KR200345383Y1 - A valve for an oxygen generator - Google Patents

Abstract

The present invention relates to a valve for the oxygen generator, the air is sucked into the inlet by the air pump, the air transferred to the inlet is transferred to the injection groove of the control panel in close contact with the bottom of the communication plate through the inlet of the communication plate The air injected into the injection groove is transferred to a supply groove communicating with the injection groove, and is supplied to the adsorption tower through two communication ports formed in the communication plate, and nitrogen separated from the adsorption tower communicates with one of the communication holes. It is conveyed through the sphere is to be discharged through the discharge port communicated with the one communication port, and despite the rotation of the control panel is always the two communication port and the supply groove is in communication and the one communication port and the discharge groove is in communication.

Description

A valve for oxygen generator {A VALVE FOR AN OXYGEN GENERATOR}

The present invention relates to an oxygen generator, and more particularly, to an oxygen generator valve for supplying air to the adsorption tower and discharging nitrogen or the like separated from the adsorption tower.

In general, oxygen generators are used in patients requiring oxygen supply, in workplaces such as factories, subways, and other places where homes are not well-suited for air circulation. It is common to separate and discharge foreign substances such as nitrogen and to supply only the oxygen to a predetermined place.

Here, the oxygen generator is an intake port for sucking external air, an adsorption tower filled with an adsorbent to separate foreign substances such as nitrogen from the sucked air, and a discharge port for supplying only oxygen remaining after the foreign matter is separated from the adsorption tower to a specific place. And, it is generally composed of a discharge port for discharging foreign matters such as nitrogen.

In addition, the connection pipe connecting the suction port and the discharge port with the adsorption tower is usually configured to control the concentration of the oxygen by a single, and through the connection pipe to the air supply and the discharge to achieve the discharge of nitrogen, etc. It is common for the outlet and the connection pipe to be interconnected by a valve which is able to change the flow of gas.

Here, the valve is connected to each of the respective pipes to control the inlet and outlet and the connection pipe, respectively, and the connector of the box at the same time to open and close the connector of the box to which all three pipes are connected in sequence 1 There have been developments such as opening / closing dogs or two.

However, the conventional valve as described above has a problem in that its configuration is complicated and control thereof is difficult.

In addition, the conventional valve has a problem that the efficiency is lower than the configuration and control operation.

In addition, the conventional oxygen generator is a valve for controlling the intake or exhaust of the atmosphere, oxygen and nitrogen, respectively, by stirring each gas to improve the oxygen separation efficiency, and to control the degree of nitrogen discharge to control the purity of the There was a problem that each should be provided with a stirrer.

The present invention is designed to solve the above problems, the object is to provide a valve for the oxygen generator to achieve a simple structure and control operation.

Another object of the present invention is to provide a valve for an oxygen generator, which is adapted to appropriately adjust the amount of oxygen received and discharged in the adsorption column and the atmosphere to be sucked.

Still another object of the present invention is to provide an oxygen generator valve configured to simultaneously achieve intake / exhaust of each gas and agitation of the gas.

1 is a schematic diagram of an oxygen generator according to the present invention,

2 is a perspective view of a valve for an oxygen generator according to the present invention,

3 is a plan view of an oxygen generator valve according to the present invention.

<Description of Major Symbols in Drawing>

10-adsorption tower 11-adsorbent

12-outlet 20-air pump

21-inlet 30-outlet

40-motor 50-valve

51-housing 52-connector

60-communicating plate 61-inlet

62-Communication holes 70-Control panel

71-blocking surface 72-outlet groove

73-suction groove 74-injection groove

75-Supply Home

The present invention for achieving the above object is characterized in that the inlet for inhaling the atmosphere, the outlet for discharging foreign substances such as nitrogen and the connection pipe connected to the adsorption tower.

Another feature of the present invention, the housing is formed so that the interior is hollow to cover the communication plate of the valve so that the atmosphere supplied from the valve and nitrogen discharged to the valve is first collected between the connecting pipe connected to the valve and the adsorption tower Characterized in that it is provided.

Another feature of the present invention, there is provided with a communication plate formed with an inlet opening to allow the atmosphere to be sucked, and a plurality of communication ports opened to supply the atmosphere to the adsorption tower or to discharge nitrogen separated from the adsorption tower through the discharge groove. It is characterized by.

Another feature of the present invention, the injection groove recessed to receive the air sucked through the injection port to guide the supply groove, and to communicate with the injection groove to transfer the air transferred from the injection groove to the adsorption tower through the communication port. A recessed supply groove and a discharge groove recessed to discharge nitrogen discharged from the adsorption tower and transported through the communication port are formed, and a control panel is formed to be in close contact with the communication plate.

Another feature of the present invention is that the control panel is installed in close contact with the bottom surface of the communication plate and the control panel is rotated in close contact with the bottom surface of the communication plate by the driving force of the motor while inhalation of the atmosphere and discharge of nitrogen Characterized in that to achieve.

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

1 illustrates a schematic configuration of an oxygen generator according to the present invention, FIG. 2 shows each component of the valve 50 according to the present invention, and FIG. 3 shows an inlet 61 of the valve 50 according to the present invention. ) And the communication port 62 and the injection groove 74 and the supply groove 75 and the discharge groove 72 shows the relationship between the operation of the oxygen generator valve 50.

The present invention includes a housing 51, a communication tube, and a control panel 70.

The housing 51 is formed in a semi-spherical box shape in which the inside thereof is hollow so as to cover the entire upper surface of the communication plate 60, which will be described later, and collect the gas flowing through the communication plate 60. The connecting pipe 52 connected to the 10 is fastened to the upper end thereof.

The communication plate 60 is formed in a circular plate shape and is fixed to the lower portion of the oxygen generator, and includes an injection port 61 and a communication port 62.

The inlet 61 is formed in a circular opening in the center of the communication plate 60, the front end of the inlet 21 formed in a tubular shape to convey the outside air or indoor air sucked by the air pump 20 Connected.

The communication port 62 is circularly arranged at equal intervals in the circular arc portion of the communication plate 60 and is opened in a circular manner. In this embodiment, five communication ports 62 forming an equal interval are provided in the communication plate 60. The opening is formed in contact with the arc.

The control panel 70 is formed in a circular plate shape that is the same as the shape of the communication plate 60 to be in close contact with the bottom surface of the communication plate 60, the circular shape forming the same diameter as the diameter of the communication plate 60. It is formed into a plate shape.

In addition, the control panel 70 is formed by recessing a motor shaft groove (not shown) so that the motor shaft of the motor 40 that is rotated in response to the application of power to the lower end thereof is fixed.

In addition, the control panel 70 includes a blocking surface 71, a discharge groove 72, and a suction groove 73.

The blocking surface 71 is formed in a horizontal plane that is in close contact with the bottom surface of the communication plate 60 so that the upper surface of the control panel 70 is horizontal with the bottom surface of the communication plate 60 so that there is no leakage of gas. Is done.

The discharge groove 72 is formed by recessing one side of the blocking surface 71 of the control panel 70 in a box shape to the inside, and in this embodiment, the control panel 70 along the circumferential shape of the control panel 70. A portion of the edge is formed in a cut shape at the point where the upper surface and the side meet.

In addition, the discharge groove 72 has two communication ports 62 are always arranged in the five communication holes 62 in the supply groove 75 to be described later, and at the same time the one communication hole 62 is discharge groove 72 It is preferable to divide the circumference of the circular blocking surface 71 into six equal parts, and to have a width equal to the circumferential width of one sixth of them.

The suction groove 73 includes an injection groove 74 and a supply groove 75.

The injection groove 74 is discharged from the center of the upper end of the control panel 70 to accommodate the air flowing through the injection port 61 of the communication plate 60 and to guide in the direction of the supply groove 75 at the same time. It is formed to be recessed in the shape of a groove forming a straight line in the direction opposite to the groove 72, it is formed to be recessed from the center of the control panel 70 to a position close to the circumference of the control panel (70).

The supply groove 75 communicates with the injection groove 74 at the center thereof, and is formed in a semicircular cylindrical shape along the circumference of the blocking surface 71 in the opposite direction to the discharge groove 72. .

In addition, the supply groove 75 is a blocking surface of the control panel 70 with respect to the five communication ports 62 formed at each of the five branch points of the communication plate 60 so as to always communicate with the two communication ports 62. The 71 is divided into six equal parts so as to have a width equal to the width of two consecutive equal parts.

Next will be described the operation of the valve for the oxygen generator according to the present invention configured as described above.

As shown in FIG. 1, the atmosphere is transferred to the inlet 61 of the communication plate 60 through the inlet 21 by the driving force of the air pump 20.

The atmosphere transferred to the injection hole 61 is transferred to the injection groove 74 communicated with the lower end of the injection hole 61, and the atmosphere transferred to the injection groove 74 is along the shape of the injection groove 74. It is conveyed in the circumferential direction of one side of the blocking surface (71).

The atmosphere transferred in one circumferential direction of the blocking surface 71 is transferred to the supply groove 75 in communication with the injection groove 74, wherein the supply groove 75 communicated with the injection groove 74 is As the air is formed on both sides of the injection groove 74 along the circumference of the control panel 70, the atmosphere is uniformly transferred from the injection groove 74 to both supply grooves 75.

Here, the air transported to the injection groove 74 and the supply groove 75 is the injection groove 74 and the supply groove 75 as the communication plate 60 is in close contact with the upper end of the blocking surface 71. Are accommodated within.

As shown in FIG. 3, the air transferred to the supply groove 75 has two communication ports 62 out of the five communication ports 62 opened in the communication plate 60. As it is located at the upper end of the opening is filled into the housing 51 fastened to the upper end of the communication plate 60 through the two communication ports 62.

The atmosphere filled into the housing 51 is supplied into the tubular adsorption tower 10 connected to the upper end of the connecting pipe 52 through the connecting pipe 52 connected to the upper end of the housing 51. .

In the atmosphere supplied to the adsorption tower 10, foreign substances such as nitrogen are separated from the components by an adsorbent 11 such as zeolite filled in the adsorption tower 10, and foreign substances such as nitrogen are separated. The oxygen remaining in the atmosphere is supplied to the place where the supply of oxygen is required through the discharge port communicated with the upper end of the adsorption tower (10).

Here, the oxygen is usually contained 21% in the atmosphere, the foreign matter such as nitrogen is separated from the interior of the adsorption tower 10 to produce oxygen having a purity of 60 to 95%, in this embodiment, such as in homes and workplaces It is preferable to generate oxygen having a purity of 60 to 70% which can be commonly used to be supplied through the discharge port.

In addition, foreign matter such as nitrogen separated by the adsorbent 11 from the adsorption tower 10 is transferred to the connection pipe 52 through an opening in the lower or side surface of the adsorption tower 10.

At this time, the nitrogen in the adsorption tower 10 is external to the adsorption tower 10 by the filling pressure in the adsorption tower 10 of another atmosphere that is continuously supplied through the supply groove 75 and the two communication ports 62. It is discharged while pressurized.

Nitrogen transferred to the connection pipe 52 is filled into the inside of the housing 51 fastened to the lower end of the connection pipe 52 and five of the communication plates 60 fastened to the lower end of the housing 51. The communication port 62 is discharged through the one communication port 62 communicated with the discharge groove 72 of the control panel 70 is transferred to the discharge groove (72).

Nitrogen transferred to the discharge groove 72 is discharged to the outside of the oxygen generator through the discharge port 30 connected to the box surrounding the outside of the control panel 70 of the valve 50.

At this time, the control panel 70 is to be continuously rotated in close contact with the lower end of the communication plate 60 for the stirring of the atmosphere and nitrogen, the two communication port regardless of the rotation of the control panel 70 The air is supplied through 62, and the communication ports 62 are respectively opened at five equal points so that nitrogen is discharged through another communication port 62, and the supply grooves 75 are six equal circumferences. It is formed to have the same width as the two equal widths of, and the discharge groove 72 is formed to have the same width as one equal width of the six equal circumference and to cut and cut.

Therefore, air is injected into the adsorption tower 10 through the two communication ports 62, oxygen of about 50% of the air separated from the adsorption tower 10 is supplied through the discharge port, and the oxygen is discharged. Nitrogen in an amount of about 50% of the atmosphere, such as nitrogen, is discharged to the outside of the oxygen generator through the one communication port 62 and the discharge groove 72 so that the indoor pressure of the adsorption tower 10 is always maintained uniformly. .

In addition, as the control panel 70 is continuously rotated by the driving force of the motor 40 to achieve supply of the atmosphere and discharge of nitrogen, the atmosphere and nitrogen are agitated to intake and exhaust.

Here, the agitation of the atmosphere is the atmosphere filled with the supply groove 75 through the injection groove 74 is rotated continuously the supply groove 75, the two communication ports (62) of the five communication port (62) 62) through each of them is sequentially supplied into the housing 51 so that the atmosphere is sequentially supplied along the inner circumference of the housing 51, the atmosphere is sequentially supplied to each of the outer circumference of the housing 51 While being rotated by the atmospheric pressure is sequentially supplied to the adsorption tower 10 through the connecting pipe 52 to make a rotation in the adsorption tower 10 to contact more adsorbent (11) to separate the nitrogen, The nitrogen discharged from the adsorption tower 10 rotates through one communication port 62 among five communication ports 62 which are sequentially opened at the lower end of the housing 51 according to the rotated discharge groove 72. Is discharged, and this rotation The nitrogen is discharged while being rotated in the connecting pipe 52 and the housing 51 by an output to achieve intake / exhaust while the atmosphere and nitrogen are rotated at separate positions with a difference of mass different from the atmosphere supplied while being rotated. .

In addition, by controlling the mixing rate of the atmosphere and nitrogen or the degree of rotation of the atmosphere to control the separation rate of oxygen, that is, the purity of oxygen.

In the present embodiment, five communication ports 62 are formed in the communication plate 60, and the supply groove 75 of the control panel 70 that is rotated communicates with the two communication ports 62 and discharge grooves ( 72 is formed to communicate with the one communication port 62, but the communication port 62 so that the amount of air supplied to the adsorption tower 10 and the amount of oxygen discharged and nitrogen discharged is 2: 1: 1. Of course, the width of the supply groove 75 and the width of the discharge groove 72 may be formed to be adjusted.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person having ordinary skill in the art to which the present invention belongs without departing from the gist of the present invention claimed in the claims, various modifications Of course, such changes are within the scope of the claims.

As described above, according to the present invention, there is an effect that the stirring of the atmosphere and nitrogen is achieved while constantly maintaining the supply amount of the atmosphere and the amount of nitrogen discharged.

Another effect of the present invention is to control the intake / exhaust of the atmosphere and nitrogen and at the same time to agitate the atmosphere and nitrogen.

Another effect of the present invention, there is an effect that can generate oxygen by a simple configuration and control operation.

Another effect of the present invention, there is an effect to control the purity of oxygen by a simple control operation, such as the rotational force control of the control panel.

Claims (3)

A housing formed in a hollow interior to cover an upper portion of the communication plate while communicating with an end of a connection pipe connected to an adsorption tower separating oxygen from the atmosphere; A communication plate formed in a circular plate shape to be fastened to the lower end of the housing and having an opening for injecting air into the center thereof and opening a plurality of communication holes in the arc; A control panel formed in a circular plate shape to be in close contact with the bottom surface of the communication plate; An injection groove recessed at an upper end of the control panel so as to communicate with the injection hole and extend in the circumferential direction; A supply groove recessed in an arc shape along the circumference of the control panel in the injection groove so as to communicate with the two communication ports; A discharge groove formed by recessing an edge of an upper circumference of the control panel opposite to the supply groove so as to communicate with the one communication hole; Oxygen generator valve comprising a. The method of claim 1, Oxygen generator valve, characterized in that the motor is applied to the lower end of the control panel to generate a driving force in accordance with the application of the power so that the control panel is rotated in close contact with the lower end of the communication plate. The method of claim 1, Communication holes formed by five openings in each of the five points of the circular communication plate; A discharge groove recessed in the same width as one of six equal portions of the upper surface of the control panel and recessed; A supply groove recessed in a width equal to the width of two consecutive portions among the six equal portions of the upper surface of the control panel; Oxygen generator valve comprising a.