A water tap installation structure for a new energy battery that prevents detachment

By combining the tube, sliding sleeve, push rod and baffle, the problem of loose threaded connection of water nozzle for new energy battery cooling plate is solved, realizing fast and stable water nozzle installation and anti-loosening function, and enhancing the stability and sealing of the connection.

CN224454063UActive Publication Date: 2026-07-03ANHUI JUNYI PRECISION MANUFACTURING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ANHUI JUNYI PRECISION MANUFACTURING CO LTD
Filing Date
2025-08-22
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

The existing threaded connection between the cooling plate and the water nozzle of new energy batteries is difficult to install and remove and is prone to loosening, resulting in poor anti-detachment effect and inconvenience in use.

Method used

The system employs a combination structure of insert tube, sliding sleeve, push rod, and baffle. The insert tube is inserted into the connecting frame and pushes the sliding sleeve to retract the push rod into the push rod groove. The water nozzle is fixed by a spring and guide structure, and a sealing ring is used for a sealed connection to ensure that the water nozzle is not easily detached.

Benefits of technology

It enables rapid installation and stable connection of the faucet, avoids detachment due to vibration, improves installation efficiency and stability, and enhances the corrosion resistance of the connection structure.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224454063U_ABST
    Figure CN224454063U_ABST
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Abstract

This utility model discloses an anti-detachment water nozzle installation structure for new energy batteries, including a cooling plate with a connecting frame at one end. During installation, the water nozzle is inserted into the connecting frame via a tube, while a sliding sleeve is pushed to overcome the spring force of a first spring, causing the sleeve to misalign with a baffle. As the tube is inserted, it drives a push rod to retract into a push rod groove, overcoming the spring force of the first spring. The push rod, through a guide rod, causes the baffle to extend out of its groove. When the groove aligns with the push rod groove, the first spring pushes the push rod against the groove, releasing the sliding sleeve and aligning it with the baffle. This prevents the push rod from moving out of the groove, thus preventing the tube from being forced out of the connecting frame and preventing the water nozzle from detaching due to force or vibration after installation. This water nozzle installation structure allows for direct insertion and prevents detachment due to force or vibration, improving installation efficiency and stability.
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Description

Technical Field

[0001] This utility model relates to the field of water tap installation technology, specifically to a water tap installation structure for preventing detachment from new energy batteries. Background Technology

[0002] New energy vehicle batteries are a new type of automotive battery that uses new energy technologies to reduce greenhouse gas emissions. When new energy vehicles are in use, the new energy battery needs to be cooled by a cooling plate, and the cooling plate needs to be installed with a water nozzle to inject or discharge coolant into the cooling plate.

[0003] The existing connection between the cooling plate and the water nozzle of new energy batteries is generally made by threaded connection. However, it has been found that the threaded connection is not only difficult to install and remove, requiring repeated operation with a wrench, but also carries the risk of loosening due to vibration. Its anti-detachment effect is poor and it is inconvenient to use. Therefore, we have proposed an anti-detachment installation structure for new energy battery water nozzles to solve the problems mentioned above. Utility Model Content

[0004] The purpose of this utility model is to provide an anti-detachment water tap installation structure for new energy batteries, so as to solve the problems currently found in the market as mentioned in the background.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a water nozzle mounting structure for an anti-detachment new energy battery, comprising a cooling plate, a connecting frame connected to one end of the cooling plate, and a water nozzle disposed at the end of the connecting frame away from the cooling plate, wherein...

[0006] A fixing plate is fixedly connected to the middle of the outer side of the water nozzle. One end of the water nozzle is connected to a tube. A first sealing ring is installed at equal intervals on the outer side of the tube inside the connecting frame. A groove is opened on the outer side of the tube near the fixing plate. A top rod groove is opened at equal intervals on the inner wall of the groove on the connecting frame. A baffle groove is opened on the outer side of the top rod groove on the connecting frame. The baffle groove and the top rod groove are connected by a guide rod groove. A guide rod passes through the guide rod groove.

[0007] The guide rod is fixedly connected to a top rod at one end within the top rod groove. A first spring is sleeved on the guide rod between the top rod and the end of the top rod groove. A baffle is fixedly connected to the guide rod at one end within the baffle groove. A sliding sleeve is slidably provided on the outer side of the connecting frame. A spring groove is formed between the inner step of the sliding sleeve and the outer step of the connecting frame. A second spring is sleeved on the outer side of the connecting frame corresponding to the spring groove. The connection between the connecting frame and the water nozzle is sealed by a sealing mechanism.

[0008] Preferably, the groove is an annular groove, and the inner diameter of the groove's cross-section matches the outer diameter of the push rod.

[0009] Preferably, the outer dimensions of the baffle match the inner dimensions of the baffle groove, and the outer diameter of the baffle is larger than the inner diameter of the guide rod groove.

[0010] Preferably, the connecting frame has guide grooves equidistantly provided on the outer side of the corresponding sliding sleeve end, and the sliding sleeve has guide blocks fixedly connected to the inner wall of the corresponding guide groove.

[0011] Preferably, the sliding sleeve is elastically connected to the connecting frame via a second spring.

[0012] Preferably, the sealing mechanism includes a second sealing ring, and the outer sides of both ends of the connecting frame corresponding to the sliding sleeve are equipped with the second sealing ring, and the outer side of the insertion tube corresponding to the opening of the connecting frame is fitted with a third sealing ring.

[0013] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0014] This invention, during faucet installation, involves inserting the faucet into the connecting bracket via a insertion tube. Simultaneously, a sliding sleeve is pushed, causing it to move against the first spring's elasticity. This misaligns the sliding sleeve with the baffle, allowing the insertion tube to press against the spherical surface of the push rod. The push rod then retracts into the push rod groove against the first spring's elasticity. Simultaneously, the push rod, via a guide rod, causes the baffle to extend out of the baffle groove. When the groove and push rod groove are aligned, the first spring pushes the push rod against the groove. The sliding sleeve is then released, aligning with the baffle, preventing the push rod from moving out of the groove. This prevents the insertion tube from being forced out of the connecting bracket and avoids the faucet from detaching due to force or vibration after installation. This faucet installation structure allows for direct insertion and prevents detachment due to force or vibration, improving installation efficiency and stability.

[0015] In this invention, when the sliding sleeve moves, it drives the guide block to move within the guide groove. The guide structure formed by the guide groove and the guide block guides the movement of the sliding sleeve, preventing it from deviating. At the same time, it limits the movement stroke of the sliding sleeve. The sliding sleeve is elastically connected to the connecting frame via a second spring, so that the sliding sleeve is against the baffle in the normal state, thereby fixing the push rod and preventing it from being dislodged from the groove by force.

[0016] In this invention, after the water tap is installed, the openings at both ends of the sliding sleeve are sealed to the outside of the connecting frame through the second sealing ring, while the insertion tube is sealed to the inner wall of the opening of the connecting frame through the third sealing ring. The sealing mechanism can seal the connection structure of the water tap, prevent the connection structure of the water tap from being corroded, and effectively improve the stability of the water tap connection structure. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the structure of this utility model;

[0018] Figure 2 This is a cross-sectional structural diagram of the present invention;

[0019] Figure 3 This utility model Figure 2 A magnified schematic diagram of the structure at point A in the middle.

[0020] In the diagram: 1. Cooling plate; 2. Connecting frame; 3. Water nozzle; 4. Fixing plate; 5. Insert pipe; 6. First sealing ring; 7. Groove; 8. Top rod groove; 9. Guide rod groove; 10. Baffle groove; 11. Guide rod; 12. Top rod; 13. First spring; 14. Baffle; 15. Sliding sleeve; 16. Guide groove; 17. Guide block; 18. Spring groove; 19. Second spring; 20. Second sealing ring; 21. Third sealing ring. Detailed Implementation

[0021] 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.

[0022] Please see Figures 1 to 3 This utility model provides a technical solution: a water nozzle installation structure for an anti-detachment new energy battery, including a cooling plate 1, a connecting frame 2 connected to one end of the cooling plate 1, and a water nozzle 3 disposed at the end of the connecting frame 2 away from the cooling plate 1.

[0023] A fixing plate 4 is fixedly connected to the middle of the outer side of the water nozzle 3. One end of the water nozzle 3 is connected to the connecting frame 2 and a tube 5 is connected to it. The first sealing ring 6 is installed at equal intervals on the outer side of the tube 5 inside the connecting frame 2. A groove 7 is opened on the outer side of the tube 5 near the fixing plate 4. A top rod groove 8 is opened at equal intervals on the inner wall of the connecting frame 2 corresponding to the groove 7. A baffle groove 10 is opened on the outer side of the connecting frame 2 corresponding to the top rod groove 8. The baffle groove 10 and the top rod groove 8 are connected by a guide rod groove 9. A guide rod 11 passes through the guide rod groove 9.

[0024] One end of the guide rod 11 is fixedly connected to the top rod 12 inside the top rod groove 8. A first spring 13 is sleeved on the guide rod 11 between the top rod 12 and the end of the top rod groove 8. A baffle 14 is fixedly connected to one end of the guide rod 11 inside the baffle groove 10. A sliding sleeve 15 is slidably provided on the outside of the connecting frame 2. A spring groove 18 is formed between the inner step of the sliding sleeve 15 and the outer step of the connecting frame 2. A second spring 19 is sleeved on the outside of the connecting frame 2 corresponding to the spring groove 18. The connection between the connecting frame 2 and the water nozzle 3 is sealed by a sealing mechanism.

[0025] When installing the water nozzle 3, insert the water nozzle 3 into the connecting bracket 2 through the insert tube 5 (the connecting bracket 2 is annular and connected to the port of the cooling channel in the cooling plate 1). At the same time, push the sliding sleeve 15 to move against the elastic force of the first spring 13, causing the sliding sleeve 15 to be misaligned with the baffle 14. When the insert tube 5 is inserted, the insert tube 5 abuts against the spherical surface of the push rod 12, causing the push rod 12 to retract into the push rod groove 8 against the elastic force of the first spring 13. At the same time, the push rod 12 drives the baffle 14 to extend out of the baffle groove 10 through the guide rod 11, in the groove 7. When aligned with the push rod groove 8, the first spring 13 pushes the push rod 12 against the groove 7, and then the sliding sleeve 15 is released, so that the sliding sleeve 15 is aligned with the baffle 14 to prevent the push rod 12 from moving out of the groove 7. This prevents the insertion tube 5 from being moved out of the connecting bracket 2 by force, and prevents the water nozzle 3 from being dislodged by force or vibration after installation. With this water nozzle 3 installation structure, installation can be completed by direct insertion, and it can avoid being dislodged by force or vibration. This not only improves the installation efficiency of the water nozzle 3, but also has an anti-dislodging function, which improves the stability of the water nozzle 3 installation.

[0026] Please see Figures 1 to 3 The groove 7 is an annular groove, and the inner diameter of the groove 7 matches the outer diameter of the top rod 12. The outer dimensions of the baffle 14 match the inner dimensions of the baffle groove 10, and the outer diameter of the baffle 14 is larger than the inner diameter of the guide rod groove 9.

[0027] Please see Figures 1 to 3 The connecting frame 2 has guide grooves 16 equidistantly provided on the outer side of the corresponding end of the sliding sleeve 15. The sliding sleeve 15 is fixedly connected to the inner wall of the guide groove 16. The sliding sleeve 15 is elastically connected to the connecting frame 2 through the second spring 19. When the sliding sleeve 15 moves, it drives the guide block 17 to move in the guide groove 16. The guide structure formed by the guide groove 16 and the guide block 17 guides the movement of the sliding sleeve 15, preventing the sliding sleeve 15 from deviating. At the same time, it limits the movement stroke of the sliding sleeve 15. The sliding sleeve 15 is elastically connected to the connecting frame 2 through the second spring 19, so that the sliding sleeve 15 is against the baffle 14 in the normal state, thereby fixing the top rod 12 and preventing the top rod 12 from being moved out of the groove 7 by force.

[0028] Please see Figures 1 to 3 The sealing mechanism includes a second sealing ring 20. The outer sides of the connecting frame 2 corresponding to both ends of the sliding sleeve 15 are equipped with the second sealing ring 20. The outer side of the insertion tube 5 corresponding to the opening of the connecting frame 2 is fitted with a third sealing ring 21. After the water nozzle 3 is installed, the openings at both ends of the sliding sleeve 15 are sealed to the outer side of the connecting frame 2 through the second sealing ring 20, while the insertion tube 5 is sealed to the inner wall of the opening of the connecting frame 2 through the third sealing ring 21. Through the sealing mechanism, the connection structure of the water nozzle 3 can be sealed, preventing the connection structure of the water nozzle 3 from being corroded, and effectively improving the stability of the connection structure of the water nozzle 3.

[0029] Working principle: This anti-detachment water nozzle installation structure for new energy batteries involves inserting the water nozzle 3 into the connecting frame 2 via the insertion tube 5 (the connecting frame 2 is annular and connected to the port of the cooling channel in the cooling plate 1) during installation. Simultaneously, the sliding sleeve 15 is pushed, causing it to move against the elastic force of the first spring 13, thus misaligning the sliding sleeve 15 with the baffle 14. When the insertion tube 5 is inserted, it abuts against the spherical surface of the push rod 12, causing the push rod 12 to retract into the push rod groove 8 against the elastic force of the first spring 13. Simultaneously, the push rod 12, through the guide rod 11, drives the baffle 14 to extend... When the groove 7 and the push rod groove 8 are aligned, the first spring 13 pushes the push rod 12 against the groove 7. Then the sliding sleeve 15 is released so that the sliding sleeve 15 is aligned with the baffle 14, preventing the push rod 12 from moving out of the groove 7. This prevents the insertion tube 5 from being moved out of the connecting bracket 2 by force, and prevents the water nozzle 3 from being dislodged by force or vibration after installation. With this water nozzle 3 installation structure, installation can be completed by direct insertion, and it can prevent dislodging by force or vibration. This not only improves the installation efficiency of the water nozzle 3, but also has an anti-dislodgement function, which improves the stability of the water nozzle 3 installation.

[0030] When the sliding sleeve 15 moves, it drives the guide block 17 to move within the guide groove 16. The guide structure formed by the guide groove 16 and the guide block 17 guides the movement of the sliding sleeve 15, preventing it from deviating and limiting its travel. The sliding sleeve 15 is elastically connected to the connecting frame 2 via the second spring 19, ensuring that it abuts against the baffle 14 in normal conditions, thus fixing the push rod 12 and preventing it from being dislodged from the groove 7. After the water nozzle 3 is installed, the openings at both ends of the sliding sleeve 15 are sealed to the outside of the connecting frame 2 via the second sealing ring 20, while the insertion tube 5 is sealed to the inner wall of the opening of the connecting frame 2 via the third sealing ring 21. The sealing mechanism effectively seals the connection structure of the water nozzle 3, preventing corrosion and improving its stability.

[0031] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A new energy battery water nozzle anti-dropping mounting structure, comprising a cooling plate (1), characterized in that: The cooling plate (1) is connected to a connecting frame (2) at one end, and a water nozzle (3) is provided at the end of the connecting frame (2) away from the cooling plate (1). A fixing plate (4) is fixedly connected to the middle of the outer side of the water nozzle (3). One end of the water nozzle (3) is connected to a tube (5) corresponding to the connecting frame (2). A first sealing ring (6) is installed at equal intervals on the outer side of the tube (5) inside the connecting frame (2). A groove (7) is opened on the outer side of the tube (5) near the fixing plate (4). A top rod groove (8) is opened at equal intervals on the inner wall of the connecting frame (2) corresponding to the groove (7). A baffle groove (10) is opened on the outer side of the connecting frame (2) corresponding to the top rod groove (8). The baffle groove (10) and the top rod groove (8) are connected by a guide rod groove (9). A guide rod (11) passes through the guide rod groove (9). The guide rod (11) is located in the top rod groove (8) and one end is fixedly connected to the top rod (12). A first spring (13) is sleeved on the guide rod (11) between the top rod (12) and the end of the top rod groove (8). A baffle (14) is fixedly connected to one end of the guide rod (11) located in the baffle groove (10). A sliding sleeve (15) is slidably provided on the outside of the connecting frame (2). A spring groove (18) is formed between the inner step of the sliding sleeve (15) and the outer step of the connecting frame (2). A second spring (19) is sleeved on the outside of the connecting frame (2) corresponding to the spring groove (18). The connection between the connecting frame (2) and the water nozzle (3) is sealed by a sealing mechanism.

2. The anti-dropping new energy battery hydrant mounting structure according to claim 1, characterized in that: The groove (7) is an annular groove, and the inner diameter of the groove (7) matches the outer diameter of the top rod (12).

3. The anti-extraction new energy battery hydrant mounting structure according to claim 1, characterized in that: The outer dimensions of the baffle (14) match the inner dimensions of the baffle groove (10), and the outer diameter of the baffle (14) is larger than the inner diameter of the guide rod groove (9).

4. The anti-extraction new energy battery hydrant mounting structure according to claim 1, characterized in that: The connecting frame (2) has guide grooves (16) equidistantly opened on the outer side of the end of the sliding sleeve (15), and the inner wall of the sliding sleeve (15) is fixedly connected to the guide groove (16).

5. The anti-detachment water tap installation structure for a new energy battery according to claim 1, characterized in that: The sliding sleeve (15) is elastically connected to the connecting frame (2) via the second spring (19).

6. The anti-extraction new energy battery hydrant mounting structure according to claim 1, characterized in that: The sealing mechanism includes a second sealing ring (20), and the outer sides of the connecting frame (2) corresponding to both ends of the sliding sleeve (15) are equipped with the second sealing ring (20), and the outer side of the insertion tube (5) corresponding to the opening of the connecting frame (2) is fitted with a third sealing ring (21).