KR940011571B1 - Daisy chain connector and method - Google Patents

Abstract

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Description

Daisy-Chain Connector and Termination Method

1 is a side view of a connector placed in such a way that the back plate and back plate cover can be removed and terminated in a ribbon or round cable in accordance with the present invention.

2 is a plan view of a ribbon cable showing how cable leads are separated to form a loop needed for daisy chain termination.

3 is a perspective view of the split cable of FIG. 2 in which two loops are formed.

4 is a side view of the connector of FIG. 1 terminated in a daisy chained cable.

5 is a side view of the connector taken along line 5-5 of FIG.

6 is a lower end view of the connector taken along line 6-6 of FIG.

7 is a top end view of the connector taken along line 7-7 of FIG.

FIG. 8 shows a series of connectors, such as the connector of FIG. 1, installed in a daisy chain structure of a ribbon cable.

9 is an alternative showing a series of connectors terminated in a multi-conductor round cable having a daisy chain structure.

* Explanation of symbols for main parts of the drawings

16 contact portion 20 connector housing

46: cable 48: lead wire

56,58: End cover

The present invention relates to a single / socket connector that can be provided in a daisy chain structure, and more specifically, a pin that can be inserted into a conductor of a multi-conductor flat cable or a conductor of a multi-conductor round cable. It relates to a socket connector and a termination method thereof.

Connectors that terminate flat ribbon cables in a daisy chain are well known and are described in US Pat. Nos. 4,068,912, 4,410,229 and 4,668,039. These connectors are designed to terminate the ribbon cable with a receiving receptacle contact in the rectangular post of the corresponding array.

U.S. Pat.Nos. 4,062,616, 4,241,970 and RE 32,439 describe pin / socket connectors capable of terminating a daisy chain of planar ribbon cables. The connectors of these patents are terminated in a single array of conductors. With contacts, the leads are terminated in contacts fixed to the connectors to form a daisy chain structure. High density connectors, such as the currently available AMPLIMITE 0.50 series connectors, have contacts with cable terminations that consist of two double-sided arrays to adjust the insulation displacement, which contacts terminate the ribbon cable in the form of the aforementioned connector. Can't.

Japanese Patent Application No. 61-074100 also describes a daisy chain connector cable.

The ribbon cable may be folded with the conductors of the cable terminated in two rows of contacts. As taught in US Pat. No. 4,143,935, the first portion of the lead of the cable terminates at the crossover terminal at the first level and the remaining lead terminates at spaced contacts at the second level. However, this approach is not appropriate for daisy chain applications. The reason is that such an approach is such that the cable cannot be accepted from the primary connector of the daisy chain structure on the first side of the terminating connector and from the second side of the terminating connector to the subsequent connector of the daisy chain structure. It's because you can't. In addition, to address other problems, the quota of pins between cable leads and contacts is extremely limited and inconsistent with each other, depending on how the leads of the folded cable are oriented with respect to two levels of contacts in each connector. It may be.

The insulation that interconnects the conductors of the ribbon cable is divided in parallel to the axis of the conductor in the middle of the conductors of limited length along the cable. The staggered conductor group forms the first loop when divided from the cable, and the remaining conductor group forms the second loop. The connector housing having two rows of insulation displacement contacts is positioned between the conductors forming the two loops, wherein the insulation displacement portions of the contacts are directed to terminate at the conductors forming the loop. The cable termination cover is fitted to each of the first and second loops of the conductor. The leads are placed in the grooved recesses of the cover for each cable termination in accordance with the predetermined lead contact relationship. The cable termination cover is placed so that the legs to be joined to each other face each other. The leads are terminated at the insulation displacement portion of the contact in the connector housing by crimping the cable termination covers against each other.

An embodiment of the present invention will now be described with reference to the accompanying drawings.

1 shows a side view of an electrical connector 10, wherein the electrical connector 10 is a two-row insulation displacement contact portion capable of terminating a conductor of a multi-conductor cable to a pin / socket type connector of a daisy chain structure according to the present invention. Equipped with. Connector 10 is an improvement on the connector described in US Patent Application No. 090,296 filed August 31, 1987. Exemplary embodiments show shielded plug connectors, but the present invention is in application according to different connectors such as unshielded connectors and receptacle connectors. The draw set 12 shields the tab 14 of the contact 16 and also engages the shield of the connector when assembled.

The elongated housing 20 is formed of a thermoplastic material having an assembly surface 22 on the front side and a rear surface 24 on the rear side, and a plurality of contact receiving passages 26 extend between the two sides. The collecting surface 22 may provide a polarization characteristic by forming a trapezoidal or ultra-D-shaped. The shell 12 surrounds the collecting surface 22 to match the shape of the housing 20. The shell 12 also extends forward of the mating surface 22 to provide a shield for the contact 16. The contact receiving passages 26 are arranged in two rows 27 and 29 so that the contact portions 16 are fixed thereto. The contact portion 16 is fixed to the contact receiving passage 26 by the feather 28, which is formed in the side wall of the contact receiving passage 26 when the contact portion 16 is inserted, and is pressed into the contact portion in a customized manner. (16) is fixed.

The contact 16 includes a central body portion 30 fixedly received in the contact receiving passage 26, in which the collection, indicated by the tab 14, in an exemplary embodiment extends from the first side. The end portion 32 extends from the other side of the body portion 30 and at its free end a grooved insulating displacement plate 34 extends as is well known in the art. Since the connector 10 has a relatively small dimension compared to the centerline spacing of the contact portions 16, the adjacent contact portions 16 of each row 27 and 29 have end portions 32 of different lengths so that the insulation displacement plate ( Space for 34 is provided and the insulation displacement plates 34 are formed in two rows 35 and 37 on each side of the terminal support block 36.

The terminal support block 36 extends rearward from the rear face 24 between the two rows 27, 29 of the contact receiving passages 26, with the end 32 as far as possible and the surface 42. And 44, and both ends have holes 38 (see FIG. 6). The hole 38 has an axis parallel to the insulation displacement plate 34. Insulation displacement plates 34 in rows 27 and 29 are provided with recessed grooves 40 that open away from surfaces 42 and 44 on either side. While terminating the conductive wire 48 to the contact 16, an insulating displacement plate 34 lies on each surface 42, 44 of the block 36.

The electrical connector 10 can be terminated in either a multi-conductor ribbon cable or a multi-conductor round cable in accordance with the present invention. To terminate connector 10 to a multi-conductor jacketed or shielded cable, jacket 47 or shield 48 is stripped back or removed through a segment 50 of defined length.

In order to terminate the connector 10 to a multi-conductor ribbon cable 46 with each conductor 48 spaced apart from the centerline, the insulation between the two adjacent conductors 48 is primarily segment 4 in FIG. Is divided axially along Typically, a split 49 is formed between the mode adjacent leads 48 so that each lead 48 terminates at a particular contact 16 to maintain and repeat the specified lead-contact type along the daisy chain structure. do. This also causes the ribbon cable 46 with the conductors 48 to be terminated to the insulating displacement plate 34 of the contact 16, with the grooves 40 of the plate being smaller than the first interval to be smaller. It is a 2nd interval over.

Leads 48 are formed in two loops through a restricted segment 50 of cable 46 as shown in FIG. The first loop 52 of the conducting wire is formed of the conducting wires 48a between the center line 50C of the segment 50 and the end 50a, and the second loop 54 is the center line 50C and the end of the segment 50. It is formed of the conducting wires 48b between 50b. Each lead 48 is typically formed by only one of the two loops 52, 54 of the lead. However, the main wire 48 is formed of respective loops 52 and 54 and also terminated at the contact portions 16 of the passages 27 and 29 in each row so as to terminate or otherwise specify on both sides of the connector 10. It can be terminated on one connector and thus bypassed on another connector in a daisy chain.

In a preferred embodiment, every other conductive wire 48 is formed of a loop 52 and staggered conductive wires 48 are formed of a loop 54. This embodiment thus provides a very convenient way of terminating the ribbon cable with the conductors at the first spacing to the contact with the insulating displacement grooves at the second spacing, whereby the spacing of the contacts 16 is the length of the ribbon cable 46. Twice as large as the lead 48 spacing. Therefore, as shown in FIG. 4, the conductive lines 48a form the loops 52 and the conductive lines 48b form the loops 54. When the conductors 48 are moved out of the plane of the ribbon cable 46, the non-divided portion of the ribbon cable 46 is pulled to be more accessible along the axial direction of the conductors. The final end and the loops 52, 54 are shown very clearly in FIG. 1, with the cable terminated in the covers 56, 58 in a preliminary termination position, and in FIG. And 58).

The operation of dividing the conductors of the multi-conductor cable into first and second groups to form the first and second loops so that the conductors can maintain a predetermined lead-contact designation or dressing as a daisy chain structure. It is observed within the scope of the present invention. In a preferred embodiment, the conducting wires are described as forming the first loop, and the staggered wires form the second loop, but the invention is not limited thereto. For example, in a cable having ten conductors, the first, third, fourth, ninth and tenth conductors may form a first loop and the remaining conductors may form a second loop.

With the conductors 48 of the ribbon cable split or the outer jacket 47 removed from the multi-conductor cable, the conductor-contact designation allows a wide range of assignments in a very flexible state. In ribbon cable applications, the first conductor 48 of the transverse path traversing the ribbon cable is the first of the transverse path of the contact row 29 across the surface 42 of the terminal support block 36. Although terminated at the contact 16, the third lead 48 (second lead 48 in the loop 52) in the transverse path of the ribbon cable is transverse to the surface 42 of the terminal support block 36. And the fifth lead 48 (the third lead in the loop 52) is terminated in the third contact in the lateral path of the contact row in the direction. The remainder is terminated in this way, but the present invention is not necessarily limited thereto. Other lead contact designations are also envisaged in the present invention. Color tone-coded insulators are advantageous where more complex wire-contact designations are required because the wires can be easily identified by the color tone code used in the round cable formed in each wire. The leads of the two twisted cables can be terminated while holding two twisted leads on adjacent contacts.

With the loops 52 and 54 formed, each of the cable termination covers 56 and 58 passes axially along the loops 52 and 54 of the conductor 48, as shown in FIG. It is placed in a state in which the conductors 48 can be terminated. The conductors 48 can be unfolded as an organic structure that can be folded back during daisy chain application. The conductors may be held at such intervals by known methods such as sticky strips, heat bonds or chemical bonds of insulators in such structures, or by tools.

The cable termination cover 56, 58 is essentially the same as described in US patent application Ser. No. 090,296, filed August 31,1987. The covers 56 and 58 form side walls 60 and 62, opposing end walls 64 and 66, an outer surface 68, an inner surface 70 and a grooved portion. Leg means 72, 74 extend from an inner surface 70 proximate end walls 64, 66, and with hole means 73, 75 adjacent thereto. The cable termination covers 56 and 58 may be shaped like male conductors, and the side walls 60 defining the conductor receiving passages 78 passing the conductors 48 between the cable termination covers 56 and 58 may be formed. And a recess 76 formed in any one of 62, and a rear surface 24 which is continuous in a daisy chain structure. Conductor 64 is rotated 90 ° from passing through surface 70 and terminates in through passage 78 extending at right angles to surface 70 and parallel to insulation displacement plate 34. In a preferred embodiment, the passage 78 takes the form of a notch 80 to keep the conductors 48 in place throughout and after the termination. The passage 78 may take the form of a single wide recess for all leads, or a recess with individual notches for each lead, as shown in FIG.

As can be seen in FIG. 6, the conductors 48 are positioned in the notch 80 for terminations where insulation displacement is possible. The cable termination covers 56 and 58 may also have a channel 82 in the outer surface 68 to provide a recess for the lead 48. In this way, the outer surface 68 of the terminating covers 56 and 58 provides a support surface for applying force to terminate the conductive wire 48 to the contact 16. Notch 80 provides a path for conductor 48 to protrude from end cover 56 and 58 and terminal support block 36 and from end cover 56 and 58 to rear surface 24. By doing so, the conductive wire 48 can be sustained in a daisy chain structure. Leads 48 passing between the termination cover 56 and 58 and the terminal support block 36 provide strain relief for the termination.

Leg means 72, 74 provide a means for securing the end covers 56, 58 to the terminal support block 36 and the connector 10. The interlocking leg means 72, 74 formed on the inner surface 70 of the end cover 56, 58, respectively, are axially aligned with the hole 38, as can be seen in FIG. For this reason, the end covers 56 and 58 are moved toward the terminal support block 36 in the direction of the arrow 84 and the leg means 72 and 74 pass through the holes 38 in an interference fit manner. Accordingly, it passes through the hole means 73 and 75 of the cover for the other end. As the end covers 56 and 58 are squeezed together until they are seated on the respective surfaces 42 and 44 of the terminal support block 36, the conductors 48 are connected by two rows of contacts by the respective insulating displacement plates 34. 16) is terminated. The second means (72, 74) is coupled to the side wall of the hole 38 and the projections 86 formed on the wall of the hole means (73, 75) of the other end cover terminates the end cover (56, 58) Secure to position.

In this way, the interference fit between the projection 86 and the leg means 72, 74 gives the result of engaging the projection 86 against the surface of the leg means 72, 74 which are not deformed in the longitudinal position. do.

7 shows a series of connectors 10 terminated in a daisy chain to a ribbon cable 46. The connectors are shown without a backplate and a backplate, but have the same characteristics as above.

8 shows a series of connectors 10 that are daisy chained to a round cable 46. The housing 20 may be fixed to the thick plate members 88 and 90 or partially wrapped. The plate members 88 and 90 may be electrically conductive with the ordinary shell 12 and the shield 49 for the cable 46, so as to provide a common ground between them in some cases. Thick plates 88 and 90 may have a single cable outlet 92 for cable 46 as described in US patent application 090,296. Alternatively, as shown in FIG. 9, the rear plates 88 'and 90' may have double cable outlets 92 'for conducting wires. The conductor close to the cable exit is provided with strain relief means 94.

Claims (10)

An electrical connector assembly for daisy chaining the conductors of a multi-conductor cable, comprising an insulating housing and a pair of conductor termination covers, the insulating housing having a backing surface on the mating surface and the opposite side, and a plurality of cables between them. The contact receiving passages extend and are arranged in two rows, and the housings have first and second rows of contacts fixed thereto, the contacts have a single axis, and there is a collecting portion proximate to the collecting surface, and the termination portion is more than the rear surface. The terminal portion, which extends further and forms an insulation displacement plate, has one groove in its own, and each of the conductor termination covers terminates the conductors at the termination portions formed in each of the one row of contacts adjacent to the rear surface. Each cover has means for securing the cover to the housing and further By confining the lead receiving path through the conductors between the rear face and each longitudinal section cover adjacent to the back, the leads of the multi-conductor cable are daisy chained and terminated at the contacts of the electrical connector assembly. And an electrical connector assembly which is received from one side and extends through each insulated displacement plate for termination to the daisy chain structure from the second side of the connector assembly to the other connector through the bow passage. 2. The electrical connector assembly of claim 1, wherein the lead path has a shape in which the leads of the cable are aligned with the ends of each contact. 3. The electrical connector assembly of claim 2, wherein the grooves of the cable terminating cover are recessed so that the conductors of the cable are spaced at the same distance from each contact portion. 2. The insulation displacement plate of claim 1, wherein the groove of the insulation displacement plate extends in a direction perpendicular to the axis of the contact portion, the insulation displacement plate in the first row of contacts extends in the first direction, and the insulation displacement plate in the second row extends in the second direction. Extending, wherein the second direction and the first direction are opposite to each other. 5. The electrical connector assembly of claim 4, wherein the terminal support block extends from the rear surface of the housing between the rows of contacts, and the lead terminating cover is secured to the block. 6. The method of claim 5, wherein the pair of spaced apart holes in the terminal support block define a hole wall, and the cover fixing means includes: a first hole means defining a first wall means adjacent to the first terminating cover; A second hole means defining a first leg means spaced apart from each other and a second wall means comprising a second leg means spaced apart from a second hole means adjacent to a second end cover, wherein the first leg means The pair of spaced holes are received in a paired manner between the first portion of the first leg means and the first portion of the hole wall in a position, the second leg means being different from the first leg means. Received in the paired spaced holes in the opposite direction, and the second leg means is adapted to fit between the first portion of the second leg means and the second portion of the hole wall at a predetermined position. Received in paired spaced holes, The first leg means is fixed to the spaced apart hole in the longitudinal position and extends to the second hole means in an interfitting manner between the second portion of the first leg means and the second wall means, and the second leg The means is fixed simultaneously with the first leg means to support the end cover to the wall means and the preliminary end position from the preliminary end position to the end position of the first and second end covers. The first and second termination covers allow the conductors to terminate at the ends of the contacts as they move, while being secured by fitting them to the end positions between the areas of the leg means which are not deformed in advance by interference fits. An electrical connector assembly, characterized in that one. A method of terminating a connector having a housing and a plurality of insulated displacement contacts at the midpoint of the lead with respect to the leads of the multi-conductor cable divides the leads of the multi-conductor cable into pre-selected first and second group leads. And the first group of conductors in the form of a first loop, and then the first group of conductors are terminated in the first portion of the insulation displacement contact. 8. The termination method according to claim 7, wherein the second group of conductors is shaped like a second loop, and the second group of conductors is terminated in the second portion of the insulator displacement contact portion. 8. The method of claim 7, having a step of splitting adjacent conductors over a limited length of cable prior to dividing the conductors into first and second groups. 8. The method of claim 7, wherein dividing the leads into preselected first group v and A2 group leads comprises selecting the first group of conductors as crossed conductors and selecting the second group of conductors as the remaining conductors. Termination method, characterized in that.

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