KR20040021834A - Indoor-type oxygen generator - Google Patents

Abstract

PURPOSE: An indoor oxygen generator is provided to secure stable performance of the oxygen generator without a hitch regardless of seasons. CONSTITUTION: The indoor oxygen generator for supplying high concentrated oxygen to a user by sucking air of the atmosphere includes: a housing(100) having an inlet hole and an outlet hole; an oxygen permeable membrane(120) positioned in the housing(100) and for selectively separating oxygen from the air sucked from the atmosphere using a pressure difference; a vacuum pump(130) connected to one side of the oxygen permeable membrane(120) by an oxygen inlet pipe(131), and for exhausting the separated oxygen in a predetermined direction; and an oxygen supply pipe(140) positioned at the other side of the vacuum pump(130), and for transferring the exhausted oxygen to a predetermined place. An inlet fan(110) located at the inlet hole of the housing(100) sucks air in the housing(100), and an exhausting fan(102) located at the exhausting hole of the housing(100) lowers temperature of a compressor using air having a low oxygen concentration flowed in the housing(100), and exhausts the air indoors.

Description

Indoor-type oxygen generator

The present invention relates to an oxygen generator, and more particularly, by installing some components of the oxygen generator installed on the outdoor side integrally to the indoor side to ensure stable product performance under adverse conditions caused by external temperature changes, and at the same time compact (compact The present invention relates to an indoor type oxygen generator that can be designed on a scale.

In general, air is composed of nitrogen and other components, including pure oxygen, and contains 20.9% oxygen in the atmosphere. The oxygen generator sucks air from the atmosphere to separate pure oxygen and supply it to the user. In the conventional oxygen generator, oxygen is separated and supplied to the user using the PSA method or the UFL method as well as the electrolysis method for electrolyzing water and the chemical reaction method by chemical reaction. In the present specification, an oxygen generator of the PSA method using the adsorption column will be described as an example. Here, the basic principle of the PSA method is that as the raw material gas passes through the adsorption tower filled with the adsorbent under high pressure, the high selectivity components are first adsorbed, and the low selectivity components are discharged out of the adsorption tower. The pressure in the adsorption column is regenerated to remove adsorbed components and the tower is washed with a portion of the high pressure product. By repeating this series of steps, the product can be obtained continuously. Synthetic zeolites are used as such adsorbents, and these synthetic zeolites are used as ion exchangers, catalysts, adsorption / dehydrating agents, and the like.

Conventional oxygen generator, as shown in Figure 1, the suction pump (1) is installed in the outdoor and sucks the outside air to apply pressure, and extracts only oxygen in the outside air sucked through the suction pump (1) and oxygen The first and second adsorption towers 3, which are in a reduced state by adsorbing components in the air other than the oxygen adsorbed on the synthetic zeolites 3a and 4a and the like, are discharged. 4), a pressure valve 5 for adjusting pressure according to compression / vacuum at the time of adsorption / reduction of the first and second adsorption towers 3 and 4, and the first and second adsorption towers 3 and 4; Oxygen flow control valve (6, 7) for controlling the flow of oxygen extracted from the oxygen and oxygen supply unit (8) for supplying oxygen flowing through the oxygen flow control valve (6, 7) and the first and the first 2 Ship installed outdoors to exhaust air other than oxygen discharged at the time of reduction of adsorption tower (3, 4) to the outside According to the gas pump 9 and the adsorption / reduction state of the first and second adsorption towers 3 and 4, the adsorption tower 3 of the adsorption operation is connected to the suction pump 1 side, and the adsorption tower of the reduction operation ( 4) the four-way valve (2) connected to the exhaust pump (9) side.

In this configuration, when the oxygen generator is operated, the suction pump 1 and the exhaust pump 9 are driven, and in the adsorption tower 3 on one side, the components of the atmosphere other than oxygen are compressed by the compression of the suction pump 1. Adsorbed to (3a) and only oxygen is extracted and supplied to oxygen supply section 8 through oxygen flow control valves 6 and 7, and in the other adsorption tower 4, atmospheric components other than oxygen that were adsorbed as reduction mode. It is reduced while being discharged to the outside through the exhaust pump (9).

Then, when either side of the adsorption tower (3) reaches the adsorption capacity of the components in the atmosphere other than oxygen due to the generation of oxygen, the pressure valve (5) is driven to the first, second adsorption tower (3, 4) impact of pressure change The valve is operated and the four-way valve (2) is switched to a path different from the previous state. At this time, the adsorption tower (3), which has been adsorbed in the previous mode by the driving of the four-way valve (2), is connected to the exhaust pump (9) to perform the reduction mode, and the adsorption tower (4) which performed the reduction mode is in the adsorption mode. It is connected to the suction pump 1 to generate oxygen. This series of processes is repeated sequentially to produce oxygen.

However, the conventional oxygen generator as described above shows a high performance suction pump and exhaust pump separately in the outdoor side to reduce the noise in the room, showing poor performance characteristics in the summer or winter bad conditions, and also due to high heat or freezing There was a problem of poor durability of the generator.

In addition, the oxygen generator using the conventional PSA method has another problem of lowering the competitiveness of the oxygen generator because high noise and vibration is generated because the suction pump and the exhaust pump to generate a high pressure.

The present invention has been made in view of the above, it is an object of the present invention to provide a room-type oxygen generator that can stably supply oxygen indoors even under adverse conditions such as summer or winter.

Another object of the present invention is to provide an indoor oxygen generator which greatly reduces vibration and noise by using a flat membrane, excluding the application of the PSA method requiring the suction pump and the exhaust pump.

1 is a schematic diagram showing a schematic configuration of a conventional oxygen generator.

Figure 2 is a schematic diagram showing the configuration of the indoor type oxygen generator of the present invention.

Explanation of symbols on the main parts of the drawings

100; Housing 101: air supply port

102: discharge fan 110: suction fan

120: oxygen permeable membrane 130: vacuum pump

131: oxygen inlet pipe 140: oxygen supply pipe

In order to achieve the above object, the indoor oxygen generator according to the present invention, in the oxygen generator for supplying a high concentration of oxygen to the user by sucking the air in the atmosphere, the housing having a suction port and the discharge port, and in the housing An oxygen permeable membrane that selectively separates oxygen from the air sucked from the air by using a pressure difference, and a vacuum pump connected to one side of the oxygen permeable membrane by an oxygen inlet tube to collect the separated oxygen and discharge it in a predetermined direction And an oxygen supply pipe installed at the other side of the vacuum pump to transport the discharged oxygen to a predetermined point.

The suction port of the housing is provided with a suction fan for sucking the air in the atmosphere into the housing, the discharge port of the housing is provided with a discharge fan for discharging the low oxygen concentration air introduced into the housing into the room.

In addition, a plurality of air supply holes are formed on one side of the housing to one side of the oxygen permeable membrane to discharge the low oxygen concentration air that has not completely passed through the oxygen permeable membrane to the indoor side.

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

As shown in FIG. 2, the apparatus according to the present invention includes a housing 100, a suction fan 110, an oxygen permeable membrane 120, a vacuum pump 130, and an oxygen supply pipe 140.

Housing 100 is installed in the interior of the building and forms the appearance of the oxygen generator. In a preferred embodiment of the present invention, one side of the housing 100 is formed with an inlet 100a through which air in the atmosphere is introduced, and the other side of the housing 100 discharges air of low oxygen concentration inside the housing 100. The discharge port 100b is formed. In addition, a plurality of air supply holes 101 are formed on the upper surface of the housing 100. The air supply port 101 does not completely pass through the oxygen permeable membrane 120 to be described later, and supplies air of low oxygen concentration that floats inside the housing 100 to the room.

The suction fan 110 is mounted on the rear side of the inside of the housing 100 to suck air in the air, which is composed of oxygen and various components, into the housing 100. That is, when the suction fan 110 rotates, air outside the housing 100 is sucked into the housing 100 through a grill (not shown) at the rear side of the housing 100.

The oxygen permeable membrane 120 is mounted inside the housing 100 to selectively separate oxygen from air sucked into the housing 100. Oxygen permeable membrane 120 is composed of a membrane (membrane) of a thin film, and selectively absorbs oxygen contained in the air by using a pressure difference by a vacuum pump to be described later.

The vacuum pump 130 is connected to the oxygen inlet tube 131 on one side of the oxygen permeable membrane 120 to collect the separated oxygen and discharge it to a predetermined direction, preferably indoors.

One end of the oxygen supply pipe 140 is installed in communication with the vacuum pump 130, and the other end of the oxygen supply pipe 140 is installed to be exposed to the outside of the housing 100, preferably to a predetermined point or room where oxygen is required, and the oxygen permeable membrane ( The air containing the high concentration of oxygen permeated while passing through 120 is supplied to the room.

In this configuration, when the user operates the oxygen generator, the suction fan 110 is rotated and the air in the air is sucked into the housing 100. The air introduced into the housing 100 passes through the oxygen permeable membrane 120, except for oxygen due to a pressure difference between the pressure of the oxygen permeable membrane 120 and the oxygen permeable membrane 120 opposite to the suction fan 110. The other components of are filtered off and only pure oxygen undergoes a process of dissolution and diffusion to obtain concentrated oxygen. Only this concentrated oxygen flows into the vacuum pump 130 through the oxygen inlet pipe 131.

Low oxygen concentration air that does not pass through some oxygen permeable membrane 120 is supplied to the room through the air supply port 101 formed on the upper side. At this time, although the suction fan 110 may send air to the oxygen permeation membrane 120, the suction fan 110 may have a low oxygen concentration that does not pass through the oxygen permeation membrane 120 and a part of the introduced air. Helps to discharge the air to the outside of the housing 100 through the air supply port (101). Preferably, since it is difficult to discharge the low oxygen concentration air inside the housing 100 to the outside only by the suction fan 110, the low oxygen concentration inside the housing 100 may be separated by using a separate discharge fan 102. It helps to supply air to the outside of the housing 100.

On the other hand, the air containing the high concentration of oxygen introduced into the vacuum pump 130 is discharged to the outside through the oxygen supply pipe 140 to make the air in the room comfortable, and energizes the human body by activating metabolism to the user At the same time to relieve fatigue, in the case of a hospital is provided with a mouthpiece (mouthpiece) (not shown) at the end of the oxygen supply pipe 140 to supply emergency air containing oxygen in a high concentration.

As described above, the present invention does not require the suction pump and the exhaust pump, which are conventionally installed on the outdoor side, and by integrally mounting all the components of the oxygen generator on the indoor side, regardless of external adverse conditions such as summer or winter, It is effective to secure performance smoothly.

In addition, the present invention has another effect that can be designed on a compact scale while significantly reducing vibration and noise while eliminating the application of the PSA method requiring a high pressure generating suction pump and an exhaust pump.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

Claims (3)

In the oxygen generator that inhales the air in the atmosphere and supplies a high concentration of oxygen to the user, A housing having an inlet and an outlet, an oxygen permeable membrane mounted inside the housing to selectively separate oxygen from the air sucked from the atmosphere by using a pressure difference, and connected to an oxygen inlet tube at one side of the oxygen permeable membrane. An indoor oxygen generator comprising a vacuum pump for collecting the collected oxygen and discharged in a predetermined direction, and an oxygen supply pipe which is installed on the other side of the vacuum pump and delivers the discharged oxygen to a predetermined point. The method of claim 1, A suction fan is installed at the suction port of the housing to suck air in the air into the housing, and the discharge port of the housing discharges the compressor temperature by lowering the temperature of the compressor using low oxygen concentration air introduced into the housing and discharging it to the room. Indoor oxygen generator, characterized in that the fan is installed. The method according to claim 1 or 2, An indoor oxygen generator, characterized in that a plurality of air supply port is formed on one side of the housing to one side of the oxygen permeable membrane to discharge the low oxygen concentration air that has not completely passed through the oxygen permeable membrane to the outside of the indoor device.