KR102468999B1 - Connector having a structure of terminal pushing - Google Patents

Abstract

(Problem) To provide a connector device capable of reducing a load applied to a second terminal upon contact between a first terminal and an elastic contact portion of the second terminal.
(Solution Means) The first connector has a first housing and a plurality of first terminals, and the second connector has a second housing and a plurality of second terminals. The second terminal includes an elastic contact portion that contacts the first terminal inserted into the insertion space of the second housing, and the insertion space is in a direction orthogonal to both the insertion direction of the first terminal and the terminal arrangement direction of the second terminal. has a reference surface spaced apart from the elastic contact portion. The elastic contact portion is configured to push the first terminal toward the side approaching the reference plane in a direction orthogonal to the first terminal through contact with the first terminal. The second housing has a second protrusion protruding to the side approaching the reference plane, and the second protrusion pushes the plurality of first terminals supported by the first housing to the side approaching the reference plane through abutting with the first housing. Paste.

Description

Connector device having a terminal pushing structure {CONNECTOR HAVING A STRUCTURE OF TERMINAL PUSHING}

The present invention is a connector device having a terminal pressing structure, in other words, when connectors included in the connector device are connected to each other, a terminal of one connector is connected to a terminal of the other connector by using a protrusion formed on a housing constituting the connector. It relates to a connector device having a structure that is pushed into a predetermined portion.

An example of a connector device including the above structure is disclosed in Japanese Laid-open Patent Publication No. 2015-185257. The connector device has a first connector, eg a cable connector, and a second connector, eg a board connector, which can be connected to each other. Upon connection of the first connector and the second connector, the first terminal of the first connector comes into contact with the second terminal of the second connector, particularly its elastic contact portion, and is pressed downward. In order to maintain the connected state of the first terminal and the second terminal, the second housing of the second connector has an elastic contact portion of the second terminal in a direction opposite to the pressing direction, that is, upward, in other words, from the side of the reference plane. A protrusion protruding toward the side of the elastic contact portion is formed, and correspondingly, a protrusion portion protruding downward from the side of the elastic contact portion toward the reference plane side is formed in the first housing of the first connector. When the first connector and the second connector are connected, the protrusion formed on the first housing climbs over the protrusion formed on the second housing, and as a result, the first connector and the second connector can be locked to each other. have.

These protrusions in Patent Literature 1 are mainly formed to lock the first connector and the second connector to each other, but actually, when the first connector and the second connector are connected, the first terminal and the second connector The relative positions of the terminals are moved through contact between the protrusions of the first housing and the protrusions of the second housing. In other words, the first terminal is pushed upward through the contact of these projections, that is, from the side of the reference plane to the side of the elastic contact. Accordingly, it can be said that Patent Literature 1 discloses an example of a connector device including the above structure.

Japanese Unexamined Patent Publication No. 2015-185257

However, since the direction in which the first terminal is pushed through contact with the elastic contact portion of the second terminal is opposite to the direction in which the first terminal is received through contact with the protruding portion, in this case, the second terminal A force is applied to the elastic contact portion in a direction opposite to the direction in which the first terminal is pressed, in other words, in an unnecessary direction not originally planned, and as a result, the second terminal is damaged or deteriorated. this happens For example, in the connector device disclosed in Patent Literature 1, since the use of a small second terminal such as 0.2 mm or less in thickness and 2.0 mm or less in height is also assumed, even a small load causes great damage to the second terminal, Alternatively, there is a high possibility of deteriorating spring properties, and for this reason, it is desired to reduce the load applied to the second terminal and prevent damage or deterioration of the second terminal as much as possible.

The present invention has been made to solve these problems in the prior art, in a connector device having a terminal pushing structure, a first terminal and a second terminal included in each of the first and second connectors included in the connector device To provide a connector device capable of reducing the load applied to the second terminal upon contact with the elastic contact portion of the terminal and preventing damage or deterioration of the second terminal accompanying insertion and removal of the first connector and the second connector. The purpose.

In order to solve the above problem, a connector device according to an embodiment of the present invention includes a first connector and a second connector, wherein the first connector includes a first housing and supported by the first housing. It has a plurality of first terminals, and the second connector has a second housing and a plurality of second terminals supported by the second housing, and the second terminals are inserted into an insertion space of the second housing. and an elastic contact portion contacting the first terminal, wherein the insertion space is perpendicular to both the insertion direction of the first terminal and the terminal arrangement direction of the plurality of second terminals with respect to the insertion space. has a reference surface spaced apart from the elastic contact portion, and the elastic contact portion is configured to push the first terminal toward the side approaching the reference surface in the orthogonal direction through contact with the first terminal; 2 The housing has a second protrusion protruding toward the side approaching the reference plane in the orthogonal direction, and at least the first terminal through contact with the elastic contact portion toward the side approaching the reference plane in the orthogonal direction. When being pushed, a plurality of the first terminals supported by the first housing through abutting of the second protrusion and the first housing inserted into the insertion space are directed against the reference plane in the orthogonal direction. It has as a feature that it is configured to be pushed to the approaching side.

According to the connector device of this embodiment, the direction in which the first terminal is pushed through contact with the elastic contact portion and the direction in which the first housing supporting the first terminal is pushed through contact with the second housing In this respect, the force applied to the second terminal at the time of contact between the first terminal and the elastic contact portion of the second terminal can be reduced, and damage to the second terminal accompanying insertion and removal of the first connector and the second connector can be reduced. or deterioration can be prevented.

In the connector device of the above embodiment, the first housing has a first protrusion protruding in a side opposite to the side approaching the reference plane in the orthogonal direction, and the second protrusion in the first protrusion. It is good to be in contact with

Further, in the connector device of the above embodiment, it is preferable that the timing at which the first terminal contacts the elastic contact portion and the timing at which the first protrusion abuts the second protrusion portion are substantially simultaneous.

By making these timings substantially simultaneous, the load applied to the second terminal can be more effectively reduced.

Further, in the connector device of the above embodiment, the second protrusion is located outside the second terminal arrangement and/or in the middle of the second terminal arrangement in a direction along the terminal arrangement direction. , may be arranged.

Further, in the connector device of the above embodiment, the reference surface may be a sliding contact surface to which the first housing slides when the first housing is inserted into the insertion space.

In the connector device of the above embodiment, the reference plane may be formed by the second housing and/or the second terminal.

In the connector device of the above embodiment, it is preferable that the elastic contact portion is formed of a metal plate, and a contact surface of the elastic contact portion with the first terminal is a surface forming a plate thickness of the metal plate.

By using the plate surface as the contact surface, it becomes easy to ensure strength even when the second terminal is small.

Further, in the connector device of the above embodiment, each of the plurality of second terminals is formed of a metal plate, and at least in the elastic contact portion, the second terminals face each other in a state in which the plate surfaces of the metal plates face each other. They may be arranged next to each other.

Further, in the connector device of the above embodiment, it is preferable that a concave portion is formed at a portion of the first terminal that contacts the elastic contact portion, and is formed in a direction approaching the reference plane in the orthogonal direction.

According to this configuration, the load applied to the second terminal can be reduced.

In the connector device of the above embodiment, the second terminal may include a movable piece on which the elastic contact portion is formed, and a fixed piece connected to the movable piece.

In addition, the movable piece includes a substantially L-shaped portion, the fixing piece includes a substantially linear portion formed along the insertion direction, and the movable piece and the fixing piece are substantially U-shaped when viewed from the side as a whole. It may have a part of the shape.

In the connector device of the above embodiment, at least a portion of the first terminal contacting the elastic contact portion may be exposed from the first housing.

According to the present invention, in a connector device having a terminal push-in structure, when the elastic contact portion of the first terminal and the second terminal included in each of the first and second connectors included in the connector device comes into contact with the second terminal. It is possible to provide a connector device capable of reducing an applied load and preventing damage or deterioration of the second terminal accompanying insertion and removal of the first connector and the second connector.

1 is a perspective view showing a state before mating of a cable connector and a board connector.
Fig. 2 is a plan view showing a state after mating of the cable connector and the board connector.
3 is a perspective view of a cable terminal;
Fig. 4 is a partially enlarged perspective view of the cable housing viewed from the bottom side.
5 is a cross-sectional perspective view of a board connector.
FIG. 6 is a cross-sectional view along line I-I of FIG. 2, showing a state after the cable connector and the board connector are mated.
Fig. 7 is a cross-sectional view along line II-II of Fig. 2, showing a state after the cable connector and the board connector are mated.
Fig. 8 is a view corresponding to a cross-sectional view along line I-I in Fig. 2, showing a state before the cable connector and the board connector are completely engaged.
Fig. 9 is a view corresponding to a cross-sectional view along line II-II in Fig. 2, showing a state before the cable connector and the board connector are completely engaged.

(Mode for implementing the invention)

EMBODIMENT OF THE INVENTION Hereinafter, one preferred embodiment of this invention is described, referring an accompanying drawing. For convenience of explanation, only suitable embodiments are shown, but, of course, the present invention is not intended to be limited thereto.

The connector device 1 of the present invention comprises a combination of a cable connector as a first connector and a board connector as a second connector that can be fitted (fitted) to each other. Fig. 1 is a perspective view showing a state before mating of these cable connectors 20 and board connector 50, and Fig. 2 is a plan view showing a state after mating. The cable connector 20 is used in a state fixed to one end of the cable 11, while the board connector 50 is used in a state fixed to the board 13. These cable connectors 20 and board connectors 50 each have a left-right symmetrical shape.

The cable connector 20 mainly includes a cable housing 21 extending in the terminal arrangement direction (longitudinal direction) "γ" and a cable housing 21 supported by the cable housing 21 arranged along the terminal arrangement direction "γ" , a plurality of cable terminals 40 having the same shape. In addition, the "terminal arrangement direction" in this specification includes not only the case where the cable terminals 40 are arranged on a straight line, but also the case where they are formed in a zigzag shape, for example.

The cable housing 21 mainly includes a body portion 29 extending in the terminal arrangement direction “γ”, and a front side of the body portion 29, in other words, a mating direction between the cable connector 20 and the board connector 50. It consists of the fitting convex part 22 formed on the fitting side in "(alpha)". In the fitting convex portion 22, a plurality of cable terminals 40 are arranged substantially in a line with each other at a predetermined pitch along the terminal arrangement direction "γ".

The body portion 29 is, for example, a substantially box-shaped body, and the fitting convex portion 22 is higher than the body portion 29 in the vertical direction "β", in other words, the fitting direction "α" and terminal arrangement. It is formed as a thin plate in the direction orthogonal to both directions "γ" and as a plate-shaped body having a narrow width in the terminal arrangement direction "γ". By these body parts 29 and fitting convex parts 22, the cable housing 21 as a whole forms a substantially convex shape when viewed from the side. On the left and right outer surfaces of the fitting convex portion 22 in the terminal arrangement direction "γ", substantially semicircular protrusions 25 are formed, respectively. These protrusions 25 protrude upward.

The fitting convex portion 22 is inserted into the board housing 51 of the board connector 50 along the mating direction (insertion direction) "α" when the cable connector 20 and the board connector 50 are mated. It is inserted into the space 52. As a result, a part of the cable terminal 40 is also inserted into the insertion space 52. The upper surface of the fitting convex portion 22 inserted into the insertion space 52 is formed into a comb shape by removing a part along the fitting direction "α" at the position where each cable terminal 40 is arranged, and each cable terminal A part of the upper surface of 40 is exposed to the outside of the cable housing 21 from the gap 28 between the comb teeth. Through these exposed portions and the like, each cable terminal 40 comes into contact with a terminal on the board connector 50 side.

A plurality of terminal insertion ports 24 are formed on the rear side of the body portion 29 . The cable terminal 40 or a part of the cable 11 fixed to one end of the cable terminal 40 passes through each of these terminal insertion holes 24 along the fitting direction “α” to the cable housing 21. inserted, installed

3(a) and (b), perspective views of the cable terminal 40 are shown. Each of the cable terminals 40 is formed into a substantially cylindrical shape by punching and bending a single metal plate. An opening 45 into which one end of the cable 11 is accommodated and installed is formed on the rear side of the cable 40 in the mating direction "α". By fixing the opening 45 while receiving one end of the cable 11, the cable 11 is fixed there.

On the other hand, on the front side of the cable terminal 40 in the mating direction "α", an upper contact surface 47 and a bottom contact surface 46 spaced apart from each other in the vertical direction "β" are formed. The cable terminal 40 can contact the board terminal 60 of the board connector 50 on each of the top contact surface 47 and the bottom contact surface 46 .

In order to ensure contact with the board terminal 60 of the board connector 50, a concave portion 41 into which a part of the board terminal 60 is fitted is formed on the upper contact surface 47 of the cable terminal 40. have. In order to smooth the contact with the board terminal 60, it is preferable to form a taper 42 at the tip of the upper contact surface 47.

On the rear side of the bottom contact surface 46 of the cable terminal 40, a locking piece 43 is formed in a state of protruding downward. The cable terminal 40 is locked to the cable housing 21 using this locking piece 43 . Further on the rear side of the locking piece 43, a concave portion 44 is formed. A lance 23 formed in the cable housing 21 can be hung on the concave portion 44 to install the cable terminal 40 at a predetermined position inside the cable housing 21 .

Fig. 4 shows a partially enlarged perspective view of the cable housing 21 viewed from the bottom side. The lance 23 is formed along the fitting direction "α" in a state supported in a cantilever shape by the body portion 29, and its tip is in the fitting direction "α" of the fitting convex portion 22. located near the middle of the When the cable terminal 40 is inserted into the cable housing 21 through the terminal insertion hole 24, the lance 23, by its elastic action, penetrates the concave portion 44 of the cable terminal 40 (FIG. 3). reference) is inserted. As a result, the cable terminal 40 is positioned at a predetermined position of the cable housing 21 . The bottom surface 23a of the lance 23 is a flat surface corresponding to at least a part of the surface 56 (see FIG. 1) of the insertion space 52 of the board connector 50 into which the fitting convex portion 22 is inserted. is making up Similarly, at least a part of the lower surface 27 on the front side of the fitting convex portion 22 in the fitting direction “α” also has an insertion space 52 of the board connector 50 into which the fitting convex portion 22 is inserted. It forms a flat surface corresponding to at least a part of the surface (reference surface) 54 (see FIG. 1).

5, a sectional perspective view of the board connector 50 is shown. The position of the cross section in this figure may be considered to correspond to the line I-I in FIG. 2 . The board connector 50 mainly includes a board housing 51 extending in the terminal arrangement direction "γ", a plurality of same-shaped board terminals 60 supported by the board housing 51, and a terminal arrangement direction. It includes reinforcing brackets 12 formed on the left and right outer surfaces of the board housing 51 at "γ", respectively. The board housing 51 is fixed to the board 13 (refer to FIG. 1) via board terminals 60 and reinforcing brackets 12.

In order to place the board terminal 60 in the board housing 51, a plurality of terminal insertion holes 66 are formed on the rear side of the board housing 51. Each board terminal 60 is inserted into and attached to the board housing 51 along the mating direction "α" through each of these terminal insertion holes 66, and the mating convex portion 22 of the cable connector 20 In the insertion space 52 into which are inserted, corresponding to each of the cable terminals 40 of the cable connector 20, they are arranged substantially in a line with each other at a predetermined pitch along the terminal arrangement direction "γ".

The board terminal 60 is formed into a plate shape by punching one sheet of metal plate, and in the board housing 51, the plate surfaces of the respective metal plates face each other in a state in which they face each other in the terminal arrangement direction “γ”. arranged next to each other. Each board terminal 60 includes a support portion 61 , an elastic arm portion 62 connected to the support portion 61 , and a mounting portion 63 .

The mounting portion 63 is a portion formed near the connection portion of the support portion 61 and the elastic arm portion 62, and is used to solder the board terminal 60 to the board. By soldering the mounting portion 63 to a predetermined portion of the board, the board terminal 60 can be fixed to the board and electrically connected to the predetermined portion of the board.

The support portion 61 is a portion used as a fixing piece, and includes a substantially linear portion formed along the fitting direction "α", and like the mounting portion 63, the support portion 61 and the elastic arm portion 62 In the vicinity of the connecting portion, it has a locking protrusion 61a that locks to the substrate housing 51 . The board terminal 60 is fixed to the board housing 51 by press-fitting the locking projection 61a into the terminal insertion hole 66 of the board housing 51 .

The elastic arm portion 62 is a portion used as a movable piece, and includes a substantially L-shaped portion extending in a cantilever shape from the support portion 61, and the side surface of the entirety of the support portion 61 and the elastic arm portion 62. When viewed from above, it forms a roughly U-shaped part. The inside of the approximately U-shape forms an insertion space 65 into which predetermined portions of the cable terminal 40 of the cable connector 50, in particular, its upper contact surface 47 and lower contact surface 46 are inserted. By being inserted into the insertion space 65, the cable terminal 40 comes into contact with the board terminal 60. In order to ensure electrical contact with the cable terminal 40, an elastic contact portion 62a is formed at the tip of the elastic arm portion 62. For the contact surface 62b of the elastic contact portion 62a with the cable terminal 40, a surface that forms the plate thickness of the metal plate, that is, a fracture surface is used. By making the contact surface a fracture surface, strength can be ensured even when the board terminal 60 is small. Upon contact with the cable terminal 40, the elastic contact portion 62a moves upward by the elastic action of the elastic arm portion 62 through contact with the cable terminal 40, for example, the taper 42 at the tip thereof. is once lifted up, and then fitted into the concave portion 41 formed in the upper contact surface 47 of the cable terminal 40. By inserting the elastic contact portion 62a into the concave portion 41, the contact between the board terminal 60 and the cable terminal 40 can be stabilized. In the insertion space 52, a relief space 57 for contact prevention is formed in consideration of lifting of the elastic contact portion 62a.

In the insertion space 52, a flat reference surface (sliding contact surface) 54 defined by two directions of the fitting direction "α" and the terminal arrangement direction "γ" is formed. When the fitting convex portion 22 is inserted into the insertion space 52, the bottom surface 27 (see Fig. 4) on the front side of the fitting convex portion 22 moves over the reference surface 54 in the fitting direction "α" sliding contact along and finally being placed there. In order to guide the lower surface 27 of the fitting convex portion 22, it is preferable to form a taper 54a on the front side of the reference surface 54. The reference surface 54 is located downward in the vertical direction "β" in a state of being separated from the elastic contact portion 62a in the vertical direction "β". Since both the reference surface 54 and the bottom surface 27 of the fitting convex portion 22 are formed as flat surfaces, the fitting convex portion 22 is formed by sliding the flat surfaces together, and finally the reference surface 54 ), and is held in the insertion space 52.

Further, in the insertion space 52, when the fitting convex part 22 is inserted into the insertion space 52, the bottom face 23a of the lance 23 formed near the middle of the fitting convex part 22 (see Fig. 4). ) is in sliding contact, and a flat surface 56 finally placed is formed along the fitting direction "α". In order to guide the bottom surface 23a of the lance 23, it is preferable to form a taper 56a on the front side of the surface 56. Since both the surface 56 and the bottom surface 23a of the lance 23 are formed as flat surfaces, the lance 23 is finally placed on the surface 56 by sliding the flat surfaces together. In this state, it is held in the insertion space 52. In addition, corresponding to the step difference between the bottom surface 27 of the fitting convex portion 22 and the bottom surface 23a of the lance 23, the reference surface 54 is higher than the surface 56 in the vertical direction "β" , located at a slightly elevated position.

On the left and right inner surfaces of the insertion space 52 in the terminal arrangement direction "γ", substantially semicircular protruding portions 55 are formed corresponding to the protruding portions 25 of the fitting convex portions 22, respectively. These protrusions 55 protrude on the side opposite to the protrusion 25, in other words, on the side opposite to the side approaching the reference plane 54 in the vertical direction "β".

Referring to Figs. 6 to 9, the function of the projections 25 and 55 will be described. 6 and 7 are cross-sectional views taken along line I-I and II-II in FIG. 2 , respectively, showing a state after the cable connector 20 and the board connector 50 are mated, in other words, the board terminal 60 The state after the cable terminal 40 is inserted into the insertion space 65 is shown. On the other hand, FIGS. 8 and 9 are views corresponding to the cross-sectional view along the line I-I and the cross-sectional view along the line II-II of FIG. 2, respectively, but unlike FIGS. 6 and 7, A state before the cable connector 20 and the board connector 50 are completely mated, more specifically, the fitting convex portion 22 of the cable housing 21 is in the insertion space 52 of the board housing 51. It is inserted and shows the state immediately after the cable terminal 40, in particular, the taper 42 formed at its tip comes into contact with the elastic contact portion 62a of the board terminal 60.

As shown in FIG. 8 , when the taper 42 of the cable terminal 40 contacts the elastic contact portion 62a of the substrate terminal 60, the cable terminal 40 is brought into contact with the elastic contact portion 62a. It is pushed to the side approaching the reference surface 54 in the vertical direction "β". Further, when the cable terminal 40 is pressed toward the reference plane 54 in the vertical direction "β" through contact with the elastic contact portion 62a, as shown in FIG. 9 , the cable housing 21 The protrusion 25 of ) abuts with the protrusion 55 of the board housing 51, and through this abutment, the cable housing 21, in other words, the cable terminal 40 supported by the cable housing 21 ) is also pushed toward the side approaching the reference plane 54 in the vertical direction "β". Thus, according to the present configuration, the direction in which the cable terminal 40 is pushed through contact with the elastic contact portion 62a and the cable housing 21, in other words, the cable terminal supported by the cable housing 21 (40) is applied to the board terminal 60 at the time of contact between the cable terminal 40 and the elastic contact portion 62a, in that the direction in which the protruding portion 25 and the protruding portion 55 are pressed are the same, The holding force can be reduced, and damage or deterioration of the board terminal 60 accompanying insertion/extraction of the cable connector and the board connector can be reduced.

In particular, in this embodiment, the timing at which the cable terminal 40 contacts the elastic contact portion 62a and the timing at which the projection 25 of the cable housing 21 abuts with the projection 55 of the substrate housing 51, It is performed almost simultaneously, and, thereby, the load applied to the board terminal 60 can be reduced more effectively. However, these timings do not necessarily have to be simultaneous.

When the cable connector 20 and the board connector 50 are fitted, as shown in FIG. 6 , the cable terminal 40 is inserted into the insertion space 65 of the board terminal 60, and as a result, the board terminal ( The elastic contact portion 62a of 60 is fitted into the concave portion 41 of the upper contact surface 47 of the cable terminal 40 exposed from the cable housing 21 . As a result, the board terminal 60 and the cable terminal 40 are more securely connected. In addition, the concave portion 41 formed in the cable terminal 40 is formed in a state of being depressed toward the side approaching the reference plane 54 in the vertical direction "β" at the portion where the elastic contact portion 62a contacts. , it also has an effect of reducing the load applied to the board terminal 60. In addition, since this concave portion 41 is formed not on the lower contact surface 46 of the cable terminal 40 but on the upper contact surface 47, the cable terminal 40 and the board terminal 60, further In other words, contact between the lower contact surface 46 of the cable terminal 40 and the surface 61b of the support portion 61 of the board terminal 60 is not hindered, and therefore, even when the concave portion is formed, the cable terminal 40 is smoothly inserted into the insertion space 65 of the board terminal 60. When the cable connector 20 and the board connector 50 are mated, the mating state of the cable connector 20 and the board connector 50, in other words, the connection state of the board terminal 60 and the cable terminal 40 7, in order to release the mating state between the cable connector 20 and the on-board connector 50 because they are locked by the protrusions 25 and 55, the protrusion 25 and the protrusion 55 are interfering. It is necessary for the protruding part 25 to ride over the protruding part 55. In this way, the protrusions 25 and 55 not only have an action of reducing the load applied to the board terminal 60, but also function as a locking mechanism.

In addition, this invention is not limited to the embodiment mentioned above, and various other changes are possible.

For example, in the embodiment described above, the projections 55 of the substrate housing 51 are placed on the left and right inner surfaces of the insertion space 52 in the terminal arrangement direction "γ", in other words, in the terminal arrangement direction "γ". Although it was intended to be formed on the outside of the array of board terminals 60 in the direction along ", they are formed in the middle of the array of board terminals 60, and in addition to the left and right inner surfaces, in the middle, and further, on the left and right inner surfaces. You may arrange it only in the middle without forming it.

In addition, the protruding portion 25 of the cable housing 21 is not necessarily necessary, and the cable terminal 40 is formed through the abutment of the cable housing 21 and the protruding portion 55 of the board housing 51 without forming the protruding portion. ) is pushed to the side of the reference plane 54. Therefore, it is sufficient if the cable housing 21 has a portion in contact with the protruding portion 55 of the board housing 51 .

In addition, in the embodiment described above, the reference surface 54 is formed on the board housing 51, but it is formed on the board terminal 60, in other words, the flat surface formed on the support portion 61 of the board terminal 60 ( 61b) (see Fig. 5), or may be further formed by the flat surface 61b and the reference surface 54.

1: connector unit
11: cable
13: Substrate
20: cable connector (first connector)
21: cable housing (first housing)
23 : Lance
25: protrusion
40: cable terminal (first terminal)
41: recess
50: board connector (second connector)
51: substrate housing (second housing)
52: insertion space
54: reference plane
55: protrusion
60: board terminal (second terminal)
61b: plate surface
62: elastic arm part (movable part)
62a: elastic contact
62b: plate surface
63: fixed part

Claims (13)

a first connector and a second connector;
The first connector has a first housing and a plurality of first terminals supported by the first housing;
The second connector has a second housing and a plurality of second terminals supported by the second housing;
The second terminal includes an elastic contact portion contacting the first terminal inserted into the insertion space of the second housing,
The insertion space has a reference surface spaced apart from the elastic contact portion in a direction orthogonal to both an insertion direction of the first terminal into the insertion space and a terminal arrangement direction of a plurality of the second terminals;
The elastic contact portion is configured to push the first terminal toward the side approaching the reference plane in the orthogonal direction through contact with the first terminal,
The second housing has a second protrusion protruding toward the side approaching the reference plane in the orthogonal direction in the insertion space, and at least the first terminal is in contact with the elastic contact portion in the orthogonal direction. When being pushed to the side approaching the reference plane, the plurality of first terminals supported by the first housing through abutting contact between the first housing inserted into the insertion space and the second protrusion are orthogonal to each other. A connector device characterized in that it is configured to be pushed to a side approaching the reference plane in a direction. According to claim 1,
The connector device of claim 1 , wherein the first housing has a first protrusion protruding in a direction opposite to a side approaching the reference plane in the orthogonal direction, and the first protrusion abuts the second protrusion. According to claim 2,
The connector device, wherein a timing at which the first terminal contacts the elastic contact portion and a timing at which the first protrusion abuts the second protrusion portion are substantially simultaneous. According to claim 2,
The connector device according to claim 1 , wherein the second protruding portion is disposed on either or both of an outside of the second terminal arrangement and a middle of the second terminal arrangement in a direction along the terminal arrangement direction. According to any one of claims 1 to 4,
The reference surface is a sliding contact surface on which the first housing slides when the first housing is inserted into the insertion space. According to any one of claims 1 to 4,
The connector device wherein the reference plane is formed by either or both of the second housing and the second terminal. According to any one of claims 1 to 4,
The connector device according to claim 1 , wherein the elastic contact portion is formed of a metal plate, and a contact surface of the elastic contact portion with the first terminal is a surface forming a plate thickness of the metal plate. According to any one of claims 1 to 4,
The plurality of second terminals are each formed of a metal plate, and at least in the elastic contact portion, the second terminals are arranged adjacent to each other in a state in which plates of the metal plates face each other. According to any one of claims 1 to 4,
The connector device according to claim 1 , wherein a concave portion is formed at a portion of the first terminal that comes into contact with the elastic contact portion and is recessed toward the side approaching the reference plane in the orthogonal direction. According to any one of claims 1 to 4,
The second terminal includes a movable piece on which the elastic contact portion is formed, and a fixing piece connected to the movable piece. According to claim 10,
The movable piece includes an L-shaped portion, the fixing piece includes a linear portion formed along the insertion direction, and the movable piece and the fixing piece have a U-shaped portion viewed from the side as a whole. , connector device. According to any one of claims 1 to 4,
The connector device, wherein at least a portion of the first terminal that contacts the elastic contact portion is exposed from the first housing. According to any one of claims 1 to 4,
The connector device, wherein the first connector is a cable connector, and the second connector is a board connector.

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