KR100836722B1 - Oxygen generator - Google Patents

Abstract

An oxygen generator is provided to supply oxygen with a proper humidity to the outside by evaporating water from oxygen generated from the oxygen generator, and accelerate the evaporation of water in the evaporator. An oxygen generator comprises: a membrane part(20) which sucks in an external air, and in which a membrane is embedded to separate nitrogen and oxygen by filtering nitrogen from the sucked external air and passing oxygen of the external air through the membrane; a water separator(40) for separating water from the oxygen generated in the membrane part; and an evaporator(60) which contains water separated by the water separator, and which evaporates the contained water while dry nitrogen generated in the membrane part passes through the evaporator. The evaporator has an inlet(62) formed in a bottom part thereof to flow the nitrogen generated in the membrane part into the evaporator, and an outlet(64) formed on an upper part thereof to exhaust the nitrogen to the outside. The oxygen generator further comprises a compressor(80) for compressing the external air and supplying the compressed air into the membrane part, and compressing the oxygen after transferring the oxygen generated in the membrane part into the water separator. The compressor includes radiation fins(82) that comes in contact with the evaporator or extends into the evaporator to increase an evaporation effect.

Description

Oxygen Generator

1 is a block diagram showing an oxygen generator according to a preferred embodiment of the present invention.

2 is a block diagram showing an oxygen generator according to another preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

20: membrane portion 40: water separator

60: evaporator 62: inlet

64 outlet portion 66 foam member

80: compressor 82: heat dissipation fin

The present invention relates to an oxygen generator, and more particularly, to an oxygen generator for supplying oxygen with an appropriate humidity to the outside by evaporating moisture from the generated oxygen.

Today, oxygen generators are used in various places in various places. Most commonly, oxygen generators provide oxygen to confined spaces in offices and homes to help the fatigue of the modern people and the activation of cells. .

For example, when operating a heater or an air conditioner with the windows closed in an enclosed room, it is known that the air in the enclosed room becomes cloudy for a short time and the concentration of oxygen decreases. Such air pollution and lowering of oxygen concentrations make it easy for the occupants and passengers, including the driver, to feel tired and uncomfortable. Therefore, air conditioning systems such as various air cleaners and oxygen generators may be installed indoors.

On the other hand, it is widely used for air purification, such as a medical oxygen generator, an automotive oxygen generator, a diver's air tank filling oxygen generator, and an air conditioner.

To date, oxygen generators can be classified into chemical and electrical methods, using PSA and RVSA methods using zeolites and membranes such as flat or circular constructions.

 Among them, flat membrane or hollow fiber oxygen generator can be used semi-permanently when there is no clogging caused by dust or other pollutant sources, whereas zeolite method, electrical method, and chemical method can use oxygen generator (separator) after a certain period of time. There is a disadvantage to be exchanged.

 However, in the case of oxygen generators using membranes such as flat membranes and hollow fiber, condensation occurs at the outlet of oxygen, and condensation is accelerated as the humidity of the inhaled air is higher and the ambient temperature difference is larger.

This phenomenon is caused by hydrophilicity, which is a membrane's own characteristics.

Particularly, in order to increase the flow rate and concentration of oxygen, an oxygen generating system has been recently constructed by using a high performance compressor, but there is a problem in that generation of condensed water in the pipe is further promoted.

For the treatment of such condensate, by installing a separate bucket in the headset or stand of the membrane-type oxygen generator, the condensed water collected in the pipe is collected separately to prevent the discharge of water to the oxygen discharge port, but the user Not only has the inconvenience of checking and discarding the amount, there is a limit that occurs when a certain amount of water is filled in the water tank, the water is discharged again through the oxygen discharge port.

The present invention has been made to solve the above problems, and an object thereof is to provide an oxygen generator capable of supplying oxygen with an appropriate humidity to the outside by evaporating moisture from the generated oxygen.

In order to achieve the above object, an oxygen generator according to a preferred embodiment of the present invention includes: a membrane unit for injecting outside air and separating nitrogen and oxygen by a built-in membrane for filtering nitrogen and passing oxygen from the sucked outside air; A water separator for separating water from oxygen generated in the membrane part; And an evaporator accommodating the water separated by the water separator and evaporating the contained water while passing the dry nitrogen generated in the membrane portion.

At this time, the evaporator, it is preferable that the inlet portion is formed in the nitrogen is introduced from the membrane portion, the discharge portion is discharged to the nitrogen is formed in the upper portion.

In addition, the evaporator, it is preferable that the foam member of the porous material is installed to increase the surface area in which the moisture and the nitrogen contacted therein.

In addition, it is preferable to further include a compressor for compressing and supplying outside air to the membrane unit, and transporting and compressing oxygen generated in the membrane unit to the water separator.

On the other hand, the compressor is provided with a heat radiation fin for dissipating heat, the heat radiation fin is preferably in contact with the evaporator or extends to the inside of the evaporator.

1 is a block diagram showing an oxygen generator according to a preferred embodiment of the present invention, Figure 2 is a block diagram showing an oxygen generator according to another preferred embodiment of the present invention.

Referring to the drawings, the oxygen generator of the present invention, the membrane portion 20 is installed inside the membrane, the water separator 40 for separating the moisture of the oxygen generated from the membrane portion 20, and the water separator 40 And an evaporator 60 for evaporating the water separated therefrom.

The membrane portion 20 is configured to suck outside air. In addition, a membrane is installed inside the membrane portion 20 to filter nitrogen and allow oxygen to pass from outside air sucked in. That is, the outside air can be separated into a high oxygen concentration air and a high nitrogen concentration air by the membrane.

The oxygen generated by separation by the membrane is characterized by high temperature and high humidity due to the hydrophilic nature of the membrane, and has a humidity of about 95% or more higher than the inhaled outside air. In addition, the nitrogen generated by separation by the membrane has a humidity of about 30% or less, which is relatively lower than the oxygen.

The reason for the difference in humidity between oxygen and nitrogen as described above is that the humidity of the outside air sucked is unchanged in the membrane part 20. Therefore, if the humidity of the oxygen side is high, the humidity of the nitrogen side is lowered.

In addition, the moisture separator 40 serves to separate moisture from oxygen generated in the membrane portion 20. When the oxygen generated in the membrane portion 20 is discharged to the outside as the humidity is high, a pleasant environment is not formed around the oxygen generator, so that users around the oxygen generator may feel uncomfortable. In order to prevent such a situation, the water separator 40 separates moisture from oxygen of high humidity, and discharges oxygen having a humidity of 60% to the outside. Such a water separator 40 may be utilized by adopting a water separator used in the related art, and is not limited so long as it is a structure that separates water from oxygen generated in the membrane portion 20.

On the other hand, the present invention further comprises a compressor (80) for compressing and supplying the outside air to the membrane portion 20, compresses the oxygen generated in the membrane portion 20 to be transferred to the water separator (40).

That is, the compressor 80 is configured to communicate with the membrane portion 20 and the water separator 40, respectively.

As such, the compressor 80 generally inhales outside air having a humidity of about 70% or less. The compressor 80 then compresses the sucked outside air, which is compressed air having a humidity of at least about 95%.

In addition, the compressor 80 also serves to compress oxygen generated at the membrane portion 20 and high humidity to be transferred to the water separator 40.

In this way, the compressor 80 compresses and supplies external air to the membrane portion 20, and transfers the high humidity oxygen generated from the membrane portion 20 to the water separator 40. Is fitted.

On the other hand, the evaporator 60 receives the water separated by the water separator 40, and passes the nitrogen generated in the membrane portion 20 to evaporate the contained water.

That is, the evaporator 60 communicates with the water separator 40 and is formed in a predetermined space therein to receive the water separated by the water separator 40. In addition, the evaporator 60 is also in communication with the membrane portion 20 to suck the dry nitrogen generated from the membrane portion 20.

In this way, the evaporator 60 passes the sucked dry nitrogen therein to take the moisture contained in the dry nitrogen and discharge it to the outside.

In the evaporator 60 configured as described above, an inlet portion 62 through which nitrogen generated from the membrane portion 20 is introduced is formed at a lower portion thereof, and a discharge portion 64 through which the nitrogen is discharged to the outside is formed. Is formed. That is, the dry nitrogen generated from the membrane portion 20 is introduced into the evaporator 60 through the inlet formed in the lower portion of the evaporator 60 and discharged to the discharge portion 64 formed on the evaporator 60. .

As such, by being drawn into the lower part of the evaporator 60 and discharged to the upper part, it is possible to ensure the maximum time for the dry nitrogen to pass through the evaporator 60 to increase the contact time with the moisture contained therein to promote the drying nitrogen to take moisture. It works.

On the other hand, the evaporator 60, it is preferable that the foam member 66 of the porous material is installed to increase the surface area of the moisture and the nitrogen contacted therein.

That is, the foam member 66 of the porous material, so as to maximize the surface area that the nitrogen passing through the evaporator 60 in contact with the received moisture as possible.

As such, the foam member 66 of the porous snow material used in the evaporator 60 is not limited, and is configured to have a wide surface area where nitrogen and moisture contact each other as much as possible.

On the other hand, the compressor 80 is provided with a heat radiation fin 82 for dissipating heat. The compressor 80 emits a large amount of heat in the process of compressing air at high pressure, and is equipped with a heat dissipation fin 82 to efficiently discharge this heat to the outside in a short time.

In addition, the heat radiation fins 82 of the compressor 80 are in contact with the evaporator 60 or extends to the inside of the evaporator 60. The evaporator 60 serves to evaporate the high humidity oxygen generated from the membrane, which requires a certain amount of heat. At this time, the heat dissipation fin 82 having a high temperature installed in the compressor 80 is in contact with the evaporator 60 or extends to the inside of the evaporator 60, thereby promoting the evaporation of moisture in the evaporator 60.

According to the oxygen generator according to the present invention, the intake of the outside air, the membrane portion that separates nitrogen and oxygen by filtering the nitrogen in the inhaled outside air passes through the oxygen, separating the moisture from the oxygen generated in the membrane portion And a water separator to receive the water separated by the water separator, and an evaporator for evaporating the contained water while passing dry nitrogen generated in the membrane portion, thereby evaporating the water from the oxygen generated from the oxygen generator. Oxygen with adequate humidity can be supplied to the outside. In addition, the heat radiation fin having a high temperature installed in the compressor is in contact with the evaporator or extended to the inside of the evaporator, thereby facilitating evaporation of water in the evaporator.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

Claims (5)

A membrane portion 20 which separates nitrogen and oxygen by incorporating a membrane through which the outside air is sucked and the nitrogen is filtered and oxygen is passed through the sucked outside air; A water separator 40 for separating water from oxygen generated in the membrane part 20; And And an evaporator (60) for receiving the water separated by the water separator (40) and evaporating the contained water while passing the dry nitrogen generated from the membrane portion (20). The method of claim 1, The evaporator 60, Oxygen generator, characterized in that the inlet portion (62) is formed in the lower portion is the nitrogen is introduced from the membrane portion 20, the discharge portion (64) is discharged to the outside in the upper portion is formed. The method of claim 1, The evaporator 60, Oxygen generator, characterized in that the foam member 66 of the porous material is installed to increase the surface area of the moisture and the nitrogen contacted therein. The method of claim 1, Oxygen generator further comprises a compressor (80) for compressing and supplying the outside air to the membrane portion 20, the oxygen generated in the membrane portion 20 is transferred to the water separator 40 and compressed. . The method of claim 4, wherein The compressor 80 is provided with a heat dissipation fin 82 for dissipating heat, and the heat dissipation fin 82 is in contact with the evaporator 60 or extends to the inside of the evaporator 60 to increase the evaporation effect. Oxygen generator.

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