Hydrogen-rich water injection nozzle
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HAIDUN ZHILIAN INTERNET OF THINGS TECH HEBEI CO LTD
- Filing Date
- 2025-06-18
- Publication Date
- 2026-07-14
AI Technical Summary
When filling hydrogen-rich sparkling water with existing automatic filling equipment, the drain pipe is prone to deviating due to high-pressure impact, causing water to splash everywhere and resulting in waste.
A hydrogen-rich water injector was designed. A support system consisting of a fixed sleeve, guide rail, guide block and telescopic sleeve rod stabilizes the drainage pipe. Combined with a ball valve to control the flow direction, it enables quick connection and flexible adjustment.
It effectively prevents the drainage pipe from shifting, reduces water spillage, improves filling stability and ease of operation, and reduces waste of hydrogen-rich water.
Smart Images

Figure CN224493734U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of water injection equipment technology, specifically to a hydrogen-rich water injection nozzle. Background Technology
[0002] Hydrogen-rich sparkling water can neutralize reactive oxygen species in the blood and cells.
[0003] After hydrogen-rich sparkling water is prepared, it needs to be bottled using filling equipment. However, in existing automatic filling equipment, after filling the hydrogen-rich sparkling water, the drain pipe is usually left to hang down naturally during the water dispensing process. Due to the lack of fixation and guidance for the drain pipe, the position of the drain pipe is easily deviated due to the impact force of the high-pressure hydrogen storage tank during the drainage process. This causes water to splash everywhere, resulting in unnecessary waste and spillage of hydrogen-rich sparkling water during filling. Utility Model Content
[0004] In view of this, the present invention provides a hydrogen-rich water nozzle that can provide auxiliary support for the drain pipe assembly through a fixing sleeve, thereby achieving stable water output and preventing the hydrogen-rich bubble water from spilling during filling, thus avoiding unnecessary waste of hydrogen-rich water.
[0005] To solve the above-mentioned technical problems, this utility model provides a hydrogen-rich water nozzle, including a three-way connector connected to a hydrogen-rich water storage tank. The three-way connector is equipped with an adjustment switch, which controls the connection of two pipes within the three-way connector. The three-way connector includes a connecting pipe assembly, which includes a branch pipe, a water injection pipe connected to the branch pipe, a water inlet pipe coaxial with the water injection pipe, and a drain pipe perpendicular to the axes of the water injection pipe and the water inlet pipe. A drain guide is inserted into the drain pipe, and a fixing sleeve is provided at the drain pipe. The fixing sleeve is slidably fitted onto the outside of the drain guide. This utility model enables quick connection between the hydrogen-rich water tank and the automatic filling machine through the connecting pipe assembly. Furthermore, the fixing sleeve provides auxiliary support for the drain guide, preventing excessive movement of the drain guide due to excessive water impact during dispensing, thus avoiding unnecessary waste caused by water splashing everywhere.
[0006] The regulating switch includes a reversing valve installed inside the diversion pipe, and a rotating handle is provided on the outside of the reversing valve. This utility model can adjust the rotation of the reversing valve by turning the rotating handle, thereby adjusting the liquid flow direction in the diversion pipe, which is more convenient and efficient.
[0007] A guide rail is provided on the outside of the diversion pipe, located below the drainage pipe. A guide block is slidably disposed within the guide rail, and a telescopic sleeve is provided on the upper part of the guide block. The telescopic sleeve includes a fixed cylinder disposed on the guide block, a spring disposed within the fixed cylinder, and a push rod disposed on the spring. A fixed seat is hinged to the upper part of the telescopic sleeve, and the fixed seat is hinged to the upper part of the push rod via a universal joint. A fixed sleeve is disposed on the upper part of the fixed seat. This utility model can achieve auxiliary support for the drainage pipe through the sliding action of the guide block within the guide rail and the action of the telescopic sleeve, greatly improving the stability of the drainage pipe during filling operations and making operation more convenient and stable.
[0008] The guide rail is provided with multiple fixing holes, and the guide block is provided with pin holes. Fixing pins are inserted into the fixing holes. The fixing pins can be inserted and fixed to the coaxial fixing holes and pin holes. This utility model can lock the position of the guide block after it has been adjusted by using multiple fixing holes in conjunction with the fixing pins.
[0009] The directional valve is a ball valve.
[0010] A sealing nut is provided at the lower part of the water inlet pipe. The internal thread of the sealing nut is compatible with the external thread of the water inlet pipe of the hydrogen-rich water storage tank. This utility model can achieve a quick and efficient connection between the T-connector and the water inlet pipe of the hydrogen-rich water storage tank by using the sealing nut in conjunction with the external thread of the water inlet pipe, which greatly improves the portability and efficiency of the connection.
[0011] In summary, compared with the prior art, this application includes at least one of the following beneficial technical effects:
[0012] 1. Effectively prevents drainage pipe misalignment and liquid splashing, reducing waste: This invention significantly enhances the stability of the drainage pipe under high-pressure water flow impact by setting a fixed sleeve that slides onto the outside of the drainage pipe, combined with a support system consisting of guide rails, guide blocks, and telescopic sleeve rods. This structure effectively suppresses the shaking and displacement of the pipe caused by water flow impact, fundamentally solving the problem of hydrogen-rich water splashing and spilling due to pipe misalignment during filling, and greatly reducing unnecessary waste of precious hydrogen-rich water.
[0013] 2. Providing adaptive support to ensure filling stability and flexibility: This invention utilizes the telescopic sleeve (including a spring) and universal joint design in the support structure to give the fixed sleeve flexible and adaptive support for the drainage conduit. The spring buffers the impact of water flow, while the universal joint allows the conduit to flexibly adjust its angle within a certain range. This ensures that during filling operations, the conduit is firmly supported to maintain a stable water flow trajectory, while also adapting to different operating angles or minor changes in the container's position, thus improving operational convenience and overall stability.
[0014] 3. Adjustable and securely locked position to adapt to diverse filling needs: This invention utilizes a sliding design of the guide block on the guide rail, combined with a locking mechanism of multiple fixing holes and fixing pins, to allow the position of the fixing sleeve supporting the drain pipe to be flexibly adjusted according to actual filling requirements (such as different bottle neck heights and spacing). Once adjusted, the fixing pins can quickly and reliably lock the guide block (and thus the entire support structure) in the preset position on the guide rail, ensuring the stability and reliability of the support point during the filling process and enhancing the equipment's adaptability to different filling scenarios.
[0015] 4. Convenient connection and efficient flow control, improving overall operational efficiency: This utility model achieves a quick and sealed connection with the inlet of the hydrogen-rich water storage tank through the sealing nut design at the bottom of the inlet pipe, simplifying the installation steps. Using a ball valve (reversing valve) with a rotating handle as the regulating switch, operators can efficiently and accurately control the flow direction of hydrogen-rich water in the diversion pipe (e.g., selecting to supply water to the injection or drainage pipe) simply by rotating the handle. The operation is intuitive and simple, significantly improving the control efficiency and convenience of the filling process. Attached Figure Description
[0016] Figure 1 This is a schematic diagram of the structure of the hydrogen-rich water injection nozzle of this utility model;
[0017] Figure 2 This is a front view of the hydrogen-rich water injector of this utility model;
[0018] Figure 3 This utility model Figure 2 Sectional view at point AA.
[0019] Explanation of reference numerals in the attached drawings: 100, T-joint; 110, Connecting pipe assembly; 111, Diverter pipe; 112, Water injection pipe; 113, Water inlet pipe; 114, Drain pipe; 120, Drainage guide pipe; 200, Adjusting switch; 201, Reversing valve; 202, Rotating handle; 300, Fixing sleeve; 400, Guide rail; 500, Guide block; 600, Telescopic sleeve rod; 700, Fixing base; 800, Fixing hole; 900, Fixing pin. Detailed Implementation
[0020] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the following will be described in conjunction with the accompanying drawings of the embodiments of this utility model. Figure 1-3 The technical solutions of the embodiments of this utility model are clearly and completely described herein. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. All other embodiments obtained by those skilled in the art based on the described embodiments of this utility model are within the protection scope of this utility model.
[0021] like Figure 1-3As shown: This embodiment provides a hydrogen-rich water injector, including a three-way connector 100 connected to a hydrogen-rich water storage tank. The three-way connector 100 is equipped with an adjustment switch 200, which controls the connection of two pipes within the three-way connector 100. The three-way connector 100 includes a connecting pipe assembly 110, which includes a branch pipe 111, a water injection pipe 112 connected to the branch pipe 111, a water inlet pipe 113 coaxial with the water injection pipe 112, and a pipe perpendicular to the axes of the water injection pipe 112 and the water inlet pipe 113. The drain pipe 114 has a drain conduit 120 inserted inside it. A fixing sleeve 300 is provided at the drain pipe 114 and is slidably fitted on the outside of the drain conduit 120. This utility model can achieve quick connection between the hydrogen-rich water tank and the automatic filling machine through the connecting pipe assembly 110. Moreover, the fixing sleeve 300 can provide auxiliary support for the drain conduit 120, avoiding unnecessary waste caused by excessive movement of the drain conduit 120 due to excessive impact force of the water when the hydrogen-rich water tank is dispensing water.
[0022] According to one embodiment of the present invention, such as Figure 1-3 As shown, the regulating switch 200 includes a reversing valve 201 disposed in the diversion pipe 111. The reversing valve 201 is a ball valve, and a T-shaped connecting hole is provided inside the reversing valve 201. When the rotating handle 202 on the outside of the reversing valve 201 is parallel to the direction of the inlet pipe 113, the horizontal through hole of the reversing valve 201 is connected to the inlet pipe 113 and the drain pipe 114. The rotating handle 202 is provided on the outside of the reversing valve 201. This utility model can realize the rotation adjustment of the reversing valve 201 by turning the rotating handle 202, thereby realizing the adjustment of the liquid flow direction in the diversion pipe 111, which is more convenient and efficient.
[0023] According to another embodiment of the present invention, such as Figure 1 and Figure 3 As shown, a guide rail 400 is provided on the outer side of the diversion pipe 111, and the guide rail 400 is located below the drainage pipe 120. A guide block 500 is slidably arranged inside the guide rail 400. A telescopic sleeve 600 is provided on the upper part of the guide block 500. The telescopic sleeve 600 includes a fixed cylinder arranged on the guide block 500, a spring arranged inside the fixed cylinder, and a push rod arranged on the spring. A fixed seat 700 is hinged to the upper part of the telescopic sleeve 600. The fixed seat 700 is hinged to the upper part of the push rod through a universal joint. A fixed sleeve 300 is arranged on the upper part of the fixed seat 700. This utility model can achieve auxiliary support for the drainage pipe 120 through the sliding action of the guide block 500 in the guide rail 400 and the action of the telescopic sleeve 600, which greatly improves the stability of the drainage pipe 120 during filling operations and makes operation more convenient and stable.
[0024] According to another embodiment of the present invention, such as Figure 2 and Figure 3 As shown, the guide rail 400 is provided with multiple fixing holes 800, the guide block 500 is provided with a pin hole, and a fixing pin 900 is inserted into the fixing hole 800. The fixing pin 900 can be inserted and fixed to the coaxial fixing hole 800 and pin hole. This utility model can lock the position of the guide block 500 after it has been adjusted by using multiple fixing holes 800 in conjunction with the fixing pin 900.
[0025] A sealing nut is provided at the lower part of the water inlet pipe 113. The internal thread of the sealing nut is compatible with the external thread of the water inlet pipe 113 of the hydrogen-rich water storage tank. This utility model can achieve a quick and efficient connection between the tee connector 100 and the water inlet pipe 113 of the hydrogen-rich water storage tank by using the sealing nut in conjunction with the external thread of the water inlet pipe 113, which greatly improves the portability and efficiency of the connection.
[0026] How to use this utility model:
[0027] First, it needs to be clarified that the water inlet involved in this utility model is mainly used for connecting the hydrogen-rich water storage tank to the automatic hydrogen-rich water filling machine. This utility model uses the water inlet during the filling and water dispensing process as an example to describe its usage in detail. When it is necessary to fill the hydrogen-rich water storage tank, the operator needs to use a wrench to tighten the sealing nut at the bottom of the three-way connector 100 to the water inlet pipe 113 at the top of the hydrogen-rich water storage tank. Then, the operator places the hydrogen-rich water storage tank on the filling station of the automatic filling machine, and then grasps the rotating handle 202 and rotates it 90 degrees clockwise. At this time, the automatic filling machine is started to carry out the filling operation. After filling is completed... The operator removes the hydrogen-rich water storage tank. When it is necessary to remove the water from the storage tank, the operator first adjusts the guide block 500 to the appropriate position according to the position of the container. Then, the fixing pin 900 is inserted into the fixing hole 800 and the pin hole to lock the adjusted guide block 500. The operator then grasps the rotating handle 202 and rotates it 90 degrees in the opposite direction to automatically dispense water. This invention significantly enhances the stability of the drainage pipe 120 under high-pressure water flow impact by setting a fixing sleeve 300 that slides on the outside of the drainage pipe 120 and combining it with the support system composed of guide rail 400, guide block 500, and telescopic sleeve rod 600. This structure can effectively suppress the shaking and displacement of the pipe caused by water flow impact, fundamentally solving the problem of hydrogen-rich water splashing and spilling everywhere due to pipe deviation during the filling process, and greatly reducing the unnecessary waste of precious hydrogen-rich water.
[0028] Furthermore, it should be noted that, in the description of this utility model, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.
[0029] The above description is the preferred embodiment of this utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the principle of this utility model, and these improvements and modifications should also be considered within the protection scope of this utility model.
Claims
1. A hydrogen-rich water injector, characterized in that: The device includes a three-way connector (100) connected to a hydrogen-rich water storage tank. The three-way connector (100) is equipped with an adjustment switch (200). The adjustment switch (200) can control the connection of two pipes of the three-way connector (100). The three-way connector (100) includes a connecting pipe assembly (110). The connecting pipe assembly (110) includes a diversion pipe (111), a water injection pipe (112) connected to the diversion pipe (111), a water inlet pipe (113) coaxial with the water injection pipe (112), and a drain pipe (114) perpendicular to the axes of the water injection pipe (112) and the water inlet pipe (113). A drain conduit (120) is inserted into the drain pipe (114). A fixing sleeve (300) is provided at the drain pipe (114). The fixing sleeve (300) is slidably sleeved on the outside of the drain conduit (120).
2. The hydrogen-rich water injector as described in claim 1, characterized in that: The regulating switch (200) includes a reversing valve (201) disposed in the diverter pipe (111), and a rotating handle (202) is disposed on the outside of the reversing valve (201).
3. The hydrogen-rich water injector as described in claim 2, characterized in that: A guide rail (400) is provided on the outside of the diversion pipe (111). The guide rail (400) is located below the drain pipe (120). A guide block (500) is slidably provided inside the guide rail (400). A telescopic sleeve rod (600) is provided on the upper part of the guide block (500). A fixed seat (700) is hinged on the upper part of the telescopic sleeve rod (600). A fixed sleeve (300) is provided on the upper part of the fixed seat (700).
4. The hydrogen-rich water injector as described in claim 3, characterized in that: The guide rail (400) is also provided with a plurality of fixing holes (800), the guide block (500) is provided with a pin hole, and a fixing pin (900) is inserted into the fixing hole (800). The fixing pin (900) can be inserted and fixed to the coaxial fixing hole (800) and pin hole.
5. The hydrogen-rich water injector as described in claim 4, characterized in that: The reversing valve (201) is a ball valve.
6. The hydrogen-rich water injector as described in claim 5, characterized in that: A sealing nut is provided at the lower part of the water inlet pipe (113), and the internal thread of the sealing nut is compatible with the external thread of the water inlet pipe (113) of the hydrogen-rich water storage tank.