KR20230131303A - Oxigen generator with fine flow control - Google Patents

Abstract

The present invention relates to an oxygen generator, and in particular, includes a flow rate controller provided on one side of the zeolite unit to adjust the flow rate of extracted oxygen, wherein the flow rate controller includes a hollow housing and rotatable inside the housing, It is an oxygen generating device that includes a cylinder in communication with the zeolite unit and is capable of fine flow rate control that can precisely control the oxygen flow rate by controlling the flow rate of oxygen discharged by the rotation angle of the cylinder.

Description

Oxygen generator with fine flow rate control {OXIGEN GENERATOR WITH FINE FLOW CONTROL}

The present invention relates to an oxygen generator, and in particular, includes a flow rate controller provided on one side of the zeolite unit to adjust the flow rate of extracted oxygen, wherein the flow rate controller includes a hollow housing and rotatable inside the housing, It is an oxygen generating device that includes a cylinder in communication with the zeolite unit and is capable of fine flow rate control that can precisely control the oxygen flow rate by controlling the flow rate of oxygen discharged by the rotation angle of the cylinder.

Recently, oxygen generating devices have been widely used for environmental pollution or patient treatment. These oxygen generators mainly use water electrolysis techniques and oxygen extraction techniques.

As is widely known, the electrolysis technique generates oxygen by supplying electricity to water to separate oxygen. This electrolysis technique requires large-scale equipment and is difficult to manage, making it difficult to use in general homes or hospitals.

The oxygen extraction technique is intended to solve the problems of the electrolysis technique and uses the principle that nitrogen molecules are adsorbed to the adsorption tube as air passes through an adsorption tube filled with zeolite, and oxygen is extracted by passing through without being adsorbed. .

This oxygen extraction technique can miniaturize the equipment compared to the electrolysis technique, but it is difficult to precisely control the flow rate of extracted oxygen, making it difficult to use as a medical device for children.

Meanwhile, the above-described oxygen generating device itself is widely known and is described in detail in the prior art literature below, so description and illustration thereof will be omitted.

Korean Registered Patent No. 10-2208032 Korea Registered Patent No. 10-2291765 Korea Registered Utility Model No. 20-0435487

The present invention is intended to solve the above-described problem, and includes a flow rate controller provided on one side of the zeolite unit to adjust the flow rate of extracted oxygen, wherein the flow rate controller includes a hollow housing and a rotatable interior of the housing. The purpose is to provide an oxygen generator capable of fine flow rate control, which includes a cylinder in communication with the zeolite unit and can precisely control the oxygen flow rate by controlling the flow rate of oxygen discharged by the rotation angle of the cylinder. do.

However, the object of the present invention is not limited to the object mentioned above, and other object not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve the above object, the present invention includes a zeolite unit 300 that extracts oxygen from sucked air, and a flow rate controller 500 provided on one side of the zeolite unit 300 to adjust the flow rate of the extracted oxygen. It includes, and the flow rate control unit 500 includes a hollow housing 510 and a cylinder 520 rotatably provided inside the housing 510 and in communication with the zeolite unit 300, The cylinder 520 includes a cylindrical cylinder body 5210, a flow part 5220, a groove part 5230, and a discharge part 5240 formed in the cylinder body 5210, and the zeolite unit 300 ) Oxygen generated from the flow unit 5220 flows into the housing 510, and the groove 5230 is formed on the side of the cylinder body 5210 and is in close contact with the inner surface of the housing 510. , the discharge portion 5240 is formed inside the cylinder body 5210, communicates with the groove portion 5230, and is connected to the outside, so that as the cylinder body 5210 rotates, the groove portion 5230 moves into the housing ( 510) An oxygen generating device capable of fine flow rate control is provided by being in close contact with the inner surface or being open, and controlling the flow rate of oxygen by adjusting the open area of the groove portion 5230.

In the above, a lower part of the cylinder body 5210 of the cylinder 520 is disposed inside the housing 520, the upper side is exposed to the upper part of the housing 520, and the moving part 5220 is located in the cylinder body 5210. an introduction portion 5221 formed on the upper surface of the cylinder body 5210 and penetrating through the inside of the cylinder body 5210, and a discharge portion formed inside the cylinder body 5210, communicating with the introduction portion 5221, and penetrating through the side of the cylinder body 5210. It includes (5222), and the discharge portion 5222 extends to the outer surface of the cylinder body 5210 to form a discharge hole 5223, and the discharge hole 5223 is located inside the housing 510. The cylinder body 5210 is disposed inside the housing 510, and the introduction part 5221 communicates with the zeolite unit 300 to allow oxygen to enter the housing 510 through the discharge part 5222. is injected.

In the above, the housing 510 has a hollow shape and includes a housing body 5110 in which a portion of the cylinder 520 is disposed, a sealing block 5120 formed inside the housing body 5110, and the sealing block. (5120) includes a base 5130 disposed on the lower side, and the sealing block 5120 has an arc shape with a specific circumferential length and is in contact with the cylinder 520, so that the sealing block (5120) is in contact with the cylinder 520 according to the rotation of the cylinder 520. 5120 is in contact with or separated from the groove 5230 of the cylinder 520, and the base 5130 is formed at the center of the base body 5131 and the base body 5131 in a disk shape, and the cylinder 520 ) The lower side includes a through hole 5132 penetrating, and the interior of the housing body 5110 is filled with oxygen discharged through the discharge hole 5223 of the cylinder 520, and when the cylinder 520 rotates, Accordingly, the area where the groove portion 5230 is opened by the sealing block 5120 is adjusted so that oxygen is injected into the cylinder 520 through the groove portion 5230 and then discharged to the outside through the discharge portion 5240. .

In the above, the housing main body 5110 includes a hollow receiving part 5111, a protrusion 5112 formed on an upper part of the receiving part 5111, and a discharge hole formed on the bottom of the receiving part 5111. It includes (5113), and the cylinder 520 is introduced into the receiving part 5111 through the protrusion 5112, and the oxygen discharged through the discharge part 5240 of the cylinder 520 is supplied to the receiving part 5111. It is discharged to the outside of the housing 510 through the discharge hole 5113 of (5111).

In the above, the groove portion 5230 is grooved at a specific depth on the outer surface of the cylinder body 5210, and the discharge portion 5240 is formed by penetrating the bottom surface of the groove portion 5230 and then formed into the cylinder body 5210. extends to the floor.

In the above, the oxygen generator 10 includes a case 100 in which the zeolite unit 300 is disposed, and a discharge port provided on one side of the case 100 and communicating with the zeolite unit 300 ( 400), a sensing unit 600 connected to the zeolite unit 300, and a control unit (CON) and a display unit (DIS) provided on the outside of the case 100, and the sensing unit 600 A flow rate sensing unit 610 that measures the flow rate of oxygen discharged from the flow rate control unit 500, a concentration sensing unit 620 that measures the concentration of oxygen, and a temperature sensing unit 630 that measures the temperature of the oxygen. ), and the control unit (CON) analyzes the signal obtained from the sensing unit 600 to calculate the flow rate, concentration, and temperature and displays them on the display unit (DIS).

The 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 this specification and claims should not be construed in their usual, dictionary meaning, and the inventor may appropriately define the concept of the term in order to explain his or her invention in the best way. It should be interpreted with meaning and concept consistent with the technical idea of the present invention based on the principle that it is.

According to the present invention described above, the flow rate of oxygen can be precisely controlled, which has the effect of allowing it to be used as a medical device for pediatric patients.

1 is a schematic diagram of an oxygen generating device according to an embodiment of the present invention;
Figure 2 is a schematic diagram of the flow rate control unit of the oxygen generating device according to an embodiment of the present invention;
3 and 4 are schematic diagrams showing the operational relationship between the groove of the flow rate controller and the sealing block according to an embodiment of the present invention;
Figures 5 and 6 are an exploded perspective view showing the housing of the flow rate controller according to an embodiment of the present invention;
7 to 9 are partial cross-sectional perspective views of the cylinder of the flow rate controller according to an embodiment of the present invention, with the cylinder separated from the housing;
Figure 10 is an exploded perspective view of the flow rate control unit according to an embodiment of the present invention, with a portion of the cylinder and sealing block in the height direction cut and separated;
Figure 11 is a schematic diagram showing the connection relationship between the control unit and the sensing unit of the oxygen generator according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings. In this process, the thickness of lines or sizes of components shown in the drawing may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

In addition, the examples below do not limit the scope of the present invention, but are merely illustrative of the elements presented in the claims of the present invention, and are included in the technical idea throughout the specification of the present invention and constitute the scope of the claims. Embodiments that include elements that can be replaced as equivalents may be included in the scope of the present invention.

The oxygen generator 10 according to an embodiment of the present invention includes a zeolite unit 300 and a flow rate controller 500, as shown in FIG. 1. The zeolite unit 300 extracts oxygen from the sucked air, and since the zeolite unit 300 itself is a widely known configuration, its description and illustration are omitted.

The oxygen generator of the present invention includes a flow rate controller 500 provided on one side of the zeolite unit 300 to control the flow rate of the extracted oxygen.

This flow rate controller 500 and the zeolite unit 300 may be placed inside the case 100. This case 100 is provided with an air intake unit 200 and can be supplied to the zeolite unit 300 through a supply pipe (P1). The air intake unit 200 may use a widely known pump. As the air introduced into the zeolite unit 300 through the pipe P1 passes through the zeolite unit 300, oxygen is extracted. The extracted oxygen may be discharged through the discharge pipe (P2). The discharge pipe (P2) may be discharged to the outside of the case 100 in conjunction with the discharge port 400. To this end, the discharge port 400 may be installed penetrating the case 100.

As shown in FIG. 1, a plurality of zeolite units 300 may be provided, and accordingly, a plurality of discharge pipes P2 may also be provided. The flow rate control unit 500 can be installed in each of the discharge pipes (P2) (reference numeral 500-1), or it can also be installed as one unit after the discharge pipes are combined (refer to reference numeral 500-1). 2) see)

A sensing unit 600 may be provided inside or outside the case 100. This sensing unit 600 can be connected to the zeolite unit 300 to obtain various information. As shown in Figures 1 and 11, the sensing unit 600 includes a flow rate sensing unit 610 that measures the flow rate of oxygen discharged from the flow rate control unit 500, and a concentration sensing unit that measures the concentration of oxygen. It may include a unit 620 and a temperature sensing unit 630 that measures the temperature of the oxygen. The flow sensing unit 610 can use a well-known flow meter, the concentration sensing unit 620 can use a well-known concentration sensor, and the temperature sensing unit 630 can also use a well-known temperature sensor.

A control unit (CON) and a display unit (DIS) are provided outside the case 100. The control unit (CON) analyzes the signal obtained from the sensing unit 600, calculates the flow rate, concentration, and temperature, and then displays them on the display unit (DIS). At this time, the flow rate, concentration, temperature, etc. may be displayed digitally.

The flow rate control unit 500 includes a hollow housing 510, as shown in FIGS. 2 to 10, and a cylinder 520 rotatably provided inside the housing 510 and communicating with the zeolite unit. do. This cylinder 520 includes a cylindrical cylinder body 5210, a flow part 5220, a groove part 5230, and a discharge part 5240 formed in the cylinder body 5210. At this time, oxygen generated from the zeolite unit flows into the housing 510 through the moving part 5220.

That is, the cylinder 520 is placed inside the housing 510, and oxygen flows through the flowing part 5220 of the cylinder 520 and flows into the housing 510.

The groove portion 5230 is formed on the side of the cylinder body 5210 and is in close contact with the inner surface of the housing 510, and the discharge portion 5240 is formed inside the cylinder body 5210 and the groove portion 5230 It communicates with and is connected to the outside. That is, oxygen filled inside the housing 510 flows into the cylinder body 5210 through the groove portion 5230 and is then discharged to the outside through the discharge portion 5240. At this time, as described above, the groove portion 5230 is in close contact with the inner surface of the housing 510, and as the cylinder body 5210 rotates, the groove portion 5230 is in close contact with the inner surface of the housing 510. It is open.

As shown in FIG. 3, when the groove portion 5230 is in close contact with the inner surface of the housing 510, the groove portion 5230 is closed. Therefore, oxygen injected into the housing 510 cannot flow into the groove 5230 and thus cannot be discharged to the outside. At this time, as shown in FIG. 4, as the cylinder body 5210 rotates, the groove portion 5230 may be spaced apart from the inner surface of the housing 510 without being in close contact with it. In this case, the groove 5230 is opened and the air injected into the housing 510 is injected into the cylinder body through the groove 5230. In other words, by adjusting the opening angle of the groove 5230, the open area of the groove 5230 is adjusted, thereby adjusting the flow rate of oxygen introduced into the groove 5230, making it possible to precisely control the flow rate. .

The cylinder body 5210 of the cylinder 520 may have a cylindrical shape as shown, and the lower portion of the cylinder body 5210 is disposed inside the housing 520, and the upper portion is located on the upper portion of the housing 520. exposed. The moving part 5220 includes an introduction part 5221 and an outlet part 5222 formed in the cylinder body 5210. The introduction portion 5221 is formed on the upper surface of the cylinder body 5210 and penetrates the inside of the cylinder body 5210. The discharge portion 5222 is formed inside the cylinder body 5210, communicates with the introduction portion 5221, and penetrates the side of the cylinder body 5210. At this time, the introduction part 5221 is formed in the height direction of the cylinder body 5210, as shown, and the discharge part 5222 communicates with the lower end of the introduction part 5221 and may be formed to be tapered in the side direction. This discharge portion 5222 extends to the outer surface of the cylinder body 5210 to form a discharge hole 5223 on the outer surface of the cylinder body 5210. At this time, the cylinder body 5210 is located inside the housing 510 so that the discharge hole 5223 is located inside the housing 510. At this time, the introduction part 5221 communicates with the zeolite unit 300 to inject oxygen, and oxygen is injected into the housing 510 through the discharge part 5222.

That is, the oxygen is injected into the cylinder body 5210 through the introduction part 5221. The injected oxygen is discharged to the outside of the cylinder body 5210 through the discharge portion 5222 and the discharge hole 5223. At this time, since the discharge hole 5223 is located inside the housing 510, oxygen discharged through the discharge hole 5223 is injected into the housing 510.

The housing 510 has a hollow shape and includes a housing body 5110 in which a portion of the cylinder 520 is disposed, a sealing block 5120 formed inside the housing body 5110, and the sealing block 5120. It includes a base 5130 disposed on the lower side.

The sealing block 5120 has an arc shape with a specific circumferential length and is in contact with the cylinder 520. That is, the sealing block 5120 has a predetermined thickness t and its inner surface is in close contact with the cylinder 520. To this end, the inner surface curvature of the sealing block 5120 may be formed to be the same as the curvature of the cylinder 520. With this configuration, the sealing block 5120 contacts or separates from the groove 5230 of the cylinder 520 as the cylinder 520 rotates.

The base 5130 includes a disk-shaped base body 5131 and a through hole 5132 formed at the center of the base body 5131 and passing through the lower side of the cylinder 520. At this time, the interior of the housing body 5110 is filled with oxygen discharged through the discharge hole 5223 of the cylinder 520, as described above. In this state, as the cylinder 520 rotates, the area where the groove 5230 is opened by the sealing block 5120 is adjusted and oxygen is injected into the cylinder 520 through the groove 5230. It is discharged to the outside through the discharge part 5240.

The housing main body 5110 includes a hollow receiving part 5111, a protrusion 5112 formed on the upper part of the receiving part 5111, and a discharge hole 5113 formed on the bottom of the receiving part 5111. may include. The cylinder 520 can be inserted into the receiving portion 5111 through this protrusion 5112. In addition, oxygen discharged to the lower side of the cylinder 520 through the discharge portion 5240 of the cylinder 520 may be discharged to the outside of the housing 510 through the discharge hole 5113 of the receiving portion 5111. .

The groove portion 5230 is grooved on the outer surface of the cylinder body 5210 to a specific depth. At this time, the discharge portion 5240 is formed by penetrating the bottom surface of the groove portion 5230 and then extends to the bottom surface of the cylinder body 5210. That is, the bottom surface of the groove portion 5230 and the discharge portion 5240 communicate with each other. With this configuration, oxygen introduced into the groove portion 5230 is injected into the discharge portion 5240. Since the lower end of the discharge part 5240 is formed up to the bottom surface of the cylinder body 5210, oxygen injected into the discharge part 5240 is discharged toward the lower side of the cylinder 520 through the bottom surface of the cylinder body 5210. . The discharged oxygen may be discharged to the outside of the housing 510 through the discharge hole 5113 of the housing 510.

As described above, the area where the groove 5230 is opened by the sealing block 5120 is adjusted as the cylinder 520 rotates. As shown in FIG. 10, the opening angle θ of the groove portion 5230 is adjusted according to the rotation of the cylinder 520. As a result, the open area of the groove 5230 is adjusted, and as a result, the flow rate of oxygen injected into the groove 5230 is adjusted.

The oxygen generator of the present invention may further include a driving unit 700 that rotates the cylinder 520, as shown in FIG. 2. The driving unit 700 may include an actuator 710 that generates rotational force, and a gear unit 720 that transmits the rotational force generated by the actuator 710 to the cylinder body 5210. The actuator 710 may use a widely known electric motor. In order for the gear unit 720 to be coupled to the cylinder body 5210, teeth may be formed on the cylinder body 5210 to be coupled to the gear unit 720.

At this time, the control unit (CON) can control the rotation angle of the cylinder body 5210 by controlling the actuator 710, thereby precisely controlling the flow rate.

The cylinder 520 may include an introduction coupling portion 5250 formed at the top of the cylinder body 5210. This introduction part coupling part 5250 can be combined with the introduction part IN in communication with the zeolite unit to allow oxygen to be introduced into the cylinder body 5210.

Additionally, a connection portion 5140 is formed to extend downward around the discharge hole 5113 of the housing 510 and may communicate with a connection hose HS connected to the outside.

Although the present invention has been described in detail through specific examples, this is for detailed explanation of the present invention, and the present invention is not limited thereto, and can be understood by those skilled in the art within the technical spirit of the present invention. It is clear that modifications and improvements are possible.

All simple modifications or changes of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be made clear by the appended claims.

100: Case 200: Air intake unit
300: Zeolite unit 400: Discharge port
500: flow control unit 510: housing
5110: Housing body 5120: Sealed block
5130: Base 5140: Connection part
520: Cylinder 5210: Cylinder body
5220: floating part 5221: introduction part
5222: discharge part 5230: groove part
5240: discharge part

Claims (6)

It includes a zeolite unit 300 that extracts oxygen from the sucked air, and a flow rate controller 500 provided on one side of the zeolite unit 300 to adjust the flow rate of the extracted oxygen,
The flow rate control unit 500 includes a hollow housing 510 and a cylinder 520 rotatably provided inside the housing 510 and in communication with the zeolite unit 300,
The cylinder 520 includes a cylindrical cylinder body 5210, a moving part 5220, a groove 5230, and a discharge part 5240 formed in the cylinder body 5210,
Oxygen generated from the zeolite unit 300 flows into the housing 510 through the moving part 5220,
The groove 5230 is formed on the side of the cylinder body 5210 and is in close contact with the inner surface of the housing 510,
The discharge portion 5240 is formed inside the cylinder body 5210, communicates with the groove portion 5230, and is connected to the outside,
As the cylinder body 5210 rotates, the groove 5230 comes into close contact with the inner surface of the housing 510 or opens, and the open area of the groove 5230 is adjusted to control the flow rate of oxygen. Oxygen generator with adjustable flow rate. According to paragraph 1,
A lower portion of the cylinder body 5210 of the cylinder 520 is disposed inside the housing 520, and the upper portion is exposed to the upper part of the housing 520,
The moving part 5220 includes an introduction part 5221 formed on the upper surface of the cylinder body 5210 and penetrating inside the cylinder body 5210, and an introduction part 5221 formed inside the cylinder body 5210. It is in communication and includes a discharge portion 5222 penetrating through the side of the cylinder body 5210,
The discharge portion 5222 extends to the outer surface of the cylinder body 5210 to form a discharge hole 5223, and the cylinder body 5210 is housed so that the discharge hole 5223 is located inside the housing 510. (510) is placed inside,
The introduction part 5221 is in communication with the zeolite unit 300 to inject oxygen, and the oxygen is injected into the housing 510 through the discharge part 5222. An oxygen generator capable of fine flow rate control. According to paragraph 1,
The housing 510 has a hollow shape and includes a housing body 5110 in which a portion of the cylinder 520 is disposed, a sealing block 5120 formed inside the housing body 5110, and the sealing block 5120. It includes a base 5130 disposed on the lower side,
The sealing block 5120 has an arc shape with a specific circumferential length and is in contact with the cylinder 520, so that as the cylinder 520 rotates, the sealing block 5120 contacts the groove 5230 of the cylinder 520. touching or separating,
The base 5130 includes a disk-shaped base body 5131 and a through hole 5132 formed at the center of the base body 5131 and passing through the lower side of the cylinder 520,
The interior of the housing body 5110 is filled with oxygen discharged through the discharge hole 5223 of the cylinder 520,
As the cylinder 520 rotates, the area where the groove 5230 is opened by the sealing block 5120 is adjusted, and oxygen is injected into the cylinder 520 through the groove 5230, and then the discharge portion 5240 ), an oxygen generator capable of controlling the fine flow rate discharged to the outside. According to paragraph 3,
The housing main body 5110 includes a hollow receiving part 5111, a protrusion 5112 formed on the upper part of the receiving part 5111, and a discharge hole 5113 formed on the bottom of the receiving part 5111. Including,
The cylinder 520 is introduced into the receiving part 5111 through the protrusion 5112,
An oxygen generator capable of finely controlling the flow rate in which oxygen discharged through the discharge portion 5240 of the cylinder 520 is discharged to the outside of the housing 510 through the discharge hole 5113 of the receiving portion 5111. According to paragraph 4,
The groove portion 5230 is grooved at a specific depth on the outer surface of the cylinder body 5210,
The discharge part 5240 is formed by penetrating the bottom surface of the groove part 5230 and then extends to the bottom surface of the cylinder body 5210. An oxygen generating device capable of fine flow rate control. According to paragraph 1,
The oxygen generator 10 includes a case 100 in which the zeolite unit 300 is disposed, a discharge port 400 provided on one side of the case 100 and in communication with the zeolite unit 300, and , including a sensing unit 600 connected to the zeolite unit 300, a control unit (CON) and a display unit (DIS) provided on the outside of the case 100,
The sensing unit 600 includes a flow rate sensing unit 610 that measures the flow rate of oxygen discharged from the flow rate adjusting unit 500, a concentration sensing unit 620 that measures the concentration of the oxygen, and a temperature of the oxygen. It includes a temperature sensing unit 630 that measures,
The control unit (CON) analyzes the signal obtained from the sensing unit 600 to calculate flow rate, concentration, and temperature, and then displays them on the display unit (DIS). An oxygen generator capable of fine flow rate control.

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