KR20230041480A - Air hood for Electric range - Google Patents

Abstract

The present invention provides an air hood for an electric range, capable of more efficiently exhausting pollutants to the outside by forming an air curtain on the inner side of an electric range, and the air hood for an electric range comprises a hood body located above the electric range, and spray holes formed on the bottom edge of the hood body and including a first side spray hole located on a first side surface and a second side spray hole located on a second side surface, wherein the air discharged from the first side spray hole and the second side spray hole is sprayed to the side or upper region of the electric range towards the inside of the electric range.

Description

Air hood for electric range {Air hood for Electric range}

The present invention relates to an air hood for an electric range for more efficiently exhausting pollutants to the outdoors by forming an air curtain toward the inside of the range.

Kitchen hoods are used to prevent air pollution in the kitchen by discharging combustion gases, food odors, and water vapor generated during food cooking to the outside.

A conventional kitchen hood is installed on top of a kitchen cooking appliance, and discharges the contaminants to the outside using an exhaust fan.

However, even if the hood is operated, there is a problem in that some of the contaminants are diffused into the room without being discharged to the outside.

A method of increasing the capacity of an exhaust fan in order to discharge the pollutants more quickly may be considered, but in this case, there are problems in that the size of the exhaust fan increases, requiring a lot of installation space and cost.

In addition, when the kitchen hood is operated, the gas cooktop is effective because it delivers pollutants to the vicinity of the suction end of the hood by buoyancy caused by gas combustion and diffusion of heat around it. There is a problem in that it does not have an exhaust effect as much as that of the gas cooktop due to the characteristics of the electric range in which contaminants are irregularly diffused from the point of occurrence.

The present invention is to solve the above problems, and an object of the present invention is to provide an air hood for an electric range for more efficiently exhausting pollutants to the outdoors by forming an air curtain toward the inside of the electric range.

The present invention provides the following air hood for an electric range in order to achieve the above object.

In one embodiment of the present invention, a hood body positioned above an electric range, a first side spray hole formed on a bottom edge of the hood body, and positioned on a first side surface side, and a second side spray hole positioned on a second side surface side Provides an air hood for an electric range including a nozzle comprising a, wherein the air discharged from the first side nozzle and the second side nozzle is injected toward the inside of the electric range to the side or upper region of the electric range. .

In one embodiment, the discharged air may form a first inclination angle with the lower surface of the hood body.

In one embodiment, the first inclination angle may be 40° to 75° based on a horizontal line positioned inside the hood among horizontal lines parallel to the bottom surface of the hood body.

In one embodiment, the air volume of the discharged air may be 20 to 25 CMH.

In one embodiment, the spray hole may further include a front spray hole located on the front side of the hood body.

In one embodiment, the jetting hole further includes a jetting guide, and the jetting guide is made of a pair of opposing jetting guide members, and the inner surfaces of the jetting guide members face each other at a jetting angle of the air discharged from the jetting hole. It may include a first spray guide made of an inclined shape.

In one embodiment, the jetting guide may include a second jetting guide connected to a blade for adjusting a jetting angle of the discharged air.

In one embodiment, the air discharged from the front spray hole may form a second inclination angle with the bottom surface of the hood body.

In one embodiment, the spray guide may be formed by bending an end of a housing surrounding each of the spray holes.

The present invention can provide an air hood for an electric range for more efficiently exhausting pollutants to the outdoors by forming an air curtain in the inner direction of the electric range through the structure of the air hood as described above.

1 is a cross-sectional view showing a kitchen in which a hood forming an air curtain is installed outside a cooking appliance.
Figure 2 is a cross-sectional view and a graph showing the generation tendency of fine dust during cooking in an electric range.
3 is a schematic perspective view showing a bottom surface of an air hood body according to an embodiment of the present invention.
4 is a cross-sectional plan view showing the internal structure of an air hood according to an embodiment of the present invention.
5 is a 1-1' sectional view of FIG. 3;
6 is a cross-sectional view showing a kitchen in which an air hood is installed according to an embodiment of the present invention.
7 is a graph comparing conditions according to an embodiment of the present invention with other conditions.
8 is a cross-sectional view showing a spray guide according to another embodiment of the present invention.
9 is a cross-sectional view showing a spray guide according to another embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention may add, change, or delete other components within the scope of the same spirit, through other degenerative inventions or the present invention. Other embodiments included within the scope of the inventive idea can be easily suggested, but it will also be said to be included within the scope of the inventive idea.

In addition, throughout the specification, that a component is 'connected' to another component includes not only the case where these components are 'directly connected', but also the case where they are 'indirectly connected' through other components. means that In addition, 'including' a certain component means that other components may be further included, rather than excluding other components unless otherwise stated.

In addition, components having the same function within the scope of the same idea appearing in the drawings of each embodiment are described using the same reference numerals.

This application is derived based on published patent application KR 10-2020-0115182A previously filed by the present inventor, and the contents of the prior application may be cited in implementing embodiments of the present invention to be described later.

1 includes both side nozzles 11 on the bottom surface of the exhaust device body 10, and the air discharged from the both side nozzles 11 is directed to the outside of the cooking appliance 1 through the air curtains AC 1 and AC 2 Forming is shown. The air curtains AC 1 and AC 2 prevent polluted air generated during cooking from spreading to the outside of the cooking appliance 1 to maintain indoor air in a comfortable state.

However, in the case of the exhaust system of FIG. 1, when the air curtains AC 1 and AC 2 are formed outside the cooking appliance 1, the gas cooktop 20 has good performance in preventing the diffusion of indoor contaminants On the other hand, the cooktop with a built-in electric range (200, see FIG. 2) such as induction does not show that much performance.

Figure 2 (a) shows the trend of contaminant generation when cooking on an induction cooktop, and Figure 2 (b) shows the measured amount of pollutants over time on a gas cooktop and an induction cooktop when an exhaust device is used. there is.

As shown in FIG. 2 (a), since gas combustion is not involved in the induction cooktop 200, contaminants in the induction cooktop 200 generate less buoyancy or thermal diffusion due to the combustion process, so the center of the generation point spread irregularly.

Referring to FIG. 2 (b), the pollutant exhaust performance according to the operation of the exhaust device in each of the gas cooktop and the induction cooktop is compared.

Before operating the exhaust system, the amount of pollutants generated in the induction cooktop was lower than that of the gas cooktop.

On the other hand, as a result of comparing the graph showing the amount of pollutants generated in the gas cooktop after operating the exhaust device and the amount of pollutants generated in the gas cooktop before operating the exhaust device, as a result of operating the exhaust device, the amount of pollutants generated is ① A decrease is shown. In addition, when a graph showing the amount of pollutants generated in the induction cooktop after operating the exhaust device is compared with a graph showing the amount of pollutants generated in the induction cooktop before operating the exhaust device, it is shown that the amount of pollutants is reduced by ②.

That is, before the exhaust device is operated, the induction cooktop generates less pollutants than the gas cooktop, but when the exhaust device is operated, the reduction amount is higher in the gas cooktop (① > ②). This means that the exhaust performance of pollutants according to the operation of the exhaust system is declining in the induction cooktop.

Therefore, it is necessary to design the structure of the exhaust system differently according to the fine dust generation tendency.

The present invention is to solve the above problems, and an object of the present invention is to provide an air hood for an electric range for forming an air curtain in the upper inner region of the electric range.

3 to 5 show an air hood for an electric range according to an embodiment of the present invention. Specifically, FIG. 3 is a schematic perspective view showing the bottom of an air hood according to an embodiment of the present invention, and FIG. 4 is a cross-sectional plan view of an internal structure of an air hood according to an embodiment of the present invention. FIG. 5 shows a 1-1' sectional view of FIG. 4 .

As shown in FIG. 3 , the hood body 100 is provided with a housing 170 surrounding the outside, and the housing 170 may have a flat rectangular cylinder shape with a rectangular plane section.

An inlet 140 for sucking in polluted air generated during cooking is formed at the center of the lower surface of the hood main body 100, and the inlet 140 is used to filter foreign matter particles such as oil contained in the contaminated air. Filters (140a, 140b) for this are combined. The polluted air sucked in through the filters 140a and 140b is exhausted to the outdoors through an exhaust duct 300 (see FIG. 6) by an exhaust fan (not shown).

The filters 140a and 140b may be provided in plural according to the size of the hood body 100. For example, the first filter 140a provided on one side of the lower surface of the hood body 100 and the hood body 100 It may be made of a second filter (140b) provided on the other side of the lower surface of.

Spray holes 110, 120, and 130 for spraying air for air curtains are formed around the edge of the bottom surface of the hood body 100. The plurality of spray holes 110 , 120 , and 130 may be formed as one connected spray hole along the circumference of the bottom surface of the hood body 100 , or may be formed with a plurality of spray holes spaced apart from each other.

The plurality of injection holes 110, 120, and 130 of FIG. 3 are located on the bottom surface of the hood body 100 and have an open shape along the longitudinal direction of the first side surface 100a of the hood body 100 to provide air It may be composed of a first side spray hole 110 for spraying air and a second side spray hole 120 for spraying air formed in an open shape along the longitudinal direction of the second side surface side 100b of the hood body 100. . Furthermore, the hood main body 100 may further include a front spray hole 130 configured to open along the longitudinal direction of the front side 100c and spray air.

The front spray hole 130 may be provided in plural according to the size of the hood body 100, and a first front spray hole 130a formed on one side of the front side 100c and a front spray hole 130a formed on the other side of the front side 100c. It may be made of a second front spray hole (130b).

In addition, each of the plurality of spray holes 110, 120, and 130 corresponds to the length of each side of the first side surface 100a, the second side surface 100b, and the front side 100c of the hood body 100. It may be formed in a slot shape by cutting the lower surface of the housing 170 in length.

A suction port (not shown) may be provided on an upper surface of the hood body 100 . A first side inlet (116, see FIG. 5) positioned above the first side spray hole 110 and a second side intake (not shown) positioned above the second side spray hole 120 may be provided. And, a front suction port (not shown) located above the front spray port 130 may be provided. Therefore, the air introduced through the inlet (not shown) can be sprayed through the injection holes (110, 120, 130), and the air introduced through the inlet (not shown) is made of indoor air. can In addition, when the intake port (not shown) leads to the outdoors, outdoor air may be introduced and sprayed through the spray ports 120 , 130 , and 140 .

Referring to FIG. 4 , a plurality of air blowing units 110P, 120P, and 130P are provided inside the hood body 100 .

The first side air injection unit 110P located on the first side side 100a is composed of a first side fan 161 and a first side motor 151 for rotating the first side fan 161. can

The second side air injection unit 120P located on the second side side 100b is composed of a second side fan 162 and a second side motor 152 for rotating the second side fan 162. can

The front air injection unit 130P located on the front side 100c may include front fans 163 and 164 and a front motor 153 for rotating the front fans 163 and 164 . In addition, the front motor 153 is disposed in the center, a pair of first front fan 163 and a second front fan 164 are provided on both sides of the front motor 153, and the front motor ( 153 causes the first front fan 163 and the second front fan 164 to rotate simultaneously.

The first side fan 161, the second side fan 162, and the front fans 163 and 164 are the front side 100a, the first side side 100b, and the second side side of the hood body 100. It can be composed of a cross-flow fan having a length corresponding to the length of each side of (100c).

The cross-flow fan is called a crossflow fan or a tangential fan, and is a fan having one or a plurality of fan blocks made of a plurality of blades curved in the rotational direction, and the suction flow in the axial direction is There is no flow, and the flow occurs in a plane perpendicular to the axis of the fan block. Therefore, by using the cross-flow fan, it is possible to form a downward-flowing air curtain on three surfaces of the front and both sides with a simple configuration while minimizing the size of the hood body 100, thereby reducing exhaust including the hood body 100. The size of the device (not shown) can be configured in a compact size.

When the first side motor 151, the second side motor 152 and the front motor 153 are driven, the first side fan 161, the second side fan 162 and the front fan 163, 164) is rotated, and the air introduced into the hood body 100 through the first side inlet (116, see FIG. 5), the second side inlet (not shown), and the front inlet (not shown) is blown into the hood body 100. It is sprayed downward into the electric range (200, see FIG. 6) through the first side spray hole 110, the second side spray hole 120, and the front spray hole 130.

Meanwhile, a plurality of blocking walls 141 , 142 , and 143 are provided to divide the inner space of the hood body 100 into a plurality of inner space portions 101 , 102 , 103 , and 104 .

The blocking walls 141, 142, and 143 include a central inner space portion 104 (see FIG. 5) equipped with an exhaust fan (not shown) and a first side interior portion equipped with the first side air injection unit 110P. The first side blocking wall 141 for partitioning between the space portions 101, the inner space portion 104 in the center (see FIG. 5) and the second side air injection portion 120P are provided inside the second side The front inner space 103 provided with the second side blocking wall 142 for partitioning between the spaces 102, the central inner space 104 (see FIG. 5) and the front air injection part 130P. ) It consists of a front blocking wall 143 for partitioning between.

FIG. 5 is a 1-1' cross-sectional view of FIG. 4 , and the internal structure of the first side air injection unit 110P having the first side fan 161 will be described with reference to FIGS. 4 and 5 .

The first side air injection unit 110P and the second side air injection unit 120P may have the same configuration symmetrically, and in the case of the front nozzle 130, from the front nozzle 130 to the inside of the electric range. Except for the second inclination angle θ2 (not shown) formed by the air ejected toward the hood body 100 and the bottom surface, it is the same as the embodiment described with reference to FIG. 5 .

Therefore, the same reference numerals are given to the components performing the same functions as those of one embodiment for the second side injection hole 120 and the front injection hole 130, and detailed descriptions are omitted.

The first side air injection unit 110P includes a first side fan 161 provided under the first side inlet 116 and provided between the first side fan 161 and the first side inlet 116. The first side upper guide 111 and the first side lower guide 112 provided under the first side fan 161 to form an air flow path between the first side upper guide 111 and the first side upper guide 112. consist of.

The first side nozzle 110 is formed at the lower end of the air flow passage between the first side upper guide 111 and the first side lower guide 112, and the first side nozzle 110 has a downward Jetting guides 113 and 114 are provided to set the jetting amount, jetting speed, and jetting angle of the jetted air.

The spray guides 113 and 114 according to an embodiment of the present invention include a first spray guide 113 composed of a pair of first spray guide members 113a and 113b provided to face each other, It may consist of a second spray guide 114 for setting the spray angle. A blade is connected to the second spray guide 114 to adjust the spray angle of the first side spray hole 110 .

As the shape of the spray guides 113 and 114 and the angle formed with the bottom surface of the hood body 100 are adjusted, the spray holes 110, 120 and 130 are formed in the inner region of the electric range 200 (refer to FIG. 6). It may be formed inclined toward.

Therefore, the air discharged from the first side nozzle 110 may be injected toward the inside of the electric range (200, see FIG. 6) to the side or upper region of the electric range.

The air discharged from the first side spray hole 110 may form a first inclination angle θ1 with the bottom surface of the hood body 100 . The first inclination angle θ1 may be set based on a horizontal line positioned inside the hood among horizontal lines parallel to the bottom surface of the hood main body 100 .

The first inclination angle θ1 is such that the air discharged from the first side nozzle 110 and the second side nozzle 120 moves toward the inside of the electric range (200, see FIG. 6) on the side or top of the electric range. It is an angle made to face the area.

Furthermore, the first inclination angle θ1 may be 40° to 75° based on a horizontal line (dotted line in FIG. 5 ) positioned inside the hood among horizontal lines parallel to the bottom surface of the hood.

The air injected toward the inside of the electric range from the front spray hole 130 may form a second inclination angle θ2 (not shown) with the bottom surface of the hood body 100 . The second inclination angle θ2 (not shown) may be set based on a horizontal line positioned inside the hood among horizontal lines parallel to the bottom surface of the hood main body 100 .

The second inclination angle θ2 (not shown) is the upper surface of the cooking appliance 210 (see FIG. 6) so that the air injected from the front nozzle 130 can perform the function of supplying air to supplement the exhaust of the contaminated air. means a small inclination angle that does not reach the Accordingly, the second inclination angle θ2 (not shown) may be 5° to 45° based on a horizontal line positioned inside the hood among horizontal lines parallel to the bottom surface of the hood body 100 .

6 is a cross-sectional view of a kitchen in which an air hood is installed according to an embodiment of the present invention. 6 shows an electric range 200, a cooking appliance 210 located above the electric range 200, a hood body 100, and an exhaust duct for exhausting air sucked from the hood body 100 to the outdoors ( 300) is shown.

Effects generated as the air hood according to an embodiment of the present invention is formed inside the electric range 200 will be described with reference to FIGS. 6 and 7 .

The air discharged from the first side spray hole 110 and the second side spray hole 120 is sprayed toward the inside of the electric range 200, and air curtains (AC 3, AC 4) on the side or top of the electric range ) to form In addition, the air discharged from the front spray hole 130 (not shown) is injected toward the inside of the electric range 200, forming an air curtain (AC 5, not shown) on the upper part of the electric range. The air curtains AC 3 , AC 4 , and AC 5 prevent the contaminated air generated during cooking in the cooking appliance 210 from spreading into the room, and pass through the suction port 140 (not shown) together with the contaminated air. It is sucked in and exhausted to the outdoors through the exhaust duct 300.

When the air hood sucks in polluted air through the inlet 140 (not shown) and exhausts it to the outdoors through the exhaust duct 300, a negative pressure is formed in the inner region of the upper part of the cooking appliance 210. Therefore, when air is sprayed and replenished to the inner region of the upper part of the cooking appliance 210, the polluted air is exhausted to the outside, so the exhaust performance of the air hood can be improved.

That is, the injected air forms the air curtains AC 3 , AC 4 , and AC 5 toward the inner region to prevent the spread of the polluted air to the outside and to replenish exhaust of the polluted air at the same time. It performs the function of air supply for

In addition, since the buoyancy or thermal diffusion caused by the combustion process is reduced during cooking in the electric range 200, diffusion can be suppressed with a relatively small air volume. Furthermore, due to the nature of the electric range 200, there are few constraints on the height of the left and right sides of the hood or the blown-out phenomenon, so even if the air curtains (AC 3, AC 4, AC 5) are formed inward, they do not affect the crater. don't

However, when the air curtains (AC 3 and AC 4) formed on the top or side of the electric range 200 are formed outward, contaminants generated in the electric range 200 are gas ranges accompanied by gas combustion ( 20, see FIG. 1), the exhaust performance of the air hood may deteriorate because it diffuses irregularly from the point of origin. Therefore, the air curtains (AC 3, AC 4) should be formed toward the inside of the electric range 200 to achieve the desired effect of the present invention.

This will be explained in more detail with reference to the following experimental examples, which are not intended to limit the present invention.

7 is a graph showing that the exhaust performance of a pollutant varies depending on the air volume of the air discharged from the first side nozzle 110 and the second side nozzle 120 and the angle of the first inclination angle θ1. .

The graph of FIG. 7 is shown based on the following experimental example, and the following experimental example is an experimental example in which the air volume and angle are varied.

The graph of FIG. 7 (a) is a bar graph visualizing 10 of the experimental examples based on the air volume discharged from the first side nozzle 110 and the second side nozzle 120. The x-axis of the graph represents the angle (θ1) of the first inclination angle set in the experiment, and the y-axis represents the highest point among the measured amounts of pollutants (fine dust).

Looking at the case where the air volume of the discharged air is 16 CMH, the air curtains (AC 3 and AC 4) were formed weakly outside the electric range 200 by setting the angle to 110 °, and at this time, the contamination The measured amount of the material was measured as the 5th highest among all experimental examples.

Looking at the case where the air volume of the discharged air is 23 CMH, the angle is set to 90 ° and 110 ° to form the outside of the electric range 200, but the measured amount of the contaminant is the air curtain (AC 3, AC 4) was measured higher than when formed inside the electric range 200, and when the angle was 90 °, the measured amount of the contaminant was highest.

On the other hand, when the air volume is 23 CMH and the angles are 30 °, 40 ° and 75 °, that is, when the air curtains (AC 3 and AC 4) are formed inside the electric range 200, The measured amount of contaminants is relatively lower than when the air curtains (AC 3 and AC 4) are formed outside the electric range 200, and the angles are 40 ° and 75 ° compared to the case where the angles are 30 °. When , the measured amount of the contaminant was measured to be the lowest.

Looking at the case where the air volume of the discharged air is 40 CMH, when the angle is 40°, the measured amount of pollutants is relatively lower than when the angle is 90°.

Looking at the cases where the air volume of the discharged air was 47 CMH and 57 CMH, the air curtain was strongly formed outside the electric range 200 by setting the angle to 110 °, but the measured amount of contaminants was the highest.

That is, when the air volume of the discharged air is constant and the angle of the first inclination angle θ1 exceeds a certain limit, when forming an air curtain vertically or outwardly with the electric range 200 (see FIG. 1), the The discharged air may collide with the ground and cause scattering of contaminants that spread into the room or form vortices. In addition, when some of the discharged air is dispersed to the outside, it may diffuse into the room together with some of the air dispersed to the outside as it is irregularly diffused around the point of occurrence due to the nature of the electric range 200.

In addition, as can be seen in the case where the air volume is 23 CMH, when the angle is 30°, the air curtain formed inward causes scattering of the contaminants or enters the room more than when the angle is 40° and 75°. spread may not be prevented.

Therefore, when the air volume is constant, when the air curtain is formed inside the electric range 200, the measured amount of the contaminant is the lowest and when the angle is 40 ° to 75 °, the desired exhaust performance can be obtained. can

The graph of FIG. 7 (b) is a bar graph visualizing 10 experimental examples among the experimental examples based on the angle θ1 of the first inclination angle. The x-axis of the graph represents the air volume set in the experiment, and the y-axis represents the highest point among the measured amounts of pollutants (fine dust).

When the first inclination angle θ1 was 90° or greater than 110°, the measured amount of the contaminant was measured higher than that when the first inclination angle θ1 was less than 90°. That is, when the discharged air hits the bottom of the electric range 200 or forms an air curtain toward the outside of the electric range 200, the contaminants do not reach the suction port 140 (not shown) and the It can circulate or form a vortex within the air curtain, and can diffuse into the room together with a part of the air curtain directed outward.

When the first inclination angle θ1 is 40° and 75°, that is, when the air curtain is formed toward the inside of the electric range 200, the set air volume is 23 CMH compared to the case where the set air volume is 40 CMH. When , the measured amount of the contaminant was measured to be the lowest.

In addition, even if the air curtain is formed inside the electric range 200, the measured amount of contaminants is the lowest when the angle is 40 ° and 75 ° than when the angle is 30 °. As it deviates and becomes smaller, it means that the air curtain may not be able to prevent the contaminant from scattering or spreading into the room.

That is, when the angle of the first inclination angle θ1 exceeds a certain limit and the air curtain is formed vertically or outward with the electric range 200 (see FIG. 1), the discharged air collides with the ground and moves into the room. Scattering of contaminants that spread can cause scattering or form a vortex, and when some of the discharged air is dispersed outward, due to the nature of the electric range 200, it diffuses irregularly around the point of occurrence to the outside It can diffuse into the room with some of the dispersing air. In addition, when the angle of the first inclination angle θ1 is lower than a certain range, it may not play a role in preventing the contaminant from being diffused into the room or prevent it from being sucked into the suction port 140 (not shown). there is.

Therefore, according to the experimental example of FIG. 7 (b), when the air curtain is formed toward the inside as the first inclination angle θ1 is 40° to 75°, the measured amount of the contaminant is the lowest, and at the same time, the measured amount of the pollutant is measured. When the air volume was 23 CMH, the measured amount of pollutants was the lowest.

That is, the air hood for an electric range according to an embodiment of the present invention forms air curtains (AC 3 and AC 4) inside the electric range 200 based on the experimental example, but the air curtain (AC 3 , The air volume and angle of AC 4) can be adjusted to induce optimal exhaust performance according to the tendency of fine dust generation during cooking in an electric range.

7 (c) is a graph illustrating the measured amount of contaminants according to time in the experimental example. The x-axis of the graph means the operating time of the hood, and the y-axis means the measured amount of pollutants (fine dust).

According to the graph, when the first inclination angle (θ1) is 90 ° or 110 °, that is, when the air curtains (AC 3 and AC 4) are formed outside the electric range 200, measurement of contaminants amount was the highest.

In addition, when the first inclination angle θ1 is 110° and the air volume is 16 CMH or 23 CMH, that is, when the air curtains AC 3 and AC 4 are formed outside the electric range 200, The measured amount of contaminants was measured to be relatively high.

In addition, even when the first inclination angle θ1 is 40° and the air curtains AC 3 and AC 4 are formed inside the electric range 200, when the air volume is 40 CMH, the air volume is 23 CMH. Contaminants were measured relatively high compared to the case. Furthermore, when the air volume was 23 CMH, the measurement amount of pollutants was relatively higher when the first inclination angle θ1 was 30° than when the angle was 40°.

Looking at the case where the measured amount of the contaminant is the lowest, the first inclination angle θ1 is 40° or 75°, and an air curtain is formed inside the electric range 200, and the air volume of the discharged air is 23 CMH. The amount of contaminants was measured at the lowest when .

That is, this means that the air curtain must be formed inside the electric range 200 when the first inclination angle θ1 is less than 90° to obtain the exhaust performance desired by the present invention, even when the air curtain is formed inside. When the first inclination angle θ1 is 40° to 75°, the measured amount of pollutants is the lowest, so that a desired exhaust performance can be obtained. Furthermore, when the first inclination angle θ1 is 40° to 75° and the air volume of the discharged air is 23 CMH, the measured amount of pollutants is the lowest, so that desired exhaust performance can be obtained.

Therefore, the first inclination angle θ1, which is the angle between the air discharged from the first side nozzle 110 and the second side nozzle 120 and the bottom surface of the hood body 100, is the inner side of the electric range 200. An angle may be formed so as to be directed toward a side surface or an upper region of the electric range, and the first inclination angle θ1 may be 40° to 75°. Furthermore, the first inclination angle θ1 may be set to 40° in consideration of discomfort when the discharged air touches the user's hand during cooking.

Also, when the first inclination angle θ1 is between 40° and 75°, the discharged air volume may be between 20 and 25 CMH.

A spraying guide according to another embodiment of the present invention will be described with reference to FIGS. 8 and 9 .

8 and 9 show the first side nozzle 110 inclined toward the inside of the electric range (200, see FIG. 6), but the same is true for the second side nozzle 120 and the front nozzle 130. Components that perform functions may be included. Therefore, only the first side spray hole 110 including the spray guides 123 and 133 will be described, and detailed descriptions of the second side spray hole 120 and the front spray hole 130 will be omitted.

As shown in Figure 8, another embodiment of the present invention can be made of only one spraying guide (123, 133).

The spray guide 123 of FIG. 8 (a) is composed of a pair of spray guide members 123a and 123b facing each other, and the inner surfaces of the pair of spray guide members 123a and 123b facing each other are air It is made in parallel with an inclined shape to ensure an inclined downward spray. Therefore, the first side spray hole 110 may be inclined toward the inside of the electric range (200, see FIG. 6).

In the spray guide 133 of FIG. 8 (b), the inner surfaces of the pair of spray guide members 133a and 133b are inclined at different inclinations. That is, the distance between the inner surface of the spray guide member 133a on one side and the inner surface of the spray guide member 133b on the other side is formed to become narrower toward the bottom.

As shown in FIG. 9 , another embodiment of the present invention may include spray guides 173 and 174 formed by bending an end of the housing 170 .

9, the first side inlet 116 is formed on the upper surface of the hood, the first side fan 161 is provided under the first side inlet, and the first side inlet 110 of FIG. In the lower part of the fan 161, the first side inner space 101, the first side blocking wall 141 surrounding the first side inner space 101, the first side upper housing 171, the first A side middle housing 172 and a first side lower housing 173 are provided.

The first side intermediate housing 172 forms a bottom portion of the first side inner space 101, and a second spray guide 172a bent downwardly inclined toward the inside is formed at an end portion of the first side surface.

The first side lower housing 173 includes a pair of first spray guides 173a and 173b formed to be inclined downward to the inside of the housing 170, and between the first spray guides 173a and 173b, a first The side spray port 110 is located.

The first side fan 161, the second side fan 162, and the front fans 163 and 164 according to another embodiment of the present invention may be formed as axial-flow fans. The axial fan refers to a blower in which the air flow direction is parallel to the axis of the blower, and when the axial fan is used, the size of the air hood can be further miniaturized and the configuration of parts for installing the fan can be simplified. Accordingly, the flow direction of the air generated from the first side fan 161 is formed in a vertical downward direction parallel to the axis as indicated by an arrow.

When the first side fan 161 is operated, the air introduced through the first side inlet 116 flows downward by the first side fan 161 and flows into the first side inner space 101. And, the air in the first side inner space 101 is discharged obliquely toward the inner region of the electric range 200 (see FIG. 6) through the first side spray hole 110.

In this case, the first side spray hole 110 can be formed with only the pair of first spray guides 173a and 173b, and when the second spray guide 172a is additionally provided, the second spray guide 172a The direction of the air discharged through the first side spray hole 110 can be easily adjusted only by adjusting the inclination angle of ). Furthermore, since the second spray guide 172a is positioned between the pair of spray guides 173a and 173b, it is possible to prevent the spray angle from being arbitrarily changed due to the user's hand not reaching it.

Although the present invention has been described above with reference to embodiments, the present invention is not limited to the above-described embodiments, and can be modified and practiced by a person skilled in the art without changing the technical spirit of the present invention claimed in the claims. Of course.

1: cooking appliance 10: exhaust device body
11: both side nozzles 20: gas cooktop
100: hood body 101: first side inner space
102: second side inner space 103: front inner space
104: central inner space 110: first side injection port
111: first side upper guide 112: first side lower guide
113, 123, 133: first injection guide 114: second injection guide
116: first side inlet 120: second side nozzle
130: third side nozzle 140: inlet
140a, 140b: filter 141: first side barrier
142: second side barrier 143: front barrier
151: first side motor 152: second side motor
153: front motor 161: first side fan
162: second side fan 163, 164: front fan
170: housing 171: first side upper housing
172: first side intermediate housing 173: first side lower housing
172a: second spray guide 173a, 173b: first spray guide
200: electric range 210: cooking appliance
300: exhaust duct
AC 1, AC 2, AC 3, AC 4: Air curtain
θ1: first inclination angle θ2: second inclination angle

Claims (9)

Hood body located above the electric range;
A spray hole formed on the bottom edge of the hood body and including a first side spray hole positioned on a first side surface and a second side spray hole positioned on a second side surface side; and
An air hood for an electric range wherein the air discharged from the first side nozzle and the second side nozzle is injected toward the inside of the electric range to the side or upper region of the electric range.
According to claim 1,
The air hood for an electric range, characterized in that the discharged air forms a first inclination angle with the lower surface of the hood body.
According to claim 2,
The first inclination angle is an air hood for an electric range, characterized in that consisting of 40 ° to 75 ° based on a horizontal line located inside the hood among horizontal lines parallel to the bottom surface of the hood body.
According to claim 3,
An air hood for an electric range, characterized in that the air volume of the discharged air is 20 to 25 CMH.
According to claim 1,
The spray hole is a front spray hole located on the front side of the hood body;
Air hood for electric range including more.
According to any one of claims 1 to 5,
The jetting hole further includes a jetting guide, and the jetting guide
Consisting of a pair of opposing spray guide members
An air hood for an electric range comprising: a first spray guide having an inner surface facing the spray guide member inclined at a spray angle of the air discharged from the spray hole.
According to claim 6
The spray guide
A second jetting guide connected to a blade for adjusting the jetting angle of the discharged air;
Air hood for electric range included.
According to claim 5,
An air hood for an electric range, characterized in that the air discharged from the front nozzle forms a second inclination angle with the bottom surface of the hood body.
According to any one of claims 1 to 5
The air hood for an electric range, characterized in that the spray guide is formed by bending an end of the housing surrounding each of the spray holes.

Images