KR20110047617A - Pure oxygen generator - Google Patents

Abstract

PURPOSE: A high-purity oxygen generator is provided to smoothly circulate high-purity oxygen on a bed containing zeolite, and to prevent the generation of the moisture by controlling the rapid increase of the temperature of air. CONSTITUTION: A high-purity oxygen generator comprises a motor pump, a radiator, a fuel caulk, a solenoid valve(40), a pair of zeolite beds(50,60), and a regulator(70) to filter air and discharge high-purity oxygen. The high-purity oxygen generator additionally includes upper and lower covers(100,200) sealing the upper sides of the zeolite beds, a check valve opened and closed by the oxygen pressure, and a heat radiating member installed in between the motor pump and the radiator.

Description

High Purity Oxygen Generator {PURE OXYGEN GENERATOR}

The present invention relates to an oxygen generating device, and more particularly, to smoothly circulate high-purity oxygen in a bed containing zeolite, which is a main oxygen separation material of a pressure swing adsorption (PSA) method, and to increase the temperature of the air sucked at high pressure. The present invention relates to a high-purity oxygen generating device for preventing moisture from being generated.

In general, a conventional oxygen generator having a pair of zeolite beds discharges oxygen by alternately compressing and discharging the sucked air alternately, for example, the first bed sucks air from the outside by a solenoid valve. In this case, the zeolite contained in the first bed has particles larger than oxygen in the air, for example, nitrogen, carbon dioxide, water, and the like, so as to inhibit movement and allow oxygen to pass through the upper layer. Most of the oxygen generated in the first bed is sent through the oxygen discharge pipe and some of the oxygen is sent to the second bed on the other side to push the above-mentioned substances such as nitrogen adsorbed to the zeolite of the second bed to the lower end through the cleaning valve. It has a structure, and the first and second beds alternately repeat this process.

However, in the conventional oxygen generator as described above, oxygen passing through the zeolite moves to the oxygen discharge pipe through the inlet and outlet holes of the upper layer. At this time, fine foreign matter accumulates in the hole of the valve to prevent oxygen from entering and exiting the upper valve. In some cases, as the oxygen discharge and nitrogen removal become difficult, there is a problem that such an upper valve should be periodically checked.

On the other hand, in the conventional oxygen generator, the air forcedly sucked from the outside is compressed to a high pressure while passing through a nozzle having a small diameter, and the moisture is generated as the temperature of the air rises. (Pressure Swing Adsorption) As zeolite does not perform its normal function during oxygen separation process, continuous research is needed to rapidly cool the inhaled air to a temperature close to room temperature.

The present invention has been made to solve the above-mentioned problems of the prior art, and allows the smooth circulation of high-purity oxygen in the bed containing the zeolite mainly used in the PSA oxygen generator, the air sucked at high pressure to suppress moisture generation It is an object of the present invention to provide a high-purity oxygen generator that can prevent the temperature rise.

In order to achieve the above object, the present invention, by filtering the air to the high purity oxygen through a regulator in a pair of first and second zeolite beds spaced apart from each other via a motor pump, a radiator, a washing machine and a solenoid valve An oxygen generating device for alternately circulating to discharge, comprising: a lower cover which seals an upper portion of the first and second zeolite beds, and has a spiral hole and an outlet hole corresponding to each of the zeolite beds; A lower surface is coupled to the lower surface from the upper surface of the lower cover by a predetermined interval, and a first fastening part is provided at both sides to install a first oxygen discharge valve for supplying oxygen to the upper portion of each of the first and second zeolite beds. An upper cover having a second fastening portion provided at a central portion thereof to allow the second oxygen discharge valve to be connected to the regulator to be installed, and having a communication hole communicating with the first and second fastening portions inwardly; And a panel-shaped check valve fixed to one side of the spiral hole and having a through hole having a diameter smaller than that of the entrance and exit hole so as to be in close contact with the entrance and exit hole by pressure or spaced apart from each other by a predetermined distance. It is characterized in that the spaced apart by the packing member disposed in the insertion groove formed on the upper surface.

Additionally, the motor pump and the radiator are connected to a heat pipe including a copper pipe and a plurality of aluminum heat dissipation fins fixed to the outer circumferential surface of the copper pipe, wherein the heat dissipation fins extend from a spiral part surrounding the copper pipe and the inner side of the spiral part. It is characterized in that it is made of a plurality of contacts having a gap spaced from each other and fitted in the copper pipe.

As described above, the high-purity oxygen generating device according to the present invention is provided with a thin plate-shaped check valve inside the upper and lower pairs of pairs of first and second zeolite beds, which are mainly used for PSA oxygen generators, to pass oxygen through the bed. When the pressure passes through the inlet and outlet holes of the lower cover, the check valve is lifted upward by the pressure, and fine foreign matter that can pass through with oxygen can be discharged to the lifted part of the check valve without accumulating in the inlet and outlet holes. On the other hand, in case of inhaling oxygen for cleaning through the first oxygen discharge valve, the check valve automatically closes the inlet and outlet holes due to elasticity and pressure, so that only a small amount of oxygen is sucked into one zeolite bed. The amount of accumulation on the check valve can be reduced, resulting in fewer maintenance of the check valve.

In addition, by installing an additional heat dissipation member consisting of copper pipes and heat sink fins between the motor pump and the radiator, the compressed air is cooled before the compressed air is sent to the zeolite bed, thereby reducing the amount of moisture contained in the zeolite, thereby increasing the rate of high purity oxygen production. You can.

Hereinafter, a high purity oxygen generator according to the present invention will be described with reference to the drawings.

1 is a view schematically showing the operating principle of the high purity oxygen generator according to the present invention, Figure 2 is a block diagram showing a circulating operation state of the high purity oxygen generator according to the present invention.

High-purity oxygen generating device according to the present invention by filtering the air is spaced apart from each other via a motor pump 10, a radiator 20, a washing machine (for water removal and discharge) 30 and the solenoid valve 40 A conventional oxygen generating device that alternately circulates to discharge high purity oxygen through a regulator 70 in a pair of first and second zeolite beds 50 and 60, wherein the first and second zeolite beds 50 and 60 Upper and lower covers 100 and 200 which seal the upper part and provide a movement path of oxygen, a check valve 300 installed inside the upper and lower covers 100 and 200 and opened and closed by oxygen pressure, a motor pump 10 and It comprises a heat radiating member 400 is installed between the radiator 20.

3 and 4 are a top view and a rear view showing a lower cover installed with a check valve of the high purity oxygen generating device according to the present invention.

The lower cover 100 seals the upper portions of the first and second zeolite beds 50 and 60 and has spiral holes 101 and entrance holes 102 corresponding to the zeolite beds 50 and 60, respectively. The upper surface of the first and second zeolite beds 50 and 60 is formed at the bottom thereof.

5 and 6 are a top view and a rear view showing an upper cover of the high purity oxygen generating apparatus according to the present invention.

The upper cover 200 is spaced apart from the upper surface of the lower cover 100 by a predetermined interval so as to form a space therein, the outer surface of the lower cover 100 and the inner surface of the upper cover 200 is primarily in close contact If possible, bolted together again in the secondary state. In addition, the first fastening portion 210 is provided at both sides of the first oxygen discharge valve 80 for discharging oxygen from the upper portion of each of the first and second zeolite beds (50, 60), the oxygen discharge and pressure The second fastening part 220 is provided in the center portion is provided with a second oxygen discharge valve 90 is connected to the regulator 70 for adjusting the first and second fastening parts (210, 220) inward It has a structure in which the communicating hole 201 is formed. In addition, the upper and lower covers 200 and 100 may be spaced apart by a band-shaped packing member 110 such as rubber disposed in an insertion groove formed on an upper surface of the lower cover 100.

For reference, a pair of first oxygen discharge valves 80 for discharging oxygen from the top of each of the first and second zeolite beds 50 and 60 are connected to a conventional EQ valve (a valve opening of The rate of change has the same characteristics as the rate of change of flow rate, and is used for pressure regulation) so that the other side oxygen discharge valve is closed when one side oxygen discharge valve is opened by oxygen pressure.

The check valve 300 is made of a metal having an elastic force as a material and having a panel shape having a thickness of about 2 mm. One side of the check valve is fixed to the spiral hole 101 with a bolt and has a diameter smaller than that of the inlet and outlet holes 102. 301 is formed at a position in communication with the entrance and exit hole 102 so as to be in close contact with the entrance and exit hole 102 by the oxygen pressure generated from the first or second zeolite beds 50 and 60, or part of the entrance and exit hole 102 102 is spaced apart from the predetermined interval.

According to the structure of the check valve 300 as described above, when oxygen is withdrawn from one side, for example, the first zeolite bed 50, the other side except the fixed portion of the check valve 300 is lifted to lower the cover (100) As the upper surface and the check valve 300 is spaced apart, oxygen is drawn out to the raised portions of the inlet / outlet hole 102, the through hole 301, and the check valve 300, and the extracted oxygen is upper and lower cover ( The check valve 300 corresponding to the second zeolite bed 50 is about 80% transmitted to the regulator 70 through the second oxygen discharge valve 90 in the inner space of the 200 and 100, and the inlet and outlet are caused by the elastic force and the pressure. In the state in which the hole 102 is in close contact with the hole 102, the through hole 301 is 20% above the second zeolite bed 50. In other words, by repeating the above process alternately, any one of the first and second zeolite beds (50, 60) is the oxygen through the first and second oxygen discharge valves (80, 90), respectively, the flexible tube and regulator At the time of discharging to 70, the nitrogen remaining in the first and second zeolite beds 50 and 60 is discharged to the outside via the solenoid valve 40 and the silencer installed under the bed.

7 is a view showing a heat radiation member of the high purity oxygen generating device according to the present invention.

On the other hand, the motor pump 10 and the radiator 20 are connected to the heat pipe member 410 made of a copper pipe 410, and a plurality of aluminum heat radiation fins 420 fixed to the outer circumferential surface of the copper pipe 410, thereby providing power. Apart from the air-cooling method by the fan to be used, the first air-cooled through the heat radiating member 400 made of copper and aluminum with excellent heat transfer, and then the radiator 20 can lower the air temperature closer to room temperature. .

In the heat dissipation member 400 structure, the heat dissipation fin 420 having a cross-sectional area and an easy structure to be installed in the copper pipe 410 to cool the air in a state in which the temperature is raised more efficiently is the copper pipe 410. The spiral portion 421 surrounding the and the spiral portion 421 extends from the inner surface of the copper pipe 410 is fitted with a plurality of contact portions 422 having a spaced apart from each other. According to the structure of the heat dissipation member 400 described above, as the heat dissipation member 400 is inserted into the copper pipe 410, the contact portion 422 is bent and fixed to the copper pipe 410 by elastic force and at the same time in close contact with each other. The heat dissipation is maintained between the contact portions 422 and the gaps, and the spiral portion 421 also radiates the conducted heat to the outside, thereby providing a rapid air cooling effect.

1 is a view schematically showing the operating principle of the high purity oxygen generating apparatus according to the present invention.

Figure 2 is a block diagram showing a circulating operation state of the high purity oxygen generating apparatus according to the present invention.

3 and 4 are a top view and a rear view showing a lower cover installed with a check valve of the high purity oxygen generating device according to the present invention.

5 and 6 are a top view and a rear view showing an upper cover of the high purity oxygen generating apparatus according to the present invention.

7 is a view showing a heat radiation member of the high purity oxygen generating device according to the present invention.

Claims (4)

Air is filtered in a pair of first and second zeolite beds 50 and 60 spaced apart from each other via a motor pump 10, a radiator 20, a washing machine 30 and a solenoid valve 40. In the oxygen generating device for alternately circulating to discharge high-purity oxygen through the regulator 70, A lower cover 100 which seals an upper portion of the first and second zeolite beds 50 and 60 and has a spiral hole 101 and an entrance hole 102 corresponding to each of the zeolite beds 50 and 60, respectively; ; A lower surface is coupled from the upper surface of the lower cover 100 by a predetermined interval, and a first oxygen discharge valve 80 for supplying oxygen to each of the first and second zeolite beds 50 and 60 is installed. The first fastening part 210 to be provided on both sides is provided, the second fastening part 220 to be installed to the second oxygen discharge valve 90 is connected to the regulator 70 is provided in the center portion, An upper cover 200 having a communication hole 201 communicating with the first and second fastening portions 210 and 220 inwardly; One side is fixed to the spiral hole 101 and a through hole 301 having a diameter smaller than that of the entrance and exit hole 102 is formed so that the panel-shaped check is in close contact with the entrance and exit hole 102 by pressure or a part of the gap is spaced at a predetermined interval. High purity oxygen generating device comprising a; valve (300). The method according to claim 1, The upper and lower cover 200, 100 is a high purity oxygen generating device, characterized in that spaced apart by the packing member 110 disposed in the insertion groove formed on the upper surface of the lower cover (100). The method according to claim 1, The motor pump 10 and the radiator 20 are connected to a heat pipe 400 consisting of a copper pipe 410 and a plurality of aluminum heat dissipation fins 420 fixed to the outer circumferential surface of the copper pipe 410. High purity oxygen generator. The method of claim 3, The heat dissipation fin 420 includes a spiral portion 421 surrounding the copper pipe 410 and a plurality of gaps extending from an inner surface of the spiral portion 421 and fitted into the copper pipe 410 and spaced apart from each other. High purity oxygen generator, characterized in that consisting of the contact portion (422).

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