KR20210139027A - Air cleaner - Google Patents

Abstract

The present invention relates to an air purifier and, more particularly, to an air purifier capable of purifying indoor and outdoor air by removing harmful substances from indoor and outdoor air. Disclosed is an air purifier (1000) for removing harmful substances contained in outdoor air introduced from the outside. The air purifier (1000) comprises: a housing (100) having an inlet (110) through which outdoor air is introduced and an outlet (120) through which the purified air is discharged to the outside, so that a flow path through which outdoor air flows is formed; a water particle spraying unit (200) installed on the flow path and for spraying, onto outdoor air, fine water particles for collecting the harmful substances contained in outdoor air; a water particle collecting unit (300) installed on the flow path, and for collecting the water particles having collected the harmful substances from outdoor air, and the water particles while outdoor air passes therethrough; an air flow forming unit (500) for forming a flow of outdoor air so that outdoor air having passed through the water particle collecting unit (300) is discharged through the outlet (120); and a cooling unit (800) installed on one surface of the water particle collecting unit (300) to cool the water particles and outdoor air.

Description

Air cleaner {Air cleaner}

The present invention relates to an air purifying device, and more particularly, to an air purifying device capable of removing and purifying harmful substances in indoor and outdoor air.

The smoking rate among adult males in Korea is on a declining trend to 39.6% as of 2010 due to increased health concerns due to the improvement of the quality of life, but it has the highest smoking rate among OECD countries. On the other hand, most people have experience of secondhand smoke at home, office, restaurant, and on the street, and it is acknowledged that a large number of smokers are harming others through secondhand smoke.

Currently, there are legal/institutional regulations on the ban on smoking in public places, but due to the difficulties of practical management/regulation and the low level of awareness among smokers, smoking in public places is openly occurring. In addition, due to the non-smoker's request to quit smoking in the private space inside the building, there have been many difficulties for smokers to satisfy their desire to smoke.

In addition, the conventional smoking booth has a simple configuration in which an air purifier or a purifier is installed, so there is a limit to increasing the purifying effect inside the booth for smokers. There was a problem that had to be done. In addition, air polluted with cigarette smoke inside the smoker's booth leaks out through the door that is opened when the smoker enters and pollutes the air around the smoker's booth, causing secondhand smoke to non-smokers located around the smoker's booth There were also problems with

In addition, since the problem of indoor and outdoor air pollution caused by ultrafine dust or radioactive materials has recently emerged as a serious health problem, harmful substances such as cigarette smoke, ultrafine dust, and radioactive materials in indoor and outdoor air are effectively removed at a low cost. The need for technology that can do this is growing.

Furthermore, civil complaints due to indoor and outdoor odors such as farm facilities are also serious, and technology development is required to effectively remove cigarette smoke, ultrafine dust, radioactive substances, and odorous substances from the air.

It is an object of the present invention to provide an air purifier capable of removing harmful substances from indoor and outdoor air by spraying water through a nozzle to purify external air.

Another object of the present invention is to form a flow path through which air containing harmful substances such as fine dust flows, and to spray fine water particles into the air introduced from the outside through a spray nozzle to collect foreign substances contained in the air, Water particles collecting foreign substances are moved together with the flow of air, and water particles are collected by one or more water particle collecting units installed on the movement path of air and water particles, and the air in which the water particles are collected is discharged to the outside. An object of the present invention is to provide an air purifying device capable of removing very small-sized fine dust as well as harmful substances such as cigarette smoke in the outside air passing through the water particle collecting unit at a very high level.

In addition, another object of the present invention is to further install a cooling unit for allowing the cooled refrigerant to flow along one surface of the water particle collecting unit to cool the water particles injected from the water particle jetting unit and external air introduced from the outside to cool pollutants. It is to provide an air purifying device that can maximize the removal efficiency of the air conditioner and also perform an air conditioning function.

The present invention was created to achieve the object of the present invention as described above, and is an air purifying device 1000 for removing harmful substances contained in external air introduced from the outside, and an inlet 110 through which the external air is introduced. and a housing 100 having an outlet 120 for discharging the purified air to the outside to form a flow path through which the external air flows; a water particle spraying unit 200 installed on the flow path and spraying fine water particles for collecting harmful substances contained in the outside air into the outside air; a water particle collecting unit 300 installed on the flow path, through which water particles collecting harmful substances from the outside air and the outside air pass, and collecting the water particles; an air flow forming unit 500 that forms a flow of the outside air so that the outside air passing through the water particle collecting unit 300 is discharged through the outlet 120; Disclosed is an air purifier (1000) installed on one surface of the water particle collecting unit (300) and comprising a cooling unit (800) for cooling the water particles and the outside air.

The water particle spraying part 200 and the water particle collecting part 300 are sequentially installed along the air flow direction, and the water particle spraying part 200 is installed to spray fine water particles on the flow path. One or more nozzles 210 may be included.

It may further include a water storage unit 400 for storing water particles that are collected by the water particle collecting unit 300 and then aggregated and fall to the lower side.

It may further include a water transport unit 600 for transporting the water stored in the water storage unit 400 to the water particle spray unit 200 .

The water particle collecting unit 300 may include a metal mesh member 310 in which metal threads are entangled.

The metal mesh member 310 may be made of SUS material.

The cooling unit 800 includes a cooling passage unit 810 through which a refrigerant flows; A refrigerant circulation unit connected to both ends of the cooling passage unit 810 to form a refrigeration cycle together with the cooling passage unit 810 may be included.

The cooling passage part 810 may be installed in a preset pattern on one surface of the water particle collecting part 300 facing the water particle spraying part 200 .

The refrigerant circulation unit is connected to one end 802 of the cooling passage unit 810 and receives and compresses the refrigerant coming out of the cooling passage unit 810 and is connected to the compression unit 820 and the compression unit 820 . The condensing unit 830 is connected to the other end 804 of the condensing unit 830 and the cooling passage unit 810, and the condensing unit 830 receives and condenses the refrigerant from the compression unit 820, and the condensing unit 830. It may include an expansion unit 840 that expands the refrigerant coming out of the and delivers it to the cooling passage unit 810 .

The water particle collecting unit 300 is provided in plurality, and the plurality of water particle collecting units 300 may be sequentially installed along the flow path.

The water particle spraying unit 200 may be provided in plurality to correspond to each of the plurality of water particle collecting units 300 .

The plurality of water particle collecting units 300 may be arranged in a horizontal direction on a plane.

The metal mesh member 310 may be photocatalytically coated.

The present invention forms a flow path through which air containing harmful substances such as fine dust flows, and collects harmful substances such as foreign substances contained in the air by spraying fine water particles into the air introduced from the outside through a spray nozzle, The collected water particles are moved together with the flow of air, and at least some of the water particles are collected and removed by one or more water particle collecting units installed on the movement path of the air and water particles, and the water particles are collected and removed. By discharging the exhausted air to the outside, there is an advantage in that it is possible to remove very small-sized fine dust as well as pollutants such as cigarette smoke from the outside air passing through the water particle collecting unit at a very high level.

In addition, the present invention has the advantage of being able to remove water-soluble radioactive substances such as radon and water-soluble odorous substances such as ammonia present in the air by purifying the outside air by spraying fine particles of water through the nozzle.

In addition, the present invention further provides a cooling unit for allowing the cooled refrigerant to flow along one surface of the water particle collecting unit to cool the water particles sprayed from the water particle spraying unit and external air flowing in from the outside, thereby removing the pollutant removal efficiency. It has the advantage of maximizing air conditioning and performing the air conditioning function.

1 is a cross-sectional view showing an air purifying device according to an embodiment of the present invention.
FIG. 2A is a partially enlarged view showing a modified example of a part of the configuration of the air purifier of FIG. 1 .
FIG. 2B is a bottom view showing a bottom surface of a part of the configuration of FIG. 2 .
FIG. 3 is a conceptual diagram for explaining a part of the configuration of the air purifier of FIG. 1 .
4 is a plan view showing a part of the configuration of the air purifier of FIG. 1 .
5 is a cross-sectional view showing an air purifying device according to another embodiment of the present invention.
6 is a cross-sectional view showing an air purifying device according to another embodiment of the present invention.
7A to 7C are a front view, a plan view, and a side view showing a cross-section of an air purifier according to another embodiment of the present invention.
8 is a schematic diagram showing an air purifying device according to another embodiment of the present invention.
9 is a plan view showing the air purifier of FIG. 8 .
10 is a side view showing the air purifier of FIG. 7A.

Before describing various embodiments of the present invention in detail, it will be understood that the application is not limited to the details of the construction and arrangement of components described in the following detailed description or shown in the drawings. The invention is capable of being embodied and practiced in other embodiments and of being carried out in various ways. Also, device or element orientation (eg "front", "back", "up", "down", "top", "bottom") The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral", etc. are used merely to simplify the description of the invention, and the associated apparatus Or it will be appreciated that it does not simply indicate or imply that an element must have a particular orientation. Also, terms such as “first” and “second” are used in this application and the appended claims for the purpose of description and are not intended to indicate or imply relative importance or spirit.

In order to achieve the above object, the present invention has the following features.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can replace them at the time of the present application It should be understood that there may be water and variations.

The technical gist of the present invention is to form a flow path through which air containing harmful substances such as fine dust flows, and to spray fine water particles through a spray nozzle into the air introduced from the outside, thereby removing foreign substances through water particles contained in the air. At least some of the water particles are collected and removed by one or more water particle collecting units installed on the air movement path, and the air from which the water particles have been removed is discharged to the outside, so that It relates to an air purifier capable of removing very small-sized fine dust as well as pollutants and odor substances such as cigarette smoke at a very high level.

Here, the water particles collected by the water particle collecting unit are removed from the water particle collecting unit by falling downward by their own weight due to the aggregation of the water particles.

As an embodiment of the water particle collecting unit, it may be constituted by a so-called demister in which SUS material wires are entangled.

On the other hand, in the present invention, the large water droplets formed as fine water particles pass through the water particle collecting unit and harmful substances including fine dust contained in the outside air are combined and dropped, so that the water droplets formed by the water particle collecting unit are transferred to the outside air. It has the advantage that it can be removed to the lower side of the air purifier in a state of being combined with harmful substances in the air, and thus even fine dust in the outside air can be removed with a high removal rate.

In addition, since the air purifier according to the present invention purifies the outside air by spraying water through a nozzle, there is an advantage that water-soluble radioactive materials such as radon present in the outside air can be removed together.

Hereinafter, an air purifying apparatus according to the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 to 5 , the air purifier 1000 according to the present invention is an air purifier 1000 that removes harmful substances contained in external air introduced from the outside. a housing 100 having an inlet 110 and an outlet 120 through which purified air is discharged to the outside to form a flow path through which external air flows; a water particle spraying unit 200 installed on the flow path and spraying fine water particles to the outside air for collecting harmful substances contained in the outside air; a water particle collecting unit 300 installed on the flow path and collecting water particles collecting harmful substances from outside air; It may include an air flow forming unit 500 that forms a flow of outside air so that the outside air passing through the water particle collecting unit 300 is discharged through the outlet 120 .

The housing 100 has an inlet 110 through which external air is introduced and an outlet 120 through which the purified air is discharged to the outside, so that a flow path through which the outside air flows is formed.

For example, the housing 100 is a housing in which an inlet 110 and an outlet 120 are formed, and a water particle spraying unit 200, a water particle collecting unit 300, which will be described later, are installed therein. can

As shown in FIGS. 1 to 5 , the housing 100 may form a flow path by various structures therein so that the air sucked in through the inlet 110 reaches the outlet 120 .

On the other hand, the housing 100 can be configured in various ways, such as including one or more frames and one or more panel parts connecting the frames to form an internal space.

On the other hand, the flow path formed by the housing 100 may be formed by various methods according to design and design, and as shown in FIGS. 1 and 5 to form a relatively long flow path within a limited internal space, The length of the flow path through which the air flows can be formed to be relatively long by allowing the air to repeatedly ascend and descend by the one or more partition wall members 111 .

The inlet 110 is an inlet through which external air is introduced, and various configurations are possible depending on the structure of the flow path.

For example, the inlet 110 is an opening formed in the housing 100 , and may function as a passage through which external air is introduced, may be formed in various shapes and sizes depending on the device design, and may be formed in the housing 100 . It may be formed in various positions.

The outlet 120 is an opening through which the external air introduced into the inlet 110 is purified through the air purifier 1000 and then discharged, and may be formed in various shapes and sizes according to the device design and may be formed in the housing 100 . It can be formed at various locations of

The flow path is formed by communicating with the inlet 110 and the outlet 120, and may be configured along various paths as a path through which air flows, but passes through the water particle spraying unit 200 and the water particle collecting unit 300 to be described later. In this section, it is preferable that the external air is configured to move along the movement (flow) direction (downward direction, gravity direction) of the water particles sprayed from the water particle spraying unit 200 .

Meanwhile, as shown in FIG. 1 , the housing 100 may be formed by combining a plurality of members 101 and 102 or may be formed integrally.

The water particle spraying unit 200 is installed on the flow path through which the outside air flows, and various configurations are possible by spraying fine water particles for collecting harmful substances contained in the outside air into the outside air.

The water particle spraying unit 200 may be configured to spray water with high pressure to spray ultra-fine water particles.

The water particle spraying unit 200 sprays ultra-fine water particles to the outside air flowing along the flow path through high-pressure spraying, so that harmful substances contained in the outside air are mixed with the water particles and can be collected in the fine water particles. have.

If the water particle spraying unit 200 is installed on the flow path, it can spray fine water particles in various directions, but spray the water particles toward the downward direction (gravity direction), which is the direction in which the sprayed water particles fall. installed is preferred.

In addition, the water particle spraying unit 200 may be variously arranged in a plurality of numbers.

For example, the water particle spraying unit 200 may include one or more nozzles 210 installed so that the fine water particles are sprayed in a downward direction (gravity direction), as shown in FIG. 2B .

The nozzle 210 is a configuration that sprays water granulated enough to remove foreign substances such as fine dust contained in the outside air, and any configuration is possible as long as it can spray water particles.

For example, the nozzle 210 is a spray nozzle for spraying water supplied by a water supply device (not shown), and may be composed of a nozzle tube having various inner diameters according to design, but preferably harmful substances and In order to effectively mix the micronized water particles, the inner diameter of 0.05 mm to 0.2 mm, preferably, it may be composed of a nozzle tube having an inner diameter of 0.1 mm. Through this, water particles having a diameter of 10 μm or less may be sprayed.

In addition, in order to spray a large amount of water particles, the water particle spraying unit 200 is configured such that a plurality of nozzles 210 are coupled to each other, a plurality of spray nozzle holes are formed in one member, or a plurality of nozzles 210 are provided. Various embodiments are possible, such as including a plurality of members respectively installed.

Specifically, as shown in FIG. 2B , the water particle spraying unit 200 may include a plurality of nozzles 210 disposed at intervals along an annular line, but is not limited thereto.

Meanwhile, the water particle spraying unit 200 may be supplied with water in various ways.

For example, the water particle spraying unit 200 may be supplied with water by various water supply devices such as a water pipe and a water transport unit 600 to be described later.

The water particle collecting unit 300 is installed on the flow path, and various configurations are possible such that the water particles that collect harmful substances from the outside air and the outside air pass through and collect the water particles.

The water particle collecting unit 300 is installed between the flow path water particle spraying unit 200 and the outlet 120 , and water particles collecting harmful substances and external air may pass in the same direction.

In the water particle collecting unit 300 , the micronized water particles mixed with harmful substances pass through the water particle collecting unit 300 and aggregate in the water particle collecting unit 300 to be collected as large water particles (water droplets).

At this time, harmful substances in the external air passing through the water particle collecting unit 300 may be combined with the water particles collected by the water particle collecting unit 300, and the water particles combined with the harmful substances will fall downward by their own weight. can

The water particle spraying unit 200 and the water particle collecting unit 300 are sequentially installed along the air flow direction so that the water particles collected in the water particle collecting unit 300 can naturally fall to the lower side together with harmful substances. desirable.

The water particle collecting unit 300, as long as it can collect water particles, various configurations are possible, for example, as shown in FIG. can do.

The metal mesh member 310 has a configuration in which metal yarns are irregularly entangled to form a layer with a preset thickness, and the thickness of the metal yarn and the thickness of the layer may be variously set.

In addition, the metal mesh member 310 may be installed in multiple layers in consideration of the trapping effect of the collected water particles, or layers having different diameters of metal threads may be installed in multiple layers.

In addition, when the metal mesh member 310 is installed in multiple layers, a reinforcing frame of a mesh structure may be installed between the upper and lower surfaces, and between the layers.

Meanwhile, the water particle collecting unit 300 may further include a fixing frame 320 for fixing the metal mesh member 310 in order to stably install the metal mesh member 310 .

The fixed frame 320 is a configuration that supports the installation of the metal mesh member 320 by stably supporting the metal mesh member 320, and is composed of the reinforcing frame described above or supporting the metal mesh member 320. Various configurations are possible as a structure.

The metal mesh member 310 and the fixed frame 320 may be made of SUS material for semi-permanent use.

The metal mesh member 310 may be configured by a so-called demister in which wires having very small diameters made of SUS material are entangled.

On the other hand, the water particle collecting unit 300 and the water particle spraying unit 200 have been described with reference to an embodiment in which they are installed at a single point on the flow path through which the air flows. Various embodiments are possible for the installation structure and the installation form according to the principle of removal of water particles.

For example, at least one of the water particle collecting part 300 and the water particle spraying part 200 may be installed in plurality at a plurality of points in terms of maximizing the removal effect of harmful substances on the air passage.

In this case, the air purifier 1000 may further include a water storage unit 400 for storing water particles that are collected by the water particle collecting unit 300 and then aggregated and fall downward.

The water storage unit 400 may be installed to be replaceable in order to remove water after use for a certain period of time or more.

The water storage unit 400 is a space formed below the air purifier 1000 , and water droplets that have passed through the water particle collecting unit 300 and aggregated may fall and be stored under their own weight.

In this case, the air purifier 1000 may further include a water transport unit 600 for transporting the water stored in the water storage unit 400 to the water particle spray unit 200 .

The water transport unit 600 is configured to circulate the water in the water storage unit 400 by pulling it up to the water particle spray unit 200 , and various configurations are possible.

For example, the water transport unit 600 includes a pump 610 that circulates water between the water particle injection unit 200 and the water storage unit 400 and a water particle injection unit in the water storage unit 400 . It may be composed of a pipe part 620 for moving up to (200).

In this case, the water storage unit 400 may further include a partition part that is formed to protrude upward from the bottom surface to separate one side and the other side of the water storage unit 400 .

On one side of the water storage unit 400 divided by the partition, harmful substances (sludge, sunken fine dust, etc.) heavier than the water contained in the dropped water sink and after a certain time passes, the water storage unit 400 It may be configured to be stacked on the bottom surface.

At this time, at one side of the water storage unit 400, a sludge discharge unit capable of removing harmful substances accumulated on the floor may be additionally installed.

The water in which the harmful substances have sunk may be configured to pass to the other side of the partition.

The water passed to the other side of the partition may be transported to the water particle spraying unit 200 through the water transporting unit 600 described above.

In addition, in the water storage unit 400, a sensor unit for automatically adjusting the level of stored water or automatically replenishing or exchanging water may be installed, and receiving a signal from the sensor unit to supply or replace water when required. Solenoid valves for regulating supply or discharge may be additionally installed.

The air flow forming unit 500 is configured to form a flow of outside air so that the outside air passing through the water particle collecting unit 300 is discharged through the outlet 120 , and various configurations such as a fan are possible.

The air flow forming unit 500, if it can form the flow of external air from the inlet 110 to the outlet 120, various configurations are possible and can be installed in various positions. 1 and 5 illustrate a case in which the air flow forming unit 500 is installed on the outlet 120 side, the embodiment of the present invention is not limited thereto.

According to the above configuration, the fine water particles sprayed from the water particle spraying unit 200 may be circulated in the air purifier 1000 through the water storage unit 400 and pass through the water particle collecting unit 300 . One external air may be condensed and discharged to the outside again through the outlet 120 through the water droplet falling into the water storage unit 400 .

In this process, odor particles (deodorization), oil vapor, fine dust (ultra-fine dust), and harmful substances (cigarette smoke) contained in the outside air can be effectively removed, and also radioactive substances such as water-soluble radon can be dissolved in water. It has the advantage that it can be melted and removed.

On the other hand, as shown in FIG. 1 , when the air purifier 1000 is composed of only the water particle spraying unit 200 and the water particle collecting unit 300 , residual harmful substances that cannot be captured by water particles in the outside air may remain. Possibility exists.

Accordingly, the air purifying device 1000 according to the present invention, as shown in FIG. 6 , additionally includes a filter unit 700 for removing residual harmful substances remaining in the external air that has passed through the water particle collecting unit 300 . may include Meanwhile, in the case of FIG. 6 , it may be understood that the cooling unit 800, which will be described later, is omitted.

The filter unit 700 is installed on the flow path through which the external air that has passed through the water particle collecting unit 300 flows, and is preferably installed so as not to interfere with the water particles that are aggregated and fall through the water particle collecting unit 300 .

Accordingly, as shown in FIG. 6 , the filter unit 700 is a second housing configured independently from the first housing 101 in which the water particle spraying unit 200 and the water particle collecting unit 300 are installed. (103) can be installed.

The filter unit 700 may include an oil vapor filter unit 710 for removing oil vapor contained in the external air that has passed through the water particle collecting unit 300 .

The oil vapor filter unit 710 may be configured to remove not only oil vapor (oil component) contained in external air but also fine dust (ultra-fine dust) or odor particles.

For example, the oil vapor filter unit 710 may have the same configuration as the water particle collecting unit 300 except that it does not collect water particles unlike the water particle collecting unit 300 described above.

That is, the oil vapor filter unit 710 may include a metal mesh member formed by entangled metal threads, and a fixing frame for fixing the metal mesh member, but is not limited thereto.

External air passes through the oil vapor filter unit 710 , and oil components contained in the external air may be caught by the oil vapor filter unit 710 and removed.

In addition, the filter unit 700 includes a carbon fiber filter unit 720, an activated carbon filter unit 730, and a HEPA filter unit 740 that are sequentially installed along the flow path at the rear end of the oil vapor filter unit 710. may include

Through the carbon fiber filter unit 720 and the activated carbon filter unit 730, harmful substances contained in external air can be filtered down to 0.3 μm, and even fine odor particles can be purified with carbon fiber and activated carbon (ACF activated carbon). have.

The carbon fiber filter unit 720 and the activated carbon filter unit 730 have an advantage that can be used semi-permanently.

The HEPA filter unit 740, as a HEPA filter, may finally filter fine dust (ultra-fine dust) and harmful substances (nicotine, tar, etc.) remaining in the outside air.

That is, the air purifier 1000 according to the present invention is purified through the oil vapor filter unit 710, the carbon fiber filter unit 720, the activated carbon filter unit 730, and the HEPA filter unit 740 sequentially. Air may be discharged to the outside of the air purifier 1000 through the outlet 120 .

In addition, in the air purifier 1000 according to the present invention, only the HEPA filter unit 740 needs to be replaced, and if the HEPA filter unit 740 is not exposed to cigarette smoke such as nicotine or tar, the HEPA filter unit 740 can also be used semi-permanently. have.

Hereinafter, a specific embodiment to which the air purifier 1000 according to the present invention can be applied will be described in detail with reference to FIGS. 7A to 10 .

Looking at the portable personal smoking device for removing smoke, nicotine, tar, and harmful bacteria emitted during smoking according to the present invention,

The present invention is to install a purification device (4) in the device frame (1) so that when a smoker smokes, smoke is directly injected into the device, so that the smoke emitted by the smoker is quickly purified without spreading to the surroundings; Personal portable smoking that removes harmful bacteria such as smoke, nicotine, and tar emitted during smoking that can prevent the health of smokers and non-smokers by removing odors in smoke and harmful bacteria such as nicotine and tar during smoking In the device,

The purifier (4) is installed with a replacement water tank (8) connected to the water spraying rear exhaust device (7) and the water pump (15) connected through a pipe; It is connected to the purification device (4) and the smoking inlet (2) and the purified air exhaust port (13) are installed through the installation of the intake and exhaust fan (14); The inhalation and exhaust fan 14 installed connected to the purification device 4 extends the smoke introduced through the smoking inlet 2, and the smoke discharged to the purified air exhaust port 13 is discharged through the exhaust vent of the smoking frame (1) ( 16) is connected and installed; a suction/exhaust fan (14) for sucking the smoke emitted by the smoker into the purifier (4) in the device frame (1) is installed; WATER PUMP (15) for the circulation of water in the replacement water tank (8) is installed; It is connected to the purification device (4) and the intake and exhaust fan (14) is installed and is installed to circulate through the purification air exhaust port (13);

The exhaust vent 16 of the smoking inlet 2 penetrates through the purified air exhaust 13 of the purifier 4 and extends to the exhaust vent 16 of the smoking frame 1, and is sucked on the side of the purifier 4 The exhaust fan (14) is installed to inhale the smoke, and the smoke sucked in through the smoking inlet (2) is discharged to the water jet nozzle (6) side and is connected to the purification device (4) and replaced through the installed water pump (15). Pump the water in the water tank (8) to spray water, dilute fine dust, nicotine, and tar in the smoke inhaled through the smoking inlet (2), neutralize it with water to remove it, and then place it on the lower surface where water is sprayed. Discharging fine dust, nicotine, and tar diluted water to the exhaust port 7 after the connected water jet;

A first demister member 17 is installed inside the purification device 4, which is composed of thin wires being irregularly entangled and filled. After being removed by diluting and neutralizing dust, nicotine, and tar, it is condensed while passing through the first demister member 17 so that it falls in the form of drops,

The air discharged to the discharge surface passes through the second demister member 9 composed of thin wires being irregularly tangled and filled, and oil is removed while the wire is soaked in, carbon fiber filter 10, activated carbon filter 11 , by continuously passing through the HEPA filter (12) to finally collect fine dust, nicotine, and tar, and then replace only the HEPA filter (12) and incinerate it. It is characterized in that it is discharged into the room.

In addition, it is characterized in that the pumping amount and the injection amount of water can be adjusted so that the purified smoke is discharged and the purifier 4 is installed to quickly remove fine dust, nicotine, and tar.

In addition, the smoking frame (1) is characterized in that it is possible to move and transport by mounting a handle (5).

In addition, the smoking inlet (2) of the smoking frame (1) is characterized in that the suction frame (3) is installed to guide the inflow direction of the smoke so that the smoke is quickly sucked into the purifier (4) and does not spread to the surroundings. do it with

The present invention provides a portable personal smoking device for removing smoke, nicotine, tar, and harmful bacteria emitted during smoking using a demister member,

This has the effect of minimizing the discomfort of non-smokers because it can be used independently and in a minimum space by completely changing the concept of the existing smoking booth.

In addition, it has the effect of contributing to the health promotion of smokers by reducing the stress caused by smoking by satisfying the smoker's desire to smoke.

To this end, a smoking inlet 2 through which a smoker can directly exhale smoke is installed on the exterior of the smoking frame 1, and a purifier 4 for purifying smoke by connecting the smoking inlet 2 is installed; The purification device (4) is installed by connecting the replacement water tank (8) and the WATER PUMP (15) through a pipe connecting each installation; The inhalation and exhaust fan 14 connected to the purification device 4 extends the smoke introduced through the smoking inlet 2, and the smoke discharged to the purified air exhaust port 13 is removed from the exhaust vent 16 of the smoking frame (1). ) is discharged into the room.

For this reason, the purification device 4 is mounted on a separate smoking frame 1 including the handle 5 and is designed to be moved conveniently, and the smoker can smoke without discomfort, and a comfortable indoor space even while the smoker is smoking. It contains a structure that can maintain the environment, is very neat, and is easy to store because it is stand-alone.

In order to inhale and filter the smoke emitted by the smoker into the purifier (4), the smoking inlet (2) on the outer side of the purifier (4) and a personal portable smoking device equipped with an intake/exhaust fan (14) are installed. will be.

The suction/exhaust fan 14 introduces the smoke emitted by the smoker into the suction surface of the water jet nozzle 6 through the smoking inlet 2 of the purification device 4, and the introduced smoke is replaced through the WATER PUMP 15 After pumping water from the water tank (8) and spraying water through the water spray nozzle (6), dilute fine dust, nicotine, and tar in the inhaled smoke and neutralize it with water to remove it, then the lower surface where water is sprayed It discharges water diluted with fine dust, nicotine, and tar.

At this time, the first demister member 17 is installed inside the purifier 4, which is composed of thin wires being irregularly entangled and filled, and the water vaporized and sprayed through the water spray nozzle 6, After diluting and neutralizing fine dust, nicotine, and tar in the smoke to remove it, it is condensed while passing through the first demister member 17 so that it falls in the form of droplets and is discharged, filtered through the primary water jet, and then discharged The oil is removed while passing through the second demister member 9 composed of irregularly entangled and filled thin wires, such as the second demister member 9 and the carbon fiber filter 10, The activated carbon filter 11 is sequentially passed through the HEPA filter 12, the purified air exhaust port 13, and the exhaust vent 16 is discharged into the room.

The filtering through the water spray nozzle 6 filters fine dust, nicotine, and tar in the smoke, and the second demister member 9 is a demister filter, which removes various bacteria, viruses and odors in the air, and oil in the fine dust. The carbon fiber filter 10 and ACF activated carbon fiber 11 are activated carbon filters to filter odors, and the HEPA filter 12 is a HEPA filter to completely remove fine dust, nicotine and tar in the remaining smoke. It is responsible for the filtering function.

Through the above various filters, fine dust, nicotine, and tar in the smoke emitted by the smoker are perfectly filtered, and the smoker can freely move the device to a place with or without a non-smoker to engage in smoking activities.

In addition, the pumping amount and spraying amount of water can be adjusted so as to quickly remove fine dust, nicotine, and tar by installing the purification device 4 for the discharged purified smoke.

In addition, the smoking frame (1) is adapted to be movable and transportable by mounting a handle (5); it has been done

In addition, the smoking inlet 2 of the smoking frame 1 guides the inflow of smoke into the purifier 4 so that the smoke is quickly sucked into the purifier 4 and does not spread to the surroundings. This is installed; it has been done

On the other hand, it goes without saying that the air purifier 1000 according to the above-described embodiment of the present invention may be configured to be movable, fixed to the indoor or outdoor ground, or may be installed in various ways, such as a wall-mounted type.

Meanwhile, as shown in FIG. 5 , the water particle collecting unit 300 may be provided in plurality.

In this case, the plurality of water particle collecting units 300 may be sequentially installed along the flow path. In addition, as shown in FIG. 5 , the plurality of water particle collecting units 300 may be arranged in a horizontal direction on a plane.

To this end, the partition wall member 111 may form a flow path through which air flows so that air repeatedly ascends and descends while dividing the plurality of water particle collecting units 300 in a horizontal direction.

Accordingly, the air that has passed through one water particle collecting unit 300 can pass through the next adjacent water particle collecting unit 300 again, and the filtering effect can be maximized.

Meanwhile, the water particle spraying unit 200 may be provided in plurality to correspond to each of the plurality of water particle collecting units 300 .

At this time, each of the water particle collecting unit 300 is preferably installed so as not to interfere with the water particles that are agglomerated through the neighboring water particle collecting unit 300 and falling.

When a plurality of water particle spraying units 200 are installed to correspond to each water particle collecting unit 300 , a plurality of water particle spraying units 200 may be selectively operated.

That is, in the case of FIG. 5 , the case where both of the two water particle spraying units 200 are operated is illustrated, but the present invention is not limited thereto, and if at least one of the plurality of water particle spraying units 200 is operated, another water particle spraying unit 200 . may be selectively operated as needed.

At this time, the inlet 110 may be formed in a position close to the first water particle collecting unit 300 on the flow path in the housing 100, and the outlet 120 is located close to the last water particle collecting unit 300 in the flow path. can be formed.

An air inlet member 130 for introducing external air may be installed in the inlet 110 . The air inlet member 130 may be connected to a configuration for discharging air requiring purification (eg, a contaminated air discharge pipe of the kitchen hood).

The air introduced through the inlet 110 moves along the flow path, passes through the first water particle collecting unit 300, and then sequentially passes through other water particle collecting units 300(s) and then through the outlet 120. can be discharged outside.

In the case of FIG. 5 , an embodiment in which the air introduced through the two inlets 110 is discharged to the outlet 120 after passing through the two water particle collecting units 300 is illustrated, but three or more water particle collecting units 300 Of course, an embodiment in which ) is sequentially installed or an embodiment in which the filter unit 700 is additionally discharged is possible, of course.

Meanwhile, at least one of the water particle collecting unit 300 (metal mesh member 310 ) and the filter unit 700 may be photocatalytically coated. In particular, it is preferable that the filter unit 700 is photocatalytically coated, but the present invention is not limited thereto, and an embodiment in which at least one of the plurality of water particle collecting units 300 is photocatalytically coated is also possible.

Photocatalyst is a type of catalyst, in which catalysis occurs by receiving light energy, for example, TiO ₂ (anatase), TiO ₂ (rutile), ZnO, CDS, ZRO ₂ , SNO ₂ , V ₂ O ₂ . WO ₃ and the like, perovskite-type composite metal oxide (SRTIO ₃ ) and the like may be included.

The photocatalytic coating added to the water particle collecting unit 300 and the filter unit 700 may be made of various materials as long as it is optically active, has no photocorrosion, and is biologically or chemically inactive.

When the photocatalytic coating is added to the water particle collecting unit 300 and the filter unit 700, it can be used semi-permanently, and _{has a higher oxidizing power than chlorine (CL 2} ) or ozone (O ₃ ), which has the advantage of excellent sterilization power.

The photocatalytic coating may be added to at least one of the plurality of water particle collecting units 300 and the filter unit 700, and is preferably added to the filter unit 700 through which purified air is last passed.

On the other hand, the filter part 700 is of course not a configuration that is not necessarily added as an optional configuration, and is composed of a metal mesh member formed by entangled metal threads in the same way as the water particle collecting part 300 (demister). may be absent).

On the other hand, the air purifier 1000 according to the present invention, in addition to the above-described configuration, is installed on one surface of the water particle collecting unit 300, the cooling unit 800 for cooling the water particles and the outside air is additionally may include

The cooling unit 800 is installed in the housing 100 to cool the water particles injected from the water particle injection unit 200 and the introduced external air, and various configurations are possible.

For example, the cooling unit 800 may include a cooling passage unit 810 through which a refrigerant flows; A refrigerant circulation unit connected to both ends of the cooling passage unit 810 to form a refrigeration cycle together with the cooling passage unit 810 may be included.

The cooling passage unit 810 may have various configurations as long as it functions as an evaporator that lowers the surrounding temperature by absorbing heat from the surroundings while the refrigerant flows.

Specifically, the cooling passage 810 may be installed in a preset pattern on one surface of the water particle collecting unit 300 facing the water particle collecting unit 300 .

The cooling flow passage 810 is preferably installed in a state in contact with one surface of the water particle collecting unit 300 .

The refrigerant may be discharged through one end 802 of the cooling passage 810 and the refrigerant may be introduced through the other end 804 .

The refrigerant flowing in through the other end 804 may pass through the cooling passage 810 and evaporate and be discharged through the end 802 .

Although the cooling passage part 810 is illustrated in a curved zigzag pattern in FIG. 3 , it is not limited thereto, and various shapes and patterns are possible.

The refrigerant circulation unit is connected to both ends 802 and 804 of the cooling passage unit 810 to form a refrigeration cycle together with the cooling passage unit 810 , and various configurations are possible.

The refrigerant circulation unit may be installed outside the housing 100 .

For example, the refrigerant circulation unit includes a compression unit 820 connected to one end 802 of the cooling passage unit 810 and receiving and compressing the refrigerant coming out of the cooling passage unit 810 , and the compression unit 820 . ) connected to the condensing unit 830 for receiving and condensing the refrigerant coming out of the compression unit 820 , and the condensing unit 830 and the other end 804 of the cooling passage unit 810 connected to the condensing unit It may include an expansion unit 840 that expands the refrigerant coming out of the 830 and transfers it to the cooling passage unit 810 .

A fan 832 may be installed in the condensing unit 830 .

The expansion unit 840 may be formed of a capillary tube as an expansion valve.

The refrigerant expanded through the capillary-shaped expansion unit 840 may flow into the cooling passage unit 810 to absorb ambient heat by evaporation.

Since the cooling flow path part 810 is installed on one surface of the water particle collecting part 300 toward the water particle spraying part 200, the water particles sprayed from the water particle spraying part 200 collide with the cooling flow passage part 810 and come into contact. As a result, it can be cooled to a low temperature, and the external air that communicates with the water particle collecting unit 300 also collides with the cooling passage 810 and can be cooled to a low temperature by meeting with the water particles cooled to a low temperature.

The external air cooled to a low temperature may be discharged to the outside in a relatively cool state after passing through the water particle collecting unit 300 .

In addition, the water particles cooled to a low temperature are transferred back to the water particle spraying unit 200 through the water storage unit 400 and the water transport unit 600 , and are changed to a lower temperature state by passing through the cooling passage unit 810 again. can be

Refrigerant circulation and cooling temperature through the cooling unit 800 may be controlled through a separate control unit.

Meanwhile, the air purification apparatus according to the present invention may further include a disinfection lamp unit 150 for disinfection using UVA (ultraviolet).

The disinfection lamp unit 150 is configured to disinfect the external air introduced into the housing 100 using UVA (ultraviolet), and various configurations are possible.

The disinfection lamp unit 150 may be installed in various locations if it can disinfect the external air flowing along the flow path in the housing 100 .

For example, the disinfection lamp unit 150 may be installed in a path between the water particle collection unit 300 and the outlet 120 of the housing 100 so that the external air that has passed through the water particle collection unit 300 is disinfected.

As described above, although the present invention has been described with reference to limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those of ordinary skill in the art to which the present invention pertains. Of course, various modifications and changes are possible within the scope of equivalents of the claims to be described.

1000: air purifier 100: housing
200: water particle spraying unit 300: water particle collecting unit
400: water storage unit 500: air flow forming unit

Claims (13)

An air purifier 1000 for removing harmful substances contained in external air introduced from the outside, comprising:
a housing 100 having an inlet 110 through which the outside air is introduced and an outlet 120 through which the purified air is discharged to form a flow path through which the outside air flows;
a water particle spraying unit 200 installed on the flow path and spraying fine water particles for collecting harmful substances contained in the outside air into the outside air;
a water particle collecting unit 300 installed on the flow path, through which water particles collecting harmful substances from the outside air and the outside air pass, and collecting the water particles;
an air flow forming unit 500 for forming a flow of the outside air so that the outside air passing through the water particle collecting unit 300 is discharged through the outlet 120;
and a cooling unit (800) installed on one surface of the water particle collecting unit (300) to cool the water particles and the outside air. The method according to claim 1,
The water particle spraying unit 200 and the water particle collecting unit 300 are sequentially installed along the air flow direction,
The water particle spraying unit 200 includes one or more nozzles 210 installed to spray fine water particles on the flow path. 3. The method according to claim 2,
The air purifier (1000), characterized in that it further comprises a water storage unit (400) for storing the water particles that are collected by the water particle collecting unit (300) and then aggregated and fall to the lower side. 4. The method according to claim 3,
The air purifier (1000), characterized in that it further comprises a water transport unit (600) for transporting the water stored in the water storage unit (400) to the water particle spray unit (200). The method according to claim 1,
The water particle collecting unit 300,
Air purification apparatus 1000, characterized in that it comprises a metal mesh member (310) formed by entangled metal yarn (金屬絲). 6. The method of claim 5,
The metal mesh member (310) is an air purifier (1000), characterized in that made of SUS material. The method according to claim 1,
The cooling unit 800,
a cooling passage 810 through which a refrigerant flows;
and a refrigerant circulation unit connected to both ends of the cooling passage unit (810) to form a refrigeration cycle together with the cooling passage unit (810). 8. The method of claim 7,
The cooling passage unit (810) is an air purifier (1000), characterized in that it is installed in a preset pattern on one surface of the water particle collecting unit (300) facing the water particle spraying unit (200). 8. The method of claim 7,
The refrigerant circulation unit is connected to one end 802 of the cooling passage unit 810 and receives and compresses the refrigerant coming out of the cooling passage unit 810 and is connected to the compression unit 820 and the compression unit 820 . A condensing unit 830 that receives and condenses the refrigerant from the compression unit 820, and the condensing unit 830 and the other end 804 of the cooling passage unit 810 are connected to the condensing unit 830. The air purifier (1000), characterized in that it includes an expansion unit (840) for expanding the refrigerant coming out of the cooling passage unit (810). 10. The method according to any one of claims 1 to 9,
The water particle collecting unit 300 is provided in plurality,
The plurality of water particle collecting units (300) are air purifier (1000), characterized in that sequentially installed along the flow path. 11. The method of claim 10,
The water particle spraying unit (200), the air purifier (1000), characterized in that provided in a plurality corresponding to each of the plurality of water particle collecting units (300). 12. The method of claim 11,
The plurality of water particle collecting units 300 are air purifier 1000, characterized in that arranged in a horizontal direction on a plane, 7. The method according to any one of claims 5 to 6,
The metal mesh member (310) is an air purifier (1000), characterized in that the photocatalytic coating.

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