connector

By using symmetrically arranged conductor components and a multi-layered insulator structure design, the problem of directional insertion of the connector's positive and negative poles was solved, achieving a connector design that allows for flexible insertion and high safety, thereby improving signal transmission and electrical performance.

CN224342555UActive Publication Date: 2026-06-09SUNWODA ELECTRONICS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUNWODA ELECTRONICS CO LTD
Filing Date
2025-04-17
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In existing connector designs, the fixed positive and negative pins mean that they can only be inserted in a specific direction. Reverse insertion may cause a short circuit between the positive and negative pins, posing a safety hazard.

Method used

Design a connector that uses two sets of conductor assemblies symmetrically arranged with opposite polarities and mutual insulation, and arranged at intervals on an insulator, allowing the positive and negative poles to be inserted in any direction of the connector, and ensuring insulation and safety through a multi-layer insulator structure.

Benefits of technology

It eliminates the directional limitations of connector insertion, improves the flexibility and safety of use, ensures that the positive and negative poles are not short-circuited, and enhances the stability of signal transmission and electrical performance.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the battery technical field and discloses a connector with intersecting first and second directions, characterized in that the connector comprises two groups of conductor assemblies which are symmetrically arranged and have a symmetry plane parallel to the second direction, the conductor assembly comprises a first electrode and a second electrode, the first electrode and the second electrode are opposite in polarity, the first electrode and the second electrode are insulated from each other, and the first electrode and the second electrode are arranged at intervals along the first direction. The application can solve the problem of positive and negative electrode short circuit caused by wrong direction insertion of the connector.
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Description

Technical Field

[0001] This application relates to the field of battery technology, specifically to connectors. Background Technology

[0002] In the consumer lithium battery field, the connection between the battery and the power supply device is a crucial link in realizing power transmission and signal communication. This connection typically relies on connectors, which, as specialized electronic components, are designed to ensure a stable and reliable electrical connection between the battery and the power supply device. They not only bear the task of transmitting large currents but also transmit necessary control signals and status information, ensuring the normal operation of the entire system. Connector design must consider multiple aspects, including electrical performance, mechanical strength, ease of use, and safety, to adapt to the needs of different application scenarios.

[0003] In related technologies, positive and negative pins for carrying large currents are respectively set on the left and right sides of the connector, while a certain number of signal pins are arranged in the middle area for transmitting control signals and monitoring data. This design ensures efficient signal transmission while transmitting large currents. Specifically, the positive pins are usually located on one side of the connector, while the negative pins are correspondingly located on the other side. This layout gives the connector a clear directionality when inserted.

[0004] However, the directional requirements of existing connector designs also present certain limitations. Because the positive and negative pins are fixed at the left and right ends of the connector, and one side is typically designated as positive and the other as negative, the connector can only be inserted into the power supply device in a specific orientation. If inserted in the opposite direction, the positive and negative pins may misalign, causing a short circuit. This can damage the battery and power supply device, and may also lead to serious safety issues such as fire or electric shock. Utility Model Content

[0005] This application provides a connector to solve the problem of short circuit between positive and negative terminals caused by incorrect connector orientation.

[0006] In a first aspect, this application provides a connector having an intersecting first direction and a second direction, including two sets of conductor assemblies symmetrically arranged with their symmetry plane parallel to the second direction. Each conductor assembly includes a first electrode and a second electrode, the first electrode and the second electrode having opposite polarities, being mutually insulated, and being spaced apart along the first direction.

[0007] Beneficial effects: The connector's design allows the positive and negative poles (i.e., the first and second electrodes of the two sets of conductor assemblies) to be no longer limited to the left and right ends of the connector, but rather spaced apart in a first direction. Simultaneously, the symmetrical arrangement of the two first electrodes and two second electrodes of the two sets of conductor assemblies eliminates directional limitations during connector insertion, improving flexibility and convenience. Due to the symmetrical arrangement of the positive and negative poles (i.e., two positive poles between two negative poles, or two negative poles between two positive poles), even if the connector is inserted in opposite directions, a short circuit between the positive and negative poles will not occur, thus greatly improving safety during use.

[0008] In one optional embodiment, a first insulator is included, configured as a ring structure, and a set of the conductor components are respectively disposed on both sides of the first insulator along the first direction, wherein the first electrode is disposed on the outer sidewall of the first insulator and the second electrode is disposed on the inner sidewall of the first insulator.

[0009] Beneficial effects: The ring structure design of the first insulator allows the first and second electrodes of the two sets of conductor components to be arranged compactly, which not only achieves the relative fixation of the positions of the first and second electrodes, but also provides insulation.

[0010] In one optional embodiment, signal pins are provided on both the outer and inner sidewalls of the first insulator along the second direction. The signal pins on the outer sidewalls of the first insulator along the second direction are located between the two first electrodes, and the signal pins on the inner sidewalls of the first insulator along the second direction are located between the two second electrodes.

[0011] Beneficial effects: The signal pins are located on the outer and inner sidewalls of the first insulator, between the corresponding electrodes, ensuring the stability and reliability of signal transmission. Simultaneously, by providing multiple signal pins on the outer and inner sidewalls of the first insulator, the connector's signal transmission capability and data communication efficiency are improved.

[0012] In one optional embodiment, a first connecting portion is provided at both ends of the first electrode along the second direction, both of the first connecting portions extending toward the signal pin along the first direction, and both of the first connecting portions are respectively disposed on the outer periphery sidewall of the first insulator along the second direction; a second connecting portion is provided at both ends of the second electrode along the second direction, both of the second connecting portions extending toward the signal pin along the first direction, and both of the second connecting portions are respectively disposed on the inner periphery sidewall of the first insulator along the second direction.

[0013] Beneficial effects: The first and second electrodes located at both ends are positioned on the outer and inner sidewalls of the first insulator, further optimizing the electrode layout and improving the electrical performance and safety of the connector. This allows the two positive electrodes to cover the outside of the two negative electrodes, or vice versa, ensuring that the connector can be inserted in opposite directions without causing a short circuit between the positive and negative electrodes, significantly improving safety during use.

[0014] In one optional embodiment, a second insulator and a third insulator are included. The second insulator is configured as a ring structure and is sleeved on the outside of the third insulator. A gap is provided between the inner sidewall of the second insulator and the outer sidewall of the third insulator. A first electrode is respectively provided on both sides of the second insulator along the first direction and is connected to the inner sidewall of the second insulator. Two second electrodes of the two sets of conductor assemblies are respectively provided on both sides of the third insulator along the first direction and are connected to the outer sidewall of the third insulator.

[0015] Beneficial effects: The multi-layered structure design with a second and third insulator allows for a more flexible layout of electrodes and signal pins, improving the connector's structural strength and electrical performance. The multi-layered design also enables the connector to maintain high safety while offering greater flexibility in use.

[0016] In one optional embodiment, signal pins are provided on the inner sidewall of the second insulator along the second direction and the outer sidewall of the third insulator along the second direction. The signal pins on the inner sidewall of the second insulator along the second direction are located between the two first electrodes, and the signal pins on the outer sidewall of the third insulator along the second direction are located between the two second electrodes.

[0017] Beneficial effects: Signal pins are respectively set on the inner sidewall of the second insulator and the outer sidewall of the third insulator, realizing a multi-layer layout of signal pins and improving the stability and reliability of signal transmission.

[0018] In one optional embodiment, a third connecting portion is provided at both ends of the first electrode along the second direction, both of the third connecting portions extending toward the signal pin along the first direction, and both of the third connecting portions are respectively disposed on the inner sidewall of the second insulator along the second direction; a fourth connecting portion is provided at both ends of the second electrode along the second direction, both of the fourth connecting portions extending toward the signal pin along the first direction, and both of the fourth connecting portions are disposed on the outer sidewall of the third insulator along the second direction.

[0019] Beneficial effects: The first and second electrodes located at both ends are set on corresponding insulators, which further improves the flexibility of electrode layout and adapts to the needs of different application scenarios.

[0020] In one optional embodiment, a second insulator and a third insulator are included. The second insulator is configured as a ring structure and is sleeved on the outside of the third insulator. A gap is provided between the inner sidewall of the second insulator and the outer sidewall of the third insulator.

[0021] In this configuration, a first electrode is provided on each side of the second insulator along the first direction, and the first electrode is connected to the outer sidewall of the second insulator. Two second electrodes of the two sets of conductor assemblies are respectively provided on both sides of the third insulator along the first direction, and the second electrodes are connected to the outer sidewall of the third insulator.

[0022] Beneficial effects: By setting the two first electrodes of the two sets of conductor assemblies on the outer sidewall of the second insulator and setting the two second electrodes of the two sets of conductor assemblies on the outer sidewall of the third insulator, the outer layer layout of the electrodes is realized, which improves the electrical performance and heat dissipation performance of the connector.

[0023] In one optional embodiment, both the outer periphery of the second insulator along the second direction and the outer periphery of the third insulator along the second direction are provided with signal pins. The signal pins on the outer periphery of the second insulator along the second direction are located between the two first electrodes of the two sets of conductor assemblies, and the signal pins on the outer periphery of the third insulator along the second direction are located between the two second electrodes of the two sets of conductor assemblies.

[0024] Beneficial effects: Signal pins are set on the outer sidewalls of the second and third insulators respectively, realizing the outer layer layout of signal pins and improving the stability and anti-interference ability of signal transmission.

[0025] In one optional embodiment, a fifth connection portion is provided at both ends of the first electrode along the second direction, both of the fifth connection portions extending toward the signal pin along the first direction, and both of the fifth connection portions are respectively disposed on the outer periphery of the second insulator along the second direction; a sixth connection portion is provided at both ends of the second electrode along the second direction, both of the sixth connection portions extending toward the signal pin along the first direction, and both of the sixth connection portions are disposed on the outer periphery of the third insulator along the second direction.

[0026] Beneficial effects: The first and second electrodes at both ends are placed on the outer sidewall of the corresponding insulator along the second direction, which further optimizes the overall layout and electrical performance of the connector. Attached Figure Description

[0027] To more clearly illustrate the technical solutions in the specific embodiments of this application or the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.

[0028] Figure 1 This is a schematic diagram of the structure of a connector according to an embodiment of this application;

[0029] Figure 2 This is a schematic diagram of a connector according to an embodiment of the present application, in which the first electrode is located on the inner sidewall of the second insulator;

[0030] Figure 3 This is a schematic diagram of a connector according to an embodiment of the present application, in which the first electrode is located on the outer sidewall of the second insulator.

[0031] Explanation of reference numerals in the attached figures:

[0032] 1. First electrode; 2. Second electrode; 3. First insulator; 4. Signal pin; 5. Second insulator; 6. Third insulator; 7. First connecting part; 8. Second connecting part; 9. Third connecting part; 10. Fourth connecting part; 11. Fifth connecting part; 12. Sixth connecting part; X, First direction; Y, Second direction. Detailed Implementation

[0033] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0034] The following is combined Figures 1 to 3 This describes an embodiment of the present application.

[0035] According to an embodiment of this application, in one aspect, a connector is provided having an intersecting first direction X and a second direction Y, including two sets of conductor assemblies symmetrically arranged with their symmetry plane parallel to the second direction Y. The conductor assembly includes a first electrode 1 and a second electrode 2, the first electrode 1 and the second electrode 2 having opposite polarities, the first electrode 1 and the second electrode 2 being mutually insulated, and the first electrode 1 and the second electrode 2 being spaced apart along the first direction X.

[0036] Understandably, the two sets of conductor assemblies each include a positive and a negative electrode, and the two sets of conductor assemblies are spaced apart along the first direction X and are symmetrically arranged, such that the two positive electrodes of the two sets of conductor assemblies are located between the two negative electrodes, or the two negative electrodes of the two sets of conductor assemblies are located between the two positive electrodes. This arrangement allows for connection regardless of whether the connector is inserted directly or after being rotated 180 degrees, thus avoiding short circuits.

[0037] It should be noted that the symmetry planes of the two negative poles of the two sets of conductor assemblies are parallel to the second direction Y, and the symmetry planes of the two negative poles of the two sets of conductor assemblies are parallel to the second direction Y, so that the connector can be directly inserted or inserted after rotating 180 degrees to achieve connection.

[0038] In this embodiment, the connector's configuration allows the positive and negative electrodes (i.e., the first electrode 1 and the second electrode 2 of the two sets of conductor assemblies) to no longer be limited to the left and right ends of the connector, but can be spaced apart in the first direction X. Simultaneously, the two first electrodes 1 and the two second electrodes 2 of the two sets of conductor assemblies are symmetrically arranged, eliminating directional limitations during connector insertion and improving flexibility and convenience. Due to the symmetrical arrangement of the positive and negative electrodes (i.e., two positive electrodes between two negative electrodes, or two negative electrodes between two positive electrodes), even if the connector is inserted in opposite directions, a short circuit between the positive and negative electrodes will not occur, thereby greatly improving safety during use.

[0039] like Figure 1 As shown, in one embodiment, a first insulator 3 is provided, which is configured as a ring structure. A set of the conductor components are respectively provided on both sides of the first insulator 3 along the first direction X. The first electrode 1 is provided on the outer sidewall of the first insulator 3, and the second electrode 2 is provided on the inner sidewall of the first insulator 3.

[0040] It should be noted that placing the two second electrodes 2 of the two sets of conductor assemblies on the inner sidewall of the first insulator 3, and placing the two first electrodes 1 of the two sets of conductor assemblies on the outer sidewall of the first insulator 3, can be regarded as placing the positive and negative electrodes on the inner and outer sides of the first insulator 3 of the annular structure, respectively, so that relative insulation can be achieved through the first insulator 3.

[0041] In this embodiment, the annular structure design of the first insulator 3 enables the first electrode 1 and the second electrode 2 of the two sets of conductor components to be arranged compactly, which not only achieves the relative fixation of the positions of the first electrode 1 and the second electrode 2, but also provides insulation.

[0042] In one embodiment, signal pins 4 are provided on both the outer and inner sidewalls of the first insulator 3 along the second direction Y. The signal pins 4 on the outer sidewall of the first insulator 3 along the second direction Y are located between the two first electrodes 1 of the two sets of conductor assemblies, and the signal pins 4 on the inner sidewall of the first insulator 3 along the second direction Y are located between the two second electrodes 2 of the two sets of conductor assemblies.

[0043] It should be noted that the two sets of conductor assemblies are used to carry large currents, and signal pin 4 is used to transmit control signals and monitoring data.

[0044] In this embodiment, signal pins 4 are disposed on the outer and inner sidewalls of the first insulator 3 and located between the corresponding electrodes, ensuring the stability and reliability of signal transmission. Simultaneously, by disposing of multiple signal pins 4 on the outer and inner sidewalls of the first insulator 3, the signal transmission capability and data communication efficiency of the connector are improved.

[0045] In one embodiment, a first connecting portion 7 is provided at both ends of the first electrode 1 along the second direction Y. Both first connecting portions 7 extend along the first direction X toward the signal pin 4, and both first connecting portions 7 are respectively provided on the outer sidewall of the first insulator 3 along the second direction Y. A second connecting portion 8 is provided at both ends of the second electrode 2 along the second direction Y. Both second connecting portions 8 extend along the first direction X toward the signal pin 4, and both second connecting portions 8 are respectively provided on the inner sidewall of the first insulator 3 along the second direction Y.

[0046] Understandably, by setting two sets of conductor assemblies on the outer and inner sidewalls of the first insulator 3 along the first direction X, the whole structure can be made into a loop shape, making the connection process more convenient.

[0047] In this embodiment, the first electrode 1 and the second electrode 2 located at both ends are disposed on the outer and inner sidewalls of the first insulator 3, further optimizing the electrode layout and improving the electrical performance and safety of the connector. This ensures that the two positive electrodes cover the outside of the two negative electrodes, or vice versa, so that even when the connector is inserted in opposite directions, a short circuit between the positive and negative electrodes will not occur, further greatly improving safety during use.

[0048] like Figure 2As shown, in one embodiment, a second insulator 5 and a third insulator 6 are included. The second insulator 5 is configured as a ring structure and is sleeved on the outside of the third insulator 6. A gap is provided between the inner sidewall of the second insulator 5 and the outer sidewall of the third insulator 6. A first electrode 1 is respectively provided on both sides of the second insulator 5 along the first direction X, and the first electrode 1 is connected to the inner sidewall of the second insulator 5. Two second electrodes 2 of the two sets of conductor assemblies are respectively provided on both sides of the third insulator 6 along the first direction X, and the second electrode 2 is connected to the outer sidewall of the third insulator 6.

[0049] It should be noted that placing the two second electrodes 2 of the two sets of conductor assemblies on the outer sidewall of the third insulator 6, and placing the two first electrodes 1 of the two sets of conductor assemblies on the inner sidewall of the second insulator 5, can be regarded as setting the positive and negative electrodes inside and outside. Not only can relative insulation be achieved through the second insulator 5 and the third insulator 6, but insulation can also be achieved through the gap between the second insulator 5 and the third insulator 6.

[0050] In this embodiment, the multi-layer structure design of the second insulator 5 and the third insulator 6 enables a more flexible layout of the electrodes and signal pins 4, improving the structural strength and electrical performance of the connector. The multi-layer design allows the connector to maintain high safety while also offering greater flexibility in use.

[0051] In one embodiment, signal pins 4 are provided on the inner sidewall of the second insulator 5 along the second direction Y and the outer sidewall of the third insulator 6 along the second direction Y. The signal pins 4 on the inner sidewall of the second insulator 5 along the second direction Y are located between the two first electrodes 1, and the signal pins 4 on the outer sidewall of the third insulator 6 along the second direction Y are located between the two second electrodes 2.

[0052] In this embodiment, signal pins 4 are respectively provided on the inner sidewall of the second insulator 5 and the outer sidewall of the third insulator 6, realizing a multi-layer layout of signal pins 4 and improving the stability and reliability of signal transmission.

[0053] In one embodiment, a third connecting portion 9 is provided at both ends of the first electrode 1 along the second direction Y. Both third connecting portions 9 extend along the first direction X toward the signal pin 4, and both third connecting portions 9 are respectively provided on the inner sidewall of the second insulator 5 along the second direction Y. A fourth connecting portion 10 is provided at both ends of the second electrode 2 along the second direction Y. Both fourth connecting portions 10 extend along the first direction X toward the signal pin, and both fourth connecting portions 10 are provided on the outer sidewall of the third insulator 6 along the second direction Y.

[0054] Understandably, this allows the two sets of conductor assemblies to form a loop-shaped structure, making the connection process more convenient.

[0055] In this embodiment, the first electrode 1 and the second electrode 2 located at both ends are disposed on corresponding insulators, which further improves the flexibility of electrode layout and adapts to the needs of different application scenarios.

[0056] like Figure 3 As shown, in one embodiment, it includes a second insulator 5 and a third insulator 6. The second insulator 5 is configured as an annular structure and is sleeved on the outside of the third insulator 6. A gap is provided between the inner sidewall of the second insulator 5 and the outer sidewall of the third insulator 6.

[0057] In this configuration, a first electrode 1 is provided on each side of the second insulator 5 along the first direction X, and the first electrode 1 is connected to the outer sidewall of the second insulator 5. The two second electrodes 2 of the two sets of conductor assemblies are respectively provided on both sides of the third insulator 6 along the first direction X, and the second electrode 2 is connected to the outer sidewall of the third insulator 6.

[0058] It should be noted that placing the two second electrodes 2 of the two sets of conductor assemblies on the outer sidewall of the third insulator 6, and placing the two first electrodes 1 of the two sets of conductor assemblies on the outer sidewall of the second insulator 5, can be regarded as setting the positive and negative electrodes inside and outside. Not only can relative insulation be achieved through the second insulator 5 and the third insulator 6, but insulation can also be achieved through the gap between the second insulator 5 and the third insulator 6.

[0059] In this embodiment, by setting the two first electrodes 1 of the two sets of conductor assemblies on the outer sidewall of the second insulator 5, and setting the two second electrodes 2 of the two sets of conductor assemblies on the outer sidewall of the third insulator 6, the outer layer layout of the electrodes is realized, which improves the electrical performance and heat dissipation performance of the connector.

[0060] In one embodiment, both the second insulator 5 and the third insulator 6 are provided with signal pins 4 along the peripheral sidewall of the second direction Y. The signal pins 4 on the peripheral sidewall of the second insulator 5 along the second direction Y are located between the two first electrodes 1 of the two sets of conductor assemblies, and the signal pins 4 on the peripheral sidewall of the third insulator 6 along the second direction Y are located between the two second electrodes 2 of the two sets of conductor assemblies.

[0061] In this embodiment, signal pins 4 are respectively provided on the outer sidewalls of the second insulator 5 and the third insulator 6, realizing the outer layer layout of the signal pins 4 and improving the stability and anti-interference capability of signal transmission.

[0062] In one embodiment,

[0063] A fifth connection portion 11 is provided at both ends of the first electrode 1 along the second direction Y. Both fifth connection portions 11 extend along the first direction X toward the signal pin 4, and are respectively provided on the outer sidewall of the second insulator 5 along the second direction Y. A sixth connection portion 12 is provided at both ends of the second electrode 2 along the second direction Y. Both sixth connection portions 12 extend along the first direction X toward the signal pin, and are respectively provided on the outer sidewall of the third insulator 6 along the second direction Y.

[0064] Understandably, this allows the two sets of conductor assemblies to form a loop-shaped structure, making the connection process more convenient.

[0065] In this embodiment, the first electrode 1 and the second electrode 2 located at both ends are placed on the outer sidewall of the corresponding insulator along the second direction Y, which further optimizes the overall layout and electrical performance of the connector.

[0066] Although embodiments of this application have been described in conjunction with the accompanying drawings, those skilled in the art can make various modifications and variations without departing from the spirit and scope of this application, and all such modifications and variations fall within the scope defined by the appended claims.

Claims

1. A connector having intersecting first direction (X) and second direction (Y), characterized in that, include: Two sets of conductor components are symmetrically arranged, and the plane of symmetry is parallel to the second direction (Y). The conductor components include a first electrode (1) and a second electrode (2). The first electrode (1) and the second electrode (2) have opposite polarities and are mutually insulated. The first electrode (1) and the second electrode (2) are spaced apart along the first direction (X).

2. The connector according to claim 1, characterized in that, include: The first insulator (3) is configured as a ring structure. A set of conductor components are respectively provided on both sides of the first insulator (3) along the first direction (X). The first electrode (1) is provided on the outer sidewall of the first insulator (3), and the second electrode (2) is provided on the inner sidewall of the first insulator (3).

3. The connector according to claim 2, characterized in that, Signal pins (4) are provided on both the outer and inner sidewalls of the first insulator (3) along the second direction (Y). The signal pins (4) on the outer sidewall of the first insulator (3) along the second direction (Y) are located between the two first electrodes (1), and the signal pins (4) on the inner sidewall of the first insulator (3) along the second direction (Y) are located between the two second electrodes (2).

4. The connector according to claim 3, characterized in that, A first connecting portion (7) is provided at both ends of the first electrode (1) along the second direction (Y). Both first connecting portions (7) extend along the first direction (X) toward the signal pin (4) and are respectively disposed on the outer sidewall of the first insulator (3) along the second direction (Y). A second connecting portion (8) is provided at both ends of the second electrode (2) along the second direction (Y). Both second connecting portions (8) extend along the first direction (X) toward the signal pin (4) and are respectively disposed on the inner sidewall of the first insulator (3) along the second direction (Y).

5. The connector according to claim 1, characterized in that, include: The second insulator (5) and the third insulator (6) are provided. The second insulator (5) is configured as a ring structure. The second insulator (5) is sleeved on the outside of the third insulator (6). A gap is provided between the inner sidewall of the second insulator (5) and the outer sidewall of the third insulator (6). In this embodiment, a first electrode (1) is provided on both sides of the second insulator (5) along the first direction (X), and the first electrode (1) is connected to the inner sidewall of the second insulator (5). The two second electrodes (2) of the two sets of conductor assemblies are respectively provided on both sides of the third insulator (6) along the first direction (X), and the second electrode (2) is connected to the outer sidewall of the third insulator (6).

6. The connector according to claim 5, characterized in that, Signal pins (4) are provided on the inner sidewall of the second insulator (5) along the second direction (Y) and the outer sidewall of the third insulator (6) along the second direction (Y). The signal pins (4) on the inner sidewall of the second insulator (5) along the second direction (Y) are located between the two first electrodes (1), and the signal pins on the outer sidewall of the third insulator (6) along the second direction (Y) are located between the two second electrodes (2).

7. The connector according to claim 6, characterized in that, A third connecting portion (9) is provided at both ends of the first electrode (1) along the second direction (Y). Both third connecting portions (9) extend along the first direction (X) toward the signal pin (4) and are respectively disposed on the inner sidewall of the second insulator (5) along the second direction (Y). A fourth connecting portion (10) is provided at both ends of the second electrode (2) along the second direction (Y). Both fourth connecting portions (10) extend along the first direction (X) toward the signal pin and are respectively disposed on the outer sidewall of the third insulator (6) along the second direction (Y).

8. The connector according to claim 1, characterized in that, include: The second insulator (5) and the third insulator (6) are provided. The second insulator (5) is configured as a ring structure. The second insulator (5) is sleeved on the outside of the third insulator (6). A gap is provided between the inner sidewall of the second insulator (5) and the outer sidewall of the third insulator (6). In this embodiment, a first electrode (1) is provided on both sides of the second insulator (5) along the first direction (X), and the first electrode (1) is connected to the outer sidewall of the second insulator (5). Two second electrodes (2) of the two sets of conductor assemblies are respectively provided on both sides of the third insulator (6) along the first direction (X), and the second electrode (2) is connected to the outer sidewall of the third insulator (6).

9. The connector according to claim 8, characterized in that, Signal pins (4) are provided on the outer sidewall of the second insulator (5) along the second direction (Y) and the outer sidewall of the third insulator (6) along the second direction (Y). The signal pins on the outer sidewall of the second insulator along the second direction (Y) are located between the two first electrodes (1) of the two sets of conductor assemblies, and the signal pins on the outer sidewall of the third insulator along the second direction (Y) are located between the two second electrodes (2) of the two sets of conductor assemblies.

10. The connector according to claim 9, characterized in that, Fifth connecting portions (11) are respectively provided at both ends of the first electrode (1) along the second direction (Y). Both fifth connecting portions (11) extend along the first direction (X) toward the signal pin (4), and both fifth connecting portions (11) are respectively provided on the outer sidewall of the second insulator (5) along the second direction (Y). Sixth connecting portions (12) are respectively provided at both ends of the second electrode (2) along the second direction (Y). Both sixth connecting portions (12) extend along the first direction (X) toward the signal pin, and both sixth connecting portions (12) are provided on the outer sidewall of the third insulator (6) along the second direction (Y).