding to the exhaust fan, an exhaust opening through which the air flowing by the exhaust fan is discharged is formed,
And a lower end of the air barrier is in contact with an upper surface of the partition member corresponding to the exhaust openings.
The method of claim 1,
The exhaust fan assembly,
A first exhaust fan assembly including an exhaust motor, a first outer exhaust fan coupled to one side of the exhaust motor, and a first inner exhaust fan positioned on the other side of the exhaust motor; And
A second exhaust fan assembly including an exhaust motor, a second outer exhaust fan coupled to one side of the exhaust motor, and a second inner exhaust fan coupled to the other side of the exhaust motor; Including,
And the first and second exhaust fan assemblies are disposed side to side so that the first and second inner exhaust fans are adjacent to each other.
The method according to claim 6,
The air guide has a larger value than the sum of the cross sectional flow areas of the air flowing by the first and second inner exhaust fans and the sum of the cross sectional areas of the air flowing by the first and second inner exhaust fans. And a hood combined microwave for partitioning the space between the rear of the cavity and the front of the back plate.
The method according to claim 6,
The air guide includes two first air guides spaced apart from left and right, and a second air guide spaced apart from side to side between the first air guides.
Air discharged from the first and second outer exhaust fans flows into a space between the first and second air guides, respectively.
The air discharged from the first and second inner exhaust fan, the hood combined microwave flows into the space between the second air guide.
In a hooded microwave oven with hood function:
A cavity having a cooking chamber and having an indoor exhaust port for exhausting air into the room;
A base plate defining an intake flow path between the bottom and the bottom of the cavity;
A back plate defining a rear surface of the cavity and a first exhaust flow path;
An out casing defining an upper surface of the cavity and a second exhaust flow path;
A first installed on the intake flow path and configured to flow the intake flow path and the first and second exhaust flow paths to be discharged indoors, or to form a flow of air discharged to the outside by flowing the intake flow path and the first exhaust flow paths; And a second exhaust fan assembly; And
A plurality of air guides disposed on the first exhaust flow path and partitioning air flowing by the first and second exhaust fan assemblies; Including,
The first and second exhaust fan assemblies each include one exhaust motor and two exhaust fans respectively coupled to both sides of the exhaust motor,
The air guide is a hood, microwave oven that partitions the air flowing by the exhaust fan.
The method of claim 9,
The intake flow passage communicates with the intake port formed in the base plate,
The first exhaust flow path communicates with an outdoor exhaust port formed at a rear end of the intake flow path and the out casing,
And the second exhaust flow path communicates with an indoor exhaust port formed at an upper end of the first exhaust flow path and in front of the cavity.
The method of claim 9,
The air guide is a hood, microwave oven for partitioning the air flow by the exhaust fan constituting the first and second exhaust fan assembly.
The method of claim 9,
The first and second exhaust fan assembly is disposed left and right on the intake passage so that any one of the exhaust fan is adjacent to each other,
The air guide may include an exhaust fan of the first and second exhaust fan assemblies as compared with a cross section of a space in which air discharged from two exhaust fans spaced apart from each other among the exhaust fans of the first and second exhaust fan assemblies flows. A hood-use microwave oven that divides the first exhaust flow path such that a cross section of a space in which air discharged from two exhaust fans closest to each other flows has a relatively small value.
The method of claim 9,
And the first and second exhaust fan assemblies are fixed to a fan mount having a plurality of exhaust openings through which air discharged from the exhaust fan flows.
The method of claim 13,
The fan mount partitions the intake passage and the first exhaust passage,
And the exhaust opening is configured to have a number corresponding to the exhaust fan.
The method of claim 13,
The upper and lower ends of the air guide are respectively positioned on the outdoor exhaust port and the fan mount through which the air flowing in the first exhaust flow path is discharged to the outside,
The second exhaust passage is in communication with an indoor exhaust port through which air is discharged to the room,
When the second exhaust flow path is opened, air flowing through the first and second exhaust flow paths is discharged into the room through the indoor exhaust port,
When the second exhaust flow path is shielded, the hood combined microwave that the air flowing through the first exhaust flow path is discharged to the outside through the outdoor exhaust port.

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