KR20220151494A - Hydrogen respiration generator drive control system for treatment - Google Patents

Abstract

The present invention relates to a hydrogen respiration generator drive control system for treatment. The hydrogen respiration generator drive control system for treatment according to the present invention comprises: a hydrogen respiration generator which electrolyzes collected purified water to generate hydrogen gas and oxygen gas, cools water vapor included with the hydrogen gas when discharging the generated hydrogen gas, and returns the cooled water vapor to the tank in which the purified water is collected; a user terminal which acquires time information including use start time and end time in link with the hydrogen respiration generator, and transmits the acquired time information; and a management server which collects identification information of the user, determines whether the user continuously uses the hydrogen respiration generator by accumulating the time information received from the user terminal, and provides event information according to the determination result. According to the present invention, a cooling device is installed on one side of a hydrogen gas storage formed inside the water tank in which the purified water is collected so that water flowing into a hydrogen discharge pipe can be recovered to the inside of the hydrogen gas storage to prevent water vapor other than the hydrogen gas from flowing into the hydrogen discharge pipe. A discharge pipe is formed to be divided into a hydrogen gas discharge pipe and an oxygen gas discharge pipe so that a user can selectively breathe the hydrogen gas or the hydrogen and the oxygen gas at the same time.

Description

Hydrogen respiration generator drive control system for treatment {Hydrogen respiration generator drive control system for treatment}

The present invention relates to a driving control system for a hydrogen respiration generator for treatment, and more particularly, to provide a device capable of inhaling hydrogen generated through electrolysis of a polymer electrolyte method, but enabling the user to monitor the user's use cycle, so that the user It relates to a hydrogen respiration generator drive control system for treatment that induces continuous use.

It is said that 90% of aging and diseases are caused by active oxygen. While 2% (14g) of about 700g of oxygen consumed per day by adults turns into active oxygen, the removal of active oxygen that attacks the cell membrane, which is the health effect of antioxidant enzymes, gradually decreases from the age of 30.

Active oxygen attaches to normal cells or proteins to deform the existing shape and prevent their functioning. There were research results. In addition, a research team at Johns Hopkins Medical School in the United States revealed that more than 90% of all diseases are caused by active oxygen.

Hydrogen gas relieves the oxidation of the human body by active oxygen generated as a by-product of ATP energy source generated from mitochondria in the human body and is discharged through sweat and urine. In other words, by neutralizing active oxygen in the body, hydrogen gas shows effects such as anti-inflammatory action, antioxidant action, respiratory diseases, circulatory diseases, diabetes, and kidney disorders.

In addition, hydrogen gas has various effects such as cell proliferation signal transmission system action, angiogenesis inhibition action, and apoptosis inhibition through antioxidant action and anti-inflammatory action. These actions improve rheumatoid arthritis, etc. It also has the potential to inhibit the neurological process of the disorder.

Therefore, research on removing active corals using hydrogen gas has recently been continued, which has led to research on devices for generating hydrogen-oxygen mixed gas.

However, the conventional hydrogen-oxygen mixture gas generator generates a large amount of water vapor due to high heat, and since this is introduced into the suction tube, there is a problem in that water and hydrogen are discharged together during suction.

The background technology of the present invention is disclosed in Korean Patent Registration No. 10-1801364 (published on November 24, 2017).

The technical problem to be achieved by the present invention is to provide a device capable of inhaling hydrogen generated through electrolysis of a polymer electrolyte method, but to monitor the user's use cycle, thereby inducing the user to continuously use therapeutic hydrogen breathing It is to provide a generator drive control system.

Hydrogen gas and oxygen gas are generated by electrolyzing the collected purified water according to an embodiment of the present invention to achieve this technical problem, and when the generated hydrogen gas is discharged, the water vapor included with the hydrogen gas is cooled, and the cooling A hydrogen respiration generator that recovers the purified water vapor into the tank in which the purified water is collected, a user terminal that obtains time information including use start time and end time in conjunction with the hydrogen respiration generator, and transmits the obtained time information, and the and a management server that collects user identification information, accumulates time information received from the user terminal, determines whether the user continuously uses the device, and provides event information according to the determination result.

The hydrogen respiration generator collects purified water, measures the water level for the purified water inside, and is connected to a water tank for recovering generated hydrogen gas and electricity to decompose the purified water introduced into hydrogen gas and oxygen gas. A decomposition cell, a cooling device located on one side of the hydrogen gas discharge pipe connected to the water tank, and cooling the inside of the discharge pipe, and controlling the operation of the electrolysis cell and the cooling device by receiving power supplied from the outside, A control unit may be included to measure start and end times of discharge of oxygen and hydrogen from the oxygen gas discharge pipe and the hydrogen gas discharge pipe connected to the upper side and transmit the results to the user terminal.

The water tank collects purified water, and a sensor for measuring the level of the purified water therein, a hydrogen gas storage unit for recovering generated hydrogen gas, a purified water passage pipe for supplying the purified water to the electrolysis cell, and the electrolysis cell. An oxygen gas inlet pipe that introduces hydrogen gas generated by the cell and a part of the purified water provided to the electrolysis cell, an oxygen gas outlet pipe that is connected to the outside and discharges oxygen gas, a hydrogen gas outlet pipe that discharges hydrogen gas, and the electricity A hydrogen gas inlet pipe for introducing hydrogen gas generated by the decomposition cell into the hydrogen gas storage unit,

The hydrogen gas discharge pipe may pass through the cooling device, and liquefied water vapor by the cooling device may be injected in a shape inclined at a predetermined inclination angle so that water vapor liquefied by the cooling device may be returned to the water tank.

The inclination angle may be formed to be greater than or equal to 35° and less than or equal to 55° relative to the horizontal.

On the upper side of the hydrogen gas storage unit, a hydrogen gas inlet pipe for introducing hydrogen gas generated from the electrolysis cell and a hydrogen gas discharge pipe for discharging collected hydrogen gas to the outside or recovering liquefied water vapor are formed,

A vapor discharge pipe for discharging the liquefied vapor to the inside of the water tank may be formed at a lower portion of the hydrogen gas storage unit.

The controller includes a power supply module that converts AC power into DC power and supplies it;

A driving module for generating a driving signal for driving the electrolysis cell and the cooling device according to an input of the operation panel, and a start time and an end time of the electrolysis cell and the cooling device respectively driven according to the generated driving signal. A time information acquisition module for acquiring time information, performing wireless communication with the user terminal to transmit the current driving state and the obtained time information to the user terminal, and upon receiving a driving stop or play signal from the user terminal, the received A communication module for transmitting the received signal to the driving module, and a voice output module for outputting a guide message according to the level information of the purified water received from the sensor installed in the water tank and the start or end of driving of the electrolysis cell and the cooling device by voice. can include

The user terminal is either a personal terminal carried by the user or a stationary terminal installed in the field, and is connected to the hydrogen respiration generator by short-range communication, and is connected to the hydrogen respiration generator in the current driving state and start time and end time. It outputs time information according to, and it is possible to stop or reproduce the driving of the hydrogen respiration generator.

The management server accumulates the number of uses for each user by using a receiving unit that receives time information according to start and end times from the user terminal, and the received time information, and determines whether the accumulated number of uses appears continuously. It may include a determining unit that determines, and an event information providing unit that provides event information that can participate if it is determined that the user has continuously used for a predetermined period of time.

As described above, according to the present invention, by installing a cooling device on one side of the hydrogen gas storage formed inside the water tank in which purified water is collected, water flowing into the hydrogen discharge pipe can be recovered to the inside of the hydrogen gas storage so that water vapor other than hydrogen gas can be recovered can be prevented from entering the hydrogen discharge pipe, and the discharge pipe is formed by separating the hydrogen gas discharge pipe and the oxygen gas discharge pipe, so that the user can select and breathe hydrogen gas and oxygen gas at the same time.

In addition, according to the present invention, the use of the hydrogen respiration generator is recorded in conjunction with the user terminal, and when it is not used continuously, a notification message is output through the user terminal to allow the user to continuously use the hydrogen respiration generator. can be induced to do so.

1 is a block diagram showing a hydrogen respiration generator driving control system for treatment according to an embodiment of the present invention.
Figure 2 is a configuration diagram for explaining the hydrogen breathing generator shown in Figure 1.
FIG. 3 is an enlarged view of the water tank shown in FIG. 2 .
4 is a configuration diagram for explaining the control unit shown in FIG. 1;
5 is a configuration diagram for explaining the user terminal of FIG. 1 .
6 is a configuration diagram for explaining the management server of FIG. 1 .
Figure 7 is a flow chart showing the operational flow of the treatment hydrogen respiration generator driving control method according to an embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

First, a hydrogen respiration generator driving control system for treatment according to an embodiment of the present invention will be described through FIGS. 1 to 6.

1 is a block diagram showing a hydrogen respiration generator driving control system for treatment according to an embodiment of the present invention.

As shown in Figure 1, the hydrogen respiration generator driving control system for treatment according to an embodiment of the present invention includes a hydrogen respiration generator 100, a user terminal 200 and a management server 300.

First, the hydrogen respiration generator 100 is a device for generating hydrogen gas and oxygen gas by electrolysis of purified water collected in a water tank, and a cooling device is installed on one side of a discharge pipe for discharging hydrogen gas. Then, the hydrogen respiration generator 100 liquefies the water vapor contained in the discharged hydrogen gas and recovers it into the hydrogen, thereby preventing water from forming on the hydrogen gas discharge pipe or being discharged to the outside when the user inhales the hydrogen gas.

The user terminal 200 is connected to the hydrogen respiration generator 100 by short-range communication, receives and outputs the start and end times of using the hydrogen respiration generator 100, and stops or reproduces the operation of the hydrogen respiration generator 100. It can provide a signal that can do it. Meanwhile, the user terminal 200 may be any one of a personal terminal carried by the user and a stationary terminal installed in the field.

Finally, the management server 300 receives the use information according to the start time and end time of using the hydrogen respiration generator 100 through the user terminal 200, and accumulates the received use information. In addition, the management server 300 transmits event information capable of participation to the user terminal 200 using the accumulated usage information.

Hereinafter, the hydrogen respiration generator 100 according to an embodiment of the present invention will be described in more detail using FIGS. 2 to 4.

2 is a configuration diagram for explaining the hydrogen respiration generator shown in FIG. 1, FIG. 3 is an enlarged view of the water tank shown in FIG. 2, and FIG. 4 is a configuration diagram for explaining the control unit shown in FIG. .

As shown in Figure 2, the hydrogen respiration generator 100 according to an embodiment of the present invention includes a water tank 110, an electrolysis cell 120, a cooling device 130 and a control unit 140.

First, the water tank 110 collects purified water to have a certain depth. Then, the water tank 110 provides purified water to the electrolysis cell 120, and introduces oxygen gas and hydrogen gas decomposed by the electrolysis cell 120. In addition, the water tank 110 discharges oxygen gas and hydrogen gas introduced into the inside to the outside.

In detail, as shown in FIG. 3, the water tank 110 has an internal space and collects purified water. The inside includes a sensor 111 for measuring the level of purified water and a hydrogen gas storage unit 112 for storing hydrogen gas.

And, on the lower side of the water tank 110, a purified water passage pipe 113 for providing the collected purified water to the electrolysis cell 120 to be described later, and oxygen gas and a small amount of purified water generated in the electrolysis cell 120 are introduced again. It includes an oxygen gas inlet pipe 114 to be.

The upper side of the water tank 110 includes an oxygen gas discharge pipe 115 for discharging oxygen inside the water tank 110. In addition, the hydrogen gas discharge pipe 116 located at a distance from the oxygen gas discharge pipe 115 on the upper side of the water tank 110 and connected to and passing through the upper side of the hydrogen gas storage unit 112, and the electrolysis cell 120 A hydrogen gas inlet pipe 117 for introducing the generated hydrogen gas is further included.

Next, the electrolysis cell 120 electrolyzes the purified water introduced from the water tank 110 through the purified water passage pipe 113 to generate oxygen gas and hydrogen gas. That is, the electrolysis cell 120 includes a negative electrode plate and a positive electrode plate therein, and when power is supplied, hydrogen gas is generated at the negative electrode and oxygen gas is generated at the positive electrode using an internal catalyst. The generated oxygen gas is delivered to the water tank 110 through the oxygen gas inlet pipe 114, and the hydrogen gas is delivered to the hydrogen gas storage unit 112 through the hydrogen gas inlet pipe 117.

Next, the cooling device 130 is installed on one side of the hydrogen gas discharge pipe 116 connected to the water tank 110, and the cooling device 130 lowers the temperature inside the hydrogen gas discharge pipe 116 to discharge it together with hydrogen gas. cools the water vapor.

The hydrogen gas discharged through the hydrogen gas discharge pipe 116 includes some water vapor. And, the water vapor causes condensation on the inner surface of the hydrogen gas discharge pipe 116 . Therefore, when the user inhales the hydrogen gas discharged through the hydrogen gas discharge pipe 116, it is frequently inhaled together with water. Therefore, in the embodiment of the present invention, the cooling device 130 is installed on one side of the hydrogen gas discharge pipe 116, and water vapor is liquefied using the installed cooling device 130.

On the other hand, so that the liquefied water vapor can be recovered back to the hydrogen gas storage unit 112, the inner part of the hydrogen gas discharge pipe 116 is formed to have a certain slope, and the cooling device 130 is installed at the location where the slope occurs .

In the embodiment of the present invention, the inner part of the hydrogen gas discharge pipe 116 is formed at various inclination angles, and the amount of cooled water vapor recovered to the hydrogen gas storage unit 112 is tested for each inclination angle.

Tilt angle (°) 0° 15° 30° 45° 60° 75° 90° Water vapor recovery amount (%) 0% 30% 50% 70% 72% 75% 75%

As shown in Table 1 above, the cooled water vapor was recovered into the hydrogen gas storage unit 112 when the inclination angle was 35 ° or more, and the higher the inclination angle, the greater the amount of recovered cooled water vapor. It can be seen that . However, it can be seen that when the inclination angle is 55° or more, the amount of recovery is not greatly increased.

Therefore, in the embodiment of the present invention, the inclination angle formed on the inner part of the hydrogen gas discharge pipe 116 is set to 35° or more and 55° or less with respect to the horizontal.

Finally, the control unit 140 controls the operation of the electrolysis cell 120 and the cooling device 130 using power received from the outside, and communicates with the user terminal 200 using wireless communication.

4, the control unit 140 includes a power supply module 141, a drive module 142, a time information acquisition module 143, a communication module 144, and a voice output module 145. ).

First, the power supply module 141 converts AC power received from the outside into DC power and supplies it.

Next, the drive module 142 drives the electrolysis cell 120 and the cooling device 130 according to the control signal received from the control panel or the user terminal 200 while the power is supplied.

The time information acquisition module 143 acquires use start and end times, respectively, according to the driving states of the electrolysis cell 120 and the cooling device 130 . In other words, when hydrogen is inhaled for a predetermined period of time or continuously, the effect of removing active oxygen in the body can be increased.

Therefore, the time information acquisition module 143 according to an embodiment of the present invention acquires time information including start and end times of use according to the driving of the electrolysis cell 120 and the cooling device 130, and Time information is transmitted to the user terminal 200 through the communication module 144 .

The communication module 144 communicates with the user terminal 200 at a short distance to transmit a driving state at the current time to the user terminal 200, and drives the transmitted signal when a driving stop or play signal is transmitted from the user terminal 200. to module 142.

Finally, the voice output module 145 transmits information on the water level of the purified water received from the sensor 111 installed in the water tank 110 and a guide message according to the start or end of operation of the electrolysis cell 120 and the cooling device 130. output in audio

5 is a configuration diagram for explaining the user terminal of FIG. 1 .

As shown in FIG. 5 , the user terminal 200 according to an embodiment of the present invention includes an input unit 210 , a database 220 , an extraction unit 230 and a communication unit 240 .

First, when the pre-installed application is executed by the user, the input unit 210 provides a login screen to receive a member ID and password from the user, and if the login is successful, the user's hydrogen breathing generator 100 information on the time of use is displayed. to provide. Here, the time information represents information obtained by counting the start and end times of use of the hydrogen respiration generator 100.

In addition, the input unit 210 receives input whether to stop or reproduce the drive for the hydrogen respiration generator 100 from the user.

If a new member whose member information is not stored in the database 220 attempts to log in, the input unit 210 receives member information according to the sign-up procedure from the user and provides a login screen when member sign-up is completed. A member ID and password may be input from the user.

In addition, the database 220 stores data on whether or not the hydrogen respiration generator 100 is used and information on usage time, and member information including member ID and password is stored.

And the cost extraction unit 230 calculates and outputs the cost corresponding to the usage time, and allows the user to pay the corresponding cost. At this time, the cost extraction unit 230 may output the corresponding cost as a QR code or barcode so that it can be easily paid by a smartphone (not shown) owned by the user, or by various payment methods such as credit card or account transfer. You can also make payment.

And the communication unit 140 transmits the cost information extracted from the cost extraction unit 130 and the use time for the hydrogen respiration generator 100 to the management server 200.

6 is a configuration diagram for explaining the management server of FIG. 1 .

As shown in FIG. 6 , the management server 300 according to an embodiment of the present invention includes a receiving unit 310 , a determining unit 320 and an information providing unit 330 .

First, the receiving unit 310 receives the user's identification information received from the user terminal 100 and the time information using the hydrogen respiration generator 100.

Then, the determination unit 320 accumulates the time information received through the reception unit 310 for each day, and determines whether the accumulated number of days of use continuously appears.

In addition, when the information providing unit 330 determines that the corresponding user has continuously used the hydrogen respiration generator 100 for a predetermined period of time, the user terminal possessing the event information or free gift provision information that the corresponding user has ( 200).

Hereinafter, a method for controlling the driving of a hydrogen respiration generator for treatment according to an embodiment of the present invention will be described in more detail with reference to FIG. 7 .

Figure 7 is a flow chart showing the operational flow of the treatment hydrogen respiration generator driving control method according to an embodiment of the present invention.

First, when a pre-installed application is executed by a user, a login screen is provided and a member ID and password are input from the user to determine whether the login is successful.

At this time, if login fails, the user terminal 200 determines that the user is a new member not stored as member information in the database 220, receives member information according to the sign-up procedure from the user, and completes member sign-up. If so, a login screen may be provided and the user may input the member ID and password.

Then, according to an embodiment of the present invention, as shown in Figure 7, the hydrogen breathing generator 100 receives a drive signal according to start or stop from the operation panel or the user terminal 200 (S710).

First, when power is supplied to the hydrogen respiration generator 110, the electrolysis cell 120 electrolyzes the purified water collected in the water tank 110 to generate oxygen gas and hydrogen gas. To elaborate, one side of the electrolysis cell 120 includes a pump (not shown). Therefore, the pump introduces the purified water inside the water tank 110 into the electrolysis cell 120 through the purified water passage pipe 113. When electrolysis is completed in the electrolysis cell 120, oxygen gas is delivered to the water tank 110 through the oxygen gas inlet pipe 114, and hydrogen gas passes through the hydrogen gas inlet pipe 117 to the hydrogen gas storage unit ( 112) is passed on.

Then, when the user transmits a use start signal using the operation panel or user terminal 200, the hydrogen respiration generator 110 discharges the oxygen gas stored in the water tank 110 through the oxygen gas discharge pipe 115, and hydrogen The hydrogen gas stored in the gas storage unit 112 is discharged through the hydrogen gas discharge pipe 116 .

At this time, the cooling device 130 installed on one side of the hydrogen gas discharge pipe 116 cools the water vapor contained in the hydrogen gas by cooling the inside of the hydrogen gas discharge pipe 116. On the other hand, the hydrogen gas discharge pipe 116 has a predetermined inclination angle on an inner part, and the cooling device 130 is installed at the inclination position. Therefore, water vapor liquefied by the cooling device 130 is recovered to the hydrogen gas storage unit 112 according to the gradient and introduced into the water tank 110 through a water vapor discharge pipe (not shown).

The user inhales oxygen gas and hydrogen gas through a mask-type respirator (not shown) connected to the ends of the oxygen gas discharge pipe 115 and the hydrogen gas discharge pipe 116.

Then, the hydrogen breathing generator 100 receives a stop signal from the operation panel or the user terminal 200.

When step S710 is completed, the hydrogen respiration generator 100 transmits time information about the use start time and end time to the user terminal 200.

Then, the user terminal 200 acquires time information actually used by the user using the received use start time and end time, and transmits the obtained time information to the management server 300 .

The management server 300 determines whether the received time information corresponds to a preset time (S730).

If the determined result time information corresponds to the preset time, the management server 300 determines that the user has normally used the hydrogen respiration generator and sets the number of uses to "1".

On the other hand, if the time information does not correspond to the preset time, the management server 300 determines that the user has not normally used the hydrogen respiration generator and sets the number of uses to "0".

For example, if the start time of use is 7:00 and the end time of use is 7:40, the user terminal 200 counts from the start of use to the end of use so that the time actually used by the user is "40". minutes” as time information.

Next, the management server 300 compares the received time information with a preset time.

At this time, if the preset time is set to "30 minutes", the management server 300 sets the number of uses to "1".

On the other hand, if the preset time is set to "1 hour", the management server 300 sets the number of uses to "0".

Then, the management server 300 accumulates the number of uses, and determines whether or not to use continuously (S740).

The purpose of the treatment hydrogen respiration generator drive control system according to an embodiment of the present invention is to induce continuous use by the user.

Therefore, the management server 300 accumulates the number of uses, and if the accumulated number of times is greater than or equal to the reference value, it is determined that the user has continuously used it.

And, if it is determined that the user continuously used, the management server 300 extracts the corresponding event information, and delivers the extracted event information to the user terminal 200 of the corresponding user (S750).

Then, the user participates in the event using the event information output through the user terminal 200 or inputs the contact information and address according to the gift application.

As such, the treatment hydrogen respiration generator driving control system according to the present invention recovers the water introduced into the hydrogen discharge pipe into the hydrogen gas storage by installing a cooling device on one side of the hydrogen gas storage formed inside the water tank in which the purified water is collected. It is possible to prevent water vapor other than hydrogen gas from entering the hydrogen discharge pipe, and the discharge pipe is formed by separating the hydrogen gas discharge pipe and the oxygen gas discharge pipe, allowing the user to select hydrogen and oxygen gas at the same time as hydrogen gas allow you to breathe

In addition, the hydrogen respiration generator drive control system for treatment according to the present invention performs a record of the use of the hydrogen respiration generator in conjunction with the user terminal, and when it is not used continuously, a notification message is output through the user terminal to the user. It can be induced to continuously use a hydrogen respiration generator.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. will be. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the claims below.

100: hydrogen breathing generator
110: water tank 111: sensor
112: hydrogen gas storage unit 113: purified water passage pipe
114: oxygen gas inlet pipe 115: oxygen gas discharge pipe
116: hydrogen gas discharge pipe 117: hydrogen gas inlet pipe
120: electrolysis cell 130: cooling device
140: control unit 141: power supply module
142: drive module 143: time information acquisition module
144: communication module 145: voice output module
200: user terminal
210: input unit 220: database
230: extraction unit 240: communication unit
300 management server
310: receiving unit 320: determining unit
330: information provision unit

Claims (8)

Hydrogen gas and oxygen gas are generated by electrolyzing the collected purified water, and when the generated hydrogen gas is discharged, the water vapor included with the hydrogen gas is cooled, and the cooled water vapor is returned to the water tank in which the purified water is collected. breathing machine,
A user terminal that obtains time information including use start time and end time in conjunction with the hydrogen respiration generator and transmits the obtained time information, and
Hydrogen breathing generator for treatment including a management server that collects the identification information of the user, determines whether the user continuously uses it by accumulating time information received from the user terminal, and provides event information according to the determination result. drive control system. According to claim 1,
The hydrogen breathing generator,
A water tank for collecting purified water, measuring the water level for the purified water inside, and recovering generated hydrogen gas;
An electrolysis cell connected to the water tank and decomposing the inflow purified water into hydrogen gas and oxygen gas;
A cooling device located on one side of the hydrogen gas discharge pipe connected to the water tank and cooling the inside of the discharge pipe; and
It controls the operation of the electrolysis cell and the cooling device by receiving power supplied from the outside, and measures the start and end times of oxygen and hydrogen discharge from the oxygen gas discharge pipe and the hydrogen gas discharge pipe connected to the upper side of the water tank. Hydrogen respiration generator drive control system for treatment comprising a control unit for transmitting to the user terminal. According to claim 2,
The water tank,
A sensor for collecting purified water and measuring the water level for the purified water inside;
A hydrogen gas storage unit for recovering generated hydrogen gas;
A purified water passage pipe providing the purified water to the electrolysis cell;
An oxygen gas inlet pipe for introducing hydrogen gas generated by the electrolysis cell and a part of the purified water provided to the electrolysis cell;
An oxygen gas discharge pipe that is connected to the outside and discharges oxygen gas,
A hydrogen gas discharge pipe for discharging hydrogen gas, and
A hydrogen gas inlet pipe for introducing hydrogen gas generated by the electrolysis cell into the hydrogen gas storage unit;
The hydrogen gas discharge pipe,
The treatment hydrogen respiration generator drive control system that penetrates the cooling device and is injected in a gradient form by a predetermined inclination angle so that the water vapor liquefied by the cooling device can be recovered to the water tank. According to claim 3,
The tilt angle is,
A hydrogen respiration generator drive control system for treatment that is 35° or more and 55° or less relative to the horizontal. According to claim 3,
On the upper side of the hydrogen gas storage unit,
A hydrogen gas inlet pipe for introducing hydrogen gas generated from the electrolysis cell and a hydrogen gas outlet pipe for discharging the collected hydrogen gas to the outside or recovering liquefied water vapor are formed,
At the bottom of the hydrogen gas storage unit,
A hydrogen respiration generator drive control system for treatment in which a steam discharge pipe for discharging the liquefied water vapor into the tank is formed. According to claim 2,
The control unit,
A power supply module that converts AC power into DC power and supplies it;
A driving module for generating a driving signal for driving the electrolysis cell and the cooling device according to the input of the operation panel;
A time information acquisition module for obtaining time information according to start and end times of the electrolysis cell and the cooling device respectively driven according to the generated driving signal;
Communication that performs wireless communication with the user terminal to transmit the current driving state and acquired time information to the user terminal, and transmits the received signal to the driving module when a driving stop or play signal is received from the user terminal module, and
A hydrogen respiration generator drive control system for treatment comprising a voice output module for outputting a guide message according to the level information of the purified water received from the sensor installed in the water tank and the start or end of driving for the electrolysis cell and cooling device. According to claim 1,
The user terminal,
It is either a personal terminal carried by the user or a stationary terminal installed in the field, and is connected to the hydrogen respiration generator by short-range communication to provide time information according to the current driving state and start time and end time of the hydrogen respiration generator. A hydrogen respiration generator drive control system for treatment that outputs and stops or regenerates the drive of the hydrogen respiration generator. According to claim 1,
The management server,
A receiving unit for receiving time information according to a start time and an end time from the user terminal;
a determination unit for accumulating the number of uses for each user using the received time information and determining whether the accumulated number of uses continuously appears; and
If it is determined that the user has been continuously used for a predetermined period of time, the treatment hydrogen respiration generator drive control system comprising an event information providing unit for providing event information that can participate.

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