KR101547853B1 - Electric connector assembly - Google Patents

Abstract

To provide an electrical connector assembly capable of engaging a connector with a simple operation without damaging the connector.
In the connector fitting process, the cable electrical connector (1) comes from above with respect to the circuit board electrical connector (2) while maintaining the lateral posture so that the lock protrusion (13A) The locking protrusion 13A reaches the position of the lock recess 31F at the time of completing the connector fitting, and the elastic arm portion 13 is brought into contact with the side surface of the elastic arm portion 13, The lock projection portion 13A is allowed to engage with the rim portion of the lock concave portion 31F so that the upward movement of the electrical connector 1 for cable is regulated, The electrical connector 1 for a cable is brought into the inclined posture so that the engageable state between the lock projection 13A and the rim of the lock recess 31F is released and the electrical connector 1 Is allowed to move.

Description

[0001] ELECTRIC CONNECTOR ASSEMBLY [0002]

The present invention relates to an electrical connector assembly comprising an electrical connector for a circuit board disposed on a mounting surface of a circuit board and an electrical connector for a cable fitted and connected to the electrical connector for the circuit board.

This type of electrical connector assembly is disclosed, for example, in Patent Document 1. The electrical connector assembly of Patent Document 1 includes a receptacle connector (electrical connector for a circuit board) arranged on a mounting surface of a circuit board, and a cable extending backward in parallel with the mounting surface in the connector fitting state, And a cable connector (electrical connector for cable) for holding the front end side portion of the cable connector. In this patent document 1, lock projections formed on the outer side surfaces of both side walls (cable side walls) of the housing of the cable connector are formed on both side walls (substrate side walls) of the receptacle connector accommodating the cable connector, So that the cable connector can be prevented from being unintentionally dislodged.

The lock groove portion of the receptacle connector is formed so as to be recessed from the inner side surface of the side wall of the board as it is opened upward and downward in the vertical direction. Further, the projecting portion is formed so as to protrude inwardly from the upper portion of the front edge of the lock groove portion toward the rear in the lock groove portion.

When the connector is fitted, the cable connector comes from above with respect to the receptacle connector while maintaining the inclined posture in which the front end is raised. Then, the lock projecting portion of the cable connector enters the lock groove portion without interfering with the projecting portion of the receptacle connector. When the lock projection reaches the lowermost position in the lock groove portion, the cable connector is lowered at the front end side and becomes a lateral posture parallel to the circuit board. As a result, a part of the lock projection is located directly under the projection, and the upward movement of the lock projection in the lateral position is restricted by the projection. Therefore, even when the cable is lifted upwards, the locking protrusion is caught by the protrusion, thereby preventing unexpected disconnection of the cable connector. When the connector is pulled out, the front end side of the cable connector in the transverse direction posture is raised to be inclined posture, and the lock protrusion is brought to a position where it does not interfere with the protrusion, thereby making it possible to pull out the cable connector.

Japanese Patent Application Laid-Open No. 2010-267604

As described above, in the electrical connector assembly of Patent Document 1, at the time of fitting the connector, it is first necessary to set the cable connector in an inclined posture. In recent years, however, the connector tends to be miniaturized, and it is difficult to operate the cable connector in an inclined posture, and the cable connector may come to the receptacle connector in a lateral posture near the horizontal position unconsciously. In addition, for example, when an erroneous operation of inserting the cable connector into the receptacle connector with the transverse posture is performed, the external force is applied from the upper side while the protruding portion of the receptacle connector and the lock projection of the cable connector interfere with each other There is a risk that the lock projections and the projections are damaged.

SUMMARY OF THE INVENTION In view of the foregoing, it is an object of the present invention to provide an electrical connector assembly comprising an electrical connector for a circuit board and an electrical connector for a cable, wherein the connector can be fitted by a simple operation without damaging the connector .

The electrical connector assembly according to the present invention includes an electrical connector for a circuit board disposed on a mounting surface of a circuit board and a mounting portion for mounting the electrical connector for circuit board from above in a fitting direction facing downward at right angles to the mounting surface And an electrical connector for the cable to be connected thereto.

In this electrical connector assembly, in the present invention, the electrical connector for a cable includes a cable-side housing for supporting a portion of the cable in the front-end side extending in a rearward direction from the electrical connector for the cable, The housing includes a housing main body having two cable side walls extending in the front-rear direction, and a housing extending from both side portions of the housing main body in the connector width direction opposite to each other of the cable side walls, Wherein the elastic arm portion is formed with a protruding lock portion facing the connector width direction, and the circuit board electrical connector has two board side portions extending in the front-rear direction Side housing having a side wall formed therein, the substrate- At least a housing main body of the cable electrical connector can be received in a receiving portion formed between the board side sidewalls, and the substrate side wall is provided at a position corresponding to the lock projection portion of the electrical connector for cable, And a locking concave portion that is recessed from the side surface is formed in the electrical connector for a circuit board, and in the connector fitting process, the electrical connector for a cable is provided with a lock recess in which a cable extends in a lateral posture parallel to the circuit board The lock projecting portion is brought into contact with the side surface of the side wall of the board to move downward while elastically displacing the resilient arm portion, and when the connector fitting is completed, the lock projecting portion reaches the position of the lock recess portion, By reducing the amount of elastic displacement of the elastic arm portion, The locking member is engaged with the rim of the lock recess to restrict the upward movement of the electrical connector for cable, and in the process of pulling out the connector, the electrical connector for cable has a rear end , The engaging state between the lock projection and the rim of the lock concave portion is released so that the cable is inclined rearward with respect to the fitting direction and is released from the circuit board in the detaching direction, So that movement of the electrical connector is permitted.

In the present invention, the locking projections of the electrical connector for the cable are formed on the elastic arm portion, and in the connector fitting process, the locking projections abut the side surface of the board side wall of the board electrical connector, The connectors for cables are fitted to each other by inserting the electric connector for cables downward in the lateral posture. Therefore, it is not necessary to set the electrical connector for cable to the inclined posture such that it is lifted from the front end side, and it is possible to easily perform the connector interlocking operation in the lateral posture. Further, in the connector fitting process, since the elastic arm is elastically displaced, an excessive external force does not act on both connectors, and the connector is not damaged.

According to the present invention, in the electrical connector for a board, the lock recess is formed on the outer side surface of the side wall of the board, and the electrical connector for a cable has an elastic arm portion, And the lock portion may be formed on the surface of the elastic arm portion that faces the outer side surface of the side wall of the substrate. Further, in the electrical connector for a board, the lock recess is formed on the inner side surface of the side wall of the board, and the electrical connector for a cable is characterized in that the elastic arm portion is located in an accommodating portion of the board- And the lock portion may be formed on a surface of the elastic arm portion that faces the inner side surface of the side wall of the substrate.

In the present invention, the lock recess of the electrical connector for a board is formed with an inclined surface on the rear side inner edge of the lock concave portion. The inclined surface is inclined so as to reduce the depth of the lock concave portion toward the rear, The upward movement of the lock protrusion of the electrical connector for cable in the lateral posture is regulated by the upper inner edge of the lock recess and the protrusion of the electrical connector for cable in the inclined posture And the resilient arm portion is resiliently displaced against the lock projection portion on the inclined surface to permit movement of the lock projection in the releasing direction.

As described above, in the present invention, the electrical connector for a cable can be fitted to an electrical connector for a board even in a lateral position, but becomes a tilted posture when the connector is pulled out. According to the present invention, by forming the inclined surface in the lock concave portion as described above, when the electrical connector for cable is set in a tilted posture in the process of pulling out the connector, the lock protrusion causes the lock concave The lock concave portion gradually changes its position in a direction in which the depth of the lock concave portion is small. As a result, the elastic arm portion is elastically displaced in the connector width direction. Therefore, since the lock projecting portion moves on the inclined surface in a direction in which the lock projecting portion slips out, it moves without difficulty and falls out of the lock concave portion, so that the electrical connector for cable can be easily removed.

In the present invention, the lock concave portion of the board-use electrical connector is recessed from the side surface of the side wall of the board, as viewed upward in the width direction of the connector, and extends obliquely rearward as it goes upward and opens upward, The front inner rim of the concave portion has a protruding portion projecting rearward at a position offset to the upper end of the front inner rim. In the connector fitting state, the lock stalk The upward movement of the connector can be restricted by the protruding portion and the locking protrusion of the electrical connector for cable in the tilted posture can be moved in the detaching direction during the connector removal process.

When the electrical connector for a cable is inclined in the connector withdrawing process by opening the lock concave portion upwardly so as to be inclined rearward, the lock protector moves without difficulty toward the detaching direction without interfering with the protruding portion of the lock concave portion So that the electrical connector for a cable can be easily pulled out.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, by inserting the electric connector for cables in the lateral posture, the connectors can be fitted to each other. Therefore, since it is not necessary to set the electrical connector for cable in a tilted posture, the connector fitting operation can be easily performed. Further, in the connector fitting process, since the elastic arm portions of the electrical connectors for cables are resiliently displaced in the connector width direction, no excessive external force acts on both connectors, and breakage of the connector can be prevented.

Fig. 1 is a perspective view of the electrical connector assembly according to the first embodiment as seen from the front side, and shows a state before the connector is fitted. Fig.
Fig. 2 is a perspective view of the electrical connector assembly of Fig. 1 seen from the rear side, and shows a state before the connector is fitted. Fig.
Fig. 3 (A) is an enlarged perspective view of an elastic arm portion formed in an electrical connector for a cable of the electrical connector assembly of Fig. 1; Fig. 3 (B) is a perspective view of the elastic arm portion of Fig. 3 (A) as viewed from the inner side. Fig. 3 (C) is a perspective view showing only the rear lock projection formed on the elastic arm portion of Fig. 3 (A) and facing the lock recess of the board connector in the connector width direction.
Fig. 4 is a rear view of the electrical connector assembly viewed from the rear side. Fig. 4 (A) shows a state before connector fitting, and Fig. 4 (B) shows a state after connector fitting.
5A is a sectional view perpendicular to the connector fitting direction, FIG. 5B is a sectional view perpendicular to the connector width direction, and FIG. 5B is a sectional view perpendicular to the connector width direction. 5 (C) show a cross section perpendicular to the anteroposterior direction.
Fig. 6 is an enlarged view of a section of a locking portion between the lock projection and the lock recess shown in Fig. 5, and Figs. 6 (A) to 6 (C) ) Is enlarged and shown.
7A is a cross-sectional view of the electrical connector assembly in the connector removal process, which is a cross-sectional view perpendicular to the connector width direction, and Fig. 7B is a sectional view of the lock- Fig.
8 is a perspective view of the electrical connector assembly according to the second embodiment as seen from the front side, and shows a state before connector fitting.
Fig. 9 is a rear view of the electrical connector assembly according to the third embodiment when viewed from the rear, showing the state before the connector is fitted. Fig.
Fig. 10 is a side view of the electrical connector assembly of Fig. 9 viewed in the connector width direction. Fig. 10 (A) is a state before connector fitting, Fig. 10 (B) is a state after connector fitting, And shows the state in the process.

(Mode for carrying out the invention)

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of an electrical connector assembly comprising an electrical connector for a cable and an electrical connector for a board according to the first embodiment, viewed from the front side opposite to the extension side of the cable, showing a state before connector fitting. Fig. 2 is a perspective view of the electrical connector assembly of Fig. 1 seen from the rear side, and shows a state before the connector is fitted. In Figs. 1 and 2, one of a plurality of cables C extending in the front-rear direction is shown as being pulled backward (upper right room in Fig. 1, right lower room in Fig. 2).

The electric connector assembly according to the present embodiment includes an electric connector 1 for a cable (hereinafter referred to as a "cable connector 1") to which a plurality of (six in this embodiment) cables are connected, (Hereinafter referred to as " substrate connector 2 ") disposed on the mounting surface of the circuit board. The cable connector 1 can be fitted and connected to the board connector 2 from above in a fitting direction (see arrows in Figs. 1 and 2) facing downward at right angles to the mounting surface.

The cable connector (1) has a cable-side housing (10) for manufacturing an electrical insulating material. The cable side housing 10 supports the cable side terminal 20 by inserting the cable side terminal 20 to which the cable C is connected from behind. That is, the cable-side housing 10 indirectly supports the cable C.

The cable side terminal 20 is formed by bending a punched metal plate and has a base 21 extending in the front and rear direction and forming the upper surface of the cable side terminal 20, The pressing portion 23, and the contact portion 24 extending forward in a pair. A pair of support portions 22 formed on the rear end side of the cable side terminal 20 are bent to fix the front end side portion of the outer surface of the cable C to support the cable C. A pair of crimping portions 23 formed at the front and rear middle portion of the cable side terminal 20 are bent to fix the core wire (not shown in Fig. 5 (A)) shown from the outer surface at the front end side of the cable C And it is connected with the core wire. The pair of contact portions 24 formed on the front end side of the cable side terminal 20 are bent so as to be close to each other and then upwardly folded back and forming an opposing interference piece inward. The abutting portion 24 abuts against the plate-like corresponding abutment portion 41 formed on the board-side terminal 40 of the board connector 2 to be described later between the abutting abutment portions to contact the corresponding abutting portion 41 (See Fig. 5 (A)).

The cable-side housing 10 includes a main body portion 11 having an approximately rectangular parallelepiped outer shape, an operating portion 12 projecting forward from the main body portion 11, an elastic portion 12 extending from both side portions of the main body portion 11, And an arm portion (13). As shown in Fig. 2, the main body portion 11 has a plurality of terminal holes 14 extending in the front-rear direction and opening rearward in the connector width direction (the direction orthogonal to both the front-rear direction and the vertical direction) And the cable side terminal 20 to which the cable C is connected is inserted into the terminal hole 14 in a forward direction. The terminal hole 14 is also opened downward from the front side of the cable side housing 10 (not shown), and the board side terminal 40 of the board connector 2, The corresponding contact portion 41 formed in the terminal hole 14 is allowed to enter the terminal hole 14 from below through this opening.

The main body portion 11 has two cable side walls 15 which extend in the front-rear direction and which face each other in the connector width direction at both end positions in the connector width direction. The outer side surface of the cable side wall 15 is located on the inner side in the connector width direction with respect to the first half portion because the rear half portion is recessed in a stepped shape with respect to the front half portion. 2, the surface formed at the boundary between the front half portion and the rear half portion and formed at a right angle to the front-rear direction is a surface to be engaged with the substrate connector 2 And is formed as an engagement surface 15A capable of engaging rearward with respect to the surface 31A. The front half portion is formed with a front lock projection portion 15B protruding from the outer side surface at a position shifted by the front end of the outer side surface of the front half portion and at an intermediate position in the vertical direction. The front lock portion 15B is capable of engaging upward with respect to the front lock recess 31B of the board connector 2 to be described later in the connector fitting state.

The lower surface of the front lock projecting portion 15B is inclined upward toward the outside in the connector width direction so as to guide the front lock projecting portion 15B toward the front lock recess 31B in the connector fitting process As shown in Fig. On the other hand, the upper surface of the front lock projecting portion 15B is inclined downwardly as it goes outward in the connector width direction, and the front lock projecting portion 15B is guided out of the front lock recess 31B in the process of pulling out the connector As shown in Fig.

The operating portion 12 protrudes forward from the upper portion of the front wall 16 of the main body portion 11 and extends over substantially the whole area in the connector width direction. As will be described later, at the time of pulling out the connector, the cable connector 1 in the connector fitting state is lifted upward from the operating portion 12 to become inclined posture so that the pulling-out operation is performed.

The elastic arm portion 13 extends from the upper portion of the outer side surface of the cable side wall 15 toward the outer side in the connector width direction at a position offset to the rear end of the cable side wall 15, And the distal end portion is elastically displaceable in the connector width direction. (At the outer side of the cable side wall 15) is provided at a position offset to the lower end (lower end) of the inner side surface of the elastic arm portion 13 (the surface facing the outer side surface of the cable side wall 15) (See Figs. 3 (A) to 3 (C)).

Fig. 3 (A) is an enlarged perspective view of the elastic arm portion 13 of the cable connector 1 of the electrical connector assembly of Fig. 1, viewed from the outside. In the same figure, the rear lock projection 13A formed on the inner surface of the distal end portion of the elastic arm portion 13 is indicated by a broken line. Fig. 3 (B) is a perspective view of the elastic arm portion 13 of Fig. 3 (A) as viewed from the inner side. Fig. 3C is a perspective view showing only the rear lock projection 13A formed on the elastic arm portion 13 of Fig. 3 (A) and facing the lock recess of the board connector 2 in the connector width direction.

3 (A) to 3 (C), the rear lock projection portion 13A is formed so as to extend from the base integrally connected to the inner side surface of the elastic arm portion 13 to the cable side wall 15 So as to have a tip. Further, the rear lock projection 13A has a tapered shape that reduces the vertical dimension when viewed in the front-rear direction as it extends from the inside toward the tip in the width direction of the connector, which is the projecting direction, (See also Fig. 4 (A)).

Here, the shapes of the respective surfaces 13A-1 to 13A of the rear lock projection 13A will be described based on Fig. 3 (C). In Fig. 3 (C), the oblique surface 13A-0 is a base surface which is a base located on the inner surface of the elastic arm 13. Fig. The rear lock projection 13A is a hexahedron including the base surface 13A-0. The upper surface 13A-1 of the rear lock projection portion 13A is formed as a convex curved surface which is gently downwardly directed toward the front side (lower left in Fig. 3C), and the rear lock projection portion 13A (The upper left chamber in Fig. 3 (C)) in the protruding direction of the protruding portion (see Fig. 4 (A)). The lower surface 13A-2 is formed as a flat surface inclined upward toward the front end, and the inclined angle thereof is larger than the upper surface 13A-1 (see Fig. 4 (A)). The front end face 13A-3 forms a flat face of a triangular shape, and the rear end face 13A-4 forms a curved face that curves convexly toward the rear side. Further, the distal end face 13A-5 is formed by a flat face curved at an upper side. In the present embodiment, the rear lock projection 13A is formed of a hexahedron including the base surface 13A-0. However, instead of this, the outer surface of the rear lock projection may be formed at a boundary position They may be curved and continuous with each other.

Returning to Figs. 1 and 2, the board connector 2 will be described. The board connector 2 has a board side housing 30 for manufacturing an electrical insulating material and a board side terminal 40 and a fixing tool 50 supported by the board side housing 30. The board-side housing 30 includes two board side walls 31 which extend in the front-rear direction and which face each other in the width direction of the connector, and two board side walls 31 extending in the connector width direction, And a bottom wall 33 extending in the connector width direction and connecting the lower ends of the first half of the substrate side wall 31 to each other. The space formed between the two board side walls 31 is formed as a receiving portion 34 for receiving the main body portion 11 of the cable side housing 10 from above.

1 and 2, the inner surface of the board side wall 31 (the surface forming the accommodating portion 34) is located on the outer side with respect to the rear half of the connector in the connector width direction, A plane perpendicular to the front-rear direction is formed at the rear of the cable connector 1 with respect to the engagement surface 15A of the cable connector 1 in the connector fitting state, As shown in Fig.

The inner side surface of the board side wall 31 is provided with a front inclined surface 31C inclined downward in the connector width direction as it is directed downward at a corner edge portion forming a boundary between the upper end surface and the inner side surface of each of the first half portion and the second half portion, Rear inclined surfaces 31D (collectively referred to as " inclined surfaces 31C and 31D ") are formed. The inclined surfaces 31C and 31D guide the main body portion 11 of the cable connector 1 into the accommodating portion 34 of the board connector 2 in the width direction of the connector in the connector fitting process. The inclined surface at a position offset to the front end of the front inclined surface 31C functions as a front lock guide surface 31C-1 for guiding the front lock projection 15B of the cable connector 1 toward the front lock concave portion described later .

The inner side surface of the board side wall 31 is formed with a front lock recess 31B which is recessed from the inner side surface at a position below the front lock guide surface 31C-1. The front lock concave portion 31B accommodates the front lock projection 15B of the cable connector 1 in the connector fitting state and the front lock projection 15B is formed at the upper inner wall surface of the front lock recess 31B, As shown in Fig.

The outer side surface of the board side wall 31 faces downward at a corner edge portion forming a boundary between the upper surface and the outer surface at a position offset to the rear end corresponding to the rear lock projection portion 13A of the cable connector 1 A rear lock guide surface 31E inclined outward in the connector width direction is formed. The rear lock guide surface 31E guides the rear lock projection 13A toward the later-described lock concave portion to be described later outward in the connector width direction.

The outer side surface of the board side wall 31 is formed with a rear lock concave portion 31F which is recessed from the outer side surface and opened downwardly at a position below the rear lock guide surface 31E. The rear lock recessed portion 31F accommodates the rear lock projection portion 13A of the cable connector 1 in the connector fitting state and is located at the rear side from the upper inner wall surface 31F-1 of the rear lock recessed portion 31F And can be hooked upward with respect to the lock projection 13A. The upper inner wall surface 31F-1 is formed as a concave curved surface that curves downward when facing the upper surface 13A-1 of the rear lock projection 13A as viewed in the connector width direction (See Fig. 6 (B)). 6 (C), when viewed in the front-rear direction, the upper inner wall surface 31F-1 is upwardly directed toward the inside of the connector width direction (the right side in FIG. 6 (C) There is an incline. 1, an inclined surface 31F-2 inclined so as to reduce the depth of the rear lock concave portion 31F toward the rear side is formed on the inner side edge of the rear side of the rear lock concave portion 31F Respectively.

6 (C), the upper surface 13A-1 of the rear lock projection portion 13A of the cable connector 1 and the rear lock recess portion 31F of the board connector 2 The upper inner wall surface 31F-1 has an acute angle with respect to the inner surface of the elastic arm portion 13 and the inclined angle with respect to the bottom wall surface (surface perpendicular to the connector width direction) of the rear lock recess 31F Therefore, the lock strength of each other is great. On the other hand, the upper surface of the front lock projection 15B of the cable connector 1 has an inclined surface that guides the front lock projection 15B out of the front lock recess 31B in the connector removal process have. Therefore, the lock strength between the front lock projection 15B and the front lock recess 31B is smaller than the lock strength between the rear lock projection 13A and the rear lock recess 31F described above. That is, the locking function between the cable connector 1 and the board connector 2 is mainly performed by the rear lock projections 13A and the rear lock recesses 31F, and the front lock projections 15B and the front lock recesses 31B are auxiliary.

As shown in Figs. 1 and 2, the board side terminal 40 is formed by punching a metal plate. The front side wall 32 of the board side housing 30, And the bottom wall 33 so as to be arranged and supported in the width direction of the connector at a position offset by the front end of the board-side housing 30. [ The board side terminal 40 has a rectangular plate-like corresponding contact portion 41 rising from the bottom wall 33 in the housing portion 34 of the board side housing 30 and a corresponding contact portion 41 extending from the lower portion of the corresponding contact portion 41 And has a connecting portion 42 extending forward (see Fig. 1). The corresponding contact portion 41 is in contact with the pair of contact portions 24 of the cable side terminal 20 so as to come into contact with the contact portion 24 at the contact pressure on both the plate surfaces (see Fig. 5 (A)). 1, a lower edge of the connecting portion 42 is soldered to a corresponding circuit portion (not shown) of the circuit board and is electrically connected to the corresponding circuit portion So that they are electrically connected.

As shown in Fig. 2, the fixing metal fitting 50 is formed by punching a metal plate. The fixing metal fitting 50 is provided at a position of the substrate side wall 31 at a position offset to the rear end of the substrate side wall 31 of the substrate- And is integrally molded and supported on the lower part. The fixing metal fitting 50 has a fixing portion 51 which extends downward from the lower surface of the board side wall 31 and is bent backward. The fixing portion 51 is soldered to a corresponding portion (not shown) of the circuit board and fixed to the circuit board.

Next, a fitting operation and a pulling-out operation between the cable connector 1 and the board connector 2 will be described. First, a fitting operation will be described based on Figs. 1 to 6. Fig. Here, FIG. 4 is a rear view of the electrical connector assembly viewed from the rear side, wherein FIG. 4 (A) shows a state before connector fitting, and FIG. 4 (B) shows a state after connector fitting. Fig. 5 is a cross-sectional view of an electrical connector assembly in a connector fitting state, in which Fig. 5 (A) is a transverse section at a plane perpendicular to the connector fitting direction, Fig. 5 FIG. 5C is a vertical cross-sectional view taken along a plane perpendicular to the longitudinal direction. Fig. 6 is an enlarged view of a section of the engagement portion between the rear lock projection 13A and the rear lock recess 31F shown in Fig. 5, and Figs. 6 (A) to 6 (A) to Fig. 5 (C).

First, the cable connector 1 is formed by attaching the front end side portions of the plurality of cables C to the cable side terminal 20 and then attaching the cable side terminal 20 to the terminal hole (s) of the cable side housing 10 Side terminal 20 to the cable-side housing 10 by inserting the cable-side terminal 20 into the cable-side housing 10 from behind. As a result, a plurality of cables C extend from the cable-side housing 10 toward the rear, and the cable connector 1 is obtained. On the other hand, on the mounting surface of the circuit board, the board connector 2 is disposed, and the board side terminal 40 and the fixing metal 50 are soldered to corresponding portions on the mounting surface respectively.

Next, as shown in Figs. 1, 2 and 4 (A), when the cable connector 1 is connected to the board connector 2 by fitting, the cable connector 1 is connected to the circuit board And is positioned above the board connector 2 in a state of being in a horizontal posture in parallel with the board connector 2. [ 4 (B), the main body portion 11 of the cable-side housing 10 is moved downward by pushing the cable connector 1 downward in the connector fitting direction, , Into the connector fitting state.

In the connector fitting state, the corresponding contact portions 41 of the board-side terminals 40 of the board connector 2 are located between the pair of contact portions 24 of the cable-side terminal 20 of the cable connector 1, And the plate surface of the corresponding contact portion 41 is forcedly engaged with both the contact portions 24 (see Fig. 4 (A)). As a result, the contact portion 24 and the corresponding contact portion 41 come in contact with each other with a contact pressure, and the terminals are electrically connected to each other.

In the process up to the connector fitting state, both side portions of the main body portion 11 of the cable connector 1 are inclined surfaces 31C and 31D (Fig. 4B) of the board side wall 31 of the board connector 2 (See Fig. 3A), and the main body portion 11 of the cable side housing 10 is guided into the receiving portion 34 in the connector width direction. At this time, the front lock projection 15B abuts against the front lock guide surface 31C-1 from above and is guided in the connector width direction toward the front lock recess 31B (see Fig. 1). When the cable connector 1 is further inserted downward, the front lock projection 15B rides over the front lock guide surface 31C-1 and reaches the front lock recess 31B, , It is possible to engage with the upper side wall surface of the front lock concave portion 31B toward the upper side.

On the other hand, the elastic arm portion 13 of the cable connector 1 is formed so that the rear lock projection portion 13A abuts against the rear lock guide face 31E of the substrate side wall 31 of the board connector 2 from above The elastic arm portions 13 are elastically displaced outward in the connector width direction. When the cable connector 1 is further inserted downward, the rear lock projection portion 13A rides over the rear lock guide surface 31E and reaches into the rear lock recessed portion 31F. 5 (B), 5 (C), 6 (B) and 6 (C) show that the elastic arm portion 13 is released from the elastic displacement state and is returned in the direction of reducing the elastic displacement amount The rear lock projection portion 13A can be engaged with the upper inner wall face 31F-1 of the rear lock recess portion 31F upwardly in the connector fitting state.

6 (A), the rear end face 13A-4 of the rear lock projection portion 13A faces the inclined face 31F-2 of the rear lock recess portion 31F in the connector fitting state, do.

In the connector fitting state, for example, when an external force acts to move the cable connector 1 upwardly at a right angle to the mounting surface of the circuit board, for example, when the cable C is unexpectedly raised The front lock projections 15B and the rear lock projections 13A are engaged with the upper inner wall face of the front lock recess 31B and the upper inner wall face 31F-1 of the rear lock recess 31F, respectively. As a result, further movement of the cable connector 1 is restricted, thereby preventing unexpected disconnection of the cable connector 1 in question.

5A, the engagement surface 15A of the cable side wall 15 of the cable connector 1 is engaged with the side wall 31 of the board 2 of the board connector 2 in the connector fitting state (In the left-right direction in Fig. 5A) with respect to the engaged surface 31A of the main body 31, and is positioned so as to engage rearward. Therefore, even when an external force acts on the cable connector 1 to move backward, for example, by unintentionally pulling the cable backward in the connector fitting state, Is caught by the engagement surface 31A, the further movement of the cable connector 1 is restricted, thereby preventing the cable connector 1 from being unintentionally dislodged.

The rear lock projection 13A of the cable connector 1 is formed in the elastic arm 13 and the rear lock projection 13A is engaged with the board connector 1 in the connector fitting process, The elastic arm portion 13 is elastically displaced outward in the connector width direction by abutting against the rear locking guide face 31E of the board side wall 31 of the housing 2 so that the cable connector 1 is moved downward The connectors can be fitted to each other. Therefore, it is not necessary to set the cable connector 1 to a tilted posture that is difficult to operate, and the connector fitting operation can be easily performed. Further, in the connector fitting process, since the elastic arm portions 13 are elastically displaced, an excessive external force does not act on both the connectors, so that breakage of both connectors can be prevented.

Next, the connector pull-out operation will be described based on Fig. 7A is a cross-sectional view of the electrical connector assembly in the connector removal process, which is a cross-sectional view perpendicular to the connector width direction. Fig. 7B is a sectional view of the rear lock projection 13A in Fig. And the rear lock concave portion 31F.

In order to pull the cable connector 1 in the connector fitting state from the board connector 2, by lifting a finger to the operating portion 12 of the cable connector 1, as shown in Fig. 7 (A) The cable connector 1 is made to be inclined in which the front end is located above the rear end. The locking function of the front lock projection 15B of the cable connector 1 by the front lock recess 31B of the board connector 2 is auxiliary. Therefore, the lock state between the front lock projecting portion 15B and the front lock recess 31B is released without requiring a large operation force, and the cable connector 1 can be made to be inclined.

On the other hand, the rear lock projection 13A of the cable connector 1 is inclined rearward with respect to the connector fitting direction in the process of coming into the inclined posture, (Tilted and then upward). The rear lock projection 13A is engaged while being in sliding contact with the rear end face 13A-4 (see Fig. 6A) and the inclined face 31F-2 of the rear lock recessed portion 31F. As a result, the resilient arm portion 13 is resiliently displaced outward in the connector width direction, whereby the engageable state between the rear lock projection portion 13A and the upper inner wall face 31F-1 of the rear lock recess portion 31F is released So that further movement of the rear lock projection 13A toward the connector detachment direction is permitted. Then, when the cable connector 1 is lifted up toward the connector disengagement direction, the rear lock projection 13A completely slips out of the rear lock recess 31F, and the connector pull-out operation is completed.

As described above, in the present embodiment, by forming the inclined surface 31F-2 on the rear lock recess 31F of the board connector 2, the elastic displacement of the elastic arm portion 13 . Therefore, the rear lock projection 13A rides over the inclined face 31F-2 and moves without difficulty toward the connector detachment direction, so that the cable connector 1 can be easily pulled out from the rear lock recess 31F . The tilted angle of each of the rear end surface 13A-4 of the rear lock projection portion 13A and the inclined surface 31F-2 of the rear lock recessed portion 31F is smaller than the inclination angle of the inclined surface 31F- It can be set appropriately according to the angle of the photograph. For example, by setting the angle of inclination of the rear end face 13A-4 and the inclined face 31F-2 to be large, even if the inclination angle of the inclined posture of the cable connector 1 is small at the time of pulling out the connector, The lock connector portion 13A rides over the inclined surface 31F-2, so that the cable connector 1 can be pulled out.

≪ Second Embodiment >

The rear lock projections 13A of the cable connector 1 are fixed to the inner side surfaces of the elastic arm portions 13 and the rear lock recesses 31F of the board connector 2 are fixed to the side walls 31 The present embodiment is different from the first embodiment in that the rear locking portion is formed on the outer side surface of the elastic arm portion and the rear locking concave portion is formed on the inner side surface of the side wall of the substrate .

Hereinafter, this embodiment will be described based on Fig. The present embodiment is different from the first embodiment mainly in the position where the rear lock projection and the rear lock recess are formed and the shape of the substrate side wall. The basic configuration of this embodiment is the same as that of the first embodiment in that the distal end portion of the elastic arm portion provided with the rear locking portion is resiliently displaced in the connector width direction to lock and release it. Therefore, in the present embodiment, the difference from the first embodiment will be mainly described, and the same reference numerals as in the first embodiment are added to the reference numerals added with " 100 " . Fig. 8 is a perspective view of the electrical connector assembly according to the present embodiment as seen from the front side, and shows a state before connector fitting.

As described above, in the present embodiment, the rear lock projection 113A of the cable connector 101 is formed on the outer surface of the elastic arm portion 113 and protrudes outward in the connector width direction. The shape of the rear lock projection 113A itself is the same as the shape of the rear lock projection 13A of the first embodiment and is different only in that the projection direction is outward in the direction opposite to that of the first embodiment.

In the present embodiment, the outer side surface of the board side wall 131 of the board connector 102 is located on the outer side in the connector width direction with respect to the front half portion. The inner side surface of the board side wall 131 has a rear end side portion, that is, a portion where the rear lock recessed portion 131F is formed, is located on the outer side in the connector width direction as compared with other portions, Is larger than that of the first embodiment. The elastic arm portion 113 is accommodated in the accommodating portion 134 of the board connector 102 in addition to the main body portion 111 of the cable connector 101 in the connector fitting state.

In the present embodiment, the rear lock recess 131F of the board connector 102 is formed on the inner surface of the rear end side portion of the board side wall 131. [ The shape of the rear lock concave portion 131F itself is the same as the shape of the rear lock concave portion 31F of the first embodiment. The inner side surface of the rear end side portion is provided with a rear locking guide surface (hereinafter referred to as " rear locking guide surface ") which is inclined inward in the connector width direction from the upper end side, 131E are formed.

The connector fitting operation and the connector pulling operation in this embodiment are the same as those in the first embodiment except that the direction in which the elastic arm portion 113 is elastically displaced is inside the connector width direction.

≪ Third Embodiment >

In the first and second embodiments, the elastic arm portions 13, 113 of the cable connectors 1, 101 are elastically displaced in the connector width direction in the connector withdrawing process, so that the rear lock recesses 31F, and 131F, the rear locking projections 13A and 113A are removed. On the other hand, in the present embodiment, when the connector is pulled out, the elastic arm portion of the cable connector is not elastically displaced, but when the connector is pulled out, the rear lock projection is withdrawn from the rear lock recess of the board connector , And is different from the first and second embodiments.

Hereinafter, the present embodiment will be described based on Figs. The present embodiment is greatly different from the first and second embodiments in that the rear lock concave portion of the board connector is opened upward and the upper side of the rear lock concave portion is closed by the upper side inner wall surface . In this embodiment, the same reference numerals as in the first embodiment denote the same parts as those in the first embodiment, and the description thereof is omitted.

Fig. 9 is a rear view of the electrical connector assembly according to the present embodiment, viewed from the rear, showing a state before connector fitting. Fig. 10 is a side view of the electrical connector assembly of Fig. 9 viewed in the connector width direction, Fig. 10 (A) is a state before connector fitting, Fig. 10 (B) is a state after connector fitting, And shows the state in the extraction process. In Fig. 10, the portion covered by the elastic arm portion 213 is indicated by a broken line.

10A, in the present embodiment, the front lock projection 215B is formed at a position offset by the lower edge of the outer side surface of the cable side wall 215 of the cable side housing 210 (Not shown) formed on the inner side surface of the board side wall 231 of the board-side housing 230. The front- 9, the elastic arm portion 213 extends from the upper portion of the outer side surface to the outside in the connector width direction at a position offset to the rear end of the outer side surface of the cable side wall 215, It is bent and extended. The rear lock projection 213A protrudes from the bottom of the inner side surface of the elastic arm 213 toward the inside in the connector width direction.

10, the rear lock concave portion 231F of the board connector 202 is located at a position offset to the rear end of the outer side surface of the board side wall 231 of the board side housing 230, And is formed as a depressed groove portion. The rear lock recessed portion 231F extends obliquely rearwardly, in other words, in the connector detachment direction, as well as downward as well as upward. In the front inner rim of the rear lock recess 231F, a protruding portion 231F-1 protruding rearward at a position offset to the upper end of the front inner rim is formed. The lower surface of the protruding portion 231F-1 functions as a latching surface 231F-1A which is engaged with the rear lock projection 213A of the cable connector 201 in the connector fitting state, as described later .

(The inner dimension in the plane parallel to the plane of the substrate side wall 231) of the rear lock concave portion 231F is smaller than the minimum dimension P between the projection 231F-1 and the rear frame 10 (A)) is set to such a dimension as to allow passage of the rear lock projection 213A in the connector detachment direction in the connector removal process (see Fig. 10 (C)).

An inclined surface inclined downward toward the outside in the connector width direction is formed at an edge of the corner forming the boundary between the upper end surface and the outer surface of the board side wall 231 from the front end to the front side of the rear lock recess 231F To the rim. The inclined surface functions as a rear lock guide surface 231E for guiding the rear lock projection 213A toward the rear lock recess 231F at a portion corresponding to the range of the projection 231F-1.

Next, the connector fitting operation and the connector pull-out operation in this embodiment will be described based on Figs. 10 (A) to 10 (C). When the connector is fitted, the cable connector 201 is caused to come from above with respect to the board connector 202 while maintaining the lateral posture as shown in Fig. 10 (A) Reference). In the connector fitting process, the front end side portion (the left end side portion in Fig. 10 (A)) of the rear lock projection portion 213A abuts against the rear lock guide face 231E so that the elastic arm portion 213 contacts the connector lateral direction Elastic displacement outward. When the cable connector 201 is further inserted downward, the front end side portion of the rear lock projection 213A rides over the rear lock guide surface 231E and the projection 231F-1 and reaches the rear lock recess 231F . At this time, the elastic arm portion 213 is released from the elastic displacement state and is returned in the direction of reducing the elastic displacement amount, so that the front end side portion of the rear lock projection portion 213A is engaged with the engagement face 231F- So that it can be hooked upward.

Even if an external force such as the cable C is accidentally lifted or the like and the cable connector 201 is moved upward is applied unintentionally in the connector fitting state, the rear lock projection 213A Is caught by the engaging surface 231F-1A of the rear lock recess 231F. As a result, further movement of the cable connector 201 is restricted, thereby preventing unexpected disconnection of the cable connector 201 in question.

When the connector is pulled out, the fingers are lifted up to the operating portion 212 of the cable connector 201 so that the cable connector 201 is inclined as shown in Fig. 10 (C). The rear lock projection 213A of the cable connector 201 is positioned in the inclined posture with respect to the protrusion 231F-1 of the rear lock recess 231F and the rear edge of the rear lock recess 231F as shown by the broken line in Fig. So that the engageable state with the engagement surface 231F-1A of the projection 231F-1 is released. When the cable connector 201 is further moved in the releasing direction, the rear lock projection 213A is pulled out of the rear lock recess 231F without interfering with the engagement face 231F-1A. Therefore, The connector 201 can be easily pulled out.

In the present embodiment, the rear locking projections are formed on the inner side surface of the elastic arm portion and the rear locking concave portions are formed on the outer side surface of the substrate side wall. However, the positions of the rear locking projections and the rear locking concave portions are not limited thereto. The rear lock recess may be formed on the outer surface of the elastic arm portion and the rear lock recess may be formed on the inner surface of the side wall of the substrate.

In the first to third embodiments, the elastic arm portion of the cable side housing extends from the outer side surface of the cable side wall. However, the extending position is not limited to this, and the elastic side portion of the cable side housing, The portion may extend from a position offset to both sides of the upper surface of the main body portion.

1, 101, 201: Cable connector (electrical connector for cable)
2, 102, 202: board connector (board-side electrical connector)
10, 110, 210: Cable side housing
11, 111, 211: a main body (housing)
13, 113, 213: elastic arm portions
13A, 113A, 213A: a rear locking projection (locking projection)
15, 115, 215: cable side wall
30, 130, 230: substrate-side housing
31, 131 and 231: substrate side wall
31F, 131F, and 213F: rear lock recesses (lock recesses)
31F-1, 131F-1: Upper inner wall surface (upper inner edge)
31F-2, 131F-2: slopes
231F-1:

Claims (5)

An electrical connector for a circuit board disposed on a mounting surface of a circuit board and an electrical connector for a cable fitted and connected to the circuit board electrical connector from above in a fitting direction facing downward at right angles to the mounting surface ≪ / RTI >
The electrical connector for a cable has a cable-side housing for holding a portion of a cable extending rearward from the electrical connector for cable in parallel with the mounting surface in a connector fitted state,
The cable-side housing includes a housing main body having two cable side walls extending in the front-rear direction, and a housing main body extending from both side portions of the housing main body in the connector width direction opposite to each other in the cable side- And has an elastic arm portion which can be elastically displaced,
Wherein the elastic arm portion is formed with a protruding lock portion protruding in the connector width direction,
The electrical connector for a circuit board has a board-side housing having two board side walls extending in the front-rear direction,
The board-side housing is capable of accommodating at least a housing main body of the cable electrical connector in a receiving portion formed between the board side walls, wherein the board side wall is located at a position corresponding to the lock projection portion of the cable electrical connector Wherein the lock concave portion is formed with an inclined surface on a rear side inner edge of the lock concave portion, and the inclined surface is inclined with respect to the depth of the lock concave portion , And,
In the connector fitting process, the electrical connector for a cable comes from above with respect to the electrical connector for a circuit board while maintaining the lateral posture in which the extending direction of the cable is parallel to the circuit board, The projecting portion is brought into contact with the side surface of the substrate side wall with an inclined surface to move downward while elastically displacing the elastic arm portion,
When the connector is completed, the lock protrusion reaches the position of the lock recess, and the elastic arm portion reduces the amount of elastic displacement so that the lock protrusion can engage with the upper inner edge of the lock recess, The upward movement is restricted,
In the connector removing process, the electrical connector for a cable has an inclined posture in which the front end of the electrical connector for the cable is located above the rear end, so that the lock protrusion is formed on the inclined surface of the rear inner side edge of the lock recess The elastic arm is resiliently displaced so that the engageable state between the lock projection and the upper inner rim of the lock concave portion is released so that the cable arm is inclined rearward with respect to the vertical direction, Wherein movement of the connector is allowed. An electrical connector for a circuit board disposed on a mounting surface of a circuit board and an electrical connector for a cable fitted and connected to the circuit board electrical connector from above in a fitting direction facing downward at right angles to the mounting surface ≪ / RTI >
The electrical connector for a cable has a cable-side housing which supports, in parallel with the mounting surface, a portion of the cable at the front end side extending rearward from the electrical connector for the cable in the connector fitting state,
The cable-side housing includes a housing main body having two cable side walls extending in the front-rear direction, and a housing main body extending from both side portions of the housing main body in the connector width direction opposite to each other in the cable side- And has an elastic arm portion which can be elastically displaced,
The elastic arm portion is formed with a protruding lock portion facing the connector width direction,
The electrical connector for a circuit board has a board-side housing having two board side walls extending in the front-rear direction,
The board-side housing is capable of accommodating at least a housing main body of the cable electrical connector in a receiving portion formed between the board side walls, wherein the board side wall is located at a position corresponding to the lock projection portion of the cable electrical connector Wherein a rim portion of the lock concave portion has a protruding portion protruding rearward from the rim portion at a position offset to the upper end of the rim portion, The portion is inclined rearward with respect to the up-and-down direction, allowing the movement of the lock projecting portion in the direction away from the circuit board,
In the connector fitting process, the electrical connector for a cable comes from above with respect to the electrical connector for a circuit board while maintaining the lateral posture in which the extending direction of the cable is parallel to the circuit board, The projecting portion is brought into contact with the side surface of the substrate side wall with an inclined surface to move downward while elastically displacing the elastic arm portion,
When the connector is completed, the lock protrusion reaches the position of the lock concave portion, and the elastic arm portion reduces the amount of elastic displacement so that the lock protrusion can engage with the protrusion of the lock concave portion, Is restricted,
In the connector removing process, the electrical connector for a cable has an inclined posture in which the front end of the electrical connector for a cable is located above the rear end, so that the lock protrusion comes from behind the protrusion of the lock recess, And the engaging state with the protruding portion is released, and the lock protrusion is moved in the releasing direction, thereby allowing movement of the cable electrical connector in the disengaged direction. 3. The method of claim 2,
The lock recess of the board electrical connector is recessed from the side surface of the board side wall as viewed upward in the width direction of the connector and extends obliquely rearward to open upward, And an inner rim formed on the inner rim. 4. The method according to any one of claims 1 to 3,
Wherein the locking recess is formed on the outer side surface of the board side wall and the elastic arm portion is located outside the accommodating portion of the board electrical connector in the connector fitting state, Wherein the elastic arm portion is formed on a surface of the surface of the elastic arm portion that faces the outer side surface of the side wall of the substrate. 4. The method according to any one of claims 1 to 3,
Wherein the locking recess is formed on the inner side surface of the side wall of the board and the elastic arm portion is located in the accommodating portion of the board electrical connector in the connector fitting state, Wherein the elastic arm portion is formed on a surface of the surface of the elastic arm portion that faces the inner side surface of the side wall of the substrate.

Images