KR20210050209A - High Purity Oxygen Generator - Google Patents

Abstract

The present invention relates to a high-purity oxygen generator. The high-purity oxygen generator includes: an air supplying unit having a suction port and a suction fan for sucking the air from the outside; an air compressing unit linked to the air supplying unit to compress the air; an oxygen separating unit linked to the air compressing unit to receive the compressed air and to separate nitrogen and oxygen contained in the air from each other; and an oxygen condensing unit linked to the oxygen separating unit to condense and discharge oxygen, wherein the air supplying unit includes: a temperature detector installed in the suction port for measuring the temperature of air and a constant-temperature module for turning on/off a cold/warmth module of a thermoelectric device, when the temperature of the temperature detector is lower than or higher than a predetermined value; and a humidity detector provided at one side of the temperature detector to measure the humidity of air and a constant-humidity module for removing moisture contained in air, when the humidity of the humidity detector is higher than a predetermined value. In this manner, according to the present invention, the filtered air free from impurities can be pressurized continuously to obtain high-purity oxygen, and the high-purity oxygen generator shows excellent efficiency to realize high competitiveness of products. In addition, the high-purity oxygen generator has a simple structure, is maintained and managed conveniently and allows economical oxygen production and supply, and particularly, can be downsized so that it may be applied to not only household and medical electronics but also various electronics, such as air purifiers and air conditioners, advantageously.

Description

High Purity Oxygen Generator

The present invention relates to a high-purity oxygen generator, and more particularly, to a high-purity oxygen generator capable of increasing the purity efficiency of oxygen by separating nitrogen and oxygen after continuously compressing air filtered from the atmosphere.

Not only has the air quality seriously deteriorated due to various environmental problems caused by rapid industrialization and urbanization, but also interest in air quality is increasing due to fine dust, and in recent years, along with air purifiers to filter pollutants in the air. Products related to oxygen generating devices that generate oxygen are receiving wide attention.

These oxygen generators are largely classified into a method of electrolyzing water, a method by reaction of chemical substances, and a method of oxygen concentration, but the method of electrolyzing water and the method by reaction of chemical substances are largely divided into large-sized facilities and In addition, there are difficulties in handling and management, and above all, it is difficult to downsize, making it unsuitable for use in homes, office spaces, hospitals, etc., and there are disadvantages that it cannot continuously produce oxygen.On the other hand, the oxygen concentration method has a simple structure. As it is economical and compact, and continuous oxygen production is possible, it is used by grafting it into various indoor spaces or devices such as household, medical, vehicle, and air conditioners.

On the other hand, the oxygen concentration method is typically applied with a pressure circulation adsorption technology.This pressure circulation adsorption technology is a technology that extracts and concentrates a target gas into a mixture of heterogeneous gases through pressure fluctuations, and uses physical adsorption and desorption properties. Safely produces oxygen without generating substances.

In other words, the pressure circulation adsorption method separates oxygen contained in the air, and uses the chemical properties of the artificial crystal, Geolite Molecular Sieve.The principle of separating oxygen from the air is the principle of separating oxygen from the air. It is due to the different adsorption power of the air molecules to the geolite molar sieve, and as the air passes through the adsorption tube filled with the geolite molar sieve, the adsorption of nitrogen molecules to the molar sieve is higher than that of the oxygen molecules. Nitrogen is adsorbed on the geolite molic sieve, and oxygen is separated from the air because oxygen passes through without being adsorbed.

As for the oxygen generator by the pressure circulation adsorption method according to the prior art, the oxygen generator of Republic of Korea Utility Model Publication No. 20-0435487 has an air inlet and an air outlet in claim 1, and compresses the air injected through the air inlet. The air compressor discharged through the air outlet, a compressed air pipe providing a flow path between the nitrogen separating unit and the nitrogen separating unit and the air outlet, and condensing oxygen by removing nitrogen from the compressed air introduced through the compressed air pipe. In an oxygen generator having an oxygen condensation unit for discharging the condensed oxygen and an oxygen discharge pipe connected to the oxygen discharge side of the oxygen condensation unit, an oxygen intake port and an oxygen outlet are formed, and oxygen discharge of the oxygen condensation unit through the oxygen inlet An oxygen generator connected to the side and comprising an oxygen pressurizer that increases and discharges the pressure of oxygen introduced from the oxygen condensing unit through the oxygen inlet, and the oxygen discharge pipe is connected to the oxygen outlet. Has been.

However, since the oxygen generator according to the prior art constitutes a separate oxygen pressurizer, the structure is complicated and there is a disadvantage in that there is a limitation in increasing the purity.

1 is a schematic view of an adsorption oxygen generator according to the prior art, wherein the adsorption oxygen generator according to the prior art includes a compressor 100, and first and second adsorption tubes 110 and 120 provided in a pair of left and right. , It consists of an orifice 300 at the end of the suction valve 200 and the discharge valve 210 and the pressure control valve 220 connecting the first and second suction pipes (110, 120) and the compressor (100).

The compressor 100 sucks and compresses air in the atmosphere, and a compressor is used, and the air compressed by the compressor 100 is selectively sent to one of the first and second suction pipes 110 and 120, At this time, the suction valve 200 of the adsorption pipes 110 and 120 is opened, and when the suction is completed, the valve is closed.

On the other hand, the intake valve 200 and the discharge valve 210, the pressure control valve 220 is a solenoid valve that is regulated to open and close by receiving a control signal from a controller is used.

The inside of the adsorption tubes 110 and 120 is filled with a geolite molar sieve for adsorbing nitrogen in the air, and gases other than oxygen in the adsorption tubes 110 and 120 for a certain period of time, such as nitrogen, carbon dioxide, and carbon monoxide. , When moisture is adsorbed, the separated oxygen is moved to the oxygen storage tank 400 through the orifice 300, and the geolite molar sieve filled in the adsorption tubes 110 and 120 discharges the adsorbed gas molecules to the outside. Only after purification can it be used continuously.

In addition, when oxygen is discharged from the first adsorption tubes 110 through the orifice 300, some of the oxygen discharged is moved to the second adsorption tube 120 while the pressure control valve 220 is opened. In the adsorption pipe 120, the gas component adsorbed by the introduced oxygen is separated from the geolite molar sieve, and the gas separated from the geolite molar sieve is discharged to the outside by opening of the discharge valve 210.

The oxygen generator according to the prior art constituted as described above has a complicated structure, but it is difficult to guarantee the reliability of operation because the organic operation between each part must be performed accurately, and there is a problem that the noise is large due to the severe pressure change of the compressed air. there was.

Registered Utility Model Publication No. 20-0435487 (2007.01.19.) Patent Registration Publication No. 10-2014-0020744 (February 19, 2014)

The present invention was created in order to solve the problems of the prior art as described above, and an object of the present invention is to continuously pressurize the separated oxygen via a geolite molar sieve after continuously compressing the air filtered from the atmosphere. It is to provide a high-purity oxygen generating device that enables high-purity oxygen to be obtained.

A high-purity oxygen generating apparatus according to a preferred embodiment of the present invention for realizing the above object comprises: an air supply unit having an inlet and a suction fan for inhaling air from the outside; An air compression unit connected to the air supply unit to compress the introduced air; An oxygen separation unit connected to the air compression unit to receive compressed air to separate nitrogen and oxygen contained in the air; In the high-purity oxygen generator comprising an oxygen condensing unit connected to the oxygen separation unit to condense and discharge oxygen, the air supply unit includes a temperature sensor that measures the temperature of air installed at the inlet, and the temperature of the temperature sensor is less than or exceeds a set value. In this case, a constant temperature module for turning on and off the cold/hot module as a thermoelectric element; and a humidity sensor provided at one side of the temperature sensor to measure the humidity of the incoming air, and in the incoming air when the humidity of the humidity sensor exceeds a set value. It characterized in that it is configured to further include a humidity module for removing the contained moisture.

As a preferred feature of the present invention, the air supply unit is provided with the intake port and an air tank for storing air; and the humidity control module is provided in the air tank and includes a dehumidification unit disposed on a conduit through which the introduced air passes. However, the dehumidifying unit includes a casing having an inlet and outlet through which air flows in and out, a hygroscopic material made of zeolite that absorbs moisture contained in the air by filling the inside of the casing, and senses humidity in the casing. It consists of a casing humidity sensor and a reduction heater that stops air intake and heats the zeolite to remove moisture when the humidity of the casing humidity sensor is higher than the set value.

As another preferred feature of the present invention, the air compression unit includes a compressor that sucks the introduced air and compresses it to a set pressure, and a compressor control unit that controls the operation of the compressor.

As another preferred feature of the present invention, the oxygen separation unit comprises: a first adsorption tube and a second adsorption tube connected to the air compressor through a pipeline; A geolite molar sieve filled in the first and second adsorption tubes to adsorb nitrogen; It consists of a; discharge valve for discharging oxygen through the first and second suction pipes.

As another preferred feature of the present invention, the oxygen condensing unit is connected to the oxygen separating unit and the oxygen tank through a pipeline to receive the collected oxygen, a condensation pump for controlling the pressure in the oxygen tank, and the oxygen in the oxygen tank to the outside. It consists of a diffusion nozzle for discharging into the furnace.

The high-purity oxygen generator according to the present invention obtains high-purity oxygen by continuously pressurizing the filtered air from which impurities have been removed, so that it is expected to have a useful effect that can increase the competitiveness of a product because it is excellent in efficiency.

In addition, the present invention can be economically produced and supplied due to its simple structure and good maintenance convenience. In particular, as it can be miniaturized, it can be applied to various electronic products such as air purifiers and air conditioners as well as home and medical use. There are possible advantages.

Features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms or words used in the present specification and claims should not be interpreted in a conventional and dictionary meaning, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

1 is a view schematically showing an adsorption oxygen generator according to the prior art;
Figure 2 is a block diagram for explaining the overall configuration of the high-purity oxygen generating device according to the present invention,
Figure 3 is a block diagram for explaining the configuration of the air compression unit in the high purity oxygen generating device according to the present invention,
Figure 4 is a block diagram for explaining the configuration of the oxygen separation unit in the high-purity oxygen generating device according to the present invention,
Figure 5 is a block diagram for explaining the configuration of the oxygen condensing unit in the high purity oxygen generating device according to the present invention,

Hereinafter, a configuration and operation of an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

However, it is not intended to limit the present invention to a specific disclosed form, and it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention. In the present application, terms such as "comprise" or "have" are intended to designate the existence of features, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features, steps, and actions. It is to be understood that the possibility of the presence or addition of, components, parts, or combinations thereof is not preliminarily excluded. That is, throughout the specification, when a certain part "includes" a certain constituent element, it means that other constituent elements may be further included rather than excluding other constituent elements unless otherwise stated.

In addition, unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Does not.

Here, repeated descriptions, known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of configurations are omitted so as not to obscure the subject matter of the present invention.

Embodiments of the present invention are provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

2 is a block diagram for explaining the overall configuration of a high-purity oxygen generating device according to the present invention.

In the drawing, an air supply unit 10 having an intake port for inhaling air from the outside and a suction fan providing air suction input, and an air compression unit connected to the air supply unit 10 to compress the introduced air at a predetermined pressure. (20), an oxygen separation unit 30 connected to the air compression unit 20 to receive compressed air and adsorb nitrogen contained in the air to separate oxygen, and connected to the oxygen separation unit 30 A high-purity oxygen generating device is shown, comprising an oxygen condensing unit 40 that receives and condenses the separated oxygen, and the air supply unit 10 includes a constant temperature module and a humidity control module.

3 is a block diagram for explaining the configuration of an air compression unit in the high purity oxygen generating device according to the present invention.

In the drawing, an air supply unit 10 having an intake port and a suction fan for inhaling indoor air, a compressor that is connected to the air supply unit 10 through a pipeline to compress the introduced air to a predetermined pressure, and controls the compressor. An air compression unit 20 consisting of a control unit, an oxygen separation unit 30 connected to the air compression unit 20 to receive compressed air and adsorb nitrogen contained in the air to separate oxygen, and the oxygen separation A high-purity oxygen generating device is shown, which is connected to the unit 30 and is composed of an oxygen condensing unit 40 that receives and condenses the separated oxygen.

Figure 4 is a block diagram for explaining the configuration of the oxygen separation unit in the high-purity oxygen generating device according to the present invention.

In the drawing, an air supply unit 10 having an intake port and a suction fan for inhaling indoor air, an air compression unit 20 connected to the air supply unit 10 through a pipeline to compress the introduced air at a predetermined pressure, and , It is connected to the air compression unit 20 to receive compressed air and adsorbs nitrogen contained in the air to separate oxygen, and is connected to the air compression unit 20 to sequentially receive compressed air. An oxygen separating unit 30 comprising a first adsorption pipe and a second adsorption tube filled with a molar sheave, and a discharge valve provided on the discharge lines of the first and second adsorption tubes, and the oxygen separation unit 30 There is shown a high-purity oxygen generating device consisting of an oxygen condensing unit 40 that is connected to and condensed by receiving the separated oxygen.

5 is a block diagram for explaining the configuration of an oxygen condensing unit in the high purity oxygen generating device according to the present invention.

In the drawing, an air compression unit consisting of an air supply unit 10 having an intake port and a suction fan for inhaling indoor air, and a control unit connected to the air supply unit 10 through a pipeline to compress the introduced air at a predetermined pressure ( 20), an oxygen separation unit 30 connected to the air compression unit 20 to receive compressed air and adsorb nitrogen contained in the air to separate oxygen, and is connected to the oxygen separation unit 30 Consisting of an oxygen condensing unit 40 consisting of an oxygen tank that stores oxygen by receiving and condensing separated oxygen, a condensation pump for compressing oxygen in the oxygen tank, and a diffusion nozzle for exhausting the condensed oxygen to the outside. A high purity oxygen generating device is shown.

A configuration of a high-purity oxygen generator according to the present invention will be described with reference to the above drawings.

The present invention is composed of an air supply unit 10, an air compression unit 20, an oxygen separation unit 30 and an oxygen condensation unit 40.

The air supply unit 10 is an element for inhaling air from the outside, and includes an inlet for inhaling air, an air tank for temporarily storing air, and a suction fan that receives power from the outside and drives intake.

A filtration filter for removing pollutants and suspended matter contained in the air is installed at the inlet.

The air supply unit 10 is configured to include a constant temperature module and a humidity module for allowing the incoming air to have a constant temperature and humidity as well.

The humidity control module is configured to include a dehumidifying unit, and at this time, the dehumidifying unit is provided in the air tank and disposed on a conduit through which the introduced air passes.

Such a dehumidifying unit includes a casing having an inlet and outlet through which air flows in and out, and a casing with an empty inside, a hygroscopic material made of zeolite that absorbs moisture contained in the air by filling the inside of the casing, and the humidity in the casing. When the humidity of the sensing casing humidity sensor and the humidity of the casing is higher than the set value, a reduction heater that stops air intake and heats the zeolite to remove moisture, and an outlet for discharging the air in the casing to the outside when the reduction heater acts. It consists of an exhaust fan.

The air compression unit 20 is an element connected to the air supply unit 10 to compress the introduced air, and includes a compressor that inhales largely introduced air and compresses it to a set pressure, and a compressor control unit that controls the operation of the compressor. It is composed.

Since the compressor is an element for inhaling and compressing air, a detailed description thereof will be omitted.

The compressor control unit controls the operation of the compressor, and may be operated by receiving a control signal from the main controller that controls the operation of the high-purity oxygen generator, or may be replaced by the main controller.

The oxygen separation unit 30 is an element connected to the air compression unit 20 to receive compressed air and separate nitrogen and oxygen contained in the air.

The oxygen separating unit 30 is composed of a first adsorption tube and a second adsorption tube connected to the air compression unit 20 through a pipeline, and adsorbs nitrogen contained in the air inside the first and second adsorption tubes. Geolite Molycular Sieve is charged.

In addition, each of the first adsorption pipe and the second adsorption tube has a discharge pipe for discharging separate oxygen, and a discharge valve for discharging oxygen is provided in the discharge pipes.

The oxygen condensing unit 40 is an element connected to the oxygen separating unit 30 to condense the supplied oxygen, and an oxygen tank connected to the oxygen separating unit 30 to receive the collected oxygen, and the oxygen It consists of a condensation pump for controlling the pressure in the tank and a diffusion nozzle for discharging oxygen in the oxygen tank to the outside.

Here, the diffusion nozzle may be configured to selectively discharge condensed oxygen by additionally installing a nozzle valve, and may be configured to apply a control signal for stopping the operation of the device when the pressure in the oxygen tank is high.

A high-purity oxygen generator according to the present invention configured as described above will be described as follows.

First, when the suction fan constituting the air supply unit 10 starts to suck air from the outside, it passes through the filtration filter and removes contaminants contained in the air, and the filtered air passes through the air supply unit 10. It has an appropriate temperature and humidity through the constituting constant temperature module and humidity module.

In other words, when the temperature is low, the oxygen capture rate decreases, so adjust to reach the set temperature (10℃~40℃). Even when the humidity is high, the oxygen capture rate decreases, so use a humidity control module to adjust the proper humidity. do. At this time, the humidity module is operated only when the humidity is high.

Subsequently, the clean air that has passed through the air supply unit 10 is supplied to the air compression unit 20 and is compressed to an appropriate pressure. The compressed air is supplied to the oxygen separation unit 30 again, and the air supplied to the oxygen separation unit 30 is supplied to the first and second adsorption pipes filled with the geolite molar sieve to separate oxygen and nitrogen. Then, the separated oxygen is supplied to the oxygen condensing unit 40.

Finally, the oxygen supplied to the oxygen condensing unit 40 is compressed by the condensing pump again to increase the oxygen concentration, and the high-purity concentrated oxygen is exhausted to the outside through the diffusion nozzle.

The high-purity oxygen generating device of this configuration can increase the oxygen purity efficiency at the same flow rate compared to the conventional oxygen generating device, and continuously through the configuration of the oxygen separation unit 30 consisting of a first adsorption tube and a second adsorption tube. It was confirmed that the production amount of oxygen can be increased by more than 2 times and the purity efficiency can be increased by more than 5% because it is compressed to produce oxygen and nitrogen separately.

On the other hand, the present invention is not limited to the described embodiments, it is possible to use it by changing the application site, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have knowledge. Therefore, such modifications or modifications will have to belong to the scope of the claims of the present invention.

10: air supply
20: air compression unit
30: oxygen separation unit
40: oxygen condensation part

Claims (5)

An air supply unit having a suction port and a suction fan for suctioning air from the outside;
An air compression unit connected to the air supply unit to compress the introduced air;
An oxygen separation unit connected to the air compression unit to receive compressed air to separate nitrogen and oxygen contained in the air;
In the high-purity oxygen generating device comprising an oxygen condensing unit connected to the oxygen separation unit to condense and discharge oxygen,
The air supply unit includes a temperature sensor for measuring the temperature of air installed in the intake port, and a constant temperature module for turning on and off a cold/hot module made of a thermoelectric element when the temperature of the temperature sensor is less than or exceeds a set value; and is provided on one side of the temperature sensor. And a humidity sensor configured to measure the humidity of the incoming air and a humidity module configured to remove moisture contained in the incoming air when the humidity of the humidity sensor exceeds a set value. The method of claim 1, wherein the air supply unit is provided as an air tank storing the air inlet and the air;,
The humidity control module includes a dehumidifying unit provided in the air tank and disposed on a conduit through which the introduced air passes, and the dehumidifying unit includes a casing having an inlet and an outlet through which air is introduced and discharged, and the inside of the casing is filled. The moisture absorbing material consisting of zeolite that absorbs moisture contained in the air, and a casing humidity sensor that senses the humidity in the casing, and when the humidity of the casing humidity sensor is higher than the set value, stop inhaling air and heat the zeolite to remove moisture. High purity oxygen generating device comprising a reduction heater to remove. The high-purity oxygen generator according to claim 1, wherein the air compression unit includes a compressor that sucks the introduced air and compresses it to a set pressure, and a compressor control unit that controls the operation of the compressor. The apparatus of claim 1, wherein the oxygen separation unit comprises: a first suction pipe and a second suction pipe connected to the air compressor through a pipe; A geolite molar sieve filled in the first and second adsorption tubes to adsorb nitrogen; A high-purity oxygen generating device comprising: a discharge valve for discharging oxygen through the first and second adsorption pipes. The oxygen condensing unit of claim 1, wherein the oxygen condensing unit is connected to the oxygen separating unit through a pipeline to receive the collected oxygen, a condensation pump that controls the pressure in the oxygen tank, and the oxygen in the oxygen tank is discharged to the outside. High purity oxygen generating device, characterized in that consisting of a diffusion nozzle for.

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