CN220585655U - Connector structure for charging - Google Patents

Abstract

The utility model relates to the field of connectors of motor vehicles, in particular to a connector structure for charging, which comprises: a charging connector, a heat conducting frame and a secondary lock assembly; the secondary lock component is connected to the charging connector in a sliding manner, and the heat conduction frame is fixedly connected to the secondary lock component; the charging connector comprises a power supply connection terminal, the heat conduction frame comprises a printed circuit board, a temperature sensor mounting assembly and a heat conductor are fixed on the printed circuit board, and the temperature sensor mounting assembly is in contact with the heat conductor; the heat conductor is in contact with the power connection terminal when the secondary lock assembly is slid to a final lock position. The utility model solves the technical problems of complex assembly and high production cost of the temperature acquisition device in the connector used in the existing automobile charging.

Description

Connector structure for charging

Technical Field

The utility model relates to the field of connectors of motor vehicles, in particular to a connector structure for charging.

Background

The charging connector is a common electrical connection member. With the increase of applications of the connector for charging, in order to secure the charging safety of the vehicle, it is necessary to obtain more data about the operation state of the connector, such as detecting the temperature of the connection terminal in the connector for charging, and it is necessary to quickly respond to the temperature of the connection terminal and accurately detect the temperature.

The connector of the prior art is internally provided with a temperature sensor to obtain the real-time temperature of the power transmission connection terminal, and the temperature sensor is electrically connected with the temperature sensor by using a conductive piece. However, in the structural design of the prior art, a conductive frame needs to be punched and bent firstly, then the conductive frame is injected into a secondary lock shell, and after injection molding is completed, a temperature sensor and a resistor are pressed into a punching terminal through a press machine, and two sets of dies are needed to be completed, so that the production cost is increased, and the assembly is complex.

Disclosure of Invention

The utility model aims to provide a charging connector structure which solves the technical problems that a temperature acquisition device in a charging connector used in the existing automobile charging process is complex in assembly and high in production cost.

In order to solve the above technical problems, the present utility model provides a charging connector structure, comprising: a charging connector, a heat conducting frame and a secondary lock assembly; the secondary lock component is connected to the charging connector in a sliding manner, and the heat conduction frame is fixedly connected to the secondary lock component; the charging connector comprises a power supply connection terminal, the heat conduction frame comprises a printed circuit board, a temperature sensor mounting assembly and a heat conductor are fixed on the printed circuit board, and the temperature sensor mounting assembly is in contact with the heat conductor; the heat conductor is in contact with the power connection terminal when the secondary lock assembly is slid to a final lock position.

Further, the printed circuit board is a multilayer printed circuit board, the printed circuit board is provided with an insert through hole, an external connector, a metal spring plate and a buckle metal spring plate, the insert through hole, the external connector, the metal spring plate and the buckle metal spring plate are respectively and electrically connected with the printed circuit board, and the external connector and the buckle metal spring plate are arranged on the same surface of the printed circuit board; the insert through holes penetrate through the multilayer printed circuit board; the external connector is positioned at the edge of the printed circuit board close to the temperature sensor mounting assembly and protrudes out of the printed circuit board; the metal spring plate is positioned at the conductive part of the plug-in through hole on the printed circuit board; the buckle metal elastic sheet is positioned in the surrounding area of the through hole of the plug-in unit.

Further, the secondary lock assembly comprises a bracket body, wherein the bracket body covers all or part of the heat conducting frame, and the external connector is exposed out of the bracket body.

Further, the charging connector further comprises a signal terminal, when the secondary lock assembly is located at the final locking position, the fastening metal elastic sheet is fastened with the signal terminal and electrically connected with the signal terminal, and the metal elastic sheet is elastically contacted with the signal terminal and electrically connected with the signal terminal.

Further, a blocking structure is arranged on the secondary lock assembly, and the blocking structure is arranged at the end part of the signal terminal, which is close to the buckle metal elastic sheet.

Further, the temperature sensor mounting assembly comprises a temperature sensor fixedly arranged on the printed circuit board, wherein the temperature sensor is fixedly connected with the heat conductor; and the resistor is fixedly arranged on the printed circuit board.

Further, the temperature sensor is a patch type sensor, and the resistor is a patch type resistor.

Further, the printed circuit board is provided with a recess in which the power supply connection terminal is located.

Further, the heat conductor is separated from the power connection terminal when the secondary lock assembly is slid to a pre-lock position.

Further, the heat conductor is a heat-conducting silica gel pad.

By adopting the technical scheme, the utility model has the following beneficial effects:

the utility model provides a charging connector structure, which is characterized in that a secondary lock assembly is connected to a charging connector in a sliding manner, a heat conduction frame is fixedly connected to the secondary lock assembly, and when the secondary lock assembly slides to a final lock position, a heat conductor is in close contact with a power supply connecting terminal, so that the temperature of the power supply connecting terminal is ensured to be collected by a temperature sensor. And the printed circuit board is used for realizing the electric connection of the temperature sensor mounting assembly, so that the cost of newly opening the stamping and bending terminal die is saved.

Drawings

In order to more clearly illustrate the technical solutions of the present utility model, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a charging connector structure according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a heat conducting frame according to an embodiment of the present utility model;

fig. 3 is a side view schematically illustrating a structure of a heat conductive frame according to an embodiment of the present utility model;

FIG. 4 is another side view of a schematic structural diagram of a thermally conductive frame provided by an embodiment of the present utility model;

fig. 5 is a schematic structural view of a charging connector according to an embodiment of the present utility model;

FIG. 6 is a schematic diagram of a secondary lock assembly according to an embodiment of the present utility model;

fig. 7 is a schematic structural diagram of a heat conducting frame according to an embodiment of the present utility model.

Wherein, the reference numerals in the figures correspond to: 1-connector for charging, 101-power connection terminal, 102-signal terminal, 2-heat conduction frame, 201-printed circuit board, 202-heat conductor, 203-plug-in through hole, 204-external connector, 205-metal shrapnel, 206-snap-in metal shrapnel, 207-temperature sensor, 208-resistor, 3-secondary lock assembly, 301-bracket body, 302-blocking structure.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 and 2, the present utility model discloses a connector structure for charging, comprising: a charging connector 1, a heat conduction frame 2 and a secondary lock assembly 3; the secondary lock assembly 3 is connected to the charging connector 1 in a sliding manner, and the heat conduction frame 2 is fixedly connected to the secondary lock assembly 3; the charging connector 1 comprises a power supply connection terminal 101, the heat conduction frame 2 comprises a printed circuit board 201, a temperature sensor mounting assembly and a heat conductor 202 are fixed on the printed circuit board 201, and the temperature sensor mounting assembly is in contact with the heat conductor 202; when the secondary lock assembly 3 is slid to the final lock position, the heat conductor 202 is in contact with the power connection terminal 101.

Optionally, the charging connector 1 further includes a housing, in which the power connection terminals 101 are accommodated, and the number and types of the power connection terminals 101 may be determined according to the use requirement, and the housing encloses the heat conductive frame 2 and the secondary lock assembly 3. The secondary lock assembly 3 is slidably connected to the charging connector 1, and the heat conductor 202 is in contact with the power supply connection terminal 101 when the secondary lock assembly 3 is slid to the final lock position. The secondary lock assembly 3 is slidably connected to the charging connector 1, the secondary lock assembly 3 is disposed in the housing of the charging connector 1 and is in contact with but not fixed to the housing, and the secondary lock assembly and the housing slide relatively between a pre-lock position and a final-lock position. The heat conductor 202 is assembled on the printed circuit board 201 of the heat conducting frame 2 and is in contact with the temperature sensor mounting assembly, the heat conductor 202 conducts the temperature of the power supply connection terminal 101 to the temperature sensor mounting assembly through the contact, and the temperature sensor mounting assembly is fixed on the printed circuit board 201 through welding. Illustratively, the thermally conductive body may be a thermally conductive silicone that matches the shape of the temperature sensor mounting assembly.

Optionally, the secondary lock assembly 3 comprises a holder body 301, and in the final lock position of the secondary lock assembly, the heat conductive frame 2 holds the power connection terminal 101 and the signal terminal 102 in the holder body 301, and the heat conductor 202 is in contact with the power connection terminal 101. The bracket body 301 has a connector terminal holding auxiliary structure for secondary protection and limitation of the terminal, preventing the terminal from coming off under the action of external tension, and causing circuit interruption.

In the embodiment of the present utility model, as further shown in fig. 2, the printed circuit board 201 is a multi-layer printed circuit board, and the printed circuit board is provided with a through hole 203, an external connector 204, a metal spring 205 and a snap metal spring 206, wherein the through hole 203, the external connector 204, the metal spring 205 and the snap metal spring 206 are respectively electrically connected to the printed circuit board 201, and the external connector 204 and the snap metal spring 206 are disposed on the same surface of the printed circuit board 201.

Optionally, the through-holes 203 penetrate through multiple layers of the printed circuit board 201, the through-holes 203 are used for accommodating fixed signal terminals, the number and the size of the through-holes 203 can be determined according to practical use requirements, the size of the through-holes 203 is matched with the signal terminals to be accommodated, and the through-holes have conductive parts.

Optionally, the external connector 204 is located on an edge of the printed circuit board 201 near the temperature sensor mounting assembly and protrudes from the printed circuit board 201. The external connector 204 is electrically connected to the temperature sensor mounting assembly via the printed circuit board 201. Alternatively, the external connector 204 may be a pin header for outputting detection information of the temperature sensor mounting assembly.

In the embodiment of the present utility model, as shown in fig. 3 and 4, the metal spring piece 205 is located at a conductive portion of the through hole 203 of the insert on the printed circuit board 201, and the fastening metal spring piece 206 is located in a surrounding area of the through hole 203 of the insert. The snap metal spring 206 is fixed around the insert through hole 203 by welding. Illustratively, the surrounding area is an area that partially surrounds, conforms to, and protrudes from the insert through hole 203.

Optionally, the metal spring piece 205 may be a stainless steel connection spring piece or a copper alloy connection spring piece, and the buckle metal spring piece 206 may also be a stainless steel connection spring piece or a copper alloy connection spring piece, where the metal spring piece 205 and the buckle metal spring piece 206 are used for fixing the signal terminals and are electrically connected with the signal terminals respectively. The number and the size of the metal spring pieces 205 and the snap metal spring pieces may be determined according to the actual use requirement, and the metal spring pieces 205 and the snap metal spring pieces 206 are matched and fixed to fix the signal terminal 102 to be placed in the insert through hole 203.

In the embodiment of the present utility model, as shown in fig. 5, the secondary lock assembly 3 includes a bracket body 301, the bracket body 301 covers all or part of the heat-conducting frame 2, and the external connector 204 is exposed from the bracket body 301.

Optionally, the holder body 301 encloses all or part of the heat conductive frame 2, so that the heat conductive frame slides together with the secondary lock assembly 3 when the secondary lock assembly 3 is slidably connected to the charging connector 1. The heat conductor 202 is in close contact with the power connection terminal 101 when the secondary lock assembly 3 is slid to the final lock position.

In this embodiment of the present utility model, the charging connector 1 further includes a signal terminal 102, when the secondary lock assembly 3 is located at the final lock position, the fastening metal spring 206 is fastened to and electrically connected with the signal terminal 102, and the metal spring 205 is elastically contacted and electrically connected with the signal terminal 102. The signal terminal 102 is inserted into the through-hole 203 to contact with the metal spring piece 205, and the metal spring piece 205 is elastically deformed, so as to generate a holding force, so that the signal terminal 102 is fixed in the through-hole 203.

Optionally, in this embodiment of the present utility model, the metal spring piece 205 is located at a conductive portion of the through hole 203 of the printed circuit board 201, and the snap metal spring piece 206 is located at a surrounding area of the through hole 203 of the plug. The signal terminals 102 are elastically contacted with the metal spring piece 205 and fixed in the through holes 203 of the plug, and the signal terminals are electrically connected with the printed circuit board 201 based on the metal spring piece. When the secondary lock assembly 3 slides to the final lock position, the signal terminal 102 is engaged with and electrically connected to the metal clip 206.

In the embodiment of the present utility model, as shown in fig. 6, a blocking structure 302 is disposed on the secondary lock assembly, and the blocking structure 302 is disposed at an end of the signal terminal 102 near the metal clip 206.

Optionally, the blocking structure 302 is configured to block the signal terminals 102 from being separated from the heat conductive frame 2, where the number and the size of the signal terminals 102 may be determined according to actual use requirements, and the number and the size of the signal terminals 102 are matched with the through holes 203 of the insert.

In an embodiment of the present utility model, as shown in fig. 2 and 7, the temperature sensor mounting assembly includes: a temperature sensor 207 fixedly arranged on the printed circuit board 201, the temperature sensor 207 being fixedly connected with the heat conductor 202; the resistor 208 is fixedly arranged on the printed circuit board 201.

Optionally, the temperature sensor 207 and the resistor 208 are fixedly soldered on the printed circuit board 201. The temperature sensor 207 is configured to detect a temperature of the power connection terminal 101, and the temperature sensor 207 is electrically connected to the external connector 204 to output temperature data. The resistor 208 is used to detect the connection state of the charging connector 1.

In the embodiment of the present utility model, the temperature sensor 207 is a chip type sensor, and the resistor 208 is a chip type resistor.

Optionally, the temperature sensor 207 and the resistor 208 are electrically connected through the printed circuit board 201, and the resistor and the temperature sensor can be soldered at one time through a surface assembly technology process to form a complete part, so that no redundant assembly crimping operation is needed during production and assembly.

In the embodiment of the present utility model, the printed circuit board 201 is provided with a recess, and the power connection terminal 101 is located in the recess.

In the embodiment of the present utility model, when the secondary lock assembly 3 slides to the pre-lock position, the heat conductor 202 is separated from the power connection terminal 101.

Optionally, when the secondary lock assembly 3 slides to the pre-lock position, the heat conductor 202 is separated from the power connection terminal 101, and the connector terminal holding auxiliary structure of the holder body 301 stops secondary protection and limitation of the signal terminal 102.

Optionally, the secondary lock assembly 3 comprises a holder body 301, and in the final lock position of the secondary lock assembly, the heat conductive frame 2 holds the power connection terminal 101 and the signal terminal 102 in the holder body 301, and the heat conductor 202 is in contact with the power connection terminal 101. The bracket body 301 has a connector terminal holding auxiliary structure for secondary protection and limitation of the terminal, preventing the terminal from coming off under the action of external tension, and causing circuit interruption.

The embodiment of the utility model has the following beneficial effects: the utility model provides a charging connector structure, which is characterized in that a secondary lock assembly is connected to a charging connector in a sliding manner, a heat conduction frame is fixedly connected to the secondary lock assembly, and when the secondary lock assembly slides to a final lock position, a heat conductor is in close contact with a power supply connecting terminal, so that the temperature of the power supply connecting terminal is ensured to be collected by a temperature sensor. And the printed circuit board is used for realizing the electric connection of the temperature sensor mounting assembly, so that the cost of newly opening the stamping and bending terminal die is saved. The temperature sensor and the resistor in the temperature sensor mounting assembly are designed into a patch type device, the resistor and the temperature sensor can be welded at one time through a surface assembly technology process to form a complete part, and redundant assembly crimping operation is not needed during production and assembly. The metal spring plate has reliable tin soldering property, can be directly welded on a printed circuit board, and can be welded on the printed circuit board together with the temperature sensor mounting assembly through a surface assembly technology process, so that the cost is reduced. The utility model provides a connector structure for charging, which solves the technical problems of complex assembly and high production cost of a temperature acquisition device in a connector used in the existing automobile charging.

The foregoing is only illustrative of the present utility model and is not to be construed as limiting thereof, but rather as various modifications, equivalent arrangements, improvements, etc., within the spirit and principles of the present utility model.

Claims (10)

1. A connector structure for charging, characterized by comprising: a charging connector (1), a heat conduction frame (2) and a secondary lock assembly (3);

the secondary lock assembly (3) is connected to the charging connector (1) in a sliding manner, and the heat conduction frame (2) is fixedly connected to the secondary lock assembly (3);

the charging connector (1) comprises a power supply connection terminal (101), the heat conduction frame (2) comprises a printed circuit board (201), a temperature sensor mounting assembly and a heat conductor (202) are fixed on the printed circuit board (201), and the temperature sensor mounting assembly is in contact with the heat conductor (202);

the heat conductor (202) is in contact with the power connection terminal (101) when the secondary lock assembly (3) is slid to a final lock position.

2. The charging connector structure according to claim 1, wherein,

the printed circuit board (201) is a multilayer printed circuit board, a plug-in through hole (203), an external connector (204), a metal spring piece (205) and a buckle metal spring piece (206) are arranged on the printed circuit board, the plug-in through hole (203), the external connector (204), the metal spring piece (205) and the buckle metal spring piece (206) are respectively electrically connected with the printed circuit board (201), and the external connector (204) and the buckle metal spring piece (206) are arranged on the same surface of the printed circuit board (201);

-said insert through holes (203) penetrating through a plurality of layers of said printed circuit board (201);

the external connector (204) is positioned at the edge of the printed circuit board (201) close to the temperature sensor mounting assembly and protrudes from the printed circuit board (201);

the metal spring piece (205) is positioned at a conductive part of the plug-in through hole (203) on the printed circuit board (201);

the fastening metal spring piece (206) is located in the surrounding area of the insert through hole (203).

3. The charging connector structure according to claim 2, wherein,

the secondary lock assembly (3) comprises a support body (301), the support body (301) is used for wrapping all or part of the heat conducting frame (2), and the external connector (204) is exposed out of the support body (301).

4. The charging connector structure according to claim 2, wherein the charging connector (1) further comprises a signal terminal (102),

when the secondary lock assembly (3) is located at a final lock position, the buckling metal elastic piece (206) is buckled with the signal terminal (102) and is electrically connected, and the metal elastic piece (205) is elastically contacted with the signal terminal (102) and is electrically connected.

5. The charging connector structure according to claim 4, wherein,

the secondary lock assembly is provided with a blocking structure (302), and the blocking structure (302) is arranged at the end part of the signal terminal (102) close to the buckle metal elastic sheet (206).

6. The charging connector structure according to claim 1, wherein,

the temperature sensor mounting assembly includes:

the temperature sensor (207) is fixedly arranged on the printed circuit board (201), and the temperature sensor (207) is fixedly connected with the heat conductor (202);

and the resistor (208) is fixedly arranged on the printed circuit board (201).

7. The charging connector structure according to claim 6, wherein,

the temperature sensor (207) is a patch type sensor, and the resistor (208) is a patch type resistor.

8. The charging connector structure according to claim 1, wherein,

the printed circuit board (201) is provided with a recess in which the power connection terminal (101) is located.

9. The charging connector structure according to claim 1, wherein,

when the secondary lock assembly (3) slides to a pre-lock position, the heat conductor (202) is separated from the power connection terminal (101).

10. The charging connector structure according to claim 1, wherein,

the heat conductor (202) is a heat-conducting silica gel pad.