JP5761951B2 - Rechargeable ultrafine bubble generator - Google Patents

Description

  The present invention relates to a technology for a rechargeable ultrafine bubble generating device, and in particular, a rechargeable ultrafine bubble generation comprising a stationary part and a moving part configured to be placed on the stationary part and generating hydrogen bubbles in water. It relates to the technology of the device.

  DESCRIPTION OF RELATED ART Conventionally, the bubble generator which arrange | positions in water tanks, such as a bathtub, and generates a bubble by ejecting gas in water is known. As an example, there is an apparatus that pressurizes and dissolves high-concentration oxygen air from an oxygen enricher into a circulation circuit of a bathtub hot water circulation device in which bathtub hot water circulates by a pump, and jets it into the bathtub as a large amount of bubbles. It is publicly known (see Patent Document 1).

  Conventionally, devices using hydrogen as a gas ejected in water are known. As described above, baths in which hydrogen is supplied into bath water, so-called hydrogen baths, have recently attracted attention as baths that exhibit beauty effects in addition to anti-aging effects. As an example, a hydrogen bubble bath apparatus that includes hydrogen supply means for supplying hydrogen into bath water in a bathtub, supplies hydrogen into the bathtub by the hydrogen supply means, and adjusts the hydrogen concentration in the bathroom to 4% or less is known. (See Patent Document 2).

JP 2005-245747 A JP 2008-036331 A

However, the conventional bubble generating device cannot produce fine bubbles unless it is jetted at a high pressure, which inevitably requires a large pump, which causes an increase in the size of the device. In addition, a battery serving as a power source for driving the pump and the compressor inevitably requires a large battery, which causes an increase in the size of the apparatus. Furthermore, when it is attached to a bubble generating device used mainly in water, it is necessary to apply strict waterproofing to prevent leakage, which causes an increase in size and a cost. Further, since the device itself becomes large, it becomes difficult to move the device, and it cannot be used in a plurality of places.
Also, when hydrogen is used, if the bubble size is large as in the prior art, it cannot stay in the water and is released into the air, so it is necessary to constantly feed in hydrogen, and a large amount of hydrogen is required. It was.

  In view of the above problems, the present invention provides a rechargeable ultrafine bubble generator capable of reducing the size of the device and generating ultrafine bubbles with a small amount of power.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

That is, in Claim 1, it comprises a stationary part and a moving part that can be placed on the stationary part and generates hydrogen bubbles in water, and the stationary part includes a hydrogen generator that generates hydrogen. A hydrogen tank for a stationary part connected to the hydrogen generator, an external power supply for supplying power to the hydrogen generator, a power cable including an output part, and a pressure in the hydrogen tank for the stationary part are detected. A first pressure detection unit; and a hydrogen control unit and a stationary unit controller connected to the first pressure detection unit, wherein the moving unit mounts the moving unit on the stationary unit. The movable part hydrogen tank connectable to the stationary part hydrogen tank, the ultrafine bubble generator connected to the movable part hydrogen tank, and the movable part placed on the stationary part Power to the ultrafine bubble generator Connecting a charging power supply which can be connected to the output of the power cable, and a second pressure detecting means for detecting the pressure of the mobile unit for the hydrogen tank, the ultrafine bubble generating device and the second pressure detecting means for A moving part control device, wherein the ultrafine bubble generating device is configured to generate a bubble generating medium connected to the moving part hydrogen tank, and a water flow flowing on a surface of the bubble generating medium driven by the charging power source. The bubble generating medium is composed of carbon and is composed of a high-density composite provided with a large number of pores.

  According to a second aspect of the present invention, the holes of the bubble generating medium are holes having a diameter of several μm to several tens of μm.

  According to a third aspect of the present invention, the charging power source is a low voltage power source of 12V or less.

  As effects of the present invention, the following effects can be obtained.

  In claim 1, a large number of ultrafine bubbles can be generated from a large number of pores of the high-density composite, and at the instant when the ultrafine bubbles are generated, they are separated from the bubble generating medium by a liquid flow. Since it can prevent becoming a big bubble, an ultrafine bubble can be generated by a simple method. Moreover, since hydrogen can be pumped by the pressure in the moving part hydrogen tank, it is not necessary to use a compressor. Therefore, only a small amount of power used for the water flow generator is required for generating ultrafine bubbles. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power.

  According to the second aspect, ultrafine bubbles having a diameter of several hundred nm to several tens of μm can be generated. Ultrafine bubbles having a diameter of several hundreds of nanometers to several tens of micrometers have small buoyancy and exist in convection in water. Therefore, it is not necessary to always feed in hydrogen, and the moving part hydrogen tank can be made small. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power.

  According to the third aspect of the present invention, since the power source is a low voltage, it is only necessary to apply a simple waterproof process, the apparatus can be miniaturized, and the cost can be saved. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power.

1 is a perspective view showing an overall configuration of a rechargeable ultrafine bubble generating device according to an embodiment of the present invention. The perspective view which shows a moving part and a stationary part. The block diagram which shows the structure of a charging type ultrafine bubble generator. The block diagram which shows the control apparatus for stationary parts, and the control apparatus for transfer parts. The cross-section partial enlarged view of a bubble generation medium. The cross-section partial enlarged view of a bubble generation medium. The perspective view which shows the use condition of a moving part. The flowchart figure which shows the control method of the control apparatus for stationary parts. The flowchart figure which shows the control method of the control apparatus for moving parts.

  Next, embodiments of the invention will be described. In addition, the front and rear direction, the left and right direction, and the up and down direction are defined as shown by arrows in FIG.

  As shown in FIGS. 1 and 2, the rechargeable ultrafine bubble generator 1 includes a stationary part 2 and a moving part 3 configured to be placed on the stationary part 2 and generating hydrogen bubbles in water. .

First, the stationary part 2 will be described with reference to FIGS. 1 to 4.
As shown in FIG. 3, the stationary unit 2 includes a hydrogen generating device 11 that generates hydrogen, a stationary unit compressor 12 that pumps the generated hydrogen, and a stationary unit hydrogen tank 13 that is connected to the hydrogen generating device 11. And a power cable 14 including a charging plug 15 as an output unit, and a first pressure for detecting the pressure in the stationary unit hydrogen tank 13. It has the 1st pressure sensor 16 as a pressure detection means, the display means 17 for stationary parts, and the control apparatus 18 for stationary parts (refer FIG. 4).

  As shown in FIGS. 1 and 2, the stationary part 2 is configured to have a substantially “L” shape when viewed from the front, and includes a pedestal part 2 a formed substantially parallel to the ground and one end of the pedestal part 2 a (this embodiment). The left end) and an upright portion 2b protruding upward from the upper surface. The pedestal portion 2a and the upright portion 2b are configured to be hollow. Inside the pedestal portion 2a and the upright portion 2b, a hydrogen generator 11, a compressor 12, a stationary hydrogen tank 13, a power cable 14, a charging plug 15, One pressure sensor 16 and a control device 18 for a stationary part are arranged.

As shown in FIG. 3, the hydrogen generator 11 is provided on the pedestal portion 2 a of the stationary unit 2. The hydrogen generator 11 is, for example, an apparatus that collects hydrogen collected at the cathode by electrolyzing water. In addition, the structure of the hydrogen generator 11 is not limited, For example, the apparatus which electrolyzes hydrocarbons, such as methane, may be sufficient, and the apparatus which electrolyzes the water | moisture content in air may be sufficient.
The storage part that collects and stores hydrogen in the hydrogen generator 11 is connected to the compressor 12 and the hydrogen tank 13 for the stationary part.

  The compressor 12 is disposed on the side of the hydrogen generator 11 and is provided on the pedestal portion 2 a of the stationary unit 2. The compressor 12 is driven by electric power from an external power source 100 described later, and pumps the hydrogen collected in the storage part of the hydrogen generator 11 to the stationary part hydrogen tank 13.

  The stationary part hydrogen tank 13 is provided above the hydrogen generator 11 and in the upright portion 2 b of the stationary part 2. The stationary part hydrogen tank 13 is formed in a cylindrical shape and is made of a metal such as aluminum. In the present embodiment, the stationary part hydrogen tank 13 has a capacity of about 3 liters. The lower end of the stationary part hydrogen tank 13 is connected to the storage part of the hydrogen generator 11, and the hydrogen pumped from the hydrogen generator 11 is stored in the stationary part hydrogen tank 13. A discharge passage 19 is connected to the upper portion of the stationary part hydrogen tank 13, and one end of the discharge passage 19 is exposed on the upper surface of the upright portion 2 b of the stationary part 2. One end of the discharge passage 19 is provided at a position where it is connected to one end of a second communication pipe 42 of the moving part hydrogen tank 31 described later when the moving part 3 is placed on the stationary part 2. An on-off valve 20 is provided in the middle of the discharge passage 19. The on-off valve 20 is configured to be opened only when one end of the discharge passage 19 and one end of the second communication pipe 42 are connected. The on-off valve 20 is configured to mechanically open when one end of the second communication pipe 42 is connected to one end of the discharge passage 19. The on-off valve 20 can be electrically controlled by the stationary control device 18.

  The power cable 14 is a copper wire having a plug, for example, and can be connected to the external power supply 100. The external power source 100 supplies power to the hydrogen generator 11, the compressor 12, and the charging plug 15 via the power cable 14.

  The charging plug 15 is provided above the upright portion 2 b of the stationary part 2, and the upper surface thereof is exposed on the surface of the stationary part 2. The charging plug 15 is provided at a position where the charging plug 15 is connected to a connection plug 48 of the charging power source 33 described later when the moving unit 3 is placed on the stationary unit 2.

The first pressure sensor 16 is provided inside the stationary part hydrogen tank 13 and detects the pressure of hydrogen stored in the stationary part hydrogen tank 13.
As shown in FIG. 1 and FIG. 2, the stationary unit display means 17 is configured by, for example, a liquid crystal screen, and displays information on the pressure of the stationary unit hydrogen tank 13 detected by the first pressure sensor 16, warning information, and the like. indicate.

  The stationary part control device 18 is constituted by a CPU, and is connected to the hydrogen generator 11, the compressor 12, the first pressure sensor 16, and the stationary part display means 17, as shown in FIG.

Next, the moving unit 3 will be described with reference to FIGS.
As shown in FIG. 3, the moving unit 3 includes a moving unit hydrogen tank 31 that can be connected to the stationary unit hydrogen tank 13 and the moving unit hydrogen tank when the moving unit 3 is placed on the stationary unit 2. 31 and a charging power source that can be connected to the charging plug 15 of the power cable 14 that supplies power to the ultrafine bubble generating device when the moving unit 3 is placed on the stationary unit 2. 33, a second pressure sensor 34 as second pressure detecting means for detecting the pressure in the stationary part hydrogen tank 31, a moving part display means 35, a moving part input means 36, and a moving part control And a device 37 (see FIG. 4).

  As shown in FIGS. 1 and 2, the moving unit 3 is configured in a state in which a substantially “L” shape when viewed from the front is rotated by 180 degrees, and includes a ceiling part 3 a formed substantially parallel to the ground, and a ceiling part One end (right end in the present embodiment) of 3a is composed of a hanging portion 3b protruding downward from the lower surface. The ceiling portion 3a and the hanging portion 3b are configured to be hollow, and inside the ceiling portion 3a and the hanging portion 3b, a moving part hydrogen tank 31, an ultrafine bubble generating device 32, a charging power source 33, a second pressure sensor 34, In addition, a moving unit controller 37 is disposed. Further, a hook portion 3c projects from the lower surface of the other end (left end in the present embodiment) of the ceiling portion 3a.

  As shown in FIG. 3, the moving part hydrogen tank 31 is provided on the upper part of the hanging part 3 b of the moving part 3. The moving part hydrogen tank 31 is formed in a cylindrical shape and is made of a metal such as aluminum. In the present embodiment, the moving part hydrogen tank 31 has a capacity of approximately 3 liters. The lower end of the moving part hydrogen tank 31 is connected to the ultrafine bubble generating device 32 via the first series pipe 40, and a control valve 41 is provided in the middle part of the first series pipe 40. Yes. In addition, a second communication pipe 42 is provided in the upper part of the moving part hydrogen tank 31. One end of the second communication pipe 42 is exposed on the side surface (the left side surface in the present embodiment) of the hanging portion 3b of the moving unit 3, and when the moving unit 3 is placed on the stationary unit 2, It is provided at a position connected to one end.

The ultrafine bubble generating device 32 includes a bubble generating medium 45 connected to the moving part hydrogen tank 31, and a water flow generating device 46 that is driven by the charging power source 33 and generates a water flow that flows on the surface of the bubble generating medium 45.
The ultrafine bubble generating device 32 is provided below the moving part hydrogen tank 31 and below the hanging part 3b. In addition, a plurality of discharge holes 3d through which bubbles and water flow pass are provided on the lower side surface (right side surface in the present embodiment) of the hanging portion 3b.
The bubble generating medium 45 is a columnar member, and is arranged so that its longitudinal direction is substantially parallel to the ground. In this embodiment, it is formed in a columnar shape. As shown in FIGS. 5 and 6, the bubble generating medium 45 has a space 45 a therein, and the end of the first series pipe 40 is connected to the space 45 a. The space 45 a is provided up to the middle in the longitudinal direction of the bubble generating medium 45.

  The bubble generating medium 45 is made of carbon and is made of a high-density composite provided with a large number of holes 45b having a diameter of several μm to several tens of μm. The high density composite constituting the bubble generating medium 45 is a conductor.

  As shown in FIG. 3, the water flow generator 46 flows the water flow along a surface portion 45 c of the bubble generation medium 45 in a direction substantially orthogonal to the discharge direction of the ultrafine bubbles discharged by the bubble generation medium 45. Is a device that generates In the present embodiment, the water flow generator 46 is composed of a rotor blade and a nozzle provided with a motor, and when the motor is driven, the rotor blade is rotated to generate a water flow, and water is ejected from the nozzle. Generate water flow. The water flow generator 46 is provided on the side (left side in the present embodiment) of the bubble generating medium 45, and generates a water flow toward the discharge hole 3d on the opposite side.

  In the water flow generated by the water flow generator 46, as shown in FIG. 6 (b), the ultra-fine bubbles are released at the moment when the ultra-fine bubbles are generated from the holes 45b as shown in FIG. 6 (a). The surface portion 45c is separated from the surface portion 45c by passing through the surface portion 45c at a high speed.

  Thereby, as shown in FIG.6 (c), the ultrafine bubble of the surface part 45c goes into a liquid independently, without uniting with the ultrafine bubble which generate | occur | produces later and the ultrafine bubble which generate | occur | produces from the surrounding hole 45b. Will move. With this configuration, it is possible to generate ultrafine bubbles by a simple method. Ultrafine bubbles with a diameter of several tens of μm exist with a small buoyancy and convection in water. Therefore, it is not necessary to always send in hydrogen, and the moving part hydrogen tank 31 can be made small.

  The charging power supply 33 is provided in the ceiling part 3a of the moving part 3, as shown in FIG. The charging power source 33 is a 12V low-voltage power source and supplies power to the water flow generator 46. The charging power source 33 has a connection plug 48, and the connection plug 48 is exposed on the lower surface of the ceiling portion 3 a of the moving unit 3. The connection plug 48 is provided at a position where it is connected to the charging plug 15 when the moving unit 3 is placed on the stationary unit 2.

The second pressure sensor 34 is provided inside the moving part hydrogen tank 31 and detects the pressure of hydrogen stored in the moving part hydrogen tank 31.
As shown in FIGS. 1 and 2, the moving unit display means 35 is configured by a liquid crystal screen, for example, information on pressure in the moving unit hydrogen tank 31 detected by the second pressure sensor 34, warning information, and the like. Is displayed.
As shown in FIGS. 1 and 2, the moving unit input means 36 is constituted by a switch, for example, and an operator operates the moving unit input means 36 to switch between a driving state and a stopped state. Is called.

  The moving part control device 37 is constituted by a CPU. As shown in FIG. 4, the second pressure sensor 34, the moving part display means 35, the moving part input means 36, the control valve 41, and the water flow generator 46 are provided. It is connected to the.

Next, a method for generating hydrogen in the bathtub 101 will be described.
First, the moving unit 3 is placed on the stationary unit 2. While the moving unit 3 is placed on the stationary unit 2, the connection plug 48 of the moving unit 3 is connected to the charging plug 15 of the stationary unit 2, and the charging power source 33 is charged. The hydrogen generated in the hydrogen generator 11 is pumped from the storage part of the hydrogen generator 11 to the stationary hydrogen tank 13 by the compressor 12 and stored in the stationary hydrogen tank 13. The upper limit of the pressure of the stationary part hydrogen tank 13 is 10 kgf / cm 2.
While the moving unit 3 is placed on the stationary unit 2, the second communication pipe 42 of the moving unit 3 is connected to the discharge passage 19 of the stationary unit, whereby the on-off valve 20 is opened and the stationary unit hydrogen is installed. Hydrogen flows from the stationary part hydrogen tank 13 into the moving part hydrogen tank 31 due to the differential pressure between the tank 13 and the moving part hydrogen tank 31. The inflow of hydrogen continues until the pressure difference between the stationary part hydrogen tank 13 and the moving part hydrogen tank 31 disappears. For example, when the pressure in the stationary part hydrogen tank 13 is 10 kgf / cm 2 and the pressure in the moving part hydrogen tank 31 is 0 kgf / cm 2, the inflow of hydrogen flows into the stationary part hydrogen tank 13 and The process continues until the pressure in the moving part hydrogen tank 31 reaches 5 kgf / cm 2.

In a state where the charging power source 33 is charged and hydrogen is stored in the moving part hydrogen tank 31, the moving part 3 is installed on the wall surface of the bathtub 101 as shown in FIG. At this time, the moving portion 3 is fixed to the wall surface of the bathtub 101 by the hook portion 3 c contacting the opposite side of the wall surface of the bathtub 101. The hanging part 3b of the moving part 3 is located in the lower part, particularly the part provided with the discharge hole 3d in the bath water.
When the moving part input means 36 is operated to select an operating state, the moving part control device 37 opens the control valve 41. When the control valve 41 is opened, the hydrogen in the moving part hydrogen tank 31 is transferred from the moving part hydrogen tank 31 to the space of the bubble generating medium 45 through the first continuous pipe 40 by the pressure in the moving part hydrogen tank 31. It is pumped into 45a. Here, the opening amount of the control valve 41 is adjusted so that the amount of hydrogen pumped is 50 to 100 cc / min.

Hydrogen in the space 45a of the bubble generating medium 45 moves to the surface portion 45c of the bubble generating medium 45 through a large number of holes 45b and becomes ultrafine bubbles. Bubbles generated on the surface portion 45 c of the bubble generation medium 45 are separated by the water flow generated by the water flow generation device 46. By comprising in this way, it can prevent uniting and becoming a big bubble, and can produce a superfine bubble by a simple method. The separated bubbles are discharged together with the water flow from the discharge hole 3d into the bath water of the bathtub 101.
After the use of the moving part 3 in the bathtub 101 is finished, the moving part 3 is placed on the stationary part 2.

Next, the control by the stationary part control device 18 will be described with reference to FIG.
First, the stationary part controller 18 drives the hydrogen generator 11 and drives the compressor 12 (step S10). Next, the stationary part control device 18 determines whether or not the pressure p1 in the stationary part hydrogen tank 13 detected by the first pressure sensor 16 is equal to or higher than a predetermined value P1 (step S20). Here, in the present embodiment, P1 is 10 kgf / cm2. If the pressure p1 is equal to or higher than the predetermined value P1, a warning screen is displayed on the stationary part display means 17 (step S30), the hydrogen generator 11 is stopped, and the compressor 12 is stopped (step S40). When the pressure p1 is smaller than the predetermined value P1, the hydrogen generator 11 is continuously driven, and the process returns to step S20 again with the compressor 12 being driven.

Next, control of the control valve 41 by the moving part control device 37 will be described with reference to FIG.
The moving unit control device 37 opens the control valve 41 (step S110). Next, the moving part control device 37 determines whether or not the pressure p2 in the moving part hydrogen tank 31 detected by the second pressure sensor 34 is equal to or lower than a predetermined value P2 (step S120). If the pressure p2 is less than or equal to the predetermined value P2, the control valve 41 is closed (step S130). If the pressure p2 is greater than the predetermined value P2, the process returns to step S120 again with the control valve 41 still open.

The shape of the bubble generating medium 45 is not limited to this embodiment, and can be formed in a plate shape or a weight shape, for example.
In the present invention, the rechargeable ultrafine bubble generator 1 using hydrogen is described. However, it is possible to use air by replacing the hydrogen generator 11 with an air pump. It is also possible to use ozone by replacing the generator 11 with an ozone generator.

As described above, the rechargeable ultrafine bubble generating device 1 includes the stationary unit 2 and the moving unit 3 configured to be placed on the stationary unit 2 and generating hydrogen bubbles in water. A hydrogen generator 11 for generating hydrogen, a stationary part hydrogen tank 13 connected to the hydrogen generator, an external power supply 100 for supplying power to the hydrogen generator 11, and a power cable 14 including a charging plug 15; The first pressure sensor 16 for detecting the pressure in the stationary part hydrogen tank 13, and the stationary part control device 18 connected to the hydrogen generator 11 and the first pressure sensor 16, and the moving part 3 is When the moving part 3 is placed on the stationary part 2, a moving part hydrogen tank 31 that can be connected to the stationary part hydrogen tank 13, an ultrafine bubble generator 32 connected to the moving part hydrogen tank 31, and The moving part 2 is placed on the stationary part 3 Can, a charge plug 15 charging power supply 33 connectable with a power cable 14 for supplying power to ultrafine bubble generation device 32, a second pressure sensor 34 for detecting the pressure in the mobile unit for the hydrogen tank 31, ultrafine A moving part control device 37 connected to the bubble generating device 32 and the second pressure sensor 34, and the ultrafine bubble generating device 32 includes a bubble generating medium 45 connected to the moving part hydrogen tank 31, and a charging power source. And a water flow generating device 46 that creates a water flow that flows on the surface of the bubble generating medium 45, which is driven by 33, and the bubble generating medium 45 is made of carbon and is made of a high-density composite provided with a number of holes 45 b. It is what has been.
With this configuration, a large number of ultrafine bubbles can be generated from the large number of holes 45b of the high-density composite, and at the instant when the ultrafine bubbles are generated, they are separated from the bubble generating medium 45 by a liquid flow. Since it is possible to prevent coalescence and large bubbles, it is possible to generate ultrafine bubbles by a simple method. Moreover, since hydrogen can be pumped by the pressure in the hydrogen tank 31 for moving parts, it is not necessary to use a compressor. Therefore, only a small amount of power used for the water flow generator 46 is required for generating the ultrafine bubbles. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power.

Moreover, the hole 45b of the bubble generating medium 45 is a hole having a diameter of several μm to several tens of μm.
With this configuration, it is possible to generate ultrafine bubbles having a diameter of several tens of μm. Ultrafine bubbles having a diameter of several tens of μm have a small buoyancy and exist in convection in the bath water. Therefore, it is not necessary to always send in hydrogen, and the moving part hydrogen tank 31 can be made small. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power. In addition, since the device is downsized, it can be easily moved, and one rechargeable ultrafine bubble generator can be used for a plurality of bathtubs.

The charging power source 33 is a low voltage power source of 12V or less.
With this configuration, since the power source is a low voltage, it is only necessary to apply a simple waterproof process, the apparatus can be miniaturized, and the cost can be saved. Therefore, the apparatus can be miniaturized and ultrafine bubbles can be generated with less power.

DESCRIPTION OF SYMBOLS 1 Rechargeable ultrafine bubble generator 2 Mounting part 3 Moving part 11 Hydrogen generator 12 Compressor 13 Hydrogen tank for stationary part 14 Power cable 15 Charging plug 16 First pressure sensor 17 Display means for stationary part 18 Control apparatus for stationary part DESCRIPTION OF SYMBOLS 20 On-off valve 31 Hydrogen tank for moving parts 32 Ultrafine bubble generator 33 Charging power supply 34 Second pressure sensor 35 Moving part display means 36 Moving part input means 37 Moving part control device 41 Control valve 45 Bubble generating medium 45b Hole 46 Water flow generator

Claims (3)

A stationary part, and a movable part configured to be placed on the stationary part and generating hydrogen bubbles in water;
The stationary part is
A hydrogen generator for generating hydrogen;
A hydrogen tank for a stationary part connected to the hydrogen generator;
A power cable connected to an external power source for supplying power to the hydrogen generator, and including an output unit;
First pressure detecting means for detecting the pressure in the stationary part hydrogen tank;
A stationary unit controller connected to the hydrogen generator and the first pressure detector;
The moving unit is
When the moving part is placed on the stationary part, the moving part hydrogen tank connectable to the stationary part hydrogen tank;
An ultrafine bubble generator connected to the moving part hydrogen tank;
When the moving unit is placed on the stationary unit, a charging power source that can be connected to an output unit of the power cable that supplies power to the ultrafine bubble generating device;
Second pressure detecting means for detecting the pressure in the moving part hydrogen tank ;
A moving unit controller connected to the ultrafine bubble generating device and the second pressure detecting means,
The ultrafine bubble generator is
A bubble generating medium connected to the hydrogen tank for the moving part;
A water flow generating device that is driven by the charging power source and creates a water flow that flows on the surface of the bubble generating medium,
The bubble generating medium is composed of carbon and is composed of a high-density composite provided with a large number of holes. The rechargeable ultrafine bubble generating device according to claim 1, wherein the hole of the bubble generating medium is a hole having a diameter of several μm to several tens of μm. The rechargeable ultrafine bubble generating device according to claim 1, wherein the charging power source is a low voltage power source of 12 V or less.

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