KR102435149B1 - Oxygen generator and oxygen supply system using the same - Google Patents

Abstract

The present invention relates to an oxygen generator and an oxygen supply system using the same. The present invention provides an oxygen generator having an air pocket which smoothly collects oxygen through one or more oxygen separation membranes and uniformly concentrates the same in a state of vacuum suction by a vacuum pump, thereby being capable of always providing, to a user, a proper amount of fresh and clean oxygen, preventing vibration and noise generated during vacuum pump processing from being delivered to the outside of the oxygen generator, effectively preventing dyspnea or asphyxia in an emergency situation such as fire or toxic gas release, being able to normally supply, to the user, proper amount of fresh and clean oxygen whenever, as necessary, and enabling the user to drink oxygen water containing high dissolved oxygen.

Description

Oxygen generator and oxygen supply system using the same

The present invention relates to an oxygen generator, and more particularly, while allowing oxygen to be smoothly collected and evenly concentrated through at least one oxygen separation membrane in a vacuum suction state by a vacuum pump, a clean and fresh appropriate amount to the user at any time It relates to an oxygen generator capable of supplying oxygen and an oxygen supply system using the same.

In general, an oxygen respirator is mainly used for the purpose of effectively supplying oxygen in a situation in which it is difficult to receive a smooth oxygen supply, which is a large-capacity oxygen storage tank and an oxygen intake body that can receive and inhale oxygen from the oxygen storage tank was implemented in the form of having

These oxygen respirators are used in hospitals, used for underwater activities such as scuba diving, and used for fire suppression and rescue activities at fire sites.

On the other hand, at the site of a fire or leaking toxic gas, rapid evacuation along with the smooth supply of oxygen can minimize human casualties such as suffocation. In particular, it is known that the main cause of casualties at the site of a fire is suffocation by poisonous gas or smoke, not by flames. According to the investigation, the survival rate decreases by 7 to 10% every 1 minute after the occurrence of a fire, and the survival rate drops to about 25% after 5 minutes and less than 5% after 10 minutes.

In these disaster situations, it is very important to be able to breathe clean air (i.e. oxygen) quickly on a portable device.

However, because the conventional oxygen respirator is difficult to carry, it is difficult to use it when an emergency situation occurs or when you want to receive oxygen normally.

In other words, the dust contained in the air is 10㎛ or more that can be confirmed with the naked eye, and 10㎛ or less dust, especially ultra-fine dust (PM-2.5) of 2.5㎛ or less that is difficult to check with the naked eye. Corona virus, which has strong contagious power, may be contained in the air, and the fine dust or virus as described above is inhaled through the respiratory tract of the human body, threatening health.

Accordingly, in the prior art, masks having various shapes and structures are used as a means for preventing the penetration of fine dust and / or viruses, but when the mask is worn for a long time, there is a problem that oxygen supply is not smooth and breathing problems occur. . Therefore, in the recent quarantine situation where wearing a mask is inevitable, it acts as a big hindrance.

)을 촉매인 이산화망간(MnO

)과 조합한 물질로 이루어지는 것이다.Accordingly, in the prior art, a tank in which compressed or liquefied oxygen or air is accommodated is coupled to a mask or oxygen is supplied while an oxygen generator is applied. Potassium superoxide (KO) as a substance that generates oxygen by

) as the catalyst manganese dioxide (MnO

), which is a combination of

However, the tank or the oxygen generator as described above requires periodic replacement, and its use is inevitably limited. That is, in an emergency situation, the use of the tank or oxygen generator as described above is inevitably limited, and the use of the tank or oxygen generator is limited even in normal times, and the tank or oxygen generator has to be frequently replaced.

Registered Patent Publication No. 10-1340583 (date of publication 2013.12.12.)

Registered Patent Publication No. 10-2091547 (published on March 20, 2020)
Laid-open Patent Publication No. 10-2007-0031489 (published on March 20, 2007)
Publication No. 10-2019-0074770 (published on June 28, 2019)
Laid-open Patent Publication No. 10-2021-0037768 (published on April 7, 2021)

The problem to be solved by the present invention is to smoothly collect and evenly concentrate oxygen through at least one oxygen separation membrane in a vacuum suction state by a vacuum pump, through which clean and fresh oxygen is supplied to the user at any time at any time It is intended to provide an oxygen generator that makes this possible.

Another object to be solved by the present invention is to provide an oxygen generator capable of preventing vibration noise generated during vacuum pump processing through an air pocket from being transmitted to the outside of the oxygen generator.

Another problem to be solved by the present invention is to effectively prevent breathing difficulties or suffocation in emergency situations in which a fire or toxic gas is emitted while connecting a wearable member for supplying oxygen to an oxygen generator, while also preventing the user from breathing difficulties or suffocation whenever necessary It is intended to provide an oxygen supply system that enables the supply of clean, fresh, and adequate oxygen to people.

Another problem to be solved by the present invention is to provide an oxygen supply system that enables drinking of oxygenated water with high dissolved oxygen by using an oxygen generator connected to a water purification device.

The oxygen generator, which is a problem solving means of the present invention, includes: a housing through which an oxygen outlet is drawn to the outside; an air supply fan formed in the housing, receiving driving power from an internal or external battery, and operating to introduce external air; a filter member formed to form a structure in which at least one is stacked in the housing and concentrating and collecting oxygen from external air introduced by the air supply fan in a vacuum suction state; a vacuum pump formed in the housing to provide a vacuum suction pressure, to receive driving power from the battery, and to discharge oxygen concentrated and collected by the filter member through the oxygen outlet; Including, wherein the filter member includes: a filter case in which a ring-shaped seating jaw and a coupling hole protruding along the inner periphery are formed; a membrane fixing plate having a plurality of contact protrusions that are contact areas, and a collection flow path that is a non-contact area between the contact protrusions, having an edge seated on the seating jaw forming a ring shape; It is in contact with the contact protrusion, which is a contact area, while covering one surface and the other surface of the membrane fixing plate to close the collection passage, and the low-permeability nitrogen contained in the air introduced by the air supply fan is adsorbed and separated. , a polymer membrane that transmits oxygen with high permeability to the collection passage while concentrating; and a transfer member connected to the vacuum pump while being coupled to the coupling port formed in the filter case, and guiding the oxygen concentrated and collected in the collection passage to be transferred to the vacuum pump by vacuum suction pressure. will include

In addition, at least one or more air pockets for absorbing the vibration to prevent the vibration according to the operation of the vacuum pump applying vacuum suction pressure from being transmitted to the outside of the housing is formed in the housing.

In addition, the coupling hole is formed at one edge of the filter case, and coupling protrusions for fixing the stacked state when at least one filter case is stacked are protruded from the other edge of the filter case.

In addition, an end cap is coupled to the coupling port to maintain airtightness of the movement path of oxygen concentrated and collected in the collection passage.

In addition, in the membrane fixing plate, a through structure is formed between the plurality of contact protrusions, respectively, and the movement of concentrated and collected oxygen in the collection flow path is guided by non-contact with the polymer membrane, but at the contact portion of the polymer membrane. A first guide channel is formed to press the contact portion of the polymer film to hold the polymer film from being pushed.

In addition, a second guide flow path for guiding the movement of concentrated and collected oxygen in the collection flow path is formed in a portion of one corner of the membrane fixing plate that is not in contact with the polymer membrane while forming a penetrating structure penetrating the edge portion.

In addition, the transfer member has a first discharge hole for pressing and fixing an edge portion of the polymer film seated on the seating jaw of the filter case, and guides the oxygen concentrated and collected in the collection passage to be transferred by vacuum suction pressure. multi connector; and an adapter connected to the vacuum pump for applying a vacuum suction pressure while being rotatably coupled to the multi-connection port, and having a second discharge hole for transferring oxygen guided by the multi-connection port to the vacuum pump; will include

In addition, the multi-connector, the first body portion for pressing and fixing the edge portion of the polymer film; and a first connector protruding from the first body portion to transfer the oxygen through the first outlet hole to which a vacuum suction pressure is applied. Including, the first discharge hole is to pass through the center of the first body portion and the first connector.

In addition, the adapter may include: a second body portion to which the first connector to which the O-ring is coupled is inserted and coupled; and a second connector extending orthogonally from the second body portion. Including, the second discharge hole is to pass through the second body portion and the second connector.

In addition, when forming the structure in which at least one or more of the filter members are stacked, the first connector of the multi-connector disposed at the lowermost end is inserted and coupled to the coupler formed in the adjacent upper filter case.

Further, the concentration of oxygen contained in the air that is concentrated and permeated by the polymer film is in the range of 23 to 30%, and the concentration of nitrogen contained in the air adsorbed by the polymer film is in the range of 81 to 85%.

In addition, a wearing member for supplying oxygen to the user's respirator is connected to the oxygen outlet formed in the housing included in the oxygen generator.

In addition, the wearing member may include: an earring body having an oxygen inlet connected to the oxygen outlet through a hose; and a rod-type microphone connected to the oxygen inlet of the earring body and having an oxygen flow path. It is a headset structure comprising a, and at least one oxygen outlet for discharging oxygen-containing air guided through the oxygen flow path to the user's respirator is formed in the rod-type microphone.

In addition, the water outlet line of the water purifier including at least one filter, a cooling unit, and a heating unit for discharging cooled or heated drinking water, the oxygen outlet of the housing included in the oxygen generator, and the oxygen generated in the oxygen generator are cooled. Alternatively, a dissolver for dissolving in heated drinking water and releasing oxygen water having high dissolved oxygen is connected.

In addition, a diaphragm forming a zig-zag flow path is formed inside the dissolver, and a mesh network through which the drinking water passes in a bubble form so that the oxygen is dissolved in the drinking water is formed at the ingestion end of the dissolver.

In addition, the oxygen generator is to supply oxygen to the dissolver by turning on the water purifier when a signal for drinking water of cold water or hot water is generated from the water purifier.

As described above, the present invention constitutes an oxygen generator to which an air pocket that smoothly collects oxygen and evenly concentrates oxygen through at least one oxygen separation membrane in a vacuum suction state by a vacuum pump is applied, through which it is always clean to the user at any time. And it is possible to supply an appropriate amount of fresh oxygen, as well as the effect of preventing the vibration noise generated during vacuum pump processing from being transmitted to the outside of the oxygen generator.

In addition, the present invention connects a wearable member for supplying oxygen or a water purifying device to an oxygen generator to effectively prevent breathing difficulties or suffocation in emergency situations in which a fire or toxic gas is emitted, as well as providing cleanliness to the user at any time during normal times as needed. And while it is possible to supply an appropriate amount of fresh oxygen, the effect of drinking oxygenated water with high dissolved oxygen can be expected.

The effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a partially exploded perspective view showing the structure of an oxygen generator according to a first embodiment of the present invention;
2 is an exploded perspective view showing the structure of a filter member according to a first embodiment of the present invention;
Figure 3 is a perspective view showing the structure of the membrane fixing plate according to the first embodiment of the present invention.
4 is a cross-sectional view taken along line AA of FIG. 3 as a first embodiment of the present invention.
5 is a cross-sectional view taken along line BB of FIG. 3 as a first embodiment of the present invention.
6 is a perspective view showing a state in which the filter members are stacked in two stages according to the first embodiment of the present invention;
7 is a side view showing the structure of a filter member stacked in two stages according to the first embodiment of the present invention;
8 is an enlarged cross-sectional view showing the structure of a filter member stacked in two stages according to the first embodiment of the present invention.
9 and 10 are perspective views showing a state in which the filter member is stacked in three stages according to the first embodiment of the present invention.
11 is a perspective view showing a state in which the filter members are stacked in four stages according to the first embodiment of the present invention;
12 is a structural diagram of an oxygen supply system in which an oxygen generator and a wearing member are connected according to a second embodiment of the present invention;
13 is a structural diagram of an oxygen supply system in which an oxygen generator and a water purifier are connected according to a third embodiment of the present invention;

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

1 is a partially exploded perspective view showing the structure of an oxygen generator according to a first embodiment of the present invention, FIG. 2 is an exploded perspective view showing the structure of a filter member according to a first embodiment of the present invention, and FIG. 3 is a first embodiment of the present invention. A perspective view showing the structure of a membrane fixing plate according to a first embodiment, FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3 as a first embodiment of the present invention, and FIG. 5 is a cross-sectional view taken along line B-B of FIG. 3 as a first embodiment of the present invention. will show

1 to 5 , the oxygen generator SG according to an embodiment of the present invention includes a housing 10 , an air supply fan 20 , a filter member 30 , a vacuum pump 40 , and / or to include an air pocket (50).

The housing 10 has a combined structure of an upper cover 10a, a lower cover 10b, and a side cover 10c, and the oxygen outlet 11 is drawn out from the lower cover 10b.

The air supply fan 20 is accommodated in the battery housing 12 in the housing 10 and is electrically connected to a control board (not shown) in the housing 10 through a built-in battery BT or a cable. It is driven by receiving driving power through an external battery (BT) electrically connected to the control board, and is operated to introduce external air.

Here, the battery BT includes the air supply fan 20 and the vacuum pump 40 to be described later according to a control signal of the control board according to a signal input of an operation unit (not shown) formed in the housing 10 . to supply driving power to each.

On the other hand, although not shown in the drawings, the control board sets the use time for the oxygen generator (SG), automatically stops after a safe operation time, checks whether normal operation is performed through the dust sensor and the control unit, and detects overheating of the battery (BT) and a control program for performing functions such as power off, prevention of overcharging of the battery BT, and warning and blocking of overvoltage and undervoltage.

The filter member 30 is formed to have a structure in which at least one is stacked in the housing 10 , and is formed by the air supply fan 20 in a vacuum suction state according to the operation of the vacuum pump 40 . Oxygen is concentrated and collected from the incoming external air, and includes a filter case 31 , a membrane fixing plate 32 , a polymer membrane 33 , and a transfer member 34 .

The filter case 31 is a rectangular ring-shaped structure in which a ring-shaped seating jaw 31a and a coupling hole 31b protruding along the inner periphery are formed, and the coupling hole ( 31b) is formed, as well as a coupling protrusion 31c for fixing the stacking state when one or more filter cases 31 are stacked on the other edge portion of the filter case 31, and the coupling hole 31b) An end cap (31d) may be coupled thereto to maintain airtightness of the movement path of oxygen collected in the collection passage (32b).

The membrane fixing plate 32 has an edge portion seated on the seating jaw 31a forming a ring shape, and includes a plurality of contact protrusions 32a that are contact areas, and a non-contact area between the contact protrusions 32a. A flow path 32b may be formed.

On the other hand, between the plurality of contact protrusions 32a, each forming a through structure and not in contact with the polymer film 33, while guiding the movement of concentrated and collected oxygen in the collection passage 32b, the polymer film 33 A first guide flow path 32c is formed to prevent sagging of the film fixing plate 32, and the collection flow path 32b has a structure penetrating the edge portion and is not in contact with the polymer membrane 33. ), a second guide flow path 32d for guiding the movement of concentrated and collected oxygen may be formed.

At this time, the collecting flow path 32b forms a non-contact portion of the polymer film 33 by securing a space of about one protrusion between the three successive contact protrusions 32a low, which secures a more expanded flow path. is to do

However, when the non-contact portion with the polymer film 33 is widely maintained, there may be a problem in that the sag of the polymer film 33 is exceptionally increased in a specific region due to the pressing pressure of the sucked air, and this may cause the polymer film 33 to sag. Since the membrane 33 is partially stretched and the durability life can be shortened, the first guide for additionally forming a flow path that penetrates vertically inside the three contact protrusions 32a in succession to prevent this, that is, a sagging space. A flow path 32c is formed.

This is to be given a new function to be distinguished from the collection flow path 32b for guiding the movement of the collected oxygen, and a sagging space in which the pressing pressure of the sucked air passes vertically inside the three contact protrusions 32a in succession. Since it also extends to the first guide flow path 32c, which is a flow path, it is possible to repeatedly hold the push of the polymer layer 33 at the contact portion of the polymer layer 33 several times.

In this way, by effectively pressing the contact portion of the polymer film 33 , the horizontal movement of the polymer film 33 , that is, the pushing phenomenon, can be caught, thereby affecting the widely secured collection passage 32b. It is also possible to prevent the polymer film 33 from being treated excessively by the pressing pressure of air.

The polymer film 33 is in contact with the contact protrusion 32a, which is a contact area, while covering one surface and the other surface of the film fixing plate 32 to seal the collection passage 32b, and the air supply fan 20 ), nitrogen with low permeability contained in the air introduced by the inlet is adsorbed and separated, and oxygen with high permeability is transmitted through the collection passage 32b while being concentrated.

Here, the polymer membrane 33 is hollow, and the concentration of oxygen contained in the air to be concentrated and collected is in the range of 23 to 30%, and the concentration of nitrogen contained in the adsorbed air is in the range of 81 to 85%, and , the nitrogen adsorbed without passing through the polymer film 33 is adsorbed and dissolved on the surface of the polymer film 33 and then diffused into the polymer film 33 and is orthogonal to the direction in which the oxygen is transmitted It can be decomposed and discharged.

The transfer member 34 is connected to the vacuum pump 40 while being coupled to the coupling hole 31b formed in the filter case 31, and the oxygen collected along the collection passage 32b is vacuumed. It guides to be transferred to the vacuum pump 40 by suction pressure, and includes a multi-connection port 341 , an adapter 342 , and an O-ring 343 .

The multi-connector 341 presses and fixes the edge portion of the polymer film 33 seated on the seating jaw 31a of the filter case 31 and has a first discharge hole T1, and the collection passage ( It guides the oxygen collected in 32b) to be transported by vacuum suction pressure, and may include a first body portion 341a and a first connector 341b.

The first body portion 341a is to press and fix the edge portion of the polymer film 33 .

The first connector 341b is formed to protrude from the first body 341a, and guides the oxygen to be transferred to the vacuum pump 40 through the first discharge hole T1 to which a vacuum suction pressure is applied. will do

Here, the first discharge hole T1 may pass through the central portions of the first body portion 341a and the first connector 341b.

The adapter 342 is connected to the vacuum pump 40 that applies a vacuum suction pressure while being rotatably coupled to the multi-connection port 341, and the oxygen guided by the multi-connection port 341 is supplied to the vacuum pump ( 40) to have a second discharge hole (T2), which may include a second body portion (342a) and a second connector (342b).

The second body portion 342a is to be inserted and coupled to the first connector 341b to which the O-ring 343 is coupled, and the second connector 342b extends orthogonally from the second body portion 342a. is formed, and the second discharge hole T2 may pass through the second body portion 342a and the second connector 342b.

At least one or more of the O-ring 343 is coupled to the outer circumferential surface of the connector 341b, which is in close contact with the inner circumferential surface of the adapter 342 and the oxygen transferred through the first discharge hole T1. Confidentiality can be maintained to prevent leakage.

The vacuum pump 40 is formed in the housing 10 to provide vacuum suction pressure, and receives driving power from the battery BT, and supplies oxygen concentrated and collected by the filter member 30 to the oxygen outlet. It is discharged through (11).

At least one or more than one air pocket 50 is formed in the housing 10 , and vibration according to the operation of the vacuum pump 40 applying a vacuum suction pressure is transmitted to the outside of the housing 10 . It is possible to absorb the vibration to prevent it.

On the other hand, in the oxygen generator (SG) according to the first embodiment of the present invention, the filter member 30 has at least one first stage in the housing 10 as shown in FIGS. 2 to 5, but the attached Formed in a two-layer stacked structure as in FIGS. 6 to 8, or a three-layer stacked structure as in FIGS. 9 and 10, or a four-layer stacked structure as in the attached FIG. 11 it might be Accordingly, the first connector 341b of the multi-connector 341 to which the O-ring 343 is coupled to be disposed at the lowermost end is inserted and coupled to the coupler 31b formed in the filter case 31 of the upper end adjacent to it. will be.

As described above, in the oxygen generator SG according to the first embodiment of the present invention, when a signal is first inputted to the control board through a manipulation unit provided in the housing 10, as shown in FIGS. 1 to 11 , the control The board can apply driving power to the air supply fan 20 and the vacuum pump 40 through the battery BT.

Then, the vacuum suction pressure is generated according to the operation of the vacuum pump 40 , and as the air supply fan 20 is operated, external air is introduced into the inside of the housing 10 , and the external air thus introduced reaches the polymer film 33 included in the filter member 30 having a structure in which at least one or more than one is stacked according to the vacuum suction pressure.

Then, the polymer membrane 33 adsorbs and separates nitrogen with low permeability contained in the air, and transmits oxygen with high permeability while concentrating it. Concentrated oxygen is collected in the collection passage 32b, which is a non-contact region formed.

That is, the polymer film 33 is in contact with the contact protrusion 32a, which is a contact area formed on the membrane fixing plate 32, and at the same time, a collection passage 32b which is a non-contact area having a lower height than the contact protrusion 32a. Since it forms a structure to cover and seal, the concentrated oxygen that has passed through the polymer film 33 is collected in the collection passage 32b and then transported along the collection passage 32b.

At this time, since first and second guide passages 32c and 32d forming a through structure are formed in the membrane fixing plate 32, the oxygen concentrated and collected in the collection passage 32b is transferred to the collection passage 32b. of course, free transfer is possible without clogging in the direction of one side and the other side based on the membrane fixing plate 32 .

Here, the first guide flow path 32c forming a through structure between the plurality of contact protrusions 32a is in contact with the polymer film 33 while not in contact with the polymer film 33 . Since the polymer film 33 is pushed by pressing the contact portion of 33, the concentration of oxygen by the polymer film 33 and the collection efficiency of oxygen enriched by the collection passage 32b are it can be raised

Therefore, the oxygen concentrated and collected in the collection flow path 32b is a multi-connection port 341 and an adapter 342 included in the transfer member 34 by the vacuum suction pressure generated according to the operation of the vacuum pump 40. Then, it can be transferred to the vacuum pump 40 connected to the adapter 342 by a hose.

At this time, the vibration caused by the operation of the vacuum pump 40 is absorbed by the air pocket 50 and the vibration noise is not transmitted to the outside, and is connected to the outlet of the vacuum pump 40 through a hose, etc. The oxygen outlet 11 discharges the concentrated and collected oxygen to the outside.

On the other hand, the oxygen discharged through the oxygen outlet 11 is directly inhaled by the user through the wearing member 100 as shown in the attached FIG. 12, which is the second embodiment of the present invention, or the attached 13, it is also possible to drink through the purified drinking water of the water purifier 200.

(Second embodiment) Application for use in combination with a wearing member (headset structure).

The oxygen supply system according to the second embodiment of the present invention, as illustrated in the accompanying FIG. 12 , provides oxygen to the user's respirator through the oxygen outlet 11 formed in the housing 10 included in the oxygen generator SG. Earrings having an oxygen inlet 111 connected to the oxygen outlet 11 and a hose (not shown) so that the wearing member 100 for supplying it can be connected through a hose, etc. It is a headset structure including a body 110 and a rod-type microphone 120 having an oxygen flow path connected to the oxygen inlet 111 of the earring body 110 .

Here, at least one oxygen outlet 121 for discharging oxygen-containing air guided through the oxygen flow path to the user's respirator may be formed in the rod-type microphone 120 , and accordingly, the user may use the oxygen outlet 121 . ), the concentrated and collected oxygen can be inhaled through the respiratory system.

(Third embodiment) Application for use in combination with a water purifier.

The oxygen supply system according to the third embodiment of the present invention is cooled or cooled while including at least one filter (F1, F2, F3), a cooling unit 210 and a heating unit 220, as illustrated in FIG. 13 . The oxygen discharge port 11 of the housing 10 included in the oxygen generator SG, and the oxygen generated from the oxygen generator SG are cooled or It is to connect the dissolver 400 for dissolving in the heated drinking water and extracting oxygen water having high dissolved oxygen.

At this time, a diaphragm 401 forming a zigzag flow path is formed inside the dissolver 400 , and the oxygen is dissolved in the drinking water at the inlet end of the dissolver 400 , and the drinking water is converted to bubble form.

Oxygen generated from the oxygen generator (SG) that is connected to the outlet line through a connector and injected into drinking water is converted into a bubble state as soon as it is exposed to the air and is injected in the state of broken drinking water water particles. As it is split, oxygen dissolves more efficiently in the water particles, which greatly improves the oxygen dissolution rate.

The oxygen generator SG is immediately turned on without waiting time when a signal for drinking water of cold or hot water is applied from the water purifier 200, which is a facility that does not require the oxygen generator SG to warm up. Because.

Therefore, it is possible to immediately supply oxygen to the dissolver 400 without waiting time, so that the user can drink oxygenated water with high dissolved oxygen by selecting drinking water of cold water or hot water.

Although the technical idea of the oxygen generator of the present invention and the oxygen supply system using the same has been described with the accompanying drawings, the most preferred embodiment of the present invention is exemplarily described, and the present invention is not limited thereto.

Therefore, the present invention is not limited to the specific embodiments described above, and without departing from the gist of the present invention claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications. Of course, such modifications are intended to be within the scope of the claims.

10; housing 10a; upper cover
10b; lower cover 10c; side cover
11; oxygen outlet 12; battery compartment
20; air supply fan 30; filter element
31; filter case 31a; chin
31b; coupler 31c; bonding protrusion
31d; end cap 32; Membrane Fixing Plate
32a; contact protrusion 32b; collection oil
32c; first guide flow passage 32d; 2nd guide euro
33; polymer film 34; transfer member
341; multi-connection 341a; first body part
341b; first connector 342; adapter
342a; a second body portion 342b; 2nd connector
343; o-ring 40; vacuum pump
50; Air Pocket BT; battery
T1; a first outlet hole T2; 2nd outlet hole
SG1; oxygen generator 100; wear member
110; earring body 111; oxygen intake
120; rod microphone 121; oxygen outlet
200; Water purifier F1, F2, F3; filter
210; cooling unit 220; heating unit
400; dissolver 401; diaphragm
402; mesh net

Claims (17)

delete a housing through which the oxygen outlet is drawn to the outside;
an air supply fan formed in the housing, receiving driving power from an internal or external battery, and operating to introduce external air;
a filter member that is formed to form a structure in which at least one is stacked in the housing, and concentrates and collects oxygen from external air introduced by the air supply fan in a vacuum suction state;
a vacuum pump formed in the housing to provide a vacuum suction pressure, to receive driving power from the battery, and to discharge oxygen concentrated and collected by the filter member through the oxygen outlet; including,
The filter member again,
a filter case in which a ring-shaped seating jaw and a coupling hole are formed protruding along the inner periphery;
a membrane fixing plate having a plurality of contact protrusions that are contact areas, and the collection flow path that is a non-contact area between the contact protrusions, which is seated on the ring-shaped seating jaw;
By covering one surface and the other surface of the membrane fixing plate, it is in contact with the contact protrusion, which is a contact area, to close the collection passage, and nitrogen with low permeability contained in the air introduced by the air supply fan is adsorbed and separated, a polymer membrane that transmits oxygen with high permeability to the collection passage while concentrating; and,
a transfer member connected to the vacuum pump while being coupled to the coupling port formed in the filter case, and guiding the oxygen concentrated and collected in the collection passage to be transferred to the vacuum pump by vacuum suction pressure; is composed of
In the membrane fixing plate,
While forming a through structure between the contact protrusions forming a plurality of each, the movement of concentrated and collected oxygen in the collection flow path is guided by non-contact with the polymer film, and by pressing the contact portion of the polymer film at the contact portion of the polymer film. Oxygen generator, characterized in that the first guide passage for holding the push of the polymer film is formed. 3. The method of claim 2,
The oxygen generator, characterized in that at least one air pocket for absorbing the vibration is formed in the housing to prevent the vibration according to the operation of the vacuum pump applying a vacuum suction pressure from being transmitted to the outside of the housing. 4. The method of claim 3,
A coupler is formed in one corner of the filter case,
The oxygen generator according to claim 1, wherein a coupling protrusion for fixing the stacked state when the filter case is stacked is protruded from the other edge portion of the filter case. 5. The method of claim 4,
Oxygen generator, characterized in that the end cap (End Cap) is coupled to the coupling port to maintain the airtight movement path of the oxygen concentrated and collected in the collection passage. delete 3. The method of claim 2,
Oxygen generator, characterized in that the second guide flow path for guiding the movement of concentrated and collected oxygen in the collection flow path to form a structure penetrating the edge portion of the membrane fixing plate is non-contact with the polymer film Oxygen generator characterized in that. 8. The method of claim 7,
The transfer member is
a multi-connector having a first discharge hole for pressurizing and fixing an edge portion of the polymer film seated on the seating jaw of the filter case, and guiding the concentrated and collected oxygen to the collection passage to be transferred by vacuum suction pressure; and,
an adapter connected to the vacuum pump for applying a vacuum suction pressure while being rotatably coupled to the multi-connection port, and having a second discharge hole for transferring oxygen guided by the multi-connection port to the vacuum pump; Oxygen generator comprising a. 9. The method of claim 8,
The multi-connector,
a first body portion for pressing and fixing an edge portion of the polymer film; and a first connector protruding from the first body portion to transfer the oxygen through the first outlet hole to which a vacuum suction pressure is applied. including,
The first discharge hole is an oxygen generator, characterized in that through the central portion of the first body portion and the first connector. 10. The method of claim 9,
The adapter is
a second body portion to which the first connector to which the O-ring is coupled is inserted; and a second connector extending orthogonally from the second body portion. including,
The second discharge hole is an oxygen generator, characterized in that through the second body portion and the second connector. 11. The method of claim 10,
When the filter member forms a structure in which at least one or more are stacked, the first connector of the multi-connector disposed at the lowermost end is inserted and coupled to a coupler formed in an adjacent upper filter case. 12. The method of claim 11,
The concentration of oxygen contained in the air that is concentrated and permeated by the polymer membrane is in the range of 23 to 30%, and the concentration of nitrogen contained in the air adsorbed by the polymer membrane is in the range of 81 to 85%. oxygen generator. An oxygen generator having the structure of any one of claims 2 to 5 and 7 to 12; and,
a wearing member connected to the oxygen generator to supply oxygen to the user's respiratory tract; including,
The wearing member is an oxygen supply system, characterized in that connected to the oxygen outlet drawn out from the housing included in the oxygen generator. 14. The method of claim 13,
The wearing member,
an earring body having an oxygen inlet connected to the oxygen outlet through a hose; and a rod-type microphone connected to the oxygen inlet of the earring body and having an oxygen flow path. It is a headset structure comprising a,
Oxygen supply system, characterized in that at least one oxygen outlet for discharging oxygen-containing air guided through the oxygen flow path to the user's respirator is formed in the rod-type microphone. An oxygen generator having the structure of any one of claims 2 to 5 and 7 to 12; and,
a water purifier having an oxygen outlet of the oxygen generator connected to a water outlet line, the water purifier including at least one filter, a cooling unit, and a heating unit, and discharging cooled or heated drinking water; including,
An oxygen supply system, characterized in that connected to the water outlet line of the water purifier to which the oxygen discharge port is connected, is connected to a dissolver for dissolving oxygen generated from the oxygen generator in cooled or heated drinking water and dissolving oxygen water having high dissolved oxygen. 16. The method of claim 15,
A diaphragm forming a zigzag flow path is formed inside the dissolver,
Oxygen supply system, characterized in that the mesh network for passing the drinking water in the form of bubbles so that the oxygen is dissolved in the drinking water is formed at the receiving end of the dissolver. 16. The method of claim 15,
The oxygen generator is an oxygen supply system, characterized in that when the water purifier to supply the oxygen to the dissolver by operating when a signal for drinking water of cold or hot water is generated from the water purifier.

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