JP2022002846A - Hydrogen gas dissolution device - Google Patents

Abstract

To provide a hydrogen gas dissolution device that can stably supply hydrogen water with high dissolved hydrogen concentration.SOLUTION: A hydrogen gas dissolution device 1 comprises an electrolytic cell 4 for generating hydrogen gas by electrolysis and a hydrogen dissolution module 6 that dissolves hydrogen gas supplied from the electrolytic cell 4 by contacting the gas with water. The electrolytic cell 4 is arranged below the hydrogen dissolution module 6.SELECTED DRAWING: Figure 1

Description

The present invention relates to a hydrogen gas dissolving device for dissolving hydrogen gas generated by electrolysis in water.

In recent years, a hydrogen gas dissolving device has been proposed in which hydrogen gas generated by electrolysis is dissolved in tap water to generate hydrogen water. For example, Patent Document 1 discloses an apparatus for supplying hydrogen gas and tap water via a gas-separated hollow fiber membrane to generate hydrogen water. In Patent Document 1, it is possible to supply hydrogen water having a predetermined concentration or higher by adjusting the pressure of hydrogen gas according to the water temperature and making the pressure of hydrogen gas and the pressure of tap water the same. Has been described.

An electrolyzer is known as a hydrogen gas generator that electrolyzes water to generate hydrogen gas. For example, in the apparatus of Patent Document 1, when water vapor generated by evaporation of water used for electrolysis in a hydrogen gas generator moves to a hydrogen gas dissolving means, it becomes water droplets due to dew condensation inside the hydrogen gas dissolving means. There is room for improvement from the viewpoint of stably supplying hydrogen water with a high dissolved hydrogen concentration, which may adhere to the structure and suppress the dissolution of hydrogen gas.

Japanese Unexamined Patent Publication No. 2016-77987

The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a hydrogen gas dissolving apparatus capable of stably supplying hydrogen water having a high dissolved hydrogen concentration.

The present invention includes an electrolytic tank for generating hydrogen gas by electrolysis and a hydrogen dissolution module for contacting and dissolving the hydrogen gas supplied from the electrolytic tank with water, and the electrolytic tank is provided. , A hydrogen gas melting device arranged below the hydrogen melting module.

The hydrogen gas dissolving apparatus further includes a hydrogen extraction pipe for taking out the hydrogen gas from the electrolytic tank and supplying the hydrogen gas to the hydrogen dissolution module, and the outlet of the hydrogen extraction pipe is connected to the lower part of the hydrogen dissolution module. It is desirable to have.

In the hydrogen gas dissolving apparatus, it is desirable that the inlet of the hydrogen take-out pipe is arranged in the upper part of the electrolytic cell.

In the hydrogen gas dissolving apparatus, it is desirable that the water level in the hydrogen extraction pipe is kept lower than that of the outlet.

The hydrogen gas dissolving apparatus further includes a water supply means for supplying the water to the hydrogen dissolution module, and the hydrogen dissolution module has a tubular body for passing the water supplied from the water supply means. It is desirable that the tubular body is composed of a porous film that allows the hydrogen gas to permeate.

In the hydrogen gas dissolving apparatus, it is desirable that the porous membrane is a hollow fiber membrane.

In the present invention, the electrolytic cell is arranged below the hydrogen dissolution module. In other words, the hydrogen dissolution module is arranged above the electrolytic cell. In such a positional relationship between the hydrogen dissolution module and the electrolytic cell, the hydrogen gas generated in the electrolytic cell has a smaller specific gravity than the water vapor, so that the hydrogen gas fills the vicinity of the hydrogen dissolution module and moves above the water vapor. Prevents the movement of. As a result, the adhesion of water droplets inside the hydrogen dissolution module is suppressed, and hydrogen water having a high dissolved hydrogen concentration can be stably supplied.

It is a figure which shows the schematic structure of one Embodiment of the hydrogen gas dissolution apparatus of this invention. It is a block diagram which shows the electric structure of the hydrogen gas melting apparatus. It is a figure which shows the structure of the electrolytic cell of the hydrogen gas dissolution apparatus and its periphery.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a schematic configuration of the hydrogen gas dissolving apparatus 1 of the present embodiment. In the figure, the hatched area is a area filled with water (hereinafter, the same applies to FIG. 3). The hydrogen gas melting device 1 includes an electrolytic cell 4 and a hydrogen melting module 6.

The electrolytic cell 4 generates hydrogen gas by electrolysis. The hydrogen dissolution module 6 brings the hydrogen gas supplied from the electrolytic cell 4 into contact with water to dissolve it. This makes it possible to generate dissolved hydrogen water used for hemodialysis and drinking water with a simple structure.

An electrolytic cell 40 is formed inside the electrolytic cell 4. In the electrolytic chamber 40, an anode feeding body 41, a cathode feeding body 42, and a diaphragm 43 are arranged. The electrolytic chamber 40 is divided by the diaphragm 43 into an anode chamber 40a on the anode feeding body 41 side and a cathode chamber 40b on the cathode feeding body 42 side.

For the diaphragm 43, for example, a solid polymer material made of a fluororesin having a sulfonic acid group or the like is appropriately used. In order to efficiently perform electrolysis in the electrolytic cell 4, it is desirable that the electrolytic cell 40 is divided into an anode chamber 40a and a cathode chamber 40b by a diaphragm 43, but the diaphragm 43 may be abolished.

Water for electrolysis is supplied to the anode chamber 40a and the cathode chamber 40b. When a DC voltage for electrolysis is applied to the anode feeding body 41 and the cathode feeding body 42, water is electrolyzed in the anode chamber 40a and the cathode chamber 40b, oxygen gas is generated in the anode chamber 40a, and the cathode chamber is generated. Hydrogen gas is generated at 40b.

In the present embodiment, the anode chamber 40a and the cathode chamber 40b are further provided with a water supply pipe 3 for supplying water for electrolysis. The water for electrolysis may be supplied from the oxygen take-out pipe 7 and the hydrogen take-out pipe 8 described later. The water supply pipe 3 is branched into a water supply pipe 31 and a water supply pipe 32 at the branch portion 3a. The water supply pipe 31 is connected to the anode chamber 40a, and the water supply pipe 32 is connected to the cathode chamber 40b. An on-off valve 91 (first on-off valve) is provided on the water supply pipe 3 on the upstream side of the branch portion 3a.

The hydrogen gas melting device 1 further includes a water supply means for supplying water to the hydrogen melting module 6. The water supply means includes a water supply pipe 5. In the present embodiment, the water supply pipe 3 is branched from the water supply pipe 5. Therefore, water is supplied to the water supply pipe 3 and the water supply pipe 5 from a water source of the same system. This simplifies the configuration of the hydrogen gas dissolving device 1. The water source of the water supply pipe 3 and the water source of the water supply pipe 5 may be separate systems.

The cathode chamber 40b and the hydrogen dissolution module 6 are connected by a hydrogen extraction pipe 8 described later. The hydrogen gas generated in the cathode chamber 40b is supplied to the hydrogen dissolution module 6 via the hydrogen extraction pipe 8.

The hydrogen dissolution module 6 has a pipe body 61 for passing water supplied from the water supply pipe 5. In this embodiment, a plurality of pipes 61 are provided inside the hydrogen dissolution module 6. The tubular body 61 extends in the horizontal direction.

The tubular body 61 is composed of a porous membrane that allows hydrogen gas to permeate. As a result, the hydrogen gas supplied from the cathode chamber 40b permeates the tube 61 and comes into contact with the water inside the tube 61 to dissolve.

In the present embodiment, a hollow fiber membrane is applied to the porous membrane constituting the tubular body 61. The hollow fiber membrane has innumerable micropores that allow hydrogen gas to pass through. In the present embodiment, the hydrogen gas generated in the cathode chamber 40b increases the external pressure of the tube 61, so that the hydrogen gas outside the tube 61 moves inward and dissolves in the water inside the tube. Dissolved hydrogen water can be easily obtained.

FIG. 2 shows the electrical configuration of the hydrogen gas melting device 1. The hydrogen gas dissolving device 1 includes a control means 10 that controls each part of the anode feeding body 41, the cathode feeding body 42, and the like.

The control means 10 has, for example, a CPU (Central Processing Unit) that executes various arithmetic processes, information processing, and the like, a program that controls the operation of the CPU, and a memory that stores various information. A current detecting means 44 is provided in the current supply line between the anode feeding body 41 and the control means 10. The current detecting means 44 may be provided in the current supply line between the cathode feeding body 42 and the control means 10. The current detecting means 44 detects the electrolytic current supplied to the anode feeding body 41 and the cathode feeding body 42, and outputs an electric signal corresponding to the value to the control means 10.

The control means 10 controls the DC voltage applied to the anode feeding body 41 and the cathode feeding body 42 based on the electric signal output from the current detecting means 44, for example. More specifically, the control means 10 has an anode feeding body 41 and a cathode feeding body so that the electrolytic current detected by the current detecting means 44 becomes a desired value according to the dissolved hydrogen concentration set by the user or the like. The DC voltage applied to the body 42 is feedback-controlled. For example, when the electrolytic current is excessive, the control means 10 decreases the voltage, and when the electrolytic current is too small, the control means 10 increases the voltage. Thereby, the electrolytic current supplied to the anode feeding body 41 and the cathode feeding body 42 is appropriately controlled.

As shown in FIG. 1, in the present hydrogen gas melting apparatus 1, the electrolytic cell 4 is arranged below the hydrogen melting module 6. In other words, the hydrogen dissolution module 6 is arranged above the electrolytic cell 4. In this embodiment, the hydrogen dissolution module 6 is arranged above the cathode chamber 40b. In such a positional relationship between the hydrogen dissolution module 6 and the electrolytic cell 4, the hydrogen gas generated in the electrolytic cell 4 has a smaller specific gravity than the water vapor, so that the vicinity of the hydrogen dissolution module 6 is filled with hydrogen gas. Prevents the upward movement of water vapor. As a result, the adhesion of water droplets in the internal structure of the hydrogen dissolution module 6 (that is, the micropores of the hollow fiber membrane) is suppressed, more hydrogen gas moves inside the tube 61, and the dissolved hydrogen concentration is easily high. It is possible to stably supply hydrogen water.

The hydrogen gas dissolving device 1 of the present embodiment includes an oxygen take-out pipe 7 for taking out oxygen gas from the anode chamber 40a of the electrolytic cell 4. The oxygen take-out pipe 7 has an inlet 7a on the anode chamber 40a side of the electrolytic cell 4 and an outlet 7b opened in the hydrogen gas dissolving device 1.

It is desirable that the inlet 7a is arranged above the anode chamber 40a of the electrolytic cell 4. As a result, the oxygen gas generated in the anode chamber 40a tends to flow out from the inlet 7a to the oxygen take-out pipe 7 due to the water pressure in the anode chamber 40a.

The outlet 7b is provided at the tip of the oxygen take-out pipe 7. The oxygen take-out pipe 7 may be appropriately extended so that the outlet 7b is opened to the outside of the hydrogen gas dissolving device 1.

The hydrogen gas melting device 1 includes a hydrogen extraction pipe 8 for extracting hydrogen gas from the electrolytic cell 4. The hydrogen extraction pipe 8 has an inlet 8a connected to the cathode chamber 40b of the electrolytic cell 4 and an outlet 8b connected to the hydrogen dissolution module 6. The hydrogen gas generated in the cathode chamber 40b is supplied to the hydrogen dissolution module 6 by the hydrogen extraction pipe 8.

It is desirable that the inlet 8a is arranged below the exit 8b. As a result, hydrogen gas having a specific gravity smaller than that of water vapor fills the vicinity of the outlet 8b and prevents the water vapor from moving upward (that is, in the vicinity of the outlet 8b). Therefore, the adhesion of water droplets inside the hydrogen dissolution module 6 is suppressed, and hydrogen water having a high dissolved hydrogen concentration can be easily supplied.

It is desirable that the inlet 8a is arranged above the cathode chamber 40b of the electrolytic cell 4. As a result, the hydrogen gas generated in the cathode chamber 40b can easily flow into the hydrogen extraction pipe 8 from the inlet 8a due to the water pressure in the cathode chamber 40b.

It is desirable that the outlet 8b is connected to the lower part of the hydrogen dissolution module 6 and is open. As a result, the hydrogen gas having a small specific gravity that has flowed into the hydrogen extraction pipe 8 from the cathode chamber 40b rises and easily flows into the hydrogen dissolution module 6. Further, even if water vapor enters the hydrogen dissolution module 6, since the lower portion of the hydrogen dissolution module 6 is opened by the outlet 8b, the water vapor drops as water droplets and easily escapes from the outlet 8b. Further, it is desirable that the outlet 8b is open in a direction crossing the pipe body 61. As a result, the hydrogen gas having a small specific gravity in the hydrogen dissolution module 6 easily comes into contact with the surface of the tubular body 61 when rising, so that the hydrogen gas easily flows into the hydrogen dissolution module 6.

An open pipe 81, which is branched from the hydrogen take-out pipe 8 at the branch portion 81a and whose end portion 81b is open, is connected to the hydrogen take-out pipe 8. The open pipe 81 may be appropriately extended so that the end portion 81b is opened to the outside of the hydrogen gas melting device 1.

An on-off valve 92 (second on-off valve) is located near the outlet 7b of the oxygen take-out pipe 7 connected to the anode chamber 40a, and the end 81b of the open pipe 81 branching from the hydrogen take-out pipe 8 connected to the cathode chamber 40b. An on-off valve 93 (second on-off valve) is provided in the vicinity of the above. The on-off valve 92 is provided to discharge the gas in the oxygen take-out pipe 7. The on-off valve 93 is provided to discharge the gas in the hydrogen extraction pipe 8.

As the electrolysis for generating hydrogen gas progresses, the water in the electrolytic chamber 40 is consumed. At this time, when the on-off valves 91, 92, and 93 are opened, water is supplied from the water supply pipe 3 to the electrolytic chamber 40 due to the difference in internal pressure between the water supply pipe 3, the oxygen take-out pipe 7, and the hydrogen take-out pipe 8.

FIG. 3 shows the configuration of the electrolytic cell 4 and its peripheral portion. In order for the electrolytic cell 4 to efficiently perform electrolysis, it is desirable that the anode chamber 40a and the cathode chamber 40b are always maintained in a full state. Therefore, in the present embodiment, water is replenished from the water supply pipe 3 to the anode chamber 40a and the cathode chamber 40b prior to the electrolysis. In the present embodiment, since the water supply pipe 31 and the water supply pipe 32 communicate with each other at the branch portion 3a, the water level in the oxygen take-out pipe 7 and the water level in the hydrogen take-out pipe 8 become equal to each other.

The on-off valves 91, 92 and 93 are configured by, for example, solenoid valves and are controlled so as to cooperate with each other by the control means 10. For example, in the control means 10, by opening the on-off valves 91 and 93, gas is discharged from the hydrogen take-out pipe 8 by the water pressure of the water supplied from the water supply pipe 31, and the water level of the hydrogen take-out pipe 8 rises. This makes it possible to raise the water level in the path from the cathode chamber 40b, which is lowered by electrolysis, to the hydrogen extraction pipe 8 in advance.

Further, after closing the on-off valves 91, 92, and 93, the control means 10 applies a DC voltage for electrolysis to the anode feeding body 41 and the cathode feeding body 42 to start electrolysis. That is, with the on-off valves 91, 92, and 93 closed, electrolysis proceeds in the electrolytic chamber 40, and hydrogen gas is generated in the cathode chamber 40b.

As a configuration for appropriately maintaining the water level in the oxygen take-out pipe 7 and the water level in the hydrogen take-out pipe 8, the hydrogen gas melting device 1 of the present embodiment has a water level sensor (water level detecting means) S1, S2, S3, S4. And S5 and the on-off valves 91, 92 and 93.

The water level sensors S1 and S2 are arranged side by side at appropriate intervals above and below the oxygen extraction pipe 7. The water level sensor S5 is provided between the water level sensor S1 and the water level sensor S2. The water level sensors S1, S2 and S5 detect water in the pipe by an optical method or buoyancy, and output a corresponding electric signal to the control means 10. The control means 10 knows the water level in the oxygen take-out pipe 7 based on the electric signals input from the water level sensors S1, S2 and S5.

Similarly, the water level sensors S3 and S4 are arranged side by side at appropriate intervals above and below the hydrogen extraction pipe 8. The water level sensors S3 and S4 detect water in the pipe by an optical method or buoyancy, and output a corresponding electric signal to the control means 10. The control means 10 knows the water level in the hydrogen extraction pipe 8 based on the electric signals input from the water level sensors S3 and S4.

The water level sensors S1 and S3 are arranged at the same height. The water level sensors S2 and S4 are arranged at the same height. The water level sensor S5 may be provided in the hydrogen extraction pipe 8. In this case, the water level sensor S5 is provided between the water level sensor S3 and the water level sensor S4.

The water level sensor S4 is arranged below the branch portion 81a. As a result, when water for electrolysis is supplied to the cathode chamber 40b, water is suppressed from entering the hydrogen extraction pipe 8 on the hydrogen dissolution module 6 side of the branch portion 81a.

By opening the on-off valves 91, 92, and 93, the water level in the oxygen take-out pipe 7 and the water level in the hydrogen take-out pipe 8 rise while maintaining the same height. When it is detected that the water level in the oxygen take-out pipe 7 has risen appropriately (to the height of the water level sensor S5) by the electric signal output from the water level sensor S5, the control means 10 controls the on-off valves 91, 92, 93. Close the cap. As a result, the supply of water to the electrolytic cell 4 is completed.

As the electrolysis progresses, the water level in the oxygen take-out pipe 7 and the water level in the hydrogen take-out pipe 8 change at different heights. Then, when a decrease or increase in the water level is detected by the electric signals output from the water level sensors S1 to S4, the control means 10 stops applying the electrolytic voltage to the anode feeding body 41 and the cathode feeding body 42. That is, when the electric signal output from the water level sensor S1 detects a decrease in the water level in the oxygen take-out pipe 7, or the electric signal output from the water level sensor S2 detects an increase in the water level in the oxygen take-out pipe 7, control is performed. The means 10 stops the electrolysis. Further, when the electric signal output from the water level sensor S3 detects a decrease in the water level in the hydrogen take-out pipe 8, or the electric signal output from the water level sensor S4 detects an increase in the water level in the hydrogen take-out pipe 8, control is performed. The means 10 stops the electrolysis.

Further, the control means 10 opens the on-off valves 92 and 93. As a result, the pressures in the anode chamber 40a and the cathode chamber 40b become equal to the atmospheric pressure, and the water level in the oxygen extraction pipe 7 and the water level in the hydrogen extraction pipe 8 become equal. Then, when a drop in the water level in the oxygen take-out pipe 7 is detected by the electric signal output from the water level sensor S5, the on-off valve 91 is opened to replenish the water. As a result, the water level in the hydrogen extraction pipe 8 is maintained between the water level sensors S3 and S4.

After closing the on-off valves 91, 92 and 93, the control means 10 applies a DC voltage for electrolysis to the anode feeding body 41 and the cathode feeding body 42 to start electrolysis. That is, with the on-off valves 91, 92, and 93 closed, electrolysis proceeds in the electrolytic chamber 40, and hydrogen gas is generated in the cathode chamber 40b. Along with this, the pressure in the hydrogen extraction pipe 8 rises, and the hydrogen dissolution module 6 is pressurized. As a result, the pressure in the hydrogen gas supply path from the hydrogen extraction pipe 8 to the hydrogen dissolution module 6 is increased without providing a complicated configuration such as a pump in the hydrogen extraction pipe 8. Therefore, the amount of hydrogen gas that comes into contact with water inside the hydrogen dissolution module 6 increases, and hydrogen water having a high dissolved hydrogen concentration can be supplied at low cost with a simple configuration.

It is desirable that the water level in the hydrogen extraction pipe 8 is kept lower than that of the outlet 8b by controlling the on-off valves 91, 92 and 93 by the control means 10. This prevents the water supplied from the water supply pipe 32 from flowing into the hydrogen dissolution module 6.

The hydrogen take-out pipe 8 may be provided with an on-off valve (not shown). This on-off valve is closed when the cathode chamber 40b is replenished with water for electrolysis. As a result, the water supplied from the water supply pipe 32 is further prevented from flowing into the hydrogen dissolution module 6.

By the way, when the on-off valves 91, 92 and 93 are opened, water may flow vigorously from the water supply pipe 3 into the electrolytic chamber 40 and flow out from the outlet 7b and the end 81b.

Therefore, in the present hydrogen gas melting device 1, it is desirable that a throttle valve 94 for limiting the amount of water flowing through the water supply pipe 3 is provided between the on-off valve 91 and the branch portion 3a in the water supply pipe 3. The throttle valve 94 suppresses the water supplied to the electrolytic chamber 40 from flowing out from the outlet 7b and the end 81b.

Further, in the present hydrogen gas dissolving device 1, it is desirable that a throttle valve 95 for limiting the amount of water flowing through the oxygen take-out pipe 7 is provided between the on-off valve 92 and the outlet 7b in the oxygen take-out pipe 7. Similarly, in the open pipe 81, it is desirable that a throttle valve 96 for limiting the amount of water flowing through the open pipe 81 is provided between the on-off valve 93 and the end portion 81b. The throttle valves 95 and 96 suppress the water supplied to the electrolytic chamber 40 from flowing out from the outlet 7b and the end 81b. If the throttle valve 94 alone can sufficiently suppress the outflow of water from the outlet 7b and the end portion 81b, the throttle valves 95 and 96 may be omitted.

When the dissolved hydrogen water generated by the hydrogen gas dissolving device 1 is used for hemodialysis, the reverse osmosis water treated by the reverse osmosis membrane treatment device (not shown) is supplied to the water supply pipe 5 as raw water. Then, the hydrogen gas is dissolved in the back-permeated water in the hydrogen dissolution module 6, so that the dialysate preparation water is generated and supplied to the dialysate supply device.

Although the hydrogen gas dissolving apparatus 1 of the present invention has been described in detail above, the present invention is not limited to the above-mentioned specific embodiment, but is modified to various embodiments. That is, the hydrogen gas dissolving device 1 is at least an electrolytic tank 4 for generating hydrogen gas by electrolysis and a hydrogen melting module 6 for contacting and dissolving the hydrogen gas supplied from the electrolytic tank 4 with water. The electrolytic tank 4 may be arranged below the hydrogen dissolution module 6.

1: Hydrogen gas dissolving device 3: Water supply pipe 4: Electrolytic cell 5: Water supply pipe (water supply means)
6: Hydrogen dissolution module 7: Oxygen take-out pipe 7a: Inlet 7b: Outlet 8: Hydrogen take-out pipe 8a: Inlet 8b: Outlet 40a: Anode chamber 40b: Cathode chamber 61: Tube

Claims (8)

An electrolytic cell for generating hydrogen gas by electrolysis,
The hydrogen gas supplied from the electrolytic cell, the hydrogen dissolving module for dissolving in contact with water,
A hydrogen extraction pipe for taking out the hydrogen gas from the electrolytic cell and supplying it to the hydrogen dissolution module is provided.
The electrolytic cell is arranged below the hydrogen dissolution module .
An open pipe with an open end is connected to the hydrogen take-out pipe.
The open pipe is branched from the hydrogen extraction pipe at a branching portion.
The electrolytic cell is further provided with a water supply pipe for supplying water for electrolysis.
The water supply pipe is provided with a first throttle valve that limits the amount of water flowing through the water supply pipe.
Hydrogen gas melting device. The hydrogen gas dissolving apparatus according to claim 1 , wherein the open pipe is provided with a second throttle valve that limits the amount of water flowing through the open pipe. An oxygen take-out pipe for taking out oxygen gas from the electrolytic cell is further provided.
The hydrogen gas dissolving apparatus according to claim 1 or 2, wherein the oxygen take-out pipe is provided with a third throttle valve that limits the amount of water flowing through the oxygen take-out pipe. The oxygen take-out pipe is provided with a first water level sensor and a second water level sensor below the branch portion.
The hydrogen gas dissolving apparatus according to claim 3, wherein the first water level sensor and the second water level sensor are provided side by side at intervals above and below. The hydrogen extraction pipe is provided with a third water level sensor and a fourth water level sensor.
The third water level sensor is arranged at the same height as the first water level sensor.
The hydrogen gas dissolving apparatus according to claim 4, wherein the fourth water level sensor is arranged at the same height as the second water level sensor. The hydrogen gas dissolving apparatus according to claim 4 or 5, wherein a fifth water level sensor is provided between the first water level sensor and the second water level sensor. The hydrogen gas dissolving apparatus according to any one of claims 1 to 6, wherein the water supply pipe and the open pipe are provided with an on-off valve. The hydrogen gas dissolving apparatus according to claim 3 or 4, wherein the oxygen take-out pipe is provided with an on-off valve.

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