JP6785184B2 - Floating connector - Google Patents

Description

The present invention relates to a floating connector used for electrical connection.

Conventionally, as this kind of floating connector, it straddles both a fixed side housing fixed on a board, a movable side housing having a fitting portion that can be fitted with a mating connector, and both the fixed side housing and the movable side housing. The movable housing can move relative to the fixed housing by utilizing the elastic deformation of the contact in order to absorb the deviation between the boards and the deviation of the fitting position with the mating connector. Is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2014-10964

In recent years, in a floating connector having such a configuration, measures for obtaining a shielding effect against electromagnetic waves generated from the connector or electromagnetic waves from the outside are required.

The present invention has been made in view of such a problem, and an object of the present invention is to provide a floating connector capable of exerting a shielding effect against electromagnetic waves.

In order to achieve the above object, the floating connector according to the present invention is movable in which a fitting portion (for example, a fitting recess 74 in the embodiment) for fitting with the mating connector (for example, the plug connector 10 in the embodiment) is formed. When the side housing, the fixed side housing that supports the movable side housing so as to be relatively movable, and the movable side housing and the fixed side housing are supported and fitted with the other party connector, the other side of the other party connector. A contact (eg, a receptacle contact 80 in the embodiment) that comes into contact with a contact (eg, a plug contact 30 in the embodiment) and a shield shell (eg, in the embodiment) that is attached across the movable housing and the fixed housing. A shield shell 91) is provided, and the contact is elastically deformed in a predetermined direction orthogonal to the fitting direction while being supported across the movable connector and the fixed housing, thereby forming the fixed housing. On the other hand, the movable side housing is a floating connector (for example, the receptacle connector 50 in the embodiment) configured to be relatively movable in the predetermined direction, and the shield shell is fixed to the movable side housing. A movable shell portion (for example, the movable portion 92 in the embodiment) that covers at least a part of the outer surface of the movable housing, and a movable portion 92 that is fixed to the fixed housing and covers at least a part of the outer surface of the fixed housing. It has a fixed-side shell portion (for example, a fixed portion 93 in the embodiment) and an elastic shell portion (for example, an elastic portion 94 in the embodiment) that connects the movable-side shell portion and the fixed-side shell portion. The elastic shell portion is characterized in that it is configured to be elastically deformable in the predetermined direction by following the relative movement of the movable side housing with respect to the fixed side housing in the predetermined direction.

In the floating connector having the above configuration, the elastic shell portion is orthogonal to the first elastic portion that elastically deforms in the first direction (for example, the arrow α direction in the embodiment) as the predetermined direction and the first direction as the predetermined direction. It is preferable to include a second elastic portion that elastically deforms in the second direction (for example, the direction of arrow β in the embodiment).

In the floating connector having the above configuration, when mating with the counterparty connector, after the shield shell contacts the counterparty shield shell of the counterparty connector (for example, the shield shell 41 in the embodiment), the contact with the counterparty contact. It is preferably configured to be in contact.

According to the floating connector according to the present invention, in order to absorb the deviation of the fitting positions of both connectors, when the movable side housing moves relative to the fixed side housing in a predetermined direction (first direction and second direction), Following this movement, the elastic shell portion of the shield shell is elastically deformed, and the movable side shell portion moves relative to the fixed side shell portion in predetermined directions (first direction and second direction), whereby the fixed side is fixed. Even if the relative positional relationship of the movable housing with respect to the housing changes, the shield shell can reliably cover the fixed housing and the movable housing, so that it is excellent against noise such as electromagnetic waves. It is possible to exert a shielding effect.

In the floating connector having the above configuration, when mating with the mating connector, the shield shell first contacts the mating shield shell of the mating connector, and then the contact contacts the mating contact (that is, staggered contact). Therefore, it is possible to prevent the intrusion of noise such as electromagnetic waves when the connector is connected.

It is sectional drawing of the connector device provided with the receptacle connector (floating connector) which concerns on one Embodiment of this invention. It is a perspective view of the plug connector of the said connector device. It is a bottom view of the plug connector. It is sectional drawing which follows the arrow IV-IV in FIG. It is an exploded perspective view of the said plug connector. It is a perspective view which shows the plug contact of the said plug connector. (A) is a perspective view of the plug shell of the plug connector viewed from above, and (B) is a perspective view of the plug shell of the plug connector viewed from below. It is a perspective view which shows the said receptacle connector. It is a top view which shows the said receptacle connector. It is sectional drawing which follows the arrow XX in FIG. It is an exploded perspective view of the above receptacle connector. It is a perspective view which shows the receptacle contact of the above-mentioned receptacle connector. (A) is a perspective view of the receptacle shell of the receptacle connector viewed from above, and (B) is a perspective view of the receptacle shell of the receptacle connector viewed from below. It is sectional drawing which shows the state in which the plug connector is aligned above the receptacle connector. It is sectional drawing which shows the state which the said plug shell and the said receptacle shell are in initial contact. It is sectional drawing which shows the state which the said plug contact and the said receptacle contact are in initial contact. It is sectional drawing which shows the state in which the plug shell and the receptacle shell are in sliding contact with each other, and the plug contact and the receptacle contact are in sliding contact with each other. It is sectional drawing which shows the state in which the plug connector and the receptacle connector are fitted.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a connector device 1 provided with a floating connector (receptacle connector 50) according to an embodiment of the present invention, and the overall configuration of the connector device 1 will be outlined with reference to this figure.

The connector device 1 is composed of a plug connector 10 provided on a first board (not shown) and a receptacle connector 50 provided on a second board (not shown), and both connectors 10 and 50 are provided. The first substrate and the second substrate can be electrically connected by fitting in a direction orthogonal to the surface of each substrate. That is, the connector device 1 according to the present embodiment is configured as a stack connection type board-to-board connector. In the following description, for convenience, the front-back, left-right, and up-down directions are defined with reference to the states shown in FIGS. 1, 2, and 8, respectively, as the directions of the arrows shown in FIGS. 1, 2, and 8. The fitting direction of the connectors 10 and 50 will be referred to as a vertical direction, the longitudinal direction (width direction) of each of the connectors 10 and 50 will be referred to as a front-rear direction, and the directions orthogonal to these vertical and front-rear directions will be referred to as a left-right direction.

First, the configuration of the plug connector (counterpart connector) 10 will be described with reference to FIGS. 2 to 7. The plug connector 10 includes a plug housing 20 fixed on a first substrate, a plurality of plug contacts 30 held in a two-row aligned state along the left-right direction (longitudinal direction) of the plug housing 20, and a plug housing. It is configured to include a shield shell 40 that covers the periphery of 20.

The plug housing 20 is molded using an electrically insulating material such as synthetic resin, and has a horizontally long rectangular parallelepiped housing body 21 and a pair of attachments provided at the front and rear ends of the housing body 21. It is configured to include a part 29.

The housing main body 21 has a base portion 22 formed in a U-shaped cross section and extending in the front-rear direction, side walls 23 provided at the left and right ends of the base portion 22, and end walls 24 provided at the front and rear ends of the base portion 22. As a whole, it is formed in the shape of a substantially rectangular box with an open bottom surface. The housing body 21 is provided with a receiving space 25 having a rectangular cross section (a space in which the protrusion 75 of the receptacle connector 50 is received) that is open downward. The upper half of the housing body 21 is configured as a fitting convex portion 26 having an outer shape that can be fitted with the receptacle connector 50 while being surrounded by the plug shell 40. Further, the side wall 23 of the housing body 21 is recessed with an engaging groove 23a into which the invitation portion 46 formed at the lower edge end of the plug shell 40 can be engaged.

The base portion 22 of the housing body 21 connects a plurality of partition plate portions 22a formed in two rows in the left-right direction and at a predetermined arrangement pitch in the front-rear direction and the left and right partition plate portions 22a formed extending in the front-rear direction. It has a connecting portion 22b to be formed. Further, in the base portion 22, contact accommodating spaces 27 for holding the plug contacts 30 in a predetermined arrangement posture are arranged in two rows on the left and right and side by side at a predetermined arrangement pitch. Each contact accommodating space 27 is defined between the front and rear partition plate plates 22a, and communicates with the receiving space 25 below the contact accommodating space 27. The contact accommodating space 27 is provided with a contact holding groove 27a for press-fitting and holding the plug contact 30.

The mounting portion 29 is formed with a cylindrical positioning protrusion 29a for positioning the plug connector 10 on the first substrate. Further, the mounting portion 29 is formed with a shell holding groove 29b for press-fitting and holding the upper leg portion 43 of the shield shell 40.

The plug contact 30 is formed in a predetermined shape shown in FIG. 6 or the like by pressing (punching and bending) a thin flat plate of a conductive material such as metal. The surface of the plug contact 30 is subjected to a necessary surface treatment (plating treatment) for coating a thin film such as gold (Au).

The plug contact 30 is formed from a press-fitting portion 31 that is press-fitted and held in the contact holding groove 27a of the plug housing 20, a contact portion 32 that is connected to the lower end of the press-fitting portion 31 and elastically displaced in the substantially plate thickness direction, and the upper end of the press-fitting portion 31. It is configured to have a lead portion 33 that bends in an L shape and extends outward. The press-fitting portion 31 is formed with press-fitting protrusions 31a that project outward at both ends in the plate width direction and bite into the inner surface of the contact holding groove 27a so that the press-fitting portion 31 is press-fitted and held in the contact holding groove 27a in a retaining state. It has become. The contact portion 32 is bent and formed in a substantially U shape so as to be convex toward the receiving space 65 side, and the arc-shaped contact curved portion 32a most protruding toward the receiving space 65 side comes into contact with the counterpart receptacle contact 80. It is configured as a part. The lead portion 33 is soldered to a wiring pattern formed on the first substrate and is electrically connected.

The plug shell 40 is composed of a pair of shield shells 41 arranged symmetrically on the left and right, and by combining the left and right shield shells 41 in a tubular shape, the outer peripheral portion of the housing body 21 (the contact portion 32 of the plug contact 30). It covers the surrounding area). Each shield shell 41 is formed into a predetermined shape shown in FIG. 7 or the like by pressing (punching and bending) a thin flat plate of a metal material such as a copper alloy. Each shield shell 41 has a shape along the outer surface of the housing body 21.

The shield shell 41 includes a shell body 42 that covers the left and right side walls 23 of the housing body 21, and an upper arm portion that is bent substantially vertically from the front and rear ends of the shell body 42 and covers the upper portion of the end wall 24 of the housing body 21. 43, a lower arm 44 that is bent substantially vertically from the front and rear ends of the shell body 42 to cover the lower portion of the end wall 24 of the housing body 21, and a gland that protrudes from the upper end of the upper arm 44. It is configured to have a terminal portion 45. At the lower edge of the shell body 42, a plurality of invitation portions 46 are formed that are inclined inward to the left and right toward the tip (lower end). The upper arm portion 43 is press-fitted and held in the shell holding groove 29b formed in the mounting portion 29 of the plug housing 20. Here, the upper arm portion 43 is formed with press-fitting projections 43a protruding outward at both ends in the plate width direction, and is press-fitted and held in the shell holding groove 29b of the plug housing 20 in a retaining state. It has become. The ground terminal portion 45 is soldered and connected to a ground pattern formed on the first substrate. As shown in FIG. 2 and the like, of the pair of shield shells 41, the lower arm portion 44 of the shield shell 41 arranged on the left side is exposed to the outside, while the shield shell 41 arranged on the right side is exposed. The lower arm portion 44 is included in the housing main body 21, but this is a difference due to the fact that the plug housing 20 is manufactured by using an existing mold, and there is no particular functional difference.

Subsequently, the configuration of the receptacle connector 50 will be described with reference to FIGS. 8 to 13. The receptacle connector 50 includes a fixed side housing 60 fixed on a second substrate, a movable side housing 70 attached so as to be relatively movable with respect to the fixed side housing 60, and each housing straddling both housings 60 and 70. A plurality of receptacle contacts 80 held in an aligned state in two rows along the left-right direction (longitudinal direction) of 60 and 70, and a receptacle that is attached across both housings 60 and 70 and covers the periphery of both housings 60 and 70. It is configured with a shell 90.

The fixed side housing 60 is formed by using an electrically insulating material such as synthetic resin, and is formed on a substantially rectangular plate-shaped base wall 61 that faces the second substrate vertically and at the left and right ends of the base wall 61. It is formed by having the left and right walls 62 provided and the front and rear walls 63 provided at the front and rear ends of the base wall 61. A cylindrical positioning protrusion 61a for positioning the fixed-side housing 60 on the second substrate is projected from the base wall 61. A plurality of contact holding grooves 62a penetrating in the vertical direction are arranged side by side on the left and right walls 62 in the front-rear direction at a predetermined arrangement pitch. A shell holding groove 63a for press-fitting and holding the fixing portion 93 side of the receptacle shell 90 is recessed upward in the front and rear walls 63.

The movable housing 70 is formed by using an electrically insulating material such as synthetic resin, and is formed on a main body wall 71 that faces the base wall 61 of the fixed side housing 60 and at the left and right ends of the main body wall 71. It has a protective wall 72 that is provided and bends in an inverted U shape, and a vertical wall 73 that is provided at the front and rear ends of the main body wall 71, and is surrounded by these wall surfaces and is open upward. The joint recess 74 (the space for receiving the fitting convex portion 26 of the plug connector 10) is defined. In the fitting recess 74, a convex protrusion 75 protruding upward from the main body wall 71 is formed. On the left and right side surfaces of the protrusions 75, a plurality of contact holding grooves 75a formed in a concave cross section and extending in the vertical direction are arranged side by side at a predetermined arrangement pitch in the front-rear direction. Further, a plurality of contact holding holes 71a penetrating in the vertical direction are arranged side by side in the main body wall 71 at a predetermined arrangement pitch in the front-rear direction, and these contact holding holes 71a and the contact holding groove 75a are aligned in the vertical direction. Therefore, they are in a positional relationship that communicates with each other. Further, the inverted U-shaped protective wall 72 is surrounded between the outer wall portion 72a and the inner side wall portion 72b, and is flexible for accommodating the elastically deformable portion (flexible portion 83 described later) of the receptacle contact 80. A part accommodating space 76 is formed. Further, the movable side housing 70 has a stepped portion 77 for fixing the movable portion 92 side of the receptacle shell 90 on the opposite long side side of the housing 70, straddling the inner surface of the fitting recess 74 from the upper surface thereof. Is formed.

The receptacle contact 80 is formed by pressing (punching and bending) a thin flat plate of a conductive material such as metal to form a predetermined shape shown in FIG. 12 and the like. The receptacle contact 80 includes a holding portion 81 that is press-fitted into the contact holding groove 62a of the fixed-side housing 60, a lead portion 82 that is bent substantially vertically from the lower end of the holding portion 81 and extends outward, and a holding portion 81. A flexible portion 83 connected to the upper end of the flexible portion 83 and bent in an inverted U shape to be received by the flexible portion accommodating space 77, and an intermediate portion connected to the lower end of the flexible portion 83 and extending in the left-right direction along the back surface of the main body wall 71. It is composed of a portion 84 and a contact portion 85 which is connected to the inner end of the intermediate portion 84 and extends substantially vertically upward to be press-fitted into the contact holding hole 71a and the contact holding groove 75a. The holding portion 81 is formed with press-fitting protrusions 81a that project outward at both ends in the plate width direction and bite into the inner surface of the contact holding groove 62a so that the holding portion 81 is press-fitted and held in the contact holding groove 62a in a retaining state. It has become. Similarly, the contact portion 85 is formed with press-fitting projections 85a that project outward at both ends in the plate width direction and bite into the inner surface of the contact holding hole 71a, and are press-fitted and held in the contact holding hole 71a in a retaining state. It has become so. The surface of the receptacle contact 80 is subjected to a necessary surface treatment (plating treatment) for coating a thin film such as gold (Au).

In the receptacle contact 80, the holding portion 81 on one end side is press-fitted into the contact holding groove 62a and fixed to the fixed side housing 60, while the contact portion 85 on the other end side is press-fitted into the contact holding hole 71a and the contact holding groove 75a. It is fixed to the movable housing 70. As a result, the movable housing 70 is connected to the fixed housing 60 so as to be relatively movable back and forth and left and right via the plurality of receptacle contacts 80. The lead portion 82 is soldered to a wiring pattern formed on the second substrate to be electrically connected.

The receptacle shell 90 is composed of a pair of shield shells 91 arranged symmetrically on the left and right, and by combining the left and right shield shells 91 in an annular shape, the outer peripheral portions of both housings 60 and 70 (contact portions of the receptacle contacts 80). It covers around 85). Each shield shell 91 is formed into a predetermined shape shown in FIG. 13 or the like by pressing (punching and bending) a thin flat plate of a metal material such as a copper alloy. Each shield shell 91 has a shape along the outer surfaces of the fixed side housing 60 and the movable side housing 70.

The shield shell 91 includes a movable portion 92 fixed to the protective wall 72 of the movable housing 70, a pair of front and rear fixed portions 93 fixed to the front and rear walls 63 of the fixed side housing 60, and a movable portion 92 and a fixed portion 93. Is provided with an elastic portion 94 for connecting the housing so as to be relatively movable in a substantially horizontal direction.

The movable portion 92 is formed by bending the upper half portion in an inverted U shape and extending the lower half portion in a substantially vertical direction, and mainly covers the outer surface of the protective wall 72 of the movable housing 70. A plurality of engaging claw portions 92a projecting downward are formed in the upper half portion of the movable portion 92. When the engaging claw portion 92a engages with the stepped portion 77 of the movable side housing 70, the movable portion 92 is fixed to the movable side housing 70 and covers the protective wall 72. Further, in the upper half portion of the movable portion 92, a plurality of contact piece portions 92b projecting into the fitting recess 74 of the movable side housing 70 are formed. The contact piece portion 92b can be elastically deformed in the substantially thickness direction (left-right direction), and elastically contacts the plug shell 40 of the other party.

The fixed portion 93 has an inner leg portion 93a extending downward and an outer leg portion 93b branching out from the inner leg portion 93a, and is formed in a substantially bifurcated shape that opens downward as a whole. The inner leg portion 93a and the outer leg portion 93b are arranged on the front / rear wall 63 side of the fixed side housing 60 and mainly cover the outer surface of the front / rear wall 63. The inner leg portion 93a and the outer leg portion 93b are formed with press-fitting projections 93d that project outward at both ends in the plate width direction and bite into the inner surface of the shell holding groove 63a, and the shell holding formed on the front and rear walls 63. It is press-fitted and held in the groove 63a in a retaining state. A ground terminal portion 93c is formed at the lower end of the outer leg portion 93b. The ground terminal portion 93c is soldered and connected to a ground pattern formed on the second substrate.

The elastic portion 94 includes a first elastic portion 94a that is connected to the upper end of the fixed portion 93 and extends in the left-right direction, and a second elastic portion 94b that bends substantially vertically from the left and right outer ends of the first elastic portion 94a and extends in the front-rear direction. have. The first elastic portion 94a is arranged on the standing wall 73 side of the movable housing 70 and mainly covers the standing wall 73. The first elastic portion 94a is formed so as to be elastically deformable in the substantially plate thickness direction (front-back direction: arrow α direction in FIG. 9) with the joint portion with the fixed portion 93 as a fulcrum. The second elastic portion 94b is formed so as to be elastically deformable in the substantially plate thickness direction (left-right direction: arrow β direction in FIG. 9) with the joint portion with the first elastic portion 94a as a fulcrum. Therefore, the movable portion 92 can move relative to the fixed portion 93 in the front-rear direction and the left-right direction in accordance with the elastic deformation of the first elastic portion 94a and the second elastic portion 94b in the front-rear direction and the left-right direction.

In the receptacle shell 90 having such a configuration, when the movable housing 70 moves relative to the fixed housing 60 in the front-rear direction and the left-right direction, the elastic portion 92 elastically deforms following this movement, and the movable portion 92 It can move relative to the fixed portion 93 in the front-rear direction and the left-right direction. Therefore, even if the relative positional relationship of the movable housing 70 with respect to the fixed housing 60 changes, the posture of the receptacle shell 90 also changes accordingly, so that the receptacle shell 90 has the fixed housing 60 and the movable housing 70. It is possible to reliably cover these surroundings across and. Even when the movable housing 70 moves relative to the fixed housing 60, the plug shell 40 and the receptacle shell 9
The connection position with 0 (the contact position between the shell body 42 and the contact piece portion 92b) does not change, and a stable ground connection is provided for a long period of time.

Next, in order to facilitate understanding of the present embodiment, the operation of the connector device 1 will be described with reference to FIGS. 14 to 18. The process of connecting the plug connector 10 and the receptacle connector 50 will be described below.

First, as shown in FIG. 14, in order to connect both the connectors 10 and 50, the plug connector 10 and the receptacle connector 50 are vertically aligned. That is, the fitting convex portion 26 of the plug connector 10 and the fitting concave portion 74 of the receptacle connector 50 are vertically aligned.

Subsequently, as shown in FIG. 15, when the fitting protrusion 26 of the plug connector 10 is fitted into the fitting recess 74 of the receptacle connector 50, the protrusion 75 of the receptacle connector 50 becomes a receiving space of the plug connector 50. It is inserted in 25. At the same time, the attracting portion 46 of the plug shell 40 comes into contact with the contact piece portion 92b of the receptacle shell 90, and the plug shell 40 and the receptacle shell 90 are grounded and grounded. At this time, the contact piece portion 92b of the receptacle shell 90 protrudes into the fitting recess 74, but the tip surface of the fitting convex portion 26 has a tapering portion 46 for attracting the contact piece portion 92b. Since it is formed, the plug shell 40 and the receptacle shell 90 can be smoothly initially contacted by the guiding action of the invitation portion 46. In the initial contact between the plug shell 40 and the receptacle shell 90, the plug contact 30 and the receptacle contact 80 are separated from each other. That is, since the signal lines of the contacts 30 and 80 are connected after the shells 40 and 90 are first ground-connected, it is possible to prevent the intrusion of electromagnetic waves when the connectors are connected.

Next, as shown in FIG. 16, when the fitting convex portion 26 of the plug contact 10 is further fitted into the fitting concave portion 74 of the receptacle contact 50, the contact portion 32 of the plug contact 30 becomes the contact portion of the receptacle contact 80. Initial contact with 85. At this time, the contact piece portion 92b of the receptacle shell 90 is elastically deformed by being pressed outward from the left and right by the shell body 42 of the plug shell 40, and elastically contacts the shell body 42 by the reaction force.

Subsequently, as shown in FIG. 17, when the fitting convex portion 26 of the plug connector 10 and the fitting concave portion 74 of the receptacle connector 50 are further fitted, the contact piece portion 92b of the receptacle shell 90 becomes the plug shell 40. While elastically sliding on the shell body 42 in a pressed state, the contact portion 32 of the plug contact 30 elastically slides on the contact portion 85 of the receptacle contact 80 in a pressed state.

Then, as shown in FIG. 18, when the fitting convex portion 26 of the plug connector 10 is completely fitted into the fitting recess 74 of the receptacle connector 50, the position between the two connectors 10 and 50 is determined, and the plug contact 30 and the plug contact 30 are formed. The contact state with the receptacle contact 80 is maintained, and the contact state between the plug shell 40 and the receptacle shell 90 is maintained. Here, when the plug contact 30 and the receptacle contact 80 are elastically contacted with an appropriate contact force, both the connectors 10 and 50 are electrically connected, and signal transmission between the two substrates becomes possible. Further, the plug shell 40 and the receptacle shell 90 surround the signal transmission circuit formed inside both the connectors 10 and 50, and the two shells 40 and 90 are elastically contacted and ground-connected to the connectors 10 and 50. It is possible to reliably block electromagnetic waves generated from within 50 or electromagnetic waves from the outside. Furthermore, around the signal transmission circuit formed inside both connectors 10 and 50, the shells 40 and 90 overlap each other almost as a whole (because a metal shell having a substantially double structure is formed). Both shells 40, 9
The electromagnetic wave blocking action by 0 is further improved.

As described above, according to the connector device 1 according to the present embodiment, the movable side housing 70 is relative to the fixed side housing 60 in the front-rear direction and the left-right direction in order to absorb the deviation of the fitting positions of the two connectors 10 and 50. When it moves, the elastic portion 94 of the receptacle shell 90 elastically deforms following this movement, and the movable portion 92 moves relative to the fixed portion 93 in the front-rear direction and the left-right direction, so that the movable portion 92 can move with respect to the fixed side housing 60. Even if the relative positional relationship of the side housing 70 changes, the receptacle shell 90 can reliably cover the fixed side housing 60 and the movable side housing 70, and thus is excellent against noise such as electromagnetic waves. It is possible to exert a shielding effect.

Further, according to the connector device 1 according to the present embodiment, the plug contact 30 and the receptacle contact 80 come into contact with each other (that is, staggered contact) after the plug shell 40 and the receptacle shell 90 first come into contact with each other. Therefore, it is possible to prevent the intrusion of noise such as electromagnetic waves when the connector is connected.

The present invention is not limited to the above embodiment, and can be appropriately improved as long as it does not deviate from the gist of the present invention.

In the above embodiment, a stack connection type connector device in which both boards (first board and second board) are arranged in parallel with each other and electrically connected has been described as an example, but the present invention is not limited to this configuration. It may be applied to a vertical connection type connector device in which both boards are arranged at right angles to each other and electrically connected, or a horizontally connected connector device in which both boards are arranged in the same plane and electrically connected.

In the above embodiment, the board-mounted connector has been described as an example of the mating connector, but the present invention is not limited to this configuration, and various connectors such as a cable-mounted connector can be applied.

1 Connector device 10 Plug connector (other party connector)
20 Plug housing 25 Receiving space 26 Fitting convex part 30 Plug contact (counterpart contact)
32 Contact part 40 Plug shell 41 Shield shell (other party's shield shell)
42 Shell body 50 Receptacle connector (floating connector)
60 Fixed side housing 70 Movable side housing 74 Fitting recess (fitting part)
75 Protrusion 80 Receptacle contact (contact)
85 Contact 90 Receptacle shell 91 Shield shell 92 Movable part (movable side shell part)
92a Engagement claw part 92b Contact piece part 93 Fixed part (fixed side shell part)
94 Elastic part (elastic shell part)
94a 1st elastic part 94b 2nd elastic part

Claims (3)

A movable housing with a fitting part that fits with the mating connector,
A fixed side housing that supports the movable side housing so as to be relatively movable, and a fixed side housing.
A contact that is supported across the movable housing and the fixed housing and comes into contact with the mating contact of the mating connector when mated with the mating connector.
A shield shell that is attached across the movable housing and the fixed housing is provided.
The movable side housing is elastically deformed in a predetermined direction orthogonal to the fitting direction in a state where the contact is supported across the movable side connector and the fixed side housing, so that the movable side housing is said to the fixed side housing. A floating connector that is configured to be able to move relative to a predetermined direction.
The shield shell is fixed to the movable housing and covers at least a part of the outer surface of the movable housing, and at least one of the outer surfaces of the fixed housing fixed to the fixed housing. It has a fixed-side shell portion that covers the portion, and an elastic shell portion that connects the movable-side shell portion and the fixed-side shell portion.
The elastic shell portion is a floating connector characterized in that it is configured to be elastically deformable in the predetermined direction by following the relative movement of the movable side housing with respect to the fixed side housing in the predetermined direction. The elastic shell portion includes a first elastic portion that elastically deforms in the first direction as the predetermined direction, and a second elastic portion that elastically deforms in the second direction orthogonal to the first direction as the predetermined direction. The floating connector according to claim 1, wherein the floating connector is provided. Claim 1 or 2 characterized in that, when mated with the counterparty connector, the contact is configured to come into contact with the counterparty contact after the shield shell has contacted the counterparty shield shell of the counterparty connector. Floating connector described in.

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