JP2017191753A - Shield connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an L-shaped shield connector, suppressing the occurrence of a contact due to component connection in a conductive path.SOLUTION: A shield connector includes: a connector housing 21 in which one end side and the other end side thereof extend in a direction where both sides cross to each other and which is formed in a bent shape as a whole; and a shield shell 40 covering the connector housing 21. The shield shell 40 comprises a first halved body 41 and a second halved body 43 that form a pair of halved bent shapes in which both of the one end side and the other end side are integrally connected.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a shield connector.

  Conventionally, in an automobile (particularly, an electric car or a hybrid car), when connecting between electric devices, a shielded electric wire with noise countermeasures is routed, and a shield connector is provided at the end of the shielded electric wire. . The shield shell of the shield connector is brought into contact with the case of the device to connect the shield shell to the ground.

  As an example of the shield connector connected to the case of the device as described above, a connector disclosed in Japanese Patent Application Laid-Open No. 2015-125938 is known. This connector has a substantially L-shaped connector housing as a whole by having a structure in which an elliptical cylindrical terminal accommodating portion for accommodating terminals and a rectangular tubular electric wire accommodating portion for drawing out electric wires are continuous at right angles. ing. The connector is assembled with a first shield shell that covers the terminal housing portion of the connector housing and is fixed to the device, and a second shield shell that is connected to a shield member such as a braided wire on the wire harness side and covers the wire housing portion. It has been. The first shield shell and the second shield shell are electrically connected by being partially overlapped and bolted.

Japanese Patent Laying-Open No. 2015-125938

  However, the connector described in Japanese Patent Application Laid-Open No. 2015-125938 (Patent Document 1) is divided into two parts (a first shield shell and a second shield shell) on the terminal housing portion side and the wire housing portion side. An L-shaped shield shell is configured by connecting the two. For this reason, the connection portion of the first and second shield shells must be interposed in the conductive path from the braided wire on the wire harness side to the case of the electrical component, and connection resistance (inevitably generated in that portion) Contact resistance) may adversely affect the shielding performance.

  The shield connector disclosed in the present specification includes a connector housing that extends in a direction in which one end side and the other end side cross each other to form a bent shape as a whole, and a shield shell that covers the connector housing, The first and second halves form a pair of halved bent shapes in which the one end side and the other end side are integrally connected.

  According to such a configuration, the conductive path between the one end side to which a shield member such as a braided wire is generally connected and the other end side to be connected to the case of the electric device is the first half or It is composed of an integral part of the second half. For this reason, there is no generation of contact resistance due to component connection in the conductive path, and the resistance is lower than that of the conventional structure, and the shielding performance can be improved.

As an embodiment of the shield connector disclosed in the present specification, the following configuration may be adopted.
The connector housing is composed of one end side housing that extends to the one end side, and another end side housing that is a separate body and extends to the other end side,
The housing on the one end side and the other end side may include a first end side terminal and a second end side terminal connected to each other via a flexible portion.

  In such a configuration, the one end side housing and the other end side housing of the connector housing are separated, and an integrated side terminal provided on the one end side housing and an other end side terminal provided on the other end side housing are possible. By being connected via the flexure, the one end side housing and the other end side housing are relatively movable. Therefore, when the shield shell is mounted, the tolerance with the shield shell can be absorbed by the relative movement of the one end side housing and the other end side housing of the connector housing.

  Each of the halves of the shield shell includes one end side shell portion that covers the one end side housing of the connector housing, the other end side shell portion that covers the other end side housing of the connector housing, and the one end It is good also as a structure provided with the connection part which enables relative movement of the said one end side shell part and the said other end side shell part, connecting the side shell part and the said other end side shell part integrally.

  In such a configuration, each half of the shield shell is provided with one end side shell portion, the other end side shell portion, and a connecting portion that integrally connects them, and the one end side shell portion and the other end side shell. The part is relatively movable. Therefore, the tolerance between the connector housing and the shield shell can be absorbed even on the shield shell side.

  It is good also as a structure provided with the synthetic resin cover part which covers the said shield shell, fixing to the said connector housing.

  In such a configuration, the shield shell made of the first half and the second half is fixed to the connector housing while the cover covers the first half and the second half. It is possible to suppress relative movement from the connector housing.

  The first half is provided with a locking portion, and the second half is engaged with the locking portion, and the first half and the second half It is good also as a structure in which the to-be-latched part hold | maintained in the state which covered the connector housing is provided.

  In such a configuration, when the cover part is secondarily molded with the shield shell mounted around the connector housing, the first half and the second half of the shield shell cannot be detached from the connector housing. Since it can be made into a state, the operation | work of secondary molding of a cover part becomes easy.

  According to the shield connector disclosed in the present specification, even if it is an L-shaped shield connector, it is possible to suppress the occurrence of a contact due to component connection in the conductive path.

The front view of the shield connector in Embodiment 1 Side view of shield connector Plan view of shield connector Bottom view of shield connector Front view with shield shell assembled Side view with shield shell assembled Rear view with shield shell assembled Plan view with shield shell assembled Bottom view with shield shell assembled Sectional drawing in the XX position in FIG. Front view of the shield shell before assembly Side view of the shield shell before assembly Rear view of the shield shell before assembly Plan view of the shield shell before assembly Bottom view before assembling the shield shell The front view in the state where the shield shell in Embodiment 2 was assembled. Side view with shield shell assembled Rear view with shield shell assembled Plan view with shield shell assembled Sectional drawing in the XX-XX position in FIG. Front view of the shield shell before assembly Side view of the shield shell before assembly Rear view of the shield shell before assembly Plan view of the shield shell before assembly Bottom view before assembling the shield shell

<Embodiment 1>
A first embodiment will be described with reference to FIGS.
The shield connector 10 of the present embodiment has one end connected to a case C of an electric device such as an in-vehicle electric air conditioner and the other end connected to a mating connector attached to the end of the shielded electric wire. In the following description, with respect to the front-rear direction, the left side (fitting direction with the mating connector) in FIG. 2 is the front and the right side is the rear. Moreover, about the up-down direction, let the upper side of FIG. 1 be an upper direction, and let the lower side (attachment direction to the case C of an electric equipment) be a downward direction. About the left-right direction, it is based on the left-right direction of FIG.

  As shown in FIG. 1, the shield connector 10 is made of a synthetic resin connector housing 20, terminals 30 accommodated in the connector housing 20, a shield shell 40 covering the connector housing 20, and a synthetic resin cover covering the shield shell 40. The cover part 80 is provided.

  As shown in FIG. 11, the connector housing 20 includes a female housing 21 (an example of “one end side housing”) that holds a female terminal 31 to be described later, and a device side housing 23 (to be described later) that holds a device side terminal 33 ( An example of a “other end side housing”. The female housing 21 has a prismatic shape extending in the front-rear direction, while the device-side housing 23 has a prismatic shape extending in the vertical direction. The female housing 21 and the device housing 23 extend in directions orthogonal to each other, so that the connector housing 20 as a whole is L-shaped (bent).

  As shown in FIGS. 11 and 14, the rear end position of the female side housing 21 is located slightly forward of the front end position of the equipment side housing 23, and the female side housing 21 and the equipment side housing 23 are Since the clearance is provided between the female housing 21 and the device housing 23, the relative movement in the front-rear direction is allowed. The lower end position of the female housing 21 is located slightly above the upper end position of the device side housing 23, and a clearance is provided between the female side housing 21 and the device side housing 23, so that the female side Relative vertical movement between the housing 21 and the device side housing 23 is allowed.

  Further, as shown in FIGS. 5 and 11, a protruding portion 25 that protrudes outward (front-rear direction) is provided on the front-rear surface of the device-side housing 23. The protruding portion 25 is provided on the side of the contact piece 73 of the shield shell 40 described later, and protrudes outward to substantially the same position as the contact piece 73. Moreover, the lower end part of the protrusion part 25 becomes the taper part 25A where the protrusion dimension to the outside decreases as it goes downward.

  The terminal 30 is formed by pressing a conductive metal plate. As shown in FIGS. 11 and 12, the terminal 30 is a female terminal 31 (one example of “one end side terminal”) whose one end is connected to the counterpart terminal, and the other end is a terminal in the electrical device. This is a device-side terminal 33 to be connected (an example of “the other end-side terminal”). The female terminal 31 is held by being insert-molded in the female housing 21. The female terminal 31 has a rectangular tube shape extending in the front-rear direction, and the mating terminal can be inserted. The device-side terminal 33 has a bus bar shape extending in the vertical direction, and is held by being insert-molded in the device-side housing 23. The tip 33A is bent in a substantially L shape from the state of projecting downward from the device-side housing 23 and extends in the front-rear direction.

  13 and 14, the axial direction (front-rear direction) of the female terminal 31 of the terminal 30 is orthogonal to the axial direction (vertical direction) of the device-side terminal 33, and the terminal 30 is female. A connecting portion 35 (an example of a “flexible portion”) that connects the terminal 31 and the device-side terminal 33 is provided. The connecting portion 35 is disposed at a position exposed from the connector housing 20, and has a flat plate-like wide portion 35 </ b> A protruding from the female terminal 31 to the rear of the female-side housing 21, narrower than the wide portion 35 </ b> A, and at a right angle. A bent portion 35B that is bent and a flat narrow portion 35C that has the same width as the bent portion 35B and is connected to the device-side terminal 33 are provided. Since the bent portion 35B is bent to be narrower than the wide portion 35A, the connecting portion 35 can be bent. Therefore, the female terminal 31 and the device-side terminal 33 can be moved relative to each other in the front-rear and up-down directions.

  As shown in FIGS. 5 and 11, the shield shell 40 is divided into two parts, and is configured by combining a pair of first and second halves 41 and 43 of a halved shape. Yes. 7 and 13, the shield shell 40 accommodates the connector housing 20 and the terminals 30, and the female shell portion 45 (“one end” covering the connecting portion 35 of the female housing 21 and the terminals 30. An example of the “side shell part”, an equipment side shell part 47 (an example of the “other end side shell part”) covering the equipment side housing 23, and the female side shell part 55 and the equipment side shell part 47 are integrally connected. And a connecting portion 49.

  The first half 41 and the second half 43 are each formed by pressing a conductive plate material. As shown in FIGS. 7 and 11, the first halved body 41 includes a first female-side shell portion 51 that constitutes the female-side shell portion 45 and a first device-side shell portion 53 that constitutes the device-side shell portion 47. And the 1st connection part 55 which comprises the connection part 49 is provided. Similarly, the second halved body 43 constitutes a second female side shell part 61 constituting the female side shell part 45, a second equipment side shell part 63 constituting the equipment side shell part 47, and a connecting part 49. And a second connecting portion 65. The halves 41 and 43 are arranged so that the female shell portions 51 and 61 and the device shell portions 53 and 63 are orthogonal to each other at the rear ends of the female shell portions 51 and 61. Thus, it is substantially L-shaped in side view.

  As shown in FIGS. 5 to 9, the female-side shell portion 45 has a bottomed rectangular tube shape with an open front. The female-side shell portion 45 covers a part of both side surfaces, the top surface, the rear surface, and the lower surface of the female-side housing 21. An opening 71 is provided on the lower side of the female-side shell 45, and the opening 71 occupies the rear half of the lower surface of the female-side shell 45, and communicates with the upper opening of the device-side shell 47. A part of the connecting portion 35 of the terminal 30 is exposed.

  As shown in FIG. 11, the female side shell portions 51 and 61 constituting the female side shell portion 45 are connected so that the top plate 51A, 61A and the side plates 51B, 61B are at right angles, respectively. The side plates 51B and 61B and the lower surface plates 51C and 61C are connected so as to be substantially perpendicular to each other, thereby forming a substantially U-shape when viewed from the front. Further, the rear plates 51D and 61D are provided by being bent at right angles from the rear ends of the side plates 51B and 61B and extending inward. And each female side shell part 51 and 61 becomes a substantially symmetrical shape on both sides of a centerline.

  As shown in FIGS. 5 to 9, the device-side shell portion 47 has a rectangular tube shape that opens in the vertical direction. The device-side shell portion 47 covers both side surfaces, the front surface, and the rear surface of the device-side housing 23. A contact piece 73 that is electrically connected by contacting the case C is provided at the front and rear lower ends of the device-side shell 47. The contact piece 73 is provided at a central position in the width direction, and is formed by folding a piece extending from the lower end of the device-side shell portion 47 upward in a mountain shape. The contact piece 73 can be bent and deformed in the front-rear direction, and a flexure prevention piece 75 is provided inside the apex portion 73 </ b> A of the contact piece 73. Further, on the side of the contact piece 73, a notch 77 through which the protrusion 25 can be inserted is provided.

  And as shown in FIG.11 and FIG.15, each apparatus side shell part 53 and 63 which comprises the apparatus side shell part 47 makes each front plate 53A, 63A and side plate 53B, 63B become a right angle. The side plates 53B and 63B and the bottom plates 53C and 63C are connected so as to be substantially perpendicular to each other, thereby forming a substantially U shape as viewed from the bottom. Further, a contact piece 73 is provided on the front plate 53A of the first device-side shell portion 53, and is wider than the rear plate 53C by the width of the contact piece 73. On the other hand, a contact piece 73 is provided on the rear plate 63C of the second device-side shell 63, and is wider than the front plate 53A by the width of the contact piece 73. The dimension obtained by adding the width dimension of the front plate 53A of the first device side shell portion 53 and the width dimension of the front plate 63A of the second device side shell portion 63 is the width dimension of the rear plate 53C and the rear plate 63C. It is the same as the sum of width and dimensions. Further, a notch 77 is provided by notching from the side edge at the lower end portion of the rear plate 53C of the first device side shell portion 53, and the lower end of the front plate 63A of the second device side shell 63 portion. The part is provided with a notch 77 by notching from the side edge.

  As shown in FIGS. 11 and 12, the first connecting portion 55 integrally connects the side plate 51 </ b> B of the first female side shell portion 51 and the side plate 53 </ b> B of the first device side shell portion 53. At this time, since the first device-side shell portion 53 has entered the inner side in the width direction than the first female-side shell portion 51, the first connecting portion 55 is connected to the side plate 51B of the first female-side shell portion 51. A portion extending downward from the rear end portion is bent inward, and further bent downward to be connected to the upper end of the side plate 53B of the first device side shell portion 53. Thus, the 1st connection part 55 is bent so that it may enter in the width direction inner side, and the 1st female side shell part 51 and the 1st apparatus side shell part 53 can move relatively in the width direction. . Similarly to the first connection portion 55, the second connection portion 65 is configured such that the second female side shell portion 61 and the second device side shell portion 63 are relatively movable in the width direction. The side plate 61B of 61 and the side plate 63B of the second device-side shell 63 are integrally connected.

  Further, in order to assemble the first half 41 and the second half 43, as shown in FIGS. 10 and 11, the first half 41 and the second half 43 are provided with caulking pieces 57. (An example of “locking portion”) and a caulking portion 67 (an example of “locked portion”) are provided. The caulking piece 57 is connected to the second female side shell part 61 side or the second equipment side shell from the side edges of the top face plate 51A and the rear face plate 51D of the first female side shell part 51 and the rear face plate 53C of the first equipment side shell part 53. It is formed by projecting to the part 63 side. Further, the caulking piece 57 is formed by protruding from the side edge of the front plate 63 </ b> A of the second device side shell portion 63 toward the first device side shell portion 53. The crimping portion 67 is provided at a position overlapping with each crimping piece 57, and two slits 67A penetrating in the thickness direction are provided along the side edge. Then, the caulking pieces 57 are inserted into the slits 67A, and the caulking pieces 57 and the slits 67A are caulked together to be engaged.

  As shown in FIGS. 1 and 5, the cover 80 includes a female cover 81 that covers the female shell 45, a device cover 83 that covers the device shell 47, a female cover 81, and the device A flange portion 85 is provided between the side cover portions 83 and comes into contact with a case C (see FIG. 2) of the device. The female side cover portion 81 covers the entire female side shell portion 45 and the connecting portion 49, and the resin enters from the opening portion 71 of the female side shell portion 45, so that the gap between the connecting portion 35 of the terminal 30 and the shield shell 40 is provided. The terminal 30 is fixed so that it cannot move.

  The device side cover portion 83 and the flange portion 85 cover the upper half of the device side shell portion 47. Specifically, the caulking piece 57 and the caulking part 67 provided on the device-side shell 47 are covered and the contact piece 73 is exposed to the outside. The flange 85 is insert-molded with a metal collar 85A through which a bolt for fixing the shield connector 10 to the case C is inserted.

Next, an example of the assembly procedure of the shield connector 10 will be described.
First, the terminal 30 is formed by pressing a conductive metal plate. One end is a female terminal 31 and the other end is a device side terminal 33. At the same time, the connecting portion 35 is bent at a right angle so that the axial direction of the female terminal 31 and the axial direction of the device-side terminal 33 are orthogonal to each other. The connecting portion 35 can be bent by bending a flat plate-shaped portion narrower than the female terminal 31. Therefore, the female terminal 31 and the device-side terminal 33 can be moved relative to each other in the front-rear direction and the up-down direction.

  Then, as shown in FIGS. 11 and 12, the connector housing 20 is formed by inserting the formed terminals 30. The connector housing 20 is formed so that a female side housing 21 that holds the female terminal 31 and a device side housing 23 that is separate from the female side housing 21 and that holds the device side terminal 33 extend in a direction orthogonal to each other. Has been. The female housing 21 and the device housing 23 are connected in an L shape via a connecting portion 35 of the terminal 30. Moreover, the female side housing 21 and the equipment side housing 23 are connected to each other by a flexible connecting portion 35 in a state where the female side housing 21 and the equipment side housing 23 have a clearance, so that the female side housing 21 and the equipment side housing 23 are moved in the front-rear and vertical directions. Relative movement is possible.

  Next, the shield shell 40 is assembled to the connector housing 20. The first half 41 and the second half 43 are assembled from the side of the connector housing 20. At this time, the female-side housing 21 and the device-side housing 23 are relatively movable in the front-rear and up-down directions, and the first half 41 and the second half 43 are also relative to each other in the width direction by the connecting portion 49. It is movable. Therefore, the female side housing 21 and the equipment side housing 23 and the female side shell part 45 and the equipment side shell part 47 are moved relative to each other to accommodate the female side housing 21 in a predetermined position of the female side shell part 45. Can be accommodated in a predetermined position of the device-side shell portion 47. Then, the first half 41 and the second half 43 can be held in a state in which they are not detached from the connector housing 20 by inserting and crimping each crimping piece 57 into the slit 67 </ b> A of the crimping portion 67.

  And the cover part 80 is shape | molded by a secondary mold. The connector housing 20 in a state where the shield shell 40 is assembled is disposed in the mold, and the cover portion 80 is formed. At this time, since the shield shell 40 cannot be removed from the connector housing 20, it is only necessary to fix either the connector housing 20 or the shield shell 40 in the mold. The next molding operation becomes easy. Further, when the cover portion 80 is formed, the resin enters from the opening 71 of the female shell portion 45, so that the gap between the connecting portion 35 of the terminal 30 and the shield shell 40 is filled and the terminal 30 moves. Fix it so that it cannot. Then, since the shield shell 40 is covered by the cover portion 80, the shield shell 40, the connector housing 20, and the cover portion 80 are fixed together, so that the shield shell 40 moves relatively from the connector housing 20. It is suppressed.

  The shield connector 10 is fixed to the case C of the electric device, and the shield shell 40 is grounded by contacting the case C so that the contact piece 73 is crushed. Moreover, since the contact piece 73 is provided in each of the halves 41 and 43, each of the halves 41 and 43 has a conductive path to the case C. Specifically, each female-side shell 51, 61 connected to the mating connector reaches each device-side shell 53, 63 via each connecting portion 55, 65, and each device-side shell 53, 63 is connected to each device-side shell 53, 63. When the provided contact piece 73 is in contact with the case C, a ground connection is made.

  As described above, in the present embodiment, between the female-side shell portion 45 to which a shield member such as a braided wire is connected, and the device-side shell portion 47 connected to the case C of the electric device. The conductive path is constituted by an integrated body of the first half 41 or the second half 43. For this reason, there is no generation of contact resistance due to component connection in the conductive path, and the resistance is lower than that of the conventional structure, and the shielding performance can be improved.

  Further, since the shield shell 40 is divided into an L shape (bent shape), it is conceivable that a tolerance is generated between the shield shell 40 and the connector housing 20 so that the shield shell 40 cannot be assembled. Therefore, in the present embodiment, the female housing 21 and the equipment housing 23 are separated from each other in the connector housing 20, and the female terminal 31 provided in the female housing 21 and the equipment side provided in the equipment housing 23 are provided. By connecting the terminal 33 via the connecting portion 35, the female side housing 21 and the device side housing 23 are relatively movable. The halves 41 and 43 of the shield shell 40 are provided with female shell portions 51 and 61, device shell portions 53 and 63, and connecting portions 55 and 65 that integrally connect them. The female-side shell portion 45 and the device-side shell portion 47 are relatively movable. Therefore, since the tolerance between the connector housing 20 and the shield shell 40 can be absorbed, the shield shell 40 can be assembled to the connector housing 20.

  Then, after the assembly, the shield shell 40 and the connector housing 20 are fixed by being covered with the cover 80. Therefore, it is possible to prevent the female housing 21 and the device housing 23 from moving relatively, and the halves 41 and 43 of the shield shell 40 from moving relatively from the connector housing 20. .

<Embodiment 2>
Next, the second embodiment will be described with reference to FIGS.
In the shield connector 110 of the second embodiment, the method for assembling the first half 141 and the second half 143 is different from that of the first embodiment. In addition, about the member and site | part which have the same function as Embodiment 1, description is abbreviate | omitted or simplified by attaching | subjecting the same code | symbol. The vertical and horizontal directions are the same as those in the first embodiment.

  The shield connector 110 includes a synthetic resin connector housing 20, a terminal 30 accommodated in the connector housing 20, a shield shell 140 that covers the connector housing 20, and a synthetic resin cover portion 80 that covers the shield shell 140. ing.

  As shown in FIGS. 6 and 21, the shield shell 40 is divided into two parts, and is configured by combining the first half 141 and the second half 143. The shield shell 140 includes a female shell portion 145, a device shell portion 147, and a connecting portion 49.

  The first half 141 and the second half 143 are each formed by pressing a conductive plate material. As shown in FIGS. 18 and 21, the first half 141 includes a first female-side shell portion 151 constituting the female-side shell portion 45 and a first device-side shell portion 153 constituting the device-side shell portion 47. And the 1st connection part 55 which comprises the connection part 49 is provided. Similarly, the second halved body 143 constitutes a second female side shell part 161 constituting the female side shell part 145, a second equipment side shell part 163 constituting the equipment side shell part 147, and a connecting part 49. And a second connecting portion 65.

  Further, in order to assemble the first half body 141 and the second half body 143, as shown in FIGS. 20 and 21, the first half body 141 and the second half body 143 have fitting portions 159. (An example of “locking portion”) and a fitting portion 169 (an example of “locked portion”) are provided. The fitting portion 159 is provided at the side edge of the front plate 163A of the top plate 151A, the rear plate 151D of the first female shell portion 151, the rear plate 153C of the first appliance shell portion 153, and the front plate 163A of the second appliance shell portion 163. It has been. The side of the fitting portion 159 slightly protrudes inward, and the central portion of the fitting portion 159 further protrudes inward to form a piece-like fitting piece 159A. On the other hand, the fitted portion 169 is provided at a position overlapping with each fitted portion 159, and has a through hole 169 </ b> A that penetrates in the plate thickness direction and the fitted piece 159 </ b> A is fitted, and a hold that is bent so as to hold down the fitted portion 159. And a piece 169B. And the fitting part 159 and the to-be-fitted part 169 are engaged by inserting the fitting part 159 under each pressing piece 169B, and the fitting piece 159A entering into the through-hole 169A.

Next, an example of a method for assembling the shield shell 140 in the procedure for assembling the shield connector 110 will be described. The other procedures are the same as those in the first embodiment, and will be omitted.
The shield shell 140 is assembled to the connector housing 20. The first half 141 and the second half 143 are assembled from the side of the connector housing 20. The fitting portion 159 is inserted under each pressing piece 169B and the fitting piece 159A enters the through hole 169A, so that the first half 141 and the second half 143 are not detached from the connector housing 20. Can hold.

  As described above, in the present embodiment, when the shield shell 140 is assembled in advance, it is possible to prevent the shield shell 140 from being detached from the connector housing 20 by simply fitting together without being crimped. Therefore, the process can be simplified. Further, since the shield shell 140 and the connector housing 20 are further fixed by the cover 80 after the shield shell 140 is assembled, the shield shell 140 can be sufficiently fixed even by a simple method such as fitting. .

<Other embodiments>
The technology disclosed in this specification is not limited to the embodiment described with reference to the above description and drawings, and for example, the following embodiments are also included in the technical scope.
(1) In the first and second embodiments, the caulking piece 57 and the caulking portion 67 or the fitting portion 159 and the fitted portion 169 are provided, but the first halves 41 and 141 and the second half are divided by other methods. The bodies 43 and 143 may be locked. Further, such a locking means may not be provided.

  (2) In the first and second embodiments, the cover 80 is provided by the secondary mold. However, the cover 80 is provided by other methods such as press fitting the shield shells 40 and 140 assembled to the connector housing 20 into the synthetic resin parts. May be. Moreover, it is not necessary to provide a cover part.

  (3) Although the connecting portion 49 is provided in the first and second embodiments, the connecting portion may not be provided.

  (4) In the first and second embodiments, the female housing 21 and the device housing 23 are separated from each other in the connector housing 20, but they may be integrated.

  (5) In the first and second embodiments, the female side housing 21 and the device side housing 23 extend in a direction perpendicular to each other. However, the female side housing 21 and the device side housing 23 may extend in a crossing direction to be bent as a whole. .

  (6) In the first and second embodiments, the female terminal 31 and the device-side terminal 35 are connected by the connecting portion 35, but may be connected by another member such as a braided wire.

DESCRIPTION OF SYMBOLS 10, 110 ... Shield connector 20 ... Connector housing 21 ... Female side housing (one end side housing)
23. Equipment side housing (other end side housing)
30 ... Terminal 31 ... Female terminal (terminal on one end)
33 ... Equipment side terminal (other end side terminal)
33A ... tip 35 ... linking part (flexible part)
40, 140 ... shield shells 41, 141 ... first half 43, 143 ... second half 45, 145 ... female shell (one end shell)
47, 147 ... device side shell part (other end side shell part)
49 ... connecting part 51, 151 ... first female side shell part 53, 153 ... first equipment side shell part 55 ... first connecting part 57 ... caulking piece (locking part)
159 ... Fitting part (locking part)
159A ... fitting pieces 61, 161 ... second female side shell parts 63, 163 ... second device side shell part 65 ... second connecting part 67 ... caulking part (locked part)
169 ... Fitted portion (locked portion)
71 ... opening 73 ... contact piece 80 ... cover C ... case

Claims (5)

A connector housing that extends in a direction in which one end side and the other end side intersect with each other to form a bent shape as a whole;
A shield shell covering the connector housing;
The shield shell is a shield connector comprising a first half body and a second half body that form a pair of halved bent shapes in which the one end side and the other end side are integrally connected. The connector housing is composed of one end side housing that extends to the one end side, and another end side housing that is a separate body and extends to the other end side,
The shield connector according to claim 1, wherein the housing on the one end side and the other end side include a first end side terminal and a second end side terminal connected to each other via a flexible portion.   In each half of the shield shell, one end side shell portion covering the one end side housing of the connector housing, the other end side shell portion covering the other end side housing of the connector housing, and the one end side shell The shield connector according to claim 2, wherein a connecting portion is provided in which the one end side shell portion and the other end side shell portion are relatively movable while integrally connecting the portion and the other end side shell portion. .   The shield connector as described in any one of Claims 1-3 provided with the synthetic resin cover part which covers the said shield shell, fixing to the said connector housing.   The first half is provided with a locking portion, and the second half is engaged with the locking portion, and the first half and the second half The shield connector according to claim 4, further comprising a locked portion that holds the connector housing in a covered state.

Images