TW201615896A - A gas generator - Google Patents

Abstract

The invention provides a gas generator comprising an electrolysis device, cooling device and a pump. The electrolysis device is used for electrolyzing the electrolysis water to produce a gas mixture including hydrogen and oxygen. The gas generator of the invention can cool the electrolysis water for generating the gas mixture including hydrogen and oxygen through the cooling device and enforce to circulate the electrolysis water through the pump for heat dissipation. Meanwhile, the invention also can provide a temperature range of optimal electrolysis efficiency for electrolyzing the electrolysis water to produce a gas mixture including hydrogen and oxygen and solving the problem of energy consumption, wherein the temperature range is between 55 DEG C and 65 DEG C.

Description

Gas generator

The present invention relates to a gas generator, and more particularly to a gas generator having the effect of regulating the temperature of the electrolyzed water and cooling the electrolyzed water after the hydrogen-oxygen mixed gas is produced.

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. There are even clinical trials showing that for some long-term beds People, because of long-term breathing of high concentrations of oxygen, lung damage, can be inhaled by hydrogen to relieve the symptoms of lung injury.

Generally, hydrogen and oxygen are generated by the electrolyte water in the electrolytic cell. However, in the electrolyte state, the high temperature is easily generated, which causes the overall electrolysis efficiency to be lowered, resulting in a problem of energy consumption.

Therefore, one of the viewpoints of the present invention is to provide a gas generator having the effect of regulating the temperature of the electrolysis water and cooling the electrolyzed water after the production of the hydrogen-oxygen mixed gas, so that the electrolysis water temperature is in a temperature range providing optimum electrolysis efficiency, The problem of energy consumption is solved by effectively electrolyzing the electrolyzed water to produce a hydrogen-oxygen mixed gas.

The present invention provides a gas generator comprising an electrolysis device, a cooling device, and a water pump device. The electrolysis device houses an electrolyzed water. The electrolysis device is used to electrolyze water to produce a hydrogen-oxygen mixed gas. The cooling device is connected to the electrolysis device for cooling the electrolyzed water after generating the hydrogen-oxygen mixed gas. A water pump device is connected between the cooling device and the electrolysis device for forcibly circulating the electrolyzed water.

Furthermore, the gas generator of the present invention optionally further includes a microcomputer controller. The microcomputer controller is coupled to the water pump device for sensing the temperature of the electrolyzed water and controlling the flow rate of the pump device to be extracted and input according to the sensed temperature of the electrolyzed water.

The microcomputer controller optionally includes a temperature sensor. A temperature sensor is used to sense the temperature of the electrolyzed water.

The cooling device optionally includes a heat sink and a fan. The radiator comprises a box body and a heat pipe. The heat pipe is distributed inside the radiator case. The fan is fixed to the outer surface of the radiator.

Furthermore, the gas generator of the present invention optionally further comprises a water tank. The water tank has a first hollow portion. The first hollow portion of the water tank houses electrolyzed water. The electrolysis device is disposed within the first hollow portion of the water tank, wherein the first hollow portion and the electrolysis device are in communication with each other. The radiator is connected to the water tank, and the water pump device is connected between the radiator and the water tank.

The water tank optionally includes a water outlet and a water inlet, the radiator selectively including an inlet and an outlet. The inlet and the outlet of the radiator are connected to each other by a heat pipe. The water pump device optionally includes an inlet pipe and an outlet pipe. The water outlet of the water tank is connected to the inlet of the radiator, and the outlet of the radiator is connected with the water inlet pipe of the water pump device, and the water outlet of the water pump device is connected with the water inlet of the water tank.

Furthermore, the gas generator of the present invention optionally further comprises an atomizing/volatile gas mixing tank. The atomization/volatile gas mixing tank is coupled to the electrolysis device to receive the hydrogen-oxygen mixed gas. Wherein the atomization/volatile gas mixing tank generates an atomizing gas mixed with the hydrogen-oxygen mixed gas to form a health care gas for inhalation by the user, wherein the atomizing gas is selected from the group consisting of water vapor, atomized medicine, and volatile Essential oil and its combination, one of the ethnic groups formed.

In summary, the present invention is directed to a gas generator comprising an electrolysis device, a cooling device, and a water pump device. The gas generator of the present invention can cool the electrolyzed water after the hydrogen-oxygen mixed gas is generated by the cooling device, and the electrolyzed water is forcibly circulated by the water pump device to achieve the heat dissipation effect. At the same time, the present invention enables the temperature of the electrolyzed water to be in a temperature range that provides optimum electrolysis efficiency for effectively electrolyzing the electrolyzed water to produce a hydrogen-oxygen mixed gas to solve the problem of energy consumption.

The invention further provides a gas generator comprising an electrolysis device, a cooling device and a water pump device. The electrolysis device houses an electrolyzed water. Electrolytic device for electrolytically electrolyzing water for production A hydrogen-oxygen mixed gas is produced. The cooling device is connected to the electrolysis device for cooling the electrolyzed water after generating the hydrogen-oxygen mixed gas. A water pump device is connected between the cooling device and the electrolysis device for forcibly circulating the electrolyzed water. The temperature of the electrolyzed water contained in the electrolysis device is a conventional electrolysis temperature. The conventional electrolysis temperature range is between 55 ° C and 65 ° C.

Furthermore, the gas generator of the present invention optionally further includes a microcomputer controller. The microcomputer controller is coupled to the water pump device for sensing the temperature of the electrolyzed water and controlling the flow rate of the pump device to be extracted and input according to the sensed temperature of the electrolyzed water.

The cooling device optionally includes a heat sink and a fan. The radiator comprises a box body and a heat pipe. The heat pipe is distributed inside the radiator case. The fan is fixed to the outer surface of the radiator.

Furthermore, the gas generator of the present invention optionally further comprises a water tank. The water tank has a first hollow portion. The first hollow portion of the water tank houses electrolyzed water. The electrolysis device is disposed within the first hollow portion of the water tank, wherein the first hollow portion and the electrolysis device are in communication with each other. The radiator is connected to the water tank, and the water pump device is connected between the radiator and the water tank.

Furthermore, the gas generator of the present invention optionally further comprises an atomizing/volatile gas mixing tank. The atomization/volatile gas mixing tank is coupled to the electrolysis device to receive the hydrogen-oxygen mixed gas. Wherein the atomization/volatile gas mixing tank generates an atomizing gas mixed with the hydrogen-oxygen mixed gas to form a health care gas for inhalation by the user, wherein the atomizing gas is selected from the group consisting of water vapor, atomized medicine, and volatile Essential oil and its combination, one of the ethnic groups formed.

In summary, another focus of the present invention is to provide a gas generator comprising an electrolysis device, a cooling device, and a water pump device, wherein the temperature of the electrolyzed water contained in the electrolysis device is between 55 ° C and 65 ° C. The gas generator of the present invention can be cooled by a cooling device The electrolyzed water after the hydrogen and oxygen mixed gas is generated, and the electrolyzed water is forced to be circulated by the water pump device to achieve the heat dissipation effect. At the same time, the present invention enables the electrolyzed water temperature to be in a temperature range (between 55 ° C and 65 ° C) which provides optimum electrolysis efficiency for effectively electrolyzing electrolyzed water to produce a hydrogen-oxygen mixed gas to solve the problem of energy consumption.

W‧‧‧electrolyzed water

W2‧‧‧Supply water

G‧‧‧Hydrogen-oxygen mixed gas

G2‧‧‧ atomizing gas

H‧‧‧hydrogen water

1‧‧‧ gas generator

2‧‧‧Water tank

20‧‧‧The first hollow

200‧‧‧ upper

202‧‧‧ lower

22‧‧‧ catheter

24‧‧‧Water tank

240‧‧‧First base

242‧‧‧First wall

244‧‧‧ first opening

246‧‧‧First chimeric structure

248‧‧‧First side edge

249a‧‧‧Water outlet

249b‧‧‧ water inlet

26‧‧‧Water tank cover

260‧‧‧Second base

261‧‧‧ Cover Hole

262‧‧‧ Second wall

264‧‧‧Second hollow

266‧‧‧second opening

28‧‧‧ Seal

280‧‧‧ third opening

282‧‧‧ Third chimeric structure

3‧‧‧Electrolytic device

30‧‧‧Baffle

300‧‧‧Connected holes

32‧‧‧ Electrolytic tank body

320‧‧‧fourth base

3202‧‧‧ underperture

3204‧‧‧ Groove

322‧‧‧Fourth wall

3220‧‧‧Fixed column

324‧‧‧Fourth hollow

326‧‧‧fourth opening

33‧‧‧electrode column

34‧‧‧Multiple electrodes

340‧‧‧ cathode film

342‧‧‧Anode film

344‧‧‧Bipolar electrode sheets

36‧‧‧ pads

360‧‧‧perforation

37‧‧‧Upper cover

370‧‧‧First runner

38‧‧‧ Lower cover

380‧‧‧Second runner

4‧‧‧Atomizing/volatile gas mixing tank

5‧‧‧Water pump device

50‧‧‧water inlet

52‧‧‧Outlet

6‧‧‧Condensation filter

60‧‧‧Inlet holes

600‧‧‧Filter

602‧‧‧Filter cover

62‧‧‧ Vents

64‧‧‧Condensation film

640a‧‧‧ runner

640‧‧‧Circular runner

7‧‧‧Cooling device

70‧‧‧heatsink

700‧‧‧ cabinet

702‧‧‧heat pipe

704‧‧‧ entrance

706‧‧‧Export

72‧‧‧fan

82‧‧‧Flow detector

9‧‧‧Humidification unit

90‧‧‧ hollow body

92‧‧‧Second catheter

94‧‧‧Output tube

95‧‧‧ oscillating device

96‧‧‧ third catheter

98‧‧‧4th catheter

1A and 1B are schematic views showing different angles of view of the gas generator of the present invention in the first embodiment.

FIG. 2A and FIG. 2B are schematic diagrams showing different viewing angles of the water tank upper cover and the electrolysis device combination in the embodiment shown in FIG.

FIG. 3A and FIG. 3B are schematic diagrams showing different viewing angles of the embodiment shown in FIG. 1A with only the combination of the electrolysis device and the water tank.

4A and 4B are exploded views showing different angles of view of the electrolysis apparatus of the gas generator of the present invention in the embodiment shown in FIG.

5A and 5B are a plan view showing the embodiment of the water tank body and the electrolysis device of the gas generator of the present invention in the embodiment shown in FIG. 3A and a cross-sectional view taken along line A-A of the plan view.

Fig. 6 is a schematic view showing different viewing angles of the embodiment shown in Fig. A with only the electrolytic cell body, the separator and the electrode combination.

7A and 7B are a plan view showing the embodiment of the water tank body and the electrolysis device of the gas generator of the present invention in the embodiment shown in FIG. 3A and a cross-sectional view taken along line B-B of the plan view.

Figure 8 is a diagram showing the gas generator of the present invention in a second embodiment intention.

9A and 9B are schematic views showing different angles of view of the gas generator of the present invention in the tenth embodiment.

FIG. 10A and FIG. 10B are schematic diagrams showing different viewing angles when only the condensing filter and the water tank cover are combined in the embodiment shown in FIG. 9A.

Figure 11 is a schematic view showing the embodiment of Figure 10A without the water tank cover.

Figure 12 is a schematic view showing the embodiment of Figure 11 without a filter.

Figure 13 is a schematic view showing the embodiment of Figure 12 without the filter cover.

14A and FIG. 14B are plan views showing the condensing filter of the gas generator of the present invention in the embodiment shown in FIG. 10A and a cross-sectional view taken along line C-C of the plan view.

Figures 15A and 15B are schematic views showing different angles of view of the gas generator of the present invention in the fourteenth embodiment.

Figure 16 is a schematic view showing only the humidifying device in the embodiment shown in Figure 15A.

Figure 17 is a schematic view showing the gas generator of the present invention in a fifth embodiment.

18A and 18B are schematic views showing different angles of view of the gas generator of the present invention in the fifteenth embodiment.

Figure 19 is a diagram showing the gas generator of the present invention implemented as shown in Figure 18A. The latter view in the example.

20A and 20B are plan views showing only a condensing filter and a water tank cover in the embodiment shown in FIG. 18A, and a cross-sectional view taken along line D-D of the plan view.

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 invention or the corresponding embodiments.

First, the present invention proposes a gas generator which is an explosion-proof gas generator. Please refer to FIG. 1A, FIG. 1B, FIG. 2A and FIG. 2B. FIG. 1A and FIG. 1B are schematic diagrams showing different angles of view of the gas generator of the present invention in the first embodiment, FIG. 2B is a schematic view showing different viewing angles of the water tank upper cover and the electrolysis device in the embodiment shown in FIG. A. As shown in the figure, in the first embodiment, the gas generator 1 of the present invention includes a water tank 2 And an electrolysis device 3. The water tank 2 houses an electrolyzed water W, and the electrolysis device 3 is disposed in the water tank 2 for electrolyzing the electrolyzed water W to generate a hydrogen-oxygen mixed gas G. When the electrolysis device 3 starts to electrolyze the electrolysis water W, the electrolyzed water W is filled in the water tank 2 and the electrolysis device 3 to be at a full water level, and after the electrolysis device 3 electrolyzes the electrolysis water W, the electrolyzed water W fills the water tank 2 and the electrolysis device 3 The water level is higher than 90% of the full water level. The design of each component of the present invention will be separately described below.

First, the water tank 2 used in the present invention has a first hollow portion 20 and a duct 22. The first hollow portion 20 of the water tank 2 is adapted to accommodate an electrolyzed water W. The main component of electrolyzed water W is Pure water, if necessary, can add a small amount of electrolytes, such as sodium hydroxide, calcium carbonate, sodium chloride and the like. The duct 22 of the water tank 2 and the first hollow portion 20 of the water tank 2 are in communication with each other for outputting the hydrogen-oxygen mixed gas G generated by the electrolysis device 3 and replenishing the electrolyzed water W into the water tank 2.

Further, please refer to FIG. 3A and FIG. 3B. FIG. 3A and FIG. 3B are exploded views showing different angles of view of the water tank of the gas generator of the present invention in the specific embodiment shown in FIG. In the embodiment, the water tank 2 further includes a water tank body 24 and a water tank cover 26.

The water tank body 24 is roughly divided into a first base 240 and a first wall portion 242. The first wall portion 242 extends outward from the inner surface of the first base 240 toward the normal vector direction, and the first wall portion 242 is surrounded by the first hollow portion 20, the first hollow portion 20 is opposite to the first portion The other end of the base 240 has a first opening portion 244. At the same time, the first wall portion 242 has a first side edge 248 opposite to the other side of the first base 240, and the first side edge 248 surrounds the first opening portion 244. Further, the water tank body 24 of the water tank 2 further includes a water outlet 249a and a water inlet 249b. In the present embodiment, the water outlet 249a of the water tank body 24 communicates with the two surfaces of the first wall portion 242 of the water tank body 24 in the direction of the electrolysis device 3, and the water inlet 249b of the water tank body 24 communicates with the water tank body. The first wall portion 242 of 24 is opposite to the two surfaces of the electrolysis device 3. The water outlet 249a of the water tank body 24 and the water inlet 249b of the water tank body 24 communicate with each other through the first hollow portion 20. The water outlet 249a and a water inlet 249b of the water tank body 24 are used to allow a water pump device to communicate with the first hollow portion 20 of the water tank 2.

The water tank cover 26 is roughly divided into a second base 260 and a second wall portion 262. The second wall portion 262 extends outwardly from the inner surface of the second base 260 toward the normal vector direction, and the second wall portion 262 is surrounded by a second hollow portion 264, and the second hollow portion 264 is opposite to the second base portion. The other end of the 260 has a second opening 266. The water tank cover 26 has water through the second opening portion 266 The first side edge 248 of the tank body 24 is covered in the second hollow portion 264. The conduit 22 is disposed on the second base 260 of the water tank cover 26 and communicates with the two surfaces of the second base 260 of the water tank cover 26 in the direction of the water tank body 24, but not limited thereto. In practical applications, the conduit 22 may also be replaced by a via or other component having an output/input function. The water tank cover 26 further includes a plurality of cover holes (as shown in FIG. 10A), and the plurality of cover holes communicate with the two surfaces of the second base 260 of the water tank cover 26 in the direction of the water tank body 24 for supplying power to the device. The electrode column of 3 is penetrated and disposed in the electrolysis device 3, or is used for a detection device (such as a flow detector, a water level gauge, a safety valve) to be penetrated and disposed thereon.

Further, in the embodiment, the water tank 2 further includes a gasket 28 disposed between the water tank body 24 and the water tank cover 26 for tightly coupling the water tank body 24 and the water tank cover 26. The gasket 28 has a third opening portion 280. When the gasket 28 is disposed between the water tank body 24 and the water tank cover 26, the third opening portion 280 of the gasket 28 encloses the plurality of cover holes 261 and the second opening portion 266 therein. The corresponding surfaces of the water tank body 24 and the gasket 28 respectively have a first fitting structure 246 and a corresponding third fitting structure 282 and the two are fitted to each other. The first fitting structure 246 encloses the first opening portion 244 therein. The third fitting structure 282 surrounds the third opening portion 280 therein.

Next, please refer to FIG. 4A and FIG. 4B. FIG. 4A and FIG. 4B are exploded views showing different angles of view of the electrolysis apparatus of the gas generator of the present invention in the embodiment shown in FIG. The electrolysis device 3 includes an electrolytic cell body 32, a plurality of electrodes 34, a backing plate 36, an upper cover 37, and a lower cover 38. A plurality of electrodes 34 are respectively disposed in the electrolytic cell body 32 at intervals and form a plurality of electrode flow paths S1. A backing plate 36 is provided on the upper surface of each of the electrodes 34. The upper cover 37 is disposed on the other end of the backing plate 36 with respect to the electrolytic cell body 32. The lower cover 38 is disposed on the lower surface of the electrolytic cell body 32 opposite to the other end of the upper cover 37.

Further, please refer to FIG. 5A and FIG. 5B. FIG. 5A and FIG. 5B are plan views showing the embodiment of the embodiment of the water tank body and the electrolysis device of the gas generator of the present invention shown in FIG. And a cross-sectional view taken along line AA of the top view. The electrolysis unit additionally has a separator 30. The partition 30 extends from the side surface of the electrolytic tank body toward the normal vector direction with respect to the side surface of the water tank 2, and partitions the first hollow portion 20 of the water tank 2 into an upper portion 200 and a lower portion 202. The partition 30 includes a communication hole 300. The communication hole 300 communicates with the two surfaces of the partition plate 30 with respect to the first base 240 of the water tank body 24. The upper portion 200 and the lower portion 202 of the first hollow portion 20 are in communication with each other by a communication hole. However, the design of the communication hole is not limited to the description of the present embodiment. In practical applications, the number or shape of the communication holes may be selected according to the actual needs of the use.

Next, please refer to FIG. 6. FIG. 6 is a schematic view of different viewing angles of the embodiment shown in FIG. 1A with only the electrolytic cell body, the separator and the electrode combination. The electrolytic cell body 32 is roughly divided into a fourth base 320 and a fourth wall portion 322. The fourth wall portion 322 extends outward from the inner surface of the fourth base 320 in the direction of the normal vector, and the fourth wall portion 322 is surrounded by the fourth hollow portion 324, and the fourth hollow portion 324 is opposite to the fourth portion. The other end of the base 320 has a fourth opening portion 326. The fourth hollow portion 324 is adapted to accommodate the electrolyzed water W. In addition, in order to express the design of the electrolytic cell body of the present invention, a plurality of electrodes are deliberately omitted in FIG. 6, however, in practical applications, the design is selected according to actual needs.

Next, please refer to FIG. 5A, FIG. 5B, FIG. 6 , FIG. 7A and FIG. 7B. FIG. 7A and FIG. 7B show the water tank body and the electrolysis device of the gas generator of the present invention in FIG. 3A. A plan view of the embodiment shown in the drawings and a cross-sectional view taken along line BB of the plan view. In the present embodiment, the lower surface of the electrolytic cell body 32 is the fourth base 320 of the electrolytic cell body 32. The fourth base 320 of the electrolytic cell body 32 has a plurality of lower perforations 3202. a plurality of lower perforations 3202 communicate with the fourth base of the electrolytic cell body 32 320 is opposite the two surfaces of the first base 240 of the water tank body 24. The fourth base 320 of the electrolytic cell body 32 further has a plurality of grooves 3204. A plurality of grooves 3204 extend from the surface of the fourth base 320 of the electrolytic cell body 32 in the direction of the normal vector with respect to the surface of the fourth opening portion 326. Each groove 3204 is spaced between the lower perforation 3202 and the adjacent lower perforation 3202. A plurality of grooves 3204 are provided for placing the electrodes 34. At the same time, the fourth wall portion 322 of the electrolytic cell body 32 further has a plurality of fixing posts 3220. A plurality of fixing posts 3220 are formed from the fourth wall portion 322 with respect to the surface of the plurality of lower perforations 3202 extending outward in the direction of the normal vector. The fixing post 3220 and the adjacent fixing post 3220 are used to fix the electrode 34 placed on the recess 3204. When a plurality of electrodes 34 are respectively disposed in the recess 3204 of the electrolytic cell body 32 and fixed between the fixing post 3220 and the adjacent fixing post 3220, a plurality of electrode flow paths S1 are formed in the electrolytic cell body 32. Each of the electrode flow paths S1 is independently connected to the lower portion 202 of the first hollow portion 20 by the corresponding lower perforations 3202.

The backing plate 36 has a plurality of upper perforations 360. A plurality of upper perforations 360 are connected to the two surfaces of the pad 36 in the direction of the electrolytic cell 32. Further, each of the electrode flow channels S1 is also independently connected to the upper portion 200 of the first hollow portion 20 by the corresponding upper through holes 360.

The plurality of electrodes 34 includes a cathode sheet 340, an anode sheet 342, and a plurality of bipolar electrode sheets 344. A plurality of bipolar electrode sheets 344 are spaced apart between the cathode sheet 340 and the anode sheet 342. In the present embodiment, the electrolysis device 3 further includes two electrode columns 33 for individually locking the anode piece 342 and the cathode piece 340 on the water tank cover 26 to fix the electrolysis device 3 in the water tank 2 in a suspended manner. Further, in the embodiment, the gas generator 1 further includes a power source (not shown). The cathode piece 340 is connected to the negative electrode of the power source, and the anode piece 342 is connected to the positive electrode of the power source.

The upper cover 37 includes at least one first flow path 370. As shown in FIG. 4B, the first flow path 370 is formed inwardly from the upper cover body 37 with respect to the surface of the backing plate 36 in the normal vector direction. lie in The plurality of upper perforations 360 of the backing plate 36 and the first hollow portion 20 are in communication with each other by the at least one first flow path 370.

The lower cover 38 includes at least one second flow path 380. As shown in FIG. 4A, the second flow path 380 is formed inwardly from the lower cover 38 with respect to the surface of the fourth base 320 of the electrolytic cell 32 in the direction of the normal vector. A plurality of lower perforations 3202 located at the fourth base 320 of the electrolytic cell body 32 and the first hollow portion 20 are in communication with each other by the at least one second flow path 380.

Further, please refer to FIG. 8 , which is a schematic diagram of the gas generator of the present invention in a second embodiment. In a second embodiment, the gas generator 1 of the present invention further comprises a water pump device 5 (shown only in phantom in Figure 8). The water pump device 5 is used to forcibly circulate the electrolyzed water W accommodated in the first hollow portion 20 and the electrolysis device 3. The water pump device 5 includes an inlet pipe 50 and an outlet pipe 52. The water outlet pipe 52 of the water pump device 5 is used to connect the water supply pump device 5 to the water inlet 249b of the water tank 2. The water inlet pipe 50 of the water pump device 5 is used to connect the water supply pump device 5 to the water outlet 249a of the water tank 2.

Further, in the third embodiment, the gas generator 1 of the present invention further comprises an atomizing/volatile gas mixing tank 4 (as shown in Fig. 15A). The atomizing/volatile gas mixing tank 4 is connected to the electrolysis device 3 for receiving the hydrogen-oxygen mixed gas G. The atomizing/volatile gas mixing tank 4 can generate an atomizing gas G2 mixed with the hydrogen-oxygen mixed gas G to form a health care gas for inhalation by the user. In practical applications, the atomizing gas G2 is selected from the group consisting of water vapor, atomized syrup, volatile essential oil, and combinations thereof.

In the above, after the individual design of each component is described, the combination of the components of a gas generator and its application will be described below.

In the assembled electrolysis device 3, a plurality of electrodes 34 are respectively disposed at intervals The electrolytic cell body 32, the backing plate 36 is disposed on the upper surface of each of the electrodes 34, the upper cover body 37 is disposed on the other end of the backing plate 36 with respect to the electrolytic cell body 32, and the lower cover body 38 is disposed under the electrolytic cell body 32. The surface is opposite to the other end of the upper cover 37.

In the assembled water tank 2 and the electrolysis device 3, the anode piece 342 and the cathode piece 340 of the assembled electrolysis device 3 are respectively locked to the tank cover 26 by the two electrode columns 33. The detecting device (such as the flow detector 82) is inserted through the plurality of cover holes 261 of the tank cover 26 and disposed on the tank cover 26. The gasket 28 is disposed in the water tank body 24 and is fitted to each other by the third fitting structure 282 of the gasket 28 and the first fitting structure 246 of the water tank body 24. The first side edge 248 of the water tank body 24 is covered in the second hollow portion 264 of the water tank cover 26 by the second opening portion 266 of the water tank cover 26 to close the water tank body 24 and the water tank cover 26. In combination, the electrolysis device 3 is suspended in the water tank 2 in a suspended manner. The first hollow portion 20 of the water tank 2 and the electrolysis device 3 are in communication with each other.

Next, in the assembled water tank 2, the electrolysis device 3, and the water pump device 5, the water tank 2 and the water pump device 5 are connected by the water outlet pipe 52 of the water pump device 5 and the water inlet 249a of the water tank 5, and the water inlet pipe of the water pump device 5. 50 is connected to the water outlet 249a of the water tank 5 to communicate with each other. Further, in the third embodiment, the atomizing/volatile gas mixing tank 4 is connected to the electrolysis device 3.

In practical application, the water tank 2 houses an electrolyzed water W, and the electrolysis device 3 is disposed in the water tank 2 for electrolyzing the electrolyzed water W to generate a hydrogen-oxygen mixed gas G. The hydrogen-oxygen mixed gas G generated in the electrode flow path S1 is input to the first hollow portion 20 via the perforation 360 above the corresponding pad 36 and the first flow path 370 of the corresponding upper cover 37. The hydrogen-oxygen mixed gas G input to the first hollow portion 20 is further outputted through the conduit 22 of the water tank 2, and is for the user to inhale, but not limited thereto, and is input to the first hollow portion 20 in practical use. The hydrogen-oxygen mixed gas G can be further mixed with the atomizing gas G2 generated through the atomizing/volatile gas mixing tank 4 to form a health gas for the user to suck In.

Further, when the electrolysis device 3 suspends the electrolytic electrolysis water W to generate the hydrogen-oxygen mixed gas G, the conduit 22 can be used to supplement the input electrolysis water W so that the electrolyzed water W fills the first hollow portion 20 and the electrolysis device 3. The electrolyzed water W added to the first hollow portion 20 is input to the corresponding electrode flow path S1 via the second flow path 380 of the lower cover 38 of the electrolysis device 3 and a plurality of lower perforations 3202 to provide electrolysis device 3 during electrolysis. The required electrolyzed water W. Here, when the electrolysis device 3 starts to electrolyze the electrolysis water W, the electrolyzed water W is filled in the water tank 2 and the electrolysis device 3 to be in a full water level. When the electrolysis device 3 electrolyzes the electrolyzed water W, the water level of the electrolyzed water W filling the water tank 2 and the electrolysis device 3 is still higher than 90% of the full water level. In practice, the gas generator of the present invention detects the water level contained in the first hollow portion of the water tank and the electrolysis device by a water level gauge to control the replenishment of the electrolyzed water, so that the electrolyzed water fills the first hollow of the water tank. The water level of the unit and the electrolyzer is between 90% and 99.99% of the full water level. Therefore, the gas generator of the present invention is designed to prevent the air chamber from being present in the water tank, and the temperature of the electrolysis device can be lowered, thereby reducing the risk of high temperature gas explosion and improving its safety.

Further, the first hollow portion 20 of the water tank 2 is further in communication with the water pump device 5. The water pump device 5 can be used to forcibly circulate the electrolyzed water W accommodated in the first hollow portion 20 and the electrolysis device 3. The electrolyzed water located at the upper portion 200 and the lower portion 202 of the first hollow portion 20 is circulated through the communication hole 300. Wherein, when the electrolysis device electrolyzes the electrolyzed water W, the water level of the first hollow portion 20 of the electrolysis water W filling the water tank 2 and the electrolysis device 3 is between 90% and 99.99% of the full water level. Furthermore, the gas generator of the present invention is designed to positively circulate the electrolyzed water contained in the first hollow portion and the electrolysis device, so that the gas chamber in the water tank approaches zero to avoid the pressure of hydrogen and oxygen in the water tank. Or the amount of storage, causing a gas explosion.

In addition, the flow detector 82 is coupled to the electrolysis device 3 to detect the hydrogen-oxygen mixed gas. The flow rate of G, and thereby controlling the output of the hydrogen-oxygen mixed gas G in the electrolysis device 3. The flow detector 82 can selectively cut off the electrical connection between the electrolysis device 3 and a power source (not shown).

In summary, the design of the electrolysis device in the water tank of the present invention can save space, and the hydrogen-oxygen mixed gas generated by the electrolysis device can avoid the existence of the gas cavity by filling the first hollow portion of the water tank and the electrolyzed water of the electrolysis device. In the water tank, the temperature of the electrolysis device can also be lowered to prevent the occurrence of gas explosion. Furthermore, the gas outlet and the water inlet of the electrolysis device of the present invention are designed such that the electrolyzed water in the water tank can be replenished to the electrolysis device, and the hydrogen-oxygen mixed gas generated by the electrolysis device can be discharged to the water tank to achieve a gas-water cycle. Further, in the present invention, the water pump device, the water tank and the electrolysis device are connected to each other in a structural design, so that the electrolyzed water accommodated in the first hollow portion and the electrolysis device can be forcibly circulated, so that the gas chamber in the water tank approaches Zero to prevent the occurrence of gas explosion.

Please refer to Figure 17. In a fourth embodiment, the present invention further provides a gas generator which is a gas generator having the effect of regulating the temperature of the electrolyzed water and cooling the electrolyzed water after the hydrogen-oxygen mixed gas is produced. In the present embodiment, the gas generator 1 includes an electrolysis device (not shown), a water pump device 5, and a cooling device 7. The electrolysis device 3 houses an electrolyzed water W. The electrolysis device 3 is for electrolytically electrolyzing water W to produce a hydrogen-oxygen mixed gas G. The cooling device 7 is connected to the electrolysis device 3 for cooling the electrolyzed water W after the generation of the hydrogen-oxygen mixed gas G. The water pump device 5 is connected between the cooling device 7 and the electrolysis device 3 for forcibly circulating the electrolyzed water W.

Referring to FIG. 17, FIG. 17 is a schematic view showing the gas generator of the present invention in a fifth embodiment. In a fifth embodiment, the gas generator 1 of the present invention further comprises a water tank 2. The water tank 2 has a first hollow portion 20 and a duct 22 (shown only in phantom in Figure 17). The first hollow portion 20 of the water tank 2 houses the electrolyzed water W. The electrolysis device 3 is disposed in the first of the water tank 2 Within the hollow portion 20, the first hollow portion 20 and the electrolysis device 3 are in communication with each other.

Further, in the sixth embodiment, the gas generator 1 of the present invention further comprises an atomizing/volatile gas mixing tank 4 (as shown in Fig. 15A). The atomizing/volatile gas mixing tank 4 can generate an atomizing gas G2 mixed with the hydrogen-oxygen mixed gas G to form a health gas for inhalation by the user.

The design of each component of the present invention will be separately described below.

First, since the structural design of the water tank 2, the electrolysis device 3, the water pump device 5, and the atomization/volatile gas mixing tank 4 has been described above, it will not be described again.

Please refer to Figure 15A, Figure 15B and Figure 17. In the fourth embodiment, the cooling device 7 of the present invention comprises a heat sink 70 and a fan 72. The heat sink 70 includes a case 700 and a heat pipe 702. The heat pipe 702 is distributed within the casing 700 of the heat sink 70. The shape of the heat pipe 702 is a serpentine tube (not shown in the figure), which is used to increase the overall heat dissipation area and improve the heat dissipation efficiency. However, the shape of the heat pipe 702 is not limited to this shape, and may be a spiral disk in practical applications. tube. In addition, in practical applications, the heat pipe 702 is made of one of the above materials of silver, aluminum, iron, copper, silver alloy, aluminum alloy, iron alloy, and copper alloy. Further, the heat sink 70 includes an inlet 704 and an outlet 706. The inlet 704 of the radiator 70 is connected to the two surfaces of the casing 700 of the radiator 70 in the direction of the heat pipe 702, and the outlet 706 of the radiator 70 is connected to the casing 700 of the radiator 70 with respect to the direction of the heat pipe 702. Two surfaces. The inlet 704 and the outlet 706 of the heat sink 70 are connected to each other by the heat pipe 702.

Further, in the fourth embodiment, the gas generator 1 of the present invention further comprises a microcomputer controller (not shown). The microcomputer controller is for sensing the temperature of the electrolyzed water W and controlling the flow rate of the pumping device 5 to be extracted and input according to the sensed temperature of the electrolyzed water W. In addition, the microcomputer controller includes a temperature sensor (not shown). The temperature sensor is for sensing the temperature of the electrolyzed water W accommodated in the electrolysis device 3. In addition, the microcomputer controller further includes a traffic detector 82. The flow rate detector 82 is configured to detect the flow rate of the hydrogen-oxygen mixed gas G, and thereby control the output amount of the hydrogen-oxygen mixed gas G in the electrolysis device 3. The flow detector 82 can selectively cut off the electrical connection of the electrolysis device 3 to the power source (not shown).

In the above, after the individual design of each component is described, the combination of each component and its application will be described below.

In the assembled water tank 2 and the electrolysis device 3, the assembled electrolytic device 3 is placed in the first hollow portion 20 of the water tank 2, wherein the first hollow portion 20 of the water tank 2 and the electrolysis device 3 are in communication with each other. In addition, since the combination of the assembled water tank 2 and the electrolysis device 3 has been described above, it will not be described again.

In the assembled water tank 2, the electrolysis device 3, the water pump device 5, and the cooling device 7, the first hollow portion 20 of the water tank 2 and the electrolysis device 3 are in communication with each other (not shown), and the cooling device 7 is connected to The water tank 2 and the water pump device 5 are connected between the radiator 7 and the water tank 2, but not limited thereto. In practical applications, the radiator 70 is directly connected to the electrolysis device 3, and the water pump device 5 is directly connected to the radiator. 7 and the water tank 2, that is, the gas generator of the present invention does not require the water tank 2, or the gas generator of the present invention can be completed without providing the electrolysis device 3 in the water tank 2.

Next, the connection relationship between the assembled water tank 2, the electrolysis device 3, the water pump device 5, and the cooling device 7 will be further described. Please refer to Figure 15A and Figure 15B. The water outlet 249a of the water tank 2 provided with the electrolysis device 3 is connected to the inlet 704 of the radiator 70 of the cooling device 7, and the outlet 706 of the radiator 70 of the cooling device 7 is connected to the water inlet pipe 50 of the water pump device 5, and the water pump The water outlet pipe 52 of the device 5 is connected to the water inlet 249b of the water tank 2. But not above The connection relationship is limited. In practical applications, the water outlet 249a of the water tank 2 provided with the electrolysis device 3 is connected to the water inlet pipe 50 of the water pump device 5, and the water outlet pipe 52 of the water pump device 5 is cooled by the cooling device 7. The inlets 704 of the heaters 70 are connected to each other, and the outlet 706 of the radiator 70 of the cooling device 7 is connected to the water inlet 249b of the water tank 2.

In practical application, the water tank 2 houses an electrolyzed water W, and the electrolysis device 3 is disposed in the water tank 2 for electrolytically electrolyzing the water W to generate a hydrogen-oxygen mixed gas G. The hydrogen-oxygen mixed gas G generated in the electrode flow path S1 is input to the first hollow portion 20 via the perforation 360 above the corresponding pad 36 and the first flow path 370 of the corresponding upper cover 37. The hydrogen-oxygen mixed gas G input to the first hollow portion 20 is further outputted through the conduit 22 of the water tank 2, and is for the user to inhale, but not limited thereto, and is output by the first hollow portion 20 in practical use. The hydrogen-oxygen mixed gas G can be further mixed with the atomizing gas G2 generated via the atomizing/volatile gas mixing tank 4 to form a health care gas for the user to inhale.

Further, when the electrolysis device 3 suspends the electrolytic electrolysis water W to generate the hydrogen-oxygen mixed gas G, the conduit 22 can be used to supplement the input electrolysis water W so that the electrolyzed water W fills the first hollow portion 20 and the electrolysis device 3. The electrolyzed water W added to the first hollow portion 20 is input to the corresponding electrode flow path S1 via the second flow path 380 of the lower cover 38 of the electrolysis device 3 and a plurality of lower perforations 3202 to provide electrolysis device 3 during electrolysis. The required electrolyzed water W.

Further, the water tank 2, the electrolysis device 3, the water pump device 5, and the cooling device 7 are in communication with each other. When applied, the electrolyzed water W after the hydrogen-oxygen mixed gas G is generated by the water pump device 5 from the water outlet 249a of the water tank 2 to the inlet 704 of the radiator 70 of the cooling device 7, and the heat pipe of the radiator 70 Cooling is performed within 702. The cooled electrolyzed water W is forcibly outputted to the inlet pipe 50 of the water pump device 5 via the outlet 706 of the radiator 70 by the water pump device 5, and further, the electrolyzed water W is obtained. The water pump device 5 is forcibly input to the water inlet 249b of the water tank 2 via the water outlet pipe 52 of the water pump device 5. Therefore, the gas generator of the present invention can cool the electrolyzed water after the hydrogen-oxygen mixed gas is generated by the cooling device, and the electrolyzed water is forcibly circulated by the water pump device to achieve the heat dissipation effect. Wherein, the temperature of the electrolyzed water accommodated in the electrolysis device is a conventional electrolysis temperature, and in actual application, the temperature of the electrolyzed water W accommodated in the electrolysis device 3 is between 55 ° C and 65 ° C.

Further, the microcomputer controller 8 is coupled to the water pump device 5 for sensing the temperature of the electrolyzed water W, and controlling the flow rate of the pumping device 5 to be extracted and input according to the sensed temperature of the electrolyzed water W. In practical application, when the temperature of the electrolyzed water W sensed via the temperature sensor 80 is higher than a preset temperature, the information of the excessive temperature is transmitted back to the microcomputer controller 8, and the microcomputer controller 8 further The water pump device 5 is controlled to accelerate the flow rate of the electrolysis water W cycle, and the temperature of the electrolyzed water is lowered to return to the preset temperature. Conversely, when the temperature of the electrolyzed water W sensed via the temperature sensor 80 is lower than a predetermined temperature, the information that the temperature is too low is transmitted back to the microcomputer controller 8, and the microcomputer controller 8 further controls the water pump. The device 5 slows the flow rate of the electrolyzed water W cycle to raise the temperature of the electrolyzed water to return to the preset temperature. The preset temperature is the temperature that provides the best electrolysis efficiency. In this embodiment, the preset temperature is a conventional electrolysis temperature. In practice, the conventional electrolysis temperature range is between 55 ° C and 65 ° C.

In summary, the present invention is directed to a gas generator comprising an electrolysis device, a cooling device, and a water pump device. The gas generator of the present invention can cool the electrolyzed water after the hydrogen-oxygen mixed gas is generated by the cooling device, and the circulating electrolyzed water is forced by the water pump device to achieve the heat dissipation effect. At the same time, the present invention enables the electrolyzed water temperature to be within a temperature range that provides optimum electrolysis efficiency for effectively electrolyzing the electrolyzed water to produce a hydrogen-oxygen mixed gas to solve the problem of energy consumption.

Please refer to Figure 9A and Figure 9B. The invention further provides a gas generator which is a gas generator having a filtering function. In a seventh embodiment, the gas generator 1 comprises an electrolysis unit 3 and a condensing filter 6. The electrolysis device 3 houses an electrolyzed water W (not shown). The electrolysis device 3 is for electrolytically electrolyzing water W to produce a hydrogen-oxygen mixed gas G. The condensing filter 6 is connected to the electrolysis device 3 for condensing the hydrogen-oxygen mixed gas G while filtering one of the impurities in the hydrogen-oxygen mixed gas G. When the electrolysis device 3 suspends the electrolytic electrolysis water W to generate the hydrogen-oxygen mixed gas G, the condensing filter 6 can be used to input a supplementary water W2 (not shown), and the impurities can be condensed by the supplementary water W2. The filter 6 is backflushed to the electrolysis device 3.

Further, in the eighth embodiment, the gas generator 1 of the present invention further comprises a water tank 2. The water tank 2 has a first hollow portion 20. The first hollow portion 20 of the water tank 2 houses the electrolyzed water W. The electrolysis device 3 is disposed inside the first hollow portion 20 of the water tank 2, and the first hollow portion 20 and the electrolysis device 3 are in communication with each other.

Further, in the ninth embodiment, the gas generator 1 of the present invention further comprises an atomizing/volatile gas mixing tank 4 (as shown in Fig. 15A). The atomizing/volatile gas mixing tank 4 can be used to receive the filtered hydrogen-oxygen mixed gas G. The atomizing/volatile gas mixing tank 4 can generate an atomizing gas G2 mixed with the filtered hydrogen-oxygen mixed gas G to form a health gas for inhalation by the user.

Please refer to FIG. 9A and FIG. 9B. FIG. 9A and FIG. 9B are schematic diagrams showing different angles of view of the gas generator of the present invention in the tenth embodiment. In a tenth embodiment, the gas generator 1 of the present invention further comprises a water pump device 5 and a cooling device 7.

The design of each component of the present invention will be separately described below.

First, since the structural design of the water tank 2, the electrolysis device 3, and the atomization/volatile gas mixing tank 4 has been described above, it will not be described again.

Please refer to Figure 10A, Figure 10B, Figure 11, Figure 12, Figure 13, Figure 14A and Figure 14B. The condensing filter 6 of the present invention has an air inlet 60 and an air outlet 62. The air inlet 60 is connected to the electrolysis device 3 for receiving the hydrogen-oxygen mixed gas. The air outlet 62 serves to discharge the filtered hydrogen-oxygen mixed gas G. Further, the condensing filter 6 of the present invention comprises a plurality of condensing sheets 64. Each of the condensing fins 64 has a flow path 640, and the flow path 640a of the condensing sheet 64 communicates with the flow path 640a of the adjacent condensing sheet 64 to form a circulation flow path 640 through which the hydrogen-oxygen mixed gas G flows for condensation. Hydrogen-oxygen mixed gas G. The air inlet 60 and the air outlet 62 are connected to each other by the circulation flow path 640. Further, an active carbon fiber is disposed in the flow path 640a for filtering impurities in the hydrogen-oxygen mixed gas G. The flow path 640a is further provided with any filter material composed of ceramic, quartz stone, diatomaceous earth, sepiolite or a combination of the above, and the filter material can further filter impurities in the hydrogen-oxygen mixed gas G. The impurity is the electrolyte in the electrolyzed water W, which is sodium hydroxide. However, it is not limited to this. In practical applications, the impurities are calcium carbonate, sodium chloride and the like. In addition, the air inlet 60 of the present invention is composed of a filter 600 and a filter cover 602. The filter 600 and the filter cover 602 are connected to the electrolysis device 3 for receiving the hydrogen-oxygen mixed gas G and initially filtering the hydrogen-oxygen mixed gas G. The electrolysis device 3 is housed in the water tank 2 for further connection with the condensing filter 6.

In the above, after the individual design of each component is described, the combination of each component and its application will be described below.

In the assembled electrolysis device 3, a plurality of electrodes 34 are respectively disposed at intervals on the electrolytic cell body 32. The backing plate 36 is disposed on the upper surface of each of the electrodes 34, and the upper cover 37 is disposed on the backing plate 36 relative to the electrolytic cell body 32. At the other end, the lower cover 38 is disposed on the lower surface of the electrolytic cell body 32 with respect to the other end of the upper cover 37.

In the assembled water tank 2 and electrolysis device 3, the assembled electrolysis device 3 The anode piece 342 and the cathode piece 340 are respectively locked to the tank cover 26 by the two electrode columns 33. The detecting device (such as the flow detector 82) is inserted through the plurality of cover holes 261 of the tank cover 26 and disposed on the tank cover 26. The gasket 28 is disposed in the water tank body 24 and is fitted to each other by the third fitting structure 282 of the gasket 28 and the first fitting structure 246 of the water tank body 24. The first side edge 248 of the water tank body 24 is covered in the second hollow portion 264 of the water tank cover 26 by the second opening portion 266 of the water tank cover 26 to close the water tank body 24 and the water tank cover 26. In combination, the electrolysis device 3 is suspended in the water tank 2 in a suspended manner. The first hollow portion 20 of the water tank 2 and the electrolysis device 3 are in communication with each other.

In the assembled water tank 2, the electrolysis device 3, and the condensing filter 6, the water tank 2 and the condensing filter 6 provided with the electrolysis device 3 are connected between the duct 22 of the water tank 2 and the air inlet 60 of the condensing filter 6. Connect to connect to each other. Further, the atomizing/volatile gas mixing tank 4 is connected to the air outlet 62 of the condensing filter 6.

In practical application, the water tank 2 houses an electrolyzed water W, and the electrolysis device 3 is disposed in the water tank 2 for electrolytically electrolyzing the water W to generate a hydrogen-oxygen mixed gas G. The hydrogen-oxygen mixed gas G generated in the electrode flow path S1 is input to the first hollow portion 20 via the perforation 360 above the corresponding pad 36 and the first flow path 370 of the corresponding upper cover 37. The hydrogen-oxygen mixed gas G input to the first hollow portion 20 is further output through the conduit 22 of the water tank 2. The hydrogen-oxygen mixed gas G outputted from the conduit 22 of the water tank 2 is passed through the inlet port 60 of the condensing filter 6 into the condensing filter 6 for condensation and filtration. The hydrogen-oxygen mixed gas G entering the air inlet 60 of the condensing filter 6 is firstly filtered first through the filter 600 and the filter cover 602. Then, the preliminary filtered hydrogen-oxygen mixed gas G is further introduced into the circulation flow path 640 for condensation, and at the same time, the hydrogen-oxygen mixed gas G is filtered by the activated carbon fiber and the filter material disposed in the flow path 640a. Impurities are adsorbed within the circulation channel 640. Then, the filtered hydrogen-oxygen mixed gas G is output through the vent 62 of the condensing filter 6. The filtered hydrogen-oxygen mixed gas G is supplied to the user for inhalation, but not limited thereto. In practical applications, the filtered hydrogen-oxygen mixed gas G outputted from the condensing filter 6 can be further atomized. The atomizing gas G2 generated by the volatilizing gas mixing tank 4 is mixed to form a health gas for inhalation by the user.

Further, when the electrolysis device 3 suspends the electrolytic electrolysis water W to generate the hydrogen-oxygen mixed gas G, the vent hole 62 of the condensing filter 6 can be used for input to replenish the makeup water W2. The makeup water W2 supplemented by the air outlet 62 of the condensing filter 6 is input to the first hollow portion 20 of the water tank 2 via the duct 22 connected to the air outlet 62. The electrolyzed water W added to the first hollow portion 20 is input to the corresponding electrode flow path S1 via the second flow path 380 of the lower cover 38 of the electrolysis device 3 and a plurality of lower perforations 3202 to provide electrolysis device 3 during electrolysis. The required electrolyzed water W. At the same time, the impurities adsorbed in the circulation flow path 640 of the condensing filter 6 can be backflushed into the water tank 2 provided with the electrolysis device 3 via the inlet holes 60 and the conduit 22 by the above-mentioned supplementary water W2.

In addition, the flow rate detector 82 coupled to the electrolysis device 3 can detect the flow rate of the hydrogen-oxygen mixed gas G. The flow rate of the hydrogen-oxygen mixed gas G of the gas generator 1 is between 0.01 L/min. and 12 L/min.

In summary, the focus of the present invention is to propose a gas generator comprising an electrolysis device and a condensing filter. In the gas generator of the present invention, the hydrogen-oxygen mixed gas produced by the electrolysis device can be condensed by the condensing filter and the impurities therein can be filtered to provide a hydrogen-oxygen mixed gas suitable for human body inhalation. At the same time, the design of the present invention enables the electrolyte to be backflushed to the electrolysis device while replenishing water to reduce electrolyte consumption and to prevent electrolyte clogging in the condensing filter.

Please refer to Figure 15A, Figure 15B and Figure 16. In an eleventh embodiment, the present invention further provides a gas generator which is a gas generator having a humidification function. The gas generator 1 comprises an electrolysis device 3 (not shown) and a humidification device 9. The electrolysis device 3 houses electrolyzed water W for electrolytically electrolyzing the water W to produce a hydrogen-oxygen mixed gas G. The humidification device 9 is connected to the electrolysis device 3 for receiving and humidifying the hydrogen-oxygen mixed gas G.

Further, in the twelfth embodiment, the gas generator 1 of the present invention further comprises a condensing filter 6. The condensing filter 6 is disposed between the electrolysis device 3 and the humidification device 9 for condensing the hydrogen-oxygen mixed gas G produced by the electrolysis device 3 while filtering one of the impurities in the hydrogen-oxygen mixed gas G.

Further, in the thirteenth embodiment, the gas generator 1 of the present invention further comprises an atomizing/volatile gas mixing tank 4. The atomizing/volatile gas mixing tank 4 can be used to receive the filtered hydrogen-oxygen mixed gas G. The atomizing/volatile gas mixing tank 4 can generate an atomizing gas G2 mixed with the filtered hydrogen-oxygen mixed gas G to form a health care gas for the user to inhale. However, in another example, the atomization/volatile gas mixing tank 4 of the present invention is a hand-held atomizing device (not shown). The hand-held atomizing device is connected to the humidifying device 9 for receiving the humidified hydrogen-oxygen mixed gas. The hand atomizing device generates an atomizing gas mixed with the humidified hydrogen-oxygen mixed gas to form a health gas for inhalation by a user, wherein the atomizing gas is selected from the group consisting of water vapor, atomized syrup, volatile essential oil and combinations thereof. One of the ethnic groups formed. In practical applications, the hand-held atomizing device has a pressing structure, and the user can inhale the required amount of the health gas by pressing the pressing structure of the hand-held atomizing device.

Referring to FIG. 15, FIG. 15A and FIG. 15B are schematic diagrams showing different angles of view of the gas generator of the present invention in the fourteenth embodiment. Further, in the fourteenth embodiment, the gas generator 1 of the present invention further comprises a water tank 2, a mercury mercury device 5, a cooling device 7, and a gas output device 10. The gas output device 10 is configured to output a health gas for the user. Inhalation, the health care gas is a mixture of the hydrogen-oxygen mixed gas G and the atomizing gas G2 after the humidification.

The design of each component of the present invention will be separately described below.

First, since the structural design of the condensing filter 6 and the atomizing/volatile gas mixing tank 4 has been described above, it will not be described again.

The humidification device 9 of the present invention comprises a hollow body 90, a second conduit 92, at least one output tube 94, an oscillating device 95 (shown only in phantom in FIG. 15), a third conduit 96 and a fourth Catheter 98. The hollow body 90 is configured to receive a supplemental water W2. The second conduit 92 is disposed on the hollow body 90 for connection with the electrolysis device 3 (not shown). At least one output tube 94 is disposed in the hollow body 90 and coupled to the second conduit 92. The second conduit 92 is connected to the two output tubes 94 to form a T-shaped structure, but not limited thereto. In practical applications, the connection between the second conduit and the at least one output tube 94 is adjusted depending on the use. Further, the surfaces of the two output tubes 94 each have a plurality of nano-perforations, wherein the nano-perforations have a nanometer-sized aperture. In practical applications, the size of the nano-perforation can range from 2 nm to 10 nm, but not limited to this, and can be adjusted by the user's needs. The ends of the two output tubes 94 connected to the second conduit 92 are respectively provided with rubber stoppers for allowing the hydrogen-oxygen mixed gas G received by the second conduit 92 to be perforated by a plurality of nanometers of the two output tubes 94 (not shown) It is discharged to the hollow body 90, but not limited thereto. In practical applications, the ends of the two output tubes 94 connecting the second conduits 92 may also be of a closed design. The oscillating device 95 is disposed in the hollow body 90 and located below the at least one output tube 94 for oscillating the makeup water. The oscillating device 95 is adapted to include an ultrasonic oscillator for oscillating the makeup water in the hollow body 90. In practice, the oscillating device is not limited to the ultrasonic oscillator of the specific embodiment, and its position is not limited to the position shown in FIG. 15B. Any of the oscillating devices are disposed on the hollow body and can oscillate or stir the water to effectively disperse. The device in which the hydrogen-oxygen mixed gas is formed into tiny bubbles belongs to the present The oscillating device defined by the invention. For example, the oscillating device 95 may also include a centrifugal blade and a drive motor that connects the centrifugal blades. The drive motor can drive the centrifugal blades to rotate to generate eddy currents in the water, and assist the hydrogen in the hydrogen-oxygen mixed gas to be more effectively dispersed in the water to form hydrogen water. The oscillating device 95 can also include the above-described ultrasonic oscillator, centrifugal blades and drive motor to make the generation of hydrogen water more efficient. The third conduit 96 is disposed on the hollow body 90 for outputting hydrogen water H or for supplementing the input makeup water W2. In practical applications, the third conduit is connected to a guide hole, and the third conduit passes through the guide hole to pour out the hydrogen water H or pour the supplementary water W2. The fourth conduit 98 is disposed on the hollow body 90 for outputting the humidified hydrogen-oxygen mixed gas G.

Further, in another example, the gas generator 1 of the present invention further comprises a water tank 2. The water tank 2 has a first hollow portion 20. The first hollow portion 20 of the water tank 2 houses the electrolyzed water W. The electrolysis device 3 is disposed inside the first hollow portion 20 of the water tank 2, and the first hollow portion 20 and the electrolysis device 3 are in communication with each other. In addition, the humidification device 9 of the present invention may further comprise a second mercury mercury device (not shown). The second mercury mercury device is disposed on the water tank cover 26 and communicates with the first hollow portion 20 for extracting gas inside the water tank 2 to generate a negative pressure inside thereof.

In the above, after the individual design of each component is described, the combination of each component and its application will be described below.

In the assembled electrolysis device 3, a plurality of electrodes 34 are respectively disposed at the electrolytic cell body 32, the backing plate 36 is disposed on the upper surface of each of the electrodes 34, and the upper cover 37 is disposed on the backing plate 36 with respect to the electrolytic cell body 32. At the other end, the lower cover 38 is disposed on the lower surface of the electrolytic cell body 32 with respect to the other end of the upper cover 37.

After the assembled water tank 2 and the electrolysis device 3, the anode piece 342 and the cathode piece 340 of the assembled electrolysis device 3 are respectively locked to the tank cover 26 by the two electrode columns 33. Inspection A measuring device (such as the flow detector 82) is inserted through the plurality of cover holes 261 of the tank cover 26 and disposed on the tank cover 26. The gasket 28 is disposed in the water tank body 24 and is fitted to each other by the third fitting structure 282 of the gasket 28 and the first fitting structure 246 of the water tank body 24. The first side edge 248 of the water tank body 24 is covered in the second hollow portion 264 of the water tank cover 26 by the second opening portion 266 of the water tank cover 26 to close the water tank body 24 and the water tank cover 26. In combination, the electrolysis device 3 is suspended in the water tank 2 in a suspended manner. The first hollow portion 20 of the water tank 2 and the electrolysis device 3 are in communication with each other.

In the assembled water tank 2, the electrolysis device 3, the condensing filter 6, and the humidifying device 9, the water tank 2 and the condensing filter 6 provided with the electrolysis device 3 are the air inlet holes of the conduit 22 and the condensing filter 6 of the water tank 2. The connections between 60 are connected to each other. Next, the condensing filter 6 and the humidifying device 9 communicating with the water tank are connected to each other by the connection between the air outlet 60 of the condensing filter 6 and the second duct 92 of the humidifying device 9. Further, in the thirteenth embodiment, the atomizing/volatile gas mixing tank 4 is connected to the fourth conduit 98 of the humidifying device 9.

In practical application, the water tank 2 houses an electrolyzed water W, and the electrolysis device 3 is disposed in the water tank 2 for electrolytically electrolyzing the water W to generate a hydrogen-oxygen mixed gas G. The hydrogen-oxygen mixed gas G generated in the electrode flow path S1 is input to the first hollow portion 20 via the perforation 360 above the corresponding pad 36 and the first flow path 370 of the corresponding upper cover 37. The hydrogen-oxygen mixed gas G input to the first hollow portion 20 is further output through the conduit 22 of the water tank 2. The hydrogen-oxygen mixed gas G outputted from the conduit 22 of the water tank 2 is passed through the inlet port 60 of the condensing filter 6 into the condensing filter 6 for condensation and filtration. The hydrogen-oxygen mixed gas G entering the air inlet 60 of the condensing filter 6 is firstly filtered first through the filter 600 and the filter cover 602. Then, the preliminary filtered hydrogen-oxygen mixed gas G is further introduced into the circulation flow path 640 for condensation, and at the same time, the hydrogen-oxygen mixed gas G is filtered by the activated carbon fiber and the filter material disposed in the flow path 640a. Impurities will be adsorbed in the circulation channel Within 640. Next, the filtered hydrogen-oxygen mixed gas G is supplied to the filtered hydrogen-oxygen mixed gas G through the gas outlet 62 of the condensing filter 6.

Further, the filtered hydrogen-oxygen mixed gas G is input to the humidification device 9 through the second conduit 92 connected to the air outlet 62. The filtered hydrogen-oxygen mixed gas G received by the second conduit 92 is perforated by a plurality of nanometers of the two output tubes 94 to be discharged into the hollow body 90. In practical applications, due to the plurality of nanoperforations on the surface of the output tube 94, it is used to refine the hydrogen-oxygen mixed gas input to the humidification device to form a resolvable refinement bubble. At the same time, the makeup water accommodated in the humidification device 9 is oscillated by the oscillating device 95 to allow the gas to be easily dissolved in the oscillating makeup water. The hydrogen-oxygen mixed gas G discharged from the perforation of the nanometer is humidified by the supplementary water oscillated by the oscillating device 95 to generate a humidified hydrogen-oxygen mixed gas, which is for inhalation by the user, but To be limited, in the actual application, the humidified hydrogen-oxygen mixed gas G outputted from the humidification device 9 can be further mixed with the atomizing gas G2 generated through the atomization/volatile gas mixing tank 4 to form a health gas supply. The user inhales. Further, the above-described hydrogen-oxygen mixed gas G discharged from the output tube having the nanoperforation on the surface is also combined with the supplementary water oscillated by the oscillating device 95 to generate a hydrogen water H. More specifically, the hydrogen-oxygen mixed gas G discharged from the output tube having the nanoperforation on the surface is a refining refining bubble, and the replenishing water oscillated by the oscillating device 95 is a supplementary water in which the gas is easily dissolved. . Therefore, the hydrogen-oxygen gas generator of the present invention can generate hydrogen water H which dissolves a relatively high concentration of hydrogen and oxygen.

Further, when the electrolysis device 3 suspends electrolytic electrolysis of water to produce a hydrogen-oxygen mixed gas, the second mercury mercury device is used to extract the gas inside the water tank 2 to generate a negative pressure inside thereof. The supplemental water W2 replenished via the third conduit 96 is input from the humidification device 9 back into the water tank 2 provided with the electrolysis device 3 by the above-described negative pressure. More specifically, the second conduit of the makeup water by the humidification device 9 The connection between the 92 and the air outlet 62 of the condensing filter 6 is input to the condensing filter 6 by the humidifying device 9. Further, the impurities adsorbed in the circulation flow path 640 of the condensing filter 6 can be backflushed into the water tank 2 provided with the electrolysis device 3 through the inlet holes 60 and the conduit 22 by the above-mentioned supplementary water to restore the circulation flow path. The filtration capacity, prevention of blockage and corrosion of the circulation flow path and reduction of electrolyte consumption. In practice, the present invention utilizes makeup water to backflush impurities (i.e., electrolytes) into a water tank 2 provided with an electrolysis device 3, which can be used to provide electrolyzed water required for electrolysis device 3 to perform electrolysis. Further, the electrolyzed water W supplementing the first hollow portion 20 of the input water tank 2 is input to the corresponding electrode flow path S1 via the second flow path 380 of the lower cover 38 of the electrolysis device 3 and a plurality of lower perforations 3202, The electrolyzed water W required for electrolysis of the electrolysis device 3 is provided.

In summary, the focus of the present invention is to propose a gas generator comprising an electrolysis device and a humidification device. In the gas generator of the present invention, the hydrogen-oxygen mixed gas produced by the electrolysis device can be humidified by a humidifying device to provide a hydrogen-oxygen mixed gas suitable for human inhalation. In addition, the hydrogen-oxygen mixed gas generated by the electrolysis device can be used to generate hydrogen water which dissolves a relatively high concentration of the hydrogen-oxygen mixed gas by the humidification device, and in actual application, depending on the user's needs to produce the desired concentration. Hydrogen-oxygen mixed gas of hydrogen water. In addition, the design of the present invention can be used to supplement the makeup water while the electrolyte is backflushed to the electrolysis device to restore the filtration capacity of the circulation flow path, prevent clogging and corrosion of the circulation flow path, and reduce the consumption of the electrolyte.

Finally, please refer to FIG. 18A, FIG. 18B, FIG. 19, FIG. 20A and FIG. 20B. FIG. 18A and FIG. 18B show the gas generator of the present invention in the fifteenth FIG. 19 is a rear view showing the gas generator of the present invention in the embodiment shown in FIG. 18A, and FIG. 20A and FIG. In the embodiment shown in FIG. 8A, there is only a top view of the condensing filter and the tank cover and a section along the DD line of the plan view. Figure. In a fifteenth embodiment, the gas generator of the present invention comprises a water tank, an electrolysis device, an atomization/volatile gas mixing tank, a water pump device, a condensing filter, a cooling device, and a humidification device. Since the structural design of the above components has been described above, it will not be described again. Further, compared with the circulation flow path shown in FIG. 14B, in the present embodiment (FIG. 20B), the circulation flow path 640 can be condensed only by the two sets of flow paths 640a. At the same time, the design of the condensing filter 6 can be simplified and the cost can be reduced. In addition, in the embodiment, the water pump device 5 (not shown), the condensing filter 6 and the cooling device 7 are integrated on the cover of the water tank 2 to form a modular design, and at the same time The design is more space efficient than the design of the fourteenth embodiment. In addition, when the modular water tank 2, the water pump device 5, the condensing filter 6, and the cooling device 7 are assembled with the atomizing/volatile gas mixing tank 4 and the humidifying device 9, the present invention can be easily assembled and the piping is simplified. Advantages are made to optimize the overall design of the gas generator of the present invention.

In summary, the present invention provides a gas generator comprising an electrolysis device, a cooling device, and a water pump device. The gas generator of the present invention can cool the electrolyzed water after the hydrogen-oxygen mixed gas is generated by the cooling device, and the circulating electrolyzed water is forced by the water pump device to achieve the heat dissipation effect. At the same time, the present invention enables the electrolyzed water temperature to be within a temperature range that provides optimum electrolysis efficiency for effectively electrolyzing the electrolyzed water to produce a hydrogen-oxygen mixed gas to solve the problem of energy consumption.

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. Scope is attached The scope of the patent application is subject to change.

2‧‧‧Water tank

22‧‧‧ catheter

5‧‧‧Water pump device

7‧‧‧Cooling device

Claims (13)

A gas generator comprising: an electrolysis device, accommodating an electrolyzed water for electrolyzing the electrolyzed water to generate a hydrogen-oxygen mixed gas; and a cooling device connected to the electrolysis device for cooling to generate the hydrogen The electrolyzed water after the oxygen mixed gas; and a water pump device connected between the cooling device and the electrolysis device for forcibly circulating the electrolyzed water. The gas generator of claim 1, further comprising a microcomputer controller, wherein the microcomputer controller is coupled to the water pump device for sensing the temperature of the electrolyzed water, and according to the sensed electrolyzed water The temperature is used to control the flow rate of the pump device extraction and input. The gas generator of claim 2, wherein the microcomputer controller comprises a temperature sensor for sensing the temperature of the electrolyzed water. The gas generator of claim 1, wherein the cooling device comprises a heat sink and a fan, the heat sink comprises a box body and a heat dissipating tube, wherein the heat dissipating tube is distributed in the box of the heat sink The fan is fixed to an outer surface of the case of the heat sink. The gas generator according to claim 1, further comprising a water tank, wherein the water tank has a first hollow portion, the first hollow portion of the water tank is accommodated with the electrolyzed water, and the electrolysis device is disposed in the water tank The first hollow portion communicates with the electrolysis device in the first hollow portion, and the heat sink is connected to the water tank, and the water pump device is connected between the heat sink and the water tank. The gas generator of claim 5, wherein the water tank comprises a water outlet and a water inlet, the heat sink comprises an inlet and an outlet, and the inlet and the outlet of the radiator are mutually connected by the heat pipe In connection, the water pump device includes an inlet pipe and an outlet pipe, the water outlet of the water tank is connected to the inlet of the radiator, and the outlet of the radiator is connected to the water inlet pipe of the water pump device, the water pump device The water outlet pipe is connected to the water inlet of the water tank. The gas generator according to claim 1, further comprising an atomization/volatile gas mixing tank, wherein the atomization/volatile gas mixing tank is coupled to the electrolysis device to receive the hydrogen-oxygen mixed gas, wherein the atomization/ The volatile gas mixing tank generates an atomizing gas mixed with the hydrogen-oxygen mixed gas to form a health care gas for inhalation by the user, wherein the atomizing gas is selected from the group consisting of water vapor, atomized medicine, volatile essential oil and combinations thereof. One of the ethnic groups formed. A gas generator comprising: an electrolysis device, accommodating an electrolyzed water for electrolyzing the electrolyzed water to generate a hydrogen-oxygen mixed gas; and a cooling device connected to the electrolysis device for cooling to generate the hydrogen The electrolysis water after the oxygen mixed gas; and a water pump device connected between the cooling device and the electrolysis device for forcibly circulating the electrolyzed water; wherein the temperature of the electrolyzed water accommodated in the electrolysis device is A conventional electrolysis temperature. The gas generator of claim 8, wherein the conventional electrolysis temperature is between 55 ° C and 65 ° C. The gas generator of claim 8, further comprising a microcomputer controller, wherein the microcomputer controller is coupled to the water pump device for sensing the temperature of the electrolyzed water, and according to the sensed electrolyzed water The temperature is used to control the flow rate of the pump device extraction and input. The gas generator of claim 8, wherein the cooling device comprises a heat sink and a fan, the heat sink comprises a box body and a heat dissipating tube, wherein the heat dissipating tube is distributed in the box body of the heat sink The fan is fixed to an outer surface of the case of the heat sink. The gas generator of claim 8, further comprising a water tank, wherein the water tank has a first hollow portion, the first hollow portion of the water tank is accommodated with the electrolyzed water, and the electrolysis device is disposed in the water tank The first hollow portion communicates with the electrolysis device in the first hollow portion, and the heat sink is connected to the water tank, and the water pump device is connected between the heat sink and the water tank. The gas generator according to claim 8, further comprising an atomization/volatile gas mixing tank, wherein An atomization/volatile gas mixing tank is connected to the electrolysis device to receive the hydrogen-oxygen mixed gas, wherein the atomization/volatile gas mixing tank generates an atomizing gas mixed with the hydrogen-oxygen mixed gas to form a health gas for the use. Inhaled, wherein the atomizing gas is selected from the group consisting of water vapor, atomized syrup, volatile essential oil, and combinations thereof.