TW201332656A - Health oxy-hydrogen gas supply facility - Google Patents

Abstract

A health oxy-hydrogen gas supply facility includes an electrolytic unit, a filter clean unit and a control unit. The electrolytic unit includes at least one positive electrode plate and at least one negative electrode plate. Oxyhydrogen, produced by an aqueous electrolyte of the electrolytic chamber that applies voltages to positive and negative electrode plates, can be discharged from the filter clean unit after filtering. The control unit includes an oxy-hydrogen proportion regulation interface that is utilized to regulate voltage of the positive and negative electrode plates of the electrolytic unit, thereby varying proportions of the oxyhydrogen to comply with health requirements. Besides, the discharged oxyhydrogen gas can be filtered and cleaned by the filter clean unit, thereby purity of oxyhydrogen can be determined when inhaled.

Description

Health care hydrogen supply equipment

The invention relates to a hydrogen and oxygen supply device, in particular to a health care hydrogen and oxygen supply device for health care and medical use.

Referring to Fig. 1, the invention patent case of "National Oxygen Production Method and Apparatus for Medical and Health Care" of the Republic of China Announcement No. 119113, the oxygen generating device disclosed in the present invention comprises a container 11, a feeding port cover 12, a cylinder 13, and a purification The chamber cover 14, a measuring cup 15, and a filter dehumidification cup 16.

The inside of the container 11 is used as the reaction chamber 111, and includes a body 112, and a cover 113 covering the body 112. The cover 113 has a feeding port 114, and the feeding port cover 12 is a cover. It is disposed on the feeding port 114 and includes an upwardly extending chimney 121.

The cylinder 13 is embedded in the top surface of the filler cover 12 and is made of a transparent material and serves as a clean room 131. The clean room cover 14 is capped on the cylinder 13 and includes a cover cylinder 141 extending downwardly and spaced around the riser tube 121, and an oxygen output pipe 142 communicating with the outside.

The measuring cup 15 can cover the feeding port 114, the feeding port cover 12, the cylinder 13, and the clean room cover 14 to prevent dust from intruding when the oxygen generating device is not in use. The filter dehumidification cup 16 can be sandwiched between the feeding port 114 and the feeding port cover 12, and a plurality of small holes 161 are defined in the bottom surface, and the filtering dehumidifying cup 16 can hold a filter material, a desiccant, a fragrance or a purifying agent, etc. The saturated moisture in the oxygen is removed, and the released oxygen has a fresh effect.

In use, the measuring cup 15 is first removed and the feeding port cover 12 is opened, and an appropriate amount of clean water is poured into the reaction chamber 111, and an appropriate amount of an oxygen generating agent (sodium percarbonate) and a catalyst are simultaneously poured into the reaction chamber 111. Then, the filter dehumidification cup 16 is hung in the feeding port 114, and the feeding port cover 12 is placed on the feeding port 114 together with the cylinder 13, and finally water is added into the cleaning chamber 131 and the cleaning chamber cover 14 is covered. The oxygen produced in the reaction chamber 111 is emitted from the gas riser 121, and the user can observe the bubble generation in the clean room 131 through the cylinder 13 and can pass the oxygen output tube 142. Draw oxygen.

Oxygen can be used as a health care or medical treatment with a certain proportion of hydrogen. However, the above oxygen generating device can only produce pure oxygen, and cannot produce a hydrogen-oxygen mixed gas, so there is still a shortage in use.

Accordingly, it is an object of the present invention to provide a health care hydrogen oxygen supply apparatus which can regulate a ratio of hydrogen to oxygen and which can provide a pure hydrogen-oxygen mixed gas.

Thus, the health care hydrogen and oxygen supply device of the present invention comprises an electrolytic unit, a filter unit, and a control unit.

The electrolysis unit comprises an electrolysis chamber containing water, at least one positive electrode plate disposed in the electrolysis chamber, at least one negative electrode plate disposed in the electrolysis chamber, and an electrical connection between the positive electrode plate and the negative electrode plate a voltage controller, and a first gas pipe connecting the electrolysis chamber to output a mixed gas of hydrogen and oxygen generated by the positive electrode plate and the negative electrode plate, wherein the first gas pipe has a opposite The output of the electrolysis chamber.

The filter unit comprises a container containing water and communicating with the first gas pipe, and a second gas pipe connecting the container to output a mixed gas of hydrogen and oxygen, wherein the liquid level in the container is higher than The output end of the first gas pipe.

The control unit includes a hydrogen-oxygen ratio control interface electrically connected to the voltage controller, and the hydrogen-oxygen ratio control interface can control a voltage difference between the voltage controller output to the positive and negative electrode plates to modulate hydrogen and oxygen generation. proportion.

The invention has the effect that the purification unit can filter the hydrogen-oxygen mixed gas discharged from the electrolysis chamber, thereby ensuring the purity of the hydrogen-oxygen mixed gas sucked by the user. In addition, the hydrogen-oxygen ratio control interface can adjust the voltage difference between the positive and negative electrode plates, thereby controlling the ratio of hydrogen and oxygen generated to meet the needs of health care.

The above and other technical contents, features and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments.

2 and 3, a preferred embodiment of the health care hydrogen and oxygen supply device of the present invention comprises a housing 2, an electrolytic unit 3 disposed in the housing 2, and a filter disposed in the housing 2. Unit 4, and a control unit 5.

The electrolysis unit 3 includes an electrolysis chamber 31 containing water and liquid, a plurality of positive electrode plates 32 spaced apart from each other in the electrolysis chamber 31, a plurality of negative electrode plates 33 disposed in the electrolysis chamber 31, and an electrical connection. a voltage controller 34 of the positive electrode plate 32 and the negative electrode plates 33, a first gas delivery pipe 35 that communicates with the electrolysis chamber 31 to output a hydrogen-oxygen mixed gas, and a first communication with the electrolysis chamber 31. The hydration module 36. The positive electrode plates 32 are connected in parallel to each other and electrically connected to the voltage controller 34. The negative electrode plates 33 are connected in parallel to each other and are also electrically connected to the voltage controller 34, and the voltage controller 34 controls the positive and negative voltages, respectively. The voltages of the electrode plates 32, 33 enable the positive and negative electrode plates 32, 33 to electrolyze water to generate oxygen around the positive electrode plates 32, and hydrogen gas is generated around the negative electrode plates 33, and the first input The air tube 35 has an output end 351. The first water supply module 36 has a first conduit 361 that communicates with the electrolysis chamber 31, and a first cover 362. The first conduit 361 has an exposed body 2 for injecting water into the electrolysis. The first opening 3611 in the chamber 31 is used to close the first opening 3611.

The filter unit 4 includes a container 41 containing water and communicating with the first gas pipe 35, a second gas pipe 42 communicating with the container 41 to output a mixed gas of hydrogen and oxygen, and a first communication with the container 41. The second hydration module 43 and a filter 44 disposed in the first gas delivery pipe 35 to filter impurities in the hydrogen-oxygen mixed gas. The liquid level of the container 41 is higher than the output end 351 of the first gas supply pipe 35, and the second gas supply pipe 42 is exposed to the outer casing opposite to the other end of the container 41, and the container 41 can be inside. The oxy-hydrogen mixed gas is output outside the casing 2. The second water-retaining module 43 has a second conduit 431 communicating with the container 41, and a second cover 432 having an exposed portion of the housing 2 for injecting water into the container. The second opening 4311 of the 41, and the second cover 432 is for closing the second opening 4311.

The control unit 5 includes a hydrogen-oxygen proportional control interface 50 for regulating the ratio of hydrogen to oxygen, and a flow detector 52 for detecting the flow of the hydrogen-oxygen mixed gas output by the second gas delivery pipe 42. a flow control interface 53 for regulating the flow rate of the hydrogen-oxygen mixed gas outputted by the second gas delivery pipe 42, a first liquid level detector 55 disposed on the electrolysis chamber 31, and a second liquid disposed on the container 41 The position detector 56, a warning light 57 controlled by the first liquid level detector 55 and the second liquid level detector 56, electrically connected to the first liquid level detector 55 and the second liquid The automatic breaker 58 of the bit detector 56 and a flow meter 59 disposed on the first gas pipe 35.

The hydrogen-oxygen ratio control interface 50, the flow detector 52, the flow control interface 53, and the warning light 57 are all exposed outside the casing 2 for convenient monitoring and operation by the user.

The hydrogen-oxygen ratio control interface 50 is electrically connected to the voltage controller 34, and can control the voltage difference outputted by the voltage controller 34 to the positive and negative electrode plates 32, 33, by the positive and negative electrode plates 32, The ratio of hydrogen and oxygen generated by the difference between the 33 voltage differences is adjusted, and the flow control interface 53 is also electrically connected to the voltage controller 34, and the output can be adjusted to the positive and negative electrode plates 32, 33. The magnitude of the voltage is used to control the flow rate of the hydrogen-oxygen mixed gas flowing through the second gas delivery pipe 42.

In addition, the first liquid level detector 55 detects that the liquid level of the liquid in the electrolysis chamber 31 is lower than a predetermined height, or the second liquid level detector 56 detects the water in the container 41. When the liquid level is lower than the output end 351, the warning light 57 will be turned on, and the automatic disconnecting device 58 will also power off the electrolytic unit 3, thereby reminding the user to add water to the electrolysis chamber. 31 or the container 41, and the electrolytic unit 3 can be prevented from continuing to operate when the liquid is not in the electrolytic chamber 31, thereby causing overheating damage, and also preventing the hydrogen-oxygen mixed gas from being output through the filtration of the liquid in the container 41. The situation outside the casing 2 occurs. The flow meter 59 can detect the flow rate of the hydrogen-oxygen mixed gas flowing through the first gas delivery pipe 35, and can understand the operation state of the electrolytic cell 3 when detecting and repairing the health care hydrogen-oxygen supply device.

With the above structure, an appropriate amount of water is first injected into the electrolysis chamber 31 and the container 41 through the first and second openings 3611 and 4311, and the electrolysis unit 3 is energized. The positive electrode plate 32 and the negative electrode plates 33 respectively generate oxygen and hydrogen, and the generated hydrogen-oxygen mixed gas can be injected into the water of the container 41 through the first gas pipe 35 to form bubbles, and the bubbles are The water liquid can be further filtered, and the hydrogen-oxygen mixed gas released after the bubbles float out of the liquid surface can be outputted to the outside of the casing 2 via the second gas pipe 42 for human body to suck.

Since the ratio of hydrogen and oxygen generated is affected by the voltage difference between the positive and negative electrode plates 32, 33, for example, when the voltages of the positive and negative electrode plates 32, 33 are the same, the generated hydrogen gas The ratio of oxygen is 2:1, so the user can operate the hydrogen-oxygen ratio control interface 50 according to individual needs, and different ratios of hydrogen-oxygen mixed gas can be obtained. In general, the ratio of hydrogen to oxygen used for medical and health care purposes is 66:34, or 8:2. The flow detector 52 can be used to monitor the flow rate of the hydrogen-oxygen mixed gas flowing out of the casing 2, and the flow regulating interface 53 can be operated by itself to increase or decrease the flow rate.

In summary, the health care hydrogen oxygen supply device of the present invention can adjust the voltage difference between the positive and negative electrode plates 32 and 33 by the hydrogen-oxygen ratio control interface 50, thereby controlling the ratio of hydrogen and oxygen generated to meet the requirements. Personal needs. By passing the hydrogen-oxygen mixed gas into the water liquid in the container 41, the hydrogen-oxygen mixed gas discharged from the electrolysis chamber 31 can be filtered, and the purity of the hydrogen-oxygen mixed gas sucked by the user can be ensured. Therefore, the object of the present invention can be achieved.

The above is only the preferred embodiment of the present invention, and the scope of the invention is not limited thereto, that is, the simple equivalent changes and modifications made by the scope of the invention and the description of the invention are All remain within the scope of the invention patent.

2. . . case

3. . . Electrolytic unit

31. . . Electrolysis chamber

32. . . Positive electrode plate

33. . . Negative electrode plate

34. . . Voltage controller

35. . . First gas pipe

351. . . Output

36. . . First hydration module

361. . . First catheter

3611. . . First opening

362. . . First cover

4. . . Filter unit

41. . . container

42. . . Second gas pipe

43. . . Second hydration module

431. . . Second catheter

4311. . . Second opening

432. . . Second cover

44. . . Filter

5. . . control unit

50. . . Hydrogen-oxygen ratio regulation interface

52. . . Traffic detector

53. . . Traffic control interface

55. . . First level detector

56. . . Second level detector

57. . . Warning Light

58. . . Automatic breaker

59. . . Flow meter

Figure 1 is an exploded perspective view showing the invention patent of the Republic of China Announcement No. 119113 "Method and Apparatus for Oxygen Production for Health Care and Health Care";

Figure 2 is a schematic view showing a preferred embodiment of the health care hydrogen and oxygen supply device of the present invention;

Figure 3 is an architectural diagram illustrating the internal architecture of the preferred embodiment.

2. . . case

3. . . Electrolytic unit

31. . . Electrolysis chamber

32. . . Positive electrode plate

33. . . Negative electrode plate

34. . . Voltage controller

35. . . First gas pipe

351. . . Output

36. . . First hydration module

361. . . First catheter

3611. . . First opening

362. . . First cover

4. . . Filter unit

41. . . container

42. . . Second gas pipe

43. . . Second hydration module

431. . . Second catheter

4311. . . Second opening

432. . . Second cover

44. . . Filter

5. . . control unit

50. . . Hydrogen-oxygen ratio regulation interface

52. . . Traffic detector

53. . . Traffic control interface

55. . . First level detector

56. . . Second level detector

57. . . Warning Light

58. . . Automatic breaker

59. . . Flow meter

Claims (9)

A health care hydrogen and oxygen supply device comprises: an electrolysis unit comprising: an electrolysis chamber containing water and liquid, at least one positive electrode plate disposed in the electrolysis chamber, at least one negative electrode plate disposed in the electrolysis chamber, and an electrical connection a voltage controller of the positive electrode plate and the negative electrode plate, and a first gas pipe that communicates with the electrolysis chamber to output a mixed gas of hydrogen and oxygen generated by electrolysis of the positive electrode plate and the negative electrode plate, and The first gas pipe has an output opposite to the electrolysis chamber; a filter unit includes a container containing water and communicating with the first gas pipe, and a container for outputting a hydrogen-oxygen mixed gas a second gas delivery pipe, wherein a liquid level of the liquid in the container is higher than an output end of the first gas pipe; and a control unit comprising a hydrogen-oxygen ratio control interface electrically connected to the voltage controller, the hydrogen and oxygen The proportional control interface can control the voltage difference of the voltage controller output to the positive and negative electrode plates to modulate the ratio of hydrogen to oxygen. The health care hydrogen and oxygen supply device according to claim 1, wherein the electrolytic unit comprises a plurality of positive electrode plates spaced apart from each other, and a plurality of negative electrode plates spaced apart from each other, and the voltage controller is electrically connected to the And the positive electrode plate and the negative electrode plate, the electrolysis unit further includes a first water supply module that communicates with the electrolysis chamber to supplement the water of the electrolysis chamber, and the filter unit further includes a communication with the container a second hydration module that replenishes the water of the container. The health care hydrogen and oxygen supply device according to claim 1, wherein the filter unit further comprises a filter disposed in the first gas pipe to filter impurities of the hydrogen-oxygen mixed gas. The health care hydrogen and oxygen supply device according to claim 1, wherein the control unit further comprises a flow rate detector for detecting a flow of the hydrogen-oxygen mixed gas output by the second gas pipe, and a The voltage controller is electrically connected to regulate a flow control interface of the flow of the hydrogen-oxygen mixed gas output by the second gas pipe. The health care hydrogen and oxygen supply device according to claim 1, wherein the control unit further comprises a first liquid level detector disposed on the electrolysis chamber, and a second liquid level disposed on the container a detector, and a warning light controlled by the first liquid level detector and the second liquid level detector, wherein the first liquid level detector detects that the liquid level in the electrolysis chamber is low The warning light will illuminate at a preset height or when the second level detector detects that the level of water in the container is below the output. The health care hydrogen and oxygen supply device according to claim 5, wherein the control unit further comprises an automatic breaker, the automatic breaker being electrically connected to the first and second liquid level detectors, and When the liquid level of the water in the electrolysis chamber is lower than the preset height, or the liquid level of the liquid in the container is lower than the output end, the electrolysis unit is powered off. The health care hydrogen and oxygen supply device according to claim 1, wherein the control unit further comprises a flow meter disposed on the first gas pipe. The health care hydrogen and oxygen supply device according to claim 1, further comprising a casing, wherein the electrolysis unit and the filter unit are disposed in the casing. The health-care hydrogen-oxygen supply device according to claim 8, wherein the first water-retaining module has a first conduit and a first cover, the first conduit is connected to the electrolysis chamber and has an exposed a first opening of the housing, the first cover is for closing the first opening, the second water-retaining module has a second conduit, and a second cover, the second conduit is connected to the container, And having a second opening exposed to the housing, and the second cover is for closing the second opening.