CN217013482U - Water electrolysis oxygen production water cup - Google Patents
Water electrolysis oxygen production water cup Download PDFInfo
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- CN217013482U CN217013482U CN202220709736.6U CN202220709736U CN217013482U CN 217013482 U CN217013482 U CN 217013482U CN 202220709736 U CN202220709736 U CN 202220709736U CN 217013482 U CN217013482 U CN 217013482U
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Abstract
The utility model discloses an oxygen-generating water cup by electrolyzing water, which comprises a water cup main body and an oxygen-generating mechanism; the oxygen generation mechanism comprises an electrolytic tank, a one-way valve, an electrolytic water device, a mobile power supply, a first air pipe and a first waterproof and breathable film. The technical scheme provided by the utility model has the beneficial effects that: when the emergency oxygen generation water cup is used, when emergency oxygen generation is needed, tap water, river water or stream water is filled into the water cup main body, water in the water cup main body flows into a reaction cavity of an electrolytic tank through a one-way valve, a mobile power supply is started, electrolytic reaction occurs in the reaction cavity at the moment, oxygen ions gather at a cathode bar and generate oxygen, the generated oxygen is discharged through a first air pipe and is supplied to a user, and the one-way valve can prevent water in the reaction cavity from reversely flowing into the water cup main body, so that educt generated in the electrolytic process cannot enter the water cup main body, water in the water cup main body cannot become dirty, drinking can continue, and the inner wall of the water cup main body cannot become dirty due to electrolytic water reaction.
Description
Technical Field
The utility model relates to the technical field of oxygen generation equipment, in particular to an oxygen generation water cup by electrolyzing water.
Background
Oxygen is indispensable for human survival, and proper oxygen inhalation can also be used for correcting hypoxia, improving the partial pressure of arterial oxygen and the oxygen saturation level and promoting metabolism. At present, the oxygen generating equipment is widely used in life (for example, the Chinese utility model patent with the application number of CN 201921440763.2), and various types of oxygen generating and supplying equipment are already available, such as oxygen generators, oxygen bags, oxygen bottles and the like.
Oxygen can be prepared emergently by the water electrolysis principle, however, when water is electrolyzed, other ions exist in water, the water can move between a cathode and an anode under the electrolysis condition, if the ions are easily oxidized or reduced, corresponding reaction can occur, so that the water is discolored, precipitates can be attached to the inner wall of the water container, and if the water electrolysis reaction is directly carried out in the water cup, the water in the water cup can be dirtied and cannot be continuously drunk, and meanwhile, the inner wall of the water cup can be dirtied and is not easy to clean.
SUMMERY OF THE UTILITY MODEL
In view of the above, there is a need to provide an oxygen-generating water cup by electrolyzing water, which solves the technical problems that water in the water cup becomes dirty and cannot be continuously drunk and the inner wall of the water cup becomes dirty and is not easy to clean when the water in the water cup is subjected to an electrolyzed water reaction.
In order to realize the aim, the utility model provides an oxygen-making water cup by electrolyzing water, which comprises a water cup main body and an oxygen-making mechanism;
the water cup main body is provided with a water storage cavity;
oxygen-making mechanism includes electrolysis jar, check valve, electrolysis water installation, portable power source, first trachea and first water proof ventilated membrane, the electrolysis jar has an inclosed reaction chamber, the water inlet has been seted up on the electrolysis jar, the water inlet with the water storage chamber reaches the reaction chamber all communicates, the check valve set up in the water inlet, the electrolysis water installation has anode rod and cathode bar, the anode rod reaches the cathode bar all set up in the reaction chamber, portable power source with the electrolysis water installation electricity is connected, a first tracheal pot head is located on the anode rod, first water proof ventilated membrane embedded in the first trachea.
In some embodiments, the electrolyzed water oxygen-making water cup further comprises a nasal suction tube, and an inlet of the nasal suction tube is communicated with the other end of the first air tube.
In some embodiments, an equipment cavity is further formed in the electrolytic tank, the equipment cavity is not communicated with the reaction cavity, and the equipment cavity is used for accommodating the nasal suction tube, the water electrolysis device and the mobile power supply.
In some embodiments, a side cover is movably connected to the electrolytic tank and is used for controlling the opening or closing of the equipment cavity.
In some embodiments, a temperature sensor is disposed within the device cavity for detecting a temperature within the device cavity.
In some embodiments, the one-way valve is a duckbill valve secured within the water inlet.
In some embodiments, the oxygen generation mechanism further includes a second gas pipe and a second water-proof gas-permeable membrane, one end of the second gas pipe is sleeved on the cathode rod, the other end of the second gas pipe is located outside the reaction chamber, and the second water-proof gas-permeable membrane is embedded in the second gas pipe.
In some embodiments, a first internal thread is formed at one end of the water cup body, and a first external thread matched with the first internal thread is formed at one end of the electrolytic tank.
In some embodiments, the oxygen-making water cup by electrolyzing water further comprises a lower cover, the lower cover is matched with the first internal thread, and the lower cover is in threaded connection with one end of the water cup main body.
In some embodiments, the other end of the cup body is formed with a second internal thread, the electrolyzed water oxygen-generating cup further comprises an upper cover, the upper cover is matched with the second internal thread, and the upper cover is in threaded connection with the other end of the cup body.
Compared with the prior art, the technical scheme provided by the utility model has the beneficial effects that: when the emergency oxygen generation cup is used and needs emergency oxygen generation, tap water, river water or stream water is filled into the cup main body, the water in the cup main body flows into a reaction cavity of the electrolytic tank through the one-way valve, the mobile power supply is started, at the moment, an electrolytic reaction occurs in the reaction cavity, hydrogen ions and oxygen ions in the water are separated, the hydrogen ions gather at the cathode bar and generate hydrogen, the oxygen ions gather at the cathode bar and generate oxygen, the generated oxygen is discharged through the first air pipe to be used by a user, the first water-proof and air-permeable film is used for preventing water from entering the first air pipe, hydrogen is released into the air, and the one-way valve can prevent water in the reaction cavity from reversely flowing into the cup main body, so that, the educt generated in the electrolysis process can not enter the cup main body, so that the water in the cup main body can not become dirty and can be continuously drunk, and the inner wall of the cup main body can not become dirty due to the reaction of the electrolyzed water.
Drawings
FIG. 1 is a schematic perspective view of an embodiment of an oxygen-making water cup by electrolyzing water according to the present invention, wherein a main body of the water cup is connected to an electrolytic tank;
FIG. 2 is a schematic structural diagram of the electrolyzed water oxygen-making water cup in FIG. 1;
FIG. 3 is a schematic diagram of the oxygen generation mechanism of FIG. 2;
FIG. 4 is a schematic perspective view of a common water cup assembled by connecting a cup body and a lower cover of the electrolyzed water oxygen-making water cup of FIG. 1;
FIG. 5 is a schematic structural diagram of the electrolyzed water oxygen-making water cup in FIG. 4;
in the figure: 1-a water cup main body, 2-an oxygen generating mechanism, 21-an electrolytic tank, 211-a reaction cavity, 212-an equipment cavity, 213-a side cover, 22-a one-way valve, 23-an electrolytic water device, 231-an anode rod, 232-a cathode rod, 24-a mobile power supply, 25-a first air pipe, 26-a first water-proof and breathable film, 27-a second air pipe, 28-a second water-proof and breathable film, 3-a nasal suction pipe, 4-a temperature sensor, 5-a lower cover and 6-an upper cover.
Detailed Description
The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate preferred embodiments of the utility model and together with the description, serve to explain the principles of the utility model and not to limit the scope of the utility model.
Referring to fig. 1-3, the utility model provides an oxygen generating water cup by electrolyzing water, comprising a water cup body 1 and an oxygen generating mechanism 2.
The cup body 1 is provided with a water storage cavity. Oxygen making mechanism 2 includes electrolysis jar 21, check valve 22, electrolysis water installation 23, portable power source 24, first trachea 25 and first water proof ventilated membrane 26, electrolysis jar 21 has an inclosed reaction chamber 211, the water inlet has been seted up on electrolysis jar 21, the water inlet with the water storage chamber reaches the reaction chamber all communicates, check valve 22 set up in the water inlet, electrolysis water installation 23 has anode rod 231 and cathode rod 232, anode rod 231 reaches cathode rod 232 all set up in the reaction chamber 211, portable power source 24 with electrolysis water installation 23 electricity is connected, a pot head of first trachea 25 is located on the anode rod 231 (has the clearance between first trachea 25 and the anode rod 231), first ventilated membrane 26 embedded in the first trachea 25.
When the emergency oxygen generation water cup is used, tap water, river water or stream water is filled into the water cup main body 1, water in the water cup main body 1 flows into the reaction cavity 211 of the electrolytic tank 21 through the one-way valve 22, the mobile power supply 24 is started, at the moment, an electrolytic reaction occurs in the reaction cavity 211, hydrogen ions and oxygen ions in the water are separated, the hydrogen ions are gathered on the cathode rod 232 and generate hydrogen, the oxygen ions are gathered on the cathode rod 232 and generate oxygen, the generated oxygen is discharged through the first air pipe 25 for a user to use, the first water-proof air-permeable film 26 has the function of preventing the water from entering the first air pipe 25, the hydrogen is released into the air, the one-way valve 22 can prevent the water in the reaction cavity 211 from reversely flowing into the water cup main body 1, therefore, educts generated in the electrolytic process cannot enter the water cup main body 1, the water in the water cup main body 1 cannot become dirty, and can be continuously drunk, and, the inner wall of the cup body 1 does not become dirty due to the reaction of the electrolyzed water.
In order to facilitate oxygen inhalation, referring to fig. 2 and 3, in a preferred embodiment, the electrolyzed water oxygen-making water cup further comprises a nasal suction tube 3, and an inlet of the nasal suction tube 3 is communicated with the other end of the first air tube 25.
In order to facilitate the storage of the nasal suction tube 3, referring to fig. 1-3, in a preferred embodiment, an apparatus cavity 212 is further formed in the electrolytic tank 21, the apparatus cavity 212 is not communicated with the reaction cavity 211, the apparatus cavity 212 is used for storing the nasal suction tube 3, the electrolyzed water device 23 and the mobile power supply 24, and when not in use, the nasal suction tube 3 is stored in the apparatus cavity 212 (as shown in fig. 1), so that the nasal suction tube is convenient to carry.
In order to facilitate taking out the nasal suction tube 3, referring to fig. 1 to 3, in a preferred embodiment, a side cover 213 is movably connected to the electrolytic tank 21, the side cover 213 is used for controlling the opening or closing of the equipment cavity 212, and when oxygen inhalation is required, the side cover 213 is opened to take out the nasal suction tube 3 for oxygen inhalation.
In order to prevent the mobile power source 24 from being in danger due to an excessively high temperature, referring to fig. 2 and 3, in a preferred embodiment, a temperature sensor 4 is disposed in the equipment cavity 212, the temperature sensor 4 is used for detecting the temperature in the equipment cavity 212, and when the temperature in the equipment cavity 212 exceeds a preset temperature value during use, the mobile power source 24 is automatically powered off, so as to prevent the mobile power source 24 from being in danger of fire or even explosion due to an excessively high temperature.
To embody the function of the check valve 22, referring to fig. 2 and 3, in a preferred embodiment, the check valve 22 is a duckbill valve that is secured within the water inlet.
In order to facilitate discharging the hydrogen generated by the electrolysis, referring to fig. 2 and fig. 3, in a preferred embodiment, the oxygen generating mechanism 2 further includes a second gas pipe 27 and a second gas-impermeable film 28, one end of the second gas pipe 27 is sleeved on the cathode rod 232 (a gap is formed between the second gas pipe 27 and the cathode rod 232), the other end of the second gas pipe 27 is located outside the reaction chamber 211, and the second gas-impermeable film 28 is embedded in the second gas pipe 27.
In order to realize the detachable connection of the cup main body 1 and the electrolytic tank 21, referring to fig. 4 and 5, in a preferred embodiment, a first internal thread is formed at one end of the cup main body 1, and a first external thread matched with the first internal thread is formed at one end of the electrolytic tank 21, so that the electrolytic tank 21 is in threaded connection with the cup main body 1.
In order to facilitate the use of the water cup body 1 as a common water cup when oxygen generation by electrolysis is not required, referring to fig. 4 and 5, in a preferred embodiment, the water electrolysis oxygen generation water cup further comprises a lower cover 5, the lower cover 5 is matched with the first internal thread, and the lower cover 5 is in threaded connection with one end of the water cup body 1.
In order to facilitate the use of the water cup, referring to fig. 4 and 5, in a preferred embodiment, a second internal thread is formed at the other end of the water cup main body 1, the electrolyzed water oxygen-making water cup further comprises an upper cover 6, the upper cover 6 is matched with the second internal thread, and the upper cover 6 is in threaded connection with the other end of the water cup main body 1.
For better understanding of the present invention, the following will explain the operation of the water electrolysis oxygen-making water cup provided by the present invention in detail with reference to fig. 1-5: when the emergency oxygen generation water cup is used, tap water, river water or stream water is filled into the water cup main body 1, water in the water cup main body 1 flows into the reaction cavity 211 of the electrolytic tank 21 through the one-way valve 22, the mobile power supply 24 is started, at the moment, an electrolytic reaction occurs in the reaction cavity 211, hydrogen ions and oxygen ions in the water are separated, the hydrogen ions are gathered on the cathode rod 232 and generate hydrogen, the oxygen ions are gathered on the anode rod 231 and generate oxygen, the generated oxygen is discharged through the first air pipe 25 for a user to use, the first water-proof air-permeable film 26 has the function of preventing the water from entering the first air pipe 25, the hydrogen is released into the air, the one-way valve 22 can prevent the water in the reaction cavity 211 from reversely flowing into the water cup main body 1, therefore, educts generated in the electrolytic process cannot enter the water cup main body 1, the water in the water cup main body 1 cannot become dirty, and drinking can continue, and, the inner wall of the cup body 1 does not become dirty due to the reaction of the electrolyzed water.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.
Claims (10)
1. An oxygen-generating water cup by electrolyzing water is characterized by comprising a water cup main body and an oxygen-generating mechanism;
the water cup main body is provided with a water storage cavity;
oxygen-making mechanism includes electrolysis jar, check valve, electrolysis water installation, portable power source, first trachea and first water proof ventilated membrane, the electrolysis jar has an inclosed reaction chamber, the water inlet has been seted up on the electrolysis jar, the water inlet with the water storage chamber reaches the reaction chamber all communicates, the check valve set up in the water inlet, the electrolysis water installation has anode rod and cathode bar, the anode rod reaches the cathode bar all set up in the reaction chamber, portable power source with the electrolysis water installation electricity is connected, first tracheal pot head is located on the anode rod, first water proof ventilated membrane embedded in the first trachea.
2. An oxygen-making water cup by electrolyzing water according to claim 1, further comprising a nasal suction tube, the inlet of which communicates with the other end of the first air tube.
3. An oxygen-making water cup by electrolyzing water as claimed in claim 2 wherein an equipment chamber is formed in the electrolytic tank, the equipment chamber and the reaction chamber are not connected to each other, and the equipment chamber is used for accommodating the nasal suction tube, the water electrolyzing device and the mobile power supply.
4. An oxygen-making water cup by electrolyzing water as claimed in claim 3 wherein the electrolytic tank is movably connected with a side cover for controlling the opening or closing of the equipment cavity.
5. An oxygen-making water cup by electrolyzing water according to claim 3 wherein a temperature sensor is disposed in the chamber for detecting the temperature in the chamber.
6. An oxygen-producing water cup by electrolyzing water as recited in claim 1 wherein said one-way valve is a duckbill valve, said duckbill valve being secured within said water inlet.
7. An oxygen generating water cup by electrolyzing water according to claim 1 further comprising a second gas tube and a second water-proof and gas-permeable membrane, wherein one end of the second gas tube is sleeved on the cathode bar, the other end of the second gas tube is positioned outside the reaction chamber, and the second water-proof and gas-permeable membrane is embedded in the second gas tube.
8. An oxygen-making water cup by electrolyzing water as claimed in claim 1, wherein one end of the water cup main body is formed with a first internal thread and one end of the electrolytic tank is formed with a first external thread matching the first internal thread.
9. An oxygen-making water cup by electrolyzing water according to claim 8, further comprising a lower cover, wherein the lower cover is matched with the first internal thread, and the lower cover is connected with one end of the water cup main body in a threaded manner.
10. The electrolyzed water oxygen-producing water cup as claimed in claim 8, wherein a second internal thread is formed at the other end of the water cup main body, the electrolyzed water oxygen-producing water cup further comprises an upper cover, the upper cover is matched with the second internal thread, and the upper cover is in threaded connection with the other end of the water cup main body.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202220709736.6U CN217013482U (en) | 2022-03-28 | 2022-03-28 | Water electrolysis oxygen production water cup |
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CN202220709736.6U CN217013482U (en) | 2022-03-28 | 2022-03-28 | Water electrolysis oxygen production water cup |
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CN217013482U true CN217013482U (en) | 2022-07-22 |
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CN202220709736.6U Active CN217013482U (en) | 2022-03-28 | 2022-03-28 | Water electrolysis oxygen production water cup |
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