KR100417299B1 - Shielded Electrical Connectors - Google Patents

Abstract

The shielded electrical connector has a conductive inner shell (7) which, in combination with the insulating housing (4), a conductive outer shell (6) surrounding the housing (4), and an outer shell (6), provides an electrical shield (5). The housing 4 extends, and the second shell 7 extends inside each plug receiving cavity 3 to engage with the plug-type connector to be received by the plug receiving cavity 3.

Description

Shielded electrical connectors

FIELD OF THE INVENTION The present invention relates to shielded electrical connectors, and more particularly, to shielded electrical connectors with shielded shells surrounding the insulating housing.

US-A-5,161,999 and US-A-5,167,531 describe shielded connector assemblies comprising two electrical headers for connecting to pluggable electrical connectors. Each header is surrounded by two shells to form a shielding film. The header and two shells are installed in the conductive bracket. The bracket is equipped with a third shell to cover the rear of each header. This connector assembly is large in volume because it has a number of separate parts, including a mounting bracket, two headers, two shells surrounding each shell, and a third shell. It is therefore desirable to provide a miniaturized electrical connector in which an electrical connector comprising multiple plug receiving cavities, ie each plug receiving cavity is wrapped by a shield, and the connector consists of a reduced number of discrete components.

US-A-5,387,114 describes a shielded electrical connector comprising a conductive outer shell surrounding an insulating housing, and a conductive second shell coupled with the outer shell. Each cavity in the housing receives electrical contacts. A second shell extends along the slots of the housing, the slots next to the cavity without being inside the cavities, and portions of the housing separate the slot from the cavities. These housing portions prevent the second shell from engaging with the portions of the mating plug type connector that are inserted inside the cavity to mate with the contacts therein.

There is a need to provide an electrical connector of the smallest dimension possible by a shield that extends inside a multiple plug receiving cavity and engages with each plug to be engaged with electrical contacts within the cavity.

The present invention relates to a shielded electrical connector, in particular a small toothed electrical connector in a conductive shell that engages each plug that extends inside the multiple plug receiving cavity to engage with electrical contacts within the cavity. The present invention is made up of a smaller number of parts than the electrical connector of the prior art to simplify the assembly and reduce the manufacturing cost.

An advantage of the present invention lies in a shield that completely surrounds the plurality of plug receiving cavities, the shield comprising a second shell that engages the outer shell, and the second shell is small because it extends inside the plurality of plug receiving cavities. Form a structure.

According to an embodiment of the present invention, a shielded electrical connector includes an insulated housing, a conductive outer shell surrounding the housing, and a conductive second shell coupled with the outer shell to form an electrical shield, wherein the multiple plug receiving cavity of the housing includes: Electrical contacts are extended and the second shell extends outside each plug receiving cavity to engage with an electrical plug-type connector received in the plug receiving cavity.

Then, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view of an electrical connector with parts separated from each other.

2 and 3 are rear and front perspective views of the connector shown in FIG. 1.

FIG. 4 is a partial side view of the connector shown in FIG. 1 with two collection plug-type electrical connectors shown in dashed lines. FIG.

5 is a perspective view of an insulated housing that is part of the connector shown in FIG. 1;

6 is a perspective view of a second shell that is part of the connector shown in FIG. 1.

FIG. 7 is a perspective view of the rear portion of the housing shown in FIG. 5; FIG.

8 and 9 are perspective views of conductive electrical contacts that are part of the connector shown in FIG. 1.

FIG. 10 is a perspective view of the rear portion of the housing shown in FIG. 1, with the contacts shown in FIGS. 8 and 9.

11 is a perspective view of the front portion of the conductive outer shell that is part of the connector shown in FIG.

12 is a top view of a partial cross-section of the connector shown in FIG. 1 illustrating a second shell in the plug receiving cavity of the housing.

FIG. 13 is a top view of a partial cross section of the connector shown in FIG. 1 illustrating a single row contact in the plug receiving cavity of the housing. FIG.

1 to 4, the electrical connector 1 has two rows of electrical contacts 2 in each plug receiving cavity in the insulating housing 4, and a conductive outer shell 6 surrounding the housing 4. ) And a shield 5 comprising a conductive second shell 7 inside the outer shell 6 and outside the plug receiving cavity 3. For example, the connector 1 is shown as having two plug receiving cavities 3. As shown in phantom lines in FIG. 4, each electric plug connector 8 is inserted into each plug receiving cavity 3 to be assembled with the connector 1. Each plug connector 8 includes a conductive shell 9 protruding from the insulating overmold 10. Although not illustrated, each plug connector 8 is inserted into an insulated housing surrounded by a shell 9 and in each plug receiving cavity 3 of the connector 1 in the housing so that the contacts 2 of the connector 1 are present. Electrical collection contacts which are in electrical contact with these devices. The general structure of the electrical plug connector 8 for assembly is described in US-A-5,017,156 and US-A-5,267,882.

5, 7 and 10, the housing 4 is a unitary molded plastic structure. The partition 11 on the housing protrudes forward between the two plug receiving cavities 3 which both sides face each plug receiving cavities 3. The cavities 3 have a similar structure to each other, and the structure of one of the cavities 3 is developed with respect to the structure of the other cavity 3. The second partition 12 parallel to the partition 11 divides each plug receiving cavity 3 into two parts, each cavity being divided into a shell receiving cavity 13 and a contact receiving cavity 14. Lose.

With reference to FIGS. 8 and 9, the electrical contact 2 will be described. Each contact 2 is a single structure stamped and molded from a metal. The cantilever spring 15 forming the curved contact 16 extends forward from the elongated terminal 17 bent downward. The terminal 17 on the contact 2 shown in FIG. 8 is relatively long compared to the relatively short terminal 17 on the contact 2 shown in FIG. 9. The wide mounting portion 18 on the rear side of the spring 15 has a feathered edge. The wide mounting portion 19 on the terminal 17 has a fringed edge.

With reference to FIGS. 7 and 10, multiple contact receiving passages 20 are arranged in top and bottom rows, projecting forward from behind the housing. A wide slot 21 extends across the top of each passage 20. Short contacts 2 protrude through each passage 20 in the lower row of the upper row. The wide portions 18 on the contacts 2 are wedged in their respective slots 21 to limit the movement of the contacts 2.

Corresponding contact spacer plates 22 protrude from the remaining housing 4 underneath each row of passages 20. An elongate terminal receiving slot 23 communicates with the rear side of each contact spacer plate 22. Slots 23 formed in the upper plate 22 are aligned with the respective slots 23 of the lower plate 22. The terminal 17 of the contact 2 projects rearward from each passage 20 and downwards through the corresponding slot 23. The short terminal 17 of the contact 2 protrudes through the corresponding slot 23 of the lower plate 22 and the long terminal 17 protrudes through the slot 23 of both plates 22. Thus, each slot 23 of the lower plate 22 receives two terminals 17. The terminal 17 is thereby arranged in the device via a circuit board, not shown, aligned by the plate 22. The wide portion 19 on each terminal 17 is wedge coupled to the corresponding slot 23 of the lower plate 22 to limit the movement of the terminal 17.

4 and 13, curved contacts 15 on each electrical contact 3 extend along the passage 20. The passage 20 opens to each plug receiving cavity 3 to form a groove along each partition 12. The contact part 15 extends along this groove, and faces the contact receiving cavity part 14.

4, 6, 10 and 12, the conductive second shell 7 is a single structure stamped and molded from a metal sheet having a thickness plane. The second shell 7 has spaced plates 24, which are connected to respective webs 25 extending laterally of the plate 24 at curved corners 25. An open seam 27 separates each web 26 from the corresponding plate 24. The plate 24 is slidably fitted along the spaced slots 28 of FIGS. 4 and 7 of the housing 4. Slot 28 extends from rear to front in housing 4. As shown in FIG. 2, the second shell 7 is in front of the upper row terminal 17 on the contact 2. Thus, the second shell 7 is assembled to the housing 4 before the contact 2 is assembled to the housing 4. The cantilever latch finger 29 protrudes back on each plate 24 so as to collide with the thickness plane of the plate 24. The latch finger 29 flexes elastically when the plate 24 is inserted along the spaced slots 28 and outwards when they are introduced into each slot 28. The latch fingers 29 face towards the rear wall 30 in FIGS. 4 and 12 and engage each slot 28 to limit the backward movement of the second shell 7 relative to the housing 4.

The plate 24 on the second shell 7 is slidably fitted along the grid 11 on the housing 4. In addition, the plate 24 on the second shell 7 extends on both sides of the partition 11. Cantilever spring fingers 31 protrude forward from each plate 24. The spring fingers 31 on the second shell 7 protrude in front of the plate 24 and also extend to each plug receiving cavity 3 and each plug type to be received by the plug receiving cavity 3. It is coupled with the electrical connector (8). Each spring finger 31 has a curved tip 32 that projects into a corresponding trough 33 dug into the partition 11. This tip 32 extends along the corresponding plug receiving cavity 3 to engage with each pluggable electrical connector 8 received at the plug receiving cavity 3. A spring finger 31 on the second shell 7 extends to each plug receiving cavity 3 together with an electrical contact 2 to each plug receiving cavity 3, thereby providing a plug receiving cavity 3. The pluggable electrical connector 8 received will be engaged by a spring finger 31 on the second shell 7 and by an electrical contact 2.

4, each plug 8 enters a corresponding contact 14 and engages with a contact 15 in the corresponding row. The conductive shell 9 on the plug connector 8 enters both the contact 14 and the corresponding shell receiver 13 of the same plug receiving cavity 13.

2, 3, 11 and 12, the conductive outer shell 6 is a single structure stamped and molded from a metal sheet having a thickness plane forming the thickness plane of the outer shell 6. The outer shell 6 comprises four walls 34 joined to each other at curved corners 35 in which one space 34 is branched by an open seam 36. Four walls 34 surround the open front end on the outer shell, and outwardly curved lip 37 on each wall 34 is adjacent the open front end.

The housing 4 and the outer shell 6 are hooked together by the latches 38 of FIGS. 1 and 3, which latches correspond to the outer shell 6 receiving the wedge-shaped projection 40 on the housing 4. An opening 39 in the wall 34. This protrusion 40 is inclined from the front to the rear so that the protrusion 40 is urged to the open rear end of the outer shell 6 and is caught in the opening 39 of the corresponding wall 34.

2 and 3, the trough opening 41 extending from the rear to the front at the corresponding both walls 34 communicates with the open rear end on the outer shell 6. Elongated ribs 42 protruding from the housing 4 on both walls extend along the grooved opening 41 to prevent pivoting of the outer shell 6 relative to the housing 4. The rib 42 enters the grooved opening 41 from the rear when the housing 4 is inserted into the open rear end.

Four walls 34 on the outer shell 6 enclose an open rear end on the outer shell 6. The wall 34 branched by the seam 36 has a rear opening 43, as shown in FIG. 11. Instead of removing the metal to form the opening 43, the metal removed to form the opening 43 becomes an elongated electrical terminal 44 aligned with the opening 43. This terminal 44 is connected to and protrudes from the corresponding both walls 34. The terminal 44 is connected to the opening through a circuit board (not shown), and a connector 1 is provided on the circuit board. As shown in FIGS. 4 and 5, the shoulder 45 on the housing 4 faces forward and is received in the opening 43 to prevent forward movement of the housing 4 relative to the outer shell 6. The housing 4 is inserted into the open rear end of the outer shell 6 until the shoulder 45 faces the edge on the opening 43.

The spring fingers 46 of each of the four walls 34 on the outer shell 6 are adjacent to the open front end of the outer shell 6. Each spring finger 46 is a cantilever beam with a curved tip 47 protruding inside the outer shell 6. Spring fingers 46 on corresponding both walls 34 extend from front to back. The spring fingers 46 on the remaining corresponding both walls 34 extend from rear to front. Each spring finger 46 is bent from the thickness plane of the outer shell 6 and protrudes into the wall 34. With reference to FIG. 4, the spring fingers 46 on the branched wall 34 face each other and extend along the corresponding plug receiving cavity 3 and along the contact receiving 14. A spring finger 46 on the opposite wall 34 is received at the shell receiver 13 of the other plug receiving cavity 3, the shell receiver 13 being on the outer shell 6 and the housing 4. It is between the corresponding outer wall. As shown in FIGS. 4 and 13, the shell receiving recess 13 extends on both sides of each partition 12. The spring fingers 46 of each of the two walls 34 joining the branch walls 34 extend along the shell receiving recess 13 and sequentially along the sides of each partition 12. The spring fingers 46 engage with the shell 9 on each plug connector 8, where the plug connector 8 is received by the plug receiving cavity 3 and is assembled with the connector 1. Thus, the electrical connection is preferably formed by the coupling of each shell 9 on the plug connector 8 as well as the outer shell 6 and the second shell 7 to each other.

2, 3, 10 and 12, the second shell 7 bridges across the recesses 48 of the housing. The outer shell 6 protrudes into the recess 48 and engages with the second shell 7. More specifically, the additional spring fingers 49 formed in each wall 34 on the outer wall 6 are adjacent to the rear end of the outer shell 6 and are similar in structure to the spring fingers 46. An additional spring finger 49 on the outer shell 6 protrudes into the recess 48 of the housing 4 and engages with each web 26 on the second shell 7 thereby allowing the second shell ( 7 couples with the outer shell 6 and an electrical connection is formed between them.

An advantage of the present invention lies in a shield that completely encloses the multiple plug receiving cavity, which shield includes a second shell that engages the outer shell, the second shell extending inside the multiple plug receiving cavity to achieve a compact structure. do.

Another advantage is that the second shell engages the outer shell so that both shells extend to each of the multiple plug receiving cavities of the connector and these shells engage with the respective electrical plug connectors to be received in the plug receiving cavity. Present in the shield.

Claims (8)

Shielded electrical connectors 1 of the type having an insulating housing 4, an electrical contact 2 extending into the multiple plug receiving cavity 3 inside the housing, and a conductive outer shell 6 surrounding the housing. To A conductive second shell 7 is fixed in the housing 4 and in combination with the outer shell 6 to provide an electrical shield, the second shell 7 extending into each plug receiving cavity 3 so that the plug Shielded electrical connector, characterized in that it is engaged with the pluggable connector (8) to be received in the receiving cavity (3). The method of claim 1, The second shell 7 is slidably fitted over the partition 11 on the housing 4, the partition 11 is between the plug receiving cavities 3 and the second shell 7 is the partition 11 Shielded electrical connector, characterized in that is fitted along both sides of the). The method of claim 1, A spring finger 31 on the second shell 7 extends into each plug receiving cavity 3 together with the electrical contact 2 in each plug receiving cavity 3, whereby the plug receiving cavity 3 Shield characterized in that the pluggable electrical connector 8 received by (3) is joined by the spring fingers 31, 46 of the second and inner shells 6, 7 and by the electrical contact 2. Type electrical connector. The method of claim 1, The spaced plate 24 on the second shell 7 is slidably fitted in the spaced grooves 28 of the housing 4, and the web 26 on the second shell extends in the transverse direction of the plate 24. The web bridges across the recess 49 of the housing 4, and the spring finger 49 on the outer shell 6 protrudes into the recess 48 and engages with the web 26. Shielded electrical connectors. Insulated housing (4), at least two plug receiving cavities (3) formed in the housing, electrical contacts (2) in each plug receiving cavity, and conductive outer shell (6) surrounding the housing (4) In the shield electrical connector (1), A conductive second shell 7 is fixed in the housing 4 and combined with the outer shell 6, the second shell 7 protruding between the plug receiving cavities 3 in the housing 4, Shielded electrical connector, characterized in that each plug receiving cavity is surrounded by a shield. A conductive outer shell 6 having an insulating housing 4, a plug receiving cavity 3 in the housing for receiving each pluggable connector 8, and a first spring finger on the respective wall 34. 46, having a first spring finger 46 coupled to the respective mating plugs 8 to be inserted into the outer shell 6 adjacent the open front end on the outer shell 6; In the electrical connector (1), A conductive second shell 7 is fixed in the connector inside the outer shell 6 and has a first spring finger 31 adjacent the open front end of the outer shell, the second shell 7 receiving a respective plug. Inside the cavity 3, it is engaged with each pluggable connector 8 to be inserted into each plug receiving cavity 3, the second spring finger 49 on the outer shell 6 being second Shielded electrical connector, characterized in that for coupling with the shell (7) to form an electrical connection therebetween. The method of claim 6, Shielded electrical connector, characterized in that the partition wall in each plug receiving cavity (3) divides each plug receiving cavity into a shell receiving portion (13) and a contact receiving portion (14). The method of claim 7, wherein Some first spring fingers 46 extend to the contact receiving portion 14 of the plug receiving cavity 3, and the remaining first spring fingers 31 each shell receiving portion of the plug receiving cavity 3 ( Shielded electrical connector, characterized in that extending to 13).