EP0890203A1

EP0890203A1 - High density electrical connector

Info

Publication number: EP0890203A1
Application number: EP97915128A
Authority: EP
Inventors: Wayne Samuel Davis; Kenneth Wayne Guyer
Original assignee: Whitaker LLC
Current assignee: Whitaker LLC
Priority date: 1996-03-28
Filing date: 1997-03-18
Publication date: 1999-01-13
Anticipated expiration: 2017-03-18
Also published as: WO1997036351A1; DE69705115D1; CN1214805A; DE69705115T2; KR19990087828A; KR100473296B1; EP0890203B1; JP2000507384A

Abstract

Electrical connector (10) having a housing (12) molded around body sections of a plurality of terminals (40, 42, 44, 46) disposed in first and second rows. The terminals have IDC termination sections (32, 34, 36, 38) for respective wires (22, 24) to be urged thereinto by termination covers (26, 28). All IDC termination sections extend in a common direction from a common side of housing (12), and those (32, 34) of the first row are staggered rearwardly from those (36, 38) of the second row to facilitate wire insertion. The molding method includes providing core pins (92, 94) for supporting the terminals from one (74) of the mold halves, and lower terminals (40, 42) include lateral offsets (134) permitting core pins (94) to pass thereby to reach upper terminals (44, 46) vertically aligned therewith.

Description

HIGH DENSITY ELECTRICAL CONNECTOR

The present invention relates to the field of electrical connectors and more particularly to high density connectors.

There are connectors known in which a plurality of terminals are disposed in rows of respective passageways of an insulative housing, with contact sections exposed along a mating face of the connector, and the terminals are terminated to respective conductors at termination sections along a rear face of the housing. One such connector is disclosed in U.S. Patent No. 3,760,335 wherein the terminals are inserted into the respective passageways prior to being terminated to respective conductors, and are arranged in two rows. Once loaded into the passageways, the termination sections of the two rows of terminals are exposed along opposite sides of the housing for termination. The termination sections are of the type known as insulation displacement (IDC) , wherein a pair of parallel axially spaced plate sections traverse the conductor's path and defines a pair of slots between pairs of opposed beams; as the insulated wire is urged into the slots from beside the terminal, the beam edges cut through the insulation layer and engage and compress against the conductor to establish a pair of electrical connections between the terminal and the conductor. Insulative covers are utilized to simultaneously urge all the conductors of respective rows into their slots for termination while maintaining the appropriate spacing between the conductors, and thereafter become latched to the connector housing to protectively cover the terminations and maintain the conductors in the slots. It is desired to provide an electrical connector with a plurality of rows of closely spaced terminals enabling termination to respective conductors through insulation displacement along a common side of the connector housing.

It is also desired to provide such a connector where the terminals are molded in place in the housing. The present invention provides a connector wherein the termination sections of the terminals of a plurality of rows are exposed along a common side of the connector, for termination to respective conductors, where the terminals are molded into the housing. Preferably the termination sections are of the insulation displacement (IDC) type, and all conductors may thus be terminated by being urged into the IDC termination sections from a common side of the housing. The IDC termination sections of the two rows are staggered axially, so that the row farther from the side of the connector from which the conductors will be urged into the slots for termination, is positioned rearwardly from the IDC termination sections in the nearer row to provide a clearance for conductor termination. Additional rows could be provided with similar staggering. Within a row the IDC termination sections of adjacent terminals may be spaced axially to provide clearance from the next adjacent ones enabling close lateral spacing between terminals for greater density. The terminals may be molded in place within the connector housing in a manner exposing the IDC termination sections for eventual conductor termination, and also exposing the contact sections along the mating face, a manufacturing technique generally known. However, to assure that the terminals are retained precisely in position, core pins are utilized to engage the body sections of the terminals during molding for positional stability. So that the core pins extend from the same side of the mold, given that the terminal density is high, and the body sections of the terminals must be aligned between rows, the terminals of a certain row are formed to define lateral offsets enabling the core pins to pass by the terminals of that row to reach the terminals of another row positioned in vertical alignment therewith. Termination covers preferably are used to provide protective insulative covering of the terminations and to thereafter maintain the conductors in the slots.

An embodiment of the present invention will now be disclosed by way of example with reference to the accompanying drawings, in which: FIGURE 1 is an isometric of a connector assembly of the present invention from rearwardly thereof with representative wires extending therefrom;

FIGURE 2 is a side view of the connector of FIG. 1 prior to wire termination, with termination covers poised to be applied to the connector to terminate the wires to respective terminals, and with portions of the shell broken away to reveal detail of the housing;

FIGURE 3 is a longitudinal section view of the connector housing and terminals after the insert molding process, with upper and lower mold halves opening and core pins withdrawing from the molded housing;

FIGURES 4 through 7 are plan and elevation views of the terminals of the upper and lower rows, respectively;

FIGURE 8 is an isometric view illustrating the connector housing and terminals of the assembly of FIG. 1 prior to wire termination;

FIGURE 9 is a plan view of the rear face of the connector of FIG. 8, with a termination cover poised for attachment to the connector; FIGURE 10 is a plan view of the housing after insert molding;

FIGURES 11 and 12 are partial cross-sectional views of the IDC termination sections of several terminals after insert molding of the housing, taken along lines 11-11 and 12-12 of FIG. 10; and

FIGURE 13 is a longitudinal section view of another embodiment of the present invention, with two connectors containing the present invention secured within a common shell to define a four-row connector assembly.

In FIG. 1 connector 10 is seen having an insulative housing 12 and a shell member 14 therearound, extending from a mating face 16 to a rear face 18, and having a termination face 20. A plurality of conductor wires 22 extends to a first or lower row of terminals along termination face 20, and a plurality of conductor wires 24 similarly extends to a second or upper row of terminals. First and second termination covers 26,28 are seen in FIG. 2 about to be utilized to cover the wires after being urged into the insulation displacement termination sections 32,34,36,38 at rearward ends of terminals 40,42 of the lower row and terminals 44,46 of the upper row.

FIG. 2 also shows the shell member 14 providing a shroud 48 surrounding the mating face 16, with front contact sections 50,52 of the lower and upper rows of terminals disposed along a support wall 54 of housing 12 and exposed within large cavities 56,58 for mating with corresponding contacts of a mating connector (not shown) . Shell member 14 also is shown to include a flange 60 for holding fasteners such as jackscrews for securing a mating connector to connector 10, or for fastening of a backshell (not shown) , or both, or for mounting to a panel. A cable tie support 62 extends rearwardly from a bottom wall 64 of shell member 14 around which a cable tie would be applied to secure the plurality of wires 22,24 to the connector for strain relief. Also seen are downwardly facing ledges 66,68 along the side of the housing 12 cooperating with inwardly directed latching projections (FIG. 9) of latch arms 70,72 of the termination covers 26,28 enabling latching of the termination covers to the housing. In FIG. 3, molding of housing 12 is represented, with lower and upper mold halves 74,76 defining the mold cavity when together. In this insert molding procedure, terminals 40,42,44,46 are to be embedded within the insulative housing with only certain sections of the terminals exposed for electrical connection, namely, front contact sections 50,52 and IDC termination sections 32,34,36,38. It is imperative in the connector for the terminals to be securely held during the molding process precisely in predetermined positions, since the molding process involves the injection of molten plastic resin into the mold cavity under high pressure. The halves of the mold apparatus are seen to engage the terminals at their exposed contact sections and IDC termination sections, which generally is conventional in insert molding. IDC termination sections 32,34,36,38 are disposed in a close fit within slots 78 of the upper mold half, and front contact sections 50,52 are engaged therealong by surfaces 80 of the upper mold half within grooves 82, which is conventional in insert molding.

Additionally, the front ends 84 of the front contact sections are supported by core pins 86 that, in cooperation with mold surfaces 80, firmly grasp the front contact sections from opposed sides thereof. The upper and lower mold halves similarly support rearward portions of the terminals. Terminal support of the terminals is accomplished by ribs 88 of upper mold half 76 that abut upper surfaces of all terminals intermediate between the forward and rearward ends thereof, preferably ribs 88 are profiled to provide shallow grooves 90 within which the terminals are seated to prevent any lateral movement during molding. Lower mold half 74 includes arrays of core pins 92,94 that extend into the mold cavity for their tips 96,98 to support rearward ends of the terminals adjacent the IDC termination sections, and in cooperation with slots 78 and ribs 88 of upper mold half 76 firmly grasp the rearward ends of the terminals therebetween. Vestigial holes 100,102,104 and slots 106 remain in the housing after molding. Latch projections 110 are seen that latch into windows 112 of shell member 14 (FIGS. 1 and 2) upon assembly.

Terminals 40,42,44,46 are seen in FIGS. 5 to 8, illustrating first contact sections 50,52 and IDC 5 termination sections 32,34,36,38 having IDC slots 114 between pairs of beams 116 (best seen in FIGS. 11 and 12) for later receipt of respective insulated wires to be urged thereinto. Terminals 40 and 42 of the lower row preferably are stamped and formed together on

10 carrier strips 118,120 as are terminals 44 and 46 of the upper row, to maintain precise spacing and for convenience of handling during molding of housing 12. Preferably, carrier strips 118,120 are severed at notches 122,124 prior to insert molding, with the thin

15 tips 126,128 of front contact sections 50,52 preferably defining a chamfered surface adjacent the top surface as a lead-in to facilitate mating with mating contacts during connector mating. The terminals of the two rows further are preferred to have vertical offsets 130,132

20 along intermediate portions diverging in opposing directions allowing a wide "window" between the upper and lower rows to facilitate the flow of molten resin laterally between the two rows of terminals.

Since it is desired that front contact sections 50

25 and 52 be vertically aligned, terminals 40 of the lower row are positioned directly beneath terminals 44 of the upper row, with terminals 42 and 46 being likewise positioned. In one aspect of the present invention, lateral offsets 134 are formed in terminals 40 and 42 of

30 the lower row permitting portions of core pins 94 to pass them to reach and engage terminals 44,46 directly above them for support thereof during the insert molding process. Further, core pins 94 include shoulders 136 supporting lower terminals 40,42 spaced forwardly from -35 their IDC termination sections 32,34 that are supported by core pins 92, thus preventing intermediate portions of terminals 40,42 to bow during molding. With reference now to FIGS. 8 to 12, molded housing 12 is seen to have a lower tier of IDC termination sections 32,34 for terminals 40,42 and an upper tier of IDC termination sections 36,38 for terminals 44,46. Channels 138 are defined for receipt of conductor wires therealong forwardly and rearwardly of the IDC termination sections. Termination covers 26,28 each include a wire face 140 having grooves 142 therealong within which the conductor wires are disposed when the covers are latched to housing 12, with latch arms 70,72 of termination covers 26,28 defining latching projections 144 that latch under ledges 66,68 of housing 12 recessed along both sides thereof. Termination may be performed in sequence with wires 22 first being urged into IDC termination sections of the lower tier, and then wires 24 into IDC sections of the upper tier; the covers may be placed with upper cover 28 being latched into position, followed by lower cover 26 being worked between the rows of upper wires 24 and lower wires 22 and then latched, especially if wires 22,24 are in twisted pairs extending from a common cable (not shown) . Bottom wall 64 of shell member covers the vestigial holes 94,96, while the termination covers 26,28 effectively close off the slots 106 formed during molding.

An additional embodiment of the present invention is illustrated in FIG. 13. Four-row connector 200 includes a pair of housings 202 sandwiched together within a common shell member 204, presenting four rows of terminal front contact sections 206,208,210,212 along two housing blades 214,216 of the mating face disposed within shroud 218. Four tiers of IDC termination sections 220,222,224,226 are seen along the rearward end, with the IDC termination sections of each housing 202 facing opposed directions for termination to wires 228 as described above with respect to connector 12 of FIGS. 1 to 12. The present invention provides for a connector having for example sixty-eight terminals presenting thirty-four front contact sections along each side of the forward housing section, the terminals of the two 5 rows being vertically aligned with their centerlines spaced apart a distance of 0.8 mm. The centerlines of the conductor wires are similarly spaced apart a distance of 0.8 mm, and the IDC termination sections may each be about 0.97 mm wide, with the tiers being

10 vertically staggered about 1.3 mm. The terminals have a thickness of about 0.25 mm, a width generally of about 0.44 mm, and lengths of between about 9.3 mm and 16.6 mm. In one example of the connector made in accordance with the present invention as shown in FIGS. 1 to 12,

15 the total width of each housing is about 33.9 mm adjacent the mounting flange 60 of shell member 14; its height is about 5.2 mm adjacent the mounting flange; and its length is about 18.1 mm, all defining a very compact, high density connector having sixty-eight

20 terminals in two rows of thirty-four each.

After wire termination, the connector assembly may have potting material disposed around the connector rearwardly from the mounting flange of the shell member, embedding the IDC termination sections, the wires and

25 the termination covers for sealing thereof, if desired. Further, if desired a backshell may be affixed over the connector and an adjacent portion of the cable, rearwardly of the flange of the shell member.

The insert molding process described hereinabove

30 can be used, of course, where the terminals are not necessarily to be terminated to wires with insulation displacement, and can also be used for connectors having more than two rows of terminals.

The present invention may include more than two -35 rows of terminals with respective tiers of insulation displacement sections.

Claims

WHAT IS CLAIMED IS:

1. An electrical connector (10) of the type having a plurality of terminals (40,42,44,46) terminated onto electrical conductor wires (22,24) through insulation

5 displacement, the connector having an insulative housing (12) having a mating face (16) and a rear face (18) , with the plurality of terminals extending therethrough arranged in at least two rows, each terminal (40,42,44,46) having a front contact section (50,52) at

10 the mating face (16) and an insulation displacement section (32,34,36,38) at a rearward end thereof, and the insulation displacement sections of each terminal extending transversely from a body section of the terminal, characterized in that:

15 the insulation displacement sections (32,34,36,38) of the terminals of the at least two rows extend outwardly from the same side surface of said insulative housing (12) to be exposed along a common side of said housing (12) , the common side thus defining a

20 termination face (20) for respective conductor wires (22,24) to be inserted into slots (114) thereof from laterally of said termination face (20) .

2. The electrical connector (10) as set forth in claim 1 further characterized in that said insulative

25 housing is molded around body sections of said terminals (40,42,44,46) in a manner exposing said front contact sections and said insulation displacement sections (32,34,36,38) .

3. The electrical connector (10) as set forth in 30 either of claims 1 or 2 further characterized in that said insulation displacement sections (32,34 and 36,38) of adjacent ones of said terminals (40,42 and 44,46) in a said row are axially staggered.

4. The electrical connector (10) as set forth in ^"35 any of claims 1 to 3 further characterized in that said termination face (20) includes conductor-receiving channels (138) aligned with respective ones of said insulation displacement sections (32,34,36,38) of said terminals.

5. The electrical connector (10) as set forth in any of claims 1 to 4 further characterized in that said

5 insulation displacement sections (32,34,36,38) of said terminals of each said row are in an array staggered axially with respect to such an array of each other said row, with each said array being disposed in vertically staggered tiers along said termination face (20) of said 10 housing (12) .

6. The electrical connector (10) as set forth in any of claims 1 to 5 further characterized in that a termination cover (26,28) is associated with each said array of insulation displacement sections (32,34 and

15 36,38), and is adapted to cover conductor wires (22,24) that are urged into slots (114) of respective said insulation displacement sections and become affixed to said housing (12) .

7. A connector assembly (200) of the type having a 20 pair of electrical connectors as set forth in any of claims 1 to 6, characterized in that the pair of connectors are disposed in a common shell member (204) , each with the insulation displacement sections (220,222,224,226) of its terminals extending in opposed 25 directions from those of the other connector of the assembly.

8. A method of making an electrical connector (10) of the type having an insulative housing (12) in which are disposed a plurality of terminals (40,42,44,46) in 30 at least two rows, wherein the housing is molded using a mold apparatus having first and second mold halves (74,76) reciprocally movable together to define a mold cavity therebetween, by first providing at least first and second rows of terminals (40,42 and 44,46) each -35 having body sections extending between front (50 and 52) and rear (32,34 and 36,38) contact sections, in which the front and rear contact sections of the terminals (40 and 42) of said first row are aligned with those of the terminals (44 and 46) of said second row, the housing (12) is molded around the terminal body sections which are supported by core pins (92,94) during the molding 5 process, characterized in that: first and second core pins (92,94) are provided on said first mold half (74) extending into said mold cavity to engage and support said body sections of said terminals (40,42 and 44,46) of said first and second

10 rows from a first side of said mold cavity during molding, and providing portions (80,88) of said second mold half (76) to engage and support said terminals of said first and second rows from a second side of said mold cavity;

15 lateral offsets (134) are provided in said body sections of said first row of terminals (40,42) so that said second core pins (94) for supporting said second row of terminals (44,46) pass thereby to reach and support said terminals of said second row.

20 9. The method as set forth in claim 8 further characterized in that said second core pins (94) include shoulders (136) spaced from said second terminals for supporting adjacent ones of said first terminal body sections at said lateral offsets (134) , and said first

25 and second core pins (92,94) are tapered adjacent terminal-supporting ends (96,98) thereof.

10. The method as set forth in either of claims 8 or 9 further characterized in that said portions of said second mold half (76) include first and second ribs (88)

30 extending transversely across said mold cavity to engage adjacent surfaces of said first and second terminal body sections, and said first and second ribs (88) include axially aligned grooves (90) wherein said body sections are seated for maintaining lateral positioning thereof -35 during molding.