JPH02155178A - Multipolar connector - Google Patents

Abstract

PURPOSE:To reduce stroke between signal lines by connecting a spring-like projection of a metal plate to a predetermined constant within a connector layer through a perforation. CONSTITUTION:A plurality of spring-like projections 104 are provided on each surface of a metal plate 103, and each projection 104 is connected to a contact, which is in turn connected to a shielding wire (at the ground potential or reference potential) in each connector layer 101, through a perforation 102 provided in an insulating frame 110 for each connector layer 101. Each shielding wire and the metal plate 103 is electrically connected to each other, and electric shielding is achieved between respective layers 3. The crosstalk between the different kinds of signal lines is reduced by arranging the contact in each layer 101 so that the shielding wire is between the different kinds of signal lines. In this manner, a multipolar connector, with reduced crosstalk between the signal lines, less electromagnetic interference, simple construction, and being economical, can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field of the Invention) The present invention relates to a multipolar connector for removably connecting signal transmission cables all at once.

(Technical Background of the Invention and Problems Thereof) Conventionally, this type of multi-pole connector has had problems, mainly related to crosstalk performance between different signal lines and electromagnetic interference generated from the connector. Ta.

Figure 5 shows a conventional multi-pole connector 5 for attaching a signal transmission cable.
An example of the contact arrangement of 00 is shown. These contacts are fitted with a number of coaxial cables, S, G.
, indicate contacts connected to the core wire (signal wire) and shield wire of the coaxial cable 501, respectively. Similarly, 82,
G2 indicates contacts connected to the core wire and shield wire of the coaxial cable 502, respectively. Same below. As can be seen from this contact arrangement, for example, contact S2
Since contact G3 connected to the shield wire exists between and contact S4, crosstalk between both contacts is small. However, if there are no contacts that are openly connected to the shield wire, such as contact Sl and contact S2, the Talostalk between both contacts becomes large. This crosstalk increases as the distance between the contacts within the connector increases.

Furthermore, the frame 510 of the connector itself is generally formed of a plastic mold, and has no effective function regarding electromagnetic interference generated from the connector, and electromagnetic waves are radiated outward from each contact. .

FIG. 6 shows a conventional example of a connector 600 for attaching one coaxial cable. S, , and G indicate contacts connected to the core wire and shield wire of the coaxial cable 601, respectively. Further, the shielded wire is also connected to a metal shell 620 surrounding the connector 600 to provide countermeasures against electromagnetic interference. These single connectors 600 can be arranged horizontally and vertically and stacked to form a multi-pole connector. At this time, since the contacts connected to each core wire are shielded by the metal shell, crosstalk is small. Therefore, a multi-pole connector with good performance against crosstalk and electromagnetic interference can be obtained. However, due to the dimensional tolerance of each individual connector 600, the pitch between the contacts between each connector becomes inaccurate, and therefore there is a limit to the multipolarization. Further, since the connection between each shield wire and the metal shell 620 is performed by soldering or the like, workability is very poor.

(Objective of the Invention) An object of the present invention is to provide an inexpensive multi-pole connector with a simple configuration and low Talostalk between signal lines and low electromagnetic interference.

(Summary of the Invention) According to an embodiment of the present invention, a multi-pole connector has a structure in which a plurality of single-layer cable attachment connectors each having a plurality of contacts are stacked, and a metal plate is inserted between each layer. is provided.

A plurality of spring-like protruding members are provided on each surface of the metal plate, and each of the protruding members passes through a through hole provided in the insulating frame of each connector layer to connect the shield wire (
ground potential or reference potential). Thereby, each shield wire and the metal plate are easily electrically connected, and electrical shielding is provided between each layer. By arranging the contacts in each layer so that the shield line is located between the different signal lines, crosstalk between the different signal lines in each layer can be reduced. Therefore, crosstalk between signal lines within each layer and between each layer is reduced.

Furthermore, if the multi-polar connector is covered with a metal plate having the above-described structure and electrical contact is made with (the contact connected to) the shield wire in the connector layer that is in contact with the metal plate, Electromagnetic interference emitted from the multipole connector can be reduced.

Since the frame of each connector layer has an integral structure using plastic molding etc., the accuracy of the pitch between the contacts in each layer is good, and if the thickness of the metal plate inserted between each layer is made thinner, the distance between each layer can be improved. Pitch accuracy also improves, making it possible to create multi-pole connectors consisting of more contact pins.

The multi-pole connector has a simple structure and does not require soldering, which is difficult to work with. Therefore, it can be produced at low cost.

(Embodiment of the Invention) FIG. 1 shows a multi-pole connector 100 according to an embodiment of the invention. A large number of contacts are provided in a connector layer 101 having a frame 110 integrally formed with a mold of plastic or the like, and core wires and shield wires of a plurality of coaxial cables are connected to these contacts. Further, the contacts are arranged so that signal lines and shield lines alternate. Therefore, within the layer,
Crosstalk between contacts connected to each signal line is small. The frame 110 of each connector layer 101 has through holes 102 corresponding to contacts connected to each shield wire.
is provided.

A metal busper 103 made of a metal plate is inserted between each connector layer 101. A plate spring 104 integrally formed with the metal plate is provided on each surface of the metal busper 103, which is formed by punching out a part of the metal plate. Leaf spring 104
are electrically connected to contacts connected to each shield wire through the through hole 102. Therefore, metal busper 10
3 provides electrical shielding between each layer 101. As a result, crosstalk between different signal lines within each connector layer 101 and between each connector layer can be significantly reduced.

In addition, a metal shell (not shown) made of a metal plate having the same structure as the metal busper 103 surrounds the multi-pole connector 100, and connects the metal shell to the shield wire (in the connector layer 101 in contact with the metal shell). Electromagnetic interference emitted from the multi-polar connector 100 can be significantly reduced by electrically connecting the multi-polar connector 100 to the multi-polar connector 100 through a through hole (not shown).

As can be seen from the figure, the multi-pole connector 100 has a simple structure and does not require soldering, which is difficult to work with, to connect the metal shell and each shield wire, and therefore can be manufactured at low cost.

In addition, since each connector layer 101 is molded, the pitch between each contact can be made accurate, and if a thin metal busper 103 is used, the pitch between each connector layer 101 can be made with good accuracy. can do. Therefore, it is possible to create a multi-pole connector with more contacts.

FIG. 2 shows a multi-pole connector 200 according to another embodiment of the present invention.
shows. This multi-pole connector 200 is mainly created for shielded pair cables. For example, contacts indicated as SI+, S, and -1Gl are connected to a signal line, a signal line, and a shield line, respectively, of a set of shielded pair cables. In this example, the leaf spring 104 is attached to three of the contacts in each connector layer 101 on both the back and front sides of the metal busper 103.
They are formed for each pitch and are in electrical contact with (contacts connected to) the shield wires in each connector layer 101.

In addition, in both FIG. 1 and FIG. 2, the through holes 102 provided in the frame 110 of each connector layer 101 may be provided corresponding to each contact. This is because which contact in each connector layer 101 is electrically connected to the metal busper 103 can be determined by the arrangement of the leaf springs 104 provided on the metal busper 103.

Further, the cable connected to the multipolar connector according to the present invention is not limited to a coaxial cable or a shielded pair cable, but may simply be composed of a large number of single wires.

FIG. 3 shows a multi-pole connector 300 according to yet another embodiment of the invention. Metal plates 301 having spring properties in the longitudinal direction are provided at both ends of the metal bus spar 103 in the longitudinal direction.
is provided perpendicularly to the metal busper 103. The metal plate 301 can have an integral structure with the metal bus spar 103. This metal plate 301 allows stacking of connector layers 101 having the same shape, and also suppresses electromagnetic interference emitted from the multipolar connector.

FIG. 4 shows an embodiment of a receiver side connector 400 (hereinafter referred to as a bin header) which serves as a receiver for a multi-pole connector according to the present invention.

Bin header 400 is typically attached to a substrate, such as a printed circuit board.

Pin header 4001t3J according to the present invention 4 Figure (a
), it includes a bottle contact 401, a metal busper 402 made of a metal plate, a support member 403 made of a plastic mold, and a fixture 404.

Fittings 404 can be integrally constructed with metal bussers 402 . The fixture 404 is connected to the ground pattern of the board.

As shown in FIG. 4(b), the pin contacts 401 corresponding to the signal lines are soldered to the signal line pattern on the substrate 405 with the substrate 405 sandwiched therebetween. A via contact 401 corresponding to the shield wire is soldered to a terminal 406 on the substrate 405 and connected to a ground pattern 408 on an inner layer within the substrate 405 via a through hole 407 .

(Effects of the Invention) As described above, by using the present invention, it is possible to provide an inexpensive multi-pole connector with a simple configuration and low crosstalk between signal lines and low electromagnetic interference.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing an embodiment of the present invention, and in particular a multi-pole connector suitable for attaching a plurality of coaxial cables. FIG. 2 is a diagram showing another embodiment of the present invention, and FIG. 3 is a diagram showing a multipole connector particularly suitable for mounting a plurality of shielded pair cables. FIG. 3 is a diagram illustrating an embodiment of a multi-pole connector suitable for scooking each connector layer; FIG. 4 is a diagram showing one embodiment of a bin header for receiving a multi-pole connector according to the present invention. FIG. 5 is a diagram showing a conventional multi-pole connector. FIG. 6 is a diagram showing a conventional example of a connector for attaching one coaxial cable. 100: Multipolar connector 102: Through hole 104: Leaf spring 101: Connector layer 103: Metal bus bar

Claims (3)

[Claims] (1) A connector layer including a plurality of contacts and a plurality of through holes provided in a frame that supports the contacts, and a metal plate disposed between the connector layers and having a spring-like protrusion on each surface. A multi-pole connector comprising: and, wherein the spring-like protrusion connects to a predetermined contact in the connector layer through the through hole. (2) A metal member having spring properties in the longitudinal direction is provided at both longitudinal ends of the metal plate, and the connector layer is laminated by the metal member.
1) Multi-pole connector as described. (3) A pin header comprising: a pin header layer provided with a plurality of pin contacts; and a metal plate provided between the pin header layers and provided with a fixture for attaching the pin header to a substrate.