JP2019009138A - Fixing bracket, electric connector, and connector device - Google Patents

Abstract

To improve work efficiency of fitting a plug connector and a receptacle connector to each other.SOLUTION: There are provided receptacle fixation metal fittings 13 and 14 provided in a receptacle housing 11 included in a receptacle connector 10 configured to be insertable and extractable to/from a plug connector 50. Each of the receptacle fixation metal fittings 13 and 14 includes: a metal fitting body 33; a guide portion 27 that extends from the metal fitting body 33 and has a flat plate portion 32 the one part of which is embedded in the receptacle housing 11 and the other part of which is exposed from the receptacle housing 11, and in which the flat plate portion 32 constitutes a part of a first end inner wall surface 19 of the receptacle housing 11; and a pair of holding portions 28, which is provided so as to face each other in the metal fitting body 33 and holds plug fixation metal fittings 53 and 54 provided in the plug connector 50.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a fixture, an electrical connector, and a connector device.

  Patent Document 1 discloses a connector device for so-called board-to-board (board-to-board) connection, in which printed wiring boards (hereinafter also simply referred to as “boards”) are electrically connected to each other. It is disclosed. Such a connector device includes a plug connector and a receptacle connector. When the plug connector mounted on the board is fitted into the receptacle connector mounted on another board, the boards are electrically connected.

Japanese Patent Laying-Open No. 2015-185541

  The operation of assembling the electronic device having the connector device as described above includes the operation of mounting the plug connector and the receptacle connector on the substrate, and the operation of fitting the plug connector and the receptacle connector mounted on the substrate after the mounting process. And. Here, when these boards are faced to each other for fitting, the plug connector and the receptacle connector are hidden by the board, so that the operator may not be able to see the plug connector and the receptacle connector. For this reason, since the operator fits the plug connector into the receptacle connector by hand without visual observation, it is difficult to improve the efficiency of the work of fitting the plug connector and the receptacle connector together.

  Thus, the present disclosure describes a fixture, an electrical connector, and a connector device that can improve the efficiency of the work of fitting a plug connector and a receptacle connector together.

  One form of the present disclosure is a fixing bracket provided in a main body provided in an electrical connector configured to be insertable / removable with respect to a counterpart connector, and extends from the main body and the main body, and a part thereof is embedded in the main body. The other part has a flat plate part exposed from the main body, the flat plate part is provided so as to face each other in the metal fitting body and the guide part constituting the inner wall surface of the main body, and the counterpart fixing metal fitting provided on the counterpart connector And a pair of holding portions for sandwiching.

  The pair of holding portions may have elasticity along a direction in which the pair of holding portions face each other.

  Another embodiment of the present disclosure is an electrical connector configured to be insertable / removable with respect to a mating connector, and includes a main body and a fixing bracket provided on the main body. At both ends of the connecting portion extending from the metal fitting main body and the guide portion constituting the inner wall surface of the main body. And a pair of holding portions that are provided so as to face each other and sandwich a counterpart fixing bracket provided in the counterpart connector.

  A connector device according to still another embodiment of the present disclosure includes a plug connector and a receptacle connector configured to be insertable / removable with respect to the plug connector. The receptacle connector includes a main body and a fixing bracket provided on the main body. The fixing bracket extends from the bracket body and has a flat plate portion partially embedded in the main body and the other portion exposed from the main body, and the flat plate portion defines the inner wall surface of the main body. And a pair of holding portions that are provided so as to face each other at both ends of the connecting portion extending from the metal fitting body and sandwich the plug fixing metal fitting provided on the plug connector.

  According to the fixing bracket, the electrical connector, and the connector device according to the present disclosure, it is possible to improve the efficiency of the work of fitting the plug connector and the receptacle connector with each other.

FIG. 1 is a side view of a state in which the connector device according to the present disclosure is disassembled. FIG. 2 is a perspective view illustrating a state in which the connector device according to the present disclosure is disassembled. FIG. 3 is a perspective view showing the first fixing bracket. FIG. 4 is a perspective view showing the third fixing bracket. FIG. 5 is an enlarged plan view of the end of the receptacle connector. FIG. 6 is an enlarged plan view of the end of the plug connector. 7A is a plan view of an end portion of the connector device according to the comparative example, and FIG. 7B is a connector device for explaining the guide function performed by the connector device according to the present disclosure. It is the figure which planarly viewed the edge part. 8A is a side view of the connector device before insertion, and FIG. 8B is a plan view of the connector device shown in FIG. 8A. Parts (a) to (f) of FIG. 9 are side views of the connector device in order to explain the first guide function. FIGS. 10A to 10C are plan views of a connector device according to a comparative example for explaining the second guide function. (A) part-(d) part of Drawing 11 is a figure which planarly viewed the connector device concerning this indication for explaining the 2nd guide function. 12 (a) is a plan view of the end of the receptacle connector according to the present disclosure, and FIG. 12 (b) is a plan view of the end of the receptacle connector according to the comparative example. is there. FIG. 13 is a perspective view showing a chamfered portion in the receptacle connector. FIG. 14 is a perspective view showing a chamfered portion in the plug connector. Parts (a) and (b) of FIG. 15 are diagrams for explaining the third guide function. Parts (a) to (d) of FIG. 16 are diagrams for explaining the third guide function. FIG. 17A is a diagram showing the receptacle connector according to the modification in plan view, and FIG. 17B is a diagram showing the receptacle connector in another modification in plan view.

  The embodiments according to the present disclosure described below are examples for explaining the present invention. Therefore, the present invention should not be limited to the following contents. In the following description, the same elements are denoted by the same reference numerals, and redundant descriptions are omitted.

  As shown in FIG. 1, the connector device 1 according to the present disclosure includes a receptacle connector 10 (electric connector) and a plug connector 50 (mating connector). The receptacle connector 10 is mounted on one printed wiring board 2. The plug connector 50 is mounted on the other printed wiring board 3. The connector device 1 electrically connects the printed wiring boards 2 and 3 when the plug connector 50 is fitted to the receptacle connector 10.

  In the following description, various directions may be indicated using the XYZ coordinate system for convenience of description. The X-axis direction and the Y-axis direction are included in a virtual plane that is parallel to the printed wiring boards 2 and 3. The X-axis direction coincides with the longitudinal direction of the receptacle connector 10 and the plug connector 50 (left-right direction in FIG. 1). The Y-axis direction coincides with the short direction of the receptacle connector 10 and the plug connector 50 (the vertical direction in FIG. 1). The Z-axis direction coincides with the normal direction of the printed wiring boards 2 and 3 (vertical direction in FIG. 1). That is, the Z-axis direction coincides with the facing direction of the receptacle connector 10 and the plug connector 50.

[Receptacle connector]
First, the receptacle connector 10 will be described. As shown in FIG. 2, the receptacle connector 10 configured to be insertable / removable with respect to the plug connector 50 includes, as main components, a receptacle housing 11 (main body), a plurality of receptacle terminals 12 (main body terminals), The first receptacle fixing bracket 13 (first fixing bracket) and the second receptacle fixing bracket 14 (second fixing bracket) are provided.

  The receptacle housing 11 is a base body of the receptacle connector 10 and is formed of a material having electrical insulation. The receptacle housing 11 has a substantially rectangular parallelepiped shape extending in the X-axis direction (longitudinal direction, second direction). The receptacle housing 11 has a main surface 11 a that faces the plug connector 50 with the Z-axis direction as a normal direction.

  The receptacle housing 11 is provided with a recessed accommodating portion 16 for accommodating the plug connector 50. The accommodating part 16 is a recessed part with respect to the main surface 11a. The accommodating portion 16 includes a first main inner wall surface 17 that is one of the pair of main wall surfaces, a second main inner wall surface 18 that is the other of the pair of main wall surfaces, and a first end inner wall surface 19 (first end wall surface). A space surrounded by the second end inner wall surface 21 (second end wall surface) and the bottom surface 23. The first main inner wall surface 17 and the second main inner wall surface 18 extend along the X-axis direction and face each other in the Y-axis direction. The first end inner wall surface 19 is formed on one end side of the receptacle housing 11 in the X-axis direction, and connects one end of the first main inner wall surface 17 to one end of the second main inner wall surface 18. The first end inner wall surface 19 includes a plurality of surfaces having different normal directions. The second end inner wall surface 21 is formed on the other end side of the receptacle housing 11 in the X-axis direction, and the other end of the first main inner wall surface 17 is connected to the other end of the second main inner wall surface 18. Similar to the first end inner wall surface 19, the second end inner wall surface 21 includes a plurality of surfaces having different normal directions.

  The receptacle terminal 12 is a conductive component that ensures electrical connection between the printed wiring boards 2 and 3. The receptacle terminal 12 is a part integrally formed of a conductive material. A part of the receptacle terminal 12 is electrically connected to an electrode pad (not shown) of the printed wiring board 2 by solder or the like, and another part is connected to a plurality of plug terminals 52 (a plurality of counterpart terminals) described later. Can be connected electrically. The plurality of receptacle terminals 12 are arranged in the receptacle housing 11 so as to be aligned along the X-axis direction. Therefore, it can be said that the X-axis direction is the terminal arrangement direction. More specifically, the receptacle housing 11 has a plurality of recesses 24 that are recessed along the Y-axis direction with respect to the first main inner wall surface 17. The receptacle terminal 12 is disposed in each of the plurality of recesses 24. The receptacle housing 11 further has a plurality of recesses 24 that are recessed along the Y-axis direction with respect to the second main inner wall surface 18. The receptacle terminal 12 is also disposed in each of the plurality of recesses 24.

  The first receptacle fixing bracket 13 is disposed on one end side of the receptacle housing 11 in the X-axis direction. On the other hand, the second receptacle fixture 14 is disposed on the other end side of the receptacle housing 11 in the X-axis direction. That is, the first receptacle fixing bracket 13 and the second receptacle fixing bracket 14 are arranged so as to sandwich the plurality of receptacle terminals 12 in the X-axis direction. The first receptacle fixing bracket 13 and the second receptacle fixing bracket 14 physically fix the receptacle housing 11 to the printed wiring board 2. Further, the first receptacle fixing bracket 13 and the second receptacle fixing bracket 14 sandwich the plug connector 50 inserted into the accommodating portion 16. The first receptacle fixing bracket 13 and the second receptacle fixing bracket 14 may be electrically connected to the plug connector 50 for electrical connection with the plug connector 50.

  Further, the first receptacle fixing bracket 13 will be described in detail with reference to FIG. The second receptacle fixing bracket 14 is different only in the position where it is arranged with respect to the first receptacle fixing bracket 13, and has the same configuration as the first receptacle fixing bracket 13 as a single unit. .

  The first receptacle fixing metal fitting 13 has a substrate fixing part 26, a guide part 27, a holding part 28, and a metal fitting body 33 as main components, which are a plurality of bent parts 29a to 29d and connecting parts. They are integrated via 31a and 31b.

  The board fixing part 26 is a plate-like part that is physically fixed to the wiring pattern of the printed wiring board 2 by solder or the like. When arranged in the receptacle housing 11, the substrate fixing portion 26 extends along the Y-axis direction. A connecting portion 31a stands up in the Z-axis direction via a bent portion 29a at a substantially central portion of the substrate fixing portion 26 in the Y-axis direction. A bent portion 29b is provided at each end of the connecting portion 31a in the Y-axis direction, and a pair of connecting portions 31b extending along the X-axis direction are connected. A guide portion 27 extending along the Z-axis direction is connected to one end of each connection portion 31b. The guide portion 27 includes a bent portion 29 c and a flat plate portion 32. One end of the bent portion 29 c is continuous with the connection portion 31 b and the other end is continuous with the flat plate portion 32. The flat plate portion 32 extends from the bent portion 29c along the Z-axis direction, and its tip is a free end. The guide portion 27 is exposed from the receptacle housing 11 and constitutes a part of the first end inner wall surface 19.

  A metal fitting body 33 extends along the X-axis direction at a substantially central portion of the substrate fixing portion 26 in the Y-axis direction. An upright portion 34 extending along the Z-axis direction is formed at the tip of the metal fitting 33 via a bent portion 29d. In the metal fitting body 33, a pair of holding portions 28 are formed between one end continuous with the substrate fixing portion 26 and the other end continuous with the standing portion 34. The holding portion 28 has a curved shape extending in the Y-axis direction and the Z-axis direction. The holding unit 28 is not physically fixed to the receptacle housing 11 and has elasticity along the Y-axis direction.

[Plug connector]
The plug connector 50 will be described with reference to FIG. 2 again. A plug connector 50 configured to be insertable / removable with respect to the receptacle connector 10 includes, as main components, a plug housing 51 (plug body), a plurality of plug terminals 52, a first plug fixing metal 53, and a second plug. And a fixture 54.

  The plug housing 51 is a base body of the plug connector 50 and is formed of a material having electrical insulation. The plug housing 51 has a substantially rectangular parallelepiped shape extending in the X-axis direction (longitudinal direction, first direction). The plug housing 51 has a first main outer wall surface 57, a second main outer wall surface 58, a first end outer wall surface 59, a second end outer wall surface 61, a main surface 51a, and a substrate surface 51b.

  The first main outer wall surface 57 and the second main outer wall surface 58 extend along the X-axis direction and face each other in the Y-axis direction. The first end outer wall surface 59 is formed on one end side of the plug housing 51 and connects one end of the first main outer wall surface 57 to one end of the second main outer wall surface 58. The first end outer wall surface 59 includes a plurality of surfaces having different normal directions. The second end outer wall surface 61 is formed on the other end side of the plug housing 51 and connects the other end of the first main outer wall surface 57 to the other end of the second main outer wall surface 58. Similar to the first end outer wall surface 59, the second end outer wall surface 61 includes a plurality of surfaces having different normal directions.

  The plug terminal 52 is a conductive component that ensures electrical connection between the printed wiring boards 2 and 3. The plug terminal 52 is a component integrally formed of a conductive material. A part of the plug terminal 52 is electrically connected to an electrode pad (not shown) of the printed wiring board 3 by solder or the like, and another part can be electrically connected to the receptacle terminal 12 of the receptacle connector 10. It is said that. The plurality of plug terminals 52 are arranged in the plug housing 51 so as to be arranged along the X-axis direction.

  The first plug fixing metal 53 is disposed on one end side of the plug housing 51 in the X-axis direction. On the other hand, the second plug fixing metal 54 is disposed on the other end side in the X-axis direction of the plug housing 51. That is, the first plug fixing metal 53 and the second plug fixing metal 54 are arranged so as to sandwich the plurality of plug terminals 52 in the X-axis direction.

  The first plug fixing metal 53 and the second plug fixing metal 54 physically fix the plug housing 51 to the printed wiring board 3. In addition, the first plug fixing metal 53 and the second plug fixing metal 54 are sandwiched between the first receptacle fixing metal 13 and the second receptacle fixing metal 14 of the plug connector 50 when inserted into the housing portion 16. The first plug fixing bracket 53 may be electrically connected to the first receptacle fixing bracket 13 of the receptacle connector 10 for electrical connection with the receptacle connector 10, and the second plug fixing bracket 54 is connected to the receptacle connector 10. The second receptacle fixing bracket 14 may be electrically connected.

  Further, the first plug fixing bracket 53 will be described in detail with reference to FIG. The second plug fixing metal 54 is different only in the position where it is arranged with respect to the first plug fixing metal 53, and since it has the same configuration as the first plug fixing metal 53 as a single unit, detailed description thereof is omitted. .

  The first plug fixing metal 53 includes a substrate fixing part 66, a guide part 67, and a held part 68 as main components, which are connected via a plurality of bent parts 69a to 69d and a connecting part 71a. Integrated. The board fixing part 66 is a plate-like part that is physically fixed to the wiring pattern of the printed wiring board 3 by solder or the like. The substrate fixing part 66 extends along the Y-axis direction. One end of a connection portion 71a is connected to a substantially central portion of the substrate fixing portion 66 in the Y-axis direction via a bent portion 69a. A metal fitting body 72 is connected to the other end of the connecting portion 71a via a bent portion 69b. A bent portion 69c is provided on each side portion of the metal fitting main body 72 in the Y-axis direction, and a pair of held portions 68 extending along the Z-axis direction are connected. The held portion 68 stands up in the Z-axis direction and constitutes a part of the first main outer wall surface 57 and the second main outer wall surface 58 of the plug housing 51. When the plug connector 50 is fitted to the receptacle connector 10, the held portion 68 is sandwiched between the holding portions 28 of the first receptacle fixing bracket 13.

  A guide portion 67 is further continuous with the metal fitting body 72. The guide portion 67 includes a bent portion 69d and a flat plate portion 75. One end of the bent portion 69 d is continuous with the metal fitting body 72, and the other end is continuous with the flat plate portion 75. The flat plate portion 75 extends in the Z-axis direction from the bent portion 69d, and its tip is a free end. The guide portion 67 is exposed from the plug housing 51 and constitutes a part of the first end outer wall surface 59.

  Next, the detailed configuration on one end side of the receptacle connector 10 will be specifically described with reference to FIG. Note that the detailed configuration on the other end side of the receptacle connector 10 is the same as that on the one end side, and a specific description thereof will be omitted. Specifically, detailed description of the second receptacle guide surface (second guide region) in the second end inner wall surface 21 provided on the other end side of the receptacle connector 10 is omitted.

  As shown in FIG. 5, one end side of the receptacle connector 10 includes one end side of the first main inner wall surface 17 and the second main inner wall surface 18, and a first end inner wall surface 19. The first main inner wall surface 17 and the second main inner wall surface 18 are uneven surfaces formed by a plurality of planes. The receptacle terminal 12 is disposed in the recess 24a, and the holding portion 28 of the first receptacle fixing bracket 13 is disposed in the recess 24b. The first end inner wall surface 19 includes first receptacle guide surfaces 19a and 19b (first guide region) and a receptacle front end surface 19c. One end of the first receptacle guide surface 19 a is connected to one end of the first main inner wall surface 17. One end of the first receptacle guide surface 19 b is connected to one end of the second main inner wall surface 18. The receptacle front end surface 19c has one end connected to the other end of the first receptacle guide surface 19a and the other end connected to the other end of the first receptacle guide surface 19b. That is, the first end inner wall surface 19 includes a first receptacle guide surface 19a, a receptacle tip surface 19c, and a first receptacle guide surface 19b between one end of the first main inner wall surface 17 and one end of the second main inner wall surface 18. Are formed in this order.

  The first receptacle guide surface 19a faces the first receptacle guide surface 19b in the Y-axis direction. That is, the pair of first receptacle guide surfaces 19 a and 19 b are in a line-symmetric relationship with respect to the axis A <b> 1 along the X-axis direction of the receptacle housing 11. The separation width HR along the Y-axis direction from the first receptacle guide surface 19a to the first receptacle guide surface 19b is gradually narrowed toward the receptacle front end surface 19c. Specifically, the second separation width HR2 from the other end of the first receptacle guide surface 19a to the other end of the first receptacle guide surface 19b is such that one end of the first receptacle guide surface 19a extends to one end of the first receptacle guide surface 19b. It is narrower than the first separation width HR1. For example, when the relationship between the first separation width HR1 and the second separation width HR2 is shown as a ratio, when the first separation width HR1 is 1, the second separation width HR2 is 0.6 as an example.

  Such a structure results from the pair of first receptacle guide surfaces 19a and 19b being inclined with respect to the X-axis direction. For example, the angle between the first receptacle guide surface 19a and the X axis is 45 degrees as an example. As an example, the angle between the first receptacle guide surface 19b and the X axis is 45 degrees. In other words, it can be said that the first receptacle guide surface 19 a is inclined with respect to the first main inner wall surface 17, and the first receptacle guide surface 19 b is inclined with respect to the second main inner wall surface 18.

  Next, the detailed configuration on one end side of the plug connector 50 will be specifically described with reference to FIG. The detailed configuration on the other end side of the plug connector 50 has the same configuration as that on the one end side, and a specific description thereof will be omitted. As shown in FIG. 6, one end side of the plug connector 50 includes one end side of the first main outer wall surface 57 and the second main outer wall surface 58, and a first end outer wall surface 59. The first main outer wall surface 57 and the second main outer wall surface 58 are a pair of planes facing each other in the Y-axis direction. The first main outer wall surface 57 and the second main outer wall surface 58 are side wall surfaces of the plug housing 51. A plug terminal 52 is embedded in the plug housing 51, and a part of the plug terminal 52 is exposed from the plug housing 51 and constitutes a part of the first main outer wall surface 57 and the second main outer wall surface 58. Yes. The plug housing 51 has a first plug fixing metal 53 embedded therein, and a part of the first plug fixing metal 53 is exposed from the plug housing 51 and has a first main outer wall surface 57 and a second main outer wall surface. 58 is part of the configuration. That is, the first main outer wall surface 57 and the second main outer wall surface 58 are surfaces constituted by the plug housing 51, the plug terminal 52, and the first plug fixing metal 53.

  The first end outer wall surface 59 has a first plug guide surface 59a, a first plug guide surface 59b, and a plug tip surface 59c. One end of the first plug guide surface 59 a is connected to one end of the first main outer wall surface 57. One end of the first plug guide surface 59 b is connected to one end of the second main outer wall surface 58. One end of the plug front end surface 59c is connected to the other end of the first plug guide surface 59a, and the other end is connected to the other end of the first plug guide surface 59b. That is, the first end outer wall surface 59 is located between one end of the first main outer wall surface 57 and one end of the second main outer wall surface 58, the first plug guide surface 59a, the plug tip surface 59c, and the first plug guide surface 59b. Are formed in this order.

  The first plug guide surface 59a faces the first plug guide surface 59b in the Y-axis direction. That is, the first plug guide surface 59a and the first plug guide surface 59b are in a line-symmetric relationship with respect to the axis A2 along the X-axis direction of the plug housing 51. The housing width HP along the Y-axis direction from the first plug guide surface 59a to the first plug guide surface 59b is gradually narrowed toward the plug tip surface 59c. Specifically, the second housing width HP2 from the other end of the first plug guide surface 59a to the other end of the first plug guide surface 59b is equal to one end of the first plug guide surface 59a. It is narrower than the first housing width HP1. The second housing width HP2 is larger than the first separation width HR1 of the receptacle connector 10. Accordingly, the plug tip surface 59c of the plug connector 50 does not contact the receptacle tip surface 19c of the receptacle connector 10, and when the plug connector 50 is fitted in the receptacle connector 10, the receptacle tip surface 19c, the plug tip surface 59c, A gap is formed between the two.

  For example, when the relationship between the first housing width HP1 and the second housing width HP2 is shown as a ratio, when the first housing width HP1 is 1, the second housing width HP2 is 0.6 as an example. Such a structure results from the fact that the first plug guide surface 59a and the first plug guide surface 59b are inclined with respect to the X-axis direction. For example, the angle between the first plug guide surface 59a and the X axis is 45 degrees as an example. As an example, the angle between the first plug guide surface 59b and the X axis is 45 degrees. In other words, it can be said that the first plug guide surface 59 a is inclined with respect to the first main outer wall surface 57, and the first plug guide surface 59 b is inclined with respect to the second main outer wall surface 58.

  Here, a guide function performed by the receptacle connector 10 when the plug connector 50 is inserted into the receptacle connector 10 will be described. The guide function refers to a function of correcting the posture of the plug connector 50 to a posture that can be fitted to the receptacle connector 10. The “posture” here refers to a three-dimensional position based on the three-dimensional coordinates of the plug connector 50 with respect to the receptacle connector 10 and an inclination based on the axis of the three-dimensional coordinates. The position of the plug connector relative to the receptacle connector 10 is unique when the plug connector 50 can be physically fitted into the receptacle connector 10. Therefore, when inserting the receptacle connector 10 into the plug connector 50, it is desirable to insert the plug connector 50 after matching the posture of the plug connector 50 with respect to the receptacle connector 10 to a fitting posture. However, in an actual assembly operation, it takes time and effort to insert the plug connector 50 after making the posture of the plug connector 50 coincide with a fitting posture. Therefore, if the receptacle connector 10 or the plug connector 50 has a function of correcting the posture of the plug connector 50 to a fitting posture, the posture of the plug connector 50 is brought into a fitting posture at the start of insertion work. Even if they are not matched, the posture of the plug connector 50 is corrected during the insertion operation, and the plug connector 50 can be finally fitted to the receptacle connector 10.

<First guide function>
Part (a) of FIG. 7 is a view showing a receptacle connector 110 according to a comparative example. The receptacle connector 110 according to the comparative example has a pair of main inner wall surfaces 111. The separation width HR3 of the main inner wall surface 111 is the same size as the housing width HP3 of the plug connector 150. (B) part of Drawing 7 is a figure for explaining the 1st guide function which is one of the guide functions which receptacle connector 10 concerning this indication plays. 8A and 8B are simplified illustrations of the receptacle connectors 10 and 110 and the plug connectors 50 and 150, and are necessary for explaining the first guide function. Only the essential components are shown.

  7A, in the case of the receptacle connector 110 according to the comparative example, if the axis A2 of the plug connector 150 and the axis A1 of the receptacle connector 10 do not coincide with each other, the plug connector 150 is connected to the receptacle connector 110. Cannot be inserted into. That is, the receptacle connector 110 according to the comparative example cannot have a function of correcting the posture of the plug connector 150, and thus cannot be said to have a guide function.

  On the other hand, as shown in part (b) of FIG. 7, in the receptacle connector 10 according to the present disclosure, the receiving part (one end of one first receptacle guide surface 19 a and the other first one shown by the first separation width HR <b> 1). The gap between the one end of the receptacle guide surface 19b) is larger than the tip width (second housing width HP2) of the plug tip surface 59c of the plug connector 50. Accordingly, when the plug connector 50 is inserted into the receptacle connector 10, the displacement of the axis A2 of the plug connector 50 from the axis A1 of the receptacle connector 10 can be allowed by the difference between the first separation width HR1 and the second housing width HP2.

  For example, as shown in FIG. 8A, it is assumed that insertion in an oblique direction is started. Here, “oblique” means that the axis A2 of the plug connector 50 is inclined with respect to the Z-axis direction. 8B, the state where the plug connector 50 is displaced means that the axis A2 of the plug connector 50 is displaced in the Y-axis direction with respect to the axis A1 of the receptacle connector 10 in plan view. It is assumed that

  As shown in FIGS. 9 (a) and 9 (b), the arrow K1 from the state in which the plug connector 50 is separated from the receptacle connector 10 in the Z-axis direction (see FIG. 9 (a)). Insertion is started along the direction of. At this time, it is assumed that the axis A2 of the plug connector 50 is displaced along the Y-axis direction with respect to the axis A1 of the receptacle connector 10 (see part (b) of FIG. 9). Next, as shown in (c) and (d) of FIG. 9, the first plug guide surface 59a of the plug connector 50 abuts on the first receptacle guide surface 19a of the receptacle connector 10 (FIG. 9 ( d) see section). At this time, the first plug guide surface 59b of the plug connector 50 is not in contact with the first receptacle guide surface 19b of the receptacle connector 10 (see part (d) in FIG. 9). When the plug connector 50 is further inserted obliquely with the first plug guide surface 59a in contact with the first receptacle guide surface 19a, the plug connector 50 moves along the first receptacle guide surface 19a. Since this movement includes movement in the Y-axis direction, the axis A2 of the plug connector 50 gradually approaches the axis A1 of the receptacle connector 10. That is, the posture of the plug connector 50 is corrected. It can also be said that the first plug guide surface 59b of the plug connector 50 approaches the first receptacle guide surface 19b of the receptacle connector 10. When the first plug guide surface 59b of the plug connector 50 abuts on the first receptacle guide surface 19b of the receptacle connector 10 as shown in FIGS. 9 (e) and (f), the plug connector 50 The 50 axis A2 coincides with the axis A1 of the receptacle connector 10. That is, the posture of the plug connector 50 is corrected to a posture that can be fitted to the receptacle connector 10.

  In the above description, it is assumed that the receptacle connector 10 and the plug connector 50 are configured symmetrically with respect to the respective axis lines A1 and A2. However, the receptacle connector 10 and the plug connector 50 are respectively connected to the axis line. It may not be line symmetrical with respect to A1 and A2. In this case, the state in which the plug connector 50 can be fitted indicates a state in which the axes A1 and A2 are parallel to each other.

<Second guide function>
In short, the first guide function described above is a function for correcting the posture of the plug connector 50 in which the axis A2 is displaced in parallel with the axis A1 of the receptacle connector 10. The receptacle connector 10 of the present disclosure can further have a second guide function. The shift of the axis A1 may be shifted in parallel to each other and may be shifted so as to cross each other.

  As shown in FIG. 10A, it is assumed that the axis A2 of the plug connector 150 according to the comparative example is inclined with respect to the axis A1 of the receptacle connector 110 when viewed in plan. In this state, the plug connector 150 is inserted into the receptacle connector 110 along the axis A2. Then, as shown in FIG. 10B, one corner 151 of the plug connector 150 may come into contact with the receptacle front end surface 112 of the receptacle connector 110. In order to correct the displacement of the plug connector 150, the plug connector 150 is rotated around the Z-axis direction. However, as shown in part (c) of FIG. 10, the other corner 152 comes into contact with the main inner wall surface 111 and cannot be rotated any further. That is, the posture of the plug connector 150 cannot be corrected.

  On the other hand, as shown in FIGS. 11A to 11D, according to the receptacle connector 10 of the present disclosure, the axis A2 of the plug connector 50 is inclined with respect to the axis A1 of the receptacle connector 10 ( 11 (see the part (a) of FIG. 11), and the first receptacle guide surface 19b is in contact with the corner part 59d of the first plug guide surface 59b (see the part (b) of FIG. 11). A gap K2 is secured between the first plug guide surface 59a and the first receptacle guide surface 19a. For this reason, when the plug connector 50 is rotated around the Z-axis direction (see the part (c) in FIG. 11), the first plug guide surface 59a and the first receptacle guide surface 19a abut (see FIG. d) see section). In this state, the axis A2 of the plug connector 50 is not inclined with respect to the axis A1 of the receptacle connector 10. Accordingly, the posture of the plug connector 50 can be corrected to a posture that can be fitted to the receptacle connector 10. Such a second guide function can also be called an axis alignment function or an alignment function.

  An end configuration of the receptacle housing 11 in the receptacle connector 10 will be described from another viewpoint. As shown in FIG. 12A, a first end inner wall surface 19 is formed at the end of the receptacle housing 11. The first end inner wall surface 19 is a part of the wall body 36 surrounding the accommodating portion 16, and a wall portion 36 a is formed including the first end inner wall surface 19 and the outer end surface 11 b. Here, when the plug connector 50 is fitted to the receptacle connector 10, the locations of the receptacle connector 10 with which the plug housing 51 of the plug connector 50 can abut are the pair of first receptacle guide surfaces 19a and 19b. For example, when the plug connector 50 comes into contact with the first receptacle guide surface 19a and an external force F1 along the X-axis direction is applied to the plug connector 50, the plug connector 50 presses the first receptacle guide surface 19a. This pressing force F2 acts perpendicularly to the first receptacle guide surface 19a. Since the wall portion 36a has a sufficient thickness with respect to the pressing force F2, the wall portion 36a can suitably counter the pressing force F2. Furthermore, when the wall portion 36a is designed to have the required strength, the length in the X-axis direction can be shortened. Therefore, the length of the receptacle connector 10 in the X-axis direction can be shortened.

  The end configuration of the receptacle connector 10 according to the present disclosure will be further described in comparison with the receptacle connector 110 according to the comparative example shown in the part (b) of FIG. For example, the receptacle connector 110 according to the comparative example shown in part (b) of FIG. 12 has a pair of guide surfaces 114 provided on each of the pair of main inner wall surfaces 111. Assume that the length (guide width) of the guide surface 114 in the X-axis direction is set to a predetermined value (length L1). In this case, the length L2 from the guide surface to the outer end surface 116 of the receptacle connector 110 is at least the length L1 or more. Further, in the receptacle connector 110, a portion that opposes the pressing force F <b> 3 applied from the plug connector 150 is an end wall 117. Therefore, it is necessary to secure the thickness so that the end wall 117 also has sufficient strength.

  On the other hand, in the receptacle connector 10 according to the present disclosure shown in FIG. 12A, the pair of first receptacle guide surfaces 19a and 19b are formed so as to be inclined with respect to the X-axis direction. According to this configuration, when the length along the surface of the first receptacle guide surface 19a is the length L1, the length L3 of the first receptacle guide surface 19a along the X-axis direction is the cosine of the length L1. Component (cosine component). Therefore, the length L3 of the first receptacle guide surface 19a of the receptacle connector 10 is shorter than the length L1 of the guide surface 114 of the receptacle connector 110 when compared with the length in the X-axis direction. Furthermore, as described above, in the receptacle connector 10 according to the present disclosure, the external force F1 applied from the plug connector 50 is borne by the wall portion 36a. Further, since a gap is provided between the receptacle front end surface 19c and the plug front end surface 59c, no pressing force is applied from the plug connector 50. For this reason, the end wall constituted by the receptacle front end surface 19c is not required to be as thick as the end wall 117 according to the comparative example. Therefore, the receptacle connector 10 according to the present disclosure can be shorter in the X-axis direction than the receptacle connector 110 according to the comparative example.

  Hereinafter, the first chamfered portion 37 in the receptacle connector 10 will be described with reference to FIG. Next, the third chamfered portion 77 in the plug connector 50 will be described with reference to FIG. A third guide function that can be achieved when the plug connector 50 is inserted into the receptacle connector 10 will be described with reference to FIG.

  The first chamfered portion 37 shown in FIG. 13 will be described. Since the second chamfered portion 38 (see FIG. 2) has the same configuration as the first chamfered portion 37, detailed description thereof is omitted. The receptacle 16 of the receptacle connector 10 includes an opening 16 a that receives the plug connector 50. The opening 16 a includes an end edge 17 a of the first main inner wall surface 17, an end edge 18 a of the second main inner wall surface 18, and an end edge 19 d of the first end inner wall surface 19. Among these, the edge 19d of the first end inner wall surface 19 is connected with a chamfered portion having a curved shape in a sectional view.

  As shown in FIG. 13, the first chamfered portion 37 is connected to the edge 19 d of the first end inner wall surface 19. The first chamfered portion 37 has a corner radius portion 37a and a corner radius portion 37b. The corner radius portion 37 a has a lower end continuous with the upper end edge of the first receptacle guide surface 19 a on the first end inner wall surface 19, and an upper end continuous with the main surface 11 a of the receptacle housing 11. The corner radius portion 37 a includes a part of the receptacle housing 11 and one bent portion 29 c of the first receptacle fixing bracket 13. Since the 1st receptacle fixing metal fitting 13 is formed with the metal material, the corner | angular radius part 37a contains the part comprised with the metal material. The corner round portion 37 b has a lower end continuous with the upper end edge of the first receptacle guide surface 19 b on the first end inner wall surface 19, and an upper end continuous with the main surface 11 a of the receptacle housing 11. The corner radius portion 37 b includes a part of the receptacle housing 11 and the other bent portion 29 c of the first receptacle fixing bracket 13. Since the first receptacle fixing bracket 13 is made of a metal material, the corner radius portion 37b includes a portion made of a metal material.

  As shown in FIG. 14, the plug connector 50 includes a third chamfered portion 77 and a fourth chamfered portion 78 (see FIG. 1). Similarly to the first chamfered portion 37, the third chamfered portion 77 and the fourth chamfered portion 78 are corner round portions having a curved shape when viewed in cross section. The fourth chamfered portion 78 (see FIG. 1) is provided on the other end side of the plug housing 51. Since the fourth chamfered portion 78 has substantially the same configuration as the third chamfered portion 77, detailed description thereof is omitted.

  As shown in FIG. 14, the third chamfered portion 77 is provided on one end side of the plug housing 51. A rounded corner portion 77 a that is a part of the third chamfered portion 77 is continuous with the first plug guide surface 59 a on the first end outer wall surface 59 and the main surface 51 a of the plug housing 51. Further, the corner radius portion 77 a includes a part of the plug housing 51 and a bent portion 69 d of the first plug fixing metal 53. Accordingly, the corner radius portion 77a includes a portion made of a metal material. A rounded corner portion 77 b that is another part of the third chamfered portion 77 is continuous with the first plug guide surface 59 b of the first end outer wall surface 59 and the main surface 51 a of the plug housing 51. Further, the corner radius portion 77 b includes a part of the plug housing 51 and a bent portion 69 d of the first plug fixing metal 53. Accordingly, the corner radius portion 77b includes a portion made of a metal material.

<Third guide function>
According to the chamfered portions 37, 38, 77, 78 described above, the third guide function is achieved. In short, the third guide function is a function of correcting the position of the plug connector 50 on a virtual plane orthogonal to the Z-axis direction when the receptacle connector 10 and the plug connector 50 are viewed in plan. More specifically, as shown in FIG. 15A, the plug connector 50 may be inserted into the receptacle connector 10 while being moved along the Z-axis direction. Ideally, at this time, when the first main outer wall surface 57 of the plug connector 50 and the first main inner wall surface 17 of the receptacle connector 10 coincide with each other in the Y-axis direction, the movement along the Z-axis direction is caused. The plug connector 50 can be inserted into the receptacle connector 10. However, actually, as shown in FIG. 15B, the first main outer wall surface 57 of the plug connector 50 may be located on the main surface 11a of the receptacle connector 10, and in this case, the receptacle The receptacle housing 11 of the connector 10 and the plug housing 51 of the plug connector 50 interfere with each other (see interference M in the part (b) of FIG. 15).

  Therefore, the receptacle connector 10 and the plug connector 50 according to the present disclosure have chamfered portions 37, 38, 77, and 78. With reference to FIG. 16, the third guide function performed by the first chamfered portion 37 and the third chamfered portion 77 will be illustrated. As shown in part (a) of FIG. 16, there is a plug connector 50 that is spaced apart from the receptacle connector 10 in the Z-axis direction. The plug connector 50 forms an interference M in the Y-axis direction. As shown in part (b) of FIG. 16, when the plug connector 50 is moved along the Z-axis direction, the third chamfered portion 77 of the plug connector 50 comes into contact with the first chamfered portion 37 of the receptacle connector 10. . As shown in part (c) of FIG. 16, when the plug connector 50 is further moved along the Z-axis direction in a state where the third chamfered portion 77 is in contact with the first chamfered portion 37, the plug connector 50 is It moves along the Z-axis direction along the surface of the first chamfered portion 37 and also moves in the Y-axis direction. When the plug connector 50 is further moved along the Z-axis direction, the first main outer wall surface 57 of the plug connector 50 and the first main inner wall surface 17 of the receptacle connector 10 coincide with each other in the Y-axis direction. At this point, the interference M becomes zero. Then, as shown in FIG. 16D, the plug connector 50 is inserted into the receptacle connector 10 along the Z-axis direction while contacting the first main inner wall surface 17 of the receptacle connector 10. According to the chamfered portions 37, 38, 77, and 78, even when the plug connector 50 and the receptacle connector 10 have interference in the Y-axis direction, the state in which the plug connector 50 interferes with the receptacle connector 10 is eliminated. Can do. Accordingly, the posture of the plug connector 50 can be corrected to a posture that can be inserted into the receptacle connector 10.

  The chamfered portions 37, 38, 77, and 78 do not have to be included in both the receptacle connector 10 and the plug connector 50, and may be provided in at least one of them. For example, when the receptacle connector 10 has the chamfered portions 37 and 38, the plug connector 50 may not have the chamfered portions 77 and 78. Further, when the plug connector 50 has the chamfered portions 77 and 78, the receptacle connector 10 may not have the chamfered portions 37 and 38.

  The first guide function and the second guide function described above are targeted from the state in which a part of the plug connector 50 is inserted into the accommodating portion 16 of the receptacle connector 10 to the state in which the plug connector 50 is fitted. It was a thing. On the other hand, the third guide function is targeted from the state in which the plug connector 50 is not inserted into the receptacle 16 of the receptacle connector 10 to the state in which a part of the plug connector 50 is inserted into the receptacle 16 of the receptacle connector 10. Yes. For this reason, when the plug connector 50 is inserted into the receptacle connector 10, the first guide function and the second guide function are performed after the third guide function is performed. That is, according to the chamfered portions 37, 38, 77, and 78 that perform the third guide function, the allowable amount of deviation that can correct the posture of the plug connector 50 to a posture that can be inserted into the receptacle connector 10 is increased. Can do. Therefore, by providing the chamfered portions 37, 38, 77, 78 so as to perform the third guide function in addition to the first guide function and the second guide function, the work of inserting the plug connector 50 into the receptacle connector 10 is easy. Can be further improved. Such a third guide function can also be called an alignment function.

  Hereinafter, operational effects of the connector device 1 and the receptacle connector 10 according to the present disclosure will be described.

  In a state where the plug connector 50 and the receptacle connector 10 are fitted, the axial direction of the plug connector 50 is aligned with the axial direction of the receptacle connector 10. Therefore, in order to fit the plug connector 50 into the receptacle connector 10, it is necessary to insert the plug connector 50 into the receptacle connector 10 with the axial direction of the plug connector 50 aligned with the axial direction of the receptacle connector 10. In the plug connector 50 and the receptacle connector 10 that are initially separated from each other, when the end of the mating main body of the plug connector 50 is inserted into the receiving portion 16 of the receptacle connector 10, the axial direction of the plug connector 50 is the receptacle. It may be displaced with respect to the axial direction of the connector 10. In this state, the plug connector 50 cannot be fitted into the receptacle connector 10.

  Here, when the end of the plug connector 50 comes into contact with any one of the wall surfaces constituting the accommodating portion 16 of the receptacle connector 10, the movement of the plug connector 50 is restricted. For example, when the plug connector 50 contacts the first main inner wall surface 17, the movement of the plug connector 50 in the facing direction of the first main inner wall surface 17 is restricted. (The movement of the plug connector 50 in the Y-axis direction is limited.) In other words, the plug connector 50 is movable along the X-axis direction. The plug connector 50 that is movable along the X-axis direction eventually reaches the first end inner wall surface 19. Also on the first receptacle guide surface 19a of the first end inner wall surface 19, the movement of the plug connector 50 in the facing direction of the first main inner wall surface 17 is restricted. (The movement of the plug connector 50 in the Y-axis direction is limited.) In other words, the plug connector 50 is movable along the first receptacle guide surface 19a of the first end inner wall surface 19. The separation width HR in the facing direction of the first receptacle guide surface 19a is gradually narrowed. Then, when the plug connector 50 moves while being in contact with the first receptacle guide surface 19a, the movement of the plug connector 50 is limited to a movement in a direction obliquely intersecting the X-axis direction. The movement in the obliquely intersecting direction has a moving component in the Y-axis direction orthogonal to the X-axis direction. For this reason, even if the plug connector 50 is initially displaced with respect to the receptacle connector 10, the plug connector 50 moves while contacting the first receptacle guide surface 19a, so that the axial direction of the plug connector 50 is changed to the receptacle connector. The position of the plug connector 50 is corrected so as to be gradually aligned in the axial direction of the ten. That is, when the plug connector 50 moves in contact with the first receptacle guide surface 19a, the position of the plug connector 50 is gradually corrected to a position where it can be fitted. Finally, the axial direction of the plug connector 50 is aligned with the axial direction of the receptacle connector 10, and the plug connector 50 can be fitted into the receptacle connector 10. Therefore, according to the receptacle connector 10, even if the position of the plug connector 50 with respect to the receptacle connector 10 cannot be initially engaged, it can be corrected to a position where it can be fitted. Thereby, the receptacle connector 10 can improve the efficiency of the operation | work which fits the plug connector 50 and the receptacle connector 10 mutually.

  According to the receptacle connector 10, the plug connector 50 with respect to the receptacle connector 10 can be moved in any direction in the X-axis direction when the plug connector 50 in contact with the first main inner wall surface 17 or the second main inner wall surface 18 is moved. The position can be corrected to a position where fitting is possible. Therefore, the efficiency of the operation of fitting the plug connector 50 and the receptacle connector 10 with each other can be further improved.

  In the receptacle connector 10, the first end inner wall surface 19 and the second end inner wall surface 21 have a planar shape. According to this configuration, in the plug connector 50, the amount of movement in the facing direction relative to the amount of movement in the axial direction can be set to a desired constant value.

  According to the receptacle connector 10, the surface strength of each of the facing portions of the first end inner wall surface 19 and each of the facing portions of the second end inner wall surface 21 can be improved.

  The receptacle connector 10 has a first chamfered portion 37 and a second chamfered portion 38. When the plug connector 50 and the receptacle connector 10 are viewed in plan, the plug connector 50 is displaced with respect to the receptacle connector 10, and physical interference M between the receptacle connector 10 and the plug connector 50 may occur. In this case, the plug connector 50 cannot be inserted into the accommodating portion 16 of the receptacle connector 10. However, according to the receptacle connector 10, when the plug connector 50 is moved to the bottom side of the housing portion 16 with the plug connector 50 in contact with the first chamfered portion 37 or the second chamfered portion 38, the plug connector 50 is It moves along the surface of the chamfered portion 37 or the second chamfered portion 38, and finally reaches the first receptacle guide surface 19a or the first receptacle guide surface 19b where the first chamfered portion 37 or the second chamfered portion 38 continues. . After the plug connector 50 reaches the pair of first receptacle guide surfaces 19a and 19b, the plug connector 50 moves to the bottom side of the accommodating portion 16 along the first receptacle guide surface 19a or the first receptacle guide surface 19b. Can do. Therefore, according to the receptacle connector 10, even if the initial position of the plug connector 50 and the receptacle connector 10 cannot be fitted, the position of the plug connector 50 with respect to the receptacle connector 10 is corrected to a position where the plug connector 50 can be fitted. Can do. Thereby, the receptacle connector 10 can further improve the efficiency of the operation of fitting the plug connector 50 and the receptacle connector 10 to each other.

  In the receptacle connector 10, the first chamfered portion 37 and the second chamfered portion 38 include a portion formed of a metal material. According to this configuration, the surface strength of the first chamfered portion 37 or the second chamfered portion 38 can be improved. Therefore, the plug connector 50 in contact with the first chamfered portion 37 or the second chamfered portion 38 can move while rubbing the first chamfered portion 37 or the second chamfered portion 38.

  The present invention has been described in detail based on the embodiments. However, the present invention is not limited to the above embodiment. The present invention can be variously modified without departing from the gist thereof.

  In the above description, the first end inner wall surface 19 and the second end inner wall surface 21 are described as being planar. However, the first end inner wall surface 19 and the second end inner wall surface 21 are not limited to a planar shape. For example, as shown in FIG. 17A, the first end inner wall surface 19A may be curved. The first end inner wall surface 19A of the receptacle connector 10A according to Modification 1 shown in FIG. 17A has an arc shape in plan view. Even in such a configuration, a part of the first inner wall surface 19A faces the first receptacle guide surface 19aA and the first receptacle guide surface 19bA that face each other and the separation width gradually decreases along the X-axis direction. Can have. A curved receptacle front end surface 19cA is formed between the first receptacle guide surface 19aA and the first receptacle guide surface 19bA.

  As shown in part (b) of FIG. 17, the receptacle connector 10B according to the modified example 2 has areas corresponding to the first receptacle guide surface 19aA and the first receptacle guide surface 19bA on the first end inner wall surface 19B. The shape may be curved, and the receptacle front end surface 19cB may be flat.

  According to the receptacle connector 10 described above, the inclination of the pair of first receptacle guide surfaces 19a and 19b with respect to the X-axis direction varies depending on the positions on the surfaces. Therefore, the ratio of the movement amount in the Y-axis direction to the movement amount in the X-axis direction can be changed.

  One aspect of the present disclosure is an electrical connector configured to be insertable / removable with respect to a counterpart connector arranged in a counterpart main body so that a plurality of counterpart terminals are arranged in a first direction. An insulating main body having a recessed housing portion extending in the direction, and a body terminal electrically connected to the counterpart terminal in a state where the counterpart connector is inserted into the housing portion, A plurality of main body terminals are arranged along the second direction, extend along the second direction and face each other, and one main wall surface at one end of the pair of main wall faces the other main wall A first end wall surface connected to the wall surface and a second end wall surface connecting one main wall surface to the other main wall surface on the other end side of the pair of main wall surfaces, and at least a part of the first end wall surface is Face-to-face direction of a pair of main walls In the second direction, the separation width in the facing direction is gradually narrowed from the second end wall surface toward the first end wall surface in the second direction. The first guide region is inserted into the housing portion by the counterpart connector. When the end of the mating body comes into contact with the mating connector, the mating connector is regulated so that the mating connector moves in the facing direction of the main wall so that the first direction of the mating connector is aligned with the second direction of the receiving portion. To guide you.

In a state where the mating connector and the electrical connector are fitted, the first direction of the mating connector is aligned with the second direction of the electrical connector. Therefore, in order to fit the counterpart connector to the electrical connector, it is necessary to insert the counterpart connector into the electrical connector in a state where the first direction of the counterpart connector is aligned with the second direction of the electrical connector. In the mating connector and the electrical connector that are initially separated from each other, when the end of the mating body of the mating connector is inserted into the electrical connector housing, the first direction of the mating connector is the second direction of the electrical connector. It can be offset. In this state, the mating connector cannot be fitted to the electrical connector.
Here, when the end of the mating connector comes into contact with any one of the wall surfaces constituting the housing portion of the electrical connector, the movement of the mating connector is restricted. For example, when the counterpart connector contacts the main wall surface, the movement of the counterpart connector in the facing direction of the main wall surface is limited. In other words, the mating connector is movable along the second direction. The mating connector that is movable along the second direction eventually reaches the first end wall surface. The movement of the mating connector in the facing direction of the main wall surface is also restricted in the first guide region of the first end wall surface. In other words, the mating connector is movable along the first guide area on the first end wall surface. In the first guide region, the separation width in the facing direction of the main wall surface is gradually narrowed. Then, when the counterpart connector moves in contact with the first guide area, the counterpart connector is restricted to move in a direction that obliquely intersects the second direction. The movement in the obliquely intersecting direction has a moving component in the direction orthogonal to the second direction. For this reason, even if the counterpart connector is initially displaced from the electrical connector, the counterpart connector moves while contacting the first guide region, so that the first direction of the counterpart connector is changed to the second direction of the electrical connector. The position of the mating connector is corrected so that it is gradually aligned. That is, when the counterpart connector moves in contact with the first guide region, the position of the counterpart connector is gradually corrected to a position where the counterpart connector can be fitted. Finally, the first direction of the counterpart connector is aligned with the second direction of the electrical connector, and the counterpart connector can be fitted into the electrical connector. Therefore, according to the electrical connector according to the present disclosure, the position of the mating connector can be corrected to a matable position even when the position of the mating connector with respect to the initial electrical connector cannot be mated. Thereby, the electrical connector which concerns on this indication can improve the efficiency of the operation | work which makes a counterpart connector and an electrical connector fit each other.

In the electrical connector according to the present disclosure, at least some of the second end wall surfaces face each other in the facing direction of the pair of main wall surfaces, and are separated in the facing direction in the second direction from the first end wall surface toward the second end wall surface. The second guide region is a second guide region whose width is gradually narrowed. The second guide region is formed when the end of the counterpart main body comes into contact with the counterpart connector when the counterpart connector is inserted into the accommodating portion. The movement of the mating connector may be guided so that the first direction of the mating connector is aligned with the second direction of the accommodating portion.
According to this configuration, even when the mating connector in contact with the main wall surface is moved to any end side of the housing portion, the position of the mating connector with respect to the electrical connector is corrected to a position where the mating connector can be fitted. Can do. Accordingly, it is possible to improve the efficiency of the work of fitting the counterpart connector and the electrical connector to each other.

  In the electrical connector according to the present disclosure, the first end wall surface and the second end wall surface may have a planar shape. According to this configuration, in the counterpart connector, the amount of movement in the facing direction with respect to the amount of movement in the second direction can be set to a desired constant value.

  In the electrical connector according to the present disclosure, the first end wall surface and the second end wall surface may have a curved surface shape. According to this configuration, the inclinations of the first guide area and the second guide area with respect to the second direction vary depending on the position in the area. Therefore, the ratio of the movement amount in the facing direction to the movement amount in the second direction can be changed.

  In the electrical connector according to the present disclosure, the first guide region and the second guide region may include a portion formed of a metal material. According to this configuration, the surface strength of the first guide region and the second guide region can be improved. Therefore, the mating connector that has contacted the first guide region and the second guide region can move while rubbing the first guide region and the second guide region.

  In the electrical connector according to the present disclosure, the first guide region and the second guide region include portions formed of a metal material on each of the facing portions of the first end wall surface and each of the facing portions of the second end wall surface. May include. According to this configuration, the surface strength of each of the facing portions of the first end wall surface and each of the facing portions of the second end wall surface can be improved.

In the electrical connector according to the present disclosure, the accommodating portion includes an opening that receives the mating connector, and the opening is defined by an edge of the pair of main wall surfaces, an edge of the first end wall surface, and an edge of the second end wall surface. The formed main body has a first chamfered portion continuous with the edge of the first guide region included in the edge of the first end wall surface, and an edge of the second guide region included in the edge of the second end wall surface May have at least one of the second chamfered portions that are continuous with each other.
When the counterpart connector and the electrical connector are viewed in plan, the counterpart connector is displaced from the electrical connector, and physical interference between the electrical connector and the counterpart connector may occur. In this case, the mating connector cannot be inserted into the electrical connector housing. According to the configuration of the present disclosure, when the counterpart connector is moved while the counterpart connector is in contact with the first chamfered portion and the second chamfered portion, the counterpart connector moves along the surfaces of the first chamfered portion and the second chamfered portion. Finally, the first guide area and the second guide area that are continuous with the first chamfered portion and the second chamfered portion are reached. After the counterpart connector reaches the first guide region and the second guide region, the counterpart connector can move to the accommodating portion along the first guide region and the second guide region. Therefore, according to the electrical connector according to the present disclosure, the position of the mating connector relative to the electrical connector can be corrected to a mating position even when the initial positions of the mating connector and the electrical connector cannot be mated. it can. Thereby, the electrical connector which concerns on this indication can improve the efficiency of the operation | work which makes a counterpart connector and an electrical connector fit each other.

  In the electrical connector according to the present disclosure, the first chamfered portion and the second chamfered portion may include a portion formed of a metal material. According to this configuration, the surface strength of the first chamfered portion and the second chamfered portion can be improved. Therefore, the mating connector that contacts the first chamfered portion and the second chamfered portion can move while rubbing the first chamfered portion and the second chamfered portion.

In addition, a connector device according to another aspect of the present disclosure includes a plug connector disposed in a plug body so that a plurality of plug terminals are arranged in the first direction, and a receptacle connector configured to be insertable / removable with respect to the plug connector. The receptacle connector can be inserted into and removed from the plug connector, and has an insulating main body having a recessed receiving portion extending in the second direction, and the plug connector in a state where the plug connector is inserted into the receiving portion. And a main body terminal electrically connected to each other, and the accommodating portion is arranged such that the plurality of main body terminals are arranged along the second direction, extend along the second direction, and face each other. A wall surface, a first end wall surface connecting one main wall surface to the other main wall surface on one end side of the pair of main wall surfaces, and one main wall surface contacting the other main wall surface on the other end side of the pair of main wall surfaces. And at least part of the first end wall faces each other in the facing direction of the pair of main wall surfaces and faces in the second direction from the second end wall surface toward the first end wall surface. The first guide region is a first guide region in which the width of the plug is gradually narrowed, and the first guide region is a plug in the facing direction of the main wall surface when the end of the plug body comes into contact when the plug connector is inserted into the housing portion. The movement of the connector may be regulated to guide the mating plug connector so that the first direction of the plug connector is aligned with the second direction of the housing portion.
In the connector device, since the receptacle connector has the first guide region, it is possible to correct the position of the plug connector so that the plug connector can be fitted even if the position of the plug connector with respect to the receptacle connector cannot be fitted at the beginning. Is possible. Therefore, the electrical connector according to the present disclosure can improve the efficiency of the work of fitting the plug connector and the receptacle connector with each other.

DESCRIPTION OF SYMBOLS 1 ... Connector apparatus, 2, 3 ... Printed wiring board 10, 10A, 10B, 110 ... Receptacle connector (electrical connector), 11 ... Receptacle housing (main body), 12 ... Receptacle terminal (main body terminal), 13 ... 1st receptacle Fixing bracket (first fixing bracket), 14 ... second receptacle fixing bracket (second fixing bracket), 16 ... housing portion, 17 ... first main inner wall surface (main wall surface), 18 ... second main inner wall surface (main wall surface) ), 19 ... First end inner wall surface (first end wall surface), 19a, 19b ... First receptacle guide surface (first guide region), 19c, 112 ... Receptacle tip surface, 21 ... Second end inner wall surface (second End wall surface) 26... Board fixing portion 27. Guide portion 28. Holding portion 50 and 150. Plug connector (mating connector) 52. Plug terminal (mating terminal) 53. 54 ... 2nd plug fixing metal fitting, 57 ... 1st main outer wall surface, 58 ... 2nd main outer wall surface, 59 ... 1st end outer wall surface, 59a, 59b ... 1st plug guide surface, 59c ... Plug tip surface, 61 ... second end outer wall surface, 66 ... substrate fixing portion, 67 ... guide portion, 68 ... held portion.

Claims (4)

A fixing bracket provided on a main body provided in an electrical connector configured to be insertable / removable with respect to a counterpart connector,
The bracket body,
A guide part extending from the metal fitting body, a part of which is embedded in the body, and another part of which is exposed from the body, the plate part constituting an inner wall surface of the body;
A fixing bracket provided with a pair of holding portions that are provided so as to face each other in the bracket main body and sandwich the counterpart fixing bracket provided in the counterpart connector.   The fixing bracket according to claim 1, wherein the pair of holding portions has elasticity along a direction in which the pair of holding portions face each other. An electrical connector configured to be insertable / removable with respect to the mating connector,
The body,
A fixing bracket provided on the main body,
The fixing bracket is
The bracket body,
A guide part extending from the metal fitting body, a part of which is embedded in the body, and another part of which is exposed from the body, the plate part constituting an inner wall surface of the body;
An electrical connector comprising: a pair of holding portions that are provided so as to face each other at both ends of a connection portion extending from the metal fitting body and sandwich the counterpart fixing metal fitting provided in the counterpart connector. A plug connector;
A receptacle connector configured to be insertable / removable with respect to the plug connector,
The receptacle connector is
The body,
A fixing bracket provided on the main body,
The fixing bracket is
The bracket body,
A guide part extending from the metal fitting body, a part of which is embedded in the body, and another part of which is exposed from the body, the plate part constituting an inner wall surface of the body;
A connector device, comprising: a pair of holding portions that are provided so as to face each other at both ends of a connection portion extending from the metal fitting body, and sandwich a plug fixing metal fitting provided on the plug connector.

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