KR102123427B1 - Purifying device - Google Patents

Abstract

The present invention is a body having a flow path through which the fluid passes; An ultraviolet guide disposed along the flow path; It includes a UV LED for irradiating ultraviolet rays with a flow path and an ultraviolet ray guide, and the ultraviolet ray guide includes an optical wave portion and a light diffusion portion formed at one end of the optical wave portion to diffuse ultraviolet rays propagated to the optical wave portion, and irradiated from the UV LED. Ultraviolet rays are propagated through the ultraviolet ray guide to maximize the reach of the ultraviolet rays, and ultraviolet rays are propagated through the ultraviolet ray guide and the flow path, respectively, and thus has high purification ability.

Description

Purifying device

The present invention relates to a purification device, and more particularly, to a purification device for purifying a fluid such as water or air using ultraviolet rays.

In general, the purifying device can purify a fluid such as water or air, and there is an air purifying device that removes dust in the air or a water purifying device that purifies water drained by water or drainage facilities for human consumption. .

The purifying device is capable of purifying the fluid by filtering the foreign matter of the fluid through a filter through which the fluid passes. The purifying device can purify the fluid by irradiating ultraviolet rays on the filter coated with the photocatalyst to activate the photocatalyst.

Recently, a technique for purifying a fluid such as water or air using an ultraviolet (UV) lamp has been developed.

KR 10-2012-0047175 (2012.04.20)

The purification device according to the prior art functions as a filter sterilizer for sterilizing the filter by irradiating ultraviolet rays with the filter, so that the number of parts for purification is complicated, and the structure is complicated, and the size of the filter sterilized by the UV LED is large. There is a problem in that the number of UV LEDs is increased when considering the UV reach distance irradiated from the UV LED.

An object of the present invention is to provide a purifying mechanism capable of efficiently purifying a fluid by itself, irrespective of a filter.

Purification mechanism according to the present invention for solving the above problems is a body having a flow path through which the fluid passes; An ultraviolet guide disposed along the flow path; It includes a UV LED for irradiating ultraviolet rays with the flow path and the UV guide, the UV guide is formed on one end of the photoelectric wave portion for propagating the ultraviolet light irradiated from the UV LED, and the ultraviolet wave propagated in the photoelectric wave portion And a diffusing light diffuser.

The UV LED may be installed in the flow path.

The UV LED may be installed to irradiate ultraviolet rays in the flow direction of the fluid.

In the ultraviolet guide, an inner flow passage through which the fluid passes may be formed.

The inner flow passage may be continuously formed inside the light-emitting portion and inside the diffusion portion.

The UV guide may be a melt crystal.

The ultraviolet guide may be arranged long in the longitudinal direction of the flow path.

The light wave portion may be located between the UV LED and the light diffusion portion.

The light diffusion unit may be smaller in size than the light wave unit.

The light diffusion unit may have a conical shape.

The light diffusion unit may gradually decrease in size toward the opposite direction of the UV LED.

The UV LED may irradiate UV-C.

The UV LED may irradiate ultraviolet rays having a wavelength of 300 nm or less.

The UV LED may irradiate ultraviolet rays having a wavelength of 265 to 280 nm.

The UV LED may irradiate ultraviolet rays having a wavelength of 280 nm.

The purifying mechanism according to the present invention includes a body having an inlet through which fluid flows on one side and an outlet through which fluid flows on the other side; An ultraviolet guide disposed on an inner surface of the body and having an inner passage through which fluid passes; It includes a UV LED for irradiating ultraviolet rays with the UV guide and the inner flow path.

The UV LED may irradiate ultraviolet rays having a wavelength of 265 to 280 nm.

The UV guide may be located between the UV LED and the inlet.

The UV guide may be a melt crystal.

The UV LED may be installed to irradiate ultraviolet rays in a direction opposite to the flow direction of the fluid.

In the present invention, since the ultraviolet rays irradiated from the UV LEDs are transmitted through the ultraviolet rays guide, it is possible to maximize the reach of the ultraviolet rays, and the ultraviolet rays are propagated through the ultraviolet rays guide and the flow path, respectively, and thus has high purification ability.

In addition, since ultraviolet rays can be spread as well as spread by an ultraviolet guide, there is an advantage of efficient purification while minimizing the number of parts.

In addition, the fluid can be intensively exposed to ultraviolet light while passing through the interior of the body, and has a high purification ability.

There is also an advantage that the UV guide and UV LED can be protected together by the body.

1 is a diagram showing an example in which an embodiment of the purifying mechanism according to the present invention is installed in an air conditioner,
Figure 2 is a view showing the interior of one embodiment of the purifying device according to the present invention,
Figure 3 is a graph showing the UV reach according to the wavelength of the UV light irradiated from the UV LED,
Figure 4 is a graph showing the UV reach and energy according to the material of the UV guide,
5 is a view showing the interior of another embodiment of the purifying device according to the present invention,
6 is a view showing the interior of another embodiment of the purifying device according to the present invention.

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

1 is a view showing an example of a purification mechanism according to the present invention installed in an air conditioner, and FIG. 2 is a view showing the interior of one embodiment of a purification mechanism according to the present invention.

The purifying mechanism includes a body 10 having a flow path 2 through which the fluid F passes; An ultraviolet guide 20 disposed along the flow path 2; It includes a UV LED (30) for irradiating ultraviolet rays (UV) with the flow path (2) and the UV guide (20).

A purification mechanism is installed in a household appliance to purify fluid such as air or water. The purifying mechanism is installed in an air conditioner that changes at least one of air temperature, cleanliness, and humidity, and it is possible to purify air passing through the air conditioner. The purification mechanism is installed in a water purifier that purifies water for drinking by the human body and can purify water passing through the water purifier. The purification device is installed in a laundry treatment device such as a washing machine that processes laundry, and thus it is possible to purify water supplied for washing. Hereinafter, for convenience of explanation, the fluid F is limited to air, and the purification mechanism is limited to being installed in the air conditioner. However, the fluid F of the present invention is not limited to air, but can be water. , Of course, it can be installed in other household appliances than the air conditioner.

When the purifying mechanism is installed in the air conditioner, the purifying mechanism is installed in the suction flow path through which the outside air is sucked into the air conditioner, or the air supplied inside the air conditioner is installed in the discharge flow path through which the air conditioner is discharged, or the suction flow path It is possible to be provided between and the discharge passage. The body 10 is assembled with the UV guide 20 and the UV LED 30 and can be installed in an air conditioner.

The air conditioner includes a casing 56 formed with an air intake port 52 through which air is sucked and an air outlet port 54 through which air is discharged, a heat exchanger 58 installed inside the casing 56, and a casing 56. It may include a blower 60 installed therein. The air conditioner may be provided with a filter 61 that filters foreign substances in the air sucked into the air intake 52. The filter 61 may be installed before the air intake 52 in the air flow direction, or between the air intake 52 and the blower 60 in the air flow direction. The purifying mechanism may be installed to be located inside the casing 56. The purifying mechanism may be installed to be positioned in the air passage 62 through which air passes among the casing 56. The purifying mechanism may be installed to be located between the blower 60 and the air outlet 54 in the air flow direction.

Hereinafter, each configuration of the purifying mechanism will be described in detail as follows.

The body 10 may have an inlet 12 through which air flows on one side, and an outlet 14 through which air passing through the body 10 flows out may be formed on the other side. The body 10 may have a flow path 2 between the inlet 12 and the outlet 14. The flow path 2 may be an accommodation space in which the UV guide 20 and the UV LED 30 are accommodated, and may be a purification space in which air is purified while passing. The body 10 may form an external appearance of the purifying mechanism, and may protect the UV guide 20 and the UV LED 30 installed therein.

Air passing through the air conditioner may be sucked into the inlet 12 of the body 10, pass through the flow path 2, and then flow out to the outlet 14 of the body 10, while passing through the flow path 2 The UV guide 20 may pass between the outer circumferential surface and the inner circumferential surface of the body 10.

The ultraviolet ray guide 20 guides ultraviolet rays (UV) irradiated from the UV LED 30, and the ultraviolet rays (UV) irradiated from the UV LED 30 may propagate along the ultraviolet ray guide 20. It is preferable that the purifying device propagates ultraviolet (UV) light irradiated from the UV LED 30 to a maximum distance, and the UV guide 20 purifies the air while the light irradiated from the UV LED 30 propagates to the longest distance. Can help.

The UV guide 20 may include a light-emitting portion 22 (UV transmission area) and a light-diffusing portion 24 (UV diffusion area) formed on one end 23 of the light-emitting portion 22. The UV guide 20 may be arranged long in the longitudinal direction of the flow path 2. The UV guide 20 is preferably made of a material that is easy to propagate ultraviolet (UV) and diffuse UV (UV). The UV guide 20 may be formed integrally with the light-emitting portion 22 and the light diffusion portion 24 in molding by melting silicon dioxide.

The light wave portion 22 may propagate ultraviolet (UV) light irradiated from the UV LED 30, and may propagate in the longitudinal direction of the light wave portion 22. The light wave portion 22 may be located between the UV LED 20 and the light diffusion portion 24. The ultraviolet rays (UV) irradiated from the UV LED 30 and the UV LED 30 of the light wave portion 22 It may be propagated to the light propagation part 22 through the closest end 23, and may be propagated in the longitudinal direction of the light propagation part 22 along the light propagation part 22. Ultraviolet (UV) light propagated across the one end 23 of the light propagation unit 22 may be propagated to the light diffusion unit 24 and transmitted through the light diffusion unit 24. The light wave portion 22 may be in the form of a column, it may be formed in a column shape, it may be formed in a polygonal column shape, such as a triangular column or a square column. The optical wave unit 22 may have one end 23 spaced apart from the UV LED 30. A gap may be formed between the light wave portion 22 and the UV LED 30.

The light diffusion unit 24 may diffuse ultraviolet rays propagated from the light propagation unit 22. Ultraviolet rays propagated from the light diffusion unit 22 to the light diffusion unit 24 may be diffused widely around the light after passing through the light diffusion unit 24. The light diffusion unit 24 may have a conical shape. The light diffusion unit 24 may be smaller in size than the light propagation unit 22. The light diffusion unit 24 may be gradually smaller as it goes in the opposite direction of the UV LED 30. The length of the light diffusion unit 24 may be shorter than the length of the light propagation unit 22. The light diffusion unit 24 may have an end portion 25 in a disk shape.

The UV LED 30 can be miniaturized compared to a UV lamp and is easily molded into a single wavelength light source. The UV LED 30 may be installed in the flow path 2. The UV LED 30 may be installed to irradiate ultraviolet (UV) light in the flow direction of the fluid. The UV LED 30 may be installed so that the ultraviolet irradiation surface faces the outlet 14 of the body 10. The UV LED 30 may be a light source that irradiates one of UV-A in the wavelength region of 315 to 400 nm, UV-B in the wavelength region of 280 to 315 nm, and UV-C in the wavelength region of 100 to 280 nm. When the UV LED 30 irradiates UV-C through the flow path 2 and the UV guide 20, UV-C may have a large effect of directly sterilizing bacteria such as E. coli. The UV LED 30 is preferably irradiated with UV-C to the UV guide 20. The UV LED 30 may irradiate ultraviolet rays having a wavelength of 300 nm or less with the ultraviolet ray guide 20. The UV LED 30 may irradiate ultraviolet rays having a wavelength of 265 to 280 nm with the ultraviolet ray guide 20.

Meanwhile, the purifying mechanism may be installed such that each of the UV guide 20 and the UV LED 30 is in contact with the inner circumferential surface of the body 10. The UV guide 20 and the UV LED 30 may be installed such that each of them is supported on the body 10. The purifying mechanism may include an ultraviolet guide supporter 40 that supports the ultraviolet guide 20 to be spaced apart from the inner circumferential surface of the body 10. The UV guide supporter 40 includes an inner supporter 41 surrounding one side of the UV guide 20, an outer supporter 42 installed on an inner circumferential surface of the body 10, an inner supporter 41, and an outer supporter ( 42) may include a plurality of support legs (43) between. The purifying mechanism may include a UV LED supporter 44 that supports the UV LED 30 to be spaced apart from the inner circumferential surface of the body 10. The UV LED supporter 44 includes an inner supporter 45 to which the UV LED 30 is mounted, an outer supporter 46 installed on the inner circumferential surface of the body 10, an inner supporter 45 and an outer supporter 46 It may include a plurality of support legs (47) between. In the purifying mechanism, the UV guide 20 and the UV LED 30 are fixed integrally, and it is of course possible to be fixed to the body 10 by one of the UV guide supporter 40 and the UV LED supporter 44.

The purifying mechanism is arranged in the order of the UV LED 30 and the UV guide 20 in the air flow direction, and the UV LED 30 is directed toward the outlet 14 of the body 10, that is, UV light in the air flow direction ( It is possible to irradiate UV). In this case, the air may be first purified by ultraviolet (UV) light irradiated from the UV LED 30 and then secondarily purified by ultraviolet (UV) light propagated through the ultraviolet guide 20. On the other hand, the purifying mechanism is arranged in the order of the ultraviolet light guide 20 and the UV LED 30 in the air flow direction, the direction of the UV LED 30 toward the inlet 12 of the body 10, that is, the air flow direction and It is possible to irradiate ultraviolet (UV) light in the opposite direction. In this case, it is possible that the air is primarily purified by ultraviolet rays propagated through the UV guide 20 and then secondaryly purified by ultraviolet rays irradiated from the UV LED 30.

3 is a graph showing the UV reach according to the wavelength of the ultraviolet light irradiated from the UV LED.

When the UV LED 30 is irradiated with ultraviolet rays having a wavelength of 265 nm, as illustrated in (a) of FIG. 3, the UV reach may be shorter than approximately 30 mm, when irradiating ultraviolet rays having a wavelength of 280 nm, FIG. ), the UV reach can be reached to approximately 50mm. UV LED (30) It may be desirable to irradiate ultraviolet rays having a wavelength of 280 nm with an ultraviolet ray guide (20).

4 is a graph showing the UV reach and energy according to the material of the UV guide.

The UV guide 20 may be made of fused quartz. 4 (c) is a graph showing the relationship between the energy and the UV reach when the UV guide is not installed, and FIG. 4 (d) is the energy when the material of the UV guide is fused quartz. Is a graph showing the relationship between UV and UV reach, and FIG. 4E is a graph showing the relationship between energy and UV reach when the material of the UV guide is synthetic quartz. When the UV guide 20 is made of melt crystal, it is possible to secure an ultraviolet ray reaching distance of 50 to 200 mm, and it may be most preferable to be made of melt crystal.

When explaining the operation of the present invention configured as described above are as follows.

First, the purifying mechanism may be turned on the UV LED (30), the UV LED 30 may be irradiated with ultraviolet (UV). Ultraviolet rays (UV) irradiated from the UV LED 30 may be partially propagated through the one end 23 of the ultraviolet ray guide 20 to the ultraviolet ray guide 20, and the ultraviolet ray guide 20 along the ultraviolet ray guide 20 It can be propagated in the longitudinal direction. The ultraviolet rays (UV) propagated to one end 23 of the ultraviolet ray guide 20 may be propagated along the photoelectric wave portion 22 in the longitudinal direction of the photoelectric wave portion 22, and the light diffusion portion 24 in the optical wave portion 22 ). The ultraviolet (UV) light propagated to the light diffusion unit 24 may be widely spread to the surroundings after passing through the light diffusion unit 24. After the UV guide 20 is transmitted from the UV LED 30, the widely diffused UV (UV) may purify the air passing around the light diffusion unit 24. On the other hand, the ultraviolet (UV) generated by the UV LED 30 can purify the air passing through it while the rest spreads around the UV LED 30.

The air may first pass around the UV LED 30 after flowing into the inlet 12 of the body 10, and may be primarily purified by ultraviolet rays (UV) irradiated from the UV LED 30. The air that has passed through the periphery of the UV LED 30 may pass through the body 10 and the ultraviolet light guide 20, and may pass through the periphery of the light diffusion unit 24, from the light diffusion unit 24 to the surroundings. It can be secondarily purified by widely spread ultraviolet (UV) light. The air purified around the light diffusion unit 24 may be discharged through the outlet 14 of the body 10. The air may be purified not only by ultraviolet rays (UV) irradiated through the flow path 2 but also by ultraviolet rays (UV) propagated through the ultraviolet ray guide 20.

5 is a view showing the interior of another embodiment of the purifying device according to the present invention.

In the purifying mechanism of this embodiment, an inner flow passage 28 through which the fluid F passes may be formed in the ultraviolet ray guide 20. The inner flow passage 28 may be continuously formed inside the light wave portion 22 and inside the diffusion portion 24. The inside of the body 10 can be divided into an inner flow path 28 between the inner circumferential surface of the ultraviolet ray guide 20 and the inner circumferential surface of the ultraviolet ray guide 20 and the inner circumferential surface of the body 10. have. The purifying mechanism of this embodiment has the same or similar configuration and operation to the other than the inner flow path 28, so the same reference numerals may be used and detailed descriptions thereof may be omitted.

Air may be introduced into the inlet 12 of the body 10, the air introduced into the inlet 12 is partially passed through the gap between the UV LED 30 and the UV guide 20, the inner flow path 28 ), and the rest may pass through the outer flow path 29 between the UV guide 20 and the body 10. The air passing through the gap between the UV LED 30 and the UV guide 20 may be purified by ultraviolet rays (UV) irradiated from the UV LED 30 while passing through the gap. The ultraviolet rays (UV) irradiated from the UV LED 30 may be partially irradiated to the inner flow path 28 to purify air passing through the inner flow path 28. The air introduced into the inner flow passage 28 may be discharged to the outside of the UV guide 20 through the light diffusion unit 24, and the outlet 14 of the body 10 together with the air passing through the outer flow passage 29 Can be spilled.

6 is a view showing the interior of another embodiment of the purifying device according to the present invention.

The purifying mechanism of this embodiment includes a body 10' having an inlet 12 through which a fluid F flows on one side and an outlet 14 through which the fluid F flows on the other side; An ultraviolet guide 20' disposed on the inner surface of the body 10' and having an inner flow passage 28' through which the fluid F passes; It includes a UV LED (30) and UV LED (30) for irradiating ultraviolet rays with the inner flow path (28').

The body 10' includes a first hollow cylinder 16 with both ends open, and a second hollow cylinder 18 protruding through the inside of the first hollow cylinder 16 on one side of the first hollow cylinder 16 It can contain. The body 10 ′ may have an inlet 12 at one end of the first hollow cylinder 16. The other end of the first hollow cylinder 16 of the body 10 ′ may be blocked by the UV LED 30. The body 10 ′ may have an outlet 14 formed in the second hollow cylinder 18. The fluid may be introduced into the body 10' through the inlet 12 of the body 10', and after the flow direction is switched inside the body 10', the outlet 14 of the body 10' Can be spilled.

The UV guide 20' has an outer circumferential surface that can contact the inner circumferential surface of the first hollow tube 16, and the UV guide 20' allows the fluid to pass through a position facing the second hollow tube 18. A through hole 28" may be formed. The UV guide 20' may be made of melt crystal, and may guide UV (UV) light, as in one embodiment of the present invention. The UV guide 20' It can be located between the UV LED 30 and the inlet 12. The UV guide 20' has one end 26 in the longitudinal direction facing the UV LED 30, and the other end 27 in the longitudinal direction. The inlet 12 can be faced.

The UV LED 30 may irradiate ultraviolet rays toward the ultraviolet ray guide 20 ′ and the inner channel 28. The UV LED 30 may be installed to irradiate ultraviolet rays in a direction opposite to the flow direction of the fluid F. The UV LED 30 may function as a fluid guide that converts a flow direction of fluid flowing along the inner flow passage 28 ′ to the outlet 14. Some of the ultraviolet rays (UV) irradiated from the UV LED 30 may be irradiated with the inner flow path 28' to purify the fluid passing through the inner flow path 28', and the ultraviolet rays irradiated from the UV LED 30 ( The rest of the UV) may be propagated through the one end 26 of the UV guide 20' to the UV guide 20'. Ultraviolet rays propagated by the UV guide 20' may be propagated to the UV LED 30 to a long distance, and may be propagated to the periphery of the other end 27 of the UV guide 20'.

Hereinafter, for convenience of description, the fluid F is limited to air and described.

In the purifying mechanism, the UV LED 30 may be turned on, and the UV LED 30 may be irradiated with ultraviolet rays (UV). UV (UV) irradiated from the UV LED 30 may be partially irradiated to the inner flow path 28 ′, and the rest may be guided along the ultraviolet guide 20 ′ and propagated to a position close to the inlet 12. have.

Air may be introduced into the inlet 12 of the body 10', and may be primarily purified by ultraviolet (UV) light propagated through the ultraviolet guide 20'. The air introduced into the inlet 12 of the body 10' may flow toward the UV LED 30 while passing through the inner flow path 28 of the UV guide 20', and has reached the UV LED 30 around. When it is, it can be secondarily purified by ultraviolet (UV) irradiated from the UV LED 30 to the inner flow path 28 ′. Subsequently, the air may be changed in the flow direction to flow toward the outlet 14 of the body 10 and may flow through the outlet 14 of the body 10. The air can be purified not only by ultraviolet rays (UV) propagated through the ultraviolet ray guide 20 into the flow path 2 but also by ultraviolet rays (UV) irradiated directly from the UV LED 30 to the inner flow path 28'. Can be purified.

Meanwhile, the present invention is not limited to the above-described embodiments, and various implementations are possible within the technical scope to which the present invention pertains.

2: Euro 10: Body
12: inlet 14: outlet
20: UV guide 22: light wave
24: light diffuser 30: UV LED

Claims (20)

A body having a passage through which the fluid passes;
An ultraviolet guide disposed along the flow path;
It includes a UV LED for irradiating ultraviolet rays with the flow path and the UV guide,
The ultraviolet ray guide is a purifying mechanism including an optical wave portion for propagating ultraviolet rays irradiated from the UV LED, and a light diffusion portion formed at one end of the optical wave portion to diffuse ultraviolet rays propagated by the optical wave portion. According to claim 1,
The UV LED is a purification mechanism installed in the flow path. According to claim 1,
The UV LED is a purification mechanism installed to irradiate ultraviolet rays in the flow direction of the fluid. According to claim 1,
The ultraviolet guide is a purifying mechanism in which an inner flow passage through which the fluid passes is formed. The method of claim 4,
The inner flow path is a purifying mechanism continuously formed inside the light-emitting portion and inside the diffusion portion. According to claim 1,
The UV guide is a purifying mechanism that is a melt crystal. According to claim 1,
The ultraviolet ray guide is a purifying mechanism arranged long in the longitudinal direction of the flow path. According to claim 1,
The light propagation unit is a purifying mechanism located between the UV LED and the light diffusion unit. The method of claim 8,
The light diffusion unit is a purifying mechanism that is smaller in size than the light wave unit. The method of claim 8,
The light diffusion unit is a purifying mechanism having a cone shape. The method of claim 8,
The light diffusion unit is a purifying mechanism that gradually decreases as it goes in the opposite direction of the UV LED. According to claim 1,
The UV LED is a purifying device for irradiating UV-C. According to claim 1,
The UV LED is a purifying device that irradiates ultraviolet rays having a wavelength of 300 nm or less. According to claim 1,
The UV LED is a purifying device that irradiates ultraviolet rays having a wavelength of 265 to 280 nm. According to claim 1,
The UV LED is a purifying device that irradiates ultraviolet rays having a wavelength of 280 nm. delete delete delete delete delete

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