KR20020022964A - control device and control mathod in oxygen generator - Google Patents

Abstract

PURPOSE: An apparatus and a method are provided to shorten the whole pressurization cycle and vacuum cycle by reducing a time required for getting to the set pressure state from the vacuum state or to the vacuum state from the set pressure state during conversion of the pressurizing and vacuum steps in oxygen generator. CONSTITUTION: The apparatus for controlling operation of an oxygen generator comprises an adsorption column(130) in which adsorbent(Z) is filled so as to adsorb nitrogen from air flown into the column and exhausting oxygen; an air pump(110) which pressurizes or vacuums the adsorption column(130); a piping(123) which connects the adsorption column(130) with the air pump(110) so as to form a flow circuit; an inlet side valve(121) which is installed on the piping(123) so that the inlet side valve(121) is positioned at the entrance side of the air pump(110), and which is a three-way valve selectively connecting two ways out of three ways of the external atmospheric environment, the entrance side of the air pump(110) and the adsorption column(130); an outlet side valve(122) which is installed on the piping(123) so that the outlet side valve(122) is positioned at the exit side of the air pump(110), and which is a three-way valve selectively connecting two ways out of three ways of the external atmospheric environment, the exit side of the air pump(110) and the adsorption column(130); a control part(170) controlling the adsorption column(130) to the vacuum state or pressurizing state by instructing transfer of the inlet side valve(121) and the outlet side valve(122); and a signal input part(180) into which signals are inputted so that the control part(170) judges whether to operate the adsorption column(130) in the vacuum or pressurizing state by judging transfer of the valves.

Description

Control device and control method of oxygen generator {control device and control mathod in oxygen generator}

The present invention relates to an oxygen generator, and more particularly, to a control apparatus and a control method of an oxygen generator for adsorbing nitrogen from external air to separate and generate oxygen.

In general, the oxygen generator is to be supplied to the user by separating approximately 21% of the oxygen contained in the atmosphere, it is possible to use a method such as electrolysis of water, a method of chemical reaction, etc. These methods have a problem of low handling trouble 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, and FIG. 1 is a schematic configuration diagram of such a conventional oxygen generator.

As shown, the conventional oxygen generator is an air pump 10 for forced circulation of air, two tri-sides (21, 22) connected in parallel to the air pump 10 to selectively generate an air flow path, An adsorption tower (30) filled with an adsorbent (Z) connected to the two three sides (21, 22) and adsorbing nitrogen from the air therein, and connected to the adsorption tower (30) by the adsorbent (Z). It is largely composed of an oxygen discharge portion 40 for discharging the separated oxygen gas to the outside, and a check valve 50 provided between the adsorption tower 30 and the oxygen discharge portion 40.

On the other hand, as the adsorbent (Z) to be filled in the adsorption tower (30) is generally used zeolite (zeolite) excellent in nitrogen adsorption.

The operation of the conventional oxygen generator configured as described above is a pressurizing step to pressurize the inside of the adsorption tower 30 in order to adsorb nitrogen from the outside air and separate and generate oxygen, and a vacuum step of desorbing and discharging the nitrogen adsorbed on the adsorbent (Z). Each step is described in more detail as follows.

First, in the pressurizing step, the outside air is introduced and compressed through the first three-way side 21 by the operation of the air pump 10, and then supplied to the adsorption tower 30 through the second three-way side 22. 30) is pressurized by the introduced external air.

At this time, nitrogen contained in the outside air is adsorbed to the adsorbent (Z) and oxygen is separated, and when a predetermined pressure or more is discharged to the oxygen discharge portion 40 through the check valve (50).

On the other hand, in the vacuum step, the first and second three-sided (21, 22) is switched to the flow path opposite to the pressurizing step, and the suction tower 30 inside the vacuum by the suction force of the air pump 10, Nitrogen is desorbed from the adsorbent (Z) and discharged to the outside through the first three-way (21), the air pump 10, the second three-way (22) sequentially.

As described above, the conventional oxygen generator generates oxygen while repeatedly performing a pressurization step of separating and generating oxygen and a vacuum step of desorbing and discharging nitrogen.

On the other hand, Figure 2 is a diagram showing the pressure change inside the adsorption tower according to the cycle of the pressurizing step and the vacuum step in the conventional oxygen generator, as shown in the conventional pressure generator in the vacuum stage during the pressurizing step 30 set pressure It takes a long time to pressurize to a state and to vacuum the adsorption tower 30 from a set pressure state to a vacuum state in a vacuum step.

That is, since the pressurization time and the vacuum time are long, there is a problem that the overall pressurization and vacuum cycle of the oxygen generator is increased.

In particular, since the time to reach the set pressure state from the vacuum state is long, the time to press the pressure relative to the constant pressurization time is relatively reduced, and the limit on the output flow rate of oxygen in proportion to the pressure in the adsorption column 30 is limited. have.

In addition, in the conventional oxygen generator is rapidly converted from the pressurization stage to the vacuum stage, or from the vacuum stage to the pressurization stage, the instantaneous severe impact occurs in the air pump 10 by the pressure change at this time, the reliability of the oxygen generator Will adversely affect.

The present invention has been made to solve the above problems and the object is as follows.

First, it is to shorten the overall pressurization cycle and the vacuum cycle of the oxygen generator by reducing the time to reach the set pressure state or the set pressure state from the vacuum state to the vacuum state at the time of mutual conversion between the pressurizing step and the vacuum step in the oxygen generator.

Second, to prevent the sudden change from the pressurization stage to the vacuum stage or from the vacuum stage to the pressurization stage, and to improve the reliability of the oxygen generator by suppressing the instantaneous impact on the air pump.

Third, to maintain a constant concentration of the oxygen supplied to the room in an optimal state.

1 is a schematic configuration diagram of a conventional oxygen generator

2 is a view showing the pressure change inside the adsorption tower according to the cycle of the pressurization step and the vacuum step in the conventional oxygen generator

3A, 3B, and 3C are state diagrams showing an operating state of the oxygen generator according to the first embodiment of the present invention.

4 is a flowchart illustrating the operation of the control unit and the signal input unit of the oxygen generator according to the first embodiment of the present invention.

5 is a view showing the pressure change inside the adsorption tower according to the cycle of the pressurization step and the vacuum step in the oxygen generator according to the first embodiment of the present invention

6 is a view showing the pressure change in the adsorption tower according to different periods of the pressurization step and the vacuum step in the oxygen generator according to the first embodiment of the present invention

7 is a configuration diagram of an oxygen generator according to a second embodiment of the present invention;

8 is a flowchart illustrating an operation of a control unit and a signal input unit of an oxygen generator according to a second embodiment of the present invention.

9 is a flowchart illustrating an operation of a control unit and a signal input unit of an oxygen generator according to another embodiment of the present invention.

10 is a configuration diagram of an oxygen generator according to a third embodiment of the present invention

Explanation of Reference Symbols in Major Parts of Drawings

110. Air pump 121. Intake valve

122. Discharge valve 130. Suction tower

170,171,172. Control unit 180,181,182. Signal input

Z. Adsorbent

According to an aspect of the present invention for achieving the above object, an adsorption tower for adsorbing nitrogen from the air introduced by filling the adsorbent therein, and releases oxygen; An air pump to pressurize or vacuum the adsorption tower; A pipe connecting the adsorption tower and the air pump in parallel to form a flow circuit; A suction side valve installed on the pipe so as to be located at the inlet side of the air pump, the inlet side valve being a three-way valve for selectively communicating two directions among an external atmospheric pressure and an inlet side of the air pump and an adsorption tower; A discharge side valve installed on the pipe so as to be located at the outlet side of the air pump, the discharge side valve being a three-way valve for selectively communicating two directions among an external atmospheric pressure and an outlet side of the air pump and an adsorption tower; A control unit which commands the switching of the suction side valve and the discharge side valve to control the suction tower in a vacuum state or a pressurized state; The control unit of the oxygen generator is provided, characterized in that it comprises a signal input unit for inputting a signal to determine whether to operate in a vacuum state or a pressurized state by determining the valve switching.

The control unit drives the suction tower to communicate with the outside of the suction tower or the discharge side valve in the process of converting the adsorption tower from the pressurized state to the vacuum state or from the vacuum state to the pressurized state. The inside of the valve should be 'Pressed state → Atmospheric pressure → Vacuum state', or 'Vacuum state → Atmospheric pressure → Pressure state'.

According to another aspect of the present invention, as the adsorbent provided therein adsorbs nitrogen from the outside air to open the adsorption tower for separating and generating oxygen, the step of maintaining the inside of the adsorption column at atmospheric pressure; Discharging and desorbing nitrogen adsorbed to the adsorbent while discharging the internal air of the adsorption tower under atmospheric pressure to the outside; Opening the vacuum adsorption column to the outside to maintain the interior of the adsorption column at atmospheric pressure; Provided is a control method of an oxygen generator including the step of introducing external air into the adsorption tower under atmospheric pressure and pressurizing the inside of the adsorption tower to a set pressure state.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 3A, B, and C to FIG. 5.

Figure 3a is a state diagram showing the atmospheric pressure state of the oxygen generator according to the first embodiment of the present invention, Figure 3b is a state diagram showing a vacuum state of the oxygen generator according to the first embodiment of the present invention, Figure 3c It is a state diagram which shows the pressurized state of the oxygen generator which concerns on 1st Example.

As shown, the present invention includes an adsorption tower 130 having an adsorbent Z therein, an air pump 110 for pressurizing or vacuuming the adsorption tower 130, the air pump 110, and the adsorption tower 130. ) In parallel to form a flow circuit, the suction side valve 121 is installed on the inlet side pipe 123 of the air pump, and the outlet side pipe 123 of the air pump The discharge side valve 122 and the oxygen discharge unit 140 connected to the adsorption tower 130 by the check valve 150, the suction side valve 121 and the discharge side valve 122 of the A control unit 170 for commanding a switching to control the adsorption tower 130 in a vacuum state or a pressurized state; The control unit 170 includes a signal input unit 180 for inputting a signal to determine whether to operate in a vacuum state or a pressurized state by determining the valve switching.

Particularly, the suction side valve 121 selectively selects an adsorption tower 130 side and an external (O) side, an adsorption tower 130 side and an air pump 110 side, and an external (O) side and an air pump 110 side. It is a three-way valve type direction switching valve that can communicate with each other.

In addition, the discharge valve 122 is the adsorption tower 130 side and the outer (O) side, the air pump 110 and the outside (0) side, the air pump 110 and the adsorption tower 130 side selectively, respectively It is a three-way valve type direction switching valve that can communicate.

Meanwhile, the direction switching of the suction side valve 121 and the discharge side valve 122 is controlled by the control unit 170, and the signal input unit 180 is connected to the control unit 170.

Here, the signal input unit 180 is a timer for outputting time, and the control unit 170 compares the time value input from the timer with a set value so that the suction side valve 121 and the discharge side are in a pressurized state or a vacuum state. It is to switch the valve 122.

4 is an operation flowchart of the control unit and the signal input unit of the oxygen generator according to the first embodiment of the present invention. Referring to FIG. 4, the operations of the control unit 170 and the signal input unit 180 will be described in detail as follows. .

When the oxygen generator is operated, the suction side valve 121 and the discharge side valve 122 are maintained or switched so that the oxygen generator is at atmospheric pressure, and time counting is started at the signal input unit 180, and the signal input unit 180 is operated. The oxygen generator is maintained at an atmospheric pressure until the time counted at is equal to the atmospheric pressure holding time T _a set in the controller 170.

That is, the atmospheric pressure state is maintained for the atmospheric pressure holding time T _a set in the controller 170.

And, when the counted time by the signal input unit 180, such as atmospheric pressure holding time (T _a), the intake-side valve 121 and the exhaust-side valve 122 has the vacuum step is performed is switched to a vacuum.

At this time, the time counting of the signal input unit 180 is reset and recounted, and oxygen until the time counted by the signal input unit 180 is equal to the vacuum state holding time T _V set in the controller 170. The generator is maintained in a vacuum state, and thus, the vacuum step is performed during the vacuum state holding time T _V set in the controller 170.

When the time counted by the signal input unit 180 is equal to the vacuum state maintaining time T _V , the suction side valve 121 and the discharge side valve 122 are switched back to the atmospheric pressure state. As described above, the oxygen generator is maintained at the atmospheric pressure during the atmospheric pressure holding time T _a set in the controller 170.

In addition, when the time counted by the signal input unit 180 is equal to the atmospheric pressure holding time (T _a ), the suction side valve 121 and the discharge side valve 122 is switched to be in a pressurized state and the pressurization step is performed.

At this time, the time counting of the signal input unit 180 is reset and recounted, and the time counted by the signal input unit 180 is equal to the pressurized state holding time T _C set in the controller 170. The oxygen generator is maintained in a pressurized state, so that the pressurizing step is performed during the pressurized state holding time T _c set in the controller 170.

As a result, in the first embodiment of the present invention, each of the above steps is repeated in one cycle.

The operation of the oxygen generator according to the present invention having such a configuration will be described in detail.

First, in the oxygen generator of the present invention, under the control of the control unit 170 as shown in FIG. 3A, the suction side valve 121 connects the adsorption tower 130 side and the external (0) side and simultaneously discharge side valve 122. ) Also connects the adsorption tower 130 side and the outside (0) side.

Accordingly, the adsorption tower 130 is opened to the outside through the suction side valve 121 and the discharge side valve 122, the interior of the adsorption tower 130 to maintain the atmospheric pressure state.

Setting time of the next control unit 170 (T _a), the adsorption tower (130), the suction-side valve 121 under the control of the controller 170, as shown in Figure 3b after the atmospheric pressure maintained for a side with an air pump The outlet side valve 122 is switched to connect the air pump 110 side and the outside (O) side while being switched to the (110) side.

Then, the air pump 110 is operated, the internal air of the adsorption tower 130 is sucked by the suction force of the air pump 110 is discharged to the outside while being decompressed to a vacuum state.

At this time, the nitrogen adsorbed to the adsorbent (Z) is released from the adsorbent (Z) by the suction force of the air pump 110, the suction side valve 121, the air pump 110 and the discharge side valve 122. It is discharged to the outside through sequentially.

In particular, in the vacuum step of desorbing nitrogen in the present invention, since the adsorption tower 130 is at atmospheric pressure, the time required for the adsorption tower 130 to reach a vacuum state is shortened as shown in FIG. 5.

In addition, by desorbing nitrogen adsorbed on the adsorbent Z and regenerating the adsorbent Z, oxygen can be newly adsorbed to generate and separate oxygen.

After the vacuum step is performed for the vacuum time T _V set in the controller 170 as described above, the suction side valve 121 is again moved to the adsorption tower 130 by the control of the controller 180 as shown in FIG. 3A. At the same time as connecting the external (O) side and the discharge side valve 122 also connected to the adsorption tower 130 side and the outside (O) side, the adsorption tower 130 is the suction side valve 121 and the discharge side valve Open to the outside through the 122, the air pump 110 is stopped.

Thus, in the atmospheric pressure state for external air, the suction-side valve 121 and by being introduced through the discharge side valve 122, and atmospheric pressure holding time (T _a) is set in the adsorption tower (130) inside the back control unit 170 It is maintained.

Next, the suction side valve 121 is switched to the outside (O) side and the air pump 110 side under the control of the controller 170 as shown in FIG. 3C, and the discharge side valve 122 is the air pump 110. ) Is switched to connect the side and the adsorption tower 130 side, the air pump 110 is operated.

In addition, the outside air compressed by the air pump 110 is introduced into the adsorption tower 130 sequentially through the suction side valve 121, the air pump 110, and the discharge side valve 122, and the controller 170. During the set pressurization time T _c ), the adsorption tower 130 is pressurized from the atmospheric pressure to the set pressure.

At this time, oxygen is separated and generated as nitrogen contained in the outside air is adsorbed to the adsorbent (Z).

In addition, the oxygen generated in this manner is discharged to the oxygen discharge unit 140 through the check valve 150.

In particular, in the pressurizing step of separating and generating oxygen in the present invention, since the adsorption tower 130 is at atmospheric pressure, the time for reaching the adsorption tower 130 to a set pressure state is shortened as shown in FIG. 5. .

As described above, the present invention is to generate oxygen while repeatedly performing the above-described steps, that is, the atmospheric pressure step-vacuum step-atmospheric pressure step-pressing step in order.

That is, it can be seen that the present invention can shorten the time to reach the set pressure state in the pressurizing step and the time to reach the vacuum state in the vacuum step.

Therefore, in the present invention, when the pressurization time T _c and the vacuum time T _v are set at the same period as in the prior art, the set pressure and the vacuum degree of the oxygen generator can be increased.

In addition, since the oxygen generation amount and the oxygen concentration of the oxygen generator are in proportion to the pressure inside the adsorption tower 130, the present invention can increase the oxygen generation amount and the oxygen concentration.

6 is a view showing a pressure change in the adsorption tower according to different periods of the pressurization step and the vacuum step in the oxygen generator according to the first embodiment of the present invention.

As described above, the present invention shortens the time for reaching the set pressure state in the pressing step or the vacuum state in the vacuum step.

Therefore, when using the oxygen generator of the present invention based on the same pressure and vacuum effect as in the prior art as shown in Figure 6, it is possible to shorten the pressurization cycle and the vacuum cycle.

Hereinafter, an oxygen generator according to a second embodiment of the present invention will be described.

7 is a configuration diagram of the oxygen generator according to the second embodiment of the present invention, as shown in the overall configuration of the oxygen generator according to the second embodiment of the present invention is the same as the first embodiment of the present invention described above In particular, in the present embodiment, the control unit 171 for controlling the suction tower 130 in a vacuum state or a pressurized state by commanding the switching of the suction side valve 121 and the discharge side valve 122, and the control unit 171. The signal input unit 181 inputs a signal so as to determine whether to operate in a vacuum state or a pressurized state by judging valve switching.

8 is a flowchart illustrating operations of a control unit and a signal input unit of an oxygen generator according to a second embodiment of the present invention.

That is, the signal input unit 181 is a gas sensor that detects the gas concentration in the room and outputs the gas concentration, and the control unit 171 sets the concentration value input from the signal input unit 181 which functions as a gas sensor. In comparison, the suction side valve 121 and the discharge side valve 122 are switched to be in a pressurized state or a vacuum state.

In particular, the present invention can select a variety of gases detected by the signal input unit 181, in the present embodiment will be described as an example of detecting the concentration of carbon dioxide.

First, when the oxygen generator is operated, the suction side valve 121 and the discharge side valve 122 are maintained or switched to maintain the oxygen generator in a vacuum state, and a vacuum step is performed. The signal input unit 181 measures the concentration of carbon dioxide in the room. Measure

At this time, when the concentration of carbon dioxide in the room measured by the signal input unit 181 is greater than or equal to the concentration set value of the maximum carbon dioxide set in the control unit 171, the control unit 171 is the suction side valve 121 and the discharge side valve 122. ) So that the oxygen generator is pressurized.

That is, the increase in the concentration of carbon dioxide measured by the signal input unit 181 means that the oxygen concentration in the room is reduced by that amount, so as to increase the oxygen concentration in the room.

On the other hand, while the pressing step is performed as described above, the signal input unit 181 continuously measures the concentration of carbon dioxide in the room, and when the measured concentration of the carbon dioxide in the room is less than or equal to the concentration set value of the minimum carbon dioxide set in the control unit 171, The controller 171 switches the suction side valve 121 and the discharge side valve 122 so that the oxygen generator is in a vacuum state.

Reducing the concentration of carbon dioxide measured by the signal input unit 181 means that the oxygen concentration in the room is increased by that much, so as to appropriately reduce the oxygen concentration in the room.

That is, in this embodiment, by setting the concentration range of the maximum carbon dioxide concentration and the minimum carbon dioxide, and repeating the pressing step and the vacuum step in the range of the carbon dioxide concentration, it is possible to maintain the room at the optimum oxygen concentration.

9 is a flowchart illustrating an operation of a control unit and a signal input unit of an oxygen generator according to another embodiment of the present invention.

As shown, another embodiment of the second embodiment of the present invention also the signal input unit 181 detects the carbon dioxide concentration in the room, the control unit 171 is a concentration set the concentration value of the carbon dioxide measured from the signal input unit 181 In comparison with the value, when the carbon dioxide concentration in the room is above the maximum set value, the pressurizing step is performed to generate oxygen, and when the carbon dioxide concentration in the room is below the minimum setting value, the vacuum step is performed to desorb nitrogen.

In particular, in another embodiment of the second embodiment, the oxygen generator is subjected to atmospheric pressure when the oxygen generator is converted from pressurized to vacuum or from vacuum to pressurized by the set concentration value.

Accordingly, the oxygen generator repeatedly maintains the atmospheric pressure → vacuum state → atmospheric pressure → pressurized state as one cycle, thereby maintaining the optimal oxygen concentration in the room.

In addition, the controller 171 passes the atmospheric pressure state when it is converted from the pressurized state into the vacuum state or from the vacuum state to the pressurized state, so that the time to reach the set pressure state as described in the first embodiment. And time to reach the vacuum state can be shortened.

Hereinafter, an oxygen generator according to a third embodiment of the present invention will be described.

10 is a configuration diagram of an oxygen generator according to a third embodiment of the present invention, as shown in the overall configuration of the oxygen generator according to the third embodiment of the present invention is the first embodiment of the present invention, the second The same as the embodiment, in particular in the present embodiment, the control unit 171 for commanding the switching of the suction side valve 121 and the discharge side valve 122 to control the adsorption tower 130 in a vacuum state or a pressurized state, The control unit 171 has a feature in the signal input unit 181 for inputting a signal to determine whether to operate in a vacuum state or a pressurized state by determining the valve switching.

Hereinafter, an oxygen generator according to a third embodiment of the present invention will be described.

The overall configuration and operation of the oxygen generator according to the third embodiment of the present invention is also the same as the first embodiment of the present invention described above. The feature of this embodiment is that the signal input unit 182 selects a pressurized state or a vacuum state. It is made of a key input unit, and the control unit 172 is to determine to operate in a pressurized state or a vacuum state according to the value input from the signal input unit 182.

That is, by the input of the signal input unit 182 which is a key input unit, the control unit 172 determines the switching between the input values of the signal input unit 182. It is to be converted to a pressurized state at.

Of course, according to the third embodiment of the present invention, when the oxygen generator is converted from the pressurized state to the vacuum state or from the vacuum state to the pressurized state according to the input of the signal input unit 182, the above-mentioned It is clear that the time to reach the set pressure state or the vacuum state can be shortened as described in the first and second embodiments.

As described above, the present invention has the following effects.

First, by introducing an atmospheric pressure step between the pressurizing step and the vacuum step, the time to reach the set pressure state or the vacuum state is shortened, thereby reducing the pressurization cycle and the vacuum cycle.

Second, according to the present invention, as the time for reaching the set pressure state or the vacuum state is shortened, the set pressure and the degree of vacuum can be increased when maintaining the same pressurization cycle and vacuum cycle as in the prior art.

In addition, since the present invention is faster to reach the set pressure state than in the related art, it is possible to increase the oxygen generation amount and the oxygen concentration by increasing the internal pressure of the adsorption tower in proportion to the oxygen generation amount and the oxygen concentration by performing pressurization for the remaining time. It is possible.

Third, because it is pressurized or vacuum at atmospheric pressure, it prevents the rapid switching between pressurization and vacuum to suppress the instantaneous impact on the air pump, thereby helping to improve the reliability of the oxygen generator.

Fourth, by measuring the specific gas concentration in the room, it is possible to adjust the production and supply of oxygen to maintain the oxygen concentration in the room within a certain range.

Fifth, the pressurization step and the vacuum step can be easily converted to each other according to a user's selection.

Claims (2)

An adsorption tower which fills with an adsorbent to adsorb nitrogen from the introduced air and releases oxygen; An air pump to pressurize or vacuum the adsorption tower; A pipe connecting the adsorption tower and the air pump in parallel to form a flow circuit; A suction side valve installed on the pipe so as to be located at the inlet side of the air pump, the inlet side valve being a three-way valve for selectively communicating two directions among an external atmospheric pressure and an inlet side of the air pump and an adsorption tower; A discharge side valve installed on the pipe so as to be located at the outlet side of the air pump, the discharge side valve being a three-way valve for selectively communicating two directions among an external atmospheric pressure and an outlet side of the air pump and an adsorption tower; A control unit which commands the switching of the suction side valve and the discharge side valve to control the suction tower in a vacuum state or a pressurized state; And a signal input unit for inputting a signal to the controller to determine whether to operate in a vacuum state or a pressurized state by judging valve switching. The method of claim 1, The control unit drives one of the suction side valve or the discharge side valve to communicate with the outside of the adsorption tower in a process of converting the adsorption tower from a pressurized state into a vacuum state or from a vacuum state to a pressurized state, thereby allowing the outside of the adsorption tower to communicate with each other. Operation control device of the oxygen generator characterized in that the 'pressure state → atmospheric pressure → vacuum state', or 'vacuum state → atmospheric pressure → pressure state'.