KR100505256B1 - Intake and exhaust valve for oxygen generator - Google Patents

Abstract

In the present invention, since the number of solenoid valves increases as the number of adsorption parts of the conventional oxygen generator increases, the cost increases and the layout of the inside of the outdoor unit becomes complicated due to the increase of the wires connected to the solenoid valves.

Each section partitioned by the partition and partitioned by the partition, the interior being partitioned by the partition and the lower body connected to the suction and discharge lines, and partitioned orthogonal to the partition of the lower body. By the upper body connected to the different adsorption unit, the rotating disk which is located between the upper body and the lower body and the through hole is formed by the number of the adsorption unit at a predetermined interval, and a step motor for rotating the rotating disk by a predetermined angle,

By using a single device, it is possible to sequentially supply compressed air or extract residual air to a plurality of adsorption units, which simplifies the overall structure, reduces the size, and makes the layout of the outdoor unit easier because the wiring is not complicated. It relates to an intake and exhaust valve.

Description

Intake and exhaust valve for oxygen generator

The present invention relates to an intake / exhaust valve for an oxygen generator that alternately supplies compressed air to two adsorption units in an oxygen generator circuit or allows nitrogen or the like inside the adsorption unit to be discharged to the outside.

In general, the oxygen generator adsorbs carbon dioxide and nitrogen from the compressed air supplied from the compressor 11 using a compressor 11 and a synthetic zeolite (MSZ), as shown in FIG. It is provided between the adsorption unit 13 for supplying the bay to the indoor unit, the vacuum pump 12 for discharging nitrogen remaining in the adsorption unit 13 to the outside, and between the adsorption unit 13 and the indoor unit 14. When the vacuum pump 12 is operated, the check valve 15 to block the back flow of air from the indoor unit 14, the conduit connecting the compressor 11 and the suction unit 13 and the vacuum pump 12 and It is comprised by the solenoid valve 16a, 16b which is provided in the pipeline which connects the adsorption part 13, and opens and closes an air flow.

The oxygen generator configured as described above supplies only oxygen to the indoor unit by adsorbing nitrogen and carbon dioxide in the adsorption unit.

Air containing nitrogen, oxygen, carbon dioxide, carbon monoxide, and the like is compressed while passing through the compressor 11 and then supplied to the adsorption unit 13 through the first solenoid valve 16a. The adsorption part 13 adsorbs nitrogen, carbon dioxide, and carbon monoxide using a synthetic zeolite (MSZ) filled therein, and only oxygen is supplied to the indoor unit 14 through the check valve 15. Of course, nitrogen, carbon dioxide, and carbon monoxide adsorbed by the synthetic zeolite of the adsorption unit 13 are discharged to the outside by the vacuum pump 12 as the second solenoid valve 16b is turned on after a predetermined time elapses.

Here, the compressed air compressed by the compressor 11 is supplied to the adsorption unit 13 or residual air such as carbon dioxide adsorbed by the synthetic zeolite of the adsorption unit 13 is discharged to the outside by the vacuum pump 12. It is determined by opening and closing of the solenoid valves 16a and 16b. That is, when the first solenoid valve 16a is turned on, a conduit connecting the compressor 11 and the adsorption part 13 is opened, so that the air compressed by the compressor 11 is supplied to the adsorption part 13. do. In addition, when the second solenoid valve 16b is turned on, a conduit connecting the suction unit 13 and the vacuum pump 12 is opened, so that the suction unit 13 remains by the vacuum pump 12. Air is exhausted to the outside. Of course, the first solenoid valve 16a and the second solenoid valve 16b are not turned on / off at the same time. That is, when the first solenoid valve 16a is turned on, the second solenoid valve 16b is turned off, and when the first solenoid valve 16a is turned off, the second solenoid valve 16b is turned on.

In addition, the double indoor indoor type oxygen generator having two indoor units, as shown in FIG. 2, compresses air and compresses carbon dioxide and nitrogen from the compressed air supplied from the compressor 21 using a synthetic zeolite. Two adsorption units 23 for adsorbing and supplying only oxygen to the two indoor units 24, a vacuum pump 22 for discharging nitrogen remaining in the adsorption unit 23 to the outside, and the adsorption unit ( Two check valves 25 installed between the indoor unit 24 and the indoor unit 24 to block air backflow from the indoor unit 24 when the vacuum pump 22 is operated, the compressor 21 and the adsorption unit. It consists of a plurality of solenoid valves 26 which are respectively installed in the conduit connecting the 23 and the conduit connecting the vacuum pump 22 and the suction unit 23 to open and close the flow of air.

The double indoor air type oxygen generator configured as described above alternately supplies the compressed air supplied from the compressor to the two adsorption units and simultaneously discharges nitrogen remaining in the adsorption unit to the outside.

Air containing nitrogen, oxygen, carbon dioxide, carbon monoxide, and the like is compressed while passing through the compressor and then supplied to the first adsorption portion 23a through the first solenoid valve 26a. The first adsorption unit 23a adsorbs nitrogen, carbon dioxide, and carbon monoxide using a synthetic zeolite filled therein, and only oxygen in the compressed air to the first chamber 24a through the first check valve 25a. Supplied. At this time, nitrogen, carbon dioxide and carbon monoxide adsorbed by the synthetic zeolite of the second adsorption portion 23b through the fourth solenoid valve 26d are discharged to the outside by the vacuum pump 22. Of course, since the second solenoid valve 26b and the third solenoid valve 26c are in an off state, the compressed air supplied from the compressor 21 is supplied to the second adsorption portion 23b or the first adsorption portion 23a. Air is not discharged to the outside by the vacuum pump (22).

When a predetermined time elapses, the first solenoid valve 26a and the fourth solenoid valve 26d are turned off, and the second solenoid valve 26b and the third solenoid valve 26c are turned on. Therefore, the compressed air compressed by the compressor 21 is supplied to the second adsorption portion 23b through the third solenoid valve 26c to remove nitrogen, etc., and then to the second air through the second check valve 25b. Nitrogen, carbon dioxide, and carbon monoxide, which are supplied to the indoor unit 24b and adsorbed by the synthetic zeolite of the first adsorption unit 23a, are discharged to the outside by the vacuum pump 22 through the second solenoid valve 26b.

However, since the number of the solenoid valve increases as the number of the conventional oxygen generator is increased, the cost increases and the layout of the inside of the outdoor unit is complicated by the increase of the wire connected to the solenoid valve.

That is, in the conventional oxygen generator, each time the number of the adsorption unit is increased by one, the solenoid valve should be installed on the suction pipe side and the discharge pipe side, respectively. However, solenoid valves are expensive equipment, and as the number of solenoid valves increases, the increase in production cost is inevitable. In addition, since the solenoid valve is operated by a power source, the wires must be connected. As the wires increase, the layout of the outdoor unit in which the oxygen generator is installed becomes complicated.

The present invention has been made to solve the above-mentioned problems of the prior art, and the object of the present invention is to provide an intake and exhaust valve for an oxygen generator that can be inhaled and discharged at the same time as well as repeating the suction and discharge at a predetermined interval.

The present invention for solving the above technical problem is divided into partitions by the number of the adsorption portion inside the lower body connected to the suction pipe and discharge pipe, and partitioned by the partition perpendicular to the partition wall of the lower body and the lower body And an upper body coupled to each other and partitioned by the partition wall connected to different adsorption parts, a rotating disk positioned between the upper body and the lower body and having through holes formed by a number of adsorption parts at predetermined intervals, and the rotating disk. It is characterized by consisting of a step motor to rotate by a predetermined angle.

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

The intake / exhaust valve for the oxygen generator according to the present invention is applied to an oxygen generator connected to two adsorption portions, and as shown in FIG. 3, the inside is divided into two parts by the first partition wall 52 'and the suction pipe passage 56 is provided. And a lower part 52 connected to the discharge conduit 57 and a second partition 53 ′ orthogonal to the first partition 52 ′ of the lower part 52. And an upper body 53 coupled to the second partition wall 53 ′ and connected to the first adsorption pipe line 58 or the second adsorption pipe line 58. ) And a rotating disk 54 located between the lower body 52 and the through hole 55 at 180 degree intervals, and a step motor 51 for rotating the rotating disk 54 by 90 degrees.

In this case, the step motor 51 is connected to the rotating disk 54 by a rotating shaft 51 ′ penetrating the center of the first partition wall 52 ′ formed in the lower body 52.

In the intake and exhaust valve for the oxygen generator of the present invention configured as described above, the supply of compressed air and the discharge of discharged air are simultaneously made through one pipe connected to each adsorption unit.

Compressed air supplied from a compressor (not shown) is supplied to a space on one side of the lower body 52 through a suction pipe 56, and the other space is connected to a vacuum pump (not shown) through a discharge pipe 57. Residual air such as nitrogen sucked from the adsorption unit (not shown) is allowed to escape through the discharge conduit 57. In addition, one side space of the upper body 53 is connected to the first adsorption part through the first adsorption part conduit 58, and the other side space is connected to the second adsorption part via the second adsorption part conduit 59. .

When the rotating disk 54 is rotated by the operation of the step motor 51, the first through hole 55a of the rotating disk 54 is the suction space of the lower body 52 and the first suction of the upper body 53. The space communicates with each other, and the second through hole 55b communicates the discharge space of the lower body 52 with the second adsorption space of the upper body 53. Therefore, the compressed air supplied from the compressor is moved from the suction space to the first suction space through the first through hole 55a and then supplied to the first suction part through the first suction part pipe 58 and the second suction part Residual air such as nitrogen remaining in the synthetic zeolite flows into the second adsorption space through the second adsorption part pipe 59 and then passes through the second through hole 55b, the discharge space and the discharge pipe path 57 to the vacuum pump. Is discharged to the outside.

When the rotating disk 54 is rotated 90 degrees by the step motor 51, the first through hole 55a of the rotating disk 54 is formed of the discharge space of the lower body 52 and the upper body 53. The first suction space communicates with each other, and the second through hole communicates the suction space of the lower body 52 with the second suction space of the upper body 53. Therefore, the compressed air supplied from the compressor is moved from the suction space to the second suction space through the second through hole 55b and then supplied to the second suction part through the second suction part pipe 59 and the first suction part Residual air such as nitrogen remaining in the synthetic zeolite flows into the first adsorption space through the first adsorption part pipe 58 and then passes through the first through hole 55a, the discharge space and the discharge pipe path 57 to the vacuum pump. Is discharged to the outside.

When the rotating disk 54 rotates 90 degrees again, the first through hole 55a of the rotating disk 54 communicates the discharge space of the lower body 52 with the second adsorption space of the upper body 53. The second through hole 55b communicates the suction space of the lower body 52 with the first suction space of the upper body 53. Accordingly, the compressed air supplied from the compressor is moved from the suction space to the first suction space through the second through hole 55b and then supplied to the first suction part through the first suction part pipe 58 and the second suction part Residual air such as nitrogen remaining in the synthetic zeolite flows into the second adsorption space through the second adsorption part pipe 59 and passes through the first through hole 55a, the discharge space and the discharge pipe path 57 to the vacuum pump. Is discharged to the outside.

When the rotating disk 54 is rotated 90 degrees again, the first through hole 55a of the rotating disk 54 makes the suction space of the lower body 52 communicate with the second suction space of the upper body 53. The second through hole 55b communicates the discharge space of the lower body 52 with the first suction space of the upper body 53. Therefore, the compressed air supplied from the compressor is moved from the suction space to the second suction space through the first through hole 55a and then supplied to the second suction part through the second suction part pipe 59 and the first suction part Residual air such as nitrogen remaining in the synthetic zeolite flows into the first adsorption space through the first adsorption part pipe 58, and then passes through the second through hole 55b, the discharge space, and the discharge pipe path 57 to the vacuum pump. Is discharged to the outside.

That is, each time the rotating disk 54 is rotated by 90 degrees by the step motor 51, oxygen obtained from the compressed air is sequentially supplied to the first adsorption section and the second adsorption section, and the remaining air remaining in each adsorption section is simultaneously supplied. Are sequentially discharged by the vacuum pump. Therefore, it is possible to supply compressed air to each adsorption unit or to discharge residual air inside the adsorption unit without installing a separate solenoid valve.

Here, the adsorption unit is connected to the oxygen generator evenly, such as 2, 4 units, 6 units, the partition wall 52 'which is installed on the lower body 52 and the upper body 53 as the number of the adsorption unit is increased, 53 ') increases the number of zones. In addition, the number of through-holes 55 formed in the rotating disk 54 also increases with the number of adsorption portions connected thereto, and the rotation angle of the rotating disk 54 is 90 degrees in two cases, 45 degrees in four units, The six are adjusted to 30 degrees.

In addition, when four or more adsorption units are connected to the oxygen generator, the suction pipe line 56 and the discharge pipe line 57 are alternately connected to each zone formed in the lower body 52. Of course, each of the suction pipe line 56 and the discharge pipe 57 is joined to a single pipe through the confluence pipe and connected to the compressor or the vacuum pump, respectively, the suction pipe line connected to the upper body 53 in sequence It is connected to the adsorption part.

As described above, the oxygen intake / exhaust valve of the present invention can supply compressed air or extract residual air sequentially to a plurality of adsorption units using a single device, thereby simplifying the overall structure as well as reducing the size and complicated wiring. If not, there is an advantage that the layout of the outdoor unit is easy.

In addition, since the step motor is used, there is no need to use a separate timer, and there is another advantage of reducing production cost since the solenoid valve, which is expensive equipment, is not used.

1 is a circuit diagram showing a conventional single indoor model oxygen generator circuit,

2 is a circuit diagram showing a conventional double indoor model oxygen generator circuit,

3 is an exploded perspective view showing an intake and exhaust valve for an oxygen generator according to the present invention.

<Explanation of symbols on main parts of the drawings>

51: step motor 51 ': axis of rotation

52: lower body 52 ′: first bulkhead

53: upper body 53 ': second bulkhead

54: rotating disk 55 (55a, 55b): through hole

56: suction pipe 57: discharge pipe

58: first adsorption pipe line 59: second adsorption pipe line

Claims (4)

Each section partitioned by the partition and partitioned by the partition, the interior being partitioned by the partition and the lower body connected to the suction and discharge lines, and partitioned orthogonal to the partition of the lower body. The upper body connected to the different adsorption unit, the rotating disk which is located between the upper body and the lower body and the through hole is formed by the number of the adsorption unit at a predetermined interval, and a step motor for rotating the rotating disk by a predetermined angle Intake / exhaust valve for oxygen generator. The method of claim 1, The step motor is an oxygen generator intake and exhaust valve, characterized in that the rotating shaft is connected to the rotating disk through the center of the partition formed on the lower body. The method of claim 1, The adsorption unit is an oxygen generator intake and exhaust valve, characterized in that evenly connected to the oxygen generator. The method of claim 1, The suction pipe passage and the discharge pipe passage of the oxygen generator, characterized in that alternately connected to each area formed in the lower body.