KR20220106293A - Indoor oxygen generator with air cleaning function - Google Patents

Abstract

The present invention relates to an indoor oxygen generator with an air purification function, which comprises: an inner case (210) which is formed by being divided to have a plurality of spaces communicating with each other; a mounting case (220) which is arranged in a first chamber of the inner case (210); a first duct unit (230) which is coupled to the lower portion of the mounting case (220); an air compression unit (240) which is provided on the inside of the mounting case (220); a second duct unit (260) which is coupled to the bottom surface of a third chamber of the inner case (210); a filter unit (270) which is provided to be spaced apart from the second duct unit (260); a ventilating unit (280) which is provided to be spaced apart from the filter unit (270); and an oxygen generating unit (290) which is arranged at the second chamber of the inner case (210). Therefore, the clean indoor air may be maintained, and clean oxygen may be supplied. Furthermore, the problems of noise and heat generation during the air suction and discharge and the driving of the air compressor may be resolved at the same time. In addition, the durability of zeolite may be increased.

Description

Indoor oxygen generator with air cleaning function

The present invention relates to an indoor oxygen generator having an air purifying function, and more particularly, it is disposed indoors to remove harmful substances by inhaling polluted air, and at the same time supplies air from which harmful substances are removed to an oxygen generator and a room. Thus, it is possible to supply clean oxygen together with clean air, and it relates to an indoor oxygen generator having an air purification function that prevents noise and vibration, reduces heat generation, and offsets generated heat.

With industrialization, air quality contains a lot of components that are harmful to the human body. In particular, in recent years, not only harmful gases, but also respiratory diseases and skin diseases have occurred due to fine dust. In general, when pollutants distributed in space, that is, materials to be removed, are classified by size, the size of dust particles is several to tens of μm, fine dust is 0.3 μm, fungi are about 5 μm, bacteria are 0.5 to 10 μm, and viruses flow is 0.1 μm or less.

Accordingly, modern people need a pleasant and clean environment, and various air conditioning devices, ie, oxygen generators or air purifiers, are being researched and developed to make the room comfortable.

The oxygen generator is a device that sucks in outdoor air using a compressor and passes the sucked air through an oxygen separation filter such as a PSA filter, UFL filter, and membrane filter to generate high concentration of oxygen. is in the form

Among them, the PSA filter uses an oxygen concentrating device using pressure swing adsorption. Because it uses only compressed air and an adsorbent, it does not emit pollutants and is easy to use, and has been widely used for medical and household oxygen generators for a long time.

The principle of pressure circulation adsorption is to separate and concentrate oxygen by using the difference in the adsorption amount of oxygen adsorbed to the adsorbent according to the pressure in the two adsorption beds. Nitrogen, which occupies a large amount in the air, is adsorbed, and compressed oxygen remaining unadsorbed is sent to an oxygen cylinder to be stored separately. Here, zeolite is usually used as the adsorbent, because nitrogen, which is about 80% of the atmosphere, is better adsorbed to the zeolite than oxygen.

However, the conventional oxygen generator has a problem in arranging it indoors due to noise and heat generated by the compressor during air intake/discharge, and the compressed air in the air compressor is transferred to zeolite at a high temperature due to the heat generated during compression. Air has a problem that inhibits the adsorption capacity of zeolite, noise problems caused by the operation of the air compressor, and the oxygen generator installed outside is just passing through a simple filter without the step of filtering the air sucked into the oxygen generator. There is a problem of supplying oxygen in a state where it is not known which harmful substances are included.

In addition, the air purifier is a device for removing mold, bacteria, fine dust, etc. contained in indoor air, and most of the air purifiers include an air purifying sterilizer including an electric ionizer or a plurality of air filters including an antibacterial filter.

However, in the case of an air cleaning sterilizer including an electric ionizer, ozone is directly used to sterilize the space during the air cleaning process, so the sterilization power is good, but ozone emitted into the indoor space may adversely affect the human body. is being raised

In addition, among conventional air purifiers, there is a method of sterilizing within the movement path of the air by sucking air into the device without directly emitting ozone harmful to the human body into the indoor space. has a disadvantage in that the sterilization effect on the indoor air is lowered due to the large size of the air conditioner, a separate catalyst filter is required to remove residual ozone after air purification inside the device, and the catalytic filter has a relatively short lifespan. .

Moreover, since the air purifier is used in a state in which external air is blocked, that is, a window or a door is closed, there is a problem in that consumers feel stuffy due to lack of oxygen.

In addition, there is a problem in that the economic burden is aggravated in the use of separately sold oxygen generators and air purifiers.

Accordingly, the applicant of the present applicant has researched repeatedly to solve this problem, and after repeated research, an indoor oxygen generator with an air purifying function that is placed indoors, but does not cause noise and heat generation, to keep indoor air clean and to supply clean oxygen. have been developed

A first object of the present invention is to provide an indoor oxygen generator, which is arranged indoors and has an air purifying function capable of keeping indoor air clean and supplying clean oxygen at the same time.

In addition, a second object of the present invention is to provide an indoor oxygen generator having almost no noise during air intake/discharge, and having an air purifying function that has no problem in being disposed indoors by solving the pulsating noise caused by driving the air compressor. .

In addition, a third object of the present invention is to simultaneously solve the problem of heat generation caused by the driving of the air compressor, and not only to discharge the heat generated by the air compressor to the outside, but also to transport compressed air of an appropriate temperature from the air compressor to the zeolite An object of the present invention is to provide an indoor oxygen generator having an air purifying function that can increase the durability of zeolite.

An indoor oxygen generator having an air purifying function according to the present invention for achieving this technical problem,

an inner case 210 that is partitioned and formed to have a plurality of spaces communicating with each other;

a seating case 220 disposed in the first chamber of the inner case 210;

a first duct portion 230 coupled to a lower portion of the seating case 220;

an air compression unit 240 provided in the seating case 220;

a second duct part 260 coupled to the bottom surface of the third chamber of the inner case 210;

a filter unit 270 provided to be spaced apart from the second duct unit 260;

a ventilation unit 280 provided to be spaced apart from the filter unit 270; and

and an oxygen generating unit 290 disposed in the second chamber of the inner case 210 .

In addition, in the air purifier combined with an oxygen generator according to the present invention,

The inner case 210 has a bottom surface 211, a side surface 212, an upper surface 213, a horizontal partitioning surface 214 that divides the inner case up and down in a downward direction from the top surface, a horizontal partitioning surface It is composed of a vertical partition surface 215 that divides the divided lower part of the inner case back and forth from the bottom surface,

The first and second rooms formed by the bottom surface 211, the horizontal partitioning surface 214 and the vertical partitioning surface 215, and the third chamber formed by the upper surface 213 and the horizontal partitioning surface 214 are partitioned characterized by being

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The floor surface 211 is divided into a first floor surface 211-1 included in the first chamber and a second floor surface 211-2 included in the second chamber by the vertical partition surface 215, , characterized in that the second bottom surface (211-2) is provided with an air inlet hole (211-2a).

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The side surface 212 is characterized in that an inlet (212a) through which the filter is input and discharged is formed.

In addition, in the air purifier combined with an oxygen generator according to the present invention,

The horizontal partition surface 214 is divided into a first partition surface 214-1 and a second partition surface 214-2, and the first partition surface 214-1 has a first air distribution hole 214- 1a) is formed, and a second air distribution hole 214-2a is formed in the second partition surface 214-2.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

A third air distribution hole (215a) is formed at a predetermined position on the lower side of the vertical partition surface (215).

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The seating case 220 includes a bottom surface 221 on which a fourth air distribution hole 221a is formed, a side surface 222, an upper surface 223 on which a fifth air distribution hole 223a is formed, and the upper surface. It is characterized in that it is composed of a first wall border 224 formed to the outside of the 223 with a predetermined height.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

A first fan f1 is attached to the fourth air distribution hole 221a of the bottom surface 221 .

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

At least two fifth air distribution holes 223a of the upper surface 223 are provided to be spaced apart from each other.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The inner surface of the seating case 220 is characterized in that the noise and vibration prevention material is further provided.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The noise-vibration prevention material is composed of a vibration-proof material, a sound-absorbing material and a reflective refractive plate having innumerable perforated holes, or is composed of a sound-absorbing material and a reflective refractive plate having innumerable perforated holes, or is composed only of a reflective refractive plate having innumerable perforated holes. characterized by being

In addition, in the air purifier combined with an oxygen generator according to the present invention,

The first duct part 230 includes a separation plate 231 having a sixth air distribution hole 231a formed therein; a second wall border 232 formed at a predetermined height to form a space in the upper portion of the separation plate 231; and a third wall border 233 formed at a predetermined height to form a space under the separation plate 231 and having a seventh air distribution hole 235 formed therein.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

Both ends of the seventh air circulation hole 235 of the third wall border 233 are further provided with inlet guides 234 formed by bending toward the inside,

The seventh air distribution hole 235 is provided to communicate with the second chamber of the inner case 210 .

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The air compression unit 240 is fixed through a spring (S) in the seating case 220, and is a heat reducing means 242 that is closely coupled to the air compressor 241 and the upper portion of the air compressor 241. characterized in that it is composed.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The heat reduction means 242 has a heat sink 242a having a heat radiation fin disposed therein, and compressed nitrogen passing through is connected to the nitrogen discharge pipe of the oxygen generating unit 290 to take heat from the heat radiation fins It is characterized in that it is configured to be discharged to.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The oxygen generator combined air purifier further includes a silencer (250),

The silencer 250 includes a case 251 having a first room and a second room separated by a partition wall, and an intake part 252 and an exhaust part 253 disposed in the first room and the second room, respectively. It is characterized in that it is configured to include a noise reduction means.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The intake part 252 of the noise reduction means is composed of an intake pipe and a sound absorption pipe of a predetermined length disposed inside the intake pipe and having a plurality of through holes formed on the side surface, and the exhaust part 253 is an exhaust pipe and an exhaust pipe It is arranged in the interior and characterized in that it is composed of a sound-absorbing tube of a predetermined length formed with a plurality of through-holes on the side.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The second duct part 260 may include an upper surface 261 having an eighth air distribution hole 261-1a and a ninth air distribution hole 261-2a formed thereon; a fourth wall border 262 formed at a predetermined height to form a space under the upper surface 261; and a second compartment including a first compartment (D) including an eighth air distribution hole (261-1a) and a ninth air distribution hole (261-2a) in the space formed by the fourth wall border 262 ( It is characterized in that it is constituted by a shielding wall surface (263) dividing it into two parts (E).

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

A second fan f2 is selectively attached to the lower portion of the eighth air distribution hole 261-1a.

In addition, in the air purifier combined with an oxygen generator according to the present invention,

The filter unit 270 is characterized in that a plurality of separate filters are bundled into one frame, or a plurality of separate filters are fused into one to form one filter.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The ventilation unit 280 includes a third fan f3, a fan holder plate 281 on which the third fan f3 is seated, a side part 282 having a discharge port 282a on one surface, and an upper plate ( 283).

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The fan mounting plate 281 is provided with a coupling hole in the central portion of which the third fan f3 is seated and fixed, and a plurality of ventilation holes are provided,

The side portion 282 is provided with a flow guide film 284 having a predetermined curvature with the third fan f3 as a central point therein, and the air sucked from the lower portion of the third fan f3 rotates. It is characterized in that it turns in the centrifugal force direction along the circumference of the third fan f3 by the blades of the third fan f3 and is discharged through the outlet 282a.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The oxygen generating unit 290,

A first adsorption unit 291 , an oxygen reservoir 292 , and a second adsorption unit 293 are arranged and provided, and the first adsorption unit 291 , the oxygen reservoir 292 , and the second adsorption unit 293 are The upper cover assembly 294 provided to seal them, respectively, is coupled to the upper portion, and the lower cover assembly 295 provided to seal them, respectively, is also coupled to the lower portion,

The lower cover assembly 295 is coupled to the solenoid part 296, and the solenoid part 296 is coupled to the branch chamber.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The indoor oxygen generator having the acid air purification function further includes a control unit 400,

The control unit 400, the air compression unit 240, the ventilation unit 280, the oxygen generator 290 and the first fan (f1), the second fan (f2), the third fan (f3) to control the characterized in that

In addition, the indoor oxygen generator having an air purifying function according to the present invention,

an inner case 210 that is partitioned and formed to have a plurality of spaces communicating with each other;

a first duct part 230 and an air compression part 240 disposed in the first chamber of the inner case 210;

a second duct unit 260, a filter unit 270, and a ventilation unit unit 280 sequentially disposed in the third chamber of the inner case 210; and

and an oxygen generating unit 290 disposed in the second chamber of the inner case 210 .

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The inner surface of the inner case 210 is characterized in that the noise and vibration prevention material is further provided.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The air compression unit 240 is characterized in that it is composed of an air compressor 241 and a heat reducing means 242 that is closely coupled to the upper portion of the air compressor 241.

In addition, in the air purifier combined with an oxygen generator according to the present invention,

The oxygen generator combined air purifier further includes a control unit 400,

The control unit 400 is characterized in that it controls the air compression unit 240, the ventilation unit 280, the oxygen generator 290 and the fan driving.

In addition, the indoor oxygen generator having an air purifying function according to the present invention,

An oxygen generator combined air purifier comprising an oxygen generator and an air purifier,

an inner case partitioned to have a plurality of spaces communicating with each other;

an air compression unit disposed in the inner case and having a heat reducing means; and

and a silencer connected to the air compression unit and provided with a noise reduction means.

In addition, the air purifier combined with an oxygen generator according to the present invention,

In the indoor oxygen generator having an air purification function comprising an oxygen generator and an air purifier,

an air compression unit having a heat reducing means; and

and a silencer connected to the air compression unit and provided with a noise reduction means.

In addition, in the indoor oxygen generator having an air purifying function according to the present invention,

The indoor oxygen generator having the air purifying function,

It is characterized in that the refraction rod is further provided with innumerable perforated holes in the air inlet and air outlet pipes connected to the air compression unit.

The indoor oxygen generator having an air purifying function according to the present invention has the effect of being disposed indoors to keep indoor air clean and to supply clean oxygen at the same time.

In addition, the indoor oxygen generator having an air purifying function according to the present invention has almost no noise during air intake/discharge, and has the effect of simultaneously solving the problem of pulsating noise and heat generation caused by the operation of the air compressor.

In addition, the indoor oxygen generator having an air cleaning function according to the present invention not only discharges the heat of the compressed air compressed by the air compressor to the outside, but also supplies the compressed air of an appropriate temperature from the air compressor to the zeolite, so that the zeolite It has the effect of increasing the durability of

1 is an external perspective view of an indoor oxygen generator having an air purifying function according to an embodiment of the present invention;
2 is an exploded perspective view showing a coupling relationship between an outer case and an internal device of an indoor oxygen generator having an air purifying function according to an embodiment of the present invention;
3 is an exploded perspective view of all components of an inner case of an indoor oxygen generator having an air purification function according to an embodiment of the present invention;
Figure 4 is a perspective view showing the structure of only the inner case in Figure 3,
5 is an exploded perspective view showing the coupling relationship between the seating case, the air compressor and the silencer in FIG. 3;
6 is an exploded perspective view showing the coupling relationship between the seating case and the first duct part in FIG. 3;
7 (a) and (b) are views showing the schematic structure of the silencer in FIG. 3;
8 is a view showing a schematic structure of the second duct part in FIG. 3;
9 (a), (b) is a view showing the schematic structure of the filter unit and the ventilation unit in FIG. 3,
10 is a view showing a flow state in which air sequentially flows through the second duct part, the filter part, and the ventilation unit part in FIG. 3;
11 (a) and (b) are schematic cross-sectional views of the interior from one side and the other side showing the coupling relationship between all the components of the inner case of the indoor oxygen generator having an air purifying function according to an embodiment of the present invention;
12 is an embodiment of a sound-absorbing and vibration-proof plate used inside an indoor oxygen generator having an air purifying function according to an embodiment of the present invention.
13 is a detailed structural diagram of an air inlet and outlet pipe used in an indoor oxygen generator having an air purifying function according to an embodiment of the present invention.

The specific features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Prior to this, the terms or words used in the present specification and claims are based on the technical idea of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to best describe his invention. It should be interpreted as a corresponding meaning and concept. In addition, it should be noted that, when it is determined that a detailed description of a known function and its configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof is omitted.

As shown in FIGS. 1 to 13 , the indoor oxygen generator 1 having an air purifying function according to an embodiment of the present invention includes an outer case 100 , an inner device 200 , and a seating plate 300 . can be composed of Here, of course, the outer case 100 and the seating plate 300 may be selectively installed.

The outer case 100 has a tubular shape with an open lower portion, an operation unit 110 and a plurality of air discharge holes h1 are formed on an upper surface thereof, and an openable and openable door 120 is formed on one side thereof. In this case, the door 120 may be formed as a whole or only a part of one side, and a handle may be provided to facilitate opening and closing.

The operation unit 110 may include an individual or simultaneous selection function of an oxygen generator and an air purifier, an air/oxygen amount discharge control function, an operation on/off function, an indoor oxygen amount/noxious gas amount notification function, and the like.

In the present invention, the entire right side of the outer case 100 is formed as a door, but the present invention is not limited thereto, and a separate door can be formed only on a necessary portion of one side.

The open lower portion of the outer case 100 may be fixedly coupled to the side edge of the seating plate 300 having wheels formed on the bottom surface.

Here, the seating plate 300 is a case plate having side edges of a predetermined height formed by bending upward from the bottom surface and having an open top surface, and a plurality of air intake holes 300a may be formed on the bottom surface of the seating plate. And, the side edge of the seating plate may be fastened with the lower edge of the outer case.

Of course, the outer case 100 and the seating plate 300 may be selectively installed, and the manipulation unit provided in the outer case may be provided in the inner case of the inner device.

The internal device 200 includes an inner case 210 , a seating case 220 , a first duct unit 230 , an air compression unit 240 , a silencer 250 , a second duct unit 260 , and a filter unit ( 270 ), a ventilation unit 280 , an oxygen generator 290 , and a control unit 295 .

The inner case 210 is partitioned and formed to have a plurality of spaces communicating with each other, and the inner case is vertically moved from the bottom surface 211, the side surface 212, the upper surface 213, and the upper surface downward. It is composed of a horizontal partitioning surface 214 that partitions, and a vertical partitioning surface 215 that partitions the divided lower part of the inner case back and forth from the horizontal partitioning surface to the bottom, a bottom surface 211 and a horizontal partitioning surface 214 and a first chamber (A) and a second chamber (B) formed by a vertical partition surface 215 and a third chamber (C) formed by an upper surface 213 and a horizontal partition surface 214. have.

Here, the floor surface 211 is a first floor surface 211-1 included in the first room (A) and a second floor surface (211-2) included in the second room (B) by a vertical partition surface. , and an air inlet hole 211-2a is provided at a predetermined position on the second bottom surface.

An inlet 212a is formed in the side surface 212 in the horizontal direction at a predetermined position on the upper side of any one side surface. A side door is provided at the inlet 212a to enable input and discharge of the filter unit 270 through the side door. At this time, the shape of the side door may be provided to fit the shape of the inlet, and one side of the side door is connected to the side surface 212 by a hinge to be able to open and close, and the other side corresponding to it may be connected with a locking device.

A plurality of air discharge holes h2 are formed on the upper surface 213 . Of course, the air discharge hole (h2) may be formed on the upper side of the side surface (212).

In addition, the horizontal partition surface 214 is installed to be spaced apart from the upper surface by a certain distance in the downward direction to divide the inner case up and down, and is divided into a first partition surface and a second partition surface by a vertical partition surface to be described later. . A first air distribution hole (214-1a) having a large diameter is formed in the first partition surface (214-1) of the horizontal partition surface (214), and a second rectangular air distribution hole in the second partition surface (214-2) (214-2a) is formed.

The vertical partitioning surface 215 is installed from the horizontal partitioning surface to the floor to divide the lower part of the inner case divided by the horizontal partitioning surface into a first chamber (A) and a second chamber (B). A rectangular third air distribution hole 215a is formed at a predetermined position on the lower side of the vertical partition surface 215, and a plurality of through holes through which the air flow tube L passes may be provided.

In the present invention, the bottom surface, the side surface, the upper surface, the horizontal partition surface and the vertical partition surface of the inner case 210 are described as being integrally formed, but the present invention is not limited thereto. Of course, it can be provided individually in a form that can be assembled by

In addition, in the present invention, the inner case 210 is configured to be provided with a first chamber, a second chamber, and a third chamber thereon, but the present invention is not limited thereto.

In addition, the size and shape of the first air distribution hole 214-1a, the second air distribution hole 214-2a, and the third air distribution hole 215a illustrated in the present invention are the second bottom surface 211- 2), the air introduced through the air inlet hole 211-2a moves upward through the second air distribution hole 214-2a through the second chamber B, and at the same time as the vertical partition surface 215 A size capable of smooth air circulation so that it flows into the seating case 220 of the first chamber A through the third air distribution hole 215a and then moves upward through the first air distribution hole 214-1a It is configured in the form of, of course, it is not limited to the illustrated one and can be transformed into various dimensions, shapes and forms having a size that allows such smooth air circulation.

The seating case 220 is disposed in the first chamber (A) of the inner case 210, and provides a space to the outside of the bottom surface 221, the side surface 222, the upper surface 223, and the upper surface. It may be composed of a first wall border 224 having a predetermined height formed to form.

The bottom surface 221 has a fourth air distribution hole 221a formed at a central position, and a first fan f1 is attached to the lower portion of the fourth air distribution hole 221a.

Here, the first fan (f1) is installed auxiliary to ensure smooth air flow from the third air distribution hole (215a) of the vertical partition surface (215) to the inside of the seating case, the second fan (f2) and They can be installed together or selectively.

In addition, a fifth air distribution hole 223a is formed in the space formed by the first wall frame 224 on the upper surface 223 . At this time, it is preferable that at least two of the fifth air distribution holes 223a have a predetermined size and are provided adjacent to the left and right edges by being spaced apart from each other. This allows the air inside the seating case to be moved upward through the two fifth air distribution holes provided to be spaced apart, so that the air inside the seating case can flow smoothly without accumulating in any one region of the interior.

Here, the upper surface of the first wall border 224 is installed to be in close contact with the lower surface of the first partition surface 214-1 of the horizontal partition surface 214 to prevent the flowing air and internal noise from being discharged to the outside. do.

A noise and vibration prevention material may be further provided on the inner surface of the seating case 220 and/or the inner surface of the inner case 210 . As shown in FIG. 11, the anti-vibration material includes a vibration-proof material 11 that absorbs and prevents vibration as shown in FIG. 11, a sound-absorbing material 12 that absorbs noise to prevent noise diffusion, and a reflective refraction plate provided with countless perforated holes 13a ( 13), a reflective refraction plate 13 provided with an anti-vibration material for inhaling and preventing vibrations and innumerable perforated holes 13a, or a reflective refraction plate 13 having innumerable perforated holes 13a. ) can be formed only by

Here, by the innumerable perforated holes 13a formed in the reflective refractive plate 13 provided on the inner surface of the seating case 220 and/or the inner surface of the inner case 210 , it is disposed inside the seating case 220 . The noise waves and pulsating noises flowing out of the compressed air compressor are diffracted, dispersed, and reflected in each through hole, and the scattered noise waves interfere and cancel each other, thereby reducing the noise and also canceling it in connection with the waves of the flowing air. By maximizing the effect, it is possible to reduce the noise.

The first duct part 230 is an air flow path having a structure that is closely coupled to the bottom surface of the seating case 220 so that air is introduced into the seating case and at the same time prevents the outflow of internal noise. It may be composed of a plate 231 , a second wall border 232 formed to a predetermined height to form a space above the separator plate, and a third wall border 233 formed to a predetermined height to form a space below the separator plate.

The separation plate 231 is provided with a sixth air distribution hole 231a at a predetermined position. At this time, it is preferable that the sixth air distribution hole 231a has a predetermined size, and at least two are spaced apart from each other and provided on the left and right sides.

The second wall border 232 has a predetermined height to form a space in which air flows in the upper portion of the separation plate 231 and is formed to include the sixth air distribution hole 231a of the separation plate in the space.

The third wall border 233 has a predetermined height to form a space in which air flows in the lower portion of the separation plate 231 , and is positioned to correspond to the third air distribution hole 215a of the vertical partition surface 215 . A seventh air distribution hole 235 may be formed on one surface to be used.

At this time, both ends of the seventh air distribution hole 235 of the third wall border 233 may be further provided with an inlet guide 234 having a length of a predetermined dimension formed by bending toward the inside of the space. The inlet guide 234 guides the air flowing in from the second chamber B through the third air distribution hole 215a to be introduced to the inside, and at the same time prevents and reflects the diffusion of the exhaust noise and pulsating noise emitted from the inside. It acts as a barrier film to prevent noise from being emitted through the seventh air distribution hole 235 .

According to the structure of the first duct portion 230 as described above, the air introduced through the third air distribution hole 215a of the vertical partition surface 215 is the seventh air distribution hole 235 of the third wall border 233 . ) and the air introduced through the seventh air distribution hole 235 passes through the sixth air distribution hole 231a of the separating plate 231 and the fourth air distribution hole in which the first fan f1 is located. It flows into the inside of the seating case 220 through (221a).

Here, the structure of the first duct part 230 is a structure that not only allows the incoming air to flow smoothly inside, but also prevents internal noise from being emitted to the outside.

The air compression unit 240 is fixed through a spring (S) on the inner upper portion of the seating case 220, and consists of an air compressor 241 and a heat reducing means 242 that is closely coupled to the upper portion of the air compressor. .

Here, the air compressor 3241 compresses the air sucked through the air intake pipe (L1), and then sequentially releases the compressed air through the air discharge pipe (L2) through the copper pipe (R), the pipe (L3), the o pipe ( L4) to the oxygen generating unit 290, driving noise, pulsating noise, intake noise and exhaust noise are generated in the air compression process, and the temperature of the air compressor rises by compression driving and heat is generated, and compression The temperature of the air discharged by heat is high.

The heat reducing means 242 is closely coupled to the upper part of the air compressor 241 to take heat away from the air compressor and discharged to the outside, and a heat sink having a heat dissipation fin is disposed therein, and an oxygen generating unit 290 It is connected to the nitrogen discharge pipe (L5) of

Compressed nitrogen discharged from the oxygen generating unit 290 is introduced into the inside of the heat reducing means 242 through the pipe (L6) through the nitrogen discharge pipe (L5), the temperature is further lowered by adiabatic expansion, the temperature is lowered After the compressed nitrogen penetrates the inside and takes heat away from the heat dissipation fin, it is discharged to the outside through the discharge pipe L9 through the pipe L7 and the pipe L8. At this time, since the heat dissipation fins whose temperature is lowered by depriving of heat continue to absorb heat from the air compressor, the temperature of the driven air compressor 241 does not rise above a certain temperature and is efficiently cooled.

The silencer 250 includes a case 251 having a first room and a second room separated by a partition wall, and an intake part 252 and an exhaust part 253 arranged in the first room and the second room, respectively. It consists of a reduction means.

The case 251 has a hollow cylindrical shape, and the inside of the case is divided into a first room and a second room having a predetermined size by forming a partition wall in the longitudinal direction of the case, and the first room and the second room are provided to communicate at the rear end do. Here, the partition wall is formed so that the first room and the second room communicate with each other so that the flow rate of air intake from the intake part 252 disposed in the first room is passed through the exhaust part 253 disposed in the second room to the air compressor (241). in order to be able to enter

The intake part 252 of the noise reduction means is composed of an intake pipe and a sound absorption pipe of a predetermined length which is disposed inside the intake pipe and has a plurality of through holes formed on the side surface, and the exhaust part 253 is, the exhaust pipe and the interior of the exhaust pipe It is arranged on the side and consists of a sound-absorbing tube of a predetermined length formed with a plurality of through-holes.

Here, by the plurality of through-holes formed on the side surface of the sound-absorbing tube, a vortex phenomenon occurs in the air flow flowing through the tube in each through-hole portion of the inner surface of the sound-absorbing tube, and the vortex flows to the outer edge surface of the main air flow. By creating a countercurrent flow, it is possible to reduce the noise generated from the incoming or outgoing air flow by canceling the colliding air waves. Moreover, a plurality of through-holes formed on the side surface of the sound-absorbing tube diffract and disperse noise waves and pulsating noises flowing out from the mechanical device in each through-hole to reduce noise in connection with flowing air.

The silencer according to the present invention having such a configuration is connected to the air intake pipe of the air compressor and does not affect the flow rate of air sucked into the air compressor. This is because the noise discharged from the air compressor and introduced into the exhaust unit 253 of the silencer is canceled by the structure of the noise reduction means of the silencer and the structural connection with the structure of the first and second rooms of the case. .

The second duct part 260 is closely coupled to the upper portion of the horizontal partition surface 214 of the third chamber (C) of the inner case 210, and from the seating case 220 and the second chamber (B) toward the upper filter. As an air flow path having a structure for circulating air, a space consisting of an upper surface 261 and a fourth wall border 262 and a fourth wall border 262 formed at a predetermined height to form a space under the upper surface A shielding wall surface 263 that divides and divides it into a first compartment (D) including the eighth air distribution hole (261-1a) and a second compartment (E) including the ninth air distribution hole (261-2a) can be composed of

The upper surface 261 corresponds to the shielding wall surface 263 and is divided into a first upper partition surface 261-1 and a second upper partition surface 261-2, and the first upper partition surface 261-1 has An eighth air distribution hole 261-1a having a large diameter is formed, and a ninth air distribution hole 261-2a is formed in the second upper partition surface 261-2.

A second fan f2 may be attached to the lower portion of the eighth air distribution hole 261-1a. Here, the second fan (f2) is installed as an auxiliary in order to smoothly flow air from the third air distribution hole (215a) of the vertical partition surface (215) to the inside of the seating case, the first fan (f1) and They can be installed together or selectively.

Here, the lower portions of the fourth wall border 262 and the shielding wall surface 263 are installed so as to be in close contact with the upper surface of the horizontal partition surface 214 and flow from the seating case 220 of the first chamber (A) of the inner case. The air passes through the first air distribution hole (214-1a) of the horizontal partition surface (214), passes through the first partition (C), and then passes through the eighth air distribution hole (261-1a) to the upper side of the upper surface, , the air flowing upward through the second chamber (B) of the inner case passes through the second air distribution hole (214-2a) of the horizontal partition surface (214), passes through the second partition (D), and then the ninth air It passes through the distribution hole 261-2a to the upper side of the upper surface.

The structure of the second duct unit 260 facilitates the flow of air, and at the same time, the air that has passed through the seating case and the second chamber passes through the filter unit while mixing and mixing at the upper side of the second duct unit. It does not disturb the flow of air and prevents internal noise from being discharged to the outside.

Likewise, the eighth air distribution hole and the ninth air distribution hole illustrated in the present invention are configured in a size and shape that allows smooth air circulation to move upward through this, and is not limited to the illustrated one, but such a smooth air Of course, it can be transformed into various sizes, shapes, and shapes having a size that can be distributed.

The filter unit 270 may be formed by bundling a plurality of separate filters into one frame, or by fusion-bonding a plurality of separate filters into one filter.

The filter used in the filter unit 270 includes a pre-filter in the form of a mesh or non-woven fabric, a functional filter capable of collecting dust of 1 μm or more and having antibacterial and anti-viral functions, a deodorizing filter made of activated carbon and catalyst, and a 0.3 μm filter. A HEPA filter that can remove fine dust, a sterilization filter with 100% natural terpene applied, etc., can be used in combination with filters selected as needed.

Also, it goes without saying that various types of filter input auxiliary devices can be added so that the filter can be smoothly inserted and discharged and fixed without moving in the vertical direction after input.

In addition, in the present invention, a side door is configured in the inner case for input and discharge of the filter unit, but the present invention is not limited to such a form, and the filter unit mounting device itself may be provided to constitute a part of the inner case.

The ventilation unit 280 is provided with a third fan f3 having a predetermined capacity and disposed parallel to the upper surface of the filter unit 270 and spaced apart by a predetermined distance, the third fan f3, the third fan It may be composed of a fan mounting plate 281 on which (f3) is seated, a side portion 282 having a discharge port 282a on one side thereof, and an upper plate 283 .

The third fan f3 is a fan having a predetermined capacity, and is preferably a turbo fan in consideration of the suction force and noise passing through the filter, but is not limited thereto.

The fan mounting plate 281 has a coupling hole formed in the central part so that the third fan f3 is seated and fixed, and a plurality of ventilation holes are provided so that the third fan f3 can suck air from the bottom. .

In addition, the side portion 282 is provided to have a dimension approximately equal to or slightly larger than the height of the third fan f3 along the edge of the fan holder plate 281 , and a discharge port 282a formed on any one surface of the side portion 282 . ) is formed with a predetermined dimension at a position where external air does not flow through the outlet, and a flow guide film 284 having a predetermined curvature with the third fan f3 as a central point is provided inside. Of course, the side portion may be omitted in the portion where the flow guide film is formed.

Here, the flow guide membrane 284 rotates in the centrifugal direction along the circumference of the third fan f3 by the blades of the third fan f3 in which the air sucked from the lower part of the third fan f3 rotates in the direction of the side part ( This is to facilitate the discharge through the discharge port 282a formed in the 282).

In addition, the shape of the ventilation unit 280 illustrated in the present invention is such that the air sucked into the third fan f3 can be supplied only from the lower part of the third fan f3, This is to guide the efficient and smooth flow of air. Through the ventilation unit 280, the indoor air is sucked into the seating case 220 in which the air compression unit 240 of the first room (A) is installed, and at the same time is sucked into the second room (B), and the sucked air are respectively transferred to the filter unit through the second duct unit 260, filtered through the filter, and discharged through the discharge port 282a.

The oxygen generating unit 290 is for adsorbing a gas such as concentrated nitrogen from the transferred compressed air and discharging the concentrated oxygen, the first adsorption unit 291 and the oxygen storage tank 292, and the second adsorption unit 293 are arranged, and the upper cover assembly 294 provided to seal them is coupled to the upper portions of the first adsorption unit 291 and the oxygen storage tank 292 , and the second adsorption unit 293 , and , a lower cover assembly 295 provided to seal them, respectively, is also coupled to the lower part, the upper cover assembly 294 is coupled to the solenoid part 296, and the solenoid part 296 is coupled to the branch chamber. is the form The upper cover assembly 294 and the lower cover assembly 295 may be fixed to each other by tightening a connection bolt, and the oxygen generating unit 290 may be fixedly installed in the second chamber B of the inner case 210 . .

Here, the first adsorption unit 291 , the oxygen storage tank 292 , and the second adsorption unit 293 have a hollow cylindrical shape, and the adsorbent is disposed inside the first adsorption unit 291 and the second adsorption unit 293 . Phosphorus zeolite is provided, and a nonwoven fabric and a perforated plate are disposed at the upper and lower ends of the adsorbent in order to prevent the adsorbent from leaving, and a spring is provided therein to embed the adsorbent.

The oxygen discharge path of the oxygen storage tank 292 may further include a discharge amount adjusting means such as a pressure regulator and a flow rate controller, and may further include an air discharge silencer to communicate with the oxygen discharge path to prevent noise during discharge.

The solenoid unit 296 is configured to include a plurality of solenoid valves. The solenoid valve is a valve for switching the flow path, is connected to the compressed air inlet and the nitrogen outlet of the upper cover assembly 294, and absorbs the compressed air supplied from the air compressor through the compressed air inlet to the first adsorption part 291 or the second adsorption. An adsorption operation for supplying the unit 293 to adsorb nitrogen gas and a cleaning operation for discharging nitrogen gas from the first adsorption unit 291 or the second adsorption unit 293 are controlled.

At this time, the solenoid valve is a flow path that is switched by an electric signal by an electronic control circuit, and the electronic control circuit is installed to control the adsorption and cleaning process by giving a switching signal to the solenoid valve at a regular cycle.

The control unit 400, the air compression unit 240, the ventilation unit 280, the oxygen generating unit 290 and the driving fan (the first fan (f1), the second fan (f2), the third fan (f3)) etc., and the results are displayed on the control panel, and the function of individually or simultaneously selecting the oxygen generator and the air purifier, the air/oxygen amount discharge control function, the operation on/off function, and the indoor oxygen amount/noxious gas amount notification control the function.

In addition, the indoor oxygen generator having an air purifying function according to the present invention,

an inner case 210 that is partitioned and formed to have a plurality of spaces communicating with each other; a first duct part 230 and an air compression part 240 disposed in the first chamber of the inner case 210; a second duct unit 260, a filter unit 270 and a ventilation unit unit 280 sequentially arranged in the third chamber of the inner case 210; and an oxygen generating unit 290 disposed in the second chamber of the inner case 210; or

An indoor oxygen generator having an air purifying function comprising an oxygen generator and an air purifier, comprising: an inner case partitioned and formed to have a plurality of spaces communicating with each other; an air compression unit disposed in the inner case and having a heat reducing means; and a silencer connected to the air compression unit and provided with a noise reduction means; or

An indoor oxygen generator having an air purifying function comprising an oxygen generator and an air purifier, comprising: an air compression unit having a heat reducing means; and a silencer connected to the air compression unit and provided with a noise reduction means.

In addition, the air purifier combined with an oxygen generator according to the present invention,

As shown in FIG. 12 , a reflective refraction tube 14 with countless perforated holes formed in the air inlet and air outlet pipe (L) connected to the air compression unit is further provided, and is discharged through the air inlet and air outlet pipe (L). It can reduce air flow noise, compressor driving noise, and pulsating noise.

This is because the air flow or noise flowing through the air inlet and air outlet pipe (L) is caused by the countless perforated holes of the catadioptric tube. The vortex creates a countercurrent flow to the outer edge of the main air flow to reduce the noise generated from the incoming or outgoing air flow by offsetting the colliding air waves. In addition, a plurality of perforated holes formed on the side of the catadioptric tube diffracts and disperses noise waves and pulsating noises leaking from the mechanical device in each through hole, and diffusely reflects them to reduce noise in connection with flowing air. do.

Hereinafter, an operation process of an indoor oxygen generator having an air purifying function according to the present invention will be described with reference to FIGS. 1 to 12 .

<When both the air compressor and the ventilation unit are operated>

First, when the air compressor 241, the first fan f1, the second fan f2, and the third fan f3 are operated, the air compressor 241, the first fan f1, the second fan ( The indoor air is sucked into the second chamber B at the bottom of the device by the respective suction forces of f2) and the third fan f3.

Part of the air sucked into the second chamber (B) is introduced through the third air distribution hole (215a) of the vertical partition surface (215), and then the third wall border (233) of the first duct part (230) is removed. The air introduced through the seventh air distribution hole 235 and the air introduced through the seventh air distribution hole 235 passes through the sixth air distribution hole 231a of the separating plate 231 and the first fan f1 is located. It is introduced into the inside of the seating case 220 through the fourth air distribution hole (221a).

A portion of the air introduced into the seating case 220 is introduced into the air intake unit of the air compressor 241 through the air intake silencer.

The remaining air introduced into the seating case 220 moves upward through the fifth air distribution hole 223a of the seating case 220 by the suction force of the second fan f2 and the third fan f3. While cooling the air compressor 241, it moves along the air flow path of the second duct part 260, passes through the first compartment D, and moves upward through the eighth air distribution hole 261-1a. At this time, it joins with the air transported through the second chamber (B), is filtered in the filter unit 270, is discharged through the ventilation unit unit 280, and is discharged through the air discharge hole at the upper part of the inner case and the air in the outer case. It is discharged into the room as clean air through the hole.

On the other hand, the remainder of the air sucked into the second chamber (B) is moved upward through the second air distribution hole (214-2a) at the upper part of the second chamber (B) and the copper tube disposed in the second chamber (B). After cooling (R), it moves along the air flow path of the second duct part 260, passes through the second compartment E, and moves upward through the ninth air distribution hole 261-2a. At this time, it merges with the air transported through the seating case 220, is filtered by the filter unit 270, is discharged through the ventilation unit 280, and is discharged through the air discharge hole on the upper part of the inner case and the air discharge hole on the outer case It is discharged into the room as clean air.

In addition, the air introduced through the pipe (L1) to the air compressor (241) is discharged through the air outlet in the state of hot compressed air compressed by the driving of the air compressor, is transported along the air outlet pipe and flows into the copper pipe (R) do. At this time, the compressed air discharged in the process of cooling the air compressor 241 by the heat reducing means also has the effect of reducing the temperature, so that the temperature of the air introduced into the copper tube R is lowered.

The compressed air introduced into the copper tube (R) moves along the tube and heat exchanges with the surrounding external environment to lower the temperature of the compressed air. Moisture in the compressed air generated by such a temperature difference is removed by a separate water discharging device.

The compressed air whose temperature is lowered in this way is transferred to the branch chamber of the oxygen generating unit 290 and then introduced into the first adsorption unit 291 through the connected solenoid valve 296 .

Compressed air introduced into the first adsorption unit 291 is adsorbed by zeolite as an adsorbent provided in the first adsorption unit, and compressed gas such as oxygen that is not adsorbed moves to the oxygen storage tank 292 . do.

When the movement of compressed oxygen to the oxygen storage tank is completed, the solenoid valve is opened to remove the pressure applied to the first adsorption unit 291 , and the compressed nitrogen adsorbed to the first adsorption unit is connected to the first adsorption unit 291 . After flowing into the branch chamber through the lower cover assembly 295, it is discharged through the nitrogen outlet, moves along the nitrogen discharge pipe, and passes through the heat reduction means 242 of the air compression unit 240, the upper part of the air compressor 241 It is closely coupled to the air compressor to take heat away from the air compressor to cool the heat sink in a state where the temperature has risen and to be discharged to the outside.

Meanwhile, some of the compressed oxygen transferred to the oxygen storage tank 292 may be transferred to the second adsorption unit 293 and used to clean the second adsorption unit 293 .

In addition, while the movement of compressed oxygen from the first adsorption unit 291 to the oxygen storage tank is completed and the cleaning operation for discharging compressed nitrogen is in progress, the solenoid valve is operated to introduce compressed cold air into the second adsorption unit 293 and Make the same operation as in the first adsorption unit.

As described above, the operation is alternately carried out in the first adsorption unit and the second adsorption unit, so that high-purity compressed oxygen is stored in the oxygen storage tank 292 .

Compressed oxygen stored in the oxygen storage tank 292 is discharged through the oxygen discharge path, merges with the air flow, and is discharged into the room through the air discharge hole of the outer case.

At this time, the pressure or flow rate of oxygen to be discharged is adjusted by the discharge amount adjusting means provided in the oxygen discharge path, and noise is removed during discharge by the air discharge silencer.

<When only the air compressor is operated>

When only the oxygen generator is operated, when only the air compressor 241 is operated, the suction power of the air compressor 241, or the suction power of the air compressor 241 and the first fan f1, or the air compressor 241 By the suction force and the second fan f2, or the suction force of the air compressor 241, and the first fan f1 and the second fan f2, the indoor air passes through the second chamber B through the seating case 220. The sucked air is sucked into the interior, and the sucked air is introduced into the air intake part of the air compressor 241 through the air intake silencer, and then the oxygen generation process and the process of cooling the heat of the air compressor 241 are as described above.

<When only the ventilation unit is operated>

When only the air purifier is to be operated, when the third fan f3 is operated, the indoor air is sucked into the seating case 220 and the second chamber B of the device by the suction force of the third fan f3, , moves along the air flow path of the second duct unit 260, is filtered by the filter unit 270, and then is discharged into the room as clean air through the air discharge hole at the top of the inner case and the air discharge hole at the outer case .

In the indoor oxygen generator having the air purification function according to the present invention having the above configuration, when you want to replace the filter, open the door 120 of the outer case 100, and then open the side door equipped with the filter to be replaced. Open and pull the filter to remove.

Then, insert a new filter through the input hole and close the side door to seal and fix it.

Although described and illustrated in relation to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as such, and deviates from the scope of the technical idea. It will be apparent to those skilled in the art that many changes and modifications may be made to the present invention without reference to the invention. Accordingly, all such suitable alterations and modifications and equivalents are to be considered as being within the scope of the present invention.

1: Air purifier combined with oxygen generator
100: outer case 110: control unit
120: door 200: internal device
210: inner case 220: seating case
230: first duct unit 240: air compression unit
250: silencer 260: second duct part
270: filter unit 280: ventilation unit unit
290: oxygen generating unit 300: seating plate
S: Spring h1, h2: Air discharge hole

Claims (33)

an inner case 210 that is partitioned and formed to have a plurality of spaces communicating with each other;
a seating case 220 disposed in the first chamber of the inner case 210;
a first duct portion 230 coupled to a lower portion of the seating case 220;
an air compression unit 240 provided in the seating case 220;
a second duct part 260 coupled to the bottom surface of the third chamber of the inner case 210;
a filter unit 270 provided to be spaced apart from the second duct unit 260;
a ventilation unit 280 provided to be spaced apart from the filter unit 270; and
An oxygen generator for indoors having an air purifying function, characterized in that it comprises; an oxygen generator (290) disposed in the second chamber of the inner case (210).
The method of claim 1,
The inner case 210 has a bottom surface 211, a side surface 212, an upper surface 213, a horizontal partitioning surface 214 that divides the inner case up and down in a downward direction from the top surface, a horizontal partitioning surface It is composed of a vertical partition surface 215 that divides the divided lower part of the inner case back and forth from the bottom surface,
The first and second rooms formed by the bottom surface 211, the horizontal partitioning surface 214 and the vertical partitioning surface 215, and the third chamber formed by the upper surface 213 and the horizontal partitioning surface 214 are partitioned An indoor oxygen generator with an air purifying function, characterized in that it is
3. The method of claim 2,
The floor surface 211 is divided into a first floor surface 211-1 included in the first chamber and a second floor surface 211-2 included in the second chamber by the vertical partition surface 215, , An indoor oxygen generator having an air purification function, characterized in that the second bottom surface (211-2) is provided with an air inlet hole (211-2a).
3. The method of claim 2,
An inlet (212a) through which the filter is input and discharged is formed on the side surface (212).
3. The method of claim 2,
The horizontal partition surface 214 is divided into a first partition surface 214-1 and a second partition surface 214-2, and the first partition surface 214-1 has a first air distribution hole 214- 1a) is formed, and a second air distribution hole (214-2a) is formed in the second partition surface (214-2).
3. The method of claim 2,
An indoor oxygen generator having an air purification function, characterized in that a third air distribution hole (215a) is formed at a predetermined position on the lower side of the vertical partition surface (215).
The method of claim 1,
The seating case 220 includes a bottom surface 221 on which a fourth air distribution hole 221a is formed, a side surface 222, an upper surface 223 on which a fifth air distribution hole 223a is formed, and the upper surface. Indoor oxygen generator with an air purifying function, characterized in that it is composed of a first wall border (224) formed at a predetermined height on the outside of (223).
8. The method of claim 7,
An indoor oxygen generator having an air purifying function, characterized in that a first fan (f1) is attached to the fourth air distribution hole (221a) of the bottom surface (221).
8. The method of claim 7,
An indoor oxygen generator having an air purification function, characterized in that at least two fifth air distribution holes (223a) of the upper surface (223) are provided to be spaced apart.
The method of claim 1,
An indoor oxygen generator having an air purifying function, characterized in that a noise and vibration prevention material is further provided on the inner surface of the seating case (220).
11. The method of claim 10,
The noise and vibration prevention material,
Air characterized in that it is composed of a reflective refraction plate having a vibration damping material, a sound absorbing material and countless perforated holes formed, or a reflective refractive plate having a sound absorbing material and countless perforated holes, or air characterized in that it consists only of a reflective refracting plate having countless perforated holes. Indoor oxygen generator with clean function.
The method of claim 1,
The first duct part 230,
a separation plate 231 having a sixth air distribution hole 231a formed therein; a second wall border 232 formed at a predetermined height to form a space in the upper portion of the separation plate 231; and a third wall border 233 formed at a predetermined height to form a space under the separating plate 231 and provided with a seventh air distribution hole 235; Indoor oxygen generator with
13. The method of claim 12,
Both ends of the seventh air circulation hole 235 of the third wall border 233 are further provided with inlet guides 234 formed by bending toward the inside,
The seventh air distribution hole (235) is an indoor oxygen generator having an air purification function, characterized in that provided to communicate with the second chamber of the inner case (210).
The method of claim 1,
The air compression unit 240 is fixed through a spring (S) in the seating case 220, and is a heat reducing means 242 that is closely coupled to the air compressor 241 and the upper portion of the air compressor 241. An indoor oxygen generator with an air purifying function, characterized in that it is configured.
15. The method of claim 14,
The heat reduction means 242 has a heat sink 242a having a heat radiation fin disposed therein, and is connected to the nitrogen discharge pipe of the oxygen generator 290 and compressed nitrogen passing through the inside takes heat from the heat radiation fins An indoor oxygen generator with an air purifying function, characterized in that it is configured to be discharged to.
The method of claim 1,
The oxygen generator combined air purifier further includes a silencer (250),
The silencer 250 includes a case 251 having a first room and a second room separated by a partition wall, and an intake part 252 and an exhaust part 253 disposed in the first room and the second room, respectively. An indoor oxygen generator with an air purifying function, characterized in that it comprises a noise reduction means.
17. The method of claim 16,
The intake part 252 of the noise reduction means is composed of an intake pipe and a sound absorption pipe of a predetermined length disposed inside the intake pipe and having a plurality of through-holes formed on the side surface, and the exhaust part 253 is an exhaust pipe and an exhaust pipe An indoor oxygen generator with an air purifying function, characterized in that it is disposed inside the and consists of a sound-absorbing tube of a predetermined length with a plurality of through-holes formed on the side thereof.
The method of claim 1,
The second duct part 260,
an upper surface 261 on which the eighth air distribution hole 261-1a and the ninth air distribution hole 261-2a are formed; a fourth wall border 262 formed at a predetermined height to form a space under the upper surface 261; and a second compartment including a first compartment (D) including an eighth air distribution hole (261-1a) and a ninth air distribution hole (261-2a) in the space formed by the fourth wall border 262 ( An indoor oxygen generator with an air purification function, characterized in that it consists of;
19. The method of claim 18,
An indoor oxygen generator having an air purifying function, characterized in that a second fan (f2) is selectively attached to the lower portion of the eighth air distribution hole (261-1a).
The method of claim 1,
The filter unit 270 is a thread having an air purifying function, characterized in that a plurality of separate filters are bundled into one frame, or a plurality of separate filters are fused into one to form one filter. Contents Oxygen generator.
The method of claim 1,
The ventilation unit 280 includes a third fan f3, a fan holder plate 281 on which the third fan f3 is seated, a side part 282 having a discharge port 282a on one surface, and an upper plate ( 283), characterized in that it consists of an indoor oxygen generator with an air purifying function.
22. The method of claim 21,
The fan mounting plate 281 is provided with a coupling hole in the central portion of which the third fan f3 is seated and fixed, and a plurality of ventilation holes are provided,
The side portion 282 is provided with a flow guide film 284 having a predetermined curvature with the third fan f3 as a center point therein, and the air sucked from the lower portion of the third fan f3 rotates. An indoor oxygen generator having an air purification function, characterized in that it is discharged through the outlet (282a) by turning in the centrifugal force direction along the circumference of the third fan (f3) by the blades of the third fan (f3).
The method of claim 1,
The oxygen generating unit 290,
A first adsorption unit 291 , an oxygen reservoir 292 , and a second adsorption unit 293 are arranged and provided, and the first adsorption unit 291 , the oxygen reservoir 292 , and the second adsorption unit 293 are The upper cover assembly 294 provided to seal them, respectively, is coupled to the upper part, and the lower cover assembly 295 provided to seal them, respectively, is also coupled to the lower part,
The lower cover assembly (295) is coupled to the solenoid part (296), the solenoid part (296) is an indoor oxygen generator having an air cleaning function, characterized in that it is configured to be coupled to the branch chamber.
The method of claim 1,
The oxygen generator combined air purifier further includes a control unit 400,
The control unit 400, the air compression unit 240, the ventilation unit 280, the oxygen generator 290 and the first fan (f1), the second fan (f2), the third fan (f3) to control the An indoor oxygen generator with an air purifying function, characterized in that.
an inner case 210 that is partitioned and formed to have a plurality of spaces communicating with each other;
a first duct part 230 and an air compression part 240 disposed in the first chamber of the inner case 210;
a second duct unit 260, a filter unit 270, and a ventilation unit unit 280 sequentially disposed in the third chamber of the inner case 210; and
An oxygen generator for indoors having an air purifying function, characterized in that it comprises; an oxygen generator (290) disposed in the second chamber of the inner case (210).
26. The method of claim 25,
An indoor oxygen generator having an air purifying function, characterized in that the inner surface of the inner case (210) is further provided with a noise and vibration prevention material.
26. The method of claim 25,
The air compression unit (240), an air compressor (241) and a heat reducing means (242) closely coupled to the upper portion of the air compressor (241), characterized in that consisting of an air purifying function for indoor oxygen generator.
26. The method of claim 25,
The oxygen generator combined air purifier further includes a silencer (250),
The silencer 250 includes a case 251 having a first room and a second room separated by a partition wall, and an intake part 252 and an exhaust part 253 disposed in the first room and the second room, respectively. An indoor oxygen generator with an air purifying function, characterized in that it comprises a noise reduction means.
26. The method of claim 25,
The oxygen generator combined air purifier further includes a control unit 400,
The control unit 400 is an indoor oxygen generator having an air purifying function, characterized in that it controls the air compression unit 240, the ventilation unit 280, the oxygen generating unit 290 and the fan driving.
In the indoor oxygen generator having an air purification function comprising an oxygen generator and an air purifier,
an inner case partitioned to have a plurality of spaces communicating with each other;
an air compression unit disposed in the inner case and having a heat reducing means; and
and a silencer connected to the air compression unit and provided with a noise reduction means.
In the indoor oxygen generator having an air purification function comprising an oxygen generator and an air purifier,
an air compression unit having a heat reducing means; and
and a silencer connected to the air compression unit and provided with a noise reduction means.
33. The method of claim 31 or 32,
The air purifier combined with the oxygen generator,
A noise-vibration anti-vibration material consisting of a reflective refraction plate having a vibration damping material, a sound absorbing material and countless perforated holes, or a reflective refraction plate having a sound absorbing material and countless perforated holes, or only a reflective refraction plate having countless perforated holes Indoor oxygen generator with an air purifying function, characterized in that it includes.
33. The method according to any one of claims 1 to 32,
The indoor oxygen generator having the air purifying function,
An indoor oxygen generator with an air cleaning function, characterized in that the refraction rod having countless perforated holes formed in the air inlet and air outlet pipes connected to the air compression unit is further provided.

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