Cable assembly with equalizer board

Abstract

An electrical cable assembly 1 comprising: a housing 2, electrical contacts 3 in the housing 2 connected to a circuit board 4, multiple conductors 5 of an electrical cable 6 connected to the circuit board 4, signal conditioning circuitry 7 on the circuit board 4, the circuitry 7 being interposed between the electrical contacts 3 and the conductors 5, and an insulating holder 8 mounted on the circuit board 4, the contacts 3 extending on the holder 8, and the holder 8 being mounted in a cavity in the housing 2.

Description

DETAILED DESCRIPTION

With reference to the FIGS. 1-3 an electrical cable assembly 1 comprises, a housing 2, electrical contacts 3 (see FIGS. 13-15) in the housing 2 connected to a circuit board 4, multiple conductors 5 of an electrical cable 6 connected to the circuit board 4, signal conditioning circuitry 7 on the circuit board 4, the circuitry 7 being interposed between the electrical contacts 3 and the conductors 5, and an insulating holder 8 (see FIGS. 9-12) mounted on the circuit board 4, the contacts 3 extending on the holder 8, and the holder 8 being mounted in a cavity 43 in the housing 2.

The circuit board 4 is of multi-layer circuit board construction, comprising: a flat insulating substrate 9 having an upper layer 10, a central layer 11 and a bottom layer 12 (see FIGS. 20-22). The central layer 11 is separated from the other layers 10, 12 by insulating material of the substrate 9.

The central layer 11 comprises, a conducting ground plane 13, referenced to electrical ground, with plating lined apertures 14 (also known as vias) extending through the central layer 11. These plating lined apertures 14 extend through the upper layer 10 and the bottom layer 12. In the apertures 14, the plating establishes electrical connections on the upper layer 10 and the lower layer 12 to the ground plane 13. Signal conditioning circuitry 7 on the upper layer 10 is in the form of multiple conducting pads 15, of square shape, and multiple relatively narrow circuit paths 16 interconnecting various conducting pads 15 and various plating lined apertures 14. Each of the pads 15 is identified with an impedance symbol, R or L or C to indicate electrical elements that provide signal conditioning, which satisfies requirements of industry technical standard documents, ANSI X3TI 1/FC-0, ANSI X3TII specification and ANSI X3T10.1 for a High Speed Serial Data Connector. The elements vary with cable construction, data rate and length of the cable assembly 1, and have the following typical values:

R1=75 Ohm R7=37 Ohm

R2=75 Ohm R8=75 Ohm

R3=150 Ohm L1=390 nH

R4=75 Ohm C1=33 pF

R5=37 Ohm C2=33 pF

R6=150 Ohm

The elements can be constructed of discrete or individual circuit elements, not shown, that are attached to the pads by a soldering operation. Alternatively, the impedances can be of planar microstrip construction fabricated by known microstrip making processes.

The upper layer 10 of the signal conditioning circuitry 7 further comprises, an array of three conducting pads 17 along an edge 18 of the circuit board 4 for connection to respective electrical contacts 3.

The lower or bottom layer 12 of the signal conditioning circuitry 7 comprises, an array of three conducting pads 17 along the edge 18 of the circuit board 4 for connection to respective electrical contacts 3, an array of six conducting pads 19 along another edge 20 of the circuit board 4 for connection to respective cable conductors 5, and electrical circuit paths 16 interconnecting various pads 19 and plating lined apertures 14. The cable conductors 5 can extend from separate electrical cables or can extend together from a single electrical cable 6 as shown (see FIG. 3).

Each of the electrical contacts 3 has a construction as shown (see FIGS. 13-15). Each contact 3 is stamped and formed from a strip of metal having a plane of thickness. Each contact 3 extends from a carrier strip 21, and is subsequently severed from the carrier strip 21. A side view (see FIG. 14) shows a plane of thickness of the contact 3 edgewise, with various bends 22 along the length of the contact 3.

An insulating holder 8 is of unitary molded construction. Projecting, tapered latch fingers 23 project from exterior ends 24 of the holder 8 (see FIGS. 9-10). A row of spaced apart passages 25 extend through a front end 26 and a rear end 27 of the holder 8 (see FIGS. 9-11). A recess 29 in the rear end 27 intercepts each of the passages 25. The passages 25 extend beside the recess 29 and communicate with the recess 29.

Each of the contacts 3 fits with a friction fit in any one of the passages 25. When the contacts 3 are mounted in respective passages 25, the contacts 3 extend through the holder 8 from front end 26 to the rear end 27. The contacts 3 project into the recess 29.

A front edge 30 of the circuit board 4 is received in the recess 29 with a friction fit (see FIG. 15). The holder 8 aligns respective contacts 3 with corresponding pads along the front edge. The rear ends of the contacts 3 project beyond the rear end of the holder 8 and overlie corresponding pads that also project beyond the rear end of the holder 8. Both the contacts 3 and the pads are exposed for visible inspection, and to effect joining of the contacts 3 with the pads. The contacts 3 can be joined to the overlaid pads by solder. For example, the pads can be coated with solder that has solidified prior to being overlaid by the contacts 3. The solder can be reflowed by the application of heat to join the contacts 3 and the pads. The joined pads and contacts 3 can be inspected visually for defective solder joints. The circuit board 4 is further held by the holder 8 for joining cable conductors 5 to the pads on the holder 8. As shown in FIG. 3 cable conductors 5 extend from one cable 6, or, alternatively, multiple cables, to respective pads 17 on both sides of the circuit board 4. The cable conductors 5 are joined by solder to the pads 19.

The housing 2 is of unitary construction, molded from an insulating material. A latch arm 31 is a cantilever beam joined at a front end 32 to a top side 33 of the housing 2 (see FIGS. 4-5). The latch arm 31 extends at an outward incline from the front end 32 toward the rear 34 of the housing 2. A front mating end 35 of the housing 2 has an opening 36 that opens laterally to a bottom side 37 of the housing 2 (see FIG. 6). Laterally beside the opening 36 a row of contact receiving channels 38 extend recessed along a tongue 39 on the housing 2. The channels 38 have narrower front portions 40 to receive the narrower tips 41 of the contacts 3 (see FIGS. 7 and 14). The opening 36 fully exposes the channels 38 through the bottom side 37, which enables inspection of the contacts 3 for proper registration along the channels 38. This advantage is particularly important when the contacts 3 have narrow tips 41 that are susceptible to damage.

In the interior of the housing 2, the channels 38 extend through a front wall 42 of a cavity 43. The cavity 43 has a width that extends across all of the channels 38. The width extends to opposite sides 44 of the housing 2. Circuit board receiving grooves 45 are recessed in the sides 44 of the housing 2, the grooves 45 opening into the cavity 43. Resiliently deflectable latch fingers 46 project into the cavity 43 and intercept the grooves 45. Each latch finger 46 is integral with a remainder of the housing 2. Each latch finger 46 is constructed by a slit 47 through the housing 2 along three sides of the finger 46, which defines the finger 46 as a resilient cantilever beam. A ramped projection 48 on each tip of the latch fingers 46 projects into the corresponding groove 45.

The grooves 45 and the cavity 43 extend through a rear 34 of the housing 2. A first window 50 provides an open bottom side 37 of the housing 2. The window 50 spans the width of the cavity 43 and communicates with the opening 36. The opening 36 exposes the interior of the housing 2 when the housing 2 is viewed from the bottom side 51. The opening 36 exposes the lengths of the channels 38 when the housing 2 is viewed from the bottom side 51. The first window 50 extends from the front wall 42 of the cavity 43 to the rear 49 of the housing 2. A second window 52 provides an open top side 53 of the housing 2. The second window 52 spans the width of the cavity 43, and extends through the rear 49 of the housing 2 and extends forwardly to an end wall 54. The second window 52 is shorter front to rear than the first window 50.

Assembly of the housing 2 with the circuit board 4, the holder 8 and the contacts 3 will now be described. The contacts 3 and the circuit board 4 have been mounted to the holder 8, as described herein. The contacts 3 project forwardly of the holder 8 and are aligned with corresponding channels 38, as the holder 8 is inserted into the rear of the housing 2. The projecting latch fingers 23 on the holder 8 are aligned with the grooves 45. The holder 8 is moved forwardly relative to the housing 2. The latch fingers 23 on the holder 8 slide forwardly along the grooves 45 to deflect outwardly the latch fingers 46 on the housing 2. Once the latch fingers 23 on the holder 8 pass the deflected latch fingers 46 on the housing 2, the latch fingers 46 on the housing 2 deflect resiliently and return to their prior positions, whereby they lock against the latch fingers 23 on the holder 8 to resist rearward movement of the holder 8. The front end 26 on the holder 8 faces the front wall 42 on the housing 2 to resist movement farther forward. The contacts 3 are moved forwardly into and along respective channels 38. The connections of the contacts 3 and the cable conductors 5 with the circuit board 4 are visible for inspection through the respective windows 50, 52. The conductive pads 17, 19 on the circuit board 4 face respective open sides of the housing 2. The contacts 3 and the conductors 5 of the cable 6 overlie respective conductive pads 17, 19 and are viewed through the open sides for registration of the contacts 3 with the pads 17, and for registration of the cable conductors 5. The circuit board 4 has its edges held in the grooves 45.

The circuit board 4 is held centrally in the housing 2 with spacious air gaps 55 on both sides of the circuit board 4. The air gaps 55 are sufficient to prevent electrical shorting to the unprotected circuit board 4 that is exposed by the windows 50, 52. A conductive shield 56 comprised of two, sheet metal shells 57, 57 that cover the windows 50, 52 and encircle the housing 2. Further details of the shield 56 and the shells 57, 57 are disclosed in U.S. patent application Ser. No. 08/008,926, filed Jan. 26, 1993, incorporated herein by reference. The shells 57,57 are identical, and extend rearwardly beyond the rear 49 of the housing 2. Channels 59 on a rear of both shells 57,57 encircle and enclose on an electrical cable 6, providing a strain relief 60 that grips the cable 6. The application of a tensile force on the cable 6 will be absorbed by the strain relief 60 to prevent a transfer of tensile force onto the connections of the cable conductors 5 and the circuit board 4.

An insulating overmold 61 covers the shield 56 and the cable 6. The overmold 61 is molded in situ to cover a rear of the shield 56 and to encircle the cable 6 and provide a bending strain relief 58.

An advantage of the invention resides in a cable assembly 1 having a housing 2 that is constructed for alignment of a circuit board 4 relative to electrical contacts 3 and multiple cable conductors 5, which improves the time expanded for performing connection of signal conditioning circuitry 7 with the contacts 3 and the cable conductors 5.

Claims

1. An electrical cable assembly comprising: multiple conductors of an electrical cable connected to circuitry on a circuit board, multiple electrical contacts in registration with respective conductive pads of the circuitry, an insulating holder holding the circuit board and the electrical contacts, an insulating housing receiving therein the holder and the electrical contacts and the circuit board, a window providing an open side of the housing, the contacts and the pads being exposed through the open side for inspection of the registration of the contacts with the pads.

2. An electrical cable assembly as recited in claim 1, and further comprising: a conductive shield encircling the housing and covering the window.

3. An electrical cable assembly as recited in claim 2 wherein, a strain relief on the shield grips the cable.

4. An electrical cable assembly as recited in claim 1, and further comprising: another window providing a second open side of the housing, the cable conductors and the circuitry being exposed through the second open side for inspection of connections of the cable conductors with the circuitry.

5. An electrical cable assembly as recited in claim 4, and further comprising: a conductive shield encircling the housing and covering both the window and said another window.

6. An electrical cable assembly as recited in claim 5 wherein, a strain relief on the shield grips the cable.

7. An electrical cable assembly as recited in claim 1 wherein, tips of the contacts project from the holder and extend into the housing.

8. An electrical cable assembly comprising: multiple electrical contacts and multiple conductors of an electrical cable connected to respective conductive pads of circuitry on a circuit board, an insulating holder holding the circuit board and the electrical contacts, an insulating housing receiving therein the holder and the electrical contacts, the circuit board being held in the housing, and windows in open sides of the housing exposing for inspection the contacts and the conductors overlying respective conductive pads of the circuitry.

9. An electrical cable assembly as recited in claim 8 wherein, the holder and the contacts and the circuit board are received along a cavity that extends to a rear of the housing, and the holder and the housing latch together to resist rearward movement of the holder.

10. An electrical cable assembly as recited in claim 8, and further comprising: a conductive shield encircling the housing and covering the windows.

11. An electrical cable assembly as recited in claim 8 wherein, tips of the contacts project from the holder and extend into the housing.

12. An electrical cable assembly comprising: multiple electrical contacts and multiple conductors of an electrical cable connected to respective conductive pads of circuitry on a circuit board, an insulating holder holding the circuit board and the electrical contacts, an insulating housing receiving therein the holder and the electrical contacts, the circuit board being held in the housing, a window providing an open side of the housing, the cable conductors and the circuitry being exposed through the open side for inspection of connections of the cable conductors with the circuitry.

13. An electrical cable assembly as recited in claim 12, and further comprising: a conductive shield encircling the housing and covering the window.

14. An electrical cable assembly as recited in claim 12 wherein, tips of the contacts project from the holder and extend into the housing.

15. A method for incorporating signal conditioning circuitry with a cable assembly, comprising:

providing signal conditioning circuitry for conditioning signals carried over an electrical cable for a high-speed serial data connector;

mounting the signal conditioning circuitry on a circuit board;

connecting electrical contacts to the circuit board in electrical communication with the signal conditioning circuitry;

connecting conductors of an electrical cable to the circuit board in electrical communication with the signal conditioning circuitry;

constructing a housing having opposite sides and a front mating end with an opening in the front mating end that opens laterally to a bottom side of the housing, said constructing step further comprising;

providing a cavity between the opposite sides of the housing; and

providing circuit board receiving grooves at a rear end of the housing and recessed in the opposite sides of the housing; and

inserting the circuit board containing the signal conditioning circuitry into the grooves at the rear end of the housing and sliding the circuit board forwardly along the grooves to align the circuit board and the electrical contacts with the opening in the front mating end.

16. The method of claim 15, further comprising:

constructing the signal conditioning circuitry from discrete circuit elements arranged in a configuration to satisfy industry technical standards requirements for high-speed serial data connections of at least one of the ANSI X3TI 1//FC-0 requirements, ANSI X3TII requirements and ANSI X3T10.1 requirement.

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17. The method of claim 15, further comprising:

providing, in the housing, a row of channels across the front mating end of the housing beside the opening, the row of channels being exposed through the bottom side of the housing; and

fully exposing the channels through the bottom side of the housing to enable inspection of the electrical contacts for proper registration along the channels.

18. The method of claim 15, further comprises:

providing, in the housing, a row of channels across the front mating end of the housing beside the opening, the row of channels being exposed through the bottom side of the housing.

19. The method of claim 15, further comprising:

encircling the housing with the conductive shield that covers the opening in the bottom of the housing.

20. The method of claim 15, further comprising:

introducing an insulated holder into the rear end of the housing, and sliding fingers on either side of the insulated holder along the circuit board receiving grooves toward a front wall of the housing.

21. The method of claim 15, further comprising:

mounting the electrical contacts in a holder with the electrical contacts projecting forwardly of the holder; and

inserting the holder into the rear end of the housing and moving the holder forward until tips of the electrical contacts align with corresponding portions of the front mating end of the housing.

22. The method of claim 15, further comprising:

inserting a holder holding the electrical contacts into the housing through the rear end of the housing.

23. The method of claim 15, further comprising:

inserting a holder holding the electrical contacts into the grooves at the rear end of the housing before inserting the circuit board into the grooves to position the holder between the circuit board and front mating end of the housing.

24. The method of claim 15, further comprising:

providing, in the housing, a row of channels across the front mating end of the housing beside the opening, the row of channels being exposed through the bottom side of the housing, wherein the channels extend along a tongue on the housing.

25. A method for incorporating signal conditioning circuitry with a cable assembly, comprising:

providing signal conditioning circuitry for conditioning signals carried over an electrical cable for a high-speed serial data connector;

mounting the signal conditioning circuitry on a circuit board;

connecting electrical contacts to the circuit board in electrical communication with the signal conditioning circuitry;

connecting conductors of an electrical cable to the circuit board in electrical communication with the signal conditioning circuitry;

constructing a housing having opposite sides and a front mating end with an opening in the front mating end that opens laterally to a bottom side of the housing, said constructing step further comprising:

providing, in the housing, a row of channels across the front mating end of the housing beside the opening, the row of channels being exposed through the opening in the bottom side of the housing; and

inserting the circuit board into the housing until tips of the electrical contacts align with tip receiving portions on the front mating end.