JP7360813B2 - movable connector - Google Patents

Description

The present invention relates to a movable connector.

Conventionally, a movable connector as disclosed in Patent Document 1 has been known.
In this movable connector, the terminal and the housing are integrated by integral molding. By integrating by integral molding, the stress remaining in the housing can be reduced compared to a mode in which the housing is integrated by press fitting.

Japanese Patent Application Publication No. 2018-078079 Japanese Patent Application Publication No. 2005-050695

By the way, in the above connector, the displacement of the movable housing with respect to the fixed housing in the removal direction is regulated by the mounting fitting. Therefore, a space for holding the mounting fittings is required in the fixed housing, resulting in an increase in the size of the connector. Furthermore, if one were to try to restrict the displacement of the movable housing in the removal direction without using mounting brackets, it would be necessary to provide a restriction section on each of the movable housing and the fixed housing, which would also lead to an increase in size (for example, patent (See Reference 2).

The present invention has been made in view of the above. That is, an object of the present invention is to miniaturize a movable connector.

A movable connector according to a first aspect is a movable connector including a fixed housing fixed to an object to be attached, a movable housing configured to be movable relative to the fixed housing, and a terminal, the movable connector comprising: The terminal is located between a fixed held part held by the fixed housing, a movable held part held by the movable housing, and the fixed held part and the movable held part. a movable part, the holding of the fixed side held part is performed by integrally molding the fixed housing and the terminal, and the removal force when removing the connection object is determined by the elasticity of the movable part. The movable connector is smaller than the maximum elastic force in the range, and the movable connector does not have a means for defining a movable range in the removal direction of the movable housing by coming into contact with the movable housing.

In this aspect, the movable connector includes a fixed housing fixed to an attachment target such as a board, a movable housing configured to be movable relative to the fixed housing, and a terminal. The terminal includes a fixed held part held by the fixed housing, a movable held part held by the movable housing, and a movable part located between the fixed held part and the movable held part. , has.
When the movable housing is displaced relative to the fixed housing, the movable portion of the terminal is deformed.

Further, the fixed-side held portion of the terminal is held by integrally molding the fixed housing and the terminal. For this reason, stress remaining in the fixed housing is suppressed compared to a mode in which holding is performed by press-fitting.
If stress remains in the fixed housing, the fixed housing is likely to deform when placed in a high temperature environment (particularly during reflow soldering). Particularly, in small connectors, the resin wall of the fixed housing is thin and is easily deformed.
In this aspect, the stress remaining in the fixed housing is suppressed, making it easy to downsize the connector.

Further, in this aspect, the removal force when removing the connection target object is smaller than the maximum elastic force in the elastic range of the movable part. In connection with this, in this aspect, the movable connector does not include means for defining the movable range of the movable housing in the removal direction by coming into contact with the movable housing. Therefore, there is no need for a space for providing the means, and the movable connector can be made smaller.

In addition, the removal force when removing a connected object is the force when the movable connector and the mating connector are connected, and the mating connector is pulled in the removal direction at a predetermined speed (25 mm/min) to release the connection. , means the force applied to the mating connector.
Moreover, the maximum elastic force in the elastic range of the movable part means the maximum value of the elastic force in the range in which the movable part of the terminal is elastically deformed when the movable housing is pulled in the removal direction.
That is, in this aspect, the elastic force of the terminal is set to be greater than the removal force to the extent that plastic deformation does not occur in the movable portion of the terminal when the mating connector is removed from the movable connector.

In the movable connector according to the second aspect, in the first aspect, the holding of the movable-side held portion is performed by press-fitting the movable-side held portion into the movable housing.

In this aspect, the movable held part is held by being press-fitted into the movable housing. Therefore, compared to a mode in which the movable housing and the terminal are integrally molded, it is easier to complicate the shape of the movable housing, and the degree of freedom in the shape of the movable housing is ensured.

In the movable connector according to a third aspect, in the first or second aspect, the movable housing includes a defining surface that defines a movable range of the movable housing in the horizontal direction of the connector by coming into contact with the fixed housing; The connector has a guide surface that is inclined with respect to the horizontal direction to guide the connection object, and a part of the guide surface is located on the outer side of the connector in the horizontal direction than the defined surface.

Note that the horizontal direction of the connector means a direction in a plane perpendicular to the removal direction, and the outer side of the connector in the horizontal direction means a direction away from the center of the connector in the horizontal direction of the connector.

In this aspect, the movable housing has a defining surface that defines the movable range of the movable housing in the horizontal direction of the connector by coming into contact with the fixed housing. Therefore, the movable range of the movable housing in the X and Y directions is defined by the defining surface of the movable housing coming into contact with the fixed housing.
Moreover, the movable housing has a guiding surface for guiding the connection target. Therefore, when the movable connector and the object to be connected are connected, the object to be connected is guided by the part to be connected coming into contact with the guiding surface of the movable housing.
Furthermore, a portion of the guiding surface is located further outward in the horizontal direction of the connector than the regulation surface. Therefore, it is possible to increase the amount of attracting objects to be connected.

As explained above, the present invention has the excellent effect of being able to downsize the movable connector.

It is a perspective view of a reinforcing metal fitting and a terminal. FIG. 2 is a perspective view of a work-in-process product manufactured by insert molding. It is a perspective view before assembling a work-in-progress and a movable housing. It is a perspective view of a movable connector. FIG. 3 is a perspective view of a pair of terminals facing each other in the inter-row Y direction. It is a perspective view of a reinforcing metal fitting. It is a perspective view of a reinforcing metal fitting. It is a front view of a reinforcing metal fitting. It is a side view of a reinforcing metal fitting. It is a top view of a reinforcing metal fitting. FIG. 3 is a plan view of work-in-progress. FIG. 3 is a cross-sectional perspective view of the fixed housing (a cross-sectional view at the center position in the Y direction between the rows). FIG. 3 is a cross-sectional perspective view of the fixed housing (a cross-sectional view at a position shifted from the center position in the inter-row Y direction). It is a perspective view which expands and shows the pitch direction wall of a fixed housing. FIG. 2 is a cross-sectional perspective view (a cross-sectional view perpendicular to the vertical direction) of the fixed housing. FIG. 3 is a cross-sectional view (a cross-sectional view perpendicular to the vertical direction) of the fixed housing. FIG. 3 is a cross-sectional perspective view showing a state before the movable housing is assembled to the work-in-progress. FIG. 3 is a cross-sectional perspective view of the movable connector. FIG. 3 is a cross-sectional view of the movable connector (a cross-sectional view at the center position in the Y direction between the rows). FIG. 3 is a cross-sectional perspective view showing a movable connector and a mating connector. FIG. 3 is a cross-sectional perspective view showing a fitting limit state between a movable connector and a mating connector. FIG. 2 is a schematic cross-sectional view showing a mold for insert molding.

An embodiment of the present invention will be described using FIGS. 1 to 22.

In the following description, the arrow X shown in each figure is the front direction of the connector, the arrow Y is one side (left side) in the connector width direction, and the arrow Z is the upward direction of the connector. In addition, when using the terms front and back, top and bottom, and width (left and right) unless otherwise specified, they refer to the front and rear of the connector in the front and back direction, the top and bottom of the connector in the top and bottom direction, and the width (left and right) in the connector width direction (left and right direction).
Further, the arrow X may be referred to as one side in the pitch X direction, and the arrow Y may be referred to as one side in the inter-row Y direction.

(Manufacturing method of movable connector)
FIG. 4 is a perspective view of the movable connector 100. The method for manufacturing the movable connector 100 includes a work-in-progress manufacturing process of manufacturing the work-in-progress 100A (FIG. 2), and an assembly process of assembling the movable housing (FIG. 3) to the work-in-progress 100A.

In the work-in-process manufacturing process, as shown in FIGS. 1 and 2, the resin part 20 that constitutes a part of the fixed housings 20, 40 is integrally molded with the terminals 30 and reinforcing metal fittings 40 by insert molding, and the work-in-process Manufacture product 100A. Note that in the present disclosure, the reinforcing metal fittings 40 are regarded as part of the fixed housings 20 and 40.
When performing insert molding, the terminals 30 and reinforcing metal fittings 40 are connected to respective carriers (not shown) (not separated from the material).

Next, in the assembly step, as shown in FIGS. 3 and 4, the movable housing 50 is assembled from above to the work in progress 100A. In the assembly process, as shown in FIGS. 17 and 18, a portion of each terminal 30 (movable-side held portion 34) is press-fitted into the terminal press-fit groove 51H (terminal holding portion 51H) of the movable housing 50.

In the completed movable connector 100, even if the movable housing 50 moves upward in the connector, the movable housing 50 does not come into contact with the fixed housings 20, 40. That is, the movable connector 100 does not include means for defining the upward movable range (removal direction) of the movable housing 50 by coming into contact with the movable housing 50.

(terminal)
The movable connector 100 includes a plurality of terminals 30. As shown in FIG. 5, the plurality of terminals 30 are arranged in pairs so as to face each other in the inter-row Y direction, and as shown in FIG. 1, a large number of these pair of terminals 30, 30 are arranged in the pitch X direction.

The terminal 30 is manufactured by punching and bending a plate material. As shown in FIG. 5, the terminal 30 has a plurality of parts where the plate material is bent, but the thickness direction of all the parts is oriented in a plane perpendicular to the pitch X direction (in the YZ plane).

As shown in FIG. 18, the terminal 30 includes a fixed side held part 32 held by the fixed housings 20 and 40, a movable side held part 34 held by the movable housing 50, and a fixed side held part 32. A movable portion 33 located between the movable side held portion 34 and the movable side held portion 34 . Therefore, the terminal 30 bridges the fixed housings 20, 40 and the movable housing 50.

The fixed side held portion 32 is held by the fixed housings 20, 40 by integrating the terminals 30 and the resin portions 20 of the fixed housings 20, 40 by insert molding. The fixed side held part 32 includes a curved part 32M. In other words, the fixed-side held portion 32 is held by the fixed housings 20, 40 with its curved portion 32M buried in the fixed housings 20, 40.
The fixed side held portion 32 is arranged with the plate width direction facing the pitch X direction. No protrusion for press-fitting is formed on the outside of the fixed-side held portion 32 in the plate width direction. Therefore, the distance between the plurality of terminals 30 (distance in the pitch X direction) can be narrowed, and the movable connector 100 can be made smaller in the pitch X direction.

The movable side held portion 34 is held by the movable housing 50 by being press-fitted into the movable housing 50. As shown in FIG. 5, the movable-side held portion 34 is formed with a protrusion 34A that is press-fitted into the movable housing 50 and held therein. The protrusion 34A has a shape that allows the terminal 30 to be press-fitted upward into the movable housing 50.

The movable portion 33 is configured to be easily elastically deformed. This allows relative displacement of the movable housing 50 with respect to the fixed housings 20, 40. The movable part 33 includes a first straight part 33A extending upward from the fixed side held part 32, a curved part 33B bent so as to be convex above, and extending downward and diagonally inward in the inter-row Y direction. It has a second straight part 33C and a curved part 33D between the second straight part 33C and the movable side held part 34 in this order from the one end 30A side to the other end 30B side.

Further, the terminal 30 has a contact portion 36 that comes into contact with the mating connector 10 (FIGS. 20 and 21) inserted from above the connector. The contact portion 36 is located closer to the other end 30B than the movable held portion 34 is. The contact portion 36 has a curved shape that is convex inward in the inter-row Y direction, and contacts the mating connector 10 at the convex portion of this curved shape. Further, the contact portion 36 has a curved portion 36M between it and the elastic portion 35 described later, which causes the contact portion 36 to protrude inward in the inter-row Y direction.

Further, the terminal 30 includes an elastic portion 35 that is elastically deformed when the contact portion 36 contacts the mating connector 10. The elastic part 35 is located between the movable held part 34 and the contact part 36. When the mating connector 10 is inserted, the distance between the pair of contact parts 36, 36 facing each other in the inter-row Y direction is expanded, and the elastic part 35 is elastically deformed. Thereby, the contact portion 36 comes into pressure contact with the mating connector 10. However, in FIG. 21, the terminal 30 is not shown in an elastically deformed state, but is shown in a free state.

(Fixed housing)
As shown in FIG. 11, the fixed housings 20, 40 are comprised of a resin part 20 made of resin and a reinforcing metal fitting 40 integrated with the resin part 20.

The fixed housings 20, 40 have peripheral walls 21, 22. Specifically, the peripheral walls 21 and 22 include a pair of pitch direction walls 22 located on both sides in the pitch X direction, and a pair of interrow direction walls 21 located on both sides in the interrow Y direction.

A part of the movable housing 50 is accommodated inside the circumferential walls 21 and 22 (the space surrounded by the circumferential walls 21 and 22, the accommodation space 26). A portion of the movable housing 50 is restrained within the accommodation space 26 of the fixed housings 20 and 40, thereby defining the movable range of the movable housing 50 in the XY direction (horizontal direction of the connector).

As shown in FIG. 18, the fixed side held portions 32 of the terminals 30 are held in a buried state in the inter-row direction wall 21 of the movable connector 100.

The lower part 21L of the inter-row direction wall 21 of the fixed housings 20, 40 is increased in thickness so as to protrude inward in the inter-row Y direction with respect to the upper part 21U of the inter-row direction wall 21. The fixed side held portion 32 of the terminal 30 is held at the lower part 21L of the inter-row direction wall 21 of the fixed housings 20, 40. As a result, a portion of the first linear portion 33A of the movable portion 33 of the terminal 30 is located inside the upper portion 21U of the inter-row wall 21 of the fixed housings 20, 40 in the inter-row Y direction.

The upper end position of the inter-row direction wall 21 is formed at a position lower than the upper end (curved part 33B) of the movable part 33. This prevents the movable portion 33 from interfering with the fixed housings 20 and 40 when the movable housing 50 is displaced in the inter-row Y direction and the movable portion 33 of the terminal 30 is deformed.

The upper end of the pitch direction wall 22 is located above the connector than the upper end of the inter-row direction wall 21. Further, the upper end of the pitch direction wall 22 is located below the upper end (curved portion 33B) of the movable portion 33 of the terminal 30.

As shown in FIG. 11, a vertical groove 23 extending in the vertical direction is formed on the outer surface of the pitch direction wall 22 in the pitch X direction. The vertical groove 23 is formed with the inner side in the pitch X direction as the depth direction. A portion of the reinforcing metal fitting 40 is exposed from the portion of the pitch direction wall 22 where the vertical groove 23 is formed. The width of the vertical groove 23 (dimension in the Y-direction between rows) is larger than the width (dimension in the Y-direction between rows) of a carrier cutting portion 46, which will be described later.

Two reinforcing metal fittings 40 are provided for one movable connector 100. One reinforcing metal fitting 40 is located on one side of the movable connector 100 in the pitch X direction, and the other reinforcing metal fitting 40 is located on the other side of the movable connector 100 in the pitch X direction. The two reinforcing metal fittings 40 have the same structure.

The reinforcing metal fitting 40 is manufactured by punching and bending a plate material.

As shown in FIGS. 6, 7, etc., the reinforcing metal fitting 40 includes a first flat plate part 40A, a second flat plate part 40B, a third flat plate part 40C, and a fourth flat plate part 40D, each of which has a flat plate shape, and each flat plate part 40A. , 40B, 40C, and 40D. Each of the curved portions 41A, 41B, and 41C is a portion bent approximately 90 degrees in the thickness direction.

The first flat plate portion 40A constitutes a part of the pitch direction wall 22 of the fixed housings 20, 40. The first flat plate portion 40A has its thickness direction oriented in the pitch X direction. The first flat plate portion 40A has a substantially rectangular shape with the inter-row Y direction as the longitudinal direction and the up-down direction as the lateral direction.

As shown in FIG. 14, etc., the inner surface 40A2 (“other surface”) of the first flat plate portion 40A in the pitch , are exposed from the resin part 20. Both end portions 44 in the width direction of the first flat plate portion 40A are buried in the resin portion 20, and the entire surface including both surfaces is covered with the resin portion 20. Hereinafter, a portion of the first flat plate portion 40A corresponding to the exposed inner surface 40A2 in the pitch X direction will be referred to as an exposed portion 43.

As shown in FIG. 14 and the like, a surface 40A1 (“one surface”) on the outside in the pitch X direction is exposed from the resin portion 20 at the center portion in the width direction and the upper end portion of the exposed portion 43 of the first flat plate portion 40A. Therefore, the central portion in the width direction and the upper end portion of the exposed portion 43 is a double-sided exposed portion 43R in which both sides in the pitch X direction are exposed from the resin portion 20.
Specifically, a downwardly recessed recess 24 is formed in the pitch direction wall 22 of the fixed housings 20, 40. Due to this recessed portion 24, a surface 40A1 on the outside in the pitch X direction is exposed from the resin portion 20 in a part of the first flat plate portion 40A. As shown in FIG. 22, a mold ("molding jig") is placed in the recess 24 during insert molding. In addition, in FIG. 22, the upper mold, the lower mold, etc. of the mold are shown without distinction.
Further, as shown in FIG. 19, the recess 24 is formed with an inclined surface 24A. The inclined surface 24A is formed at the bottom of the recess 24 on the side adjacent to the reinforcing metal fitting 40 (on the inside in the pitch X direction). The inclined surface 24A is a surface that faces upward as it advances toward the side adjacent to the reinforcing metal fitting 40 (inner side in the pitch X direction).
On the other hand, in the exposed portion 43 other than the double-sided exposed portion 43R, the outer surface 40A1 (“one surface”) in the pitch X direction is covered with the resin portion 20, and the inner surface 40A2 (“the other surface”) in the pitch The single-sided exposed portion 43K is a portion exposed from the resin portion 20.

As shown in FIG. 14, the upper plate end surface 43R3 of the double-sided exposed portion 43R is exposed from the resin portion 20. During insert molding, the mold comes into contact with the upper plate end surface 43R3 of the first flat plate portion 40A (see FIG. 22).

The second flat plate part 40B is connected to the first flat plate part 40A via the first curved part 41A below the first flat plate part 40A. The first curved portion 41A extends linearly in the inter-row Y direction. The length of the first curved portion 41A (the length in the inter-row Y direction) is the same as the length of the lower end of the first flat plate portion 40A (the length in the inter-row Y direction). The first curved portion 41A is bent outward in the pitch X direction, and the second flat plate portion 40B is located outside in the pitch X direction with respect to the first flat plate portion 40A.

As shown in FIG. 12, the first curved portion 41A is entirely covered with the resin portion 20. As shown in FIG. The other surface of the exposed portion 43 (the inner surface 40A2 in the pitch X direction) and the surface 20A2 of the resin portion 20 formed below the other surface 40A2 are located on the same plane. In other words, the portion 20A2 of the resin portion 20 located below the first flat plate portion 40A, together with the other surface 40A2 of the exposed portion 43, is a plane (pitch ) to form. The pitch X direction defining surface can come into contact with the pitch X direction defining surface 57 (FIG. 16) of the movable housing 50. A pair of bulges 25 that bulge inward in the pitch X direction are formed on the outer side in the inter-row Y direction of the pitch X direction defining surface. By the bulging portion 25, both ends 44 of the first flat plate portion 40A in the width direction are buried in the resin portion 20 and covered from both sides.

The second flat plate portion 40B constitutes a part of the pitch direction wall 22 of the fixed housings 20, 40. The second flat plate portion 40B has its thickness direction oriented in the vertical direction of the connector. The second flat plate portion 40B extends outward in the pitch X direction from the first curved portion 41A. The width of the second flat plate portion 40B (inter-row dimension in the Y direction) is approximately the same as the width of the first flat plate portion 40A.

The second flat plate portion 40B has different lengths (lengths extending outward in the pitch X direction) depending on its position in the width direction. Specifically, as shown in FIG. 10, the second flat plate portion 40B includes a general portion 45A, a short portion 45B that is shorter than the general portion 45A, and a long portion 45C that is longer than the general portion 45A. It consists of
The short portion 45B is formed at the center in the width direction of the second flat plate portion 40B. A pair of long portions 45C are formed across the widthwise center of the second flat plate portion 40B. The general portion 45A is formed in a portion of the second flat plate portion 40B other than the short portion 45B and the long portion 45C. Specifically, a pair of general portions 45A are formed at positions between the short portions 45B and the pair of long portions 45C, and at positions on the outside in the width direction (outside in the inter-row Y direction) of the pair of long portions 45C. A pair is also formed.
As shown in FIG. 16 etc., a part of the second flat plate part 40B on the tip side of the long part 45C is exposed from the resin part 20 of the fixed housing 20, 40, and the other part is buried in the resin part 20. do. The tip of the long portion 45C (the outer end in the pitch X direction) is a carrier cutting portion 46, which will be described later.

The third flat plate part 40C is connected to the first flat plate part 40A via a pair of second curved parts 41B formed on the outside of the first flat plate part 40A in the width direction (inter-row Y direction). The second curved portion 41B extends in the vertical direction of the connector. The length (vertical dimension) of the second curved portion 41B is shorter than the vertical dimension of the first flat plate portion 40A. The second curved part 41B is connected to the lower part of the first flat plate part 40A, but not connected to the upper part of the first flat plate part 40A. The second curved portion 41B is bent inward in the pitch X direction, and the third flat plate portion 40C is located inward in the pitch X direction with respect to the first flat plate portion 40A.

The third flat plate portion 40C constitutes a part of the pitch direction wall 22 and the inter-row direction wall 21 of the fixed housings 20, 40. The third flat plate portion 40C has its thickness direction directed toward the inter-row Y direction. The entire third flat plate portion 40C is buried in the resin portion 20 and is not exposed from the resin portion 20.

The width (dimension in the pitch X direction) of the third flat plate portion 40C is enlarged at its lower end such that the outer end of the third flat plate portion 40C in the pitch X direction is located on the outer side in the pitch X direction. Therefore, the width (dimension in the pitch X direction) of the third flat plate portion 40C is larger at the lower end than at the same height as the second curved portion 41B. As shown in FIG. 9, the outer end in the pitch X direction at the lower end of the third flat plate portion 40C is located on the outer side in the pitch X direction than the surface 40A1 on the outer side in the pitch X direction of the first flat plate portion 40A.

The fourth flat plate part 40D is connected to the third flat plate part 40C via a third curved part 41C formed on the lower side of the third flat plate part 40C. The third music section 41C extends in the pitch X direction. The length (dimension in the pitch X direction) of the third curved portion 41C is the same as the width (dimension in the pitch X direction) of the lower end of the third flat plate portion 40C.

As shown in FIG. 11, the fourth flat plate portion 40D is not buried in the resin portion 20 of the fixed housings 20, 40, but is entirely exposed from the resin portion 20. The fourth flat plate portion 40D has its thickness direction oriented in the vertical direction of the connector. The fourth flat plate portion 40D has a rectangular shape with the pitch X direction as the longitudinal direction and the inter-row Y direction as the transverse direction. The width (dimension in the pitch X direction) of the fourth flat plate portion 40D is the same as the width of the third curved portion 41C and the width of the lower end of the third flat plate portion 40C. The fourth flat plate portion 40D is placed on the surface of the substrate and soldered to the substrate.

FIG. 15 is a cross-sectional view at a height corresponding to the lower portion of the first flat plate portion 40A. As shown in FIG. 15, a C-shaped portion 47 whose cross section perpendicular to the vertical direction has a substantially C-shape due to the lower part of the first flat plate portion 40A, the second curved portion 41B, and the third flat portion 40C. is formed. In other words, as shown in FIG. 8, the reinforcing metal fitting 40 can be said to have a C-shaped portion 47 whose cross-sectional shape perpendicular to the vertical direction is substantially C-shaped.
Further, the reinforcing metal fitting 40 has an extension portion 48 extending from the C-shaped portion 47 upwardly of the connector. The extension portion 48 has a substantially linear cross-sectional shape perpendicular to the vertical direction. The extension portion 48 is formed by extending the lower portion of the first flat plate portion 40A of the C-shaped portion 47 upward. That is, the extension part 48 is the upper part of the first flat plate part 40A.
The height of the upper end of the C-shaped portion 47 is lower than the height of the inter-row wall 21 of the fixed housings 20, 40, but the height of the upper end of the extension portion 48 is lower than the height of the inter-row wall 21 of the fixed housings 20, 40. taller than 21.

As described above, the reinforcing metal fittings 40 are held by the fixed housings 20, 40 by being integrated with the fixed housings 20, 40 by insert molding. Therefore, the reinforcing metal fitting 40 does not have a means for press-fitting the reinforcing metal fitting 40 into the resin portion 20 of the fixed housing 20, 40 (protrusion for press-fitting).

During insert molding, reinforcing metal fitting 40 is in a state connected to the carrier (reinforcing metal fitting 40 is not separated from the material), and after insert molding, reinforcing metal fitting 40 is separated from the carrier. Specifically, the tip of the long portion 45C of the second flat plate portion 40B of the reinforcing metal fitting 40 is the portion that was connected to the carrier. That is, the tip of the long portion 45C is the carrier cutting portion 46. The carrier cutting portion 46 refers to a portion that is formed when the portion connecting the reinforcing metal fitting 40 and the carrier is cut after insert molding.

Two carrier cutting parts 46 are formed for one reinforcing metal fitting 40. The two carrier cutting portions 46 are formed at positions symmetrical in the front and back with respect to the center in the width direction of the reinforcing metal fitting (the center in the Y direction between rows).

(movable housing)
As shown in FIG. 17, the movable housing 50 has a terminal holding portion 51H that holds the movable side held portion 34 of the terminal 30. As shown in FIG. The terminal holding portion 51H holds the terminal 30 by press-fitting the movable side held portion 34 of the terminal 30.

As shown in FIG. 17, the movable housing 50 has a receiving portion 56 that receives the mating connector 10. The receiving portion 56 is a groove (space) that opens on the upper surface side of the movable housing 50, and extends in the pitch X direction with the downward direction of the connector as the depth direction. As shown in FIG. 18, the contact portion 36 of the terminal 30 held by the movable housing 50 is arranged inside the receiving portion 56. As shown in FIG. 21, when the mating connector 10 is inserted into the receiving portion 56, the mating connector 10 and the contact portion 36 of the terminal 30 come into contact.

As shown in FIG. 17, the movable housing 50 has a plurality of isolation walls 51 arranged between each terminal 30. The plurality of isolation walls 51 are provided at equal intervals in the pitch X direction. The terminal 30 is arranged between the separating walls 51, 51 that are adjacent to each other.
A terminal press-fitting groove 51H is formed in a part of the wall surface of the separating wall 51 so as to widen the distance between adjacent separating walls 51, 51 in the pitch X direction. The terminal press-fitting groove 51H is a groove extending in the vertical direction of the connector, into which the movable side held portion 34 of the terminal 30 is press-fitted. The terminal press-fitting groove 51H functions as the aforementioned terminal holding portion 51H.

Furthermore, the movable housing 50 has a connecting portion 52 that connects the plurality of isolation walls 51 in the pitch X direction. The connecting portion 52 improves the strength of the movable housing 50.
The connecting portion 52 extends in the vertical direction, and the lower end of the connecting portion 52 is located above the lower end of the separating wall 51. The upper end of the connecting portion 52 is located above the upper surface of the movable housing 50, which will be described later. It is connected to the front and rear portions 55A of 55.
More specifically, the connecting portion 52 includes a lower portion 52L that extends in the vertical direction, and an upper portion 52U that slopes upward and outward in the inter-row Y direction. As shown in FIG. 18, the movable side held part 34 of the terminal 30 is arranged along the lower part 52L of the connecting part 52, and the second movable part 33 of the terminal 30 is arranged along the upper part 52U of the connecting part 52. The straight portion 33C (FIG. 5) is arranged along the straight line portion 33C (FIG. 5). The lower part 52L of the connecting part 52 and the movable-side held part 34 of the terminal 30 are arranged in a substantially contacting relationship, and the upper part 52U of the connecting part 52 and the second linear part 33C of the movable part 33 of the terminal 30 33 is spaced apart so that it can be displaced. In this disclosure, when the arrangement of the terminals 30 is described, unless otherwise specified, it is assumed that the terminals 30 are in a free state.

The terminal 30 extends from outside in the inter-row Y direction with respect to the connecting portion 52, with a part of the terminal 30 (elastic portion 35) passing below the connecting portion 52, to inside in the inter-row Y direction with respect to the connecting portion 52. It is growing. Thereby, the connecting portion 52 is arranged between the movable portion 33 and the movable side held portion 34 of the terminal 30 and the contact portion 36 of the terminal 30.
Further, the lower end of the connecting portion 52 and the terminal 30 located below the lower end of the connecting portion 52 are spaced apart in the vertical direction. Further, the connecting portion 52 and the terminal 30 (elastic portion 35 and contact portion 36) located inside the connecting portion 52 in the inter-row Y direction are spaced apart from each other in the inter-row Y direction. These allow the elastic portion 35 of the terminal 30 to be deformed.
Furthermore, a recessed portion 52A recessed outward in the inter-row Y direction is formed in the upper portion 52U of the connecting portion 52. This ensures a space into which the tip of the contact portion 36 can enter when the elastic portion 35 is deformed.

Furthermore, the movable housing 50 has an opening edge connecting portion 53 that connects the plurality of separation walls 51 in the pitch X direction at an edge portion that opens upwardly of the receiving portion 56 .

Furthermore, the movable housing 50 has a bottom connecting portion 54 at the bottom of the receiving portion 56 that connects the plurality of isolation walls 51 in the pitch X direction. The bottom connecting portion 54 has a structure (size, shape) that allows the terminal 30 to be assembled to the movable housing 50 from below.

Furthermore, the movable housing 50 has an upper surface portion 55 that constitutes the upper surface of the movable housing 50 . The upper surface portion 55 is formed in a rectangular shape whose longitudinal direction is the pitch X direction in plan view. The upper surface portion 55 has front and rear portions 55A that constitute both sides in the inter-row Y direction and extend in the pitch X direction. As shown in FIG. 18, the front and rear portions 55A extend outward in the inter-row Y direction so as to cover the movable portions 33 of the terminals 30 from above. As a result, the outer end of the upper surface portion 55 in the inter-row Y direction is located on the outer side in the inter-row Y direction than the movable portion 33 (the curved portion 33B and the first straight portion 33A) of the terminal 30.

Further, the opening edge connecting portion 53 constitutes a part of the upper surface portion 55. The opening edge connecting portion 53 and the front and rear portions 55A of the upper surface portion 55 are provided separately. Therefore, as shown in FIG. 17, a plurality of spaces existing between the plurality of separating walls 51 are opened in a portion of the upper surface portion 55 between the opening edge connecting portion 53 and the front and rear portions 55A.

Further, the upper surface portion 55 includes an outer edge portion 55O forming an outer edge portion thereof, an inner edge portion 55I inside the outer edge portion 55O, and a receiving port (opening of the receiving portion 56) further inside. It can also be considered that there is. Both the outer edge portion 55O and the inner edge portion 55I are planes whose normal direction is above the connector.
The outer edge 55O is formed higher than the inner edge 55I. In other words, the plane of the outer edge portion 55O is located above the plane of the inner edge portion 55I in the vertical direction of the connector.
An inclined portion 55M whose height gradually decreases from the outer edge 55O to the inner edge 55I is formed between the outer edge 55O and the inner edge 55I. The outer edge portion 55O, the inner edge portion 55I, and the inclined portion 55M are formed over substantially the entire circumference of the upper surface portion 55. These allow the mating connector 10 to be smoothly received into the receiving portion 56.
Further, an inclined portion 55N is also formed at the boundary between the inner edge portion 55I and the receiving portion 56. This inclined portion 55N is formed in the opening edge connecting portion 53.

Further, as shown in FIG. 19, the movable housing 50 has a pitch X direction defining surface 57 that comes into contact with the fixed housings 20, 40 when the movable housing 50 is displaced in the pitch X direction.

Further, as shown in FIG. 19, the upper surface portion 55 projects outward in the pitch X direction. As a result, the outer end of the upper surface portion 55 in the pitch X direction is located on the outer side in the pitch X direction than the pitch X direction defining surface 57 of the movable housing 50 . Further, an outer end in the pitch X direction of the inner edge portion 55I of the upper surface portion 55 (coinciding with an inner end in the pitch X direction of the inclined portion 55M) is located on the outer side in the pitch X direction than a pitch X direction defining surface 57, which will be described later.

Further, as shown in FIGS. 3 and 16, a concave portion 58 that is recessed inward in the pitch X direction with respect to the pitch X direction defining surface 57 is formed on the outer side of the pitch X direction defining surface 57 in the inter-row Y direction. . The recessed portion 58 is configured so that it does not come into contact with the bulged portion 25 of the fixed housing 20, 40 even if the movable housing 50 is displaced in the connector horizontal direction.

Further, as shown in FIG. 16, the movable housing 50 has an inter-row Y direction defining surface 59 that comes into contact with the fixed housings 20 and 40 when the movable housing 50 is displaced in the inter-row Y direction.

(Mate connector 10)
As shown in FIGS. 20 and 21, a mating connector 10 serving as a "connection target" is fitted into a movable connector 100. The mating connector 10 includes a plurality of mating terminals 70 and a mating housing 80.

The mating housing 80 includes a base portion 81 disposed along a mating board (not shown), and an insertion portion 82 protruding from the base portion 81 toward the movable connector. The insertion portion 82 is inserted into the receiving portion 56 of the movable housing 50. The insertion portion 82 protrudes from the base 81 toward the bottom of the connector. Arrangement grooves in which the contact portions 73 of the mating terminals 70 are arranged are formed on one side of the insertion portion 82 in the inter-row Y direction and on the other side in the inter-row Y direction. The arrangement groove extends linearly in the vertical direction of the connector.

The mating terminal 70 is manufactured by punching and bending a plate material. The mating terminal 70 has a plurality of parts where the plate material is bent, but the thickness direction of all the parts is oriented in a plane perpendicular to the pitch X direction.

The mating terminal 70 has a mounting portion 71, a first buried portion 72, a contact portion 73, and a second buried portion 74 from one end side to the other end side.

The mounting portion 71 is fixed to the surface of the mating board by soldering. The mounting portion 71 linearly extends inward in the inter-row Y direction from one end side to the other end side.

The first buried portion 72 is buried in the mating housing 80. A first curved portion 75A is formed between the mounting portion 71 and the first buried portion 72. The first buried portion 72 includes a second music portion 75B and a third music portion 75C. The first buried portion 72 passes through the base portion 81 of the mating housing 80 in the vertical direction.

The contact portion 73 is exposed from the mating housing 80. The contact portion 73 extends linearly toward the bottom of the connector, with the plate thickness direction facing the inter-row Y direction and the plate width direction facing the pitch X direction. In the fitted state shown in FIG. 21, the contact portion 36 of the terminal 30 of the movable connector 100 contacts the contact portion 73 of the mating terminal 70.

The second buried portion 74 is buried in the mating housing 80. A fourth curved portion 75D is formed between the contact portion 73 and the second buried portion 74. In the fourth curved portion 75D, the downward extending direction of the connector in the exposed portion 43 is curved inward in the inter-row Y direction. The second buried portion 74 includes a fifth music portion 75E. The entirety of the fifth music part 75E is buried in the mating housing 80. In the fifth curved portion 75E, the inner extending direction in the inter-row Y direction is curved toward the connector downward. The distal end surface (the surface formed by cutting the plate material) of the second buried portion 74 is exposed from the mating housing 80 toward the connector downward.

The plurality of mating terminals 70 and the mating housing 80 are integrated by insert molding. Therefore, the mating terminal 70 does not have a means for press-fitting the mating terminal 70 into the mating housing 80 (protrusion for press-fitting).

<Effect>
Next, the effects of this embodiment will be explained.

In the present embodiment, the movable connector 100 includes fixed housings 20, 40 fixed to a board, a movable housing 50 configured to be movable relative to the fixed housings 20, 40, and a movable housing 50 that is configured to be movable relative to the fixed housings 20, 40. 50, and a terminal 30 that bridges the terminal 50. The movable range of the movable housing 50 is defined by the movable housing 50 coming into contact with the fixed housings 20 and 40.

The fixed housings 20 and 40 also include a resin part 20 made of resin and a reinforcing metal fitting 40 integrated with the resin part 20. By integrating the resin portion 20 and the reinforcing metal fittings 40, the strength of the fixed housings 20, 40 is ensured.
Moreover, the reinforcing metal fitting 40 and the resin part 20 are integrated by insert molding. Therefore, compared to a mode in which the parts are integrated by press-fitting, a press-fitting step is not required during manufacturing.

Furthermore, the reinforcing metal fitting 40 has a portion (" single-sided exposed portion 43K''). Therefore, this portion of the reinforcing metal fitting 40 can contribute to improving the strength of the fixed housings 20, 40, and it is possible to suppress the resin from curing while the reinforcing metal fitting 40 remains deformed.
That is, since one surface (the outer surface 40A1 in the pitch X direction) of the single-sided exposed portion 43K of the reinforcing metal fitting 40 is covered with the resin portion 20, the portion is smaller than the portion where both surfaces are exposed from the resin portion. (Single-sided exposed portion 43K) can effectively contribute to improving the strength of the fixed housing.
Further, when performing insert molding, the reinforcing metal fitting 40 can be supported by bringing a mold into contact with the other surface (the inner surface 40A2 in the pitch X direction) of the one-sided exposed portion 43K of the reinforcing metal fitting 40. By supporting the reinforcing metal fittings 40, it is possible to suppress the molten resin from pushing the reinforcing metal fittings 40 and deforming the reinforcing metal fittings 40.

Moreover, in this embodiment, the fixed housings 20 and 40 have peripheral walls 21 and 22. The peripheral walls 21 and 22 form an accommodation space 26 in which the movable housing is accommodated. The other surface (inner surface 40A2 in the pitch X direction) of the single-sided exposed portion 43K is exposed to the accommodation space 26.
Therefore, as shown in FIG. 22, the other surface (the inner surface 40A2 in the pitch be able to. Therefore, the mold does not need to be complicated, and the movable connector 100 can be easily manufactured.

Further, in the present embodiment, the reinforcing metal fitting 40 includes a first flat plate portion 40A having a flat plate shape. The first flat plate portion 40A constitutes a part of the peripheral walls 21 and 22, and is arranged with the thickness direction being the same as the wall thickness direction of the peripheral walls 21 and 22. The single-sided exposed portion 43K is a part of the first flat plate portion 40A.
Therefore, the peripheral walls 21 and 22 of the fixed housings 20 and 40 can be effectively reinforced by the first flat plate portion 40A whose thickness direction is the same as the wall thickness direction of the peripheral walls 21 and 22. Furthermore, since insert molding can be performed with the first flat plate portion 40A supported, deformation of the peripheral walls 21 and 22 in a high temperature environment can be suppressed.

Further, in this embodiment, the reinforcing metal fitting 40 has a carrier cutting part 46. The carrier cutting portion 46 is a portion formed when the portion connecting the reinforcing metal fitting 40 and the carrier is cut off after insert molding. Further, the reinforcing metal fitting 40 has a connecting portion (a first curved portion 41A and a second flat plate portion 40B) that connects the single-sided exposed portion 43K and the carrier cutting portion 46 and is at least partially buried in the resin portion 20. Then, the carrier cutting portion 46 is exposed to an external space that is a space outside the peripheral walls 21 and 22. Therefore, within the limited thickness of the peripheral walls 21, 22 of the fixed housings 20, 40, the connecting portion (first curved portion 41A, second flat plate portion 40B) connecting the single-sided exposed portion 43K and the carrier cutting portion 46 is formed. can be formed into a large size.

Furthermore, in the present embodiment, the reinforcing metal fitting 40 is a portion where both one surface (the outer surface 40A1 in the pitch X direction) and the other surface (the inner surface 40A2 in the pitch X direction) are exposed from the resin part 20. It is configured to include a double-sided exposed portion 43R, which is a portion adjacent to the single-sided exposed portion 43K.
Therefore, as shown in FIG. 22, when insert-molding the fixed housings 20, 40 and the reinforcing metal fittings 40, the other surface (the inner surface in the pitch 40A2), and also bring the mold into contact with one surface (the outer surface 40A1 in the pitch X direction) of the double-sided exposed portion 43R, thereby supporting the reinforcing metal fitting 40. By supporting the double-sided exposed portions 43R of the reinforcing metal fitting 40 from both sides, deformation of the reinforcing metal fitting 40 due to being pushed by the molten resin can be more reliably suppressed.

Further, in this embodiment, as shown in FIG. 19, the resin portion 20 includes an upper portion 20U located above the connector than the reinforcing metal fitting 40. The upper portion 20U is configured to be able to come into contact with the movable housing 50 that is displaced below the connector. Therefore, even if the movable housing 50 moves below the connector, the movable housing 50 contacts the resin portion 20 and does not contact the reinforcing metal fitting 40.
In particular, in this embodiment, at the upper end of the reinforcing metal fitting 40, where the reinforcing metal fitting 40 has its fractured surface (plate end surface 43R3, see FIG. 14) facing upward, the upper part 20U of the resin part 20 This prevents the movable housing 50 from coming into contact with the movable housing 50. Therefore, damage to the movable housing 50 is suppressed.

Next, the effects of this embodiment will be explained from different viewpoints.

In this embodiment, the movable connector 100 includes fixed housings 20 and 40 fixed to a board, a movable housing 50 configured to be movable relative to the fixed housings 20 and 40, and terminals 30. The terminal 30 includes a fixed side held part 32 held by the fixed housings 20 and 40, a movable side held part 34 held by the movable housing 50, and a fixed side held part 32 and a movable side held part 34. and a movable part 33 located between the two.
When the movable housing 50 is displaced relative to the fixed housings 20 and 40, the movable portion 33 of the terminal 30 is deformed.

Further, the fixed side held portion 32 of the terminal 30 is held by integrally molding the fixed housings 20, 40 and the terminal 30. For this reason, stress remaining in the fixed housings 20, 40 is suppressed compared to a mode in which holding is performed by press-fitting.
If stress remains in the fixed housings 20, 40, the fixed housings 20, 40 are likely to deform when placed in a high temperature environment (particularly during reflow soldering). Particularly, in small connectors, the resin wall of the fixed housing is thin and is easily deformed.
In this embodiment, the stress remaining in the fixed housings 20, 40 is suppressed, making it easy to downsize the connector.

Further, in this embodiment, the removal force when removing the mating connector 10 is smaller than the maximum elastic force in the elastic range of the movable portion 33 of the terminal 30. In relation to this, in the present embodiment, the movable connector 100 does not include means for defining the movable range of the movable housing 50 in the removal direction (in the upward direction of the connector) by coming into contact with the movable housing 50. Therefore, there is no need for a space for providing the means, and the movable connector 100 can be made smaller.

Further, in this embodiment, the movable side held portion 34 is held by being press-fitted into the movable housing 50. Therefore, compared to a mode in which the movable housing 50 and the terminal 30 are integrally molded, the shape of the movable housing 50 can be easily complicated, and the degree of freedom in the shape of the movable housing 50 is ensured.

In addition, in this embodiment, the movable housing 50 has a defining surface (a pitch X direction defining surface 57, an inter-row Y direction It has a defining surface 59 (FIG. 16). Therefore, the movable range of the movable housing 50 in the X and Y directions is defined by the defining surface (pitch X direction defining surface 57) of the movable housing coming into contact with the fixed housing.
Furthermore, the movable housing 50 has a guiding surface (slope portion 55M) for guiding the mating connector 10. Therefore, when the movable connector 100 and the mating connector 10 are connected, the mating connector 10 is guided by the mating connector 10 coming into contact with the guiding surface (slanted portion 55M) of the movable housing 50.
Further, a part of the guiding surface (slanted portion 55M) is located on the outer side in the horizontal direction of the connector than the defining surfaces (pitch X direction defining surface 57, inter-row Y direction defining surface 59). Therefore, the amount of invitation of the mating connector 10 can be increased.

[Supplementary explanation of the above embodiment]
Although the above embodiment describes a movable connector in which a large number of terminals 30 are arranged, the present invention is not limited thereto. For example, the movable connector may have one terminal.

Further, in the above embodiment, an example has been described in which the reinforcing metal fitting 40 also functions as a fixing metal fitting for fixing the fixed housings 20, 40 to the substrate, but the present invention is not limited to this. For example, the reinforcing metal fittings may not have the function of a fixing metal fitting (a fixing metal fitting may be provided separately from the regulating metal fittings).

Further, in the above embodiment, an example in which the movable housing 50 is made of only a resin molded body has been described, but the present invention is not limited thereto. For example, the movable housing may be composed of a resin molded body and a metal fitting integrated with the resin molded body.

Furthermore, in the embodiment described above, an example has been described in which the accommodation space 26 is open in the vertical direction of the connector, but the accommodation space of the present disclosure is not limited to this. For example, the fixed housings 20, 40 may have a bottom wall, and the lower side of the accommodation space may be closed by the bottom wall.

100 Movable connector 20, 40 Fixed housing 20 Resin part 20U Upper part 21, 22 Peripheral wall 21 Inter-row direction wall (peripheral wall)
22 Pitch direction wall (peripheral wall)
26 Accommodation space 30 Terminal 32 Fixed side held part 33 Movable part 34 Movable side held part 36 Contact part 40 Reinforcement fitting 40A First flat plate part 40A1 Pitch X direction outer surface (one surface)
40A2 Pitch X direction inner surface (other surface)
40B Second flat plate part (connection part)
40C Third flat plate part 40D Fourth flat plate part 41A First curved part (connecting part)
43 Exposed portion 43K Single-sided exposed portion 43R Double-sided exposed portion 46 Carrier cutting portion 50 Movable housing 55M Inclined portion (guiding surface)
55N Inclined section (guiding surface)
57 Pitch X direction regulation surface (regulation surface)
59 Inter-column Y direction regulation plane (regulation plane)
10 Mating connector (connected object)

Claims (4)

A connector set comprising a movable connector and a mating connector to which the movable connector is connected,
The movable connector is
a fixed housing fixed to the object to be mounted;
a movable housing configured to be movable relative to the fixed housing;
comprising a terminal and
The terminal is
a fixed side held part held by the fixed housing;
a movable side held part held by the movable housing;
a movable part located between the fixed side held part and the movable side held part,
The holding of the fixed side held part is performed by integrally molding the fixed housing and the terminal,
The removal force when removing the mating connector from the movable connector is smaller than the maximum elastic force in the elastic range of the movable part,
The movable connector does not include a means for defining a movable range in the removal direction of the movable housing by coming into contact with the movable housing,
The mating connector is
a mating housing fixed to a mating object to which the mating connector is attached;
a mating terminal having a mating contact portion that contacts the terminal of the movable connector,
The mating contact portion is configured to be immovable relative to the mating housing in the connection direction of the connector set.
connector set . a fixed housing fixed to the object to be mounted;
a movable housing configured to be movable relative to the fixed housing;
A movable connector comprising a terminal,
The terminal is
a fixed side held part held by the fixed housing;
a movable side held part held by the movable housing;
a movable part located between the fixed side held part and the movable side held part,
The holding of the fixed side held part is performed by integrally molding the fixed housing and the terminal,
The removal force when removing the connection object is smaller than the maximum elastic force in the elastic range of the movable part,
The movable connector does not include a means for defining a movable range in the removal direction of the movable housing by coming into contact with the movable housing,
The holding of the movable side held part is performed by press fitting the movable side held part into the movable housing.
Movable connector. a fixed housing fixed to the object to be mounted;
a movable housing configured to be movable relative to the fixed housing;
A movable connector comprising a terminal,
The terminal is
a fixed side held part held by the fixed housing;
a movable side held part held by the movable housing;
a movable part located between the fixed side held part and the movable side held part,
The holding of the fixed side held part is performed by integrally molding the fixed housing and the terminal,
The removal force when removing the connection object is smaller than the maximum elastic force in the elastic range of the movable part,
The movable connector does not include a means for defining a movable range in the removal direction of the movable housing by coming into contact with the movable housing,
The movable housing is
a defining surface that defines the movable range of the movable housing in the horizontal direction of the connector by coming into contact with the fixed housing;
a guide surface for inviting the connection object by being inclined with respect to the horizontal direction of the connector;
A portion of the guiding surface is located further outward in the horizontal direction of the connector than the defined surface;
Movable connector. The holding of the movable side held part is performed by press fitting the movable side held part into the movable housing.
The movable connector according to claim 3 .