KR20230175074A - Range hood - Google Patents

Abstract

The range hood is launched. The disclosed range hood is a range hood for ventilating odors generated from food cooked on a cooktop, and includes an exhaust fan, a duct configured to accommodate the exhaust fan, and a main body coupled to the duct and positioned to face the cooktop. It includes a range hood, wherein the main body includes a light source device including an illumination light source capable of emitting illumination light from the main body in a first direction toward the cooktop and a guide light source capable of emitting guide light from the main body in a second direction. .

Description

Range hood{RANGE HOOD}

This disclosure relates to a range hood. More specifically, the invention relates to a light source module included in a range hood.

A range hood is a device that is placed above a food heating device and absorbs contaminants such as combustion gases, fine dust, and oil mist generated from the food when the food is heated.

The range hood can be placed facing the cooktop. A range hood can absorb contaminants generated from food cooked on a cooktop and discharge them to the outside.

The range hood may cast a shadow on the cooktop. In order to facilitate cooking on the cooktop, light needs to be irradiated onto the cooktop.

One aspect of the present disclosure seeks to provide a range hood configured to irradiate light onto a cooktop.

One aspect of the present disclosure seeks to provide a range hood that can irradiate light to the exterior of the range hood while irradiating light on the cooktop.

One aspect of the present disclosure is to provide a range hood capable of irradiating light on the exterior of the range hood separately from the light irradiated on the cooktop.

One aspect of the present disclosure is to provide a range hood configured to position each light source that irradiates in different directions in a limited space.

The technical problems to be achieved in this document are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those skilled in the art from the description below. There will be.

In order to solve the above problem, a range hood according to the spirit of the present disclosure is a range hood for ventilation of odors generated from food cooked on a cooktop, and includes an exhaust fan, a duct configured to accommodate the exhaust fan, and the duct. It is coupled to and includes a main body positioned to face the cooktop. The main body may include a light source device including an illumination light source capable of emitting illumination light from the main body in a first direction toward the cooktop and a guide light source capable of emitting guide light from the main body in a second direction.

The guide light source may be configured to be controlled separately from the illumination light source.

The second direction may be defined to intersect the first direction.

The guide light source may emit guide light of a different color from the illumination light emitted by the illumination light source.

The light source device may further include a transparent member spaced apart from the illumination light source in a first direction to diffuse the illumination light.

The light source device further includes a lighting diffusion plate positioned between the transparent member and the lighting light source to diffuse the lighting light, and the lighting light passes through the lighting diffusion plate and the transparent member to be emitted toward the cooktop. You can.

The lighting diffusion plate may be supported by the transparent member to be detachable.

The light source device includes a bracket support unit located on the transparent member and located in the second direction from the lighting diffusion plate, and a bracket support unit located on the transparent member and located in a direction opposite to the second direction from the lighting diffusion plate. It may further include a light source support unit positioned, and the lighting diffusion plate may include a diffusion plate guide portion bent in a direction opposite to the first direction so as to contact the bracket support unit or the light source support unit.

The guide light source may emit the guide light in the first direction, and the light source device may further include a guide diffusion plate configured to reflect the guide light in the second direction.

The guide diffusion plate may be positioned to face the transparent member so that the guide light is emitted through the transparent member.

The guide diffusion plate may be positioned so that at least a portion of the guide diffusion plate is spaced apart from the guide light source so that a guide diffusion space is defined between the guide light source and the guide light source.

The light source device further includes a light source support unit positioned in the second direction from the guide light source so that the guide diffusion space is defined between the guide diffusion plate, and the light source support unit is capable of reflecting the guide light. It may have an indirect reflective surface facing the guide diffusion space.

The guide diffusion plate may include a prism unit configured to allow the guide light to pass through the interior and be reflected on an inclined surface inclined to the first direction and the second direction.

It may further include a guide light source substrate configured to support the guide light source, and the guide diffusion plate may include a substrate support portion configured to support the guide light source substrate.

The substrate support portion is located on a side of the guide light source, and the guide diffusion plate may further include a connection portion extending from the substrate support portion to the prism portion to guide the guide light emitted from the guide light source to the prism portion. .

A range hood according to the spirit of the present disclosure is a range hood for ventilating odors generated from food cooked on a cooktop, and includes a main body positioned to face the cooktop, wherein the main body has a second body facing the cooktop. and a detachable light source device including an illumination light source capable of emitting illumination light in one direction and a guide light source capable of emitting guide light from the main body in a second direction.

It further includes a fine dust sensor that outputs a signal according to the amount of fine dust and a processor electrically connected to the fine dust sensor, wherein the processor measures fine dust above a preset value by the fine dust sensor and determines the fine dust. The color of the guide light can be controlled through the guide light source based on the signal output from the sensor.

The light source device further includes a transparent member configured to define an illumination diffusion space through which the illumination light can pass by being spaced apart from the illumination light source in a first direction so that the illumination light is diffused, and the guide light source is configured to define an illumination diffusion space through which the illumination light can pass. It is located in a direction opposite to the second direction and may emit guide light in the second direction toward the transparent member.

The light source device further includes a lighting guide diffusion plate positioned to be spaced apart from the lighting light source in a direction opposite to the second direction, wherein the lighting light source is capable of emitting the lighting light source toward the lighting guide diffusion plate, The lighting guide diffusion plate may reflect the lighting light emitted by the lighting light source in the first direction.

A range hood according to the spirit of the present disclosure includes an exhaust fan, a duct configured to accommodate the exhaust fan, an illumination light source capable of emitting illumination light downward, a guide light source capable of emitting guide light forward, and spaced below the illumination light source. and a transparent member positioned so as to diffuse the illumination light, and an illumination diffusion plate positioned between the transparent member and the illumination light source.

According to an embodiment of the present disclosure as a means of solving the problem, a range hood may include a light source module, thereby allowing light to be irradiated onto the cooktop.

According to an embodiment of the present disclosure, by including an illumination light source capable of irradiating light in a first direction toward the cooktop and a guide light source capable of irradiating light in a second direction crossing the first direction, while irradiating light on the cooktop , it may be possible to irradiate light to the exterior of the range hood.

According to an embodiment of the present disclosure, by including an illumination light source and a guide light source that are each controlled separately, light on the exterior of the range hood can be irradiated separately from the light irradiated on the cooktop.

According to an embodiment of the present disclosure, it includes a guide light source that irradiates guide light toward the cooktop and a guide diffusion plate that reflects the guide light in different directions, so that each light source that irradiates in different directions is positioned in a limited space. It can be configured.

The effects that can be obtained from the present disclosure are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description below. will be.

1 is a perspective view showing a range hood and a cooktop according to an embodiment of the present disclosure.
FIG. 2 is a perspective view showing the range hood shown in FIG. 1 emitting light.
FIG. 3 is a perspective view showing the range hood shown in FIG. 1.
FIG. 4 is a perspective view showing the main body of the range hood shown in FIG. 3.
FIG. 5 is a perspective view showing the main body of the range hood shown in FIG. 4 as seen from another side.
FIG. 6 is an exploded view showing the main body of the range hood shown in FIG. 4 disassembled.
FIG. 7 is a perspective view showing the rail module of the range hood shown in FIG. 6.
FIG. 8 is an enlarged view showing the light source module of the range hood shown in FIG. 4 being coupled to the rail module.
FIG. 9 is an enlarged view showing the light source module of the range hood shown in FIG. 8 coupled to the rail module.
FIG. 10 is a perspective view showing the light source module of the range hood shown in FIG. 6.
FIG. 11 is an enlarged view of the light source module of the range hood shown in FIG. 10.
FIG. 12 is an exploded view of the light source module of the range hood shown in FIG. 10.
FIG. 13 is an exploded view of part of the light source module configuration of the range hood shown in FIG. 12.
FIG. 14 is a perspective view showing the housing, light source module, and light source unit of the range hood shown in FIG. 6.
FIG. 15 is a cross-sectional view showing the light source device of the range hood shown in FIG. 10.
FIG. 16 is a control block diagram for the sensor of the range hood shown in FIG. 1.
FIG. 17 is a flowchart showing a sensing method by the fine dust sensor of the range hood shown in FIG. 16.
FIG. 18 is a conceptual diagram illustrating a state in which the fine dust sensor of the range hood shown in FIG. 17 does not detect fine dust.
FIG. 19 is a conceptual diagram illustrating a state in which the fine dust sensor of the range hood shown in FIG. 18 detects fine dust.
Figure 20 is a cross-sectional view showing a light source device of a range hood according to an embodiment of the present disclosure.
Figure 21 is a cross-sectional view showing a light source device of a range hood according to an embodiment of the present disclosure.
Figure 22 is an exploded view showing a portion of the main body of a range hood according to an embodiment of the present disclosure.

The various embodiments of this document and the terms used herein are not intended to limit the technical features described in this document to specific embodiments, and should be understood to include various changes, equivalents, or replacements of the embodiments.

In connection with the description of the drawings, similar reference numbers may be used for similar or related components.

The singular form of a noun corresponding to an item may include one or more of the above items, unless the relevant context clearly indicates otherwise.

As used herein, “A or B”, “at least one of A and B”, “at least one of A or B”, “A, B or C”, “at least one of A, B and C”, and “A Each of phrases such as “at least one of , B, or C” may include any one of the items listed together in the corresponding phrase, or any possible combination thereof.

The term “and/or” includes any element of a plurality of related described elements or a combination of a plurality of related described elements.

Terms such as "first", "second", or "first" or "second" may be used simply to distinguish one element from another, and may be used to distinguish such elements in other respects, such as importance or order) is not limited.

One (e.g. first) component is said to be "coupled" or "connected" to another (e.g. second) component, with or without the terms "functionally" or "communicatively". Where mentioned, it means that any of the components can be connected to the other components directly (e.g. wired), wirelessly, or through a third component.

Terms such as “include” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in this document, but are not intended to include one or more other features, numbers, or steps. , does not exclude in advance the possibility of the existence or addition of operations, components, parts, or combinations thereof.

When a component is said to be “connected,” “coupled,” “supported,” or “in contact” with another component, this means not only when the components are directly connected, coupled, supported, or in contact, but also when a third component This includes cases where it is indirectly connected, coupled, supported, or contacted through.

When a component is said to be located “on” another component, this includes not only cases where a component is in contact with another component, but also cases where another component exists between the two components.

Meanwhile, the terms “up and down direction,” “bottom side,” and “front and back direction” used in the following description are defined based on the drawings, and the shape and location of each component are not limited by these terms.

Specifically, as shown in FIG. 1, the direction in which the range hood 1 faces the cooktop 2 is defined as downward, and the top, left and right, and front and rear are defined based on this.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a perspective view showing a range hood 1 and a cooktop 2 according to an embodiment of the present disclosure.

With reference to FIG. 1 , the range hood 1 and the cooktop 2 according to an embodiment of the present disclosure will be described.

The range hood 1 according to an embodiment of the present invention may be placed indoors. For example, the range hood 1 may be placed in a kitchen.

The range hood (1) can absorb exhaust gases, smoke, or food odors generated from the cooktop (2) and discharge them outdoors.

The cooktop 2 can be configured as an oven, gas range, induction stove, etc. In particular, the cooktop 2 may include a cooktop 2 unit so that food can be placed on the cooktop 2 and cooked.

The range hood 1 may be provided in various types. The range hood 1 may be an independent hood in which the main body (X) is integrated. The independent hood may not be located in a furniture cabinet (not shown). The range hood 1 may be a chimney type hood. A chimney-type hood may have a shape where the entrance through which smoke is sucked is wide and gradually narrows like a chimney. Chimney-type hoods may not be located within furniture cabinets. The range hood 1 may be an island hood. The island hood may be a hood installed over an island dining table. An island table is a dining table that is separate from the sink or existing countertop, and can be used when the kitchen is narrow or an auxiliary countertop is needed. The range hood 1 may be a built-in hood. A built-in hood can refer to a hood that is built into the space like a support. The range hood 1 may be a secret hood. A secret hood may mean a hood that does not have the same shape as a regular hood on the outside.

In the embodiment according to the present disclosure, it is explained as an example that the range hood 1 is an island hood. However, the range hood 1 is not limited to this and may be various types of hoods.

Although an example in which the range hood 1 is installed indoors has been described, the installation method of the range hood 1 is not limited to this, and it can be installed in various ways depending on the size and characteristics of the place where it is installed, the purpose of installation, etc.

Additionally, the range hood 1 is not limited to one embodiment of the present invention and may be provided to be combined with a cooking appliance unit such as an Over The Range (OTR).

The range hood (1) can be placed facing the cooktop (2). The range hood (1) may be placed above the cooktop (2). Accordingly, exhaust gas, smoke, or food odor generated from the cooktop 2 can be sucked upward and discharged outdoors.

The range hood 1 may include a main body (X). The main body (X) may be configured to face the cooktop (2).

Contaminants generated from food cooked on the cooktop (2) may pass through the main body (X) and be discharged outdoors.

The main body (X) may be located on the upper side of the cooktop (2). The main body (X) may be positioned to be spaced apart from the cooktop (2).

The body (X) may have a substantially rectangular shape.

The body (X) may be configured to be coupled to the duct (10).

The range hood 1 may include a duct 10. The duct 10 may be connected to the main body (X).

The duct 10 may be combined with the main body (X). The duct 10 may be connected to the upper side of the main body (X).

The duct 10 may be configured to accommodate the exhaust fan 20.

The duct 10 may be located on the upper side of the main body (X). Since the food may be placed on the cooktop 2, contaminants generated from the food may be vaporized or moved upward in a small liquid state. The duct 10 may be located on the top of the cooktop 2 to guide contaminants.

The duct 10 may be configured to communicate with the main body (X). Duct 10 may be configured to guide the movement of contaminants.

Food may not be cooked on all parts of the cooktop (2). That is, food may be cooked in some parts of the cooktop 2. Cooking activities such as cutting for cooking can be performed on the remaining part of the cooktop (2).

The duct 10 may be positioned to correspond to a portion of the cooktop 2 where food can be cooked. The duct 10 may be positioned to correspond to a portion of the upper side of the main body (X) where food can be placed.

Duct 10 may have a substantially rectangular shape. However, it is not limited to this.

The duct 10 may be made of metal. However, it is not limited to this.

The duct 10 may be formed by a press process. However, it is not limited to this.

The range hood 1 may include an exhaust pipe 30. The exhaust pipe 30 may be configured to communicate with the outside.

The exhaust pipe 30 may be combined with the duct 10. The exhaust pipe 30 may be coupled to the upper side of the duct 10. Because contaminants caused by food cooked on the cooktop 2 are heated, they may move upward. Accordingly, because the duct 10 is located above the exhaust pipe 30, contaminants can be moved toward the duct 10.

The exhaust pipe 30 may be in communication with the duct 10. Accordingly, contaminants moving through the duct 10 may pass through the duct 10 and head to the exhaust pipe 30. Since the exhaust pipe 30 may be in communication with the outdoors, contaminants passing through the duct 10 may be directed to the outdoors.

The exhaust pipe 30 can guide the movement of contaminants.

The exhaust pipe 30 may have a cylindrical shape. However, it is not limited to this.

The cross-sectional area of the exhaust pipe 30 in contact with the duct 10 may be smaller than the cross-sectional area of the duct 10 facing the exhaust pipe 30.

The exhaust pipe 30 may be configured to be flexible. Accordingly, the exhaust pipe 30 can be connected to the opening toward the outdoors, regardless of the location of the duct 10.

The exhaust pipe 30 may be made of a metal material. However, it is not limited to this.

The exhaust pipe 30 may be formed through a press process. However, it is not limited to this.

The main body (X) may include a housing (100). The housing 100 may be configured to define the appearance of the main body (X).

The housing 100 may define the upper exterior of the main body (X).

The housing 100 may be in communication with the duct 10. The housing 100 can guide air containing contaminants from the lower side and move it to the duct 10.

The housing 100 may have a substantially rectangular parallelepiped shape.

The main body (X) may include a light source device (Y). The light source device Y may be configured to emit light.

The light source device (Y) may be coupled to the housing 100. The light source device (Y) may be coupled to the front or rear of the housing 100.

The light source device (Y) can define the front or rear appearance of the body (X).

The light source device Y may include a light source module 300 that is detachable for service and a light source unit 200 (FIG. 6) coupled to the housing 100.

The main body (X) may include a rail device. The rail module 400 may be configured to guide the movement of the light source module 300.

The rail module 400 may be coupled to the housing 100. The rail module 400 may be coupled to the right or left side of the housing 100.

The rail module 400 can define the left or right appearance of the main body (X).

FIG. 2 is a perspective view showing the range hood 1 shown in FIG. 1 emitting light.

With reference to FIG. 2 , the direction of light irradiation from the light source device Y according to an embodiment of the present disclosure will be described.

The light source device Y may irradiate light in a first direction D1 toward the cooktop 2. As light is irradiated in the first direction D1, the cooktop 2 may become brighter. For example, the first direction D1 may be a downward direction.

The user can cook on the cooktop 2 or prepare food using cooking utensils. Since these actions require visibility, lighting may be necessary for the user to perform various actions on the cooktop (2).

In particular, if the range hood 1 is located above the cooktop 2, a shadow may be cast by other light, so the cooktop 2 may become dark. In order to cook food on the cooktop 2 in such an environment, it may be necessary to emit light to the cooktop 2.

The light shining on the cooktop 2 can be referred to as lighting light L1. The illumination light source 210, which will be described later, can emit such illumination light L1.

The light source device Y may irradiate light in a second direction D2 that intersects the first direction D1. By irradiating light in the second direction D2, the exterior of the range hood 1 can be decorated. For example, the second orientation may be forward or backward.

Light emitted in the second direction D2 may indicate the state of the range hood 1. Since the second direction D2 is a direction that intersects the first direction D1, it may be better recognized by the user than the first direction D1. Therefore, the range hood 1 can be decorated using light emitted in this direction. Alternatively, light emitted in the second direction D2 may be used to enable the user to recognize information on the range hood 1.

The light emitted in the second direction D2 may be referred to as guide light L2. The guide light source 310, which will be described later, can emit such guide light (L2).

FIG. 3 is a perspective view showing the range hood 1 shown in FIG. 1.

Referring to FIG. 3, the exhaust of the range hood 1 will be described.

The range hood 1 may include an exhaust fan 20. The exhaust fan 20 may be a fan for exhausting contaminants entering the range hood 1.

Exhaust fan 20 may be located within duct 10 .

The exhaust fan 20 may be an axial fan.

When the exhaust fan 20 operates, contaminants or air provided on the lower side of the main body (X) may move toward the exhaust fan 20.

The exhaust fan 20 may suck in pollutants or air and discharge the pollutants or air toward the exhaust pipe 30 provided on the upper side of the duct 10. Pollutants or air discharged toward the exhaust pipe 30 may move along the exhaust pipe 30 and then be discharged outdoors.

FIG. 4 is a perspective view showing the main body (X) of the range hood 1 shown in FIG. 3.

With reference to FIG. 4 , the main body (X) according to an embodiment of the present disclosure will be described.

The range hood 1 may include a main body (X).

The main body (X) may include a housing (100).

A duct connection hole 111H may be defined on the housing 100. The duct connection hole 111H may be a hole that communicates with the duct 10.

Oil vapor generated from cooking food may move toward the duct 10 through the duct connection hole 111H.

The duct connection hole 111H may have a square shape. However, the present invention is not limited thereto, and the duct connection hole 111H may have a shape corresponding to the duct 10.

The duct connection hole 111H may be formed by cutting the housing 100.

The main body (X) may include a duct connection portion 111 connected to the duct 10. The duct connection part 111 may be connected to the duct 10.

The duct connection portion 111 may extend from the housing 100 toward the duct 10. The duct connection portion 111 may extend upward.

The duct connection portion 111 may extend inside the duct 10. This can prevent the duct connection part 111 from being visible from the outside of the duct 10. By preventing the duct connection portion 111 from being exposed to the outside of the duct 10, the aesthetics of the duct 10 can be improved.

The duct connection portion 111 may be configured to be bent from the housing 100. The duct connection portion 111 may be formed integrally with the housing 100.

The duct connection portion 111 may be positioned adjacent to the duct connection hole 111H. Oil vapor passing through the duct connection hole 111H can be smoothly guided along the duct connection part 111 by the duct 10 connection part.

The duct connection portion 111 may have chamfered corners. Because of this, the duct connection portion 111 can be easily positioned within the duct 10.

FIG. 5 is a perspective view showing the main body (X) of the range hood 1 shown in FIG. 4 as seen from another side.

With reference to FIG. 5 , the main body (X) of the range hood 1 of the present disclosure will be further described.

The range hood 1 may include a rail module 400 coupled to one side of the housing 100.

There may be multiple rail modules 400. The plurality of rail modules 400 may include a first rail module 400a coupled to the left side of the housing 100 and a second rail module 400b coupled to the right side of the housing 100.

The first rail module 400a and the second rail module 400b may support the light source module 300 on the left or right side of the light source device (Y), respectively.

The first rail module 400a and the second rail module 400b may guide the sliding movement of the light source module 300.

The first rail module 400a and the second rail module 400b may be coupled to the housing 100 at the lower side of the housing 100. The first rail module 400a and the second rail module 400b may define the lower left and lower right appearances of the main body (X), respectively.

The first rail module 400a and the second rail module 400b may substantially define an appearance corresponding to the left and right edges of the main body (X).

The range hood 1 may include a light source module 300 coupled to one side of the housing 100.

There may be a plurality of light source modules 300. The plurality of light source modules 300 include a first light source module 300a coupled to the housing 100 at the front of the housing 100 and a second light source module 300b coupled to the housing 100 at the rear of the housing 100. ) may include.

The first light source module 300a and the second light source module 300b may radiate the guide light L2 from the front and rear of the housing 100 to the front or rear, respectively.

The first light source module 300a and the second light source module 300b may be coupled to the housing 100 at the lower side of the housing 100. The first light source module 300a and the second light source module 300b may respectively define the appearance of the front lower side and the rear lower side of the main body (X).

The first light source module 300a and the second light source module 300b may substantially define an appearance corresponding to the front and rear edges of the main body (X).

The first light source module 300a and the second light source module 300b may be supported by the rail module 400.

The first light source module 300a and the second light source module 300b may be in contact with the rail module 400.

The first light source module 300a and the second light source module 300b may be located at positions corresponding to the front and rear corners of the housing 100. The first rail module 400a and the second rail module 400b may be located at positions corresponding to the left and right corners of the housing 100.

When the housing 100 has a rectangular shape, each corner may be surrounded by the first and second light source modules 300b and the first and second rail modules 400b. Accordingly, the lower exterior of the main body (X) may be defined by the housing 100 surrounded by the first and second light source modules 300b and the first and second rail modules 400b.

The light source module 300 may include a transparent member 350 and a cover member 380 that covers at least a portion of the transparent member 350. The transparent member 350 and the cover member 380 may define the lower exterior of the light source module 300.

The light source module 300 may be detachably coupled to the housing 100 .

The light source module 300 may be movable from a receiving position located within the rail module 400 to a separated position located outside the rail module 400.

The rail module 400 may contact the transparent member 350 and the cover member 380. Accordingly, the appearance corresponding to the lower edge of the main body (X) can be defined by the transparent member 350, the cover member 380, and the rail module 400. Since the appearance of the lower part of the main body (X) is defined by fewer members, the aesthetics of the lower part of the main body (X) can be improved.

The rail module 400 may be configured to move the light source module 300 in the sliding direction D3.

FIG. 6 is an exploded view showing the main body (X) of the range hood 1 shown in FIG. 4 disassembled.

With reference to FIG. 6, the main body (X) according to an embodiment of the present disclosure will be described.

The range hood 1 may include a main body (X).

The main body (X) may include a housing (100).

Housing 100 may include a housing plate 110. The housing plate 110 may be a component that defines the exterior of the housing 100.

The housing plate 110 may define a portion of the exterior of the main body (X). The housing plate 110 may define the upper exterior of the main body (X).

The housing plate 110 may cover the upper side of the main body (X). Accordingly, it is possible to prevent foreign substances from entering the interior of the main body (X).

The housing plate 110 may include a duct connection portion 111. The housing plate 110 may be connected to the duct 10.

The housing plate 110 may be combined with the light source device (Y). The housing plate 110 may be combined with the light source unit 200. The housing plate 110 may be coupled to the upper side of the light source unit 200. The housing plate 110 may cover the upper side of the light source unit 200. The housing plate 110 can prevent foreign substances from entering the upper side of the light source unit 200.

The housing plate 110 may have a substantially rectangular plate shape. However, it is not limited to this, and the housing plate 110 may have a shape corresponding to the shape of the cooktop 2.

The housing plate 110 may be made of a metal material. However, the present invention is not limited thereto, and the housing plate 110 may be made of plastic.

The housing plate 110 may be formed through a press process. However, it is not limited to this.

Housing 100 may include part housing 120. The part housing 120 may be configured to combine other components included in the main body (X).

The part housing 120 may be combined with the housing plate 110. The part housing 120 may be coupled to the housing plate 110 at the lower side of the housing plate 110.

The part housing 120 may extend from the housing plate 110 toward the cooktop 2. Part housing 120 may extend downward. Accordingly, different configurations may be coupled to the side of the portion of the part housing 120 extending toward the cooktop 2.

The part housing 120 may be combined with the light source module 300 or the rail module 400. The side of the part housing 120 and the light source module 300 or the rail module 400 may be fastened to each other by a fastening member (F).

The part housing 120 may be bent at a portion for coupling with the housing plate 110 and extend downward. Since the part housing 120 includes a portion facing the housing plate 110, the coupling with the housing plate 110 can be strengthened. The housing plate 110 and the part housing 120 may be fastened to each other by a fastening member (F).

Part housing 120 may extend along an edge of housing 100. The part housing 120 may be provided in a long shape in the longitudinal direction.

Meanwhile, the part housing 120 may be positioned to face the rail frame so as to be coupled to the rail frame 420 by the fastening member (F).

The part housing 120 may include a module part housing 121. The module part housing 121 may be a part housing 120 that can be combined with the light source module 300.

The module part housing 121 may be combined with the housing plate 110. The module part housing 121 may be positioned to extend along the edge of the housing plate 110. The module part housing 121 may extend along the long side of the housing plate 110. The module part housing 121 may be coupled to the housing plate 110 so as to be adjacent to the long side of the housing plate 110.

The module part housing 121 may be positioned to face the light source module 300. The module part housing 121 may be located at the front or rear.

The module part housing 121 may extend along the direction in which the light source module 300 extends. The module part housing 121 may extend in the left and right directions. The direction in which the module part housing 121 extends may be parallel to the direction in which the light source module 300 extends.

The module part housing 121 may have a flat surface on the front or rear side.

The module part housing 121 may be combined with the light source module 300. The module part housing 121 may be in contact with the rear of the light source module 300. The light source module 300 may contact the plane of the module part housing 121. The module part housing 121 may be fastened to the light source module 300 by a fastening member (F).

A plurality of module part housings 121 may be provided. The plurality of module part housings 121 may include a first module part housing 121a that can be coupled to the first light source module 300a and a second module part housing 121b that can be coupled to the second light source module 300b. there is.

The first module part housing 121a may be located in front of the second module part housing 121b. The second module part housing 121b may be located rearward with respect to the first module part housing 121a. The first module part housing 121a may be coupled to the front side of the housing plate 110. The second module part housing 121b may be coupled to the rear side of the housing plate 110.

The first module part housing 121a may be coupled to the rear of the first light source module 300a. The first light source module 300a may be coupled to the front side of the first module part housing 121a.

The second module part housing 121b may be coupled to the front of the second light source module 300b. The second light source module 300b may be coupled to the rear side of the second module part housing 121b.

The direction in which the first module part housing 121a and the second module part housing 121b extend may be parallel. The extension direction of the first light source module 300a coupled to the first module part housing 121a and the extension direction of the second light source module 300b coupled to the second module part housing 121b may be parallel.

The first to second module part housings 121b may include a metal material. However, it is not limited to this.

The first to second module part housings 121b may be formed through a drawing process. However, it is not limited to this.

Part housing 120 may include rail part housing 122. The rail part housing 122 may be a part housing 120 that can be combined with the rail module 400.

The rail part housing 122 may be combined with the housing plate 110. The rail part housing 122 may be positioned to extend along an edge of the housing plate 110. The rail part housing 122 may extend along the short side of the housing plate 110. The rail part housing 122 may be coupled to the housing plate 110 so as to be adjacent to a short side of the housing 100.

The rail part housing 122 may be positioned to face the rail module 400. The rail part housing 122 may be positioned at the front or rear.

The rail part housing 122 may extend along the direction in which the rail module 400 extends. The rail part housing 122 may extend in the front-to-back direction. The direction in which the rail part housing 122 extends may be parallel to the direction in which the rail module 400 extends.

The rail part housing 122 may have a flat surface on the right or left side.

The rail part housing 122 may be combined with the rail module 400. The rail part housing 122 may be in contact with the side of the rail module 400. The rail module 400 may contact the plane of the rail part housing 122. The rail part housing 122 may be fastened to the rail module 400 by a fastening member (F).

A plurality of rail part housings 122 may be provided. The plurality of rail part housings 122 may include a first rail part housing 122a that can be coupled to the first rail module 400a and a second rail part housing 122b that can be coupled to the second rail module 400b. there is.

The first rail part housing 122a may be located on the right side with respect to the second rail part housing 122b. The second rail part housing 122b may be located on the left with respect to the first rail part housing 122a. The first rail part housing 122a may be coupled to the left side of the housing plate 110. The second rail part housing 122b may be coupled to the right side of the housing plate 110.

The first rail part housing 122a may be coupled to the right side of the first rail module 400a. The first rail module 400a may be coupled to the left side of the first rail part housing 122a.

The second rail part housing 122b may be coupled to the left side of the second rail module 400b. The second rail module 400b may be coupled to the right side of the second rail part housing 122b.

The direction in which the first rail part housing 122a and the second rail part housing 122b extend may be parallel. The extension direction of the first rail module 400a coupled to the first rail part housing 122a and the extension direction of the second rail module 400b coupled to the second rail part housing 122b may be parallel.

The first to second rail part housings 122b may include a metal material. However, it is not limited to this.

The first to second rail part housings 122b may be formed through a drawing process. However, it is not limited to this.

The main body (X) may include a light source unit 200. The light source unit 200 may be configured to emit light in the first direction D1.

The light source unit 200 may be coupled to the housing plate 110. The light source unit 200 may be coupled to the lower side of the housing plate 110. The light source unit 200 may be coupled to the housing plate 110 by a fastening member (F).

The light source unit 200 may be located in the front or rear of the module part housing 121. The light source unit 200 may be positioned to correspond to the light source module 300, which will be described later. The light source unit 200 may be located above the light source module 300.

The light source unit 200 may extend in a direction parallel to the direction in which the light source module 300 extends.

The light source unit 200 may be located adjacent to the long side of the housing plate 110. The light source unit 200 may extend along the long side of the housing plate 110 .

The light source unit 200 may radiate light toward the light source module 300.

The light source unit 200 may be included in the light source device (Y).

There may be a plurality of light source units 200. The plurality of light source units 200 may include a first light source unit 200a corresponding to the first light source module 300a and a second light source unit 200b corresponding to the second light source module 300b.

The first light source unit 200a may be positioned adjacent to the first module part housing 121a. The second light source unit 200b may be positioned adjacent to the second module part housing 121b.

The first light source unit 200a may be located in front of the second light source unit 200b. The second light source unit 200b may be located rearward of the first light source unit 200a.

The main body (X) may include a light source module 300. The light source module 300 may be configured to emit light in the second direction D2.

The light source module 300 may be positioned to face the light source unit 200. Accordingly, the light emitted from the light source module 300 may be arranged to pass through the light source module 300.

The light source module 300 may be positioned to face the module part housing 121. The light source module 300 may be coupled to the module part housing 121.

The light source module 300 may be positioned adjacent to the rail module 400. The light source module 300 may contact the rail module 400.

The light source module 300 may be provided to extend in the longitudinal direction. The light source module 300 may extend to correspond to the long side of the housing plate 110 .

There may be a plurality of light source modules 300. The plurality of light source modules 300 may include a first light source module 300a coupled to the first module part housing 121a and a second light source module 300b coupled to the second module part housing 121b. .

The first light source module 300a may be located in front of the second light source module 300b. The second light source module 300b may be located rearward with respect to the first light source module 300a.

The main body (X) may include a rail module 400. The rail module 400 may be configured to guide the movement of the light source module 300.

The rail module 400 may support the light source module 300 in the direction of gravity of the light source module 300. The rail module 400 may support the light source module 300 at a side end of the light source module 300.

The rail module 400 may be combined with the rail part housing 122.

The rail module 400 may extend along the short side of the housing plate 110.

There may be multiple rail modules 400. The rail module 400 may include a first rail module 400a coupled to the first rail part housing 122a and a second rail module 400b coupled to the second rail part housing 122b.

The first rail module 400a may be located on the left with respect to the second rail module 400b. The second rail module 400b may be located on the right side with respect to the first rail module 400a.

FIG. 7 is a perspective view showing the rail module 400 of the range hood 1 shown in FIG. 6.

With reference to FIG. 7, a rail module 400 according to an embodiment of the present disclosure will be described.

The range hood 1 may include a rail module 400.

The rail module 400 may include a rail cover 410. The rail cover 410 may be configured to cover one side of the housing 100.

The rail cover 410 may be positioned to face the housing plate 110. Accordingly, the rail cover 410 can cover at least a portion of the housing plate 110.

The rail cover 410 may extend along the short side of the housing plate 110 (FIG. 9).

The rail cover 410 may have a bent plate shape.

The rail cover 410 may be capable of supporting the light source module 300 at the longitudinal end of the light source module 300 when the light source module 300 is in the receiving position.

The rail cover 410 may include a module support portion 413. The module support unit 413 may refer to a component that supports the light source module 300.

The module support 413 may contact the light source module 300. The module support portion 413 may contact the transparent member 350 to support the light source module 300.

The module support part 413 may be located in the first direction D1 with respect to the housing 100. The module support portion 413 may be located on the lower side of the housing 100. The module support portion 413 may define the lower exterior of the housing 100.

The module support portion 413 may be positioned adjacent to the cover member 380. The module support portion 413 may be in contact with the cover member 380. The module support portion 413 may define an aesthetic sense of being integrated with the cover member 380.

The module support portion 413 may extend along the short side of the housing plate 110.

The module support portion 413 may protrude in the left and right directions.

The module support portion 413 may have a plate shape. The module support portion 413 may have a long side in the front-to-back direction. The module support portion 413 may have short sides in the left and right directions.

The module support portion 413 may be positioned in the direction of gravity with respect to the light source module 300 to contact and support the light source module 300 when the light source module 300 is in the receiving position.

The module support portion 413 has a sliding opening 410A located in the sliding direction D3 so that the light source module 300 can move in the sliding direction D3 when the light source module 300 is moved from the receiving position to the separated position. can be defined.

The rail cover 410 may include a module cover portion 411. The module cover portion 411 may be configured to cover the light source module 300.

The module cover portion 411 may extend from the module support portion 413. The module cover portion 411 may extend from the module support portion 413 in a direction opposite to the first direction D1. The module cover portion 411 may extend upward from the module support portion 413.

The module cover portion 411 may extend from the end of the module support portion 413.

The module cover portion 411 may be located outside the housing 100.

The module cover portion 411 may be provided by bending from the module support portion 413.

The module cover may extend along the short side of the housing plate 110. The module cover portion 411 may extend along the second direction D2. The module cover portion 411 may extend along the front-to-back direction.

The module cover portion 411 may extend in the vertical direction.

The module cover portion 411 may have a plate shape. The module cover portion 411 may have long sides in the front-to-back direction. The module cover portion 411 may have short sides in the vertical direction.

The module cover portion 411 may be positioned in the longitudinal direction from the light source module 300 to cover the light source module 300 when the light source module 300 is in the receiving position.

A sliding opening 410A may be defined by the module cover part 411 and the module support part 413. The sliding opening 410A may be an opening into which the light source module 300 is inserted. Sliding opening 410A may be positioned forward or backward.

A sliding space 410S may be provided by the module cover part 411 and the module support part 413. The sliding space 410S may be a space capable of accommodating the light source module 300. The sliding space 410S may be located inward from the sliding opening 410A.

The rail module 400 may include a rail frame 420. The rail frame 420 may be coupled to the rail cover 410.

The rail frame 420 may be coupled to the inside of the rail cover 410. The rail frame 420 may be coupled to the module cover portion 411. By coupling the rail frame 420 to the rail cover 410, the strength of the rail cover 410 can be increased.

The rail frame 420 may extend along a short side of the housing plate 110.

The width of the rail frame 420 may correspond to the width of the module support portion 413. Because of this, the rail frame 420 can be accommodated inside the rail cover 410.

A sliding space 410S may be provided in front or behind the rail frame 420.

The rail frame 420 may be prevented from being positioned in the sliding space 410S. This is because when the rail frame 420 is located in the sliding space 410S, the guide light L2 can be prevented from diffusing to the left or right end of the transparent member 350. In order to spread the guide light L2, the rail frame 420 may be prevented from being positioned on the sliding space 410S.

Meanwhile, the rail frame 420 may extend in the sliding direction D3 so that a sliding space 410S capable of accommodating the light source module 300 is provided inside the rail cover 410.

The rail frame 420 may include a metal material. However, it is not limited to this.

The rail frame 420 may be formed through a drawing process. However, it is not limited to this.

FIG. 8 is an enlarged view showing the light source module 300 of the range hood 1 shown in FIG. 4 being coupled to the rail module 400. FIG. 9 is an enlarged view showing the light source module 300 of the range hood 1 shown in FIG. 8 coupled to the rail module 400.

With reference to FIGS. 8 and 9 , insertion of the light source module 300 into the rail module 400 according to an embodiment of the present disclosure will be described.

The range hood 1 may include a light source module 300 and a rail module 400.

The light source module 300 may be supported by the first rail module 400a and the second rail module 400b.

The rail module 400 can guide the sliding movement of the light source module 300.

It can be seen that the light source module 300 is separated from the rail module 400 and then accommodated again.

The position where the light source module 300 is inserted into the sliding space 410S defined on the rail module 400 may be referred to as the receiving position. The position where the light source module 300 is separated to the outside of the sliding space 410S may be referred to as the separation position.

The light source module 300 may be movable from a receiving position to a separated position. The light source module 300 may be movable from the separated position to the receiving position.

This will explain how the light source module 300 is moved from the separated position to the receiving position. The movement of the light source module 300 from the receiving position to the separated position is the opposite process of the light source module 300 moving from the separated position to the receiving position.

While the light source module 300 is moved from the separated position to the receiving position, the light source module 300 may be moved in a direction opposite to the second direction D2 past the sliding opening 410A.

The direction in which the light source module 300 moves from the separation position to the accommodation position can be referred to as the sliding accommodation direction D4. The direction in which the light source module 300 moves from the accommodation position to the separation position can be referred to as the sliding direction D3.

The sliding direction D3 may coincide with the second direction D2. However, since the traveling direction of the guide light L2 is not always the same as the moving direction of the module, the sliding direction may be different from the second direction D2.

While the light source module 300 moves in the sliding receiving direction D4, the transparent member 350 may be moved while contacting the module support portion 413 of the rail cover 410.

Movement of the light source module 300 in the direction of gravity may be prevented by the module support portion 413.

The light source module 300 may be moved with its movement in the left and right directions restricted by the module cover portion 411 of the rail cover 410.

When the light source module 300 is in the receiving position, the light source module 300 can be positioned within the sliding space.

The light source module 300 may contact the rail frame 420 and be prevented from moving in the sliding receiving direction D4. The light source module 300 may be placed in a receiving position in contact with the rail frame 420.

FIG. 10 is a perspective view showing the light source module 300 of the range hood 1 shown in FIG. 6. FIG. 11 is an enlarged view of the light source module 300 of the range hood 1 shown in FIG. 10 . FIG. 12 is an exploded view of the light source module 300 of the range hood 1 shown in FIG. 10. FIG. 13 is an exploded view of part of the configuration of the light source module 300 of the range hood 1 shown in FIG. 12.

With reference to FIGS. 10 to 13 , the light source module 300 according to an embodiment of the present disclosure will be described.

The light source module 300 may include a transparent member 350. The transparent member 350 may be configured to transmit the illumination light L1 emitted by the light source unit 200.

The transparent member 350 may extend along the direction in which the light source module 300 extends.

The transparent member 350 may have a rectangular plate shape. However, it is not limited to this.

The transparent member 350 may be provided to face the housing plate 110 (FIG. 6). The transparent member 350 may be provided to face the cooktop 2 (FIG. 2). The transparent member 350 may have flat surfaces on its upper and lower sides.

The transparent member 350 may be made of glass. However, it is not limited to this.

The transparent member 350 may be formed using a molding method. However, it is not limited to this.

The transparent member 350 may have a chamfer shape at the rear left or rear right corner. Because of this, the position of the conductor may not be disturbed.

The light source module 300 may include a lighting diffusion plate 360. The lighting diffusion plate 360 may be configured to diffuse the lighting light L1.

The lighting diffusion plate 360 may be positioned on the transparent member 350. The lighting diffusion plate 360 may be located above the transparent member 350. The lighting diffusion plate 360 may be supported by the transparent member 350.

The lighting diffusion plate 360 may be positioned between the transparent member 350 and the lighting light source 210 to diffuse the lighting light L1. Illumination light L1 may pass through the lighting diffusion plate 360 and the transparent member 350 and be emitted toward the cooktop 2.

The lighting diffusion plate 360 may be supported by the transparent member 350 so as to be detachable.

The transparent member 350 may extend in the sliding direction D3 to define the appearance of the light source module 300 in the direction of gravity.

The lighting diffusion plate 360 may extend in the direction in which the light source module 300 extends.

The lighting diffusion plate 360 may be made of a translucent plastic material. However, it is not limited to this.

The lighting diffusion plate 360 may be formed through a drawing process. However, it is not limited to this.

The light source module 300 may include a bracket support unit 330. The bracket support unit 330 may form the framework of the light source module 300.

The bracket support unit 330 may be positioned adjacent to the lighting diffusion plate 360. The bracket support unit 330 may be located in front or behind the lighting diffusion plate 360. The bracket support unit 330 of the first light source module 300a may be located in front of the lighting diffusion plate 360. The bracket support unit 330 of the second light source module 300b may be located behind the lighting diffusion plate 360.

The bracket support unit 330 may support the lighting diffusion plate 360. The bracket support unit 330 may guide the position of the lighting diffusion plate 360. The bracket support unit 330 may fix the position of the lighting diffusion plate 360 by contacting the lighting diffusion plate 360.

The bracket support unit 330 may be positioned on the transparent member 350. The bracket support unit 330 may contact the transparent member 350 on the upper side of the transparent member 350 . The bracket support unit 330 may be supported by the transparent member 350.

The bracket support unit 330 may extend along the extension direction of the light source module 300. The bracket support unit 330 may extend in the left and right directions.

The bracket support unit 330 can enhance the strength of the light source module 300.

That is, the bracket support unit 330 may be located on the transparent member 350 and in the second direction D2 from the lighting diffusion plate 360.

The bracket support unit 330 may include a bracket support 332. The bracket support 332 may be configured to support the bracket support unit 330.

Bracket support 332 may be positioned on transparent member 350. The bracket support 332 may be supported by the transparent member 350.

The bracket support 332 may be located inside the light source module 300.

The bracket support 332 may extend in the longitudinal direction. The bracket support 332 may extend along the longitudinal direction of the light source module 300. The bracket support 332 may extend along the long side of the transparent member 350.

The bracket support 332 may be in contact with the lighting diffusion plate 360.

The bracket support 332 may be made of metal. However, it is not limited to this.

The bracket support 332 may be formed through a drawing process. However, it is not limited to this.

The bracket support 332 may be combined with the cover housing 320.

The bracket support unit 330 may include a bracket 331. The bracket 331 may be configured to correspond to the frame of the light source module 300.

Bracket 331 may be positioned on bracket support 332. The bracket 331 can strengthen the strength of the light source module 300 together with the bracket supporter 332.

The bracket 331 may be combined with the cover housing 320.

The bracket 331 may extend in the longitudinal direction of the light source module 300. The bracket 331 may extend along the bracket support 332. The bracket 331 may extend along the long side of the transparent member 350.

The bracket 331 may have a substantially rectangular parallelepiped shape.

The bracket 331 may have a hollow interior defined therein. The hollow inside the bracket 331 may extend along the longitudinal direction of the bracket 331. Accordingly, the light source module 300 can become lighter. When the light source module 300 becomes lighter, servicing the light source module 300 may become easier. Additionally, the cost of manufacturing the light source module 300 can be reduced.

The bracket 331 may have a shape extending inside the light source module 300 on the upper side. As a result, a shape for coupling to the housing 100 can be prepared.

The bracket 331 may have a shape extending toward the outside of the light source module 300 on the lower side. As a result, a shape for coupling the cover housing 320 can be prepared.

The bracket 331 may be made of a metal material. However, it is not limited to this.

The bracket 331 may be formed through a drawing process. However, it is not limited to this.

The bracket 331 and the bracket support 332 together with the lighting diffusion plate 360 may define a lighting diffusion space 360S. The lighting diffusion space 360S may be a space through which the lighting light L1 passes.

Illumination light L1 must have a certain optical distance to be diffused. If the illumination light L1 is not diffused, the illumination light source 210 (not shown) is recognized through the transparent member 350, which may affect aesthetics.

The light source module 300 may include a light source support unit 340. The light source support unit 340 may form the framework of the light source module 300.

The light source support unit 340 may include a bracket 331. The bracket 331 may be configured to correspond to the frame of the light source module 300.

The light source support unit 340 may be located on the transparent member 350 and may be located in a direction opposite to the second direction D2 from the lighting diffusion plate 360.

Bracket 331 may be positioned on light source bracket support 342. The bracket 331 can strengthen the strength of the light source unit 200 together with the light source bracket supporter 342.

The bracket 331 may be combined with the cover housing 320.

The bracket 331 may extend in the longitudinal direction of the light source module 300. The bracket 331 may extend along the light source bracket support 342. The bracket 331 may extend along the long side of the transparent member 350.

The bracket 331 may have a substantially rectangular parallelepiped shape.

The bracket 331 may have a hollow interior defined therein. The hollow inside the light source bracket 341 may extend along the longitudinal direction of the light source bracket 341. Accordingly, the light source module 300 can become lighter. When the light source module 300 becomes lighter, servicing the light source module 300 may become easier. Additionally, the cost of manufacturing the light source module 300 can be reduced.

The light source bracket 341 may have a shape extending inside the light source module 300 on the upper side. As a result, a shape for coupling to the housing 100 can be prepared.

The light source bracket 341 may have a shape extending toward the outside of the light source module 300 on the lower side. As a result, a shape for coupling the cover housing 320 can be prepared.

The light source bracket 341 may be made of a metal material. However, it is not limited to this.

The light source bracket 341 may be formed through a drawing process. However, it is not limited to this.

The light source support unit 340 may be positioned adjacent to the lighting diffusion plate 360. The light source support unit 340 may be located in front or behind the lighting diffusion plate 360. The light source support unit 340 of the first light source module 300a may be located behind the lighting diffusion plate 360. The light source support unit 340 of the second light source module 300b may be located in front of the lighting diffusion plate 360.

The light source support unit 340 may support the lighting diffusion plate 360. The light source support unit 340 may guide the position of the lighting diffusion plate 360. The light source support unit 340 may fix the position of the lighting diffusion plate 360 by contacting the lighting diffusion plate 360.

The light source support unit 340 may be positioned on the transparent member 350. The light source support unit 340 may contact the transparent member 350 on the upper side of the transparent member 350 . The light source support unit 340 may be supported by the transparent member 350.

The light source support unit 340 may extend along the extension direction of the light source module 300. The light source support unit 340 may extend in the left and right directions.

The light source support unit 340 may enhance the strength of the light source module 300.

A lighting diffusion space 360S may be defined by placing the light source support unit 340 and the bracket support unit 330 in the front-to-back direction and the lighting diffusion plate 360 in the downward direction. As mentioned earlier, the lighting diffusion space 360S may be a space through which the lighting light L1 passes.

The light source support unit 340 may include a light source bracket support 342. The light source bracket supporter 342 may be configured to support the light source support unit 340.

Light source bracket support 342 may be positioned on transparent member 350. The light source bracket supporter 342 may be supported by the transparent member 350.

The light source bracket support 342 may be located inside the light source module 300.

The light source bracket support 342 may extend in the longitudinal direction. The light source bracket supporter 342 may extend along the longitudinal direction of the light source module 300. The light source bracket supporter 342 may extend along the long side of the transparent member 350.

The light source bracket support 342 may be in contact with the lighting diffusion plate 360.

The light source bracket support 342 may be made of a metal material. However, it is not limited to this.

The light source bracket support 342 may be formed through a drawing process. However, it is not limited to this.

The light source bracket support 342 may be combined with the cover housing 320.

The light source support unit 340 may include a light source bracket 341. The bracket 331 may be configured to correspond to the frame of the light source module 300.

The light source bracket 341 may be positioned on the transparent member 350. The bracket 331 can strengthen the strength of the light source unit 200 together with the light source bracket supporter 342.

The light source bracket 341 may extend in the longitudinal direction of the light source module 300. The light source bracket 341 may extend along the long side of the transparent member 350.

The light source bracket 341 may have a bent plate shape.

The light source bracket 341 may be made of a metal material. However, it is not limited to this. The light source bracket 341 may have a material that can reflect light. As a result, the guide light L2 may be reflected from the surface.

The light source bracket 341 may be formed through a drawing process. However, it is not limited to this.

The light source support unit 340 may include a light source bracket support 342. The light source bracket supporter 342 may be configured to support the light source bracket 341.

The light source bracket supporter 342 may extend in the longitudinal direction of the light source module 300.

The light source bracket supporter 342 may be coupled to the light source module 300 on the outside of the light source bracket 341. The light source bracket supporter 342 may support the light source bracket 341. The light source bracket supporter 342 can strengthen the strength of the light source bracket 341.

The light source bracket support 342 may have a rectangular parallelepiped shape.

The light source bracket support 342 may have a hollow interior. The hollow may extend along the longitudinal direction of the light source bracket supporter 342. Through this, less material of the light source bracket support body 342 can be used. Additionally, the weight of the light source module 300 can be reduced. If the weight of the light source module 300 is reduced, servicing the light source module 300 may become easier.

The light source module 300 may include a bracket connector 333. The bracket connector 333 may be configured to connect the bracket support unit 330 and the light source support unit 340.

The bracket connector 333 may be positioned between the bracket 331 and the light source bracket 341. The bracket connector 333 may be combined with the bracket 331 and the light source bracket 341. As a result, the bracket 331 and the light source bracket 341 can be supported. The coupling between the bracket 331 and the light source bracket 341 can be strengthened.

The bracket connector 333 may be located on the side of the light source module 300.

A pair of bracket connectors 333 may be provided. A pair of bracket connectors 333 may be located on both sides of the light source module 300, respectively. As a result, the bracket 331 and the light source bracket 341 can be coupled without receiving a rotational moment.

The bracket 331 may be positioned to be spaced apart from the lighting diffusion plate 360. The bracket 331 may be located on the upper side of the lighting diffusion plate 360. As a result, the lighting diffusion plate 360 can be separated from the light source module 300.

The bracket connector 333 may have a rectangular parallelepiped shape.

The bracket connector 333 may be made of a metal material. However, it is not limited to this.

The bracket connector 333 may be formed by casting. However, it is not limited to this.

The light source module 300 may include a guide light source 310. The guide light source 310 may be configured to emit guide light L2.

The guide light source 310 may be an LED (Light Emit Diode).

The guide light source 310 may emit guide light L2 in the first direction D1. The guide light source 310 may emit guide light L2 downward.

The guide light source 310 may be positioned to be spaced apart from the transparent member 350.

The light source module 300 may include a guide light source substrate 311. The guide light source substrate 311 may be configured to support the guide light source 310.

The guide light source substrate 311 may be configured to support the guide light source 310.

The guide light source substrate 311 may have a rectangular parallelepiped shape. The guide light source substrate 311 may have a plane facing the first direction D1.

The guide light source substrate 311 may extend along the longitudinal direction of the light source module 300.

The light source module 300 may include a guide diffusion plate 370. The guide diffusion plate 370 may be configured to guide the guide light L2.

The guide diffusion plate 370 may support the guide light source substrate 311. The guide diffusion plate 370 may be in contact with the guide light source substrate 311.

The guide diffusion plate 370 may be in contact with the transparent member 350.

The guide diffusion plate 370 may have a shape extending along the first direction D1. The guide diffusion plate 370 may extend in the vertical direction.

The guide diffusion plate 370 may be positioned between the guide diffusion substrate and the transparent member 350.

The guide diffusion plate 370 supports the guide diffusion substrate located on the upper side and may contact the end of the transparent member 350.

The guide diffusion plate 370 may have a shape that extends from one side of the guide light source 310 in the first direction D1 and is bent toward the transparent member 350 . A portion of the guide diffusion plate 370 extending toward the transparent member 350 may be located on the side of the guide light source 310 in the first direction D1.

The guide diffusion plate 370 may reflect the guide light L2 and direct it toward the transparent member 350.

The guide diffusion plate 370 may substantially function as a prism. The guide light L2 may enter the interior of the guide diffusion plate 370, be reflected from one side, and proceed toward the transparent member 350.

The guide diffusion plate 370 may be configured to reflect the guide light L2 in the second direction D2.

The guide diffusion plate 370 may be positioned to face the transparent member 350 so that the guide light L2 is emitted through the transparent member 350.

The light source module 300 may include a guide light source fixture 312. The guide light source fixture 312 may be configured to fix the guide light source substrate 311.

The guide light source fixture 312 may be in contact with the guide light source substrate 311. The guide light source fixture 312 may support the guide light source substrate 311 in a direction opposite to the first direction D1. The guide light source fixture 312 may be located on the upper side of the guide light source substrate 311.

The guide light source fixture 312 may be combined with the light source bracket support 342. The guide light source fixture 312 may be coupled to the light source bracket support 342 at the front or rear of the guide light source fixture 312 .

The guide light source fixture 312 may be combined with the guide light source substrate 311.

The guide light source fixture 312 may be made of a metal material. However, it is not limited to this. The guide light source fixture 312 may have a material capable of reflecting light.

The light source module 300 may include a cover member 380. The cover member 380 may define at least a portion of the lower exterior of the light source module 300.

The cover member 380 may be coupled to the guide diffusion plate 370 on a side of the guide diffusion plate 370 opposite to the first direction D1.

The cover member 380 extends in the first direction D1 from a portion in contact with the guide diffusion plate 370 and is bent to follow the second direction D2 from the first direction D1 of the transparent member 350. It may be extended.

The cover member 380 may extend along the longitudinal direction of the light source module 300.

The cover member 380 may be made of a metal material. However, it is not limited to this.

The cover member 380 may be formed through a drawing process.

Meanwhile, when the light source module 300 is in the receiving position, it may be positioned adjacent to the module support portion 413 in order to provide an aesthetic feel that is integrated with the module support portion 413.

The cover member 380 may be positioned to cover at least a portion of the transparent member 350 on a side opposite to the sliding direction D3 of the transparent member 350.

This will be described in more detail with reference to FIG. 12. The light source module 300 will be described assuming that it is the first light source module 300. In the case where the light source module 300 is the second light source module 300, the terms front and rear can be understood interchangeably in the following description.

The light source module 300 may include a transparent member 350. The transparent member 350 may have a plate shape.

The light source module 300 may include a lighting diffusion plate 360. A lighting diffusion plate 360 may be positioned on the transparent member 350. The lighting diffusion plate 360 may have a plate shape. The lighting diffusion plate 360 may be placed on the transparent member 350. The lighting diffusion plate 360 may be located above the transparent member 350.

The lighting diffusion plate 360 may not be attached to the transparent member 350 with adhesive. The lighting member may be supported by the transparent member 350. Accordingly, the lighting diffusion plate 360 can be separated from the transparent member 350. Accordingly, replacement service for the lighting diffusion plate 360 becomes easy.

The light source module 300 may include a bracket support 332. Bracket support 332 may be positioned on transparent member 350. The bracket support 332 may be located in front of the lighting diffusion plate 360.

The bracket support 332 may be guided so that the lighting diffusion plate 360 is coupled. The bracket support 332 may guide the coupling position of the lighting diffusion plate 360. The bracket support 332 may be spaced apart so that the lighting diffusion plate 360 is positioned between the light source bracket 341, which will be described later. A lighting diffusion plate 360 may be positioned between the bracket support 332 and the light source bracket 341. The distance between the bracket support 332 and the light source bracket 341 may correspond to the width of the lighting diffusion plate 360.

The bracket support 332 may have a substantially plate shape. The bracket support 332 may support a bracket 331 to be described later.

The light source module 300 may include a bracket 331. Bracket 331 may be positioned on bracket support 332. The bracket 331 may be located on the upper side of the bracket supporter 332. The bracket 331 may be in contact with the bracket support 332.

The bracket 331 can fix the cover housing 320, which will be described later.

The bracket 331 covers the upper side of the light source module 300 to prevent oil vapor from entering the upper side of the light source module 300.

The light source module 300 may include a cover housing 320. The cover housing 320 may define the front exterior of the light source module 300.

The front of the cover housing 320 may be arranged to be perpendicular to the ground.

The cover housing 320 may have a shape that protrudes rearward. The shape protruding rearward may be coupled to the bracket 331.

A control panel 391 may be located on the cover housing 320.

The light source module 300 may include a cover member 380. The cover member 380 may define at least a portion of the exterior of the light source module 300 on the side facing the cooktop 2 .

The cover member 380 may be provided to cover a portion of the rear of the transparent member 350. The cover member 380 may be provided to cover at least a portion of the rear of the light source module 300.

The cover member 380 may be provided to cover at least a portion of the lower side of the transparent member 350.

The cover member 380 may cover a portion of the lower rear of the transparent member 350.

The light source module 300 may include a bracket connector 333. The bracket connector 333 may connect the bracket 331 to the light source bracket 341, which will be described later.

The light source module 300 may have a lighting diffusion space 360S inside. The lighting diffusion space 360S may be a space where an opening is defined on the upper side. The lighting diffusion space 360S may be a space whose lower side is covered by the transparent member 350 or the lighting diffusion plate 360. As the lighting diffusion space 360S is defined in the light source module 300, a bending moment may occur around the opening by the lighting diffusion space 360S. Alternatively, the rigidity of the light source module 300 may be weakened by the lighting diffusion space 360S.

A component located on the front side of the lighting diffusion space 360S of the light source module 300 and a component located on the rear side of the lighting diffusion space 360S may be combined and supported by the bracket connector 333. The bracket connector 333 can strengthen the rigidity of the light source module 300.

A plurality of bracket connectors 333 may be provided. The bracket connectors 333 may be located one each on the left or right side. In this case, the bracket connector 333 can strengthen the rigidity of the light source module 300 on the left and right sides, respectively.

With reference to FIG. 13, the following configuration will be described in detail.

A lighting diffusion plate 360 may be provided on the upper side of the transparent member 350. The lighting diffusion plate 360 may be positioned between the aforementioned bracket 331 and the light source bracket 341. The lighting diffusion plate 360 may be configured to diffuse light.

The light source bracket support 332 may be located behind the light source bracket 341. The light source bracket supporter 332 may support the light source bracket 341 from the rear.

A guide light source fixture 312, which will be described later, may be fixed to the light source bracket supporter 332.

A guide diffusion space 370S may be defined between the light source bracket supporter 332 and the guide diffusion plate 370. The light source bracket support 332 may be located in front of the guide diffusion space 370S, and the guide diffusion plate 370 may be located in the rear of the guide diffusion space 370S.

A guide diffusion plate 370 may be provided behind the light source bracket supporter 332. The guide diffusion plate 370 may be located behind the transparent member 350. The guide diffusion plate 370 may be located behind the transparent member 350, the light source bracket supporter 332, and the light source bracket 341.

The guide diffusion space 370S may be defined by being surrounded by a transparent member 350, a light source bracket supporter 332, a light source bracket 341, and a guide diffusion plate 370, which will be described later. The guide diffusion space 370S may be a space through which the guide light L2 travels.

The guide diffusion plate 370 may be positioned so that at least a portion of the guide diffusion plate 370 is spaced apart from the guide light source 310 so that a guide diffusion space 370S is defined between the guide diffusion plate 370 and the guide light source 310 .

The light source support unit 340 may be positioned in the second direction D2 from the guide light source 310 so that a guide diffusion space 370S is defined between the light source support unit 340 and the guide diffusion plate 370.

The light source bracket support 332 or the light source bracket 341 may be configured so that the surface facing the guide diffusion space 370S can reflect light. When light traveling through the guide diffusion space 370S touches the light source bracket support 332 or the light source bracket 341, it is reflected and may move toward the guide diffusion plate 370.

That is, the light source support unit 340 may have an indirect reflection surface 341A facing the guide diffusion space 370S to reflect the guide light L2.

A guide light source substrate 311 that positions the guide light source 310 below may be positioned above the guide diffusion plate 370. The lower side of the guide light source substrate 311 may be supported by the guide diffusion plate 370.

A guide diffusion space 370S may be defined below the guide diffusion plate 370.

The guide light source 310 may emit guide light L2 downward. Guide light L2 may move toward the guide diffusion space 370S. The guide diffusion plate 370 may be located below the guide diffusion space 370S. The guide diffusion plate 370 may reflect the guide light L2 forward. The guide light L2 may pass through the transparent member 350 in front of the guide diffusion plate 370 and move toward the front of the light source module 300.

A guide light source fixture 312 may be located on the upper side of the guide light source substrate 311. The guide light source fixture 312 may fix the guide light source substrate 311. The guide light source substrate 311 can be prevented from moving by being fixed at the upper side by the guide light source fixture 312 and supported by the guide diffusion plate 370 at the lower side.

The guide light source fixture 312 can fix the guide light source substrate 311 by press fit.

FIG. 14 is a perspective view showing the housing 100, light source module 300, and light source unit 200 of the range hood 1 shown in FIG. 6.

With reference to FIG. 14 , a light source unit 200 according to an embodiment of the present disclosure will be described.

The range hood 1 may include a light source unit 200. The light source unit 200 may be configured to emit light in the first direction D1.

The light source unit 200 may be coupled to the housing 100. The light source unit 200 may be coupled to the housing plate 110. The light source unit 200 may be coupled to the housing plate 110 at the lower side of the housing plate 110 .

The light source unit 200 may emit illumination light L1 toward the first direction D1. Illumination light L1 may travel downward.

Illumination light L1 may proceed through an illumination diffusion space 360S defined on the light source unit 200. The illumination light L1 may pass through the illumination diffusion space 360S and pass through the illumination diffusion plate 360 and the transparent member 350.

That is, the transparent member 350 may be spaced apart from the illumination light source 210 in the first direction D1 so that the illumination light L1 is diffused.

FIG. 15 is a cross-sectional view showing the light source device Y of the range hood 1 shown in FIG. 10 cut away.

With reference to FIG. 15, the movement of light in the light source device Y will be described.

The light source device Y may include a light source unit 200 on a side away from the cooktop 2.

The light source device Y may include a light source module 300 on a side closer to the cooktop 2 than the light source unit 200.

The main body (X) may include a light source device (Y).

The light source device Y is an illumination light source 210 capable of emitting illumination light L1 in a first direction D1 from the main body It may include a guide light source 310 capable of emitting guide light L2.

The guide light source 310 may be configured to be controlled separately from the illumination light source 210. Accordingly, the power of the illumination light source 210 can be turned off while leaving the guide light L2 as is.

The second direction D2 may be defined to intersect the first direction D1. Accordingly, the guide light L2 may perform a different role from the illumination light L1.

The guide light source 310 may emit guide light L2 in the first direction D1.

The light source unit 200 may include an illumination light source 210. The illumination light source 210 may emit illumination light L1. The illumination light source 210 may emit illumination light L1 toward the cooktop 2. The illumination light source 210 may emit illumination light L1 downward.

Illumination light L1 may pass through the illumination diffusion space 360S. Illumination light L1 may be diffused while passing through the illumination diffusion space 360S. If the illumination light L1 is not diffused, the user can easily recognize the illumination light source 210. If the user can clearly recognize the lighting light source 210 from outside the light source module 300, the aesthetics of the range hood 1 may be reduced. If the shape of the light source is not visible and the light appears diffused, the aesthetics can be improved because the light is perceived as a surface rather than a point.

That is, the illumination light L1 is emitted from the illumination light source 210 and needs to travel a certain distance until it exits the outside of the light source module 300.

The light source module 300 may include an illumination diffusion plate 360 located below the illumination light source 210. The lighting diffusion plate 360 may be located below the lighting diffusion space 360S. Illumination light L1 may pass through the lighting diffusion plate 360 and be diffused. The lighting diffusion plate 360 may have a material that diffuses the lighting light L1. The lighting diffusion plate 360 may include an opaque material. The lighting diffusion plate 360 may be white.

A transparent member 350 may be included below the lighting diffusion plate 360. Illumination light L1 passing through the lighting diffusion plate 360 may penetrate the transparent member 350. The transparent member 350 may not be configured to diffuse light.

The transparent member 350 may have a transparent material through which light can penetrate. The transparent member 350 can enhance the aesthetics of the range hood 1 by having a transparent color. Aesthetics can be further improved compared to the case where the transparent member 350 serves to diffuse light.

The transparent member 350 may be located outside the light source module 300. The transparent member 350 may have a thickness of a certain thickness or more to protect the internal structure of the light source device (Y). The thickness of the transparent member 350 may be thicker than the thickness of the lighting diffusion plate 360.

The transparent member 350 may include a material that has less rigidity than the lighting diffusion plate 360. The transparent member 350 can protect a component located inside the light source device (Y) even if an impact comes from outside the light source device (Y).

Illumination light L1 passing through the transparent member 350 may proceed toward the cooktop 2. The illumination light L1 illuminates the food being cooked on the cooktop 2, allowing the user to easily cook the food.

A plurality of illumination light sources 210 may be provided. The plurality of illumination light sources 210 may be supported by an illumination light source substrate 211, which will be described later.

The number of the plurality of illumination light sources 210 may vary depending on the number of the plurality of guide light sources 310. This is because there is a limit to the power used by the light source module 300. The total number of the plurality of illumination light sources 210 and the plurality of guide light sources 310 may be a specific number. That is, as the number of the plurality of illumination light sources 210 increases, the number of the plurality of guide light sources 310 decreases. Conversely, as the number of the plurality of illumination light sources 210 decreases, the number of the plurality of guide light sources 310 increases. It can be configured to:

In other words, designing the light source by dividing it into an illumination light source 210 and a guide light source 310 may mean dividing and arranging light sources with a constant total sum.

The plurality of illumination light sources 210 may be arranged to be spaced apart at an equal distance in order to provide a desired amount of light toward the cooktop 2 despite the limited number of illumination light sources 210 .

This may also be the case for a plurality of guide light sources 310.

The light source unit 200 may include an illumination light source substrate 211. The lighting light source substrate 211 may be configured to support the lighting light source 210.

The illumination light source 210 may be located below the illumination light source substrate 211. The illumination light source substrate 211 may be located above the illumination diffusion space 360S. The illumination light source substrate 211 may be positioned to be spaced apart from the transparent member 350 .

The illumination light source substrate 211 may have a plate shape. The illumination light source substrate 211 may be positioned so that the planes located on the upper and lower sides have a larger area than the planes located on the sides. The illumination light source substrate 211 may be positioned to face upward or downward.

The illumination light source substrate 211 may be provided to extend along the light source module 300.

A plurality of lighting light source substrates 211 may be provided.

The light source unit 200 may include an illumination light source supporter 230. The lighting light source supporter 230 may be configured to support the lighting light source substrate 211 .

The illumination light source supporter 230 may be coupled to the illumination light source substrate 211 on the upper side of the illumination light source substrate 211 .

The illumination light source support 230 may be located above the illumination diffusion space 360S. The illumination light source supporter 230 may be positioned to be spaced apart from the transparent member 350 .

The illumination light source supporter 230 may have a shape corresponding to the illumination light source substrate 211 .

The illumination light source supporter 230 may be provided to extend along the light source module 300.

The lighting light source support 230 may be made of a metal material. However, it is not limited to this.

The lighting light source support 230 may be formed through a drawing process. However, it is not limited to this.

The light source unit 200 may include an illumination light source bracket 220. The illumination light source bracket 220 may be configured to fix the illumination light source substrate 211 or the illumination light source supporter 230 to the housing 100 .

The lighting light source bracket 220 may be coupled to the lighting light source support 230 on the upper side of the lighting light source support 230 .

The lighting light source bracket 220 may be combined with the housing 100. As a result, the lighting light source support 230 and the lighting light source substrate 211 can be combined with the housing 100.

The illumination light source bracket 220 may be located above the illumination diffusion space 360S. The illumination light source bracket 220 may be positioned to be spaced apart from the transparent member 350 .

The lighting light source bracket 220 may have a shape corresponding to the lighting light source substrate 211.

The illumination light source bracket 220 may be provided to extend along the light source module 300.

The lighting light source bracket 220 may be made of a metal material. However, it is not limited to this.

The lighting light source bracket 220 may be formed through a drawing process. However, it is not limited to this.

The surface of the lighting light source supporter 230 facing the lighting diffusion space 360S may have a larger area than the surface of the lighting light source substrate 211 facing the lighting diffusion space 360S. The surface of the lighting light source bracket 220 facing the lighting diffusion space 360S may have a larger area than the surface of the lighting light source substrate 211 facing the lighting diffusion space 360S.

That is, a portion of the surface of the lighting light source supporter 230 facing the lighting diffusion space 360S and a portion of the surface of the lighting light source bracket 220 facing the lighting diffusion space 360S are provided to surround the lighting diffusion space 360S. It can be.

The surface of the lighting light source supporter 230 facing the lighting diffusion space 360S and the surface of the lighting light source bracket 220 facing the lighting diffusion space 360S may be provided to reflect light. As a result, light moving upward can be reflected and moved toward the cooktop 2.

The light source module 300 may include a control panel 391. The control panel 391 may perform functions such as inputting user input, displaying the current status of the range hood 1, or displaying the kitchen environment.

The control panel 391 may be provided on the cover housing 100.

The light source module 300 may include a control box 390. The control box 390 may be configured to include electrical components related to the control panel 391.

The control box 390 may be located inside the light source module 300. The control box 390 may be located behind the control panel 391.

The light source module 300 may include a guide light source 310.

The guide light source 310 may be a light source separate from the lighting light source 210. The guide light source 310 may be controlled separately from the illumination light source 210. For example, the guide light source 310 may emit guide light L2, and the illumination light source 210 may not emit illumination light L1. For example, the guide light source 310 and the illumination light source 210 may emit light of different colors. For example, the pattern in which the guide light source 310 emits light may be different from the pattern in which the illumination light source 210 emits the illumination light L1.

The guide light source 310 may emit guide light L2.

Guide light L2 may pass through the guide diffusion space 370S. The guide light L2 may move toward the guide diffusion plate 370 located on one side of the guide diffusion space 370S.

The guide light L2 that has passed through the guide diffusion space 370S may pass through the guide diffusion plate 370. The guide light L2 may be reflected or refracted inside the guide diffusion plate 370, thereby changing its travel path.

The path of the guide light L2 may be changed to move toward the transparent member 350 by the guide diffusion plate 370. The refractive index of the guide diffusion plate 370 may be greater than the refractive index of air. Accordingly, the guide light L2 entering the guide diffusion plate 370 may move along the extension direction of the guide diffusion plate 370.

A cover member 380 may be provided below the guide diffusion plate 370. Even if part of the guide light L2 moves downward, it may be blocked by the cover member 380. Accordingly, the guide light L2 can be prevented from moving toward the cooktop 2.

The cover member 380 may be provided so that the side facing the guide diffusion plate 370 can reflect light. Accordingly, the guide light L2 directed from the guide diffusion plate 370 to the cover member 380 may be reflected by the cover member 380 and move toward the guide diffusion plate 370 or the transparent member 350.

The cover member 380 may be provided to cover the lower or rear side of the guide diffusion plate 370. The guide light L2 moving toward the rear of the guide diffusion plate 370 may be blocked by the cover member 380. Accordingly, it is possible to prevent the guide light L2 from being emitted into the inside of the range hood 1.

Guide light L2 may move forward along the transparent member 350. Since the transparent member 350 may have a higher refractive index than air, it may be difficult for the guide light L2 penetrating the transparent member 350 to move toward the air located outside the transparent member 350. The guide light L2 can thereby be moved forward.

The transparent member 350 may extend forward beyond the cover housing 100 . When the transparent member 350 does not extend forward beyond the cover housing 100, the guide light L2 may pass through the transparent member 350 and then move toward the cover housing 100. In this case, the guide light L2 may be seen as shining on the cover housing 100 and the transparent member 350 from the outside of the range hood 1, which may impair aesthetics. As the transparent member 350 extends forward beyond the cover housing 100, when the range hood 1 is viewed from the outside of the range hood 1, the guide light L2 is emitted only from the transparent member 350. It may appear that As a result, the range hood 1 with improved aesthetics can be provided.

The direction in which the guide light L2 exits the range hood 1 may intersect with the direction in which the illumination light L1 exits the range hood 1. The guide light L2 may exit the range hood 1 in a different direction from the illumination light L1 due to the above-mentioned light guiding configuration. The guide light L2 is radiated in a different direction from the illumination light L1, and thus may perform a different function from the illumination light L1.

The light source module 300 may include a guide diffusion plate 370.

The guide diffusion plate 370 may include a substrate support portion 371. The substrate supporter 371 may be configured to support the guide light source substrate 311.

The substrate supporter 371 may be configured to support the guide light source substrate 311.

The substrate support 371 may be located on the side of the guide light source 310.

The substrate support 371 may extend parallel to the guide light source substrate 311. The guide light source substrate 311 may extend in the left and right directions. The substrate support 371 may extend in the left and right directions.

The substrate support 371 may be supported by the cover member 380. The substrate support 371 may be in contact with the cover member 380.

One side of the substrate supporter 371 may be positioned toward the guide light source substrate 311, and the other side opposite the one side may be positioned toward the cover member 380.

The guide light source 310 may be located in front of the substrate supporter 371.

The guide diffusion plate 370 may include a prism portion 373. The prism unit 373 may be configured to change the path of the guide light L2.

The prism unit 373 may be located on the path of the guide light L2. The prism unit 373 may be located below the guide light source 310. The prism portion 373 may be located below the guide diffusion space 370S.

The prism unit 373 may be configured to allow the guide light L2 to pass through the interior and be reflected in the first direction D1 and the second direction D2 and on the inclined surface 373A.

The prism portion 373 may extend along the extension direction of the light source module 300. The prism portion 373 may extend in the left and right directions.

The cross section of the prism portion 373 may be a right triangle.

The prism portion 373 may include a plane facing the guide light source 310 on a side facing the guide light source 310 . The plane facing the guide light source 310 may extend in a direction perpendicular to the direction of travel of the guide light L2. Accordingly, the guide light L2 may face the plane of the prism portion 373 perpendicular to the direction of travel. The plane located on the side of the prism unit 373 facing the guide light source 310 may be a plane facing upward or a plane parallel to the ground.

The guide light L2 may pass through the air located in the guide diffusion space 370S and be incident towards the prism unit 373, which has a higher refractive index than the air. In this case, since the guide light L2 encounters a plane perpendicular to the direction of travel, it can enter the prism unit 373 without refraction. Since the guide light L2 enters the prism part and is not refracted, it may not be dispersed. Since the guide light L2 is not dispersed, the guide light L2 exiting to the outside of the light source module 300 may display a color that is not dispersed. Accordingly, the guide light L2 can be displayed in a desired color.

The prism portion 373 may include a plane facing the transparent member 350 on a side facing the transparent member 350 . The plane facing the transparent member 350 may extend in a direction perpendicular to the direction in which the guide light L2 travels as it exits the prism portion 373. The plane located on the side of the prism portion 373 facing the transparent member 350 may be a plane facing forward or a plane perpendicular to the ground.

Accordingly, the guide light L2 may face the plane of the prism portion 373 perpendicular to the direction of travel. For the same reason as before, dispersion of the guide light L2 can be prevented as it exits the prism unit 373.

The prism unit 373 may have an inclined surface 373A provided to change the direction of travel of the guide light L2. The inclined surface 373A may be located between a surface on which the prism portion 373 is located on the side facing the guide light source 310 and a surface on which the prism portion 373 is located on the side facing the transparent member 350. .

The inclined surface 373A may extend along the left and right directions. The inclined surface 373A may be inclined at a 45 degree angle with the ground. Accordingly, the downward-directed guide light L2 emitted from the guide light source 310 may be reflected from the inclined surface 373A and directed forward.

The guide diffusion plate 370 may include a connection portion 372. The connection part 372 may be configured to connect the prism part 373 and the substrate support part 371.

The connection portion 372 may be coupled to the substrate support portion 371 at the lower side of the substrate support portion 371 .

The connection part 372 may extend from the substrate support part 371 to the prism part 373 to guide the guide light L2 emitted from the guide light source 310 to the prism part 373.

The connection part 372 may be coupled to the prism part 373 on the upper side of the prism part 373.

The connection portion 372 may be configured to extend in the vertical direction. Accordingly, even if the guide light L2 does not go straight toward the prism portion 373 and moves toward the connecting portion 372, the guide light L2 can be moved to the prism portion 373 through the connecting portion 372. .

The rear side of the connection portion 372 may be supported by the cover member 380.

Additionally, the position of the lighting diffusion plate 360 may be guided.

The lighting diffusion plate 360 may include a diffusion plate guide portion 361. The diffusion plate guide unit 361 may be configured to easily guide the position of the lighting diffusion plate 360.

The position of the lighting diffusion plate 360 can be guided by the bracket support unit 330, which can be positioned at the front, and the light source support unit 340, which can be positioned at the rear.

The diffusion plate guide unit 361 may be configured to contact the bracket support unit 330 or the light source support unit 340.

The diffusion plate guide portion 361 may be bent in a direction away from the transparent member 350.

The diffusion plate guide unit 361 may be bent in a direction opposite to the first direction D1 so as to be in contact with the bracket support unit 330 or the light source support unit 340. As a result, the area in contact with the bracket support unit 330 or the light source support unit 340 can be expanded.

FIG. 16 is a control block diagram for the sensor of the range hood 1 shown in FIG. 1.

With reference to FIG. 16, a fine dust sensor 900 according to an embodiment of the present disclosure will be described.

The range hood 1 may include a fine dust sensor 900. The fine dust sensor 900 may be configured to output a signal in response to the surrounding fine dust concentration.

The fine dust sensor 900 may output a signal according to the fine dust concentration.

The range hood 1 may include a control unit 1000. The control unit 1000 may include a processor 1100 and a memory 1200.

The processor 1100 may be electrically connected to the fine dust sensor 900.

The memory 1200 may store or remember a program (a plurality of instructions) or data for processing signals and providing control signals. The memory 1200 includes volatile memory 1200 such as Static Random Access Memory (S-RAM) and Dynamic Random Access Memory (D-RAM), Read Only Memory (ROM), It may include a non-volatile memory 1200 such as Erasable Programmable Read Only Memory (EPROM). The memory 1200 may be provided integrally with the processor 1100 or may be provided as a semiconductor device separate from the processor 1100.

Additionally, an external memory may be provided outside the processor 1100.

The processor 1100 may further include a processing core (eg, an arithmetic circuit, a memory circuit, and a control circuit) that processes signals and outputs control signals based on the program or data stored in the memory 1200.

The processor 1100 may identify the fine dust concentration based on the signal output from the fine dust sensor 900. The processor 1100 may control the guide light source 310 based on the identified fine dust concentration. The processor 1100 may control the guide light source 310 so that the user can identify the concentration of fine dust through the guide light source 310.

That is, the processor 1100 measures fine dust exceeding a value preset by the fine dust sensor 900 and transmits the guide light L2 through the guide light source 310 based on the signal output from the fine dust sensor 900. You can control color.

However, the processor 1100 may control the guide light source 310 based on other signals as well as the fine dust sensor 900.

For example, when the temperature of the cooktop 2 is overheated, the processor 1100 may control the guide light source 310 to notify the user.

That is, the guide light source 310 may be controlled separately from the illumination light L1.

The guide light source 310 may emit guide light L2 of a different color from the illumination light L1 emitted by the illumination light source 210. Accordingly, the user can easily identify that the guide light source 310 displays information separate from the illumination light source 210.

FIG. 17 is a flowchart showing a sensing method by the fine dust sensor 900 of the range hood 1 shown in FIG. 16. FIG. 18 is a conceptual diagram illustrating a state in which the fine dust sensor 900 of the range hood 1 shown in FIG. 17 does not detect fine dust. FIG. 19 is a conceptual diagram showing a state in which the fine dust sensor 900 of the range hood 1 shown in FIG. 18 detects fine dust.

With reference to FIGS. 17 to 19, a method for measuring fine dust according to an embodiment of the present disclosure will be described.

The guide light source 310 may emit a first color (S1). The color of the guide light L2 emitted by the guide light source 310 may be a color other than white. However, the color of the guide light L2 emitted by the guide light source 310 may be white. For convenience of explanation, the guide light L2 is assumed to be a color other than white. For example, the first color may be blue.

Illumination light L1 emitted by the illumination light source 210 may be white. Since the illumination light L1 is used to illuminate the cooktop 2, the food needs to be clearly identified by the illumination light L1. Accordingly, the illumination light L1 may be white or have a color that is advantageous for object identification.

On the other hand, the guide light source 310 may have the purpose of display. Accordingly, the guide light L2 may have a color to decorate the exterior or clearly identify the displayed signal. Accordingly, the guide light L2 may be suitable for achieving its purpose even if it has a color other than white.

The fine dust sensor 900 may output a signal corresponding to a fine dust concentration greater than a preset fine dust concentration.

Alternatively, the fine dust sensor 900 may output a signal corresponding to the fine dust concentration.

The processor 1100 may identify the fine dust concentration based on the signal output by the fine dust sensor 900. The processor 1100 may determine whether the identified fine dust concentration is greater than or equal to a preset fine dust concentration (S2).

For example, the preset fine dust concentration may be the minimum fine dust concentration harmful to the human body.

When the fine dust sensor 900 outputs a signal corresponding to a preset fine dust concentration, the processor 1100 determines that the fine dust concentration is more than the preset value based on the signal output by the fine dust sensor 900. can be identified.

When the fine dust sensor 900 outputs a signal in response to the fine dust concentration, the processor 1100 determines that the fine dust concentration is greater than a preset value based on the signal output by the fine dust sensor 900. can do.

When the concentration of fine dust is higher than a preset value, the processor 1100 controls the guide light source 310 to change the color of the guide light (L2) emitted by the guide light source 310 to a second color different from the first color. You can. For example, the second color may be red.

The user can determine whether the indoor fine dust concentration is harmful to the human body through the guide light L2 that changes from the first color to the second color.

After checking the second color guide light L2, the user can take actions such as ventilating the room or operating an air purifier.

Above, the range hood 1 according to an embodiment of the present disclosure has been described. Below, embodiments different from the above embodiments will be described. In explaining the embodiments described below, the same reference numerals may be assigned to the same components as those shown in FIGS. 1 to 19 and the description may be omitted.

FIG. 20 is a cross-sectional view showing the light source device Y-1 of the range hood 1-1 according to an embodiment of the present disclosure.

With reference to FIG. 20, the light source module 300-1 according to an embodiment of the present disclosure will be described.

The light source module 300-1 may include a guide light source 310-1.

The guide light source 310-1 may irradiate light directly toward the transparent member 350.

The guide light source 310-1 may be located behind the transparent member 350. The guide light source 310-1 may emit guide light L2 from the rear of the transparent member 350 toward the front.

The guide light source 310-1 may be positioned to be spaced apart from the transparent member 350. By this, the guide light source 310-1 can be diffused.

The light source module 300-1 may include a guide light source substrate 311-1.

The guide light source substrate 311-1 may be positioned perpendicular to the transparent member 350 to support the guide light source 310-1.

That is, the light source device Y-1 defines an illumination diffusion space 360S through which the illumination light L1 can pass by being spaced apart from the illumination light source 210 in the first direction D1 so that the illumination light L1 is diffused. It may include a transparent member 350 configured to do so. At this time, the guide light source 310-1 is located in a direction opposite to the second direction D2 of the transparent member 350 and guide light L2-1 is directed toward the transparent member 350 in the second direction D2. can emit.

This embodiment differs from the embodiment described with reference to FIGS. 1 to 19 in that it does not require the guide diffusion plate 370.

FIG. 21 is a cross-sectional view showing the light source device Y-2 of the range hood 1-2 according to an embodiment of the present disclosure.

With reference to FIG. 21, a light source device (Y-2) according to an embodiment of the present disclosure will be described.

The light source device Y-2 may include a light source unit 200-2.

The light source unit 200-2 may include an illumination light source 210-2.

The illumination light source 210-2 may emit illumination light L1-2 from the front to the rear. However, the illumination light source 210-2 is not limited thereto, and may emit the illumination light L1-2 from the rear to the front, or may emit the illumination light L1-2 at a certain angle.

The light source unit 200-2 may include an illumination light source substrate 211-2.

The lighting light source substrate 211-2 may be configured to extend in the vertical direction to support the lighting light source 210-2.

The light source unit 200-2 may include an illumination light source supporter 230-2 and an illumination light source bracket 220-2. The lighting light source supporter 230-2 and the lighting light source bracket 220-2 may be configured to extend in the vertical direction to support the lighting light source substrate 211-2.

Illumination light L1-2 emitted from the illumination light source 210-2 may travel backward. The illumination light L1-2 needs to be moved toward the cooktop 2 located below to illuminate the cooktop 2.

The light source module 300-2 may include a lighting guide diffusion plate 250-2. The lighting guide diffusion plate 250-2 may be configured to change the path of the lighting light L1-2.

The lighting guide diffusion plate 250-2 may have a shape corresponding to the guide diffusion plate 370.

The lighting guide diffusion plate 250-2 can change the path of the illumination light L1-2 moving in the front-back direction so that it moves downward.

The lighting guide diffusion plate 250-2 may be coupled to and fixed to the light source bracket 341.

The lighting guide diffusion plate 250-2 may be positioned to be spaced apart in a direction opposite to the second direction D2.

The illumination light source 210-2 may emit illumination light L1-2 toward the illumination guide diffusion plate 250-2.

The lighting guide diffusion plate 250-2 may reflect the lighting light L1-2 emitted by the lighting light source 210-2 in the first direction D1.

This embodiment is different from the embodiment described with reference to FIGS. 1 to 19 in that the path of the illumination light L1-1 is different.

Figure 22 is an exploded view showing a portion of the main body (X-3) of the range hood (1-3) according to an embodiment of the present disclosure.

With reference to FIG. 22, a range hood 1-3 according to an embodiment of the present disclosure will be described.

The range hood 1-3 may include a light source device Y-3.

The light source device Y-3 may include a light source unit 200-3 and a light source module 300-3.

The light source unit 200-3 may be coupled to the light source module 300-3.

In the above, specific embodiments are shown and described. However, it is not limited to the above-described embodiments, and those skilled in the art can make various changes without departing from the gist of the technical idea of the invention as set forth in the claims below. .

Range hood: 1
Cooktops: 2
Body: X
Housing: 100
Light source device: Y
Light unit: 200
Lighting light source: 210
Illumination light source board: 211
Lighting light source bracket: 220
Illumination light source support: 230
Light guide diffuser plate: 250
Light module: 300
Guide light source: 310
Guide light source board: 311
Guide light source fixture: 312
Bracket support unit: 330
Light source support unit: 340
Transparent member: 350
Light diffuser: 360
Light diffusion space: 360S
Diffusion plate guide part: 361
Guide diffuser plate: 370
Board support: 371
Connection: 372
Prism part: 373
Slope: 373A
Cover member: 380
Fine dust sensor: 900
Control: 1000
Processor: 1100
Memory: 1200
Illumination light: L1
Guide light: L2
First direction: D1
Second direction: D2
Sliding direction: D3
Sliding acceptance direction: D4

Claims (20)

A range hood for ventilating odors generated from food cooked on a cooktop,
exhaust fan;
a duct configured to accommodate the exhaust fan; and
A main body coupled to the duct and positioned to face the cooktop,
The main body is a range hood including a light source device including an illumination light source capable of emitting illumination light from the main body in a first direction toward the cooktop and a guide light source capable of emitting guide light from the main body in a second direction. According to paragraph 1,
A range hood where the guide light source is configured to be controlled separately from the lighting light source. According to paragraph 1,
A range hood wherein the second direction is defined to intersect the first direction. According to paragraph 1,
The range hood is capable of emitting guide light of a different color from the illumination light emitted by the illumination light source. According to paragraph 1,
The light source device further includes a transparent member spaced apart from the illumination light source in a first direction to diffuse the illumination light. According to clause 5,
The light source device further includes an illumination diffusion plate positioned between the transparent member and the illumination light source to diffuse the illumination light,
A range hood wherein the illumination light passes through the lighting diffusion plate and the transparent member and is emitted toward the cooktop. According to clause 6,
A range hood in which the lighting diffusion plate is supported by the transparent member so that it is detachable. According to clause 6,
The light source device is,
a bracket support unit positioned on the transparent member and positioned in the second direction from the lighting diffusion plate; and
Further comprising a light source support unit located on the transparent member and located in a direction opposite to the second direction from the lighting diffusion plate,
The lighting diffusion plate is a range hood including a diffusion plate guide portion bent in a direction opposite to the first direction so as to contact the bracket support unit or the light source support unit. According to clause 5,
The guide light source emits the guide light in the first direction,
The light source device further includes a guide diffusion plate configured to reflect the guide light in the second direction. According to clause 9,
A range hood in which the guide diffusion plate is positioned to face the transparent member so that the guide light is emitted through the transparent member. According to clause 9,
A range hood wherein at least a portion of the guide diffusion plate is positioned to be spaced apart from the guide light source so that a guide diffusion space is defined between the guide light source and the guide light source. According to clause 11,
The light source device further includes a light source support unit positioned in the second direction from the guide light source so that the guide diffusion space is defined between the guide diffusion plate,
The light source support unit is a range hood having an indirect reflection surface facing the guide diffusion space to reflect the guide light. According to clause 11,
The guide diffusion plate includes a prism portion configured to allow the guide light to pass through the interior and be reflected on an inclined surface inclined to the first direction and the second direction. According to clause 13,
Further comprising a guide light source substrate configured to support the guide light source,
A range hood wherein the guide diffusion plate includes a substrate support portion configured to support the guide light source substrate. According to clause 14,
The substrate support portion is located on a side of the guide light source,
The guide diffusion plate further includes a connection portion extending from the substrate support portion to the prism portion to guide the guide light emitted from the guide light source to the prism portion. A range hood for ventilating odors generated from food cooked on a cooktop,
It includes a main body positioned to face the cooktop,
The range hood includes a detachable light source device, wherein the main body includes an illumination light source capable of emitting illumination light from the main body in a first direction toward the cooktop and a guide light source capable of emitting guide light from the main body in a second direction. According to clause 16,
A fine dust sensor that outputs a signal according to the fine dust concentration; and
Further comprising a processor electrically connected to the fine dust sensor,
The processor measures fine dust exceeding a preset value by the fine dust sensor and controls the color of the guide light through the guide light source based on a signal output from the fine dust sensor. According to clause 16,
The light source device further includes a transparent member configured to define an illumination diffusion space through which the illumination light can pass by being spaced apart from the illumination light source in the first direction so that the illumination light is diffused,
The guide light source is located in a direction opposite to the second direction of the transparent member, and emits guide light in the second direction toward the transparent member. According to clause 16,
The light source device is,
Further comprising an illumination guide diffusion plate positioned to be spaced apart from the illumination light source in a direction opposite to the second direction,
The illumination light source is capable of emitting the illumination light toward the illumination guide diffusion plate,
A range hood wherein the lighting guide diffusion plate reflects the lighting light emitted by the lighting light source in the first direction. exhaust fan;
a duct configured to accommodate the exhaust fan;
an illumination light source capable of emitting illumination light downward;
A guide light source capable of emitting guide light forward;
a transparent member positioned and spaced below the illumination light source; and
A range hood including an illumination diffusion plate positioned between the transparent member and the illumination light source to diffuse the illumination light.

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