KR101375000B1 - Heat exchanger for oxygen generator - Google Patents

Abstract

The present invention relates to a heat exchanger for an oxygen generator, in which a plurality of heat exchangers are installed in series to exchange heat at high temperature, and an oxygen supply pipe to which high temperature oxygen is supplied is connected to a heat exchanger disposed at one end of the plurality of heat exchangers, Is connected to the oxygen discharge pipe discharged oxygen exchanged through the plurality of heat exchangers.

Description

Heat Exchanger for Oxygen Generator {HEAT EXCHANGER FOR OXYGEN GENERATOR}

The present invention relates to a heat exchanger for an oxygen generator for cooling by exchanging high temperature oxygen.

In modern society, oxygen generators are used in various places for various purposes. In particular, not only when used in industrial activities such as medical oxygen generators supplied to patients in hospitals or operating rooms, oxygen generators used for oxygen supply in wastewater treatment plants or fish farms, but also due to the industrialization of modern society, the air pollution becomes serious and serious. For the purpose of eliminating pollution, the oxygen generator for daily life that supplies oxygen to an enclosed space in an office or a general home is becoming common.

In order to generate oxygen, oxygen may be generated by electrolyzing water or oxygen may be obtained by reacting chemicals. However, since the equipment is expensive or difficult to handle, oxygen is separated from the air and supplied to the user. Doing.

On the other hand, the oxygen produced in the oxygen generator can be produced at a high temperature according to the manufacturing process, the oxygen produced at this high temperature is subjected to a process of cooling by a heat exchanger.

The heat exchanger for such an oxygen generator has a structure in which a plurality are connected in parallel so that a large amount of heat can be exchanged for oxygen. Each oxygen generator heat exchanger is disposed between a first tank into which oxygen is introduced, a second tank into which heat-exchanged oxygen flows out, and a heat exchanger core that substantially exchanges high-temperature oxygen with the first tank and the second tank. It is configured to include.

At this time, an oxygen supply pipe to which oxygen is supplied is connected to the first tank on one side of each heat exchanger in which a plurality of heat exchangers are connected in parallel, and an oxygen discharge pipe to which the heat exchanged oxygen is discharged is connected to the second tank on the other side of the heat exchanger. do.

Therefore, in the related art, as each heat exchanger has a plurality of connection parts connected to the oxygen supply pipe and the oxygen discharge pipe, the connection structure of the oxygen supply pipe and the oxygen discharge pipe and each heat exchanger is complicated, and there is a risk of leakage of oxygen through each connection part. It is large and the manufacturing cost has a big problem. The prior art is Japanese Patent Laid-Open No. 2005-133966.

Therefore, the present invention is to solve the above problems, the present invention is due to the connection structure of the oxygen supply pipe and the oxygen discharge pipe, the structure is complicated, oxygen leakage through each connection portion, to prevent a large manufacturing cost It is an object of the present invention to provide a heat exchanger for an oxygen generator.

A plurality of heat exchangers for the oxygen generator of the present invention for achieving the above object is installed in succession to serve to heat the high temperature oxygen, each heat exchanger is introduced into the first tank and the first tank into which oxygen is introduced A heat exchanger core for heat-exchanging the oxygen, a second tank through which the heat exchanged oxygen flows out of the heat exchanger core, and a blowing fan for blowing external air to the heat exchanger core,

An oxygen supply pipe for supplying high temperature oxygen is connected to a first tank of the heat exchanger disposed at one end of the plurality of heat exchangers, and oxygen exchanged through the plurality of heat exchangers is connected to a second tank of the heat exchanger disposed at the other end. Characterized in that the oxygen discharge pipe is discharged.

And the first tanks of each of the heat exchangers are disposed coaxially, and the second tanks of each of the heat exchangers are arranged coaxially.

The heat exchanger core is arranged between the plurality of oxygen units for guiding oxygen introduced through the first tank to the second tank side, and each of the oxygen units to flow orthogonally with the oxygen guided through the oxygen units. It includes a plurality of air units provided to be.

As described above, the oxygen generator heat exchanger of the present invention is simple in structure as one oxygen supply pipe and an oxygen discharge pipe are connected in the overall configuration when a plurality of heat exchangers are installed, and at the site where the oxygen supply pipe and the oxygen discharge pipe are connected. The risk of oxygen leakage is reduced and the cost is reduced due to the reduction of the connection structure.

1 is a perspective view showing a heat exchanger for an oxygen generator of the present invention.
FIG. 2 is a perspective view illustrating the oxygen generator heat exchanger shown in FIG. 1 viewed from another direction.
3 is a front view showing a heat exchanger for an oxygen generator of the present invention.
Figure 4 is a perspective view showing the air fin of the air portion of the heat exchanger for oxygen generator of the present invention.
5 is a plan view of the core of the heat exchanger of the heat exchanger for oxygen generator of the present invention.
Figure 6 is a view showing for explaining the flow of oxygen of the heat exchanger for oxygen generator of the present invention.

Hereinafter, with reference to the drawings will be described in detail with respect to the heat exchanger for the oxygen generator which is installed in succession with each other, it will be described taking an example of a structure in which the two heat exchangers are installed next to each other.

1 and 2, the oxygen generator heat exchanger 30 of the present invention has a structure in which a plurality of, for example, two heat exchangers 30 are installed next to each other. The oxygen generator heat exchanger 30 is connected to an oxygen supply pipe 10 through which high temperature oxygen is supplied, and an oxygen discharge pipe 20 through which the heat exchanged oxygen is discharged. The specific structure in which the supply pipe 10 and the oxygen discharge pipe 20 are connected will be described later.

Each of the heat exchangers 30 includes a first tank 40 through which oxygen flows in, a second tank 50 through which heat exchanged oxygen flows out, and a space between the first tank 40 and the second tank 50. It is configured to include a heat exchanger core 60 is disposed in the substantially heat exchanger core 60 and a blowing fan 90 for blowing outside air to the heat exchanger core 60.

The first tank 40 is disposed on one side of the heat exchanger core 60 as shown. In this case, in FIG. 3, the first tank 40 is disposed above the heat exchanger core 60. In addition, an oxygen supply pipe 10 through which high temperature oxygen is supplied is connected to the first tank 40 of the heat exchanger disposed at one end of the plurality of heat exchangers 30.

The second tank 50 is disposed on the other side of the heat exchanger core 60 as shown. In this case, in FIG. 3, the second tank 50 is disposed below the heat exchanger core 60. In addition, an oxygen discharge pipe 20 through which oxygen exchanged through the plurality of heat exchangers 30 is discharged to the second tank 50 of the heat exchanger disposed at the other end of the plurality of heat exchangers 30.

The heat exchanger core 60 includes an air unit 70 and an oxygen unit 80 that are largely configured and stacked such that oxygen and external air flow orthogonally to each other. Here, reference numeral 65 is a core guard disposed on both sides of the heat exchanger core 60 to protect.

First, the air unit 70 includes a plurality of air units, as shown in Figs. 4 and 5, each air unit is a pair of headers 71 and a pair of headers are arranged spaced apart from each other It includes a plurality of air pins 73 disposed between the (71).

The header 71 is disposed above and below the spaced apart from each other as described above, the header 71 is the place where the oxygen of the first and second tanks 40 and 50, each air fin 73 is disposed It is provided to prevent the air flowing into the air pins 73 at the same time to prevent the leakage into the leak.

As described above, a plurality of air pins 73 are disposed at regular intervals between the pair of headers 71. The air fin 73 is formed in a corrugated shape of the metal thin plate (Corrugated). That is, the air pins 73 are formed by continuously connecting the mountain-type unit pins 73a in a second direction perpendicular to the flow direction (first direction) of air.

A plurality of air passage holes 73b are formed in the mountain unit pin 73a, and the plurality of air passage holes 73b are spaced apart from each other in the air flow direction (first direction).

At this time, the air passage hole (73b) is preferably formed such that the opening is directed toward one surface (second negative direction) of the mountain-type unit pin and toward the other surface (second bidirectional). As described above, when the air passing holes 73b are formed at both sides of the unit pin 73a, the air flowing into the air pins 73 passes through the air passing holes 73b. Thus, the air passing holes 73b. The air passing through it drops its flow rate somewhat.

This is to increase the time the air stays in the air fin 73 so that the heat transfer between the outside air and oxygen is sufficient. In addition, the air pin 73 contributes to the formation of vortices in the air pin 73.

As shown in FIG. 6, the oxygen unit 80 includes a plurality of oxygen units disposed between each air unit, and the oxygen unit may be an oxygen tube 81. Each oxygen tube 81 is formed with a plurality of flow paths 82 for guiding the oxygen introduced from the first tank 40 to be moved to the second tank 50.

In addition, the oxygen unit may be provided as a bar plate type rather than a tube type as described above, although not shown in the drawing. The bar plate type oxygen unit includes a pair of tube plates joined to the air pins and the head bar of the air unit, oxygen pins disposed between the pair of tube plates, and the front and rear portions of the oxygen pins, respectively. It includes a tube bar to prevent the oxygen introduced through the tank is leaked to the outside in the process of passing through the oxygen portion.

The blowing fan 90 is arranged at the rear of each heat exchanger as shown. The blowing fan 90 supplies the outside air to the air unit 70 so as to heat exchange the high temperature oxygen moved through the oxygen unit 80.

Meanwhile, referring to FIG. 6, a structure in which a plurality of heat exchangers are installed is as follows.

First, a plurality of oxygen generator heat exchangers 30 of the present invention are arranged in succession as shown in FIG. Here, one of the plurality of heat exchangers is referred to as a first heat exchanger and the other as a second heat exchanger.

As described above, the first and second heat exchangers include a first tank 40 into which oxygen is introduced, a heat exchanger core 60 and a heat exchanger core 60 for heat-exchanging oxygen introduced from the first tank 40. It comprises a second tank (50) through which the heat exchanged oxygen flows out. Here, the first tank 40 is disposed on one side of the heat exchanger core 60, for example, as shown, and the second tank 50 is disposed on the other side of the heat exchanger core, for example, on the lower side. do.

The heat exchanger disposed at one end of the plurality of heat exchangers, that is, the first tank 40 of the first heat exchanger is connected to an oxygen supply pipe 10 through which high temperature oxygen is supplied, and the heat exchanger disposed at the other end, that is, The second tank 50 of the two heat exchangers is connected to an oxygen discharge pipe 20 through which oxygen exchanged through the plurality of heat exchangers is discharged.

In addition, in the present invention, the high temperature oxygen supplied through one oxygen supply pipe 10 is introduced into each heat exchanger core 60 or the oxygen heat exchanged through each heat exchanger core 60 is one oxygen discharge pipe 20. The connection pipe 100 is disposed between the first tank 40 and the first tank 40 and between the second tank 50 and the second tank 50 of each heat exchanger so as to be discharged through the heat exchanger. And communicate with each other.

Looking at the order in which oxygen is heat exchanged in the heat exchanger for oxygen generator of the present invention having the structure as described above are as follows.

First, high temperature oxygen is supplied to the heat exchanger installed at one end through the oxygen supply pipe 10, that is, the first tank 40 of the first heat exchanger. Thus, the first tank 40 of the first heat exchanger is thus provided. The high temperature oxygen supplied to) is also supplied to the adjacent first heat exchanger, that is, the first tank 40 of the second heat exchanger through the connecting pipe.

As described above, the oxygen supplied to the first tank 40 of each heat exchanger flows into the heat exchanger core 60 of each heat exchanger and heat exchanges, and then moves to the second tank 50 of each heat exchanger.

After that, the oxygen transferred to the second tank 50 of each heat exchanger is discharged to the outside through an oxygen discharge pipe 20 connected to the heat exchanger installed at the other end, that is, the second tank 50 of the second heat exchanger. do. In this process, oxygen moved to the second tank 50 of the first heat exchanger is discharged to the oxygen discharge pipe 20 via the second tank 50 of the second heat exchanger through the connection pipe 100.

Therefore, in the present invention, when one oxygen supply pipe and one oxygen discharge pipe are connected to each other when the oxygen supply pipe and the oxygen discharge pipe are respectively connected to each heat exchanger when a plurality of oxygen generator heat exchangers are installed, the structure is simple, and the oxygen supply pipe The risk of oxygen leakage at the site where the and oxygen discharge pipes are connected is reduced, and the cost is reduced due to the reduction of the connection structure.

Particularly, in the present invention, unlike the conventional method in which a plurality of heat exchangers are arranged and then discharged after heat exchange only through one heat exchanger, oxygen supplied through one oxygen supply pipe is simultaneously passed through a plurality of heat exchangers and then discharged through one oxygen discharge pipe. Accordingly, the heat exchange efficiency is excellent.

10: oxygen supply pipe 20: oxygen discharge pipe
30: heat exchanger for oxygen generator 40: the first tank
50: second tank 60: heat exchanger core
70: air portion 80: oxygen portion
90: blower fan 100: connector

Claims (4)

In the heat exchanger for the oxygen generator which is provided with a plurality of consecutive heat exchange heat of high temperature oxygen,
Each heat exchanger includes a first tank into which oxygen is introduced, a heat exchanger core for exchanging oxygen introduced from the first tank, a second tank from which oxygen exchanged from the heat exchanger core flows out, and the heat exchanger core. Including a blower fan for blowing outside air,
An oxygen supply pipe for supplying high temperature oxygen is connected to a first tank of the heat exchanger disposed at one end of the plurality of heat exchangers, and oxygen exchanged through the plurality of heat exchangers is connected to a second tank of the heat exchanger disposed at the other end. The oxygen discharge pipe is connected,
The first tanks of each heat exchanger are disposed coaxially, and the second tanks of each heat exchanger are disposed coaxially,
A connecting pipe is connected between each of the first tanks of the plurality of heat exchangers and between each of the second tanks,
The heat exchanger core,
A plurality of oxygen units for guiding the oxygen introduced through the first tank to the second tank side, disposed between each oxygen unit, provided to allow the oxygen and the outside air guided through the oxygen unit to flow orthogonally It includes a plurality of air units,
The air unit includes a pair of headers spaced apart from each other, and a plurality of air pins disposed between the pair of headers,
The air pins are formed in a corrugated metal sheet, and the mountain unit pins are continuously connected in a second direction perpendicular to the flow direction (first direction) of air.
The group unit pins of a plurality of expanded air through holes are arranged to be spaced apart from each other in the flow direction of the air (first direction), the openings of which are directed toward one surface (second negative direction) of the unit unit pins. A heat exchanger for an oxygen generator, characterized in that the group facing the group and the other surface (second bidirectional) is formed repeatedly in sequence along the flow direction (first direction) of air. delete delete delete

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