Intelligent energy-saving temperature control hydrogen-rich water cup

By employing a partition structure and a heat-conducting ring for heat dissipation in the hydrogen-rich water cup, the problem of simultaneously achieving heat preservation and temperature control in existing technologies has been solved, thus achieving energy-saving temperature control.

CN224493891UActive Publication Date: 2026-07-14ZHENGZHOU MINTER MEDICAL DEVICES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHENGZHOU MINTER MEDICAL DEVICES CO LTD
Filing Date
2025-08-12
Publication Date
2026-07-14

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    Figure CN224493891U_ABST
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Abstract

The utility model provides a kind of hydrogen-rich water cup of intelligent energy-saving temperature control, solve the problem that hydrogen-rich water cup cannot simultaneously realize the heat preservation of lower water storage space and the temperature control of upper hydrogen production space.The utility model includes base, cup body and cup cover, the inside of cup body is equipped with inner bag, the inside of inner bag is fixedly equipped with baffle, the inside space of inner bag is divided into lower water storage space and upper hydrogen production space by baffle, and electrolytic cell core is equipped on baffle;Baffle is equipped with the through hole that is penetrated from top to bottom, and on-off water component is equipped in through hole;The outside of inner bag is wrapped with heat preservation layer, and heat preservation layer corresponds with the inside and outside of lower water storage space, and the upper end of heat preservation layer extends between the upper end face and lower end face of baffle;The outside of inner bag includes being equipped with heat conduction ring, and heat conduction ring corresponds with the inside and outside of upper hydrogen production space, and the lower end of heat conduction ring is equipped with multiple downward heat conduction strips extending along its circumferential direction at intervals, and the lower end of heat conduction strip extends to the lower of inner bag and is connected with heat dissipation device.
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Description

Technical Field

[0001] This utility model relates to the field of water cup technology, and in particular to a smart, energy-saving, temperature-controlled hydrogen-rich water cup. Background Technology

[0002] Hydrogen-rich water, also known as hydrogen-rich water or simply "hydrogen water" in China, is made from hydrogen gas. Hydrogen is a colorless, tasteless, non-toxic, and odorless gas. Its unique properties give it many advantages in biological applications. One notable characteristic is its strong penetrability, allowing it to easily enter any part of a cell, such as the nucleus and mitochondria. This is a crucial feature that makes hydrogen useful for treating diseases. The main functions of hydrogen include: anti-oxidation, selective neutralization of hydroxyl radicals and nitrite anions, etc. Hydrogen ions combine with reactive oxygen species, reducing them to water, which is then excreted from the body.

[0003] Hydrogen-rich water cups are a type of health water cup that can generate drinking water rich in hydrogen. They mainly rely on electrolysis to generate hydrogen to increase the hydrogen content in the water. For example, a hydrogen-rich water cup with two separate sections disclosed in patent authorization number CN106618081B can achieve the purpose of making a small amount of hydrogen-rich water on the spot. However, there are still the following problems when using this type of split hydrogen-rich water cup: (1) When the hot water in the lower water storage space enters the upper hydrogen production space and is made into hydrogen-rich water, it is impossible to quickly and accurately control the temperature of the upper hydrogen-rich water, so that the human body cannot drink it quickly. Using the method of reproducing hydrogen to replenish hydrogen will cause waste of water resources and electricity; (2) It is impossible to simultaneously achieve the purpose of heat preservation of the lower water storage space and temperature control of the upper hydrogen production space. Utility Model Content

[0004] To address the problem in the prior art that hydrogen-rich water cups cannot simultaneously maintain the temperature of the lower water storage space and control the temperature of the upper hydrogen production space, this invention proposes an intelligent, energy-saving, and temperature-controlled hydrogen-rich water cup.

[0005] The technical solution of this utility model is: a smart energy-saving temperature-controlled hydrogen-rich water cup, including a base, a cup body and a cup lid, wherein the base is detachably connected to the bottom of the cup body and the cup lid is detachably connected to the top of the cup body;

[0006] The inner side of the cup body is provided with an inner liner, and the upper end of the inner liner protrudes outward to form an edge structure, which is fixedly connected to the inner side of the cup body.

[0007] The inner liner is fixedly equipped with a partition, which divides the internal space of the inner liner into a lower water storage space and an upper hydrogen production space. The partition is equipped with an electrolysis cell core.

[0008] The partition has through holes that allow water to flow through from top to bottom, and a water-blocking component is installed inside the through holes. When the cup is inverted, the water-blocking component can automatically open the through holes, and when the cup is upright, the water-blocking component can automatically close the through holes.

[0009] A water injection pipe is installed through the partition to connect to the lower water storage space. The upper end of the water injection pipe extends to the top of the partition, and a plug can be detached from the upper end of the water injection pipe.

[0010] The outer side of the inner liner is wrapped with an insulation layer, which corresponds to the inner and outer sides of the lower water storage space. The upper end of the insulation layer extends to the space between the upper and lower ends of the partition.

[0011] The outer side of the inner liner includes a heat-conducting ring, which corresponds to the inner and outer sides of the upper hydrogen production space. The lower end of the heat-conducting ring is provided with multiple downward-extending heat-conducting strips at intervals along its circumference. The lower ends of the heat-conducting strips extend to the bottom of the inner liner and are connected to the heat dissipation device.

[0012] The base contains a power supply component and a control board. Multiple switches are embedded in the side wall of the base. The power supply component, control board and switches are electrically connected in sequence. The multiple switches are electrically connected to the electrolytic cell core and heat dissipation device respectively.

[0013] The base has several ventilation holes on its side wall that connect the inside and outside, and the internal space of the base is connected to the internal space of the cup.

[0014] Preferably, a temperature sensor is embedded in the side wall of the inner liner. The temperature sensor is connected to the control board, and the temperature sensor can control the switch connected to the heat dissipation device to automatically cut off the power through the control board.

[0015] Preferably, a display screen is embedded on the outer wall of the base. The display screen is electrically connected to the control board and is used to display the temperature value detected by the temperature sensor.

[0016] Preferably, the heat dissipation device includes a thermoelectric cooler, which is connected to the lower end of the heat-conducting strip and electrically connected to the control board.

[0017] Preferably, the base is equipped with a cooling fan located directly below the heat dissipation device. The air intake direction of the cooling fan is from top to bottom, and the heat dissipation holes are located below the cooling fan. The cooling fan and the heat dissipation device are connected in series.

[0018] Preferably, the outer diameter of the inner liner is smaller than the inner diameter of the cup body, so that a ventilation layer is formed between the inner liner and the cup body, and the ventilation layer is connected to the internal space of the base;

[0019] The side wall of the cup body is provided with a first air inlet hole that communicates with the ventilation layer, and the first air inlet hole corresponds to the inner and outer sides of the heat conduction ring.

[0020] The outer rotating part of the cup body is fitted with a heat insulation ring that can completely cover the first air inlet. A second air inlet is provided on the heat insulation ring, which can connect or disconnect with the first air inlet as the heat insulation ring rotates.

[0021] Preferably, the water flow control assembly includes a water-passing component and a water-blocking component;

[0022] The water passage component includes an inner ring and an outer ring arranged coaxially. The upper surfaces of the inner ring and the outer ring are flush. The outer ring is fixedly installed on the inner side wall of the through hole in the partition. A first connecting rod is fixedly connected between the inner ring and the outer ring. A water passage hole that is open from top to bottom is formed between the inner ring, the first connecting rod and the outer ring.

[0023] The water-blocking component includes a second connecting rod that is movably inserted into the inner ring. The length of the second connecting rod is greater than the thickness of the inner ring. A water-blocking plate is fixedly provided at the upper end of the second connecting rod. The diameter of the water-blocking plate is greater than the inner diameter of the outer ring. A counterweight is fixedly provided at the lower end of the second connecting rod. The weight of the counterweight is greater than the buoyancy of the water-passing component in the water.

[0024] Preferably, the power supply component includes a battery and a charging port. The battery is located at the bottom inner side of the base, and the charging port is embedded in the side wall of the base. The charging port is electrically connected to the battery, and the battery is electrically connected to the control board.

[0025] Preferably, an annular plate surrounding the battery is fixedly provided on the inner bottom of the base, and a mounting bracket is detachably inserted into the inner side of the annular plate. The control board is installed on the top of the mounting bracket, and the control board is located above the battery with a gap between them.

[0026] Preferably, the upper end of the water injection pipe is connected to an enlarged port, the maximum inner diameter of which is larger than the inner diameter of the water injection pipe, and the plug can be installed inside the enlarged port.

[0027] The advantages of this invention are as follows: During use, the heat dissipation device cools the inner tank corresponding to the upper hydrogen production space through the direct heat conduction effect of the heat-conducting strips and rings. Simultaneously, the airflow exiting from the heat dissipation holes also carries away the heat dissipated by the control board and power supply components during operation, preventing heat accumulation. Meanwhile, the lower water storage space, due to its external insulation layer, is not rapidly cooled, thus achieving the goal of insulating the lower water storage space and controlling the temperature of the upper hydrogen production space. Attached Figure Description

[0028] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0029] Figure 1 This is a schematic diagram of the external structure of the hydrogen-rich water cup in Example 1;

[0030] Figure 2 This is a schematic diagram of the internal structure of the hydrogen-rich water cup in Example 1;

[0031] Figure 3 for Figure 2 A schematic diagram of the base structure;

[0032] Figure 4 for Figure 2 A schematic diagram of the installation structure of the partition and its components;

[0033] Figure 5 for Figure 4 A top-view structural diagram of the water-passing component;

[0034] Figure 6 for Figure 4 A schematic diagram of the water-blocking component in the middle;

[0035] Figure 7 for Figure 2 Enlarged view of the structure at point A in the image;

[0036] Figure 8 for Figure 7 A three-dimensional structural diagram of the heat insulation ring in the middle;

[0037] Figure 9 for Figure 2 Enlarged view of the structure at point B in the image;

[0038] In the diagram, 1. Base, 101. Heat dissipation hole, 2. Inner liner, 3. Cup body, 301. First air inlet, 4. Partition, 5. Insulation layer, 6. Heat-conducting sleeve, 7. Heat-conducting strip, 8. Semiconductor cooling chip, 9. Ventilation layer, 10. Heat insulation ring, 1001. Second air inlet, 11. Cooling fan, 12. Battery, 13. Control board, 14. Mounting bracket, 15. Ring plate, 16. Charging port, 17. Switch, 18. Electrolytic cell core, 19. Water passage component, 1901. Inner ring, 1902. Outer ring, 1903. First connecting rod, 1904. Water passage hole, 20. Water blocking component, 2001. Water blocking plate, 2002. Second connecting rod, 2003. Counterweight, 21. Cup lid, 22. Temperature sensor, 23. Water injection pipe, 24. Expanded diameter port, 25. Plug, 26. Display screen. Detailed Implementation

[0039] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0040] Example 1: A smart, energy-saving, temperature-controlled hydrogen-rich water cup, such as... Figure 1 and Figure 2 As shown, it includes a base 1, a cup body 3, and a cup lid 21. The base 1 is detachably connected to the bottom of the cup body 3, and the cup lid 21 is detachably connected to the top of the cup body 3.

[0041] The inner side of the cup body 3 is provided with an inner liner 2. The upper end of the inner liner 2 protrudes outward to form an edge structure, which is fixedly connected to the inner side of the cup body 3.

[0042] The outer diameter of the inner liner 2 is smaller than the inner diameter of the cup body 3, so that a ventilation layer 9 is formed between the inner liner 2 and the cup body 3, and the ventilation layer 9 is connected to the internal space of the base 1. A first air inlet 301 communicating with the ventilation layer 9 is opened on the side wall of the cup body 3, and the first air inlet 301 corresponds to the inner and outer sides of the heat-conducting ring 6. A heat insulation ring 10 is rotatably fitted on the outside of the cup body 3, and the heat insulation ring 10 can completely cover the first air inlet 301. A second air inlet 1001 is opened on the heat insulation ring 10, and the second air inlet 1001 can be connected to or disconnected from the first air inlet 301 as the heat insulation ring 10 rotates.

[0043] The inner liner 2 is fixedly equipped with a partition 4, which divides the internal space of the inner liner 2 into a lower water storage space and an upper hydrogen production space. An electrolyzer core 18 is provided on the partition 4. The electrolyzer core 18 is prior art, and its principle can be found in the relevant description of a hydrogen-rich water cup with upper and lower parts disclosed in application number 201710187830.3.

[0044] The partition 4 has a through hole that allows water to flow through from top to bottom, and a water-closing component is installed inside the through hole. When the cup body 3 is inverted, the water-closing component automatically opens the through hole; when the cup body 3 is upright, the water-closing component automatically closes the through hole. Specifically, as shown... Figure 4 , Figure 5 and Figure 6 As shown, the water flow control assembly includes a water-passing component 19 and a water-blocking component 20. The water-passing component 19 includes an inner ring 1901 and an outer ring 1902 arranged coaxially. The upper surfaces of the inner ring 1901 and the outer ring 1902 are flush. The outer ring 1902 is fixedly installed on the inner side wall of the through hole on the partition plate 4. A first connecting rod 1903 is fixedly connected between the inner ring 1901 and the outer ring 1902. A water-passing hole 1904 that is open from top to bottom is formed between the inner ring 1901, the first connecting rod 1903 and the outer ring 1902.

[0045] The water-blocking component 20 includes a second connecting rod 2002 that is movably inserted into the inner ring 1901. The length of the second connecting rod 2002 is greater than the thickness of the inner ring 1901. A water-blocking plate 2001 is fixedly provided at the upper end of the second connecting rod 2002. The diameter of the water-blocking plate 2001 is greater than the inner diameter of the outer ring 1902. A counterweight 2003 is fixedly provided at the lower end of the second connecting rod 2002. The weight of the counterweight 2003 is greater than the buoyancy of the water-passing component 19 in the water.

[0046] A water injection pipe 23, connecting to the lower water storage space, is installed on the partition 4. The upper end of the water injection pipe 23 extends above the partition 4. To facilitate water inflow, such as... Figure 4 As shown, in this embodiment, the upper end of the water injection pipe 23 is connected to an enlarged diameter port 24. The maximum inner diameter of the enlarged diameter port 24 is larger than the inner diameter of the water injection pipe 23, and a removable plug 25 is provided inside the enlarged diameter port 24.

[0047] The outer side of the inner liner 2 is covered with an insulation layer 5, which corresponds to the lower water storage space. The upper end of the insulation layer 5 extends to the space between the upper and lower surfaces of the partition 4.

[0048] The outer side of the inner liner 2 includes a heat-conducting ring 6, which corresponds to the inner and outer sides of the upper hydrogen production space. Multiple downward-extending heat-conducting strips 7 are spaced circumferentially along the lower end of the heat-conducting ring 6, with the lower ends of the heat-conducting strips 7 extending to the bottom of the inner liner 2 and connecting to a heat dissipation device. For example... Figure 2 As shown, in this embodiment, the heat dissipation device includes a semiconductor cooling chip 8, and the lower end of the heat-conducting strip 7 is bent inward to form an L-shaped structure, and the semiconductor cooling chip 8 is mounted on the L-shaped structure.

[0049] To enhance airflow speed and improve heat dissipation, such as Figure 2 and Figure 3 As shown, a cooling fan 11 is provided inside the base 1. The cooling fan 11 is located directly below the thermoelectric cooler 8. The air intake direction of the cooling fan 11 is from top to bottom. The heat dissipation hole 101 is located below the cooling fan 11. The cooling fan 11 is connected in series with the thermoelectric cooler 8.

[0050] The base 1 is equipped with a power supply component and a control board 13. Two switches 17 are embedded in the side wall of the base 1. The power supply component, the control board and the switches 17 are electrically connected in sequence. The two switches 17 are electrically connected to the electrolytic cell core 18 and the semiconductor cooling chip 8, respectively.

[0051] The power supply components in this embodiment include a battery 12 and a charging port 16. The battery 12 is located at the bottom inner side of the base 1, and the charging port 16 is embedded in the side wall of the base 1. The charging port 16 is electrically connected to the battery 12, and the battery 12 is electrically connected to the control board 13.

[0052] An annular plate 15 is fixedly provided on the inner bottom of the base 1, surrounding the battery 12. A mounting bracket 14 is detachably inserted into the inner side of the annular plate 15. The control board 13 is installed on the top of the mounting bracket 14. The control board 13 is located above the battery 12 and there is a gap between them, so that when the hydrogen-rich water is cooled, the heat dissipated by the control board 13 and the battery 12 during operation can be carried away at the same time to avoid heat accumulation.

[0053] Several heat dissipation holes 101 with internal and external communication are provided on the side wall of the base 1, and the internal space of the base 1 is connected to the internal space of the cup body 3.

[0054] A temperature sensor 22 is embedded in the side wall of the inner liner 2. The temperature sensor 22 is connected to the control board 13, and the temperature sensor 22 can control the switch 17 connected to the heat dissipation device to automatically cut off the power through the control board 13. A display screen 26 is embedded in the outer side wall of the base 1. The display screen 26 is electrically connected to the control board 13 and is used to display the temperature value detected by the temperature sensor 22. In this embodiment, the control board 13 is equipped with a timing module.

[0055] Working principle: Based on the pre-set constant temperature automatic power-off logic and hydrogen production duration logic in the control board 13, the control board 13 can automatically control the two switches 17 to automatically power off when the corresponding conditions are met.

[0056] Normally, hot water is stored in the lower water storage space of the inner tank 2 below the partition 4, and is kept warm by the insulation layer 5.

[0057] When you need to drink hydrogen-rich water, invert the cup body 3. The water blocking component 20 will slide down automatically, and the water blocking plate 2001 will separate from the top of the water passing component 19, so that the water passing hole 1904 will open automatically. The hot water in the lower water storage space will flow into the upper hydrogen production space through the water passing hole 1904. Then, put the cup body 3 back on its upright position, and the water blocking component 20 will slide down again. The water blocking plate 2001 will press against the top of the water passing component 19 under the pull of the counterweight 2003, sealing the water passing hole 1904.

[0058] Then, turn on the switch 17 that controls the electrolyzer core 18 to start electrolysis. When the hydrogen production time condition preset by the control board 13 is reached, the control board 13 automatically controls the switch 17 to turn off and stop hydrogen production in order to save energy.

[0059] The temperature of the hydrogen-rich water in the upper hydrogen production space is observed through the display screen 26. If the temperature is too high, the heat insulation ring 10 is rotated first, so that the second air inlet 1001 is connected to the first air inlet 301 as the heat insulation ring 10 rotates, thereby connecting the ventilation layer 9 with the outside air.

[0060] Then, turn on the corresponding switches 17 for controlling the thermoelectric cooler 8 and the cooling fan 11. The thermoelectric cooler 8 cools the inner liner 2 corresponding to the upper hydrogen production space through the direct heat conduction effect of the heat conduction strip 7 and the heat conduction ring 6. At the same time, the airflow generated by the rotation of the cooling fan 11 draws cold air from the outside into the ventilation layer 9, creating a wind-cooling effect on the heat conduction ring 6, the heat conduction strip 7, and the thermoelectric cooler 8. Meanwhile, when the airflow is discharged from the heat dissipation hole 101, it can also carry away the heat dissipated by the control board 13 and the battery 12 during operation, preventing heat accumulation.

[0061] The temperature of the lower water storage space will not drop rapidly because it is wrapped with an insulation layer 5, thus achieving the purpose of insulation of the lower water storage space and temperature control of the upper hydrogen production space.

[0062] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims and not by the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A smart, energy-saving, temperature-controlled hydrogen-rich water cup, characterized in that: It includes a base (1), a cup body (3) and a cup lid (21). The base (1) is detachably connected to the bottom of the cup body (3), and the cup lid (21) is detachably connected to the top of the cup body (3). The inner side of the cup body (3) is provided with an inner liner (2), and the upper port of the inner liner (2) protrudes outward to form an edge structure, which is fixedly connected to the inner side of the cup body (3). The inner liner (2) is fixedly provided with a partition (4), which divides the internal space of the inner liner (2) into a lower water storage space and an upper hydrogen production space. An electrolytic cell core (18) is provided on the partition (4). The partition (4) has a through hole that is open from top to bottom, and a water shut-off component is installed in the through hole; when the cup (3) is inverted, the water shut-off component can automatically open the through hole, and when the cup (3) is upright, the water shut-off component can automatically close the through hole; A water injection pipe (23) is installed on the partition (4) to connect to the lower water storage space. The upper end of the water injection pipe (23) extends to the top of the partition (4). A plug (25) can be detached from the upper end of the water injection pipe (23). The outer side of the inner liner (2) is covered with a heat insulation layer (5), which corresponds to the inner and outer sides of the lower water storage space. The upper end of the heat insulation layer (5) extends to the space between the upper and lower surfaces of the partition (4). The outer side of the inner liner (2) includes a heat-conducting ring (6), which corresponds to the inner and outer sides of the upper hydrogen production space. The lower end of the heat-conducting ring (6) is provided with multiple downward-extending heat-conducting strips (7) at intervals along its circumference. The lower ends of the heat-conducting strips (7) extend to the bottom of the inner liner (2) and are connected to the heat dissipation device. The base (1) is equipped with a power supply component and a control board (13). Multiple switches (17) are embedded on the side wall of the base (1). The power supply component, control board and switches (17) are electrically connected in sequence. Multiple switches (17) are electrically connected to the electrolytic cell core (18) and heat dissipation device respectively. Several heat dissipation holes (101) are provided on the side wall of the base (1), and the internal space of the base (1) is connected to the internal space of the cup body (3).

2. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: A temperature sensor (22) is embedded on the side wall of the inner liner (2). The temperature sensor (22) is connected to the control board (13). The temperature sensor (22) can control the switch (17) connected to the heat dissipation device to automatically cut off the power through the control board (13).

3. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: A display screen (26) is embedded on the outer wall of the base (1). The display screen (26) is electrically connected to the control board (13). The display screen (26) is used to display the temperature value detected by the temperature sensor (22).

4. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: The heat dissipation device includes a semiconductor cooling chip (8), which is connected to the lower end of the heat-conducting strip (7) and electrically connected to the control board (13).

5. A smart, energy-saving, temperature-controlled hydrogen-rich water cup as described in claim 1 or 4, characterized in that: The base (1) is equipped with a cooling fan (11), which is located directly below the heat dissipation device. The air intake direction of the cooling fan (11) is from top to bottom. The heat dissipation hole (101) is located below the cooling fan (11). The cooling fan (11) is connected in series with the heat dissipation device.

6. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 5, characterized in that: The outer diameter of the inner liner (2) is smaller than the inner diameter of the cup body (3) so that a ventilation layer (9) is formed between the inner liner (2) and the cup body (3), and the ventilation layer (9) is connected to the internal space of the base (1); The side wall of the cup body (3) is provided with a first air inlet (301) that communicates with the ventilation layer (9), and the first air inlet (301) corresponds to the inner and outer sides of the heat conduction ring (6); The outer rotating part of the cup body (3) is fitted with a heat insulation ring (10), which can completely cover the first air inlet (301). A second air inlet (1001) is provided on the heat insulation ring (10), and the second air inlet (1001) can be connected to or disconnected from the first air inlet (301) as the heat insulation ring (10) rotates.

7. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: The water supply and shut-off assembly includes a water-passing component (19) and a water-blocking component (20); The water passage component (19) includes an inner ring (1901) and an outer ring (1902) arranged coaxially. The upper surfaces of the inner ring (1901) and the outer ring (1902) are flush. The outer ring (1902) is fixedly installed on the inner side wall of the through hole on the partition plate (4). A first connecting rod (1903) is fixedly connected between the inner ring (1901) and the outer ring (1902). A water passage hole (1904) that is open from top to bottom is formed between the inner ring (1901), the first connecting rod (1903) and the outer ring (1902). The water-blocking component (20) includes a second connecting rod (2002) that is movably inserted inside the inner ring (1901). The length of the second connecting rod (2002) is greater than the thickness of the inner ring (1901). A water-blocking plate (2001) is fixedly provided at the upper end of the second connecting rod (2002). The diameter of the water-blocking plate (2001) is greater than the inner diameter of the outer ring (1902). A counterweight (2003) is fixedly provided at the lower end of the second connecting rod (2002). The weight of the counterweight (2003) is greater than the buoyancy of the water-passing component (19) in the water.

8. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: The power supply components include a battery (12) and a charging port (16). The battery (12) is located on the inner bottom of the base (1), and the charging port (16) is embedded in the side wall of the base (1). The charging port (16) is electrically connected to the battery (12), and the battery (12) is electrically connected to the control board (13).

9. The intelligent energy-saving temperature-controlled hydrogen-rich water cup as described in claim 8, characterized in that: An annular plate (15) surrounding the battery (12) is fixedly provided on the inner bottom of the base (1). A mounting bracket (14) is detachably inserted into the inner side of the annular plate (15). A control board (13) is installed on the top of the mounting bracket (14). The control board (13) is located above the battery (12) and there is a gap between them.

10. A smart, energy-saving, temperature-controlled hydrogen-rich water cup as described in claim 1, characterized in that: The upper end of the water injection pipe (23) is connected to an enlarged port (24). The maximum inner diameter of the enlarged port (24) is greater than the inner diameter of the water injection pipe (23). The plug (25) can be installed inside the enlarged port (24).