KR20210140930A - Aircleaner - Google Patents

Abstract

The present invention relates to an air conditioner. More particularly, the present invention relates to an air purifier with a light-emitting assembly, which comprises: a case; a filter member disposed inside the case and including a photocatalyst; and the light-emitting assembly which activates the photocatalyst by irradiating light. The light-emitting assembly includes: a substrate disposed on one side of the filter member; a light source disposed on the substrate and irradiating light to activate the photocatalyst; and a cover which is supported on the substrate and surrounds at least a part of the light source and refracts the light emitted by the light source to the filter member. Accordingly, the light-emitting assembly uniformly irradiates light to the entire surface of the filter member and irradiates light so that light does not leak to the outside.

Description

air purifier {Aircleaner}

The present invention relates to an air purifier, and more particularly, to an air purifier having a deodorizing filter.

An air purifier is a device that sucks in polluted air, purifies it, and then discharges the purified air. The air purifier includes a blower that introduces external air into the air purifier and a filter that can filter out dust or bacteria in the air. In general, an air purifier is configured to purify an indoor space such as a home or office.

The blower is a device that sucks air into the air purifier and discharges the filtered air again. The blowing device includes a blowing fan and a fan housing accommodating the blowing fan. The fan housing has an inlet for sucking in air and an outlet for discharging the air.

A filter is a device that filters dust or bacteria contained in the air sucked into the air purifier. There are several types of filters, such as pre-filters, HEPA filters, and deodorizing filters. The air purifier may be provided by manufacturing the various types of filters as one filter member.

HEPA filter is an abbreviation of High Efficiency Particulate Air Filter, which is a high-performance filter that collects fine particles contained in air or exhaust gas. HEPA filters are placed in the air exhaust pipe to prevent harmful microorganisms from being released to the outside in pharmaceutical facilities or laboratories, and in recent years, they are installed in air conditioners to filter fine particles such as fine dust or microorganisms.

The deodorizing filter is a high-performance filter that removes odor particles generated in the room. The deodorizing filter is called an activated carbon filter or a carbon filter. The deodorizing filter removes household odors such as ammonia, removes substances that cause sick house syndrome such as formaldehyde, and filters substances that generate odors such as nitrogen oxides.

A pre-filter is usually a low-performance filter that physically removes dust. The pre-filter is disposed in the air inflow direction of the HEPA filter or the deodorizing filter, and filters some of the dust present in the air before reaching the HEPA filter or the deodorizing filter. HEPA filters and deodorizing filters are high-performance and high-efficiency filters, and their cost is also high. Therefore, a pre-filter is disposed upstream of the HEPA filter or the deodorization filter, and large dust or the like is primarily filtered. That is, the pre-filter is a filter that protects a high-performance filter such as a HEPA filter or a deodorization filter, and improves the lifespan of the high-performance filters.

According to the prior art, the deodorizing filter may be a photocatalytic filter. The photocatalytic filter includes a light emitting module. The light emitting module irradiates light with a deodorizing filter. The light irradiated to the deodorizing filter causes a chemical reaction to remove the captured odor particles and reduce the filter material. The reduced filtration material can recapture new odor particles.

However, the light irradiated from the light source is generally irradiated in all directions. Since the distance between the light source and the respective parts of the deodorizing filter is generally different, there is a problem in that it is difficult to evenly irradiate the irradiated light to the entire surface of the photocatalytic filter. In addition, the deodorizing filter according to the prior art has a problem in that the irradiated light leaks out of the photocatalytic filter, causing inconvenience to the user.

The problem to be solved by the present invention is to provide an air purifier having a light emitting module that uniformly irradiates light to the front of the deodorizing filter.

Another object of the present invention is to provide an air purifier having a light emitting module for irradiating light so that light does not leak to the outside.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, an air purifier according to an embodiment of the present invention includes a case, a filter member disposed inside the case and including a photocatalyst, and a light emitting assembly that activates the photocatalyst by irradiating light, wherein the light emitting assembly includes a filter A substrate disposed on one side of the member, a light source disposed on the substrate and irradiating light to activate a photocatalyst, a cover supported on the substrate and surrounding at least a portion of the light source, and refracting the light emitted by the light source to the filter member.

In addition, the light emitting assembly may be disposed at one end of the filter member, the substrate may be disposed vertically of the filter member, and the light source may irradiate light from one side of the filter member to the other side of the filter member.

In addition, the filter member may be formed in a cylindrical shape, and the light source may be disposed in an inner space of the filter member.

In addition, the cover may include an outer surface exposed to the outside, and an inner surface corresponding to the outer surface and facing the light source but disposed to be spaced apart from the light source.

The inner surface includes a first inner surface having a lower end disposed on the substrate radially inner side of the light source and extending radially outwardly, and a second inner surface having a lower end disposed on the substrate radially outer side of the light source and extending radially inwardly upwardly. It may include an inner surface.

The outer surface includes a first outer surface having a lower end disposed on a substrate radially inner side of the light source and extending radially outwardly upward, and a second outer surface having a lower end disposed on a substrate radially outer side of the light source and extending radially inwardly upwardly. side may be included.

In addition, the cover may be formed in a cross-sectional shape of the lower light.

The details of other embodiments are included in the detailed description and drawings.

According to the air purifier of the present invention, there are one or more of the following effects.

First, the cover according to the present invention has the advantage of refracting the light irradiated from the light source, evenly irradiating the light on the inner peripheral surface of the filter member.

Second, the upper ends of the first inner surface and the second inner surface are connected to each other to form a bent portion, and there is also an advantage of improving efficiency by preventing light that is irradiated upward and is lost.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of an air purifier;
2 is a cross-sectional view of the air purifier of FIG. 1;
3 is an exploded perspective view of the air purifier of FIG. 1;
4 is a perspective view of a filter member and a light emitting assembly disposed inside the air purifier according to the present invention;
5 is an exploded perspective view of the light emitting assembly according to the present invention;
6 is a cross-sectional view of the light emitting assembly;
7 is a state diagram of a light emitting assembly according to an embodiment of the present invention;
8 is a state diagram of a light emitting assembly according to another embodiment of the present invention;
9 is a view showing the illuminance when the light emitting assembly according to the prior art is operated;
10 is a view showing the illuminance when the light emitting assembly according to the present invention is operated.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Hereinafter, the present invention will be described with reference to the drawings for explaining the air purifier 10 according to embodiments of the present invention.

define the direction 1 , the vertical direction is called an axial direction, and the horizontal direction is called a radial direction. The axial direction may correspond to the central axial direction of the blowing fan 160 , that is, the motor shaft direction of the blowing fan 160 . The radial direction may be understood as a direction perpendicular to the axial direction. The circumferential direction is understood as an imaginary circle direction formed when rotating about an axial direction and a radial distance as a radius of rotation.

Referring to FIG. 1 , the air purifier 10 according to the present invention includes a case 101 . The case 101 forms the exterior of the air purifier 10 and forms a space in which the components are disposed.

The case 101 forms an air flow path therein.

The case 101 may be formed in a cylindrical shape. The diameter of the upper part of the case 101 may be smaller than the diameter of the lower part. The case 101 may be formed in a truncated cone shape.

A discharge unit 105 through which air is discharged is formed on the upper surface of the case 101 , and a suction unit 102 through which air is sucked is formed below the discharge unit 105 .

Referring to FIG. 1 , a suction unit 102 through which air is sucked is formed in the case 101 . The suction unit 102 includes a through hole formed through at least a portion of the case 101 . A plurality of through holes are formed.

A plurality of suction units 102 are disposed along the outer circumferential surface of the case 101 . The suction unit 102 is capable of sucking air from all sides of the case 101 . Air existing around the air purifier 10 is sucked into the air purifier 10 in a radial direction.

The case 101 is configured in a cylindrical shape, and a plurality of suction units 102 are formed along the outer circumferential surface of the case 101 , thereby increasing the amount of air intake.

Referring to FIG. 1 , a discharge unit 105 through which air is discharged is formed in the case 101 . The discharge part 105 may be formed on the upper surface of the case 101 . The air sucked in from the suction unit 102 is discharged upward of the air purifier 10 through the discharge unit 105 formed at the upper end of the case 101 .

The air purifier 10 includes a base 20 disposed under the case 101 to support the case 101 .

The base 20 is disposed to be spaced downward from the lower end of the case 101 . A base suction part 103 is formed in the space between the case 101 and the base 20 . Air sucked through the base suction unit may flow upward through the suction port of the suction grill 110 provided on the upper side of the base 20 .

The air purifier 10 includes a plurality of suction units 102 and 103 . More specifically, indoor air may be sucked into the air purifier 10 through the suction unit 102 formed on the outer circumferential surface of the case 101, and may be sucked into the air purifier 10 through the base suction unit. may be In particular, air existing in the lower part of the indoor space can be easily introduced into the air purifier 10 through the base suction unit 103 . Accordingly, the intake amount of air can be increased.

The air purifier 10 includes a suction grill 110 disposed on the upper side of the base 20 . The suction grill 110 includes a ring-shaped body. The suction grill 110 includes a suction port formed on the edge of the body, and the suction port is interlocked with the base suction unit. The air sucked from the base suction unit passes through the suction grill 110 and is mixed with the air sucked from the outer circumferential surface of the case 101 .

The air purifier 10 includes a blower 100 for flowing air. The blower 100 provides a flow pressure of air, and sucks air through an inlet.

The blower 100 is disposed on the upper side of the filter member 200 to flow the filtered air passing through the filter member 200 upward.

The blower 100 includes a fan housing 150 disposed on the outlet side of the filter member 200 . The fan housing 150 is a component supporting the fan 160 .

The fan housing 150 is supported by the filter frame 130 . In more detail, the fan housing 150 is disposed on the upper end of the filter frame 130 , and is supported by the filter frame 130 . The fan housing 150 may form a part of the side surface of the air purifier 10 . The fan housing 150 forms a space therein, and the fan 160 is disposed in the space formed by the fan housing 150 .

The blowing device 100 includes a blowing fan 160 , and the blowing fan 160 is accommodated in the fan housing 150 . The blowing fan 160 provides a flow pressure of air through rotation, and generates an air flow. The blowing fan 160 introduces the air in the lower part in the axial direction, and discharges it upward.

The blowing fan 160 may discharge the air existing in the lower part upward.

Referring to FIG. 2 , the blowing fan 160 may be a flow fan. The axial fan is a fan that discharges air introduced in the axial direction in an oblique direction of the axial direction. The blowing fan 160 discharges the air present in the lower part diagonally upward and flows to the air guide 170 .

The blower 100 includes an air guide 170 disposed above the fan 160 to guide the flow of air passing through the fan 160 . The air guide 170 is disposed on the fan housing 150 .

The air guide 170 may constitute a part of the side surface of the air purifier 10 . The air guide 170 may be formed in a cylindrical shape to match the case 101 .

The diameter of the air guide 170 may be the same as the diameter of the fan housing 150 . Accordingly, the air discharged from the blowing fan 160 has a minimum resistance and passes through the air guide 170 .

The air purifier 10 may include a discharge guide device 190 disposed at the discharge port. The discharge guide device 190 forms the outer appearance of the upper end of the air purifier (10). The discharge guide device 190 guides the air discharged from the discharge port in the axial direction.

The air purifier 10 includes a support device 140 disposed above the lever device 142 and supporting the filter member 200 . The support device 140 is disposed below the filter frame 130 . The support device 140 is disposed under the filter frame 130 and supports the fan housing 150 .

The support device 140 is disposed above the lever device 142 . The support device 140 is disposed on the upper end of the lever device 142, and is mounted or detached as the lever device 142 is operated.

The light emitting assembly 300 is disposed on the upper surface of the support device 140 . The central portion of the support device 140 may be formed lower than the edge. Accordingly, the edge of the support device 140 supports the cylindrical filter member 200 , and the central portion of the support device 140 may form a space. The light emitting assembly 300 is disposed in the space of the central portion of the support device 140 .

The air purifier 10 is provided on the upper side of the suction grill 110 and includes a lever device 142 that can be operated by the user. The lever device 142 has a ring shape and includes a body rotatably provided. The body is formed with a handle projecting in a radial direction. The user may rotate the main body clockwise or counterclockwise by manipulating the handle.

When the lever device 142 rotates in one direction, the lever device 142 may be coupled to the support device 140 . The lever device 142 pushes the support device 140 upward, and the filter member 200 is coupled to the air cleaner 10 .

When the lever device 142 rotates in the opposite direction, the lever device 142 is disengaged from the support device 140 . The support device 140 descends downward according to gravity, and the filter member 200 is disconnected from the air purifier 10 and is in a detachable state.

2 and 3 , the air purifier 10 includes a filter frame 130 that forms a mounting space for the filter member 200 . A fan housing 150 is disposed on the upper portion of the filter frame 130 , and a support member is disposed on a lower portion of the filter frame 130 .

The filter frame 130 may include a first frame 131 and a second frame 132 . The first frame 131 forms a lower portion of the filter frame 130 , and the second frame 132 forms an upper portion of the filter frame 130 . The filter member 200 is disposed between the first frame 131 and the second frame 132 .

The filter frame 130 may include a filter support 133 , and the filter support 133 connects and supports the first frame 131 and the second frame 132 . The filter support 133 extends vertically. The first frame 131 is connected to the lower end of the filter support 133, and the second frame 132 is connected to the upper end. A plurality of filter support parts 133 are disposed along the circumferential direction.

The filter member 200 is mounted in the mounting space formed by the filter frame 130 . The filter member 200 is inserted by sliding toward the mounting space from the side of the mounting space.

The air purifier 10 includes a filter member 200 that filters air. The filter member 200 is disposed on the air passage and filters the flowing air. The filter member 200 includes a plurality of filters.

Air sucked in through the suction unit 102 passes through the filter member 200 , and foreign substances are filtered and discharged through the discharge unit 105 .

The filter member 200 may be formed in a cylindrical shape. The filter member 200 may be formed in an open cylindrical shape with an upper surface and a lower surface. The filter member 200 receives air from the outer circumferential surface formed on the side and filters foreign substances.

Since the filter member 200 has a cylindrical shape, air is introduced from all sides of the plane. Accordingly, the effective area is improved.

The filter member 200 may include several types of filters. The filter member 200 may include a HEPA filter 220 and a deodorization filter 230 . The filter member 200 arranges the pre-filter 210 upstream of the HEPA filter 220 and the deodorization filter 230 to remove large dust contained in the air before passing through the HEPA filter 220 and the deodorization filter 230 . It can be filtered first.

The filter member 200 is disposed upstream of the blower 100 based on the air flow direction. Air is filtered while passing through the pre-filter, the HEPA filter 220, and the deodorizing filter 230, and fine dust is generated in the fan 160 of the blower 100 when the filtered air passes through the blower 100. Since it is hardly included, the blower fan 160 of the blower 100 has an advantage that dust is not easily caught.

The HEPA filter is a high-performance filter that filters fine dust in the air.

Referring to FIG. 4 , the HEPA filter 220 may be formed in a cylindrical shape. Air flows through the HEPA filter 220 in a radial direction from the outside of the HEPA filter 220 to the inside of the HEPA filter 220 . Air passes through the HEPA filter 220 and the odor particles are filtered. The filtered air may be directed to the deodorizing filter 230 .

The HEPA filter 220 may be divided into a support part and a filtering part.

The support supports the filtration part. The support part forms the shape of the HEPA filter 220 . The support part may be disposed on the inner circumferential surface of the filtering part. Based on the air flow direction, the support part may be disposed downstream, and the filter part may be disposed upstream.

The filter unit filters fine dust contained in the air when the air passes through it. The filter part is supported by the support member and the shape is fixed. The filtration portion may be corrugated to improve surface area.

The HEPA filter 220, particularly the filtering unit, may filter fine dust by electrostatic attraction. Accordingly, when the HEPA filter 220 is exposed to water, static particles present in the filtration unit are lost, and the HEPA filter 220 cannot be washed with water.

The deodorizing filter 230 is a high-performance filter that filters odor particles in the air. The deodorizing filter 230 passes through the blown air, and removes harmful gas substances in the air.

The deodorizing filter 230 may use a porous material such as charcoal as a deodorant, or an inorganic material such as apatite.

The deodorizing filter 230 of the present invention refers to a generally used deodorizing filter 230, and is not particularly limited to the deodorizing filter 230 according to the content to be described later.

The deodorizing filter 230 of the present invention may include a visible light active photocatalyst composition. The visible light-activated photocatalyst composition of the present invention may include a TiO2 amorphous sol and a visible light-activated photocatalyst. The visible light active photocatalyst and the TiO2 amorphous sol may be mixed in a certain ratio. The mixing ratio of the visible light active photocatalyst and the TiO2 amorphous sol is determined according to the experiment. For example, the visible light active photocatalyst and the TiO2 amorphous sol may be mixed in a weight ratio of 100 to 20 to 100. When mixed within the above range, suitable surface bonding according to the large surface area due to the small TiO2 particles of the TiO2 amorphous sol can be obtained.

The visible light active photocatalyst according to the present invention is included in the visible light active photocatalyst composition in the form of particles. The visible light-activated photocatalyst according to the present invention may be a porous metal oxide particle in which a visible light-activated metal including pores is detected.

The visible light active photocatalyst may be formed by doping visible light activity-imparting metal particles into pores in the porous metal oxide particles, and the formed visible light active photocatalyst may have photoactivity with respect to visible light.

As described above, since the visible light active photocatalyst contains visible light activity-imparting metal particles having photoactivity with respect to visible light, it can have activity against not only ultraviolet light but also visible light, and can absorb light over the entire visible light area. For example, the visible light active photocatalyst may have photoactivity with respect to visible light in a wavelength range of 380 nm to 780 nm, specifically, it may exhibit an absorbance of about 20% with respect to visible light of a wavelength of about 400 nm, and a visible light at a wavelength of about 500 nm. It can be manufactured to exhibit an absorbance of about 10% with respect to light.

Visible light-activated photocatalysts are substances that can clean air, deodorize, and antibacterially because electrons and holes generated from energy obtained by absorbing light generate superoxide anions or hydroxy radicals. For example, the superoxide anion or hydroxy radical generated from the visible light active photocatalyst may decompose harmful environmental substances such as formaldehyde. On the other hand, the visible light active photocatalyst has a high absorption rate with respect to visible light, so it can show excellent efficiency even in an indoor light source, and therefore, a separate UV supply device may not be required.

As the visible light activity imparting metal, any metal capable of imparting visible light activity to the metal oxide may be used without limitation, for example, the visible light activation imparting metal may be a transition metal or a noble metal.

For example, visible light activation metals include tungsten, chromium, vanadium, molybdenum, copper, iron, cobalt, manganese, nickel, platinum, gold, cerium, cadnium, zinc, magnesium, calcium, stronitium, barium, radium and It may include at least one metal selected from a combination thereof. In addition, the visible light activity-imparting metal may be supported on the porous metal oxide particles in the form of a metal oxide. In addition, the visible light activation imparting metal of the present invention may be used in the form of a mixture of the metal and the metal oxide.

The porous metal oxide particles of the present invention may include at least one selected from titanium oxide, tungsten oxide, zinc oxide, niobium oxide, and combinations thereof, and a known material as a metal oxide that can be used as a photocatalyst can be used without limitation. have. The porous metal oxide particles mainly have photoactivity with respect to ultraviolet rays.

Recyclable deodorizing filter 230 of the present invention refers to a deodorizing filter capable of deodorizing performance by visible light. The renewable deodorizing filter of the present invention is a renewable deodorizing filter comprising a visible light active photocatalyst composition for a deodorizing filter comprising a TiO2 amorphous sol and a visible light active photocatalyst. In addition, the deodorizing filter of the present invention is a renewable deodorizing filter characterized in that the substrate is coated with the visible light active photocatalyst composition of the present invention. In this case, the renewable deodorizing filter of the present invention may be a deodorizing filter comprising a substrate and an active photocatalyst composition applied to the substrate.

The substrate may be a substrate including fibers and activated carbon. Preferably, the fibers and the activated carbon included in the substrate may be mixed in such a way that the activated carbon is distributed between the fibers. The fiber may be a fiber generally used in a deodorizing filter, and is not particularly limited. For example, the fiber may be a synthetic fiber.

The visible light-activated photocatalyst composition of the present invention is applied to the substrate, wherein a portion of the photocatalyst composition may be disposed in an empty space of the substrate, and a portion may form a layer on the substrate. Therefore, a layer of the photocatalyst composition may be partially or entirely formed on the substrate.

The deodorizing filter 230 of the present invention may be a deodorizing filter comprising a substrate and a visible light active photocatalyst composition applied to the substrate. The substrate may include fibers and activated carbon. Activated carbon refers to activated carbon generally used in the filter-related field, and is not particularly limited.

Referring to FIG. 4 , the deodorizing filter 230 may be formed in a cylindrical shape. The deodorizing filter 230 may include a deodorizing agent inside the cylindrical shape. Air passes through the deodorizing filter 230 from the outside of the deodorizing filter 230 to the radially inside, and the odor particles are filtered. The filtered air may flow upwards.

The deodorizing filter 230 may be disposed downstream of the HEPA filter 220 . The diameter of the deodorizing filter 230 may be smaller than the diameter of the HEPA filter 220 . After the air passes through the HEPA filter 220 to filter fine dust, the air passes through the deodorization filter 230 to filter out odor particles.

The deodorizing filter 230 is one of the high-performance filters, and when exposed to water, it loses its role as a filter like the HEPA filter 220 . Accordingly, the deodorizing filter 230 is not washable with water like the HEPA filter 220 .

The light emitting assembly 300 is a device for irradiating light. The light irradiated by the light emitting assembly 300 activates the visible light active photocatalyst composition of the deodorizing filter 230 . The photocatalyst composition activated by receiving light regenerates the deodorizing filter 230 , and the regenerated deodorizing filter 230 may filter odors and the like again.

2 and 4 , the light emitting assembly 300 is disposed at the lower end of the filter member 200 . The light emitting assembly 300 is disposed at the lower end of the filter member 200, and irradiates light upward.

The light emitting assembly 300 is disposed between the support device 140 and the filter member 200 . The lower end of the light emitting assembly 300 may be disposed on the upper surface of the support device 140 to be supported by the support device 140 . The central portion of the support device 140 is formed lower than the edge, the edge of the support device 140 supports the filter member 200 , and the central portion of the support device 140 forms a space in which the light emitting assembly 300 is disposed. can do.

The upper end of the light emitting assembly 300 is disposed lower than the lower end of the filter member 200 . The upper end of the light emitting assembly 300 is disposed lower than the lower end of the filter member 200 , and when the filter member 200 is mounted and detached in the radial direction, it is not caught on the light emitting assembly 300 .

The light emitting assembly 300 is disposed inside the filter member 200 . In more detail, when viewed from the top, the light emitting assembly 300 is disposed inside the filter member 200 .

The width of the substrate 310 is defined as the maximum length in the horizontal direction of the substrate 310 , and the width of the cover 330 is defined as the maximum length in the horizontal direction of the cover 330 . The width of the substrate 310 or the width of the cover 330 is formed to be smaller than the diameter of the inner circumferential surface of the filter member 200 . For example, if the diameter of the inner circumferential surface of the filter member 200 is 190 mm, the width of the substrate 310 or the width of the cover 330 is formed not to exceed 190 mm.

The light emitting assembly 300 includes a substrate 310 disposed on one side of the filter member 200 . In addition, a light source 320 disposed on the substrate 310 and irradiating light to activate the photocatalyst is included. In addition, the cover 330 is supported on the substrate 310 , surrounds at least a portion of the light source 320 , and refracts the light irradiated by the light source 320 to the filter member 200 .

The substrate 310 fixes the light source 320 and supplies power to the light source 320 . The substrate 310 supports the cover 330 .

The substrate 310 is disposed on one side of the filter member 200 .

The substrate 310 is disposed in one side opening of the filter member 200 . When the filter member 200 is formed in a cylindrical shape, openings may be formed at the top and bottom of the filter member 200 . The substrate 310 may be disposed in an upper opening or a lower opening of the filter member 200 . Preferably, the substrate 310 is disposed in the lower opening of the filter member 200, the upper opening of the filter member 200 may be formed with an air flow path.

The substrate 310 is disposed at the lower end of the filter member 200 , and is vertically disposed with the filter member 200 .

When viewed from the top, the substrate 310 is disposed inside the filter member 200 .

The light source 320 is fixed to the substrate 310 and receives power from the substrate 310 . The light source 320 is disposed on the upper surface of the substrate 310 .

The light source 320 irradiates light upwards of the substrate 310 . The light source 320 irradiates light upwards of the filter member 200 . The light source 320 irradiates light vertically upward. The light source 320 may irradiate light to a side other than the filter member 200 .

A plurality of light sources 320 may be disposed. The plurality of light sources 320 are arranged along a circle. A plurality of light sources 320 are arranged in a circle along the inner circumferential surface of the filter member 200 . When viewed from the top, the light source 320 is disposed to be spaced apart from the inner circumferential surface of the filter member 200 .

Referring to FIG. 5 , six light sources 320 may be disposed along a circle. However, the present invention is not limited thereto, and may be arranged more or less than 6 based on those skilled in the art.

When viewed from the top, the light source 320 is disposed in the inner space of the filter member 200 .

The cover 330 is a component that refracts the light emitted by the light source 320 to the filter member 200 . The light is supported on the substrate 310 and surrounds at least a portion of the light source 320 .

The cover 330 may be formed of a poly-carbonate material.

The light source 320 irradiates light upward, and the cover 330 refracts the light laterally.

The edge of the cover 330 protrudes. The central portion of the cover 330 is formed lower than the edge. A central portion of the cover 330 is adjacent to the substrate 310 .

Referring to FIG. 6 , the cover 330 includes an outer surface 331 and an inner surface. The outer surface 331 is a surface on which the cover 330 is exposed to the outside. The inner surface is a surface that is closed by the substrate 310 and is not exposed to the outside.

The inner surface corresponds to the outer surface 331 . If the outer surface 331 forms the upper surface of the cover 330 , the inner surface forms the lower surface of the cover 330 .

The inner surface faces the light source 320 , but is disposed to be spaced apart from the light source 320 . The inner surface is spaced apart from the upper portion of the light source 320 .

The light irradiated from the light source 320 passes through the inner surface and is refracted. The light that has passed through the inner side is refracted again while passing through the side of the lump.

The inner surface includes a first inner surface 3321 whose lower end is in contact with the substrate 310 on the radially inner side of the light source 320 and extends upwardly and outwardly in the radial direction. In addition, the lower end of the light source 320 is in contact with the substrate 310 on the outer side in the radial direction, and includes a second inner side surface 3322 extending upwardly in the radial direction. The upper ends of the first inner surface 3321 and the second inner surface 3322 are connected to each other and form a bent portion 3323 .

Referring to FIG. 7 , the light irradiated upward from the light source 320 passes through the first inner surface 3321 and is refracted radially inward. The light irradiated upward from the light source 320 passes through the second inner surface 3322 and is refracted radially outward. However, the light irradiated upward from the light source 320 does not pass through the bent portion 3323 , and the light cannot be directed vertically upward of the bent portion 3323 . Accordingly, the light irradiated upward from the light source 320 is refracted radially inwardly or outwardly, and does not go upward.

The inner surface of the cover 330 may form a triangular cross section.

The outer surface 331 has a lower end in contact with the substrate 310 on the radially inner side of the light source 320 , and includes a first outer surface 3311 extending upwardly and outwardly in the radial direction. In addition, the lower end of the light source 320 is in contact with the substrate 310 on the outer side in the radial direction, and includes a second outer surface 3312 extending upwardly in the radial direction. In addition, one end is connected to the upper end of the first outer surface (3311), the other end includes a third outer surface (3313) connected to the upper end of the second outer surface (3312).

A portion where the third outer surface 3313 and the first outer surface 3311 are connected may include a bent portion. A portion where the third outer surface 3313 and the second outer surface 3312 are connected may also include a bent portion. A portion where the third outer surface 3313 and the first outer surface 3311 are connected or a portion where the third outer surface 3313 and the second outer surface 3312 are connected includes a bent portion, not a bent portion, so that light Unirradiated blind spots may not be formed.

The outer surface 331 may include a curved surface. The first outer surface 3311 may include a curved surface that is convex outwardly, that is, radially inwardly. The second outer surface 3312 may include an outer, ie, radially outwardly, convex curved surface. The third outer surface 3313 may include a curved surface convex to the outside, that is, upward. The outer surface 331 may include a curved surface to enlarge an irradiation angle of light.

Referring to FIG. 7 , light transmitted through the first inner surface 3321 and refracted radially inward passes through the first outer surface 3311 or the third outer surface 3313 and is refracted again. Light transmitted through the second inner surface 3322 and refracted radially outward passes through the second outer surface 3312 or the third outer surface 3313 and is refracted again.

Light transmitted through the first inner surface 3321 and refracted in the radial direction may be refracted upward while passing through the first outer surface 3311 , and transmitted through the third outer surface 3313 and radially inwardly transmitted through the third outer surface 3313 . can be refracted. Light transmitted through the second inner surface 3322 and refracted radially outward may pass through the second outer surface 3312 and be refracted upward, and pass through the third outer surface 3313 to radially inward. can be refracted.

Referring to FIG. 7 , according to an embodiment of the present invention, the third outer surface 3313 may be formed horizontally. According to the present embodiment, the light irradiated from the light source 320 may be radiated to the radially inner side and the radially outer side at the same irradiation angle.

Referring to FIG. 8 , according to another embodiment of the present invention, the third outer surface 3313 may form an inclination downward in the radial direction. According to the present embodiment, the light irradiated from the light source 320 may be irradiated lower in the radial direction, and irradiated higher in the radial direction outward.

For example, the light irradiated from the light source 320 disposed on the right side of the light emitting assembly 300 in FIG. 8 will be described as a reference. The light irradiated to the right from the light source 320 has a greater irradiation angle than the light irradiated to the left. Accordingly, the light irradiated to the right may be irradiated to the upper right of the filter member 200 . The light irradiated to the left from the light source 320 has a smaller irradiation angle than the light irradiated to the right. Nevertheless, the light irradiated to the left is irradiated to the upper end of the magnetic side of the filter member 200 . That is, unlike the light emitting assembly 300 having the cover 330 of FIG. 7 , the light emitting assembly 300 having the cover 330 of FIG. 8 includes a filter member ( 200) has the advantage of being able to evenly irradiate light without blind spots on adjacent or distant parts.

Referring to FIG. 7 , the inclination of the outer surface 331 may be formed to be higher than the inclination of the inner surface. Accordingly, light transmitted through the first inner surface 3321 and refracted radially inward may pass through the first outer surface 3311 and be refracted upward, and transmitted through the second inner surface 3322 and radially outward. The refracted light may pass through the second outer surface 3312 and be refracted upward.

Although not shown, the inclination of the outer surface 331 may be formed to be lower than the inclination of the inner surface. Accordingly, the light transmitted through the first inner surface 3321 and refracted radially inward can be further refracted radially inward by passing through the first outer surface 3311, and passing through the second inner surface 3322 The radially outwardly refracted light may pass through the second outer surface 3312 to be further refracted radially outwardly.

The ratio of the inclination of the outer surface 331 to the inclination of the inner surface may be determined according to an experiment.

Referring to FIG. 7 , the cover 330 has a cross-sectional shape of the lower light-upper side. The cross-section of the cover 330 is formed in the shape of the lower light-upper side, so that the upwardly irradiated light may be refracted radially outward or radially inwardly.

Hereinafter, the operation of the air conditioner according to the present invention configured as described above will be described.

The light emitting assembly 300 is disposed at the lower end of the cylindrical filter member 200, and the light source 320 irradiates light upward.

The light irradiated upward from the light source 320 passes through the first inner surface 3321 and is refracted radially inward. Light transmitted through the first inner surface 3321 and refracted in the radial direction is refracted again while passing through the first outer surface 3311 or the third outer surface 3313, It is uniformly irradiated to the inner circumferential surface.

The light irradiated upward from the light source 320 passes through the second inner surface 3322 and is refracted radially outward. Light transmitted through the second inner surface 3322 and refracted radially outward passes through the second outer surface 3312 or the third outer surface 3313 and is refracted again, It is uniformly irradiated to the inner circumferential surface.

The light irradiated upward from the light source 320 passes through the first inner surface 3321 or the second inner surface 3322 and is refracted, but does not pass through the bent portion 3323 . Accordingly, the light cannot be directed upwards and is not lost upwards of the air purifier 10 .

Hereinafter, the effect of the air conditioner according to the present invention configured as described above will be described.

9 shows the illuminance to which light is irradiated from the air conditioner according to the prior art, and FIG. 10 shows the illuminance to which light is irradiated from the air conditioner according to the present invention.

Referring to FIG. 9 on the left, light is non-uniformly irradiated to the inner circumferential surface of the filter member 200 . A red band is formed in the middle layer of the filter member 200 , and it can be seen that excessive light arrives, and a green band is formed in the upper or lower layer, light weaker than the middle layer of the filter member 200 reaches it can be seen that That is, there is a problem in that unevenness of illuminance occurs in the middle layer and the upper layer, or the middle layer and the lower layer of the filter member 200 , and the photocatalytic filter is activated non-uniformly, thereby reducing the efficiency.

Referring to the right side of FIG. 9 , excessive light is irradiated to the upper portion of the filter member 200 . It can be seen that the upper surface of the filter member 200 has an overall red color, indicating that excessive light is reached. That is, since light is irradiated to the outside of the air purifier 10, there is a problem that may cause inconvenience to the user. In addition, since light is scattered to the outside without being irradiated with the photocatalytic filter, there is a problem in that the photocatalytic filter cannot be activated and thus the efficiency is reduced.

Referring to the left view of FIG. 10 , light is uniformly irradiated to the inner circumferential surface of the filter member 200 . Although the middle layer of the filter member 200 is intermittently red, it can be seen that the overall color is blue or green. According to the experiment, in the case of the prior art, the average illuminance value reaching the filter member 200 is 4.3 mW/cm2, whereas in the case of the present invention, the average illuminance value reaching the filter member 200 is 5.2 As shown in mW/cm2, there is an advantage that more light reaches the filter member 200 on average.

Referring to the right view of FIG. 10 , almost no light is irradiated onto the upper portion of the filter member 200 . The upper surface of the filter member 200 has a blue color as a whole, so it can be seen that the light hardly reaches. According to the experiment, in the case of the prior art, the average illuminance value of the light lost upward of the filter member 200 is 3.8 mW/cm2, whereas in the case of the present invention, it is lost upward of the filter member 200. The average illuminance value of light was found to be only 0.03mW/cm2. That is, on average, there is an effect that very little light is lost to the outside of the filter member 200 .

In the above, preferred embodiments of the present invention have been shown and described, but the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

10: air purifier 20: base
101: case
100: blower 110: suction grill
130: filter frame 140: support device
150: fan housing 160: fan
170: air guide 190: discharge guide
200: filter 210: pre-filter
220: HEPA filter 230: deodorization filter
300: light emitting assembly 310: substrate
320: light source 330: cover
331: outer surface 332: inner surface

Claims (12)

case;
a filter member disposed inside the case and including a photocatalyst;
Including; a light emitting assembly that activates the photocatalyst by irradiating light
The light emitting assembly,
a substrate disposed on one side of the filter member;
a light source disposed on the substrate and irradiating light to activate the photocatalyst;
and a cover supported by the substrate, surrounding at least a portion of the light source, and refracting the light emitted by the light source to the filter member. According to claim 1,
The light emitting assembly is disposed at one end of the filter member,
The substrate is vertically disposed of the filter member,
The light source is an air purifier for irradiating light from one side of the filter member to the other side of the filter member. 3. The method of claim 2,
The light emitting assembly is disposed at the lower end of the filter member,
The light source is an air purifier that irradiates light upward. According to claim 1,
The filter member is formed in a cylindrical shape,
The commercial light source is an air purifier disposed in the inner space of the filter member. 5. The method of claim 4,
The light source is
A plurality of air purifiers are arranged in a circle along the filter member. According to claim 1,
The cover is
an outer surface exposed to the outside;
Corresponding to the outer surface, but facing the light source, the inner surface is disposed to be spaced apart from the light source; Air purifier comprising a 7. The method of claim 6,
The inner surface is
a first inner surface having a lower end disposed on the substrate radially inner side of the light source and extending radially outwardly upward;
and a second inner surface having a lower end disposed on the substrate radially outward of the light source and extending radially inwardly upward. 8. The method of claim 7,
The inner surface is
An upper end of the first inner surface and an upper end of the second inner surface are in contact with each other to form a bent portion; 7. The method of claim 6,
The outer surface is
a first outer surface having a lower end disposed on the substrate radially inside the light source and extending radially outwardly upward;
The lower end is disposed on the substrate radially outer side of the light source, the second outer surface extending radially inwardly upward; Air purifier comprising a 10. The method of claim 9,
The outer surface is
An air purifier comprising a; one end is connected to the upper end of the first outer surface, the other end is connected to the upper end of the second outer surface. 11. The method of claim 10,
The third outer side is
Air purifier comprising an inclined surface having an inclination downward in the radial direction 10. The method of claim 9,
The inclination of the outer surface is higher than the inclination of the inner surface.

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