KR102472861B1 - Apparatus for cleaning air - Google Patents

Abstract

The present invention relates to a clean air generator irradiated with plasma and far-infrared rays, and as an improved invention of prior patent No. 10-2135544, fresh air generated through an air generator is sterilized using plasma, thereby improving utilization of fresh air. and to further improve safety.
To this end, the present invention provides a main body configured with a control panel and a discharge port to discharge fresh air to the outside, a color emitting unit configured on one side of the main body and emitting light so that a selected color is irradiated according to a control signal from the control panel, An air generating unit composed of the main body and configured to purify external air to generate fresh air, and configured to inject color light irradiated from the color emitting part, and constituted in the main body and generated by the air generating unit In the clean air generating and supplying device including a far-infrared ray emitting unit for irradiating far-infrared rays, it is configured on one side of the main body 10 and sterilizes the fresh air generated through the air generating unit by plasma, thereby providing stable fresh air. Characterized in that it includes; a plasma generating unit 30 to be supplied to the user.

Description

Plasma and far-infrared ray irradiated clean air generator {Apparatus for cleaning air}

The present invention relates to a clean air generator irradiated with plasma and far-infrared rays, and more particularly, as an improved invention of prior patent No. 10-2135544, by sterilizing fresh air generated through an air generator using plasma, It relates to a clean air generator and supplier irradiated with plasma and far-infrared rays to further improve the usability and safety of air.

In general, there are cases in which health is harmed due to external environment such as fine dust and indoor air pollution such as sick house syndrome caused by volatile organic compounds, etc. This will adversely affect the weak, the elderly or the sick.

As a way to solve the above problems, the clean air generator irradiated with far-infrared rays that exhibits the color therapy performance of Prior Patent No. 10-2135544 of the present applicant, as shown in FIGS. 1 and 2, has one side. The control panel 12 and the color emitting unit 14 configured to emit light so that the selected color is irradiated according to the control signal of the control panel 12 and the color light emitted from the color emitting unit 14 A far-infrared ray emitting unit 16 that activates the injected fresh air to promote color therapy efficacy, a container 182 for accommodating a certain amount of water inside, and a distributor 184 configured at the top of the container 182 are configured. Including a main body 1 including an air generating unit 18, and a pump 2 that provides air so that air is sucked into one side of the main body 1, sucking in external air and sucking in the sucked air In the clean air generator and supply device for infiltrating into water and discharging purified fresh air to the outside, the lower end of the container 182 is inserted into the main body 1 so that the container 182 is seated in an upright form. It includes a seating space 11 of a certain depth that exerts a supporting force so that it is maintained, and the main body 1 has a far-infrared ray emitting part 16 and a color emitting part 14 sequentially configured below the seating space 11 , so that the far infrared rays emitted from the far infrared ray emitting portion 16 can be irradiated to the container 182 without interfering with the irradiation of light emitted from the color emitting portion 14, and the far infrared ray emitting portion (16) is a radiating element 162 formed in the form of a circular band of a certain size by sintering germanium powder and protecting the radiating element 162 by covering it, and colored light emitted from the lower color emitting part 14 It includes a cover 164 with a transparent center so as not to indirectly irradiate the air, and the container 182 and the distributor 184 of the air generator 18 are made of glass to maintain chemical resistance and transparency, The distributor 184 extends from one side of the cap 1841 and the cap 1841 having a collecting space therein, An inlet connected to the pump 2 and having the other side extending downward from the inside of the cap 1841 to be stored in the water stored in the container 182 and having a filter unit 1843 at the end for filtering air ( 1842) and an exhaust port 1844 that extends from the other side of the cap 1841 to the outside and exhausts the fresh air collected inside the cap 1841 to the outside.

Prior Patent No. 10-2135544 of the present invention has a problem in that it does not have bactericidal properties for eradication of bacteria such as viruses.

Republic of Korea Patent Publication No. 10-837526 (2008.06.12. Notice) Republic of Korea Patent Publication No. 10-2016-135205 (2016.11.25. Notice) Republic of Korea Patent Publication No. 10-2135544 (2020.07.20. Notice)

As a way to solve the above problems, the purpose of the present invention is an improved invention of Prior Patent No. 10-2135544, which sterilizes fresh air generated through the air generator using plasma, thereby improving the utilization of fresh air and It is to provide a clean air generating supplier in which plasma and far-infrared rays are irradiated to further improve safety.

The present invention for achieving the above object is a body configured with a control panel and a discharge port so that fresh air is discharged to the outside, and configured on one side of the body and emits light so that the selected color is irradiated according to the control signal of the control panel an air generating unit configured to generate fresh air by purifying external air and injecting color light irradiated from the color diverging unit, and constituted in the main body to generate the air A clean air generator and supply device including a far-infrared ray radiating unit for irradiating far-infrared rays to fresh air generated in the unit, which is configured on one side of the main body and sterilizes fresh air generated through the air generator unit by plasma, thereby providing stable It is characterized in that it includes; a plasma generator to supply fresh air to the user.

In the present invention, the far-infrared ray radiating unit has a seating groove formed with a certain depth, an entrance for allowing fresh air to enter the seating groove on one side, and an entrance to allow fresh air entering the seating groove to be exhausted on the other side. A housing configured with an outlet to do; a cover configured at one end of the housing to seal the seating groove; and a far-infrared ray block seated in the seating groove so that far-infrared rays are radiated to the fresh air.

In the present invention, the housing forms a plurality of seating grooves; The housing includes passage grooves that allow fresh air to sequentially move between the plurality of seating grooves; Preferably, the flow path groove includes a guide block inserted into the flow path groove and formed with a flow path so that fresh air can be sequentially moved.

In the present invention, the far-infrared ray block includes a stay groove formed with an open end at one end and formed to a certain depth to induce a residence time of fresh air to increase far-infrared ray irradiation; It is preferable to include; and a position fixing seating protrusion configured to protrude at a predetermined height at one end and supporting the position to be seated in the seating groove to be fixed.

In the present invention, it is preferable that the far-infrared ray block includes a support block configured at one side of the open end of the staying groove and supporting the open end to maintain a gap therebetween.

In the present invention, PM for obtaining basic data for measuring the concentration of fine dust or ultrafine dust in the main body and increasing or decreasing the plasma generator or far-infrared ray emitter according to the measured fine dust or ultrafine dust concentration value It is preferable to include a; sensor.

In the present invention, the main body preferably includes a CO2 recorder for measuring the surrounding CO2 concentration and obtaining basic data for increasing or decreasing the plasma generator or the far-infrared radiation emitter according to the measured CO2 concentration value.

According to the present invention, as an improved invention of Prior Patent No. 10-2135544, fresh air generated through the air generating unit is sterilized using plasma, thereby having an effect of further improving the usability and safety of the fresh air.

1 is a conceptual diagram of a clean air generator showing an example of the related art;
Figure 2 is a configuration diagram of the clean air generator of Figure 1;
3 is a schematic perspective view of a clean air generating and supplying device according to a first embodiment of the present invention.
4 is a schematic plan view of the lower case of the clean air generating and supplying device according to the first embodiment of the present invention.
5 is an exploded perspective view of a far-infrared radiation radiating unit according to a first embodiment of the present invention.
6 is a perspective view of a far infrared ray block according to a first embodiment of the present invention.
7 is a schematic perspective view of a clean air generating and supplying device according to a second embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings (the same reference numerals are used for the same components as in the prior art, and detailed descriptions thereof are omitted).

<First Embodiment>

As shown in FIG. 3, the clean air generating and supplying device of the first embodiment includes a main body 10, a pump 20, a plasma generating unit 30, and a far-infrared radiation emitting unit 40.

The main body 10 includes a case 11 engaged in upper and lower parts. In this case, the air generating unit 18 is located in the case located at the top, and the case located at the bottom is configured to form a space therein, so that devices and circuits inside the case 11 consisting of the upper and lower parts are engaged. etc. are composed.

In addition, a control panel 12 is formed on one side of the case 11 .

In addition, in the main body 10, the color emitting unit 14 and the air generating unit 18 have the same or similar configuration and functional relationship as those of the prior patent No. 10-2135544 of the present applicant, so detailed descriptions are omitted here. .

In addition, as shown in FIG. 4, the inside of the case 11 includes a pump 20, a plasma generator 30, and a far-infrared ray emitter 40.

In addition, one side of the case 11 includes a discharge port 13 through which the fresh air that has finally passed through the far-infrared radiation emitter 40 is discharged to the outside.

Fresh air can be used in various ways, such as connecting a separate conduit, for example, a hose, to the discharge port 13 and transporting it to a specific location.

The pump 20 is configured on one side of the inside of the case 11 to provide air to the air generating unit 18 . In addition, a plurality of pumps 20 are configured, one pump supplies external air to the air generating unit 18, and the other pump supplies fresh air generated by the air generating unit 18. It may also be configured to provide pressure so that it can enter the plasma generator 30.

The plasma generating unit 30 is configured on one side of the inside of the case 11 and performs a function of sterilizing fresh air generated from the air generating unit 18 . In this case, the plasma generating unit 30 is configured to sterilize the far-infrared rays radiating unit 40 before entering the fresh air. Of course, it is not limited to this, and it may be configured to sterilize before fresh air is discharged through the outlet 13 of the main body 10.

The plasma generator 30 performs a sterilization function by eradicating and purifying viruses contained in fresh air by explosively generating a large amount of plasma containing high concentration nitrogen oxide in a plasma state by high voltage discharge of 20,000 volts or more. .

In this case, the plasma generating unit 30 is formed in a module form, and is stably maintained inside the case 11. In addition, this plasma generator 30 is provided as a prototype in the form of a module.

In addition, the plasma generator 30 is configured on the inside of the case 11, and is configured in an inlet for new air or an outlet 13 through which the fresh air is discharged to the outside, so that the fresh air is finally discharged to the outside. It can be configured to perform a sterilization function before.

The far-infrared ray radiating unit 40 is configured on one side of the inside of the case 11 and performs a function of irradiating far-infrared rays to the fresh air generated by the air generating unit 18 .

As shown in FIG. 5 , the far-infrared ray emitter 40 includes a housing 42, a cover 44, a far-infrared ray block 46, and a guide block 48.

The housing 42 performs a function of supporting the far-infrared ray block 46 to maintain a stable seated state.

The housing 42 includes a seating groove 422 into which the far infrared ray block 46 is inserted and maintained in a seated state.

In addition, the housing 42 has an entry port 424 through which fresh air can enter the seating groove 422, and is configured on the other side of the seating groove 422 to pass through the far infrared ray block 46. An outlet 426 is configured to allow fresh air to be discharged.

In addition, the housing 42 is configured with a plurality of far-infrared ray blocks 46 so as to increase the irradiation amount of far-infrared rays in the fresh air, and in this case, a plurality of seating grooves 422 in which the far-infrared blocks 46 are seated It is composed of, and includes a passage groove 428 for supporting fresh air to pass between the plurality of seating grooves 422.

The cover 44 is configured to open and close one end of the housing 42 to prevent the far-infrared block 46 seated in the seating groove 422 of the housing 42 from being separated.

The far-infrared block 46 is seated in the seating groove 422 and performs a function of irradiating far-infrared rays to fresh air entering through the entrance 424 .

The far-infrared ray block 46 is made of the same material as the far-infrared ray emitter 16 presented in Patent No. 10-2135544. Of course, it is not limited thereto, and any material capable of irradiating far-infrared rays can be used.

In addition, the far infrared ray block 46 is formed in a substantially circular shape.

In addition, as shown in FIG. 6, the far-infrared ray block 46 is formed at a certain depth, so that the fresh air entering the entrance 424 increases the residence time so that the far-infrared ray irradiation amount of the fresh air is increased. groove 462. In this case, the staying groove 462 has one end open and the other end formed in a semicircular or streamlined shape so that fresh air can stably enter the outlet 426 or other seating grooves 422 .

In addition, the far-infrared ray block 46 is formed at the open end of the stay groove 462, and supports the open end of the stay groove 462 to maintain a gap, so that fresh air can enter and exhaust stably. A support block 464 is configured. In some cases, the support block 464 may be omitted.

In addition, when one end of the far-infrared block 46 is seated in the seating groove 422 of the housing 42, the seating position is supported so that the seating position is fixed, thereby protruding at a certain height to solve assembly defects. It includes protrusion 466. In this case, a groove having a predetermined depth is formed in the seating groove 422 so that the position fixing seating protrusion 466 can be inserted.

When the guide block 48 has a plurality of seating grooves 422 formed in the housing 42, a flow path groove 428 is formed to allow communication between the plurality of seating grooves 422, and at this time, the flow path groove ( 428), it performs a function of inducing fresh air to enter sequentially between the plurality of seating grooves 422.

A flow path 482 is formed in the guide block 48 so that fresh air can smoothly flow through the seating groove 422 .

The operating state of the clean air generating supply configured as described above and irradiated with far-infrared rays is as follows.

First, as in Patent No. 10-2135544, fresh air is generated through the air generating unit 18 configured in the main body 10, and the far-infrared radiation radiating unit 40 configured inside the case 11 of the main body 10 ) is entered.

In this case, since the fresh air generated by the air generating unit 18 contains the color emitted from the color emitting unit configured in the main body 10, a color therapy effect can be obtained.

Subsequently, the fresh air first enters through the entry port 424 configured on one side of the housing 42 of the far-infrared radiation radiating unit 40 . Here, for convenience of description, as shown in FIG. 5, a case consisting of a plurality will be described.

The fresh air entering in this way enters through the open end of the stay groove 462, one end of which is opened, and moves along the shape of the stay groove 462, and settles in the other through the passage groove 428 located on the other side. It enters the far-infrared block 46 seated in the groove 422. In this case, since the guide block 48 is inserted into the passage groove 428, fresh air moves through the passage 428 formed in the guide block 48.

In addition, fresh air entering another far infrared ray block 46 enters another far infrared ray block 46 along the stay groove 462 in the same manner as described above, so that fresh air enters a plurality of far infrared ray blocks 46 are sequentially moved, and the far-infrared ray content of the far-infrared ray irradiated from the far-infrared ray block 46 can be increased in the fresh air by such movement and residence time.

On the other hand, as the fresh air passing through the finally configured far-infrared block 46 is configured to communicate with the outlet 426 of the housing 42, fresh air containing far-infrared rays passes through the outlet 426 of the housing 42 to the outside. is exhausted with

In addition, a plasma generating unit 30 for sterilizing fresh air is provided in front or rear of the far-infrared radiation emitting unit 40, thereby sterilizing fresh air. In this case, it is preferable that the plasma generating unit 30 be configured so that fresh air can be sterilized before entering the far-infrared radiation radiating unit 40 .

In addition, the fresh air passing through the far-infrared radiation emitting unit 40 is exhausted to the outside through the discharge port 13 configured on one side of the main body 10, so that the user can enjoy color therapy by the color emitting unit and the plasma generating unit 30. ), and fresh air containing far-infrared rays by the far-infrared ray emitter 40 can be obtained.

<Second Embodiment>

The same reference numerals are used for components identical to those of the first embodiment, and detailed descriptions thereof are omitted.

As shown in FIG. 7, the clean air generator of the second embodiment measures the concentration of fine dust or ultra-fine dust around it, and increases or decreases the air purifying function according to the measured concentration of fine dust or ultra-fine dust. It includes a PM sensor 50 that does.

The PM sensor 50 performs a function of measuring the concentration of fine dust or ultra-fine dust in the surroundings. In this case, the PM sensor 50 is classified into PM10, PM2.5, PM1.3, etc., which may have various sensors according to the measured concentration of fine dust or ultrafine dust such as the purpose of use or the use environment.

In addition, the PM sensor 50 may be configured at any position of the main body 10 as long as the measurement of surrounding fine dust or ultra-fine dust is smooth.

In addition, the main body 10 includes an indicator light 110 that can be easily identified from the outside according to the concentration of fine dust or ultra-fine dust measured by the PM sensor 50.

The indicator light 110 illuminates a color according to the concentration value measured by the PM sensor 50, so that the concentration of fine dust or ultra-fine dust can be easily recognized from the outside.

shame situation situation Color 0 to 50 good A level that will not cause an impact even in patients with air pollution-related diseases blue 51 to 100 usually A level at which a minor effect may be caused by chronic exposure to the patient population yellow 101 to 150 Sensitive group effect Levels that can cause harmful effects to patients and sensitive groups Orange 151-200 bad Harmful effects on patients and sensitive groups (children, the elderly), level at which the general public may experience health discomfort red 201 to 300 very bad A level that can cause severe effects in case of acute exposure to patients and sensitive groups, and mild effects to the general public purple 301 or higher danger A level that can cause emergency measures to patients and sensitive groups or cause harmful effects to the general public purple

In addition, the PM sensor 50 displays the measured fine dust or ultrafine dust concentration value on the control panel 12 so that it can be easily recognized as a numerical value through the control panel 12 .

In addition, the clean air generator and supply unit includes a CO2 recorder 60 that measures and stores the concentration of carbon dioxide around it and displays it on the control panel 12 so that it can be easily identified by others.

The CO 2 recorder 60 is configured on one side of the case 11 to measure the concentration of carbon dioxide distributed around, so that users as well as administrators can easily recognize it.

In this case, the CO2 recorder 60 is configured on one side of the case 11. Of course, it is not limited thereto, and the CO 2 recorder 60 can be installed anywhere as long as it can easily measure the concentration of carbon dioxide in the surroundings.

Meanwhile, the PM sensor 50 and the CO2 recorder 60 transmit each measured value to the control unit, and the control unit pumps the pump 20 according to the measured value through the PM sensor 50 and the CO2 recorder 60. , It is used as basic data for the operating state or intensity of the plasma generator 30 or the far-infrared radiation emitter 40.

For example, when the concentration of fine dust or ultrafine dust is high through the PM sensor 50, normally, when the concentration of fine dust or ultrafine dust is high, the concentration of carbon dioxide also increases, so the pump 20 and the plasma generator 30 ) or by increasing the suction power of the far-infrared radiation emitter 40 so that a pleasant environment can be created through rapid air conditioning.

What has been described above is only one embodiment for implementing a clean air generator and supply device irradiated with plasma and far infrared rays, and the present invention is not limited to the above embodiment. Those skilled in the art in the field belonging to the present invention will be able to understand that various modifications are possible without departing from the gist of the present invention.

10: body 11: case
12: control panel 13: discharge port
18: air generating unit 20: pump
30: plasma generating unit 40: far-infrared radiation emitting unit
42: housing 422: seating groove
424: inlet 426: outlet
428: Euro home 44: cover
46: far-infrared block 462: collection home
464: support block 466: position fixing protrusion
48: guide block 482: euro
50: PM sensor 60: CO2 recorder

Claims (7)

A body configured with a control panel and a discharge port through which fresh air is discharged to the outside, a color emitting unit disposed on one side of the body and configured to emit light so that a selected color is irradiated according to a control signal from the control panel, and configured in the body and configured to externally An air generator configured to purify air to generate fresh air, and inject color light irradiated from the color emitting unit, and a far-infrared ray configured in the main body to irradiate the fresh air generated by the air generator with far-infrared rays. In the clean air generating supply comprising a diverging unit,
It is configured on one side of the main body 10, and includes a plasma generator 30 to supply stable fresh air to the user by sterilizing the fresh air generated through the air generator by plasma;
The far-infrared radiation radiating part 40 has a seating groove 422 formed at a certain depth, an entry port 424 for allowing fresh air to enter the seating groove 422 on one side, and the seating groove 424 on the other side. a housing 42 configured with an outlet 426 through which fresh air entering the groove 422 is exhausted;
a cover 44 configured at one end of the housing 42 to seal the seating groove 422; and
a far-infrared block 46 seated in the seating groove 422 to irradiate fresh air with far-infrared rays;
A clean air generating supply in which plasma and far infrared rays are irradiated, characterized in that it comprises a.
delete The method of claim 1,
forming a plurality of seating grooves 422 in the housing 42;
The housing 42 includes a passage groove 428 that allows fresh air to sequentially move between the plurality of seating grooves 422;
The guide block 48 is inserted into the flow path groove 428 and has a flow path 482 so that fresh air can move sequentially;
A clean air generating supply in which plasma and far infrared rays are irradiated, characterized in that it comprises a.
The method according to claim 1, wherein the far infrared ray block 46,
a stay groove 462 having an open end having one end open and formed at a certain depth to induce the residence time of fresh air to be increased by irradiation of far-infrared rays; and
A position fixing seating protrusion 466 configured to protrude at a certain height at one end and supporting the position to be seated in the seating groove 422 to be fixed;
A clean air generating supplier irradiated with plasma and far-infrared rays, characterized in that it comprises a.
The method according to claim 4, in the far infrared ray block 46,
a support block 464 formed at one side of the open end of the stay groove 462 and supporting the open end to maintain a gap therebetween;
A clean air generating supply in which plasma and far infrared rays are irradiated, characterized in that it comprises a.
The method according to claim 1, in the main body 10,
PM sensor for measuring the concentration of fine dust or ultra-fine dust in the surroundings and obtaining basic data for increasing or decreasing the plasma generator 30 or the far-infrared ray emitter 40 according to the measured fine dust or ultra-fine dust concentration value (50);
A clean air generating supplier irradiated with plasma and far-infrared rays, characterized in that it comprises a.
The method according to claim 1, in the main body 10,
A CO2 recorder 60 for measuring the CO2 concentration in the surroundings and obtaining basic data for increasing or decreasing the plasma generator 30 or the far-infrared radiation emitter 40 according to the measured CO2 concentration value;
A clean air generating supplier irradiated with plasma and far-infrared rays, characterized in that it comprises a.

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