A battery socket mounting structure
By installing the battery socket from the inside of the box cover and connecting it perpendicularly to the box cover in the battery socket installation structure, the safety hazards of bent wires and the large space occupation of traditional battery sockets are solved, thus improving safety and space utilization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HARBIN GUANGYU ELECTRONICS CO LTD
- Filing Date
- 2025-08-06
- Publication Date
- 2026-07-03
AI Technical Summary
The bending of wires in traditional battery sockets poses a safety hazard, and the connection between sockets requires the box cover to be closed, resulting in long wires and a large space occupation.
Design a battery socket installation structure so that the socket is installed from the inside of the box cover into the through groove, the wire lead-out direction is perpendicular to the plug direction to avoid bending, and it is connected to the box cover by fasteners such as bolts to ensure stability.
It reduces the safety hazards of wires, shortens the wire length between sockets, saves space, and improves battery capacity and battery life.
Smart Images

Figure CN224458865U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of battery socket technology, specifically to a battery socket installation structure. Background Technology
[0002] Electric vehicle batteries typically have one charging socket and one discharging socket. The external plug is inserted into the socket to enable charging and discharging functions.
[0003] Traditional sockets are straight-in, meaning the direction of the wire and the direction of the socket are in the same straight line. After the socket is installed from the outside of the box cover, the wire needs to be bent to the connection position. Bending the wire poses a safety hazard, and the wire connection between sockets needs to be done with the box cover on, and the wire is relatively long and takes up a lot of space. Utility Model Content
[0004] The purpose of this invention is to solve the safety hazards posed by bent wires and the problem of excessively long guide lengths resulting from the need to operate the wire connections between sockets while the cover is on. Therefore, it provides a battery socket installation structure.
[0005] The technical solution of this utility model is: a battery socket installation structure, including: a box cover, the box cover having a through groove for installing a socket;
[0006] The socket has at least one inserted into the through slot from the inside of the cover, the inside of the cover being the side where the wires are routed;
[0007] The socket is connected to a wire, and the direction of the wire leading out is perpendicular to the direction of the socket's insertion port.
[0008] Furthermore, the through slots have at least two spaced apart, and each through slot contains one of the sockets.
[0009] Furthermore, the socket is securely connected to the cover by fasteners.
[0010] Furthermore, the fastener is a bolt, one end of which passes through the expansion plate of the socket and is threadedly connected to the cover.
[0011] Furthermore, the bolts have at least two that are symmetrically distributed.
[0012] Furthermore, the socket is a charging dock.
[0013] Furthermore, the socket is a discharge socket.
[0014] Furthermore, the socket is both a charging socket and a discharging socket.
[0015] Compared with the prior art, the present invention has the following advantages:
[0016] 1. The battery socket installation structure provided by this utility model allows the socket to be installed from the inside of the box cover into the through groove. Since the direction of the lead wire is perpendicular to the direction of the plug, the wire does not need to be bent and can be extended directly to the connection position, reducing safety hazards. The wires between the sockets can be connected without the box cover, thereby shortening the wire connection length between the two sockets and saving the space occupied by the wires.
[0017] 2. The battery socket installation structure provided by this utility model has a smaller space occupied by the wires, and the space saved can be used to place more battery cells, increase battery capacity, and thus improve battery life. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 yes Figure 1 Top view;
[0020] Figure 3 yes Figure 2 Sectional view at point AA;
[0021] Figure 4 yes Figure 1 Exploded view;
[0022] Figure 5 yes Figure 4 A magnified view of the central socket.
[0023] In the diagram: 1. Box cover; 2. Socket; 3. Through groove; 4. Wire; 5. Fastener; 6. Expansion plate. Detailed Implementation
[0024] Specific implementation method one: Combining Figures 1 to 5 This embodiment includes a cover 1 and a socket 2. The cover 1 has a through groove 3 for installing the socket 2. The socket 2 has at least one part inserted into the through groove 3 from the inside of the cover 1. The inside of the cover 1 is the side where the wire 4 is routed, and the outside of the cover 1 is the side where the socket 2 is plugged. The socket 2 is connected to the wire 4. The direction of the wire 4 is perpendicular to the direction of the socket 2's plug. After being led out, the wire 4 extends to the connection position and is connected to the power cord.
[0025] In this embodiment of the battery socket installation structure, the socket 2 is installed from the inside of the cover 1 into the through groove 3. Since the lead-out direction of the wire 4 is perpendicular to the direction of the plug, the wire 4 does not need to be bent and can be directly extended to the connection position, reducing safety hazards. The wire 4 between the sockets 2 can be connected without the cover 1, thereby shortening the connection length of the wire 4 between the two sockets 2 and saving the space occupied by the wire 4.
[0026] Specific Implementation Method Two: Combining Figure 1 This embodiment differs from specific embodiment one in that it has at least two through slots 3 spaced apart, with one socket 2 installed in each through slot 3. In this embodiment, there are two through slots 3, and each through slot 3 is relatively small in volume, so it is not necessary to damage the area on the cover 1 between two adjacent through slots 3, thus ensuring the structural integrity of the cover 1 and preventing damage to the cover 1. Alternatively, there can be only one through slot 3, which is elongated in shape, with multiple sockets 2 installed in one through slot 3. Other components and connections are the same as in specific embodiment one.
[0027] Specific implementation method three: Combining Figure 2 , Figure 4 This embodiment differs from specific embodiment one in that the socket 2 is securely connected to the cover 1 via fasteners 5. This secure connection method is more reliable and facilitates disassembly and separation, making it convenient for replacing and repairing the socket 2. The socket 2 can also be connected to the cover 1 in other ways, such as by snap-fit or magnetic attraction. Other components and connections are the same as in specific embodiment one.
[0028] Specific implementation method four: Combination Figure 1 This embodiment differs from Specific Embodiment Three in that the fastener 5 is a bolt. One end of the bolt passes through the expansion plate 6 of the socket 2 and is threadedly connected to the cover 1. The bolt is installed from the inside of the cover 1, making installation and removal very convenient and providing good performance. The fastener 5 can also be a cylindrical pin, which simply passes through the expansion plate 6 of the socket 2 and the cover 1. Other components and connections are the same as in Specific Embodiment Three.
[0029] Specific Implementation Method Five: Combining Figure 1 , Figure 4 This embodiment differs from Specific Embodiment Four in that it has at least two bolts symmetrically distributed. In this embodiment, each socket 2 is fixed by two bolts. The connecting bolts ensure that the socket 2 will not rotate and also make the connection between the socket 2 and the cover 1 secure. Other components and connections are the same as in Specific Embodiment Four.
[0030] Specific Implementation Method Six: Combination Figures 1 to 5 This embodiment differs from Specific Embodiment 1 in that the socket 2 is a charging dock. This is the first combination of socket 2 in this embodiment, and different combination methods expand the application range of socket 2. Other components and connections are the same as in Specific Embodiment 1.
[0031] Specific implementation method seven: Combination Figures 1 to 5This embodiment differs from the first embodiment in that the socket 2 is a discharge socket. This is the second combination of socket 2 in this embodiment, which expands the application range of socket 2 through different combinations. Other components and connections are the same as in the first embodiment.
[0032] Specific implementation method eight: Combination Figures 1 to 5 This embodiment differs from Specific Embodiment 1 in that the socket 2 serves as both a charging and discharging socket, and there are at least two sockets 2. This is the third combination of sockets 2 in this embodiment, which expands the usability of the sockets 2 through different combinations. Other components and connections are the same as in Specific Embodiment 1.
[0033] Installation method of this embodiment:
[0034] Before installing socket 2, first connect the wires 4 between socket 2, then insert socket 2 into the through groove 3 from the inside of the box cover 1, and then use bolts to pass through the expansion plate 6 and thread them to the box cover 1 to complete the installation of socket 2.
[0035] The content of this utility model is not limited to the above-described embodiments; a combination of one or more specific embodiments can also achieve the purpose of the utility model.
Claims
1. A battery receptacle mounting structure characterized by comprising: include: A box cover (1) having a through groove (3) for mounting a socket (2); The socket (2) has at least one inserted into the through slot (3) from the inside of the cover (1), the inside of the cover (1) being the side where the wire (4) is routed; A wire (4) is connected to the socket (2), and the direction of the wire (4) is perpendicular to the direction of the socket (2).
2. The battery receptacle mounting structure of claim 1, wherein The through slots (3) have at least two spaced apart, and each through slot (3) contains one of the sockets (2).
3. The battery receptacle mounting structure of claim 1, wherein The socket (2) is fastened to the cover (1) by fasteners (5).
4. The battery receptacle mounting structure according to claim 3, wherein The fastener (5) is a bolt, one end of which passes through the expansion plate (6) of the socket (2) and is threadedly connected to the cover (1).
5. The battery socket mounting structure according to claim 4, characterized in that, The bolts have at least two that are symmetrically distributed.
6. The battery receptacle mounting structure of claim 1, wherein The socket (2) is a charging dock.
7. The battery receptacle mounting structure of claim 1, wherein The socket (2) is a discharge socket.
8. The battery receptacle mounting structure of claim 1, wherein The socket (2) is a charging socket and a discharging socket.