CN114436388B - Hydrogen-rich water cup capable of displaying hydrogen concentration in real time - Google Patents

Abstract

The invention discloses a hydrogen-rich water cup capable of displaying hydrogen concentration in real time, which comprises a cup body and a cup cover, wherein a base is installed at the bottom of the cup body, a clear water area, a sewage area and a detergent area are arranged in the base, a protective cover is fixed on the bottom wall inside the cup body, a rotating body is arranged in the protective cover, the outer surface of the rotating body is abutted against the inner wall of the protective cover, the rotating body is rotatably installed on the bottom wall of the cup body, a hydrogen production chamber is downwards arranged in the rotating body, and a hydrogen production instrument fixed on the bottom wall of the cup body is arranged in the hydrogen production chamber.

Description

Hydrogen-rich water cup capable of displaying hydrogen concentration in real time

Technical Field

The invention relates to the field of water cups, in particular to a hydrogen-rich water cup capable of displaying hydrogen concentration in real time.

Background

Drink hydrogen-rich water and can effectively improve the oxidation resistance of health, consequently drink hydrogen-rich water and become many people's selection, current hydrogen-rich drinking cup can carry well and make hydrogen-rich water, conveniently drinks, and in order to satisfy the user and know how much of aquatic hydrogen concentration in real time, generally placed the hydrogen measuring probe in the cup and carry out real-time detection. However, many people prefer to use the hydrogen-rich water cup to carry the beverage for drinking the beverage containing hydrogen, but after long-time use, dirt impurities are inevitably formed on the surface of the hydrogen measuring probe, the accuracy of the hydrogen measuring probe in detecting the hydrogen content is affected, and a user can hardly find out whether the accuracy of the hydrogen measuring probe is reduced, so that the phenomenon of inaccurate detection is easily caused, the cleaning is troublesome, and the using effect is poor.

Disclosure of Invention

The invention aims to provide a hydrogen-rich water cup capable of displaying hydrogen concentration in real time to solve the problems.

The technical purpose of the invention is realized by the following technical scheme: a hydrogen-rich water cup capable of displaying hydrogen concentration in real time comprises a cup body and a cup cover, wherein a base is installed at the bottom of the cup body, a clean water area, a sewage area and a detergent area are arranged in the base, a protective cover is fixed on the bottom wall inside the cup body, a rotating body is arranged in the protective cover, the outer surface of the rotating body is tightly abutted to the inner wall of the protective cover, the rotating body is rotatably installed on the bottom wall of the cup body, a hydrogen production chamber is arranged in the rotating body and downwards opened, a hydrogen production instrument fixed on the bottom wall of the cup body is arranged in the hydrogen production chamber, a detection cavity with a downwards opened side is arranged at the side edge of the hydrogen production chamber, two hydrogen measurement probes fixed on the bottom wall of the cup body are arranged in the detection cavity, one hydrogen measurement probe is a standby probe, and a partition board fixed on the bottom wall of the cup body is arranged between the two hydrogen measurement probes and at the side edge of the hydrogen measurement probes, the partition plate can seal the hydrogen measuring probe with the inner wall of the detection cavity, two ends of the inner wall of the detection cavity at the outward side are provided with openings, the outer circular surface of the protection cover is provided with two first water through holes at the side close to the detection cavity, one side of the protection cover close to the hydrogen producing chamber is provided with a second water through hole, two sides of the outer side wall of the hydrogen producing chamber are provided with third water through holes capable of being communicated with the second water through holes, the top of the protection cover is provided with two air outlets, the top wall of the hydrogen producing chamber is provided with a one-way valve, the rotation of the rotating body can switch two sides of the openings to be respectively communicated with the openings at two sides, the third water through holes at two sides can also be switched to be respectively communicated with the second water through holes, and the top of the one-way valve can be switched to be respectively communicated with the two air outlets;

a cleaning system is arranged in the rotating body, when the hydrogen measuring probes are positioned in a sealed space, the cleaning system can clean the hydrogen measuring probes, a pumping system is arranged at the bottom of the cup body, the pumping system can pump water in a clear water area into the detection cavity to clean the hydrogen measuring probes, hydrogen-rich water in the hydrogen production chamber can be pumped into the sealed space where the two hydrogen measuring probes are positioned, the numerical values measured by the two hydrogen measuring probes are compared, and the spare hydrogen measuring probe is used for detecting whether the commonly used hydrogen measuring probe is accurately detected;

the cup is characterized in that a control system for controlling the rotation of the rotating body is arranged in the cup body, a master control module is arranged in the cup body, and the master control module can control the cleaning system, the water pumping system, the control system, the hydrogen production instrument and the hydrogen measurement probe.

Preferably, the bottom of the cup body is provided with an external thread, the top of the base is rotatably provided with a threaded sleeve, the inner ring of the threaded sleeve is provided with a thread, the internal thread of the threaded sleeve can be installed with the external thread at the bottom of the cup body through the thread, and the base can be kept stationary when the threaded sleeve rotates.

Preferably, the base internal fixation has two first division boards, two first division board will divide into clear water district, sewage district and detergent district in the base, and the detergent district internal fixation is provided with the second division board, the second division board divides the detergent district into cleaning solution district and maintenance liquid district, the base top first division board with second division board top all is fixed with sealing rubber, avoids the liquid intermixture in clear water district, sewage district and the detergent district and leaks outward.

Preferably, the cleaning system comprises two water spray pipes which are communicated with the upper wall of the detection cavity and are arranged above the two hydrogen measurement probes, a first valve body is fixedly arranged in the rotating body, the two water spray pipes are respectively connected with two water outlets of the first valve body, and a water inlet of the first valve body is opened downwards.

Preferably, the pumping system is including setting up the ware of intaking of bottom in the cup body, the ware of intaking is intake and is held and install the second valve body, two water inlets of second valve body are connected with inlet tube and last inlet tube down respectively, the inlet tube stretches out downwards down the cup body bottom stretches into in the clear water district in the bowl cover, go up the inlet tube upwards with hydrogen generation room intercommunication, the ware of intaking is gone out the water end and is installed the third valve body, two delivery ports of third valve body are connected with first outlet pipe and second outlet pipe respectively, first outlet pipe with hydrogen generation room intercommunication, the second outlet pipe can with the water inlet intercommunication of first valve body.

Preferably, second outlet pipe side is provided with the material machine of taking out, take out the material machine discharge gate with second outlet pipe side intercommunication, it is connected with the fourth valve body to take out the material machine feed inlet, two feed inlets of fourth valve body are connected with first material pipeline and second respectively and take out the material pipeline, the tip of first material pipeline of taking out is followed the cup body bottom is worn out and is stretched into in the washing liquid district in the base, the tip of second material pipeline of taking out is followed the cup body bottom is worn out and is stretched into in the maintenance liquid district in the base.

Preferably, the control system comprises an annular cavity which is arranged at the bottom in the cup body and is right opposite to the lower part of the rotating body, a rotating ring which extends into the annular cavity is fixed at the bottom of the rotating body, a toothed ring is fixed on the outer circular surface of the rotating ring, a motor is fixed in the side wall of the annular cavity, and a gear which is meshed with the toothed ring is fixed on the output shaft of the motor.

Preferably, two the side of the hydrogen measuring probe is provided with a blow-off pipe which is arranged at the bottom in the cup body, the bottom end of the blow-off pipe is over against the sewage area, and a fifth valve body is arranged in each of the two blow-off pipes.

Preferably, the total control module comprises a control panel arranged outside the cup body, and the control panel is used for controlling the whole hydrogen-rich water cup to work.

Preferably, the flow direction of the check valve is outward from the hydrogen generation chamber.

In conclusion, the invention has the following beneficial effects:

1. according to the invention, two hydrogen measuring probes are arranged, one is used as a common probe, and the other is used as a standby probe, so that in the process of using the common probe, whether the common probe is accurate or not can be judged through the comparison and detection of the standby probe, and when the accuracy of the common probe is detected to be insufficient, the common probe can be automatically cleaned without manual cleaning, and the reliability and convenience in use are improved;

2. the hydrogen measuring probe and the hydrogen production instrument are arranged in the protective cover, so that the hydrogen measuring probe and the hydrogen production instrument can be effectively protected, the hydrogen measuring probe and the hydrogen production instrument are prevented from being damaged by external large objects and impurities, and the service life is prolonged;

3. according to the invention, the source of the hydrogen production water source can be switched according to whether the stored beverage or the purified water is stored, when the stored purified water is stored, the purified water is directly used for producing hydrogen, and the hydrogen can be rapidly and uniformly distributed in the water through the circulation of the purified water, when the stored beverage is stored, the hydrogen production instrument is sealed and protected, so that the hydrogen production instrument is not directly contacted with the beverage, and the produced hydrogen is unidirectionally overflowed into the beverage while water is supplied through an external water source, thereby avoiding the beverage from influencing the hydrogen production instrument;

4. when the damage of the common hydrogen production probe is detected, the common hydrogen production probe can be switched to the standby probe for use, and when the standby probe is used, the common use requirements can be still met, the service life can be effectively prolonged, and a user can select more time to maintain under the condition of not influencing the use, so that the use convenience is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic view of the internal structure of an embodiment of the present invention;

FIG. 2 is a schematic structural view of a cup body in an embodiment of the present invention;

FIG. 3 is a partial cross-sectional structural schematic view of a base in an embodiment of the invention;

FIG. 4 is a schematic view of the structure of the protective cover in the embodiment of the invention;

FIG. 5 is a schematic view showing the structure of a rotary body in the embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure at A in FIG. 1 according to the embodiment of the present invention;

FIG. 7 is a schematic view of the structure in the direction B-B in FIG. 6 according to the present invention;

FIG. 8 is a schematic view of the structure in the direction C-C in FIG. 6 according to an embodiment of the present invention;

FIG. 9 is a schematic view of the structure in the direction D-D in FIG. 6 according to the embodiment of the present invention;

FIG. 10 is a schematic diagram of a first position of the beverage container of FIG. 9;

FIG. 11 is a schematic view of the air outlet and the check valve of FIG. 10 according to the present invention;

fig. 12 is a first position structure diagram of fig. 9 when pure water is loaded;

FIG. 13 is a schematic structural view of a second position of the beverage container of FIG. 9;

FIG. 14 is a schematic view of the air outlet and the check valve shown in FIG. 13 according to the present invention;

fig. 15 is a structural diagram of a second position of the embodiment of the present invention fig. 9 when pure water is loaded.

In the figure: 11. a cup body; 12. a cup cover; 13. a base; 14. a protective cover; 15. a rotating body; 16. a hydrogen producing chamber; 17. a hydrogen production instrument; 18. a detection chamber; 19. a hydrogen measuring probe; 20. a partition plate; 21. an opening; 22. a first water passage hole; 23. a second water through hole; 24. a third water through hole; 25. a first partition plate; 26. an air outlet; 27. a one-way valve; 28. a water spray pipe; 29. a first valve body; 30. a water pumping device; 31. a second valve body; 32. a lower water inlet pipe; 33. an upper water inlet pipe; 34. a third valve body; 35. a first water outlet pipe; 36. a second water outlet pipe; 37. a material pumping machine; 38. a first material pumping pipeline; 39. an annular cavity; 40. a rotating ring; 41. a toothed ring; 42. a motor; 43. a gear; 44. a blow-off pipe; 45. a fifth valve body; 46. a control panel; 47. a threaded sleeve; 48. a second partition plate; 49. a fourth valve body; 50. a second pumping pipeline.

Detailed Description

With reference to the accompanying drawings 1-15, the hydrogen-rich water cup capable of displaying hydrogen concentration in real time comprises a cup body 11 and a cup cover 12, a base 13 is installed at the bottom of the cup body 11, a clear water area, a sewage area and a detergent area are arranged in the base 13, a protective cover 14 is fixed on the inner bottom wall of the cup body 11, a rotating body 15 is arranged in the protective cover 14, the outer surface of the rotating body 15 abuts against the inner wall of the protective cover 14, the rotating body 15 is rotatably installed on the bottom wall of the cup body 11, a hydrogen production chamber 16 is arranged in the rotating body 15 in a downward direction, a hydrogen production instrument 17 fixed on the bottom wall of the cup body 11 is arranged in the hydrogen production chamber 16, a detection cavity 18 with a downward opening is arranged at the side edge of the hydrogen production chamber 16, two hydrogen measurement probes 19 fixed on the bottom wall of the cup body 11 are arranged in the detection cavity 18, one of the hydrogen measurement probes 19 is a standby probe, the two hydrogen measuring probes 19 and the side edges thereof are provided with a partition plate 20 fixed on the bottom wall of the cup body 11, the partition plate 20 can be sealed with the inner wall of the detection cavity 18 to seal the hydrogen measuring probes 19, the two ends of the inner wall of the outward side of the detection cavity 18 are provided with openings 21, the outer circular surface of the protective cover 14 is provided with two first water through holes 22 near one side of the detection cavity 18, the protective cover 14 is provided with a second water through hole 23 near one side of the hydrogen producing chamber 16, the two sides of the outer side wall of the hydrogen producing chamber 16 are provided with third water through holes 24 capable of being communicated with the second water through holes 23, the top of the protective cover 14 is provided with two air outlets 26, the top wall of the hydrogen producing chamber 16 is provided with a one-way valve 27, the rotary body 15 can be rotated to switch the two sides, the openings 21 are respectively communicated with the two sides, and the third water through holes 24 are respectively communicated with the second water through holes 23, the top of the one-way valve 27 can be switched to be communicated with the two air outlets 26 respectively;

a cleaning system is arranged in the rotating body 15, when the hydrogen measuring probe 19 is located in a sealed space, the cleaning system can clean the hydrogen measuring probe 19, a pumping system is arranged at the bottom of the cup body 11, the pumping system can pump water in a clear water area into the detection cavity 18 to clean the hydrogen measuring probe 19, and can also pump hydrogen-rich water in the hydrogen production chamber 16 into the sealed space where the two hydrogen measuring probes 19 are located, the values measured by the two hydrogen measuring probes are compared, and the standby hydrogen measuring probe 19 is used for detecting whether the commonly used hydrogen measuring probe 19 is accurately detected;

a control system for controlling the rotation of the rotating body 15 is arranged in the cup body 11, a master control module is arranged in the cup body 11, and the master control module can control the cleaning system, the water pumping system, the control system, the hydrogen production instrument 17 and the hydrogen measurement probe 19.

Advantageously, the bottom of the cup body 11 is provided with an external thread, the top of the base 13 is rotatably provided with a threaded sleeve 47, the threaded sleeve 47 is internally and annularly provided with a thread, the internal thread of the threaded sleeve 47 can be in threaded mounting with the external thread at the bottom of the cup body 11, and the base 13 can be kept still when the threaded sleeve 47 rotates.

Beneficially, there are two first division boards 25 fixed in the base 13, two first division boards 25 will be divided into clean water district, sewage district and detergent district in the base 13, and detergent district internal fixation is provided with second division board 48, second division board 48 divides the detergent district into cleaning solution district and maintenance solution district, base 13 top first division board 25 with second division board 48 top all is fixed with sealing rubber, avoids the liquid in clean water district, sewage district and the detergent district to mix each other and leak outward.

Advantageously, the cleaning system comprises two water spray pipes 28 which are arranged on the upper wall of the detection cavity 18 and are used for the upper part of the two hydrogen measuring probes 19, a first valve body 29 is fixedly arranged in the rotating body 15, the two water spray pipes 28 are respectively connected with two water outlets of the first valve body 29, and a water inlet of the first valve body 29 is opened downwards.

Beneficially, pumping system is including setting up the ware 30 that draws water of bottom in the cup body 11, the ware 30 that draws water is intake and is held and install second valve body 31, two water inlets of second valve body 31 are connected with down inlet tube 32 and last inlet tube 33 respectively, lower inlet tube 32 stretches out downwards the cup body 11 bottom and stretches into in the clear water district in the bowl cover 12, last inlet tube 33 upwards with 16 intercommunications of hydrogen generation, ware 30 that draws water is gone out the water end and is installed third valve body 34, two delivery ports of third valve body 34 are connected with first outlet pipe 35 and second outlet pipe 36 respectively, first outlet pipe 35 with 16 intercommunications of hydrogen generation, second outlet pipe 36 can with the water inlet intercommunication of first valve body 29.

Beneficially, the side of the second water outlet pipe 36 is provided with a material pumping machine 37, a discharge port of the material pumping machine 37 is communicated with the side of the second water outlet pipe 36, a feed port of the material pumping machine 37 is connected with a fourth valve body 49, two feed ports of the fourth valve body are respectively connected with a first material pumping pipeline 38 and a second material pumping pipeline 50, an end portion of the first material pumping pipeline 38 penetrates out from the bottom of the cup body 11 and extends into a cleaning liquid area in the base 13, and an end portion of the second material pumping pipeline 50 penetrates out from the bottom of the cup body 11 and extends into a maintenance liquid area in the base 13.

Advantageously, the control system comprises an annular cavity 39 arranged at the bottom in the cup body 11 and facing the lower part of the rotating body 15, a rotating ring 40 extending into the annular cavity 39 is fixed at the bottom of the rotating body 15, a toothed ring 41 is fixed on the outer circumferential surface of the rotating ring 40, a motor 42 is fixed in the side wall of the annular cavity 39, and a gear 43 meshed with the toothed ring 41 is fixed on the output shaft of the motor 42.

Beneficially, the two hydrogen measuring probes 19 are provided at their sides with drain pipes 44 located at the bottom of the cup body 11, the bottom ends of the drain pipes 44 are opposite to the upper side of the sewage area, and the two drain pipes 44 are provided with fifth valve bodies 45.

Advantageously, the general control module comprises a control panel 46 arranged outside the cup body 11, and the control panel 46 is used for controlling the operation of the whole hydrogen-enriched water cup.

Advantageously, the flow direction of the one-way valve 27 is outwardly from the hydrogen generation chamber 16.

The use method of the invention comprises the following steps:

in the initial state: the two hydrogen measuring probes 19 are located in a sealed space formed by the partition plate 20 and the inner wall of the detection cavity 18, the openings 21 on the two sides are located on the side edges of the openings 21 on the two sides, the second water through hole 23 is located in the middle between the third water through holes 24 on the two sides, the check valve 27 is located between the air outlets 26 on the two sides, the first valve body 29, the second valve body 31, the third valve body 34, the fourth valve body 49 and the fifth valve body 45 are all in a closed state, and the water inlet of the first valve body 29 is opposite to and communicated with the outlet of the second water outlet pipe 36.

When the cup is used, one hand grasps the cup body 11 and the base 13, the other hand rotates the threaded sleeve 47, the threaded sleeve 47 is matched with the threads at the bottom of the cup body 11 through the threaded sleeve 47, the threaded sleeve 47 is screwed down from the bottom of the cup body 11, the base 13 is taken down from the bottom of the cup body 11, purified water is filled in a clear water area in the base 13 at the moment, corresponding cleaning liquid for cleaning a probe is filled in a cleaning liquid area according to the type of beverage frequently filled in the cup as required, a potassium chloride solution is filled in a nutrient solution area, then the first pumping pipeline 38 is opposite to the cleaning liquid area, the second pumping pipeline 50 is opposite to the nutrient solution area, the lower water inlet pipe 32 is opposite to the clear water area, the base 13 is re-filled in the cup body 11, and the base 13 is stably and tightly installed back to the bottom of the cup body 11 through rotating and screwing the threaded sleeve 47;

when the device is not used, in an initial state, the control panel 46 controls the fourth valve body 49 to communicate the second pumping pipeline 50 with the pumping machine 37, the second valve body 31 communicates the lower water inlet pipe 32 with the water pumping device 30, the third valve body 34 communicates the water pumping device 30 with the second water outlet pipe 36, the water pumping device 30 and the pumping machine 37 are started, the pumping machine 37 pumps potassium chloride solution in a maintenance liquid area into the second water outlet pipe 36 through the second pumping pipeline 50, the water pumping device 30 pumps purified water in a clear water area into the second water outlet pipe 36 through the lower water inlet pipe 32 to mix the potassium chloride solution into 3.0mol/l potassium chloride solution, at the moment, the first valve body 29 is controlled to be opened to be communicated with the water spraying pipes 28 on two sides in sequence, the mixed potassium chloride solution is input into a sealed space where the two hydrogen measuring probes 19 are located, the hydrogen measuring probes 19 are maintained, and then the control device is reset.

When non-purified water drinks such as tea and the like need to be loaded in the cup body 11, a drink option is manually selected on the control panel 46, at the moment, the control panel 46 firstly controls the opening of the 45 at one side, potassium chloride solution in the corresponding sealed space is discharged into a sewage area through the 44, then the first valve body 29 is controlled to be communicated with the corresponding water spraying pipe 28, the second valve body 31 is controlled again to communicate the lower water inlet pipe 32 with the water pumping device 30, the third valve body 34 communicates the water pumping device 30 with the second water outlet pipe 36, the water pumping device 30 is started, purified water is pumped into the sealed space where the hydrogen measuring probe 19 at one side is located for flushing, sewage generated by flushing is also discharged into the sewage area, after the flushing is completed, the control motor 42 is controlled to be started and drive the gear 43 to rotate, the gear 43 drives the gear ring 41 to rotate through gear meshing and drives the rotating ring 40 to rotate, the rotating ring 40 drives the rotating body 15 to rotate, until the one-way valve 27 is opposite to the air outlet 26 at one side, the third water through hole 24 at one side rotates to the side close to the second water through hole 23 but is not communicated, the hydrogen production chamber 16 is isolated from the cup body 11, so that the situation that the drink enters the hydrogen production chamber 16 to influence the hydrogen production performance of the hydrogen production instrument 17 is avoided, the opening 21 at one side is communicated with the first water through hole 22 at one side, the space where the hydrogen measuring probe 19 at the same side is located is unsealed, the hydrogen measuring probe 19 is in common use, the other hydrogen measuring probe 19 is used for calibrating the common hydrogen measuring probe 19 for standby use, at the moment, the user loads the drink into the cup body 11, after the cup cover 12 is sealed, the hydrogen production work is started through the control panel 46, at the moment, the control panel 46 controls the second valve body 31 to communicate the lower water inlet pipe 32 with the water pump 30, controls the third valve body 34 to communicate the water pump 30 with the first water outlet pipe 35, the water pump 30 is started to pump the purified water in a clean water area through the lower water inlet pipe 32, purified water is input into the hydrogen production chamber 16 through the first water outlet pipe 35, the hydrogen production instrument 17 is started to produce hydrogen at the moment, the produced hydrogen overflows into the beverage in the cup body 11 through the one-way valve 27 and the air outlet 26, and meanwhile, the hydrogen concentration of the beverage is monitored through the commonly used hydrogen measurement probe 19 and is displayed in real time through the control panel 46;

when purified water needs to be loaded in the cup body 11, a purified water option is selected on the control panel 46 in an initial state, at the moment, a potassium chloride solution in a sealed space where the hydrogen measuring probe 19 on one side is located is discharged firstly according to the above process and is cleaned, at the moment, the control panel 46 controls the rotating body 15 to rotate in the same direction until the third through hole 24 on one side is communicated with the second through hole 23, at the moment, the space where the common hydrogen measuring probe 19 is located is unsealed, the other hydrogen measuring probe 19 is still sealed, at the moment, purified water is filled in the cup body 11 and the cup cover 12 is covered, at the moment, the purified water in the cup body 11 directly flows into the hydrogen producing chamber 16 through the second through hole 23 and the third through hole 24, the hydrogen producing instrument 17 is directly started to produce hydrogen from the purified water, and the hydrogen is monitored in real time through the common hydrogen measuring probe 19;

after the use is finished, the water cup needs to be timely restored to the initial state, and 3.0mol/l potassium chloride solution is filled in the sealed space where the hydrogen measuring probe is located again for maintenance;

when the accuracy of the commonly used hydrogen measuring probe 19 needs to be detected, the potassium chloride solution in the space where the spare probe is located needs to be discharged and cleaned, if the cup is not in a use state, water in a clear water area is firstly pumped into the hydrogen production chamber 16 in an initial state, the hydrogen production instrument 17 is started to produce hydrogen, after the hydrogen production is finished, the hydrogen production instrument 17 is stopped, the control panel 46 controls the second valve body 31 to communicate the water inlet pipe 33 with the water pump 30, the third valve body 34 controls the water pump 30 to communicate with the second water outlet pipe 36, the third valve body 34 is started at the moment, hydrogen-rich water in the hydrogen production chamber 16 is pumped into the second water outlet pipe 36, the control panel 46 controls the first valve body 29 to communicate with the water spray pipes 28 on the two sides in sequence, the hydrogen-rich water is input into the sealed space where the two hydrogen measuring probes 19 are located in sequence through the two hydrogen measuring probes 19, and hydrogen content data detected by the two hydrogen measuring probes 19 are compared at the moment, if the error between the hydrogen content measured by the common hydrogen measuring probe 19 and the hydrogen content measured by the standby hydrogen measuring probe 19 is within a normal range, it indicates that the common hydrogen measuring probe 19 is in a normal state, if the error between the hydrogen content measured by the common hydrogen measuring probe 19 and the hydrogen content measured by the standby hydrogen measuring probe 19 exceeds the normal range, it is preliminarily determined that impurities cover the surface of the common hydrogen measuring probe 19 to affect the detection accuracy, at this time, the control panel 46 controls the fifth valve body 45 on one side of the common hydrogen measuring probe 19 to open, further the fifth valve body 45 is closed after the hydrogen-rich water is discharged into the sewage region through the sewage discharge pipe 44, at this time, the second valve body 31 is controlled to communicate the lower water inlet pipe 32 with the water pump 30, the water pump 30 is continuously started, further the water in the clean water region is pumped into the second water outlet pipe 36, and simultaneously the control panel 46 controls the fourth valve body 49 to communicate the first material pumping pipeline 38 with the material pumping machine 37, starting a material pumping machine 37, pumping the cleaning solution in the cleaning solution area into a second water outlet pipe 36 through a first material pumping pipeline 38, mixing the cleaning solution and purified water in the second water outlet pipe 36 to a required concentration, controlling a first valve body 29 to communicate with a water spray pipe 28 corresponding to the common hydrogen measuring probe 19, pumping the mixed cleaning solution into a sealed space where the common hydrogen measuring probe 19 is located, dissolving and washing impurities on the surface of the common hydrogen measuring probe 19 through standing for a required time, opening a corresponding fifth valve body 45 again after washing is finished, starting a water pump 30 again, stopping the material pumping machine 37, flushing out the cleaning solution remained in the second water outlet pipe 36, the first valve body 29 and the water spray pipe 28, flushing the surface of the common hydrogen measuring probe 19 and the sealed space where the common hydrogen measuring probe is located through the purified water to avoid the cleaning solution residue, discharging the cleaned sewage into a sewage area in a base 13 through a sewage discharge pipe 44, closing the fifth valve body 45 again after cleaning is finished, pumping the hydrogen-rich water in the common hydrogen measuring probe 16 into the sealed space where the common hydrogen measuring probe 19 again, and detecting the hydrogen measuring probe 19 again; if the cup is in use, the motor 42 is controlled and the rotating body 15 is driven to rotate to an initial state, and at the moment, in the detection process according to the process, the hydrogen-rich water in the hydrogen producing chamber 16 can be directly used for detection;

if the detection precision of the common hydrogen measuring probe 19 is recovered, the common hydrogen measuring probe 19 can be recovered to be used, hydrogen-rich water in the sealed space where the spare hydrogen measuring probe 19 is located is discharged, and 3.0mol/l potassium chloride solution is filled again for maintenance, and according to the condition that the common hydrogen measuring probe 19 is used or not, the potassium chloride solution is filled in the sealed space for maintenance similarly only when the common hydrogen measuring probe 19 is not used; if the detection of the common hydrogen measuring probe 19 is still inaccurate, maintenance is required;

after the common hydrogen measuring probe 19 cannot be used, the standby hydrogen measuring probe 19 needs to be started, when the cup body 11 loads drinks, firstly, a potassium chloride solution in a sealed space where the standby hydrogen measuring probe 19 is located is discharged and cleaned, then the rotating body 15 is controlled to rotate towards the other side in an initial state, the other side opening 21 is communicated with the corresponding first water through hole 22, the standby hydrogen measuring probe 19 is separated from the sealed space, the check valve 27 is just opposite to the other side air outlet 26, the other side third water through hole 24 is close to the second water through hole 23 but is not communicated, purified water in a clean water area is sucked into the hydrogen making chamber 16 and hydrogen is made through the hydrogen making instrument 17, generated hydrogen overflows into the drinks through the check valve 27 and the other side air outlet 26, the content of hydrogen in the drinks is monitored through the standby hydrogen measuring probe 19, when the cup body 11 loads purified water, the rotating body 15 is controlled to rotate to the other side third water through hole 24 to be communicated with the second water through hole 23, the content of hydrogen in the purified water is detected through the standby hydrogen measuring probe 19, the standby hydrogen measuring probe cannot be used, and the working time for calibrating the users can not be conveniently selected.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a hydrogen-rich drinking cup that shows hydrogen concentration in real time, includes cup body and bowl cover, its characterized in that: the base is installed at the bottom of the cup body, a clear water area, a sewage area and a detergent area are arranged in the base, a protective cover is fixed on the bottom wall inside the cup body, a rotating body is arranged in the protective cover, the outer surface of the rotating body abuts against the inner wall of the protective cover tightly, the rotating body is rotatably installed on the bottom wall of the cup body, a hydrogen production chamber is arranged in the rotating body and extends downwards, a hydrogen production instrument fixed on the bottom wall of the cup body is arranged in the hydrogen production chamber, a detection cavity with a downward opening is arranged at the side edge of the hydrogen production chamber, two hydrogen measurement probes fixed on the bottom wall of the cup body are arranged in the detection cavity, one of the hydrogen measurement probes is a standby probe, and a partition board fixed on the bottom wall of the cup body is arranged between the two hydrogen measurement probes and at the side edge of the hydrogen measurement probes, the partition plate can seal the hydrogen measuring probe with the inner wall of the detection cavity, two ends of the inner wall of the detection cavity at the outward side are provided with openings, the outer circular surface of the protection cover is provided with two first water through holes at the side close to the detection cavity, one side of the protection cover close to the hydrogen producing chamber is provided with a second water through hole, two sides of the outer side wall of the hydrogen producing chamber are provided with third water through holes capable of being communicated with the second water through holes, the top of the protection cover is provided with two air outlets, the top wall of the hydrogen producing chamber is provided with a one-way valve, the rotation of the rotating body can switch two sides of the openings to be respectively communicated with the openings at two sides, the third water through holes at two sides can also be switched to be respectively communicated with the second water through holes, and the top of the one-way valve can be switched to be respectively communicated with the two air outlets;

a cleaning system is arranged in the rotating body, when the hydrogen measuring probe is positioned in the sealed space, the cleaning system can clean the hydrogen measuring probe, and a water pumping system is arranged at the bottom of the cup body;

a control system for controlling the rotation of the rotating body is arranged in the cup body, and a master control module is arranged in the cup body;

two first partition plates are fixed in the base, the two first partition plates divide the interior of the base into a clean water area, a sewage area and a detergent area, a second partition plate is fixed in the detergent area and divides the detergent area into a cleaning solution area and a maintenance solution area, and sealing rubber is fixed on the top of the base, the tops of the first partition plate and the second partition plate, so that liquids in the clean water area, the sewage area and the detergent area are prevented from being mixed with each other and leaking outside;

the cleaning system comprises two water spray pipes which are communicated with the upper wall of the detection cavity and are arranged above the two hydrogen measuring probes, a first valve body is fixedly arranged in the rotating body, the two water spray pipes are respectively connected with two water outlets of the first valve body, and a water inlet of the first valve body is opened downwards;

the water pumping system comprises a water pump arranged at the bottom in the cup body, a second valve body is installed at the water inlet end of the water pump, two water inlets of the second valve body are respectively connected with a lower water inlet pipe and an upper water inlet pipe, the lower water inlet pipe extends downwards out of the bottom of the cup body and extends into a clear water area in the cup cover, the upper water inlet pipe is upwards communicated with the hydrogen generation chamber, a third valve body is installed at the water outlet end of the water pump, two water outlets of the third valve body are respectively connected with a first water outlet pipe and a second water outlet pipe, the first water outlet pipe is communicated with the hydrogen generation chamber, and the second water outlet pipe can be communicated with the water inlet of the first valve body;

the utility model discloses a maintenance liquid area in base, including base, second outlet pipe side, extractor discharge gate, second outlet pipe side intercommunication, extractor feed inlet is connected with the fourth valve body, two feed inlets of fourth valve body are connected with first material pipeline and second material pipeline of taking out respectively, the tip of first material pipeline of taking out is followed the cup body bottom is worn out and is stretched into in the cleaning liquid district in the base, the tip of second material pipeline of taking out is followed the cup body bottom is worn out and is stretched into in the maintenance liquid district in the base.

2. The hydrogen-rich water cup capable of displaying hydrogen concentration in real time according to claim 1, wherein: the cup body bottom is equipped with the external screw thread, the base top is rotated and is installed the screw sleeve, the screw sleeve inner ring is equipped with the screw thread, the internal thread of screw sleeve can with the external screw thread of cup body bottom passes through the screw thread installation.

3. The hydrogen-rich water cup capable of displaying hydrogen concentration in real time according to claim 1, wherein: the control system comprises an annular cavity which is arranged at the bottom in the cup body and is right opposite to the lower part of the rotating body, a rotating ring extending into the annular cavity is fixed at the bottom of the rotating body, a toothed ring is fixed on the outer circular surface of the rotating ring, a motor is fixed in the side wall of the annular cavity, and a gear meshed with the toothed ring is fixed on the output shaft of the motor.

4. The hydrogen-rich water cup capable of displaying hydrogen concentration in real time according to claim 1, wherein: and two drain pipes positioned at the bottom in the cup body are arranged on the side edges of the hydrogen measuring probe, the bottom ends of the drain pipes are just opposite to the upper part of the sewage area, and a fifth valve body is arranged in each drain pipe.

5. The hydrogen-rich water cup capable of displaying hydrogen concentration in real time according to claim 1, wherein: the master control module comprises a control panel arranged outside the cup body.

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