KR101903223B1 - Method for filtering and humidifying in wet type air cleaner - Google Patents

Abstract

The present invention provides an air cleaning and humidifying method using the cyclone principle. The method of the present invention includes: a swirling flow generating step of generating a swirling flow in an air purifying and humidifying vessel having a cylindrical cross section and a predetermined height while injecting air to be purified; A water supply process for spraying or scattering water inside the air purifying and humidifying vessel in which the swirling flow is formed; During the water supply process, water particles sprayed or scattered inside the container are rotated along the swirling flow to filter out foreign substances contained in the air, and at the same time, the filtered air is humidified and the air is purified and an outlet And the like. It is preferable that the swirl flow generation process and the water supply process are performed simultaneously. The swirling flow generating process is performed by supplying the air having passed through the filter by the blowing fan to the inside at the position eccentrically located at the upper part of the air cleaning and humidifying container.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wet air cleaner,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air purifying and humidifying method of an air cleaner, and more particularly, to an air purifying and humidifying method using a cyclone principle by splashing or spraying water into a constant internal space, .

Traditionally, an air cleaner has only a function of purifying air using a predetermined filter or a filtering method using electricity. The humidifier generates and supplies water vapor through various methods such as generation of water vapor using ultrasonic waves, generation of water vapor using heating, generation of water vapor using a mixture of them, or natural vaporization, irrespective of the air cleaning function Thereby performing humidification of the indoor air.

In recent years, products having both the humidifying function and the air purifying function as described above have been introduced in various forms. The so-called 'airwasher' or the 'wet type air purifier' is a product. Such an air purifier equipped with a humidification function is disclosed in Korean Patent No. 10-0863307, Japanese Patent No. 10-0805667, Registration Practical Utility Model Registration No. 20-0157935, and Korean Patent Publication No. 10-2010-0084828 It has been proposed in the form of branches.

In such an air purifier, a plurality of discs are provided on a rotating shaft disposed horizontally, and a plurality of such discs are partially rotated in a state of being immersed in water contained in a water tank. Airflow from the air blowing fan toward the disk assembly is formed so that foreign matter including dust and the like contained in the air is trapped in the water film formed on the surface of the disk and is transferred into water inside the water tank, The water on the surface of the assembly is naturally evaporated by the blowing of the blowing fan to perform a humidifying function.

However, the conventional air purifier has the following problems. In such air cleaning and humidification functions, the most important point in removing foreign substances contained in the air or spontaneously evaporating the water is the size of the contact area between the airflow and the water. However, according to the conventional air purifier, the contact area of the air flow generated in the first blowing fan is substantially limited to a part of the surface area of the disk, and the second air flow is once discharged to the outside of the air cleaner Therefore, there is a certain limit to the air purifying function and the humidifying function.

In order to sufficiently enlarge the surface area of a large number of disks provided on the rotary shaft, the interval between them must be narrow, which makes cleaning of the surface difficult. It is natural that the performance of the basic function of air cleaning is deteriorated.

In addition, in order to increase the efficiency of humidification or filtering in a conventional air cleaner, it may be considered to increase the size of the disk. However, if the disk is made large in a container having a certain volume of water, .

SUMMARY OF THE INVENTION The present invention has been made in order to solve such a conventional problem, and it is an object of the present invention to provide an air conditioner capable of efficiently collecting foreign substances in the air by making sufficient contact between water and air in a container having a certain volume, And to provide a method of air purification and humidification that can be performed by a user.

It is another object of the present invention to provide an air purifying and humidifying method by which a user can more visually confirm the operation state of the inside, thereby further satisfying a psychological effect of air cleaning and humidification.

It is a further object of the present invention to provide a more reliable air purification and humidification method by adding air cleaning effect using various types of filters in addition to wet air cleaning using water particles.

The air purifying and humidifying method of the present invention for achieving the above object is characterized in that the air purifying and humidifying vessel having a cylindrical cross section and a predetermined height includes a swirling flow generating process for generating a swirling flow while injecting the air to be purified, ; A water supply process for spraying or scattering water inside the air purifying and humidifying vessel in which the swirling flow is formed; During the water supply process, water particles sprayed or scattered inside the container are rotated along the swirling flow to filter out foreign substances contained in the air, and at the same time, the filtered air is humidified and the air is purified and an outlet And a discharging process through which the air is discharged.

The swirl flow generation process and the water supply process are preferably performed simultaneously.

According to another embodiment of the present invention, the air filtering apparatus further comprises a filtering process in which the air is primarily filtered while passing through the filter by the blowing fan, and the filtering process is performed before the swirling flow generating process.

According to another embodiment of the present invention, such a swirl flow generation process is performed by supplying air for purification into the interior of the humidification container at an eccentric position.

It is more preferable that the air flow generated by the air blowing fan is supplied to the interior of the humidification vessel from the position eccentric to the top of the humidification vessel.

According to the embodiment of the water supply process of the present invention, the air is purified by the spray nozzle and sprayed into the humidification vessel.

According to another embodiment of the water supply process, water may be spilled inside the vessel by the pumping mechanism. Here, the pumping mechanism is configured such that a horizontal cross section is arranged to correspond to a cylindrical shape, has a constant height, an open portion is formed therebetween, a plurality of grooves are formed on the inner side in a vertical direction, Side walls and a rim portion that connects the upper ends of the side walls in a circular manner. As the pumping mechanism rotates, the water moves upward along the groove, and then is scattered to the outside through the open portion.

Also in this embodiment, it is preferable that the rotation of the pumping mechanism is performed by pressurizing a plurality of blades formed in the rim portion of the air supplied to the inside of the air cleaning and humidifying container.

According to another embodiment of the water supply process, it is also possible to apply an external force to the water inside the humidification vessel and purify the air based on the rotational force so that the water particles are scattered inside the vessel.

According to the present invention having such a configuration, small-sized water such as water drops is widely distributed in the inside of the cyclone body, and a large number of water droplets and the like are generated by the swirling flow formed in the inside of the cyclone body And repeatedly contacted with the air. Therefore, it can be seen that the efficiency of collecting the foreign substances contained in the air in the water particles through the sufficient contact between the water particles and the air is increased, and the efficiency of the air cleaning can be increased relatively .

The water droplet or the like in the inside of the cyclone body is sufficiently exposed to the air as in the above-described swirl flow, so that the surface area substantially in contact with the air becomes sufficiently wide. As described above, sufficiently enlarging the surface area in contact with the air means that the humidification effect due to natural vaporization can be substantially secured. Therefore, the air purifier of the present invention is expected to have an effect of enabling more efficient humidification like efficient air cleaning.

According to the present invention, the cyclone body is provided with a sight window through which the inside can be seen, and the user can visually confirm the scattered or sprayed water from the inside through the sight window. Therefore, it can be said that it is expected to be more satisfying psychologically in terms of the effects on air cleaning and humidification.

According to the present invention, it is possible to use a separate filter in addition to the air cleaning in the above-described cyclone body, so that the filtering of the foreign substances contained in the air can be performed more effectively. This means that, for fine dust or the like which can not be substantially captured by the cyclone dust collection, sufficient filtration is possible by using a separate filter. Therefore, sufficient filtering for fine dust, which is a recent problem, becomes possible, and ultimately, an effect of achieving an optimal air cleaning effect is also expected.

1 is a flow chart showing the air purification and humidification method of the present invention.
FIG. 2 is a perspective view of a wet type air cleaner according to a first embodiment of the present invention, and FIGS. 2 (a) and 2 (b) show opposite sides.
FIG. 3 is a partially exploded perspective view of the wet type air cleaner according to the first embodiment to which the method of the present invention is applied; FIG.
FIG. 4 is a partially exploded perspective view of a wet type air cleaner according to the first embodiment to which the method of the present invention is applied. FIG.
5 is a cross-sectional exemplary view of a wet air cleaner according to a first embodiment to which the method of the present invention is applied;
6 is an exemplary perspective view showing the configuration of a pumping mechanism to which the method of the present invention may be applied;
7 is an exemplary perspective view of an air cleaner according to a second embodiment to which the method of the present invention is applied;
FIG. 8 is an exploded perspective view of an air purifier according to a second embodiment of the present invention. FIG.
Fig. 9 is a sectional exemplary view of an air cleaner according to a second embodiment to which the present invention is applied; Fig.

Hereinafter, the present invention will be described in more detail based on the embodiments shown in the drawings. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a flow chart illustrating an exemplary air purification and humidification method of the present invention. First, the overall purification and humidification method will be described. In the purification and humidification method of the present invention, the process of collecting foreign substances contained in the air such as dust and the like and humidifying the air using water in a certain container can be said to be performed substantially simultaneously.

In the present invention, air purification and humidification are simultaneously performed using the cyclone principle in such a container. To this end, a swirling flow must be formed inside the container. That is, the air to be purified is injected from the upper part of the container to the inside to form a swirling flow. In order to effectively make swirling flow in the air purifying and humidifying container, the container must have a cylindrical or ring-shaped cross section and have a certain height with respect to the up and down direction. Further, the container of the present invention should have an outlet formed at the upper central portion.

In the air purifying and humidifying vessel, a swirling flow is formed (Step 100), and water for air purification and humidification is injected or scattered into the interior of the vessel (Step 104). Therefore, water droplets or water droplets or water droplets (hereinafter, referred to as droplets or scattered water droplets, etc., which are injected or scattered into the inside of the container) . It is a matter of course that foreign particles such as dust contained in the air are collected in the water particles rotating in the container repeatedly many times.

The relatively heavy particles (for example, those which may collect foreign substances) among the particles of water contained in the air forming the swirling flow in the vessel are submerged downward by the self weight at the outer portion inside the vessel, The finely vaporized water particles are discharged to the outside through a molded outlet at the top of the vessel. Thus, the air discharged through the outlet of the vessel may be said to be substantially humidified.

In this case, the air that rotates several times inside the container while forming the swirl flow makes the water particles in the interior of the humidification container come into contact with the air many times, so that the total surface area of the water particles substantially in contact with air is sufficiently large. Since these water particles are vaporized in sufficient quantities through the swirling process, the air discharged to the outlet of the vessel will be referred to as humidified air with high humidity. Hereinafter, the air purifying and humidifying method according to the present invention will be described in more detail through an embodiment of the air purifier in which the above-described method is implemented.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in more detail with reference to the drawings. First, the structure related to the process of forming the swirling flow within the predetermined space, that is, the 100th process of the present invention, will be described first.

FIG. 2 is a perspective view showing one embodiment of an air cleaner to which the purifying and humidifying method of the present invention can be applied, wherein (a) and (b) are respectively viewed from opposite sides. 2, the air cleaner of the present invention includes a main casing 10 that forms an overall appearance and a cyclone body 30 that is installed at one side of the main casing 10 .

Here, substantial air purification and humidification takes place inside the cyclone body 30. That is, the container having the above-described air purification and humidification function can be referred to as a cyclone body 30. [ The main casing 10 is formed as an overall structure of the air purifier of the present invention and supports parts for forming a flow of air supplied to the inside of the cyclone body 30. [ 3, the cyclone body 30 and the water tank 20 are coupled to one side of the main casing 10, respectively. The water tank 20 is coupled and supported on a support portion 23 protruding from one side of the main casing 10 and the cyclone body 30 is also attached to the outer portion 23a of the support portion 23 at its lower end .

The support portion 23 includes a water guide passage 23b for guiding the water supplied through the water tank cap 22 coupled to the lower end portion of the water tank 20 to the outer portion 23a thereof, And a water storage portion 23c in which water supplied through the water storage portion 23b is stored at a predetermined water level (FIG. 4). The structure in which the water is supplied from the water tank cap 22 of the water tank 20 to the water storage portion 23c is substantially the same as the water supply structure of the conventional humidifier, A detailed description will be omitted.

4, the cyclone body 30 provided on the outer portion 23a of the support portion 23 has a pumping mechanism 40 that rotates inside the cyclone body 30. As shown in FIG. The cyclone body 30 has an upper body part 32 formed in a cylindrical shape and a cap part 34 provided on the upper part of the body part 32. The upper end portion and the lower end portion of the pumping mechanism 40 are rotatably supported by the cap portion 34 and the outer portion 23a of the support portion 23, respectively.

The body portion 32 of the cyclone body 30 has an inverted conical shape in which the upper portion is cylindrical and the lower portion is continuous in the upper portion. The lower end of the body portion 32 is supported by the outer portion 23a in an opened state. In addition, a part of the body part 32 is provided with a sight window 36 so that the user can see the inside of the cyclone body 30.

The cap portion 34 of the cyclone body 30 is installed at the open upper end portion of the body portion 32 and has a bridge type pumping mechanism support portion 34a formed at the central portion thereof. (38) is open. Since the central portion 38 of the cap portion 34 is open, the water vapor particles can be supplied to the room through the cap portion 34 as described later. That is, the central portion 38 may be an outlet through which the substantially humidified air is discharged into the room. Hereinafter, the central portion will be referred to as an outlet 38.

5, the main casing 10 includes a filter casing 10A that supports the filter 12 (see FIG. 1), and a fan casing 10B that supports the blowing fan 14 . The filter casing (10A) is provided with a filter (12) for filtering air to be sucked. In the illustrated embodiment, the filter (12) is constituted by a cylindrical filter. Accordingly, the filter 12 is provided with an opening 12a having an open upper portion of the center portion. The opening 12a is an outlet through which the filtered air substantially flows while passing through the filter 12. An inlet 15 is formed at a portion of the filter casing 10A corresponding to the outside of the filter 12 so that air can flow into the filter 12.

In the inside of the fan casing 10B, a blowing fan 14 for generating air flow is provided, and it is preferable to constitute a centrifugal fan as in the illustrated embodiment. Therefore, when the blowing fan 14 is operated by a driving motor (not shown), a flow of air from the outside to the inside of the cylindrical filter 12 is formed through the inlet 15. While passing through the filter (12), the foreign substances contained in the air are primarily filtered. The air inside the cylindrical filter 12 is moved to the inside of the fan casing 10B through the opening 12a (see FIG. 3) at the center upper end and then flows into the fan casing 10B in the circumferential direction of the blowing fan 14 Flow.

Here, the filter 12 may be said to have the primary air purifying function in the present invention. Therefore, in the air purification and humidification method according to the present invention, air is primarily filtered using the above-described filter 12, and air purification and humidification proceed in the cyclone body 30. Thus, it is expected that the ability of purifying the air can be sufficiently enhanced by the secondary air purification, and it is expected that it will be able to cope with the filtration of ultrafine dust which has recently been worried about.

The air outlet 16 of the fan casing 10B is formed at an eccentric position on one side. An inlet 35 communicating with the outlet 16 is formed at a position corresponding to the outlet 16 of the upper end of the cyclone body 30. [ Since the inlet 35 of the cyclone body 30 is formed at an eccentric position on one side of the cyclone body 30, the air introduced into the cyclone body 30 through the inlet 35 from the outlet 16, And flows in the circumferential direction inside the cyclone body 30 to form a substantially swirling flow.

That is, in an embodiment of the present invention, a swirling flow is formed inside the cyclone body 30 where air purification and humidification are performed. In this embodiment, airflow generated in the air blowing fan 14 is circulated in the cyclone body 30, Through the inlet (35) at the same position.

Next, a description will now be made of the structure 102 in which water is scattered in the cyclone body 30 described above. Sprinkling water inside the cyclone body 30 may be referred to as a pumping mechanism 40 that rotates inside the cyclone body 30. [ That is, according to the first embodiment of the present invention, the pumping mechanism 40 is one of embodiments for substantially raising and raising the water in the cyclone body 30. Hereinafter, a configuration of the pumping mechanism 40 will be described.

The pumping mechanism 40 is for spraying or spraying water droplets or small water particles into the inside of the cyclone body 30 after lifting the water upward by using centrifugal force by rotation. In order to pump water upwards by centrifugal force in this manner, the horizontal cross section of the pumping mechanism 40 is formed into a ring (cylinder) shape, and the whole is formed into a cylindrical shape, for example, .

5, the pumping mechanism 40 is configured such that the upper end portion and the lower end portion thereof are connected to the cap portion 34 of the cyclone body 30 and the outer portion of the support portion 23, respectively, And is rotatably supported by the shaft 23a. A rotation support shaft 40a formed at the lower end of the pumping mechanism 40 is inserted and supported in a rotation support groove 23d formed on the bottom surface of the water storage portion 23c.

As shown in Fig. 6, a ring-shaped rim 47 is formed at the opened upper end of the pumping mechanism 40, and a plurality of bridges 40c are formed at the rim 47. As shown in Fig. A rotation support shaft 40b is provided at the center of the bridge 40c. The rotation support shaft 40b is inserted into and supported by a rotation support groove 34b (Fig. 5) formed on the bottom surface of the pumping mechanism support portion 34a of the cap portion 34. [ As described above, the construction of the rotation support shaft 40a and the rotation support groove 23d of the lower portion of the pumping mechanism 40 and the structure of the rotation support groove 34b and the rotation support shaft 40b on the upper portion of the pumping mechanism 40 Thus, the pumping mechanism 40 is rotatably supported inside the cyclone body 30.

The support portion 23 is formed with a water supply passage 23b through which the water in the water tank is supplied. The upper portion of the outer portion 23a of the support portion 23 is connected to the support portion 23 through the water supply passage 23b A water storage portion 23c is formed in which the supplied water temporarily stays at a constant water level. Here, water at a certain level is held in the water storage portion 23c, and the lower end portion of the pumping mechanism 40 is kept locked in the water at a predetermined depth.

In the present invention, the pumping mechanism (40) is for raising the water of the water storage portion (23c) upward by the rotation and scattering it inside the cyclone body (30). The pumping mechanism 40 is formed into a cylindrical shape or a cone shape and has an upper end opened to allow air to pass therethrough. In the illustrated embodiment, the pumping mechanism 40 is formed in an inverted conical shape and has a plurality of partial sidewalls 42 and a plurality of open portions 44 formed between the sidewalls. The open portion 44 is preferably formed about the entire height of the pumping mechanism 40.

The reason why the pumping mechanism 40 is formed in an inverted conical shape is that the water is formed so as to be able to move more smoothly to the upper side by using centrifugal force based on rotation, It can be said that the lower part of the body part 32 also corresponds to the inverted conical shape.

A plurality of water guide grooves 46 are vertically formed inside the side wall 42 of the pumping mechanism 40. This water guide groove 46 is for pumping upward the water in the water storage portion 23c by using the centrifugal force when the water is substantially rotated. Therefore, in place of the water guide groove 46 in the illustrated embodiment, it is also possible to replace the water guide groove 46 with a wall having a predetermined height extending in the vertical direction. In this case, As shown in Fig.

The water guide groove 46 may have any shape as long as it can substantially rise upward along the inside of the water guide groove 46. It is obvious that the water guide groove 46 can not be limited to the vertical groove . The side wall 42 and the open portion 44 molded therebetween are formed to have a constant inclination as shown in the drawing. Therefore, the uppermost portion of the water guide groove 46 is opened (opened) along the inclined open portion 44.

Since the water guide groove 46 described above is continuously extended upward with a predetermined distance, the outlet of the water guide groove 46 is formed in the open portion 44. Since the open portion 44 and the side wall 42 are formed in an inclined state having a constant inclination with respect to the vertical direction, the outlet of the water guide groove 46 is formed in the cyclone body 30, . 5, the outlet of the water guide groove 46 has an outlet 46a at the lowest portion of the open portion 44 and an outlet 46z at the highest portion thereof , And a plurality of outlets having a predetermined interval are formed therebetween.

3 and 5, the lower end portion 48 of the pumping mechanism 40 is submerged in the water storage portion 23c and an open portion 48a is formed in the lower end portion 48 At the same time, the above-described water guide groove 46 is formed in the side wall 42. Accordingly, when the pumping mechanism 40 rotates in this state, the water in the water storage portion 23c rises along the water guide groove 46 due to the centrifugal force generated by the rotation.

And the water rising along the water guiding grooves 46 will be ejected or scattered out through the outlets 46a and 46z of the grooves, At this time, since the open portion 44 is formed with a predetermined inclination with respect to the entire height or in the vertical direction and a plurality of the water guide grooves 46 are formed at regular intervals, Over the entire height of the instrument 40, the water will be scattered out through the open portion 44. As described above, since a plurality of the outlets 44a and 44z of the water guide groove 46 formed in the open portion 44 are formed at regular intervals from the lower end portion to the upper end portion, The water may be uniformly scattered with respect to the entire height in the inside of the body 30.

 Thus, the pumping mechanism 40 has a function of uniformly scattering the water in the water storage portion 23c with respect to the entire upper and lower portions of the cyclone body 30 by using the centrifugal force during rotation. In order to scatter water in the water storage portion 23c inside the cyclone body 30, the pumping mechanism 40 must rotate. For example, the pumping mechanism 40 should be configured to rotate by a driving motor (not shown) or to rotate by the same principle as in the embodiment shown in Figs. 3 and 5.

In the illustrated embodiment, the fan casing 10B has an outlet 16 which is eccentric to one side, and an inlet 35 is provided at an upper end of the cyclone body 30 at a position corresponding to the outlet 16, So that the air coming out of the outlet 16 can be introduced into the inlet 35 as described above. As described above, the air introduced into the inlet 35 forms a swirling flow in the inside of the cyclone body 30.

A plurality of blades 43 are formed at the upper end of the pumping mechanism 40 of the present invention, that is, at a position corresponding to the inlet 35. Therefore, the air flow flowing through the inlet 35 is brought into contact with the blade 43, and the pumping mechanism 40 is rotated by the wind pressure. According to the embodiment in which the air flow flowing through the inlet 35 is configured to rotate the pumping mechanism 40 by the force acting on the blade 43, .

That is, one air blowing fan 14 is used to form an air flow directed from the outside to the inside of the filter 12, and the air thus primarily filtered is passed through the outlet 16 of the fan casing 10B To the inlet (35) of the cyclone body (30), thereby rotating the pumping mechanism (40). The rotating pumping mechanism 40 according to the above-described operation principle is configured to rotate the pumping mechanism 40 such that the rotation support shaft 40a and the rotation support groove 23d of the lower portion of the pumping mechanism 40, As described above, is also rotatably supported within the cyclone body 30 by the constitution of the rotation support shaft 34b and the rotation support shaft 40b.

In this embodiment, it can be seen that the upper end of the pumping mechanism 40 is supported by the cyclone body 30, and the lower end thereof is supported by the outer portion 23a of the support portion 23. However, the pumping mechanism 40 is sufficient if the lower end portion 48 is rotatably supported in a state in which the lower end portion 48 is locked in the water storage portion 23c, and it is also possible that the entire pumping mechanism 40 is rotatably supported by the cyclone body 30 Of course.

It can be seen that the pumping mechanism 40 as described above is for rotating the inside of the cyclone body 30 and scattering water. However, in addition to the pumping mechanism 40 as described above, it is natural that various other configurations are possible for the structure for spraying or scattering the water inside the cyclone body 30. [

For example, water in the water tank 20 may be sprayed into the inside of the cyclone body 30. In order to inject water into the inside of the cyclone body 30, it is needless to say that a nozzle and a pump for spraying water are required instead of the pumping mechanism 40 described above. When water is sprayed into the cyclone body 30 as described above and the swirling flow is formed as described above, the sprayed water particles swirl around the inside of the cyclone body 30, And at the same time, the finely vaporized water particles can be supplied to the room through the open central portion outlet 38.

Next, the air purification and gas method of the present invention will be described through the overall operation of the air purifier of the present invention having the above-described configuration.

[Air purification and swirl flow formation in the humidifying container]

When the air cleaner of the present invention is operated, external air flows into the interior of the filter 12 through the filter 12 while the blowing fan 14 operates. The filter 12 for primary filtration of such impurities can be selected to have a desired specification and function. In this case, Of course.

In the embodiment shown in Fig. 1, the filter 12 is formed of a cylindrical filter, and the blowing fan 14 is composed of a centrifugal fan. In the illustrated embodiment, the air that has passed through the filter 12 moves upward through the opening 14a at the center of the filter, and then flows in the circumferential direction. That is, the refrigerant flows into the cyclone body 30 through the outlet 16 at an eccentric position formed in the fan casing 10B.

[Air purifying and scattering or spraying of water into the humidifying container]

An inlet 35 of the cyclone body 30 communicating with the outlet 16 is also formed at an eccentric position. Therefore, the air introduced through the inlet (35) forms a swirling flow inside the cyclone body (30). The air introduced through the inlet 35 is brought into contact with the blade 43 of the pumping mechanism 40 to apply a force, and the pumping mechanism 40 is rotated by the wind pressure.

When the pumping mechanism 40 rotates, the water in the water storage portion 23c flows upwardly along the water guide groove 46 formed in the side wall 42 of the lower end portion 48 of the pumping mechanism 40 by the centrifugal force . The water moving along the water guide grooves 46 is scattered to the outside through the plurality of outlets 46a and 46z of the water guide grooves 46. The outlet of the water guide groove 46 is formed at regular intervals from the lower end portion to the upper end portion. Since the open portion 44 is formed with an inclination, the water can be uniformly scattered outward as a whole. Here, as described above, water in the water tank can be injected into the inside of the cyclone by using a nozzle and a pump in place of the pumping mechanism 40.

As described above, the water scattered inside the cyclone body 30 can be recognized by the user directly through the sight window 36. The fact that the state in which water is scattered can be visually confirmed means that the air purifier of the present invention is practically operative and that a sufficient humidifying effect can be recognized by the user. And the water in the water tank 20 will be continuously replenished to the water storage portion 23c through the guide passage 23b.

[Air purification and humidification]

In such a current state, water is scattered in the cyclone body 30 while the pumping mechanism 40 rotates, and a swirling flow is being formed in the cyclone body 30 have. If the water is scattered toward the swirling flow in a state where the swirling flow is formed inside the cyclone body 30, the water droplets that are scattered are substantially repeatedly exposed to the rotating air. The air introduced through the inlet 35 is circulated repeatedly many times within the cyclone body 30 according to the principle of cyclone and then circulated through the center portion of the open upper portion of the cyclone body 30 And is discharged to the room through the outlet (38).

The fact that the scattered water droplets are exposed to the swirling flow repeated at least a plurality of times substantially means that the contact surface area between the air introduced through the inlet 35 and the water droplets scattered through the pumping mechanism 40 is sufficiently secured do. The fact that the surface area of contact between the water droplets scattered and the air is wide means that the foreign matter contained in the air is substantially trapped in water by the surface tension and the suction force.

And the large contact surface area between the airborne droplet and the air means that the amount of water vaporized by contact with air is substantially increased. As described above, in the present invention, a swirling flow is formed in the inside of the cyclone body, and water droplets are scattered in the swirling flow, whereby the ability to collect foreign matters contained in water is excellent and a state of high humidifying performance can be secured .

The water droplets are scattered and the swirling flow is repeatedly swirled, so that the relatively heavy water particles in the cyclone body 30 sink downwardly as foreign matter, and the relatively light water particles are dispersed in the cyclone body 30, Will be vented indoors (outside) through the open central portion outlet 38 at the top. And it can be said that the discharged air can provide substantially sufficient humidification amount, and it is natural that the foreign matter is purified air sufficiently filtered.

Hereinafter, a configuration of an air cleaner according to a second embodiment of the present invention will be described with reference to FIGS. 7 to 9. FIG. In the following description, the detailed description of the parts overlapping with the above-mentioned first embodiment will be omitted.

7 to 9, the air cleaner of the present embodiment includes a main casing 10 and a cyclone body 50 detachable from the main casing 10. As shown in Fig. The main casing 10 is constituted by a fan casing 10B incorporating a blowing fan and a filter casing 10A incorporating a filter for primarily filtering the air introduced from the outside. Here, the main casing 10 of the present embodiment may have substantially the same configuration as that of the first embodiment described above.

A cyclone body 50 is installed on one side of the main casing 10 and the cyclone body 50 is detachable from the main casing 10. Here, the fact that the cyclone body 50 is attachable to and detachable from the main casing 10 means that substantially the main casing 10 alone can be used as an air cleaner. That is, as in the first embodiment described above, the main casing 10 incorporates a blowing fan and a filter, and can be independently used as an air purifier using only the blowing fan and the filter.

The cyclone body 50 in the present embodiment has a function as a water tank at the same time that a swirling flow is generated therein. That is, the cyclone body 50 is composed of a body portion 52 whose upper surface is open and whose inner surface has a cylindrical shape, and a cap portion 54 which opens and closes the open upper portion of the body portion 52. The body part 52 can hold water to a predetermined level to function as a water tank, and it can be seen that the body part 52 has a cylindrical shape in the illustrated embodiment.

At least a part of the body part 52 is formed of a transparent material so that the user can visually confirm the internal state of the body part 52. The cap portion 54 is formed with an outlet 54a through which a steam can be discharged to the outside. An inlet 55 for receiving wind blowing from the blowing fan 14 built in the fan casing 10B is formed on the upper portion of the body portion 52. [ The inlet 55 may be formed at a position corresponding to the outlet 16 formed in the fan casing 10B and the position and function of the inlet 55 and the outlet 16 may be the same as those of the embodiment same.

A pumping mechanism (40) is rotatably supported inside the cyclone body (50). Here, since the actual configuration of the pumping mechanism 40 is completely the same as that of the first embodiment, a detailed description thereof will be omitted. The pumping mechanism 40 is rotatably supported inside the cyclone body 50. For example, the rotation support shaft 40b at the upper end of the pumping mechanism 40 is supported by three bridges of the cap portion 54, Shaped pumping mechanism support portion 54b. The lower end of the pumping mechanism 40 may be supported on the bottom surface 56 of the cyclone body 50. The rotation support shaft 40a provided at the lower end of the pumping mechanism 40 may be supported on the bottom surface of the pumping mechanism support member 60 supported at a predetermined position inside the cyclone body 50. [

As described above, a part of the lower portion of the pumping mechanism 40 supported by the inside of the cyclone body 50 is supported in a water immersed state. In the present embodiment, the cyclone body 50 itself functions as a water tank, and it is possible to directly supply water through the opened upper end portion. Therefore, water having at least a minimum water level is supplied to the cyclone body 50, and the lower end of the cyclone body 50 is always kept immersed in water.

When the blower fan 14 installed in the fan casing 10B operates to generate airflow for driving the air cleaner, the outlet 16 of the fan casing and the inlet 55 of the cyclone body 50, To the inside of the cyclone body (50). The air flow is made into a swirling flow inside the cyclone body 50. At the same time, the air flow flowing into the inlet 55 is as described above for rotating the pumping mechanism 40.

Since the lower end of the rotating pumping mechanism 40 is submerged in water, the water is scattered into the cyclone body 50 as described above. Since at least a part of the body part 52 is formed as a sight window, the water that is scattered in this way is the same as the first embodiment described above because the user can visually confirm it. The process of humidifying and removing foreign matter while contacting the swirling flow while the water is scattered in the form of particles by the pumping mechanism 40 in the cyclone body 50 is the same as in the first embodiment.

9, the lower end of the pumping mechanism 40 may be supported by a pumping mechanism support member 60 supported within the cyclone body 50. [ The pumping mechanism support member 60 includes a cylindrical body 61 that is formed into a cylindrical shape or a partially inwardly arcuate shape and a plurality of support arms 62 extending outward from the upper end of the cylindrical body 61.

It is preferable that the tubular body 61 has a bottom surface and that the rotary support shaft 40a at the lower end of the pumping mechanism 40 is rotatably inserted in the support groove 62 formed in the bottom surface of the cylindrical body 61 Which is supported by the first embodiment. Here, a plurality of ventilation holes are formed in the lower part or the bottom of the tubular body 61 so that the inside and outside parts can be communicated. The water held in the cyclone body 50 can be introduced into the inside of the tubular body 61 and can be pulled up by the pumping mechanism 40 by forming the lower portion of the tubular body 61 so as to communicate with the inside and outside of the tubular body 61 Will be.

The supporting arms (62) formed at the upper end of the tubular body (61) may be formed into a plurality of the supporting arms (62) so that the lower water can be seen from the upper part of the cyclone body (50). That is, the support arm 62 is also formed as an open part, thereby forming the upper and lower parts of the inside of the cyclone body 50 to communicate with each other. The outer end of the support arm 62 is raised on the support protrusion 59 formed on the inner surface of the cyclone body 50 so that the height of the cyclone body 50 As shown in Fig. It is a matter of course that the lower end of the pumping mechanism 40, in which the lower end is supported by the pumping mechanism support member 60, is supported in a state of being immersed in water.

The tubular member 61 of the pumping mechanism support member 60 may be formed in such a manner as to prevent the water in the cyclone body 50 from being excessively excessively loosened to some extent by the surface tension of the water during the rotation of the pumping mechanism 40 Or for setting the height of the pumping member and supporting the rotation.

Also in the air purifier according to the second embodiment having the above-described configuration, it is possible to prevent the formation of the swirling flow (process 100), the spraying or scattering of water (process 102), and the discharge of humidified air 104) are practically performed at the same time. Each of these processes will be briefly described. When the air flow is introduced through the inlet 55, a swirling flow is formed inside the cyclone container 50.

Also, the water that is maintained at a certain level in the cyclone is scattered upward by the operation of the pumping mechanism 40. The scattering of the water particles will be exposed in the swirling flow and the 104th process as described above will proceed. The air that has been rotated several times while forming a swirl flow will be discharged to the outside through the outlet.

The method of humidification and air purification according to the present invention is focused on the fact that the water particles are substantially scattered in the inner space of the cyclone body so that they are sufficiently exposed in the air. Here, when the water particles are scattered in the inside of the cyclone body, the size of the water particles is practically not limited in the present invention.

As described above, the water particles scattered inside the cyclone body by the pumping mechanism may be said to be relatively large as water drops. In addition, relatively small water particles may be formed and scattered inside the cyclone body. A relatively small water particle may include, for example, spraying water in a spray manner.

According to the spraying of water, relatively small water particles are sprayed compared with the water particles scattered by the pumping mechanism 40, but it is natural that the water particles of the present invention may also include fine water particles . It should be noted that the size of the water particles injected by the diameter of the nozzle or the flow rate during the process of spraying the water can be adjusted to a certain extent and that the present invention does not limit the size of such water particles something to do. It is to be understood that the term " scattering of water " used in the description and claims of the present invention includes the concept of spraying fine water particles.

In the embodiment of the present invention, it can be seen that water is granulated using the rotational force of the pumping mechanism and scattered in the inside of the cyclone body. Here, it is natural that various changes are possible in the embodiment in which, instead of the pumping mechanism, an external force can be applied to the water based on the rotational force and the water particles are scattered inside the cyclone body by the external force.

In the embodiment described above, the water is granulated by the rotational force of the pumping mechanism, but it is apparent that the present invention can not be limited by these embodiments. For example, an external motor can be used to apply an external force to the water, and it is also possible to construct the water particle to be scattered by the external force. In this case, it will be appreciated that various modifications can be made to the components that scatter and disperse the water in the cyclone body based on the rotational force.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept as defined by the appended claims. It is also obvious that it will be done.

10 ..... Main casing
10A ..... filter casing
10B ..... fan casing
12 ..... filter
12a ..... the opening of the filter
14 ..... blowing fan
Exit 16 .....
20 ..... water tank
22 ..... water tank cap
23 ..... support
23a ..... outer portion
23b ..... guide passage
23c ..... the reservoir part
23d ..... rotation support groove
30 ..... Cyclone body
32 ..... body part
34 ..... cap portion
34a ..... pumping mechanism support portion
34b ..... rotation supporting groove
36 ..... sight window
40 ..... pumping mechanism
40a ..... rotation supporting shaft
40b ...... rotation supporting shaft
42 ..... side wall
44 .... open part

Claims (10)

A first filtering process in which air is primarily filtered while passing through a filter by a blowing fan;
The air that has undergone the first filtering process is supplied to the interior of the cyclone body through the inlet provided at an eccentric position above the cyclone body having a cylindrical shape and a predetermined height, A swirl flow generation process that generates swirl flow for the cyclone dust collection method;
A water supply process for splashing water inside the cyclone body in which the swirling flow is formed; And
The water particles being sprayed or scattered in the water supply process are rotated along a swirling flow to filter out foreign substances contained in the air while humidifying the filtered air and discharging the swirling flow;
In the water supply process, the pumping mechanism rotatably supported inside the cyclone body is rotated by the air introduced through the inlet, so that external force is applied to the water inside the cyclone body so that water is scattered inside the cyclone body ;
In the swirl flow forming and discharging process, relatively heavy water particles including foreign matter among the swirl flow formed inside the cyclone body sink downward in the swirling flow inside the cyclone body, and include vaporized water vapor in the swirling flow Wherein the relatively light air ascends at the central portion of the vessel and is discharged to the room through an outlet formed at the upper center of the cyclone body.
The method according to claim 1,
Wherein the swirl flow generation process and the water supply process are simultaneously performed.
delete delete delete delete 3. The method according to claim 1 or 2,
The pumping mechanism includes a plurality of sidewalls having a horizontal cross section corresponding to a cylindrical shape and having a constant height, a plurality of grooves arranged in the vertical direction on the inner side thereof and having a predetermined inclination with respect to the vertical direction, And having a rim portion connecting the upper end of the side wall in a circular shape;
Wherein the rotation of the pumping mechanism is accomplished by pressurizing the plurality of blades formed in the rim portion of the air introduced through the inlet of the cyclone body;
Wherein the water is moved upward along the groove while the pumping mechanism rotates, and then is scattered to the outside through the open portion.
delete The air cleaning and humidifying method according to claim 1 or 2, wherein the cyclone body is provided with a sight window through which the cyclone body can be seen.



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