KR100626438B1 - Pipe Module For An Oxygen Generator - Google Patents

Abstract

The present invention relates to an oxygen generator piping module configured to form a flow path in the body portion so that the mounting component connecting pipe is not exposed to the outside.

The oxygen generator piping module is a piping module used in the oxygen generator for generating oxygen by passing the compressed air from the air compressor through the adsorption bed filled with the adsorbent, the compressed air from the air compressor to the adsorption bed And a flow path for transporting the oxygen generated in the adsorption bed and the desorbed nitrogen to the outside; a body part formed therein; wherein the body part has an upper body in close contact with at least two members; It may be composed of an intermediate body and a lower body.

According to the present invention as described above, it is possible to easily assemble various mounting parts and pipes, to have a remarkable effect of excellent workability, low manufacturing cost, and easy repair.

Oxygen generator, PSA method, piping module, body part, orifice, sealing member

Description

Pipe Module For An Oxygen Generator

1 is a configuration diagram of an oxygen generator equipped with an oxygen generator piping module according to the present invention.

Figure 2 is an exploded perspective view of the main parts of the oxygen generator equipped with an oxygen generator piping module according to the present invention.

3 is a view showing a cover plate of an oxygen generator piping module according to the present invention,

   (a) is a perspective view, (b) is a front view, (c) is a rear view,

   (d) is sectional drawing along the A-A line | wire of FIG. 3B.

4 shows an upper cover of an oxygen generator piping module according to the present invention,

   (a) is a front perspective view, (b) is a rear perspective view, (c) is a front view, (d) is a rear view,

   (e) is a front view of the upper cover sealing member,

   (f) is sectional drawing along the B-B line | wire of FIG. 4C,

   (g) is sectional drawing about the B-B line | wire of FIG. 4C by another embodiment.

Figure 5 as showing an intermediate cover of the oxygen generator piping module according to the present invention,

   (a) is a front perspective view, (b) is a rear perspective view, (c) is a front view, (d) is a rear view,

   (e) is a front view of the intermediate cover sealing member,

   (f) is sectional drawing about the C-C line | wire of FIG. 5D.

Figure 6 shows an orifice plate of the oxygen generator piping module according to the present invention,

   (a) is a front view,

   (b) is a sectional view taken along the line D-D of FIG. 6A,

   (c) shows another sectional view along the D-D line of FIG. 6A.

7 is a bottom cover of the oxygen generator piping module according to the present invention,

   (a) is a front perspective view, (b) is a rear perspective view, (c) is a front view, (d) is a rear view,

   (e) is a front view of a lower cover sealing member.

8 is a configuration diagram schematically showing the configuration of a conventional PSA oxygen generator.

Explanation of symbols on the main parts of the drawings

Oxygen generator 110 ... filtration filter

120 air compressor 200 solenoid valve

300 ... moisture filter 400 ... orifice plate

510 ... cover plate 520 ... top cover seal

530.Top cover 540 ... Middle cover

550 ... Middle cover seal 560 ... Lower cover seal

570 Lower cover 600 Body

610 upper body 620 intermediate body

630 lower body 800 adsorptive bed

The present invention relates to a piping module for use in the oxygen generator, and more particularly to an oxygen generator piping module configured to form a flow path in the body portion so as not to expose the mounting component connecting pipe to the outside.

Today, oxygen generators are used in various places in various places. Most commonly, oxygen generators provide oxygen to confined spaces in offices or homes to help people recover from fatigue and activate cells. In addition, it is widely used for air purification such as medical oxygen generators, automobile oxygen generators, divers air tank filling oxygen generators and air conditioners.

In order to generate oxygen in this manner, a PSA (Pressure Swing Adsorption) method is generally used, and a membrane method, an electrolysis method, and the like are also used.

Among these, PSA type oxygen generator is a device that separates nitrogen and oxygen from air by using selective adsorption capacity of zeolite Molecular Sieve (zeolite), and it is operated by continuous operation of adsorption, equalization and desorption while changing pressure of adsorption bed. Will produce oxygen. That is, when the pressurized air is blown into the adsorption bed filled with the adsorbent, oxygen having low adsorption selectivity is discharged from the outlet of the adsorption bed, and the adsorption bed where the specific component (nitrogen) is adsorbed is reduced to a part of oxygen obtained at high pressure. It goes through the process of regeneration (cleaning, detaching).

8 is an opening diagram showing a schematic configuration of a conventional PSA oxygen generator.

As shown in FIG. 8, the conventional oxygen generator 1 includes an air compressor 20 for compressing air, two flow paths through which compressed air flows, and an electromagnetic valve 30 for controlling the flow path. A pair of adsorption beds 40 and 40a connected to the solenoid valve 30 to adsorb nitrogen to discharge pure oxygen, and a silencer for storing and discharging nitrogen separated through the adsorption beds 40 and 40a; 50).

Here, the air compressor 20 is connected to the filtration filter 10 for removing dust in the outside air into which the inlet is introduced and supplying purified air, and the outlet is connected to one end of the solenoid valve 30, thereby filtering the filtration filter ( The purified air from 10 is compressed and discharged to the solenoid valve 30.

The solenoid valve is generally used to form a branched flow path for the solenoid valve 30 connected to the air compressor 20. At this time, each branched flow path forms a form in which when the current is supplied, the port is opened and the compressed air flowing inwardly is momentarily pushed out, and the port is closed when the supply of the current is cut off. ) To alternately supply compressed air.

Two suction beds 40 and 40a are independently operated, and an inlet thereof is connected to the solenoid valve 30, and an orifice 90, 90a and 95 is connected to the outlet thereof to maintain the discharge pressure of oxygen at a low pressure. To form an oxygen outlet.

That is, as shown in FIG. 8, the air introduced into the air compressor 20 through the filtration filter 10 is pressurized and introduced into the adsorption bed 40 along the flow path of the solenoid valve 30, and the adsorption bed 40. Oxygen discharged from) is discharged to the room via the orifices (90,95).

Meanwhile, some of the oxygen obtained from the adsorption bed 40 is supplied to the adsorption bed 40a through an orifice 90a, and the adsorption bed 40a is decompressed to undergo a regeneration (cleaning, desorption) process to silencer 50. It is slowly discharged to the outside without noise.

On the contrary, when the flow path of the solenoid valve 30 is changed, the adsorption and regeneration processes of the adsorption beds 40 and 40a alternate with each other.

Such a conventional oxygen generator is equipped with a large number of parts therein and a plurality of pipes connected between these parts is very complicated internal structure, low productivity and high incidence of defects, later maintenance, repair and replacement Many difficulties follow. In addition, in order to connect the mounting parts, the connection part is fitting using a bend made of steel or PP in order to prevent leakage and secure product reliability, but there is a problem in that the connection part is very large and difficult to work.

In order to solve this problem, conventionally, various paths of piping and mounting parts used for the oxygen generator have been optimized, but the above-mentioned problems cannot be fundamentally solved.

In addition, when the oxygen generator is used for a long time, the pipe ages and fluid leakage occurs, so it is necessary to replace the pipe. In the case of replacing the pipe as described above, if there is not enough prior knowledge of the oxygen generator, many difficulties in reassembling after disassembly will follow. In particular, the PSA type oxygen generator has a problem that it takes much time to repair and replace the mounting parts and pipes because the structure of the PSA type oxygen generator is more complicated than the hollow fiber membrane type or flat membrane type oxygen generator.

Furthermore, in the case of replacing the pipes, when the pipes that do not accurately detect the leaking pipes are not accurately identified, the leaked parts are searched for by replacing the respective pipes, but in this case, there is a problem in that it takes a lot of time and money for the A / S.

The present invention is to solve the above problems, it is easy to assemble the mounting parts and the pipe by forming a flow path inside the body, it provides excellent workability, low manufacturing cost, and low oxygen product piping module for the product. It aims to do it.

In addition, an object of the present invention is to provide a piping module for an oxygen generator that not only facilitates the pipe replacement but also facilitates maintenance and repair of the entire oxygen generator.

In order to achieve the above object, the present invention, in the piping module used in the oxygen generator for generating oxygen by passing the compressed air in the air compressor through the adsorption bed filled with the adsorbent, the compressed air from the air compressor And a flow passage for transferring the adsorption bed to the adsorption bed and a flow passage for transporting oxygen generated from the adsorption bed and nitrogen desorbed to the outside.

Preferably, the body portion is connected to the air compressor and the fluid flows from the air compressor flows in the lower body formed therein, one side is connected to the suction bed and the other side is connected to the flow path formed in the lower body And an upper body in which a flow path for fluid flowing in and out of the suction bed is formed.

More preferably, the body portion further comprises an intermediate body formed therein a flow path connecting the flow path formed inside the upper body and the flow path formed inside the lower body, the flow path formed in the upper body is the intermediate It is connected to the flow path formed in the lower body through a flow path formed in the body.

At this time, the flow path formed in the body portion is preferably formed by close contact with two or more members.

Preferably, a plurality of flat plates may be connected to the flow path formed inside the lower body and the flow path formed inside the intermediate body, and to perform a plurality of orifices between the flow paths formed inside the lower body and the intermediate body. The orifice plate is formed through the orifice hole; may further include.

Also preferably, a space for mounting an oxygen generator mounting part is formed between the upper body and the intermediate body, and the mounting part may be connected to a flow path formed inside the upper body or the intermediate body.

Preferably, the upper body may have a nipple protruding to be connected to the adsorptive bed, and the lower body may have a nipple protruding to be connected to the air compressor.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are set in consideration of functions in the present invention, which may vary depending on the intention or custom of the producer producing the product, and the definitions should be made based on the contents throughout the present specification.

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

1 is a configuration diagram of an oxygen generator equipped with an oxygen generator piping module according to the present invention, Figure 2 is an exploded perspective view of the main parts of the oxygen generator equipped with an oxygen generator piping module according to the present invention, Figure 3 is 4 is a view illustrating a cover plate of an oxygen generator piping module according to the present invention, and FIG. 4 is a view showing an upper cover of an oxygen generator piping module according to the present invention, and FIG. 5 is an oxygen generator piping according to the present invention. The middle cover of the module is shown. 6 is a view showing an orifice plate of the oxygen generator piping module according to the present invention, Figure 7 is a view showing a lower cover of the oxygen generator piping module according to the present invention.

First, as shown in FIG. 1, the oxygen generator 100 equipped with an oxygen generator piping module according to the present invention has a configuration similar to that of the conventional oxygen generator illustrated in FIG. 8. However, although the conventional oxygen generator is exposed to a plurality of pipes to the outside, the oxygen generator piping module according to the present invention forms a portion of the pipe inside the body to provide a piping module that is easy to assemble, maintain and repair. Characterized in that. Particularly, in the present specification, for convenience of description, the PSA oxygen generator is illustrated and described as an example, but may be widely applied to other oxygen generators such as a membrane method and an electrolysis method without departing from the spirit and the gist of the present invention.

As shown in Figure 2, the oxygen generator piping module according to the present invention, the flow path for transferring the compressed air from the air compressor 120 to the adsorption bed 800 and the oxygen generated in the adsorption bed 800 And a flow path for transporting the desorbed nitrogen to the outside includes a body part 600 formed therein.

Preferably, the body portion 600 is connected to the air compressor 120, the lower body 630 is formed therein a flow path for the fluid flowing from the air compressor 120 and one side is the suction bed It is connected to the 800 and the other side is connected to the flow path formed in the lower body 630 and has an upper body 610 formed therein is a flow path for the fluid flowing in and out of the adsorption bed 800.

More preferably, the body part 600 may include an intermediate body 620 having a flow path connecting a flow path formed inside the upper body 610 and a flow path formed inside the lower body 630. It may be further provided to form a flow path connected to the mounting components located between the air compressor 120 and the adsorption bed 800, in this case the flow path formed in the upper body 610 is the intermediate body It is connected to the flow path formed in the lower body 630 through a flow path formed in the (620).

For example, as shown in FIGS. 1 and 2, between the air compressor 120 and the adsorption bed 800, the secondary suction filter 130, the solenoid valve 200, the water removal filter 300, and the pressure A plurality of orifices and the like may be provided to adjust the flow rate, and these parts may vary depending on design specifications, whether to be mounted, the number, location, and flow path structure to be connected.

The secondary suction filter 130 is primarily filtered in a filtration filter 110 including a HEPA (HEPA) filter, and secondarily filters the air supplied through the air compressor 120. The solenoid valve 200 is connected to the ports 210, 220, 230, 240, and 250 so as to transfer the compressed air from the air compressor 120 to the adsorption bed 800 or to discharge nitrogen desorbed from the adsorption bed 800 to the outside. Is changed. In addition, the water removal filter 300 serves to remove the moisture of the air supplied from the air compressor. Meanwhile, the adsorption bed 800 is filled with an adsorbent such as zeolite to generate oxygen by adsorption of nitrogen, and is desorbed in the cleaning process to discharge nitrogen.

Pipes connecting the mounting parts may be formed as in the configuration diagram shown in FIG. 1, but are not limited thereto, and an appropriate flow path (pipe) connection structure may be set according to design specifications.

The present invention has the advantage that it is possible to effectively perform the assembly and repair by forming such a pipe inside the body portion so as not to expose at least a part of the flow path (pipe) connecting the various mounting parts to the outside.

 In the present embodiment, for convenience of description, the body portion 600 consisting of three main bodies 610, 620, and 630 is illustrated and described. However, the body portion 600 may be formed of only one body according to a design specification. It may be formed of two bodies, the upper body 610 and the lower body 630, it may be composed of four or more bodies.

First, the upper body 610 will be described in more detail with reference to FIGS. 2 to 4.

The upper body 610 is formed therein one side is connected to the adsorption bed 800, the other side is connected to the flow path formed in the lower body 630, the flow path for the fluid flowing in and out of the adsorption bed 800 is formed do.

In the present specification, for the convenience of description, two adsorption beds 810, 820 and four nipples 511, 512, 513, and 514 are used and described. However, the number of such adsorption beds and nipples may be changed according to design specifications. In addition, the nipples 511, 512, 513, and 514 connected to the adsorption bed 800 may be installed bent from the cover plate 510 as shown in FIG. 3, but may be installed from the upper cover 530 as shown in FIG. 2. It may be installed in two rows extending in a straight line, and can be changed according to the installation structure of the adsorptive bed and its piping connection structure.

As described above, only one member may be used to form a flow path inside the upper body 610, but a flow path may be formed by bringing two or more members into close contact with each other to improve manufacturing convenience and design freedom.

For example, in order to form an internal flow path, the upper body 610 may form a flow path by bringing the cover plate 510 and the upper cover 530 into close contact with each other, as illustrated in FIG. 2. An upper cover sealing member 520 may be mounted between the cover plate 510 and the upper cover 530 for airtightness.

As shown in FIG. 4F, the flow path includes an upper cover 530 having a trough, a cover plate 510 that is in close contact with the upper cover 530, and forms a flow path 539, and the flow path 539. It may be made of an upper cover sealing member 520 that is mounted to be installed in the trough of the upper cover 530 to maintain the airtight of the flowing fluid. At this time, the upper cover 530 and the cover plate 510 are bonded by ultrasonic fusion or maintained in close contact through a known fastening structure such as a screw.

Alternatively, as illustrated in FIG. 4G, the cover plate 510 in which the trough of the semicircle cross section is formed and the upper cover 530 in which the trough is formed may be joined by ultrasonic welding to form a flow path 539. . At this time, the cover plate 510 or the upper cover 530 may be formed with a protrusion 519 for ultrasonic welding.

Preferably, the flow path formed inside the upper body 610 may be connected to the suction bed 800 through the nipples (511, 512, 513, 514) formed on the cover plate 510 as shown in Figure 3a to 3d. . At this time, the nipples (511, 512, 513, 514) is connected to the holes (511a, 512a, 513a, 514a) of the cover plate 510 through the nipple body 517, the suction bed through the holes (511a, 512a, 513a, 514a) Fluid input and output from the 800 is connected to the flow path (531,532,533,534) formed in the upper cover 530 of FIG. In addition, the flow paths 531, 532, 533, and 534 are connected to nipples 531b, 532b, 533b, and 534b formed on the rear surface of the upper cover 530 of FIG. 4D through the holes 531a, 532a, 533a, and 534a shown in FIG. 4C. It is connected to a flow path formed in the lower body 630 through mounting components such as the intermediate body 620 or the water removal filter 300.

Specifically, two nipples 511 and 512 formed on the cover plate 510 may be connected to the first suction bed 810, and the other two nipples 513 and 514 may be connected to the second suction bed 820. have. In addition, two nipples 531b and 533b formed on the rear surface of the upper cover 530 of the upper body 610 are connected to two moisture removal filters 310 and 320, respectively, and the other two nipples 532b and 534b are The nipples 542 and 544 formed in the middle cover 540 of the intermediate body 620 of FIG. 5A are connected to the flow paths 571 and 572 formed in the lower cover 570 of the lower body 630 (see FIG. 7A).

In addition, the upper cover 530 may be formed with flow paths 538 and 539 connecting the solenoid valve 200 and the water removal filter 300, and are connected to the solenoid valve 200 on the rear surface of the upper cover 530. Nipples 538a and 539a and nipples 538b and 539b connected to the water removal filter 300 may be provided.

On the other hand, the upper cover sealing member 520 is seated in the trough of the upper cover 530, and consists of partial members (521, 522, 523, 524, 528, 529) formed in accordance with the shape of the flow path to maintain the airtight of the fluid flowing through the flow path (531,532,533,534,538,539).

In addition, a position fixing protrusion F2 (refer to FIG. 4A) is formed on the upper cover 530 for convenience of adhesion (bonding) of the cover plate 510 and the upper cover 530 to cover the cover plate 510. Can be fitted into the position fixing hole F1 (see FIG. 3A). At this time, the cover plate 510 and the upper cover 530 may be ultrasonically fused or screwed through an assembly hole S (see FIGS. 3A and 4A) for close contact.

In addition, the oxygen generated in the adsorption bed 800 is discharged to the outside through the oxygen discharge nipple 535 of Figures 4a and 4c through the flow path formed in the body portion 600. Reference numeral 515 in FIG. 3 is a through hole through which the oxygen discharge nipple 535 passes.

Next, the intermediate body 620 will be described in more detail with reference to FIGS. 2, 5 and 6.

The intermediate body 620 has a flow path connecting the flow path formed inside the upper body 610 and the flow path formed inside the lower body 630 therein.

As described above, only one member may be used to form the flow path inside the intermediate body 620, but the flow path may be formed by bringing two or more members into close contact with each other in order to improve manufacturing convenience and design freedom.

For example, as shown in FIG. 5F, the intermediate body 620 has one surface 541 of the intermediate cover 540 having a trough for forming an internal flow path, and one surface 541 of the intermediate cover 540. ), Which is attached to the flat plate 401 which is in close contact with each other and forms a flow path 546, and a trough formed on one surface 541 of the intermediate cover 540 to maintain the airtightness of the fluid flowing through the flow path 546. It may be made of an intermediate cover sealing member 556. At this time, in the embodiment of the present invention to reduce the number of parts using a flat plate 401 as a cover member in order to form a flow path in the interior of the intermediate body 620, the intermediate body 620 using a separate cover member The flow path may be formed inside. That is, in this embodiment, one surface of the plate 401 is used to form the internal flow path of the intermediate body 620, while the other surface is used to form the internal flow path of the lower body 630, but the upper body 610 In order to form an inner flow path, it is also possible to use an independent cover member, such as a cover plate 510 which is in close contact with the upper cover 530. In addition, an independent cover member may be used to have a cross section as shown in FIG. 4G, and a close contact structure may be obtained through a known method such as ultrasonic welding or screw coupling for airtightness of the fluid.

Preferably, as shown in Figure 2, between the upper body 610 and the intermediate body 620 is formed a mounting space that can be mounted mounting components, such as solenoid valve 200, water removal filter 300, The mounting component may be connected to a flow path formed in the upper body 610 or the intermediate body 620.

The intermediate body 620 is connected to the flow paths 532 and 534 of the upper body 610 through nipples 542 and 544 communicating with the nipples 532b and 534b of the upper body 610, and the nipples 542 and 544 are rear surfaces thereof. It is connected to the flow paths 571 and 572 (see FIG. 7C) formed in the lower body 630 through the connection holes 542b and 544b formed in the lower body 630. In addition, the air compressed by the air compressor 120 is supplied to the port 210 (see FIG. 1) of the solenoid valve 200 through the flow path 546 and the connection hole 546a formed in the intermediate cover 540, The nitrogen discharged through the ports 220 and 230 of the solenoid valve 200 is discharged to the outside through the connection holes 547a and 548a of FIG. 5C and the nipples 547 and 548 of FIG. 5B.

At this time, in order to maintain the airtight between the solenoid valve 200 and the upper body 610 or the intermediate body 620, airtight members 260 and 270 may be mounted as shown in FIG.

Meanwhile, the flow paths 543 and 549 of FIG. 5D connect the flow paths 571, 572, 573 and 574 of FIG. 7C through the connection holes 431, 432, 433, 434 and 435 formed in the orifice plate 400 of FIG. 6A, such as oxygen generation and dilution of the oxygen generator and nitrogen desorption. Perform a function.

In addition, the intermediate cover sealing member 550 is seated in the trough of the intermediate cover 540, and is composed of partial members 553, 556, 559 formed in accordance with the shape of the flow path to maintain the airtight of the fluid flowing through the flow path (543, 546, 549).

As shown in FIG. 5, parts such as a filtration filter 110 or an air tank (not shown) may be mounted on the box portion 541a formed at the lower portion of the intermediate cover 540. An air tank (not shown) for storing the supplied air may be mounted to supply purified air to the air compressor 120 through the hole 575 of FIG. 7.

Finally, the lower body 630 will be described in more detail with reference to FIGS. 2, 6, and 7.

The lower body 630 is connected to the air compressor 120 therein, and a flow path through which the fluid flowing from the air compressor 120 flows is formed.

Similar to the upper body 610 and the intermediate body 620 described above, only one member may be used to form a flow path inside the lower body 630, but two or more members may be mutually interposed to improve manufacturing convenience and design freedom. The flow path may be formed by being in close contact.

For example, as shown in FIG. 6C, the lower body 630 has a lower cover 570 having a trough for forming an internal flow path, and a flat plate 401 that is in close contact with the lower cover 570 to form a flow path. And a lower cover sealing member 560 seated and installed in the trough of the lower cover 570 to maintain the airtightness of the fluid flowing in the flow path. At this time, in the embodiment of the present invention to reduce the number of parts using a flat plate 401 as a cover member to form a flow path in the lower body 630, the lower body 630 using a separate cover member The flow path may be formed inside. Alternatively, an independent cover member may be used, such as a cover plate 510 that is in close contact with the upper cover 530 to form a flow path inside the upper body 610. In addition, an independent cover member may be used to have a cross section as shown in FIG. 4G, and a close contact structure may be obtained through a known method such as ultrasonic welding or screw coupling for airtightness of the fluid.

Preferably, the lower body 630 is connected to the air compressor 120 through the nipples (575, 576) installed on the back. In this case, the nipple 575 is connected to the inlet of the air compressor 120 through which the air passing through the filtration filter 110 of FIG. 2 is introduced, and the nipple 576 is connected to the outlet of the air compressor 120. The air supplied through 576 is supplied to the solenoid valve 200 through the flow path 546 of FIG. 5B.

In addition, the flow paths 571 and 572 formed on the upper portion of the lower cover 570 allow the fluid supplied from the suction bed 800 to flow through the nipples 542 and 544 of FIG. 5A. At this time, the flow path (571, 572) is connected to the flow path (573, 574) in the lower through the connection holes (431, 432, 433, 434, 435 (see Fig. 6) of the flat plate 401 and the flow path (543, 546, 549) (see Fig. 7a) of the intermediate body 620. As a result, oxygen is discharged to the outside or oxygen is supplied to the adsorption bed 800 for cleaning.

In addition, the lower cover sealing member 560 is seated in the trough of the lower cover 570, and consists of partial members 561, 562, 563, 564 formed in accordance with the shape of the flow path to maintain the airtight of the fluid flowing through the flow path (571, 572, 573, 574).

Preferably, the oxygen generator piping module according to the present invention, as shown in Figures 2 and 6, the plurality of orifices between the flow path formed in the lower body 630 and the flow path formed in the intermediate body 620 It may further include an orifice plate 400 through which a plurality of orifice holes are formed in the plate 401 to perform a function.

The orifice plate 400 may be provided separately from the cover member used to form a flow path in the lower cover 570 or the intermediate cover 540, but in the present embodiment, the orifice plate to reduce the number of parts 400 is installed in close contact with the lower cover 570 and the intermediate cover 540 to form a flow path in the lower cover 570 and the intermediate cover 540. That is, in this embodiment, as shown in FIG. 6C, one surface of the flat plate 401 of the orifice plate 400 is used to form an internal flow path of the intermediate body 620, and the other surface is an internal flow path of the lower body 630. It is used to form a hole, the hole formed in the flat plate 401 functions as an orifice or connects the flow path of the intermediate body 620 and the lower body 630, or a plurality of parts such as nipples to pass through Will perform the function of. As such, when the orifice plate 400 is installed to perform a plurality of functions, the intermediate cover 540, the orifice plate 400, and the lower cover 570 may be fastened by screws to facilitate replacement of parts. Although it is preferable to maintain close contact through, it may be possible to maintain close contact through the above-described ultrasonic welding or the like.

At this time, in order to seal the fluid flowing through the orifice hole, as shown in FIG. 6C, one or both sides of the orifice hole may be equipped with a sealing means such as an O-ring OR1 or the sealing members 550 and 560.

In addition, the lower cover 570 is preferably formed of a metal material such as steel to withstand the vibration of the air compressor 120, in this case the lower cover 570 is intermediate with the orifice plate 400 It is preferable that the cover 540 is fastened with a screw or the like so as to be assembled and disassembled.

On the other hand, when the orifice plate 400 is mounted between the intermediate cover 540 and the lower cover 570, as shown in Figures 2 and 7c to adjust the step of the lower portion where the orifice plate 400 is not located A step adjusting member 580 may be provided.

Meanwhile, the orifice holes 411, 412, 413, 414, 415, 416 and 417 formed in the flat plate 401 of the orifice plate 400 may be formed such that the diameter d1 of the outer portion is larger than the diameter d2 of the middle portion, as shown in FIG. 6B, but FIG. 6C It may be to have a constant diameter (d2) smaller than the diameter (d1) of the flow path connected to the orifice hole as in.

At this time, as shown in Figure 1, the plate 401 has cleaning orifice holes (411, 412) for adjusting the pressure and flow rate in order to introduce the oxygen generated for the desorption of the adsorption bed 800 to the opposite adsorption bed (800) side It may be provided. In addition, the oxygen discharge orifice hole 413 for adjusting the pressure and flow rate to discharge the oxygen to the outside through the cleaning orifice holes (411,412), through the air compressor 120 to lower the concentration of the discharged oxygen to a certain level An oxygen dilution orifice hole 414 may be provided to adjust the pressure and flow rate of the supplied air. Also preferably, a noise reduction orifice hole 415 may be provided to lower the pressure of the air supplied from the air compressor 120 to reduce the noise of the oxygen generator 100, and adjust the pressure and flow rate of the nitrogen discharged. Nitrogen noise reduction orifice holes 416 and 417 may be provided to reduce the noise.

These orifice holes may be added or subtracted according to design specifications. For example, without installing the nitrogen noise reducing orifice holes 416 and 417, nitrogen discharge nipples 547 and 548 (see FIG. It can also be formed as a through hole.

By forming a flow path in the body 600 as described above, the assembly of the mounting parts and piping such as the solenoid valve 200, the water removal filter 300, the adsorption bed 800, the air compressor 120, and the like is easy to work. It has the advantage of excellent performance and low manufacturing cost. In addition, when the pipe needs to be replaced due to the aging of the pipe, only a part of the body part needs to be replaced, so the repair time is greatly reduced, and even if the internal structure is not known, the repair is advantageous. Furthermore, since the number of pipes exposed to the outside is extremely limited, the structure is simple, and there is an advantage that the maintenance and repair of the entire oxygen generator are easy.

The operation of one embodiment of the present invention having the above configuration will be described with reference to FIGS. 1 to 7.

First, as shown in FIGS. 1 and 2, the air purified by the filtration filter 110 including a HEPA filter is illustrated in the nipple 541b of the middle cover 540 of FIG. 5A, and FIG. 7B. Through the nipple 575 of the lower cover 570 of the air compressor 120 is introduced. The air compressed by the air compressor 120 is connected to the port 210 of the solenoid valve 200 through the nipple 576 of the lower cover 570 of FIG. 7B and the flow path 546 of the intermediate cover 540 of FIG. 5B. (See FIG. 1).

At this time, the compressed air is the first moisture removal filter 310 or the second moisture removal filter 320 through the flow path (538, 539) formed in the upper cover 530 of Figure 4a according to the port connection structure of the solenoid valve 200 The fluid flowing through the first or second water removal filter 310.320 is nipples 531b and 533b formed on the rear surface of the upper cover 530 of FIG. The nipples 511 and 513 of the cover plate 510 are sequentially introduced into the first adsorption bed 810 or the second adsorption bed 820.

 When compressed air flows into the first adsorption bed 810 through the port 240 (see FIG. 1) of the solenoid valve 200, the oxygen generated in the first adsorption bed 810 is shown in FIG. The nipple 512 of the cover plate 510 of 3a, the flow path 532 formed in the top cover 530 of FIG. 4a, the nipple 532b of the top cover 530 of FIG. 4b, and the intermediate cover 540 of FIG. 5a. Nipple 542 of the, and the orifice hole 411 of the orifice plate 400 of Figure 6a sequentially flows into the flow path 571 of the lower cover 570 of Figure 7a.

Oxygen flowing into the inlet side 571a of the flow path 571 of the lower cover 570 reaches the outlet side 571b of the flow path 572, and the connection holes 431, 432, 433 of the orifice plate 400 of FIG. 6A, and It branches to the flow paths 572 and 573 of the lower cover 570 of FIG. 7A through the flow path 549 formed in the middle cover 540 of FIG. 5B.

At this time, the oxygen transferred to the flow path 573 of the lower cover 570 is connected to the holes 434 and 435 of the orifice plate 400 of Figure 6a, the flow path 543 formed in the intermediate cover 540 of Figure 5b and Figure 7a 6 is introduced into the oxygen discharge orifice hole 413 of FIG. 6A through the flow path 574 formed in the lower cover 570 of FIG. 5A and discharged to the outside through the nipple 545 of the intermediate cover 540 of FIG. 5A. Here, the compressed air passing through the nipple 576 of the lower cover 570 of FIG. 7B to reduce the concentration of oxygen discharged to the outside is flow path 546 of the intermediate cover 540 of FIG. 5B and oxygen of FIG. 6A. The dilution orifice hole 414, the flow path 573 of the lower cover 570 of FIG. 7A, the connection hole 434 of FIG. 6A, the flow path 543 formed in the intermediate cover 540 of FIG. 5B, and the connection hole of FIG. 6A. A flow path 574 formed in the lower cover 570 of FIG. 7A is sequentially passed through 435 to be mixed with oxygen generated from the adsorption bed 810.

In addition, the oxygen branched into the flow path 572 of the lower cover 570 is the cleaning orifice hole 412 of the orifice plate 400 of FIG. 6A, the nipple 544 of the intermediate cover 540 of FIG. 5A, and FIG. 4B. The nipple 534b of the upper cover 530 of the upper portion of the cover plate 510 of FIG. 3A sequentially passes through the nipple 514 of the second adsorption bed 820.

Nitrogen desorbed from the second adsorption bed 820 is again the nipple 513 of the cover plate 510 of Figure 3a, the flow path 533 formed in the upper cover 530 of Figure 4a, the upper cover 530 of Figure 4b Nipple 533b of the nipple 533b, the second water removal filter 320, the nipple (539b) of the rear of the upper cover 530 of Figure 4b, the flow path 539 formed in Figure 4a, the rear of the upper cover 530 of Figure 4b It flows into the port 250 (see FIG. 1) of the solenoid valve 200 via the nipple 539a and is discharged to the outside through the port 230 and the nipple 547 of the middle cover 540 of FIG. 5B. In this case, nitrogen may be passed through the nitrogen noise reduction orifice hole 416 of the orifice plate 400 of FIG. 6A.

On the contrary, even when the port connection of the solenoid valve 200 is changed, the compressed air from the air compressor 120 is introduced into the second adsorption bed 820 to pass through a similar flow path.

According to the present invention as described above, by forming a flow path inside the body portion, it is easy to assemble various mounting parts and pipes, and it is possible to provide an oxygen generator piping module having excellent workability and low manufacturing cost. .

In addition, when the pipe needs to be replaced due to the aging of the pipe, only some parts of the body part need to be replaced, thereby greatly reducing the repair time and cost, and even if the internal structure is not easily repaired.

Furthermore, since the number of pipes exposed to the outside is extremely limited, the structure is simple, and there is an effect that it is possible to provide an oxygen generator pipe module that is easy to maintain and repair.

 In addition, the configuration of the mounting parts can be changed by replacing some parts of the body part, and the flow path connecting them can also be changed, so that various changes of the mounting parts and the flow paths can be made for the customer's demand or better performance while using the oxygen generator. The effect is possible.

While the invention has been shown and described with respect to particular embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as set forth in the claims below. I want to make it clear.

In particular, in the case of the present embodiment is shown and described with respect to the oxygen generator of the PSA method (including the VSA method), it is also applicable to the oxygen generator of the membrane method, electrolysis method, the flow path structure formed in the body portion is an example I would like to make it clear that it is only presented.

Claims (7)

In the piping module used in the oxygen generator for generating oxygen by passing the compressed air in the air compressor through the adsorption bed filled with the adsorbent, A body part formed therein with a flow path for transferring compressed air from the air compressor installed outside to the adsorption bed installed outside and a flow path for transporting oxygen generated from the adsorption bed and nitrogen desorbed to the outside; Including; The body portion, A lower body connected to the air compressor through a nipple protruding from the air compressor, and having a flow path through which a fluid flowing from the air compressor flows; One side is connected to the adsorption bed through the protruding nipple and the other side is connected to the flow path formed in the lower body, the flow path of the fluid flowing in and out of the adsorption bed is characterized in that it has an upper body formed therein Plumbing module. delete The method of claim 1, The body portion further includes an intermediate body formed therein a flow path connecting the flow path formed in the interior of the upper body and the flow path formed in the interior of the lower body, The flow path formed in the upper body is an oxygen generator piping module, characterized in that connected to the flow path formed in the lower body through the flow path formed in the intermediate body. The method according to claim 1 or 3, The flow path formed in the body portion is an oxygen generator piping module, characterized in that formed by close contact with two or more members. The method of claim 3, A plurality of orifice holes penetrate the plate to perform a function of a plurality of orifices between the flow path formed inside the lower body and the flow path formed inside the intermediate body, and between the flow path formed inside the lower body and the intermediate body. Formed orifice plate; Piping module for the oxygen generator further comprises a. The method of claim 3, A space for mounting an oxygen generator mounting part is formed between the upper body and the intermediate body, wherein the mounting part is connected to a flow path formed inside the upper body or the intermediate body. delete

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