TWI672397B - Water electrolysis device - Google Patents

Abstract

An electrolysis water device comprises an electrolysis tank, an air supply pipe and a supplemental gas pump. The electrolytic cell comprises an ion exchange membrane, a cathode chamber, and a cathode electrode disposed in the cathode chamber. The cathode electrode generates hydrogen gas when the electrolytic cell electrolyzes water. The supplemental air pump absorbs air and is connected with the air supply tube by a conduit. A guide angle is formed between the conduit and the air supply tube, so that the air in the conduit is introduced into the air supply tube to dilute a hydrogen concentration in the air supply tube. The volume of the electrolyzed water device is 8.5 liters, and the hydrogen generation rate ranges from 120 ml/min to 600 ml/min.

Description

 Electrolytic water device  

The present invention relates to an electrolyzed water device, and more particularly to an electrolysis water device in which a supplemental air pump and a supplemental gas pipe are connected by a catheter, and a lead angle is interposed between the catheter and the supplemental gas pipe.

Human beings have always attached great importance to life. Many medical technologies have been developed to fight disease and continue human life. Most of the past medical treatments are passive, that is, when the disease occurs, the disease is treated again, such as surgery, drug administration, and even chemotherapy, radiotherapy, or the rehabilitation, rehabilitation, and correction of chronic diseases. However, in recent years, many medical experts have gradually made research toward preventive medical methods, such as health food research, genetic disease screening and early prevention, etc., and actively prevent future morbidity. In addition, in order to extend human life, many anti-aging and anti-oxidation technologies have been developed and widely used by the public, including smeared skin care products and antioxidant foods/drugs.

Studies have found that the body's unstable oxygen (O+), also known as free radicals (harmful free radicals), can be mixed with inhaled hydrogen for various reasons (such as disease, diet, environment or lifestyle). Part of the water, and excreted. Indirectly reduce the amount of free radicals in the human body, achieve acidic body to reduce to a healthy alkaline body, can resist oxidation, anti-aging, and thus achieve the elimination of chronic diseases and beauty care effects. Even clinical trials have shown that for some patients with long-term beds, lung damage caused by long-term breathing of high concentrations of oxygen can relieve the symptoms of lung injury by inhaling hydrogen.

In order to improve the efficiency of inhaling hydrogen, increasing the time of inhaling hydrogen is an effective way to improve the efficacy. However, conventional electrolyzed water devices are relatively bulky, and it is not easy to discharge enough time to take hydrogen gas by a known electrolyzed water device during a person's daily activities. Therefore, the use of hydrogen during sleep should be an effective time. However, as mentioned above, the conventional electrolyzed water device is bulky. How to reduce the volume of the electrolyzed water device and maintain sufficient hydrogen production is a must. Question.

In addition, in addition to the above-mentioned health care, the use of hydrogen gas can also be used to generate an oxyhydrogen flame for heating or combustion, and also to remove engine carbon deposits and the like. Generally, hydrogen is generated by the electrolyte water in the electrolytic cell. However, in the electrolyte state, the high temperature is easily generated. In order to avoid the gas explosion, the conventional hydrogen-oxygen electrolysis cell is mostly air-cooled, that is, the fan is used for cooling, but If the fan fails, the temperature of the hydrogen-oxygen cell will rise and the gas explosion will be dangerous. In addition, the hydrogen-oxygen mixed gas produced after electrolyzing water through the electrolysis device is usually entrained with an electrolyte, which is not suitable for direct inhalation by a human body. At the same time, there is a problem of electrolyte consumption during the electrolysis process.

The invention provides an electrolysis water device, which comprises an electrolytic cell, a gas supplement pipe and a supplemental gas pump. The electrolysis cell comprises a cathode electrode. When the electrolysis cell electrolyzes water, the cathode electrode generates hydrogen gas; the supplemental gas pipe receives hydrogen gas generated by the electrolysis cell; the supplemental air pump absorbs air and is connected with the gas supply pipe through a gas supply interface to receive air. Dilute a hydrogen concentration in the air supply tube. Wherein, the air supply pipe comprises a gas supply interface; the air supply pump comprises a conduit. A joint between the air supply interface and the air supply tube has a lead angle so that the air in the duct is introduced into the air supply tube.

In an embodiment of the invention, the air supply pipe has a first flow path direction, and the air supply interface has a second flow path direction, the first flow path direction is directed to the upper side of the electrolysis water device, and the second flow path direction is directed to the air supply pipe. The lead angle is formed between the direction of the first flow path direction and the direction of the second flow path direction. The angle of the lead angle is preferably between 25 degrees and 45 degrees, and the shape of the joint with the lead angle is formed to have a circular arc.

In an embodiment of the invention, the electrolytic cell further comprises an anode chamber and an oxygen output tube, wherein the anode chamber comprises an anode electrode, an anode sealing plate, an anode conductive plate and an anode outer pressure plate. When the electrolytic cell electrolyzes water, The anode chamber generates oxygen, the oxygen output tube is used for outputting oxygen, and the oxygen output tube is inserted through the anode outer pressure plate, the anode conductive plate and the anode sealing plate.

In an embodiment of the invention, the electrolytic cell further comprises a cathode chamber and a hydrogen output tube, the hydrogen output tube is for outputting hydrogen, the cathode chamber comprises a cathode electrode, a cathode sealing plate and a cathode conductive plate, and the hydrogen output tube runs through the anode. The outer pressure plate, the anode conductive plate, the anode sealing plate and the cathode sealing plate, wherein the oxygen and the hydrogen are output on the same side of the electrolytic cell.

In an embodiment of the present invention, the electrolytic cell further includes a water supply pipe, and the water supply pipe is disposed through the anode outer pressure plate, the anode conductive plate and the anode sealing plate to connect the anode chamber and the water tank, and the water from the water tank flows through the water supply pipe. The anode chamber is used to supplement the electrolyzed water in the anode chamber.

In an embodiment of the invention, the electrolysis water device further comprises a water level detecting device, the water level detecting device being disposed outside the water tank for detecting the amount of water in the water tank.

In one embodiment of the present invention, the electrolysis water device further includes a fan that draws air from the environment outside the electrolyzed water device into the electrolyzed water device for the supplemental air pump to draw air into the supplemental gas pipe.

In one embodiment of the present invention, the electrolysis water device further includes a hydrogen concentration detector connected to the air supply tube to detect whether the hydrogen gas concentration in the gas supply pipe is within a range, and the range is determined by a first predetermined value. And a second predetermined value, when the detected hydrogen volume concentration is higher than the first predetermined value, generating a first warning signal; and a controller coupled to the hydrogen concentration detector, the supplemental air pump, and the electrolysis The slot, when the hydrogen concentration detector receives the first warning signal, generates a start command to stop the air pump from starting to operate.

In one embodiment of the present invention, when the hydrogen concentration detected by the hydrogen concentration detector is higher than a second predetermined value, a second warning signal is generated; and when the controller receives the second warning signal, a second warning signal is generated. Stop the command to stop the cell.

In one embodiment of the present invention, the first predetermined value is 4%, the second predetermined value is 6%, and the volumetric concentration of hydrogen in the supplemental gas pipe is ranged from 4% to 6%.

In an embodiment of the invention, the electrolysis water device further comprises an atomization/volatile gas mixing tank connected to the gas supply pipe and receiving the atomized gas and the hydrogen gas by the diluted hydrogen gas and the atomization/volatile gas mixing tank. Mixing to form a health care gas, wherein the atomizing gas is selected from one or a combination of a group consisting of water vapor, atomized syrup, and volatile essential oil.

In an embodiment of the invention, the electrolysis water device further comprises a power supply, the power supply comprises a high power output end and a low power output end, wherein the electric power output by the low power output end is the electric power outputted by the high power output end. Less than half of the time, wherein the high power output terminal outputs a first voltage and a first current, and the low power output terminal outputs a second voltage and a second current, the first voltage is less than the second voltage, and the first current is greater than the second current .

The invention further provides an electrolysis water device comprising an electrolytic cell, a gas supplement pipe and a supplemental gas pump. The electrolysis cell comprises a cathode electrode. When the electrolysis cell electrolyzes water, the cathode electrode generates hydrogen gas; the supplemental gas pipe receives hydrogen gas generated by the electrolysis cell; the supplemental air pump absorbs air and is connected with the gas supply pipe through a gas supply interface to receive air. Diluting a hydrogen concentration in the gas supply pipe; wherein the volume of the electrolysis water device is less than 8.5 liters, and the hydrogen generation rate of the electrolysis water device may range from 120 ml/min to 600 ml/min, and a user has to use the electrolysis An operation panel of the water device adjusts the rate of hydrogen generation of the electrolyzed water device.

In an embodiment of the invention, the electrolysis water device further comprises a casing, the casing comprising a base and a side wall, and the electrolytic cell is disposed at a non-center of the casing.

In an embodiment of the invention, the electrolytic cell comprises a first side, a second side, an ion exchange membrane, an anode electrode, an oxygen outlet tube and a hydrogen outlet tube. The ion exchange membrane is disposed between the anode electrode and the cathode electrode, and when the electrolytic bath electrolyzes water, the cathode electrode generates hydrogen gas, the anode electrode generates oxygen, the oxygen output tube outputs oxygen, and the hydrogen output tube outputs hydrogen. The first side is adjacent to the side wall, and both oxygen and hydrogen are outputted on the second side of the electrolytic cell.

In one embodiment of the invention, wherein the anode electrode is interposed between the ion exchange membrane and the second side, the cathode electrode is interposed between the ion exchange membrane and the first side, and the oxygen outlet tube is from the ion exchange membrane and the second side The sides extend between the sides and extend through the second side, and the hydrogen outlet tube extends from the ion exchange membrane and the first side to the second side and extends through the second side.

In one embodiment of the invention, wherein the anode electrode is interposed between the ion exchange membrane and the first side, the cathode electrode is interposed between the ion exchange membrane and the second side, and the oxygen outlet tube is from the ion exchange membrane and the first side The sides extend between the sides and extend through the second side, and the hydrogen outlet tube extends from the ion exchange membrane and the second side to the second side and extends through the second side.

The electrolysis tank outputted by the same side of hydrogen and oxygen, and the equipment such as the water tank, the gas-water separation tank and the gas supply pipe are disposed in the casing within the defined volume, and the present invention uses the inside of the casing as much as possible while maintaining sufficient hydrogen production. The space is accommodated, and the use of the fan and the supplemental air pump is also demanded by low noise, so the present invention actually provides an electrolyzed water device that effectively uses space, small volume and low noise. Suitable for placement around the user.

1, 2‧‧‧ Electrolytic water device

10, 70‧‧‧ sink

12, 72‧‧‧Ion membrane electrolyzer

10-1‧‧‧ upper interface

10-2‧‧‧ Lower interface

100‧‧‧shell

102‧‧‧Operator panel

110‧‧‧ side wall

112‧‧‧Base

120‧‧‧Ion exchange membrane

1201‧‧‧Cathode chamber

1202‧‧‧Anode chamber

1203‧‧‧Ion exchange membrane body

1204‧‧‧Ion exchange membrane peripheral plate

121‧‧‧Cathode external pressure plate

122‧‧‧Anode external pressure plate

123‧‧‧Cathode electrode

123-1‧‧‧Cathode conductive plate

123-2‧‧‧Cathode electrode plate

123-3‧‧‧Cathode chamber

124‧‧‧Anode electrode

124-1‧‧‧Anode Conductive Plate

124-2‧‧‧Anode electrode plate

124-3‧‧‧Anode chamber

125‧‧‧Cathode sealing plate

126‧‧‧Anode sealing plate

127‧‧‧ Cathode Catalyst

128‧‧‧Anode Catalytic Layer

14, 74‧‧ ‧ controller

16, 76‧‧‧Atomization / Volatile Gas Mixing Tank

162‧‧‧ oscillator

18, 78‧‧‧ Hydrogen concentration detector

11, 71‧‧ ‧ air supply tube

112‧‧‧ gas supply interface

13, 73‧‧‧ gas pump

132‧‧‧ catheter

134‧‧‧Inhalation

15, 75‧‧‧ fans

17, 77‧‧‧ preheating sink

172‧‧‧Preheating the water tank

174‧‧‧ Electrolytic tank water inlet

176‧‧‧Oxygen receiving tube

178‧‧‧Oxygen discharge pipe

171‧‧‧ Heat sink fins

173‧‧‧second fan

21‧‧‧ Hydrogen output tube

211‧‧‧ Hydrogen interface

22‧‧‧Oxygen output tube

222‧‧‧Oxygen interface

24‧‧ ‧ water supply pipe

242‧‧‧ water interface

25‧‧‧Washers

30‧‧‧ gas water separation tank

32‧‧‧ Spring valve

34‧‧‧Float

36‧‧‧Hydrogen discharge pipe

40‧‧‧Water level detection device

50‧‧‧ sterilizer

60‧‧‧Filter

602‧‧‧ filter heart

80‧‧‧Power supply

801‧‧‧High power output

A‧‧‧ lead angle

D-D, Q-Q‧‧‧ section line segment

D1‧‧‧First runner direction

D2‧‧‧Second runner direction

1A is a perspective view of an electrolyzed water device in accordance with an embodiment of the present invention.

FIG. 1B is a perspective view of the electrolysis water device removing the housing according to an embodiment of the present invention.

1C is a functional block diagram of an embodiment of the present invention.

2A is a simplified schematic cross-sectional view of an ion-exchange membrane electrolysis cell in accordance with an embodiment of the present invention.

2B is a simplified schematic view showing a cross section of an ion-exchange membrane electrolysis cell according to another embodiment of the present invention.

2C is a schematic cross-sectional view of an ion-exchange membrane cell according to the embodiment of FIG. 2A of the present invention.

3 is an exploded view of an ion membrane electrolysis cell in accordance with an embodiment of the present invention.

4 is an exploded view of an ion-exchange membrane electrolyzer different from the perspective of FIG. 3, in accordance with an embodiment of the present invention.

5A and 5B are combined views of the ion-exchange membrane electrolyzer shown in FIG. 3 at different viewing angles.

Figure 6 is an exploded view of an electrolyzed water apparatus in accordance with an embodiment of the present invention.

7A and 7B are respectively an exploded view and a combined view of the electrolyzed water device different from the viewing angle of Fig. 6.

8A is a top view of a water electrolysis apparatus according to an embodiment of the present invention, and FIG. 8B is a cross-sectional view according to line D-D of FIG. 8A.

9 is a schematic view of an electrolysis water apparatus according to another embodiment of the present invention.

Figure 10 is a cross-sectional view taken along line Q-Q of Figure 8A.

Figure 11 is a block diagram showing the function of another embodiment of the present invention.

The advantages, spirits and features of the present invention will be described and discussed in detail by reference to the accompanying drawings.

For the sake of the advantages and spirit of the invention, the spirit and the features may be more easily and clearly understood, and the detailed description and discussion will be made by way of example and with reference to the accompanying drawings. It is noted that the embodiments are merely representative embodiments of the present invention, and the specific methods, devices, conditions, materials, and the like are not intended to limit the present invention or the corresponding embodiments.

Referring to FIG. 1A to FIG. 1C, FIG. 1A is a perspective view of a water electrolysis device according to an embodiment of the present invention. FIG. 1B is a perspective view of the electrolysis water device removing the housing according to an embodiment of the present invention. 1C is a functional block diagram of an embodiment of the present invention. In one embodiment, the electrolysis water device 1 provided by the present invention comprises a housing 100 and an operation panel 102. The housing 100 includes a side wall 110 and a base 112. The housing 100 includes a water tank 10 and an ion membrane electrolysis cell 12 for providing electrolysis water for the ion-exchange membrane electrolysis cell 12, which is disposed on one side of the casing 100 with respect to the operation panel 102. The ion-exchange membrane electrolytic cell 12 is disposed between the operation panel 102 and the water tank 10 and is offset from one side of the center of the casing 100. The ion membrane electrolysis cell 12 is used to electrolyze water to produce hydrogen gas. In one embodiment, the water may be deionized water, and high-purity hydrogen may be prepared, but not limited to deionized water. In practical applications, any water that can be obtained by the user is acceptable. Moreover, the present invention is not limited by an ion-exchange membrane electrolytic cell, and other types of electrolytic cells can be used in the present invention.

Please refer to FIG. 2A and FIG. 2B. FIG. 2A is a simplified schematic diagram of a cross section of an ion membrane electrolysis cell according to an embodiment of the invention. 2B is a simplified schematic view showing a cross section of an ion-exchange membrane electrolysis cell according to another embodiment of the present invention. This paragraph will briefly explain the main features of the present invention in conjunction with Figures 2A and 2B.

Referring to FIG. 2A, the ion-exchange membrane electrolysis cell 12 generally includes an ion exchange membrane 120, a cathode electrode 123, an anode electrode 124, a first side S1, a second side S2, a hydrogen output tube 21, and a Oxygen output tube 22. The ion exchange membrane 120 is disposed between the first side S1 and the second side S2, the cathode electrode 123 is disposed between the ion exchange membrane 120 and the first side S1, and the anode electrode 124 is disposed on the ion exchange membrane 120 and the second Between the sides S2. The region in which the first side S1 and the cathode electrode 123 are located is referred to as a cathode chamber 1201, and the region in which the second side S2 and the anode electrode 124 are located is referred to as an anode chamber 1202, except that the cathode chamber 1201 and the anode chamber 1202 are more clearly expressed. Corresponding to the position, the position is indicated by a broken line in Fig. 2A. The hydrogen output tube 21 extends from the ion exchange membrane 120 and the first side S1 to the second side S2 and penetrates the second side S2. The oxygen output tube 22 is between the ion exchange membrane 120 and the second side S2. Extending to the second side S2 and penetrating the second side S2. When the ion-exchange membrane electrolytic cell 12 electrolyzes water, the cathode electrode 123 generates hydrogen gas, and the anode electrode 124 generates oxygen. The main feature of the present invention is that hydrogen and oxygen generated by electrolyzing water are separately supplied to the second side S2 of the ion-exchange membrane electrolytic cell 12 via the hydrogen output pipe 21 and the oxygen output pipe 22. In the present embodiment, the hydrogen gas output pipe 21 is output together with the oxygen gas output pipe 22 on one side of the anode chamber 1202 of the ion-exchange membrane electrolytic cell 12.

However, the positions at which the hydrogen gas output pipe 21 and the oxygen gas output pipe 22 of the present invention are disposed are not limited to the foregoing embodiments. Referring to FIG. 2B, the components of the ion-exchange membrane electrolysis cell 12 illustrated in FIG. 2B are the same as those of FIG. 2A except that the first side S1 and the second side S2 of FIG. 2B are disposed opposite to each other in FIG. 2A. In FIG. 2B, the anode electrode 124 is disposed between the ion exchange membrane 120 and the first side S1, the cathode electrode 123 is disposed between the ion exchange membrane 120 and the second side S2, and the cathode chamber 1201 includes the second side S2. And the cathode electrode 123, and the anode chamber 1202 includes a first side S1 and an anode electrode 124. The hydrogen output pipe 21 extends from the ion exchange membrane 120 and the second side S2 to the second side S2 and penetrates the second side S2, and the oxygen output pipe 22 passes between the ion exchange membrane 120 and the first side S1. The second side S2 extends and penetrates the second side S2. When the ion-exchange membrane electrolytic cell 12 electrolyzes water, the cathode electrode 123 generates hydrogen gas, and the anode electrode 124 generates oxygen. The main feature of the present invention is that hydrogen and oxygen generated by electrolyzing water are output to the second side S2 of the ion-exchange membrane electrolysis cell 12 via the hydrogen output pipe 21 and the oxygen output pipe 22, respectively. In the present embodiment, the hydrogen gas output pipe 21 is output together with the oxygen gas output pipe 22 on one side of the cathode chamber 1201 of the ion-exchange membrane electrolytic cell 12.

That is, the hydrogen gas output pipe 21 and the oxygen gas output pipe 22 of the present invention are disposed on either side of the ion-exchange membrane electrolysis cell 12 according to the actual needs of the user.

Next, please refer to FIG. 2C. FIG. 2C is a schematic cross-sectional view of an ion-exchange membrane electrolytic cell according to the embodiment of FIG. 2A of the present invention. As shown in FIG. 2C, the ion-exchange membrane electrolysis cell 12 includes an ion exchange membrane 120, a cathode chamber 1201, and an anode chamber 1202. The cathode chamber 1201 includes a cathode electrode 123, and the anode chamber 1202 includes an anode electrode 124. The ion exchange membrane 120 is disposed between the anode chamber 1202 and the cathode chamber 1201. When the ion membrane electrolytic cell 12 electrolyzes water, the cathode electrode 123 generates hydrogen gas. The anode electrode 124 generates oxygen. In one embodiment, the anode chamber 1202 is filled with water, and the water in the anode chamber 1202 is further passed through the ion exchange membrane 120 to penetrate into the cathode chamber 1201. 2A to 2C are only schematic cross-sectional views for explaining the internal structure of the ion-exchange membrane electrolyzer. Therefore, the internal structure of the ion-exchange membrane electrolysis cell is not disclosed in FIGS. 2A to 2C, and the white space block in the upper part of FIG. 2C represents ions. The outer casing of the membrane electrolyzer.

As shown in FIG. 2C, the ion exchange membrane 120 includes an ion exchange membrane body 1203, a cathode catalytic layer 127, and an anode catalytic layer 128. The ion exchange membrane body 1203 can be a proton exchange membrane, which can preferably be a Nafion membrane. The cathode catalytic layer 127 may be selected from one of a group consisting of Pt, Ir, Pd, and Pt alloy powders, or a combination thereof. The anode catalytic layer 128 may be selected from one or a combination of a group consisting of Pt, Ir, Pd, Pt alloy powder, and carbon black. In one embodiment, the materials of the cathode catalyst layer 127 or the anode catalyst layer 128 may be separately disposed as a slurry coating on both sides of the ion membrane to form a cathode catalyst layer 127 and an anode catalyst layer 128. In practical applications, hydrogen can be generated on the catalytic layer, but not limited thereto, hydrogen can also be generated on the electrode plate, or even between the ion membrane and the electrode plate. Therefore, the ion-exchange membrane electrolytic cell 12 used in the present invention can avoid the problem of corrosion of the tank body, environmental pollution, incomplete filtration, and inhalation of the electrolyte-containing gas, as compared with the conventional alkali-type electrolytic cell.

Referring to FIG. 2A to FIG. 2C, the cathode chamber 1201 includes a cathode outer pressure plate 121, a cathode electrode 123, a cathode sealing plate 125, and a cathode catalytic layer 127. The anode chamber 1202 includes an anode outer pressure plate 122 and an anode electrode 124. An anode sealing plate 126 and an anode catalytic layer 128. Corresponding to the content of FIG. 2A, the first side S1 and the second side S2 of FIG. 2A respectively correspond to the cathode outer pressure plate 121 and the anode outer pressure plate 122 of FIG. 2C; and corresponding to the content of FIG. 2B, The first side S1 and the second side S2 of FIG. 2B correspond to the anode outer pressure plate 122 and the cathode outer pressure plate 121 of FIG. 2C, respectively. The ion-exchange membrane electrolysis cell 12 includes a hydrogen gas output pipe 21, an oxygen gas output pipe 22, and a water supply pipe 22 for outputting oxygen. The hydrogen gas output pipe 21 is for outputting hydrogen gas generated in the cathode chamber 1201, as shown in FIG. 2C. It is shown that the hydrogen output pipe 21 penetrates through the cathode sealing plate 125, the anode sealing plate 126, the anode electrode 124 and the anode outer pressing plate 122 (as in the second side S2 of FIG. 2A), so that the cathode chamber 1201 can be combined with the ion membrane electrolytic cell. The external environment other than 12 is connected to and outputs hydrogen; and the oxygen output pipe 22 is for outputting oxygen generated in the anode chamber 1202, and the oxygen output pipe 22 is penetrated through the anode electrode 124 and the anode outer plate 122 to enable the anode chamber 1202 to be combined with the ion. The external environment other than the membrane electrolysis cell 12 communicates with and outputs oxygen; the water supply pipe 24 penetrates the anode electrode 124 and the anode outer pressure plate 122, and is connected to the water tank 10 for introducing water in the water tank 10 into the anode chamber 1202 to replenish ions. The electrolysis water of the membrane electrolysis cell 12. The hydrogen output tube 21 and the oxygen output tube 22 are both disposed on the same side of the ion-exchange membrane electrolysis cell 12. In the embodiment, the hydrogen output tube 21, the oxygen output tube 22 and the water supply tube 24 are both penetrated and disposed on the anode outer pressure plate 122. on. However, the present invention is not limited thereto. Under a similar structure, the hydrogen output pipe 21, the oxygen output pipe 22 and the water supply pipe 24 may also pass through and be disposed on the cathode outer pressure plate 121, as shown in the second side S2 of FIG. 2B. .

Please refer to FIG. 3 to FIG. 4. FIG. 3 is an exploded view of an ion membrane electrolysis cell according to an embodiment of the invention. 4 is an exploded view of an ion-exchange membrane electrolysis cell different from the perspective of FIG. 3, wherein the ion exchange membrane 120 further includes an ion exchange membrane peripheral plate 1204 for fixing the ion exchange membrane body 1203 and the cathode according to an embodiment of the present invention. The relative positions of the catalytic layer 127 and the anode catalytic layer 128 within the ion-exchange membrane cell. 3 and FIG. 4 more clearly illustrate the relative positional relationship between the components in the ion-exchange membrane electrolysis cell 12, and the ion-exchange membrane electrolysis cell 12 includes various components which can be stacked as shown in FIGS. 3 and 4. Assembly in sequence.

Please refer to FIG. 3 to FIG. 4 . In an embodiment, the ion exchange membrane peripheral plate 1204 , the cathode sealing plate 125 and the anode sealing plate 126 can be surrounded by the electrode plate to achieve an insulating and airtight effect. The material of the ion exchange membrane peripheral plate 1204, the cathode sealing plate 125 and the anode sealing plate 126 may be silicone, but the arrangement and material of the cathode sealing plate 125 and the anode sealing plate 126 are not limited to the above, as long as practical applications The setting method or material that can achieve the effect of insulation and airtightness can be used.

As shown in FIG. 3 and FIG. 4, the hydrogen output pipe 21 is penetrated through the cathode sealing plate 125, the ion exchange membrane peripheral plate 1204, the anode sealing plate 126, the anode electrode 124, and the anode outer pressing plate 122 to generate the cathode chamber 1201. Hydrogen gas can be output to the side of the anode external pressure plate 122 via the hydrogen output pipe 21; and the oxygen output pipe 22 is penetrated through the anode electrode 124 and the anode external pressure plate 122, so that oxygen generated in the anode chamber 1202 can be exchanged with the ion through the oxygen output pipe 22. The membrane peripheral plate 1204 is outputted on the side of the anode outer pressure plate 122. The water supply pipe 24 is inserted through the anode electrode 124 and the anode outer pressure plate 122, and is connected to the water tank 10 for introducing water in the water tank 10 into the anode chamber 1202 to supplement ions. The electrolysis water of the membrane electrolysis cell 12. A gas gasket 25 is disposed between the hydrogen gas output pipe 21, the oxygen gas output pipe 22, and the water supply pipe 24 and the anode outer pressure plate 122 to seal the space between the hydrogen gas output pipe 21, the oxygen gas output pipe 22, and the water supply pipe 24 and the anode outer pressure plate 122. .

As shown in FIG. 3 and FIG. 4, the cathode electrode 123 includes a cathode conductive plate 123-1 and a cathode electrode plate 123-2, and the anode electrode 124 includes an anode conductive plate 124-1 and an anode electrode plate 124-2. In one embodiment, each of the electrode plates may be a titanium powder die-casting piece, and the material of each of the conductive plates may be titanium, but the actual application is not limited to the above materials or molding methods. As shown in FIG. 3, in an embodiment, the cathode electrode plate 123-2 may be disposed between the ion exchange membrane 120 or the ion exchange membrane body 1203 and the cathode conductive plate 123-1, and the anode electrode plate 124-2 may be disposed on The ion exchange membrane 120 or the ion exchange membrane body 1203 is interposed between the anode conductive plates 124-1. The ion-exchange membrane cell 12 can be connected to an external power source via a cathode conductive plate 123-1 and an anode conductive plate 124-1. In one embodiment, the anode conductive plate 124-1 (shown in FIG. 3) and the cathode conductive plate 123-1 (shown in FIG. 4) have flow path designs respectively, when the cathode conductive plate 123-1 and the cathode electrode When the plates 123-2 are stacked on each other, a plurality of cathode chambers 123-3 can be formed in the cathode chamber 1201, and the anode conductive plates 124-1 and the anode electrode plates 124-2 can be stacked in the anode chamber 1202 when they are stacked on each other. A plurality of anode chambers 124-3 are formed. The cathode chamber 123-3 and the anode chamber 124-3 are available for gas and water to circulate therein, wherein the anode chamber 124-3 is connected to the oxygen delivery tube 22, and the cathode chamber 123-3 is connected to the hydrogen delivery tube 21.

Please refer to FIG. 5A and FIG. 5B . FIG. 5A and FIG. 5B are combinations of the ionic membrane electrolyzer shown in FIG. 3 at different viewing angles. The cathode outer pressure plate 121 and the anode outer pressure plate 122 are respectively disposed on both outer sides of the ion-exchange membrane electrolytic cell 12 to fix and isolate the entire ion-exchange membrane electrolytic cell 12, wherein the cathode outer pressure plate 121 and the anode outer pressure plate 122 are made of stainless steel. In an embodiment, after the ion-exchange membrane electrolysis cell 12 is assembled, it can be locked by a locking component (shown in FIG. 6), but the number, type, and locking manner of the locking component are not shown. The limit shown in Figure 6 is shown. As shown in the figure, since the combined volume of the ion-exchange membrane electrolytic cell 12 is relatively small, the volume of the electrolyzed water device of the present invention itself can be made small.

Referring to FIG. 1C, FIG. 6, and FIG. 7A to FIG. 7B, FIG. 6 is an exploded view of an electrolyzed water device according to an embodiment of the present invention. 7A and 7B respectively show an exploded view and a combined view of the electrolyzed water device different from the viewing angle of Fig. 6, and for the sake of explanation, only necessary elements are shown in Figs. 6, 7A and 7B. The electrolysis water device 1 of the present invention comprises a gas supply pipe 11, a gas supplement pump 13, a fan 15, an atomization/volatile gas mixing tank 16, and a hydrogen concentration in addition to the water tank 10 and the ion membrane electrolysis cell 12 described above. The detector 18, a controller 14, a gas-water separation tank 30, and a water level detecting device 40. As shown in Fig. 6, the gas-water separation tank 30 is housed in the water tank 10, and its detailed structure will be described later. The electrolysis water device 1 of the present invention further includes a water level detecting device 40 for detecting the amount of water in the water tank 10. In one embodiment, the water level detecting device 40 is a capacitive water level detecting device and is disposed on the outer surface of the water tank 10, and measures the difference between the water and the water-free region in the water tank 10 to measure the water tank. The amount of water in 10.

Referring to FIG. 6, FIG. 8A and FIG. 8B, FIG. 8A is a top view of the electrolysis water device according to an embodiment of the present invention, and FIG. 8B is a cross-sectional view according to the line segment D-D of FIG. 8A. The hydrogen gas output pipe 21 of the ion-exchange membrane electrolysis cell 12 is connected and communicated with the gas-water separation tank 30 via the hydrogen gas port 211, and the oxygen gas output pipe 22 is connected and connected to the water tank 10 via the oxygen port 222. The water tank 10 includes a sterilizer 50 therein. For example, in the present embodiment, the sterilizer 50 is a continuous cylindrical ultraviolet sterilizer, and the sterilizer 50 is disposed in the water tank 10 on one side away from the gas-water separation tank 30. The water supply pipe 24 directly communicates with one side of the water tank 10 near the sterilizer 50 via the water port 242 to receive the sterilized water from the water tank 10 to replenish the electrolysis water of the ion-exchange membrane electrolytic cell 12.

The gas-water separation tank 30 includes a spring valve 32, a float 34, and a hydrogen discharge pipe 36. The hydrogen gas generated by the electrolysis of the ion-exchange membrane electrolysis cell 12 is conducted to the gas-water separation tank 30 via the hydrogen gas output pipe 21 and the hydrogen gas port 211. When the hydrogen in the gas-water separation tank 30 is accumulated to a certain extent, the spring valve 32 will be opened due to the hydrogen gas pressure, allowing hydrogen gas to be discharged to the filter 60 via the hydrogen discharge pipe 36 to filter impurities in the hydrogen gas. Further, when hydrogen gas is output from the ion-exchange membrane electrolytic cell 12, a small amount of residual electrolyzed water may be mixed, and these residual electrolyzed water may accumulate in the gas-water separation tank 30 to form liquid water, and the float 34 may float due to accumulated liquid water. At this time, a drain port (not shown) covered by the float 34 will be opened, and the accumulated liquid water will be discharged into the water tank 10 through the drain port for recycling.

The oxygen generated by the electrolysis is directly discharged into the water tank 10 via the oxygen outlet pipe 22 and the oxygen port 222, and the oxygen gas is directly discharged from the upper portion of the water tank 10 to the atmospheric environment, and may be mixed when the oxygen is output from the ion-exchange membrane electrolysis cell 12. There is a small amount of residual electrolyzed water, and these residual electrolyzed water is directly discharged into the water tank 10 for recycling.

Referring to FIG. 7A, FIG. 7B, FIG. 8A and FIG. 9, FIG. 9 is a cross-sectional view of the line segment Q-Q according to FIG. 8A. As described in the preceding paragraph, the hydrogen gas is discharged to the filter 60 via the hydrogen discharge pipe 36, and the impurity in the hydrogen gas is filtered by a filter core 602 contained in the filter 60, and the filtered hydrogen gas is further conducted to the gas supply pipe 11 for dilution. To enter the atomization/volatile gas mixing tank 16. The air supply pipe 11 is connected to the filter 60 to receive the filtered hydrogen gas, and the air supply pipe 11 is connected to the air supply pump 13, and the fan 15 draws in air from the external environment other than the electrolysis water device 1 to dilute the hydrogen gas in the air supply pipe 11. . All of the aforementioned components are covered by the housing 100. The housing 100 is provided with a plurality of small holes, and the fan 15 draws air from the external environment into the electrolyzed water device 1 through the perforations penetrating the housing 100, and the sucked air is further inhaled by the air supply pump 13. Inside the trachea 11. In the present embodiment, the supplemental air pump 13 is a vortex fan, and the air sucked by the fan 15 is sucked into the supplemental air pump 13 through a suction port 134 of the supplemental air pump 13 to introduce air into the supplemental gas supply tube 11. As shown in FIG. 7B and FIG. 9, a conduit 132 of the supplemental air pump 13 is connected to a supplemental air interface 112 of the supplemental air tube 11, the air supply tube 11 has a first flow channel direction D1, and the air supply interface 112 has a second flow channel. In the direction D2, the gas flow direction in the first flow path direction D1 flows to the atomization/volatile gas mixing tank 16, as indicated by the arrow on the indication line representing the first flow path direction D1, and the arrow on the indication line also points above the electrolysis water device; The flow direction of the gas in the second flow path direction D2 is directed to the air supply pipe 11, as indicated by an arrow on the indication line representing the second flow path direction D2, so that the air flowing in from the duct 132 through the air supply port 112 is introduced into the air supply pipe 11 . A guide angle A is formed between the direction of the first flow path direction D1 and the direction of the second flow path direction D2, and the lead angle A is an acute angle of less than 90 degrees. The preferred angle of the design angle A is between 25 degrees and 25 degrees. Between 45 degrees, and at the angle A of the position where the air supply pipe 11 and the air supply port 112 are engaged, the shape of the engagement position is formed with a circular arc lead angle. By the design of the guide angle A, the air in the duct 132 can be smoothly and introduced into the air supply pipe 11 to dilute the hydrogen gas in the air supply pipe 11.

Referring to FIG. 9, the atomization/volatile gas mixing tank 16 is connected to the supplemental gas pipe 11, and receives the filtered and diluted hydrogen from the gas supply pipe 11, and generates an atomizing gas mixed with hydrogen to form a health care gas. Wherein the atomizing gas may be selected from one or a combination of the group consisting of water vapor, atomized syrup, and volatile essential oil. The atomizing/volatile gas mixing tank 16 includes an oscillator 162 which atomizes water, atomized syrup or volatile essential oil added to the atomizing/volatile gas mixing tank 16 by shaking to generate an atomizing gas. Then, hydrogen and oxygen are mixed with the atomizing gas to form a health care gas. The atomizing/volatile gas mixing tank 16 can be selectively opened or closed according to user requirements, that is, the atomizing/volatile gas mixing tank 16 can be activated by actuating the oscillator to provide hydrogen for mixing the atomizing gas. The user is inhaled, or the atomizing/volatile gas mixing tank 16 can be closed by stopping the oscillator to provide only filtered and diluted hydrogen for inhalation by the user. The means for the user to inhale the filtered and diluted hydrogen or health gas includes the atomizing/volatile gas mixing tank 16 to directly release the hydrogen or health care gas into the atmosphere, or to be inhaled by the user via a line and a cover.

The hydrogen concentration detector 18 is connected to the supplemental gas pipe 11 to detect the hydrogen concentration in the gas supply pipe 11, and the controller 14 is connected to the hydrogen concentration detector 18, the supplemental gas pump 13, and the ion membrane electrolysis cell 12. In one embodiment, the hydrogen concentration detector 18 can be connected to the hydrogen output tube 21 or the hydrogen port 211 to detect the volumetric concentration of hydrogen gas output from the ion-exchange membrane electrolysis cell 12 into the supplemental gas tube 11. The hydrogen concentration detector 18 detects whether the hydrogen gas concentration is within a range, and the range is composed of a first predetermined value and a second predetermined value, for example, the first predetermined value is 4%, and the second predetermined value is 6%, that is, the hydrogen concentration detected by the hydrogen concentration detector 18 may be between 4% and 6%, wherein the first predetermined value and the second predetermined value may be transmitted through the operation panel 102 according to user requirements. The size of the aforementioned predetermined value is adjusted. In this embodiment, when the hydrogen concentration detector 18 detects that the hydrogen gas volume in the hydrogen gas output pipe 21 or the hydrogen gas port 211 is higher than the first predetermined value by 4%, a first warning signal is generated to the controller 14, When the controller 14 receives the first warning signal, a start command is generated to the makeup pump 13 to activate the supplemental air pump 13 to draw air into the supplemental gas tube 11 to dilute the hydrogen in the supplemental gas supply tube 11. When the hydrogen concentration detector 18 detects that the hydrogen volume concentration in the hydrogen output pipe 21 or the hydrogen port 211 is higher than the second predetermined value of 6%, a second warning signal is generated to the controller 14, when the controller 14 receives When the second warning signal is issued, a stop command is generated to stop the operation of the ion-exchange membrane electrolytic cell 12, for example, the power input to the ion-exchange membrane electrolytic cell 12 is cut off, thereby avoiding the gas explosion caused by the excessive hydrogen concentration, thereby improving the overall safety.

Please refer to FIG. 10, which is a cross-sectional view of a water electrolysis apparatus according to another embodiment of the present invention. In another embodiment of the present invention, a preheating water tank 17 is further connected between the water tank 10 and the ion membrane electrolytic cell 12. The preheating water tank 17 is substantially cylindrical or circular. Although the preheating water tank 17 is larger than the water tank 10 in FIG. 10, in other embodiments, the preheating water tank 17 has a smaller volume than the water tank 10. The preheating water tank 17 includes a preheating water tank water filling port 172, is connected to the lower port 10-2 of the water tank 10, an electrolytic cell water inlet 174, and is connected to the water supply pipe 24 of the ion membrane electrolysis cell 12, an oxygen receiving pipe 176, and connected. The oxygen output pipe 22 and an oxygen exhaust pipe 178 are connected to the upper port 10-1 of the water tank 10. The preheating water tank 17 is provided between the water tank 10 and the ion-exchange membrane electrolytic cell 12, and the electrolyzed water in the water tank 10 first flows into the preheating water tank 17, and flows into the ion-exchange membrane electrolytic cell 12 through the electrolytic cell water injection port 174 to perform electrolysis. The oxygen generated during the electrolysis of water and part of the residual electrolyzed water are discharged into the preheating water tank via the oxygen receiving pipe 176, and part of the residual electrolyzed water is retained in the preheating water tank 17, and the oxygen generated by the electrolysis is discharged through the oxygen exhaust pipe. 178 is discharged to the water tank 10 and discharged to the outside of the electrolysis water device.

Among them, the temperature of the ion-exchange membrane electrolysis tank 12 is increased in the process of electrolyzing water, and the temperature of the electrolyzed water itself is also related to the electrolysis efficiency, and the electrolysis water temperature of about 55 to 65 ° C can improve the electrolysis efficiency. Then, the preheating water tank 17 of the present invention preheats the electrolyzed water entering the ion-exchange membrane electrolytic cell 12 in the preheating water tank 17 by recovering the relatively warm residual electrolyzed water discharged from the oxygen output pipe 22 of the ion-exchange membrane electrolytic cell 12. To a suitable temperature, for example between 55 and 65 °C. In order to control the temperature of the electrolyzed water in the preheating water tank 17 to be maintained between 55 and 65 ° C, the preheating water tank further includes a plurality of fins 171 and a second fan 173. The plurality of heat dissipation fins 171 are disposed on the outer groove wall of the preheating water tank 17 in a radial pattern, and the second fan 173 is disposed at one end of the preheating water tank 17, and is matched with the plurality of heat dissipation fins 171 to utilize forced convection. The way to heat the preheating water tank 17 is. For the sake of simplicity, only the heat dissipation fins 171 are drawn on a part of the outer groove wall of the preheating water tank 17, and in other embodiments, the heat dissipation fins 171 may be distributed on the outer groove wall of the preheating water tank 17.

Please refer to FIG. 11. FIG. 11 is a functional block diagram of another embodiment of the present invention. The present invention further provides an electrolysis water device 2 comprising a water tank 70, an ion membrane electrolysis cell 72, an atomization/volatile gas mixing tank 76, an air supply pipe 71, a supplemental gas pump 73, a fan 75, a controller 74, and a preheating water tank 77. The difference between the electrolysis water device 2 and the electrolysis water device 1 is that the connection relationship between the three elements of the ion membrane electrolysis cell 72, the atomization/volatile gas mixing tank 76, and the supplemental gas pipe 71 of the electrolysis water device 2 is different from that of the electrolysis water device 1. The function and connection relationship of the other elements of the same name are the same as those of the electrolysis water device 1 except for the ion-exchange membrane electrolysis cell 12, the atomization/volatile gas mixing tank 16, and the gas supply pipe 11, and will not be described herein.

In the embodiment of the electrolysis water device 2, the ion membrane electrolysis cell 72 is connected and communicated with the atomization/volatile gas mixing tank 76 through a hydrogen gas output pipe to receive hydrogen gas generated by the ion membrane electrolysis cell 72, atomizing/volatile gas. The tank 76 is mixed and an atomizing gas is mixed with hydrogen to form a health care gas. The atomizing gas may be selected from one or a combination of a group consisting of water vapor, atomized syrup, and volatile essential oil. The atomizing/volatile gas mixing tank 76 includes an oscillator which atomizes water, atomized syrup or volatile essential oil added to the atomizing/volatile gas mixing tank 76 by shaking to generate atomizing gas, and then generates atomizing gas. Hydrogen is mixed with the atomizing gas to form a health care gas. The atomizing/volatile gas mixing tank 76 can be selectively opened or closed according to user requirements, that is, the atomizing/volatile gas mixing tank 76 can be activated by actuating the oscillator to provide hydrogen for mixing the atomizing gas. The user is inhaled, or the atomizing/volatile gas mixing tank 76 can be closed by stopping the oscillator to provide only hydrogen for the user to inhale. The means for inhaling hydrogen or health care gas by the user includes the atomization/volatile gas mixing tank 76 to directly release the hydrogen or health care gas into the atmosphere, or through a conduit and a cover for the user to inhale.

The hydrogen concentration detector 78 is coupled to the atomizing/volatile gas mixing tank 76 to detect the hydrogen concentration in the atomizing/volatile gas mixing tank 76, and the controller 74 is connected to the hydrogen concentration detector 78 and the ion membrane electrolytic cell. 72. In one embodiment, the hydrogen concentration detector 78 can be coupled to the atomization/volatile gas mixing tank 76 to detect the volumetric concentration of hydrogen gas output from the ion membrane electrolysis cell 12 to the atomization/volatile gas mixing tank 76. The hydrogen concentration detector 78 detects whether the hydrogen gas volume concentration is within a range, and the range is composed of a first predetermined value and a second predetermined value, for example, the first predetermined value is 4%, and the second predetermined value is The 6%, that is, the hydrogen concentration detector 78 can detect a hydrogen volume concentration between 4% and 6%, wherein the first predetermined value and the second predetermined value can be transmitted through the operation panel 102 according to user requirements. The size of the aforementioned predetermined value is adjusted. In this embodiment, when the hydrogen concentration detector 78 detects that the hydrogen volume concentration in the atomization/volatile gas mixing tank 76 is higher than the first predetermined value by 4%, a first warning signal is generated to the controller 14, When the controller 14 receives the first warning signal, a start command is generated to the makeup pump 13 to activate the supplemental air pump 13 to draw air into the supplemental gas tube 11 to dilute the hydrogen in the supplemental gas supply tube 11. When the hydrogen concentration detector 18 detects that the hydrogen volume concentration in the hydrogen output tube 21 or the hydrogen port 211 is higher than the second predetermined value of 6%, a second warning signal is generated to the controller 14, when the controller 74 receives When the second warning signal is issued, a stop command is generated to stop the operation of the ion-exchange membrane electrolytic cell 72, for example, to cut off the electric power input to the ion-exchange membrane electrolytic cell 72, thereby avoiding the gas explosion caused by the excessive hydrogen concentration, thereby improving the overall safety.

The air supply pipe 71 is connected to the atomization/volatile gas mixing tank 76, and the air supply pipe 71 is further connected to the fan 75 and the air supply pump 73, thereby drawing in air from the external environment other than the electrolysis water device 2 to dilute the atomization/volatile gas mixture. Hydrogen in tank 76. The electrolyzed water device 2 of the present invention has a casing for covering all of the aforementioned elements. The housing is provided with a plurality of small holes, and the fan 75 draws air from the external environment into the electrolyzed water device 2 through the small holes in the casing, and the sucked air is sucked into the air supply pipe 71 by the air supply pump 73.

Since one of the objects of the present invention is to reduce the volume of the electrolyzed water device while reducing the volume of the electrolyzed water device, and to reduce the noise generation, so as to be suitable for the user to use during sleep, the applicant first reduces the volume of the electrolyzed water device. For the main purpose. For example, the electrolyzed water device of the present invention is roughly cylindrical, and the longest section length at the bottom, that is, the minimum diameter is 200 mm, and the height of the device is at most 270 mm, so the volume is at most about 8500 cubic centimeters, or 8.5 liters, but The shape of the electrolyzed water device of the invention is not limited to the cylindrical type, and the shape of the electrolyzed water device may be other shapes, for example, when the shape of the electrolyzed water device is elliptical, square or polygonal, as long as the bottom thereof or the base 112 The longest cross-sectional side length is greater than the longest cross-sectional side length of the top to conform to the design of the present invention that tapers from the bottom to the top. . The storage space defined by the housing of the electrolyzed water device is effectively utilized as much as possible to maintain a sufficient amount of hydrogen production for the user to smoke. For example, the hydrogen production rate of the electrolyzed water device has a total of six output settings, including the electrolysis water device. The hydrogen production rate of the health gas outputting mixed air and hydrogen and atomizing gas: 120ml/min, 240ml/min, 360ml/min, corresponding to the three settings of the health gas output rate of the electrolyzed water device: 2L/min, 4L/min And 6L/min. And let the electrolyzed water device output 400 ml/min of pure hydrogen, 500 ml/min, 600 ml/min. Moreover, the user can adjust the hydrogen generation rate of the electrolysis water device 1 and the type of gas output through the operation panel. The noise is reduced to allow the user to place the present invention in a position close to the user's head while sleeping.

Please refer to FIG. 1C and FIG. In one embodiment, the electrolysis water apparatus 1, 2 provided by the present invention includes a power supply 80 for converting commercial power to output 240 watts of direct current to supply the electrolyzed water apparatus 1, 2 electric power. The power supply 80 includes a high power output 801 and a low power output. The high power output terminal 801 is connected to the ion membrane electrolysis cells 12, 72 to supply the electric power required for the electrolysis reaction. The low power output is adapted to supply other non-electrolytic cell components in the electrolysis water device 1, 2, such as the gas required for operation of the components such as the supplemental gas pump 13, the controller 14, the fan 15, and the hydrogen concentration detector 18, and Simplified graphical content, only the power supply 80 and the high power output 801 are depicted in FIGS. 1C and 11 , but generally the knowledger should be able to know how the low power output that supplies the power required for the operation of the electrolyzed water device is in the electrolyzed water device. The power line is configured inside.

Of the 240 watts of direct current supplied by the power supply 80, 172 watts are output from the high power output 801 to the ion membrane electrolysis cells 12, 72. The high power output 801 outputs a first voltage and a first current, wherein the first voltage ranges between 3 volts and 6.3 volts and outputs a first current of 10 amps to 27.3 amps. The low power output outputs 60 watts of direct current to supply the power required to operate the electrolysis unit. The low power output outputs a second voltage and a second current, wherein the second voltage is a 24 volt DC voltage and a maximum current of 2.5 amps. In another embodiment, the second voltage can also be stepped down from 24 volts to 5 volts and output a second current of up to 0.5 amps. Comparing the power parameters outputted by the high power output and the low power output, the first voltage is lower than the second voltage, but the first current is higher than the second current. Therefore, the high-power output terminal outputs high-current low-voltage DC power, and the low-power output terminal outputs low-current high-voltage DC power.

In summary, the present invention provides an electrolysis water device comprising an ion membrane electrolysis cell with the same side of hydrogen and oxygen output, a supplemental gas pipe, a supplemental gas pump, and an atomization/volatile gas mixing tank. The ion-exchange membrane electrolyzer electrolyzes water to generate hydrogen gas. After the hydrogen gas is input to the air supply pipe, the air-enhanced pump draws in air, and the air is unidirectionally input into the air supply pipe through a gas-filling port with a lead angle and a supplemental gas pipe to dilute the gas supply pipe. The hydrogen gas is supplied to the gas supply tube and then the diluted hydrogen gas is introduced into the atomization/volatile gas mixing tank to be mixed with an atomizing gas for the user to suck.

The ionic membrane electrolyzer, which is output on the same side as the hydrogen and oxygen, and the water tank, the gas-water separation tank, and the gas supply tube are disposed in a casing within a defined volume, and the present invention uses the shell as much as possible while maintaining sufficient hydrogen production. The housing space in the body, and the use of the fan and the air pump are also low noise, so the present invention actually provides an electrolytic water device that effectively uses space, small volume and low noise. Suitable for placement around the user.

The features and spirit of the present invention will be more apparent from the detailed description of the preferred embodiments. On the contrary, the intention is to cover various modifications and equivalents within the scope of the invention as claimed. Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and the present invention can be modified and modified without departing from the spirit and scope of the present invention. The scope is subject to the definition of the scope of the patent application attached.

Claims (17)

An electrolysis water device comprising: an electrolysis cell comprising a cathode electrode, the cathode electrode generating the hydrogen gas when the electrolysis cell electrolyzes water; and a supplemental gas pipe receiving the hydrogen gas generated by the electrolysis cell, comprising a supplemental gas And a gas supplement pump comprising: a gas pipe that absorbs air and is connected to the gas supply port of the gas supply pipe to receive air to dilute a hydrogen concentration in the gas supply pipe; wherein the gas supply pipe Having a first flow channel direction, the gas supply interface has a second flow channel direction, the first flow channel direction is directed to the upper portion of the electrolysis water device, the second flow channel direction is directed to the air supply pipe, and the air supply interface is An engagement position between the air supply tubes has a lead angle formed between the direction of the first flow path and the direction of the second flow path, so that the air in the duct is introduced into the supplement Inside the trachea. The electrolysis water device of claim 1, wherein the angle of the lead angle is preferably between 25 degrees and 45 degrees, and the connecting position with the lead angle is formed to have a shape Arc lead angle. The electrolysis water device of claim 1, wherein the electrolysis cell further comprises an anode chamber and an oxygen output tube, the anode chamber comprising an anode electrode, an anode sealing plate, an anode conductive plate and an anode The pressure plate, when the electrolytic cell electrolyzes water, the anode chamber generates oxygen, the oxygen output tube is used for outputting the oxygen, and the oxygen output tube is penetrated through the anode outer pressure plate, the anode conductive plate and the anode sealing plate. The electrolysis water device of claim 3, wherein the electrolysis cell further comprises a cathode chamber and a hydrogen output tube, wherein the hydrogen output tube is for outputting the hydrogen gas, the cathode chamber package The cathode electrode, a cathode sealing plate and a cathode conductive plate, the hydrogen output tube penetrating through the anode outer pressure plate, the anode conductive plate, the anode sealing plate and the cathode sealing plate, wherein the oxygen and the hydrogen are in the electrolysis The same side of the slot is output. The electrolysis water device of claim 3, wherein the electrolysis cell further comprises a water supply pipe disposed through the anode outer pressure plate, the anode conductive plate and the anode sealing plate to communicate the anode The chamber and a water tank through which the water from the water tank flows into the anode chamber to supplement the water in the anode chamber. The electrolysis water device according to claim 5, further comprising a water level detecting device disposed outside the water tank for detecting the amount of water in the water tank. The electrolyzed water device of claim 1, further comprising a fan that draws the air from the environment outside the electrolyzed water device into the electrolyzed water device for the insufflation pump to draw in the air and Introduce into the air supply tube. The electrolyzed water device of claim 1, wherein the electrolyzed water device further comprises: a hydrogen concentration detector connected to the supplemental gas tube to detect whether the hydrogen gas concentration in the supplemental gas tube is between In the range, the range is composed of a first predetermined value and a second predetermined value. When the detected hydrogen volume concentration is higher than the first predetermined value, a first warning signal is generated; and a controller is The hydrogen concentration detector, the supplemental air pump and the electrolysis tank are coupled, and when the controller receives the first warning signal, a start command is generated to start the operation of the supplemental air pump. The electrolysis water device according to claim 8, wherein the hydrogen concentration detector detects When the hydrogen volume concentration is higher than a second predetermined value, a second warning signal is generated; and when the controller receives the second warning signal, a stop command is generated to stop the electrolytic cell from operating. The electrolyzed water device according to claim 9, wherein the first predetermined value is 4%, and the second predetermined value is 6%, and the range is 4% to 6%. The electrolysis water device according to claim 1, further comprising an atomization/volatile gas mixing tank connected to the gas supply pipe and receiving the diluted hydrogen gas, the atomization/volatile gas mixing tank selectively generating one An atomizing gas is mixed with the hydrogen to form a health care gas, wherein the atomizing gas is selected from one or a combination of a group consisting of water vapor, atomized syrup, and volatile essential oil. The electrolysis water device according to claim 1, further comprising a power supply; the power supply comprises a high power output end and a low power output end, wherein the low power output end outputs the electric power One or more of the electric power outputted by the power output end, wherein the high power output terminal outputs a first voltage and a first current, and the low power output terminal outputs a second voltage and a second current, the first voltage being less than the first The second voltage is greater than the second current. An electrolysis water device comprising: an operation panel; an electrolysis cell comprising a cathode electrode, the cathode electrode generates the hydrogen gas when the electrolysis cell electrolyzes water; and a supplemental gas pipe receives the hydrogen gas generated by the electrolysis cell; And a supplemental air pump, which absorbs air and is connected to the air supply pipe by a gas supply interface Connecting to dilute a hydrogen concentration in the gas supply pipe; wherein the volume of the electrolysis water device is less than 8.5 liters, and the hydrogen production rate of the electrolysis water device can be adjusted between 120 ml/min and 600 ml/min by the operation panel . The electrolyzed water device according to claim 13, wherein the electrolyzed water device further comprises a casing comprising a base and a side wall, the electrolytic cell being disposed at a non-center of the casing. The electrolysis water tank of claim 14, wherein the electrolysis tank further comprises a first side, a second side, an ion exchange membrane, an anode electrode, an oxygen outlet tube and a hydrogen outlet tube. The ion exchange membrane is disposed between the anode electrode and the cathode electrode. When the electrolysis cell electrolyzes water, the hydrogen output tube outputs the hydrogen gas, and the anode electrode generates oxygen and the oxygen is outputted by the oxygen output tube. One side is adjacent to the side wall, and the oxygen and the hydrogen are output from the second side of the electrolytic cell. The electrolysis water device of claim 15, wherein the anode electrode is interposed between the ion exchange membrane and the second side, the cathode electrode being interposed between the ion exchange membrane and the first side The oxygen output tube extends from the ion exchange membrane and the second side to the second side and extends through the second side, and the hydrogen output tube is between the ion exchange membrane and the first side The second side extends and extends through the second side. The electrolysis water device of claim 15, wherein the anode electrode is interposed between the ion exchange membrane and the first side, the cathode electrode being interposed between the ion exchange membrane and the second side The hydrogen output tube extends from the ion exchange membrane and the second side to the second side and extends through the second side, and the oxygen output tube is between the ion exchange membrane and the first side The second side extends and extends through the second side.