KR100686107B1 - Device for sensing pressure leakage in oxygen generator - Google Patents

Abstract

The present invention relates to a pressure leak detection device for an oxygen generator installed in a pipeline forming an air flow path of an oxygen generator, the pressure leak detection device of the oxygen generator, the pressure leakage detection device of the present invention draws in the outside air by the air pump An oxygen generator isolating the oxygen by performing the adsorption process of nitrogen by pressurization to be discharged to the user, comprising: a hollow body vertically communicated on the pipe connecting the air pump and the oxygen separation device; A flexible diaphragm installed at a lower end of the body in a sealed manner along the inner circumferential surface of the body to expand and contract by air pressure flowing along a pipe line; An electrolyte solution filled with a predetermined head on the diaphragm; A plurality of electrode rods connected to an external power source and installed at different heights in the upper end of the body so that current flows in the electrolyte solution according to the head of the electrolyte solution changed by vertical vibration of the diaphragm; It is configured to include a light emitting device connected to the electrode to visually transfer the current flow state to the user.

Oxygen Generator, Pressure Sensing Device

Description

Device for sensing pressure leakage in oxygen generator

1 is a configuration diagram showing the configuration of a typical oxygen generator

2 is a sectional view showing the main parts of the pressure leakage detecting apparatus according to the present invention;

Explanation of Reference Symbols in Major Parts of Drawings

600-Sensor 610-Body

620-Diaphragm 631 ~ 634-Electrode

A, B, C-light emitting diode L-electrolyte

The present invention relates to an oxygen generator, and more particularly, to an apparatus for detecting pressure leakage of an oxygen generator installed in a conduit forming an air flow path of an oxygen generator to detect leakage of air pressure.

In general, the oxygen generator is to be supplied to the user by separating the oxygen of 21% contained in the atmosphere, it is possible to use a method such as the electrolysis of water, the reaction of chemicals, etc. The methods suffered from troublesome handling and low stability.

Therefore, in recent years, an oxygen generator for separating and supplying oxygen by using a method of adsorbing and desorbing oxygen from the atmosphere is mainly used. An example of the configuration of the oxygen generator will be described with reference to the accompanying drawings. Same as

As shown in FIG. 1, the conventional oxygen generator includes an air pump 10 for forced circulation of air, and two triangular valves 21 connected in parallel with the air pump 10 to selectively generate an air flow path. 22) and an adsorption tower 30 connected to the two three sides 21 and 22 and filled with an adsorbent Z for adsorbing nitrogen from the air therein, and connected to the adsorption tower 30 through an adsorption tower. It is composed of an oxygen discharge portion 40 for discharging the separated oxygen gas to the outside.

As the adsorbent Z filled in the adsorption tower 30, zeolite having excellent nitrogen adsorption property is mainly used.

Operation of the conventional general oxygen generator configured as described above is made as follows.

When the operation of the oxygen generator starts, the outside air is drawn in through the first three-way (21) by the operation of the air pump 10, compressed and then supplied to the adsorption tower (30) through the second three-way (22). As a result, the adsorption tower 30 is pressurized by the sent external air.

As described above, in the adsorption tower 30 pressurized by external air, nitrogen in the atmosphere is adsorbed by the adsorbent Z, and oxygen is separated and discharged to the oxygen discharge unit 40.

On the other hand, after a certain time elapses the process of desorbing nitrogen from the adsorbent is carried out, wherein the first, two, and three sides 21, 22 form a flow path opposite to the initial.

That is, when the desorption mode is selected, the flow path of the first three-way direction 21 and the second three-way direction 22 is switched, and the adsorbent while the inside of the adsorption tower 30 is vacuumed by the operation of the air pump 10. Nitrogen gas is desorbed from (Z) and discharged to the outside through the first three-way 21, the air pump 10, and the second three-way 22 in order.

This desorption process proceeds until the nitrogen gas in the adsorption tower 30 is completely desorbed and discharged.

As described above, the oxygen generator performs the adsorption and desorption process as described above and provides oxygen to the user. The generation of oxygen through this process is proportional to the amount of zeolite as the adsorbent and the air pressure provided.

Therefore, when the pressure is lowered according to various factors such as leakage of the connection part of the air flow line and each component and pressure loss caused by the pipe in the oxygen generator, the generation of oxygen is lowered.

Accordingly, in recent years, a post-measurement has been taken by installing a sensor 60 capable of detecting pressure in the pipeline 25 of the oxygen generator, or by detecting a pressure leak using a flow meter or the like to check the flow rate. .

However, in the case of mounting a sensor to detect the pressure leakage as described above, it is easy to detect the leak, but the cost of the equipment is expensive, which is a factor that increases the cost, and even if a flow meter is installed, it may be expensive. In addition, it was difficult to identify leaks.

Accordingly, the present invention has been made in order to solve the above problems, by installing a pressure leakage detection device made of a structure that can detect pressure leakage accurately and cheaply installed in the air passage of the oxygen generator air passage of the oxygen generator The purpose is to improve the reliability of operation.

In order to achieve the above object, the present invention, the air pump for forced circulation by drawing the outside air; An oxygen separation device connected to the air pump through a pipe line through which air flows, and separating oxygen by adsorbing nitrogen by pressurization while the outside air sucked by the air pump is introduced; An oxygen generator comprising an oxygen discharge device for discharging the oxygen gas separated from the oxygen separation device to the outside, comprising: a hollow body vertically communicated on a pipe connecting the air pump and the oxygen separation device; A flexible diaphragm installed at a lower end of the body in a sealed manner along the inner circumferential surface of the body to expand and contract by air pressure flowing along a pipe line; An electrolyte solution filled with a predetermined head on the diaphragm; A plurality of electrode rods connected to an external power source and installed at different heights in the upper end of the body so that current flows in the electrolyte solution according to the head of the electrolyte solution changed by vertical vibration of the diaphragm; It is connected to the electrode provides a pressure leak detection device of the oxygen generator, characterized in that configured to include a light emitting device for visually transmitting the current flow state to the user.

Hereinafter, with reference to the accompanying drawings an embodiment of the pressure leakage detection device of the oxygen generator according to the present invention will be described in detail.

For the sake of clarity, the basic configuration of the oxygen generator except for the pressure leakage detecting device is the same as that described in the above-described conventional technology, which will be described with reference to FIG. 1.

Pressure leak detection device 600 of the present invention is preferably installed on the pipe line 25 for connecting the second three-way (22) and the adsorption tower (30).

Here, looking at the configuration of the pressure leak detection device, the hollow cylindrical body 610 is installed in vertical communication with the air flow pipe (25), the lower end of the body 610, that is, the body 610 And a flexible diaphragm 620 is installed along the inner circumferential surface of the body 610 at a portion where the conduit 25 is connected, and the body 610 is completely closed from the conduit 25 by the diaphragm 620. .

In addition, an electrolyte solution L such as sodium chloride solution is filled directly above the diaphragm 620 by a predetermined height.

In addition, a plurality of electrode rods 631, 632, 633, and 634 are formed at upper ends of the body 610 so that the lower ends thereof have different heights from the diaphragm 620 so as not to be contained or soaked according to the height of the electrolyte solution. Among them, one electrode 631 having the lowest height among these electrodes 631 to 634 is connected to the anode (+) of the external power source, and the other electrodes 632, 633, and 634 are each in a current flow state. It is connected to the cathode (-) of the external power supply via a plurality of light emitting diodes (A, B, C: LED) for visually delivering to the user.

Therefore, since the electrode to be contained in the electrolyte (L) allows the flow of current, light is emitted from the light emitting diodes (A, B, C) connected thereto, and conversely, the electrode not contained in the electrolyte (L) is the current. Since no light is emitted from the light emitting diodes connected thereto, the present invention uses the same principle to bring the light emitting diodes C connected to the electrode 634 at the highest position into a normal state, and then to the next highest light emitting diode. When the light emitting diode B connected to the electrode 633 at the position is displayed at a low pressure state, and the light emitting diode A connected to the electrode 632 at the next higher position is marked as a dangerous state, the user changes the head of the electrolyte solution. It is possible to easily grasp the state of the air pressure depending on whether the light emitting diodes A, B, and C emit light.

In detail, when the operation of the oxygen generator is started, the air flows along the pipe line 25 by the air pump 10 (see FIG. 1), and in the pressure leakage detecting device installed on the pipe line 25, the diaphragm ( 620 is inflated by the air pressure to increase the height of the electrolyte (L).

At this time, if there is no leakage of air pressure in the oxygen generator, the electrolyte (L) is raised to a height that the bottom of the electrode 634 of the highest position is locked so that current can flow in all the electrodes (631 ~ 634). As a result, all of the light emitting diodes A, B, and C connected to the electrode electrodes 631 to 634 emit light. The initial height at this time is the height of the electrolyte solution.

If air pressure leakage occurs due to air leakage during operation of the oxygen generator, the diaphragm 620 shrinks as the air pressure decreases, and the head of the electrolyte solution L is lowered. When the lower part of the electrode 633 in the high position comes down to the point where it is barely locked, the light of the light emitting diode (C) indicating the normal state is turned off, and only the low pressure and the dangerous state light emitting diodes (B, A) light up and the low pressure You will be notified of the status.

When the head of the electrolyte (L) becomes excessively low so that the lower end of the electrode rod 632 of the third highest position is immersed, the light of the light emitting diode B indicating the low pressure is turned off and the dangerous state is Will be announced.

As described above, according to the present invention, the head of the electrolyte solution L changes according to the change in air pressure, and according to the change in the head of the electrolyte solution L, whether or not current flows in each electrode 631 to 634 is determined. Pressure leakage may be sensed by determining whether the light emitting diodes A, B, and C connected to the 631 to 634 emit light.

As described above, according to the present invention, the installation cost can be reduced by electrically detecting and displaying a change in the head of the electrolyte depending on the pressure of the air flowing through the pipe without installing an expensive pressure sensor or a flow meter. Detection of pressure leakage can be made easily.

Claims (2)

An air pump that draws outside air and forcibly circulates it; An oxygen separation device connected to the air pump through a pipe line through which air flows, and separating oxygen by adsorbing nitrogen by pressurization while the outside air sucked by the air pump is introduced; In the oxygen generator comprising an oxygen discharge device for discharging the oxygen gas separated from the oxygen separation device to the outside, A hollow body vertically communicating on a pipe connecting the air pump and the oxygen separator; A flexible diaphragm installed at a lower end of the body in a sealed manner along the inner circumferential surface of the body to expand and contract by air pressure flowing along a pipe line; An electrolyte solution filled in an upper portion of the diaphragm; Pressure leak detection device of the oxygen generator, characterized in that it comprises a detection means for detecting the change in the head of the electrolyte according to the expansion and contraction of the diaphragm. The method of claim 1, wherein the sensing means is connected to an external power source, different heights in the upper end of the body to allow the flow of current is contained in the electrolyte according to the head of the electrolyte is changed by the vertical vibration of the diaphragm A plurality of electrode rods; Connected to the electrode rod pressure leakage detection device of the oxygen generator, characterized in that it comprises a light emitting device for transmitting the current flow state to the user visually.

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