EP0307521B1

EP0307521B1 - Zero insertion force connector

Info

Publication number: EP0307521B1
Application number: EP87308136A
Authority: EP
Inventors: Fred Christian Sitzler
Original assignee: EI Du Pont de Nemours and Co
Current assignee: EIDP Inc
Priority date: 1987-09-15
Filing date: 1987-09-15
Publication date: 1993-03-17
Anticipated expiration: 2007-09-15
Also published as: DE3784932D1; EP0307521A1; ATE87131T1; DE3784932T4; DE3784932T2

Abstract

A zero insertion force connector for a printed circuit card has opposed rows of terminals (46,50) having normally spaced contacts (60) at the ends of outwardly bowed portions (44,48). Cams (14,15) and followers (36,40) are located beneath the bowed portions in positions where the followers can engage the bowed portions, engage the contacts with an inserted card and then stress the bowed portions, supplying contact normal force and contact wipe.

Description

This invention relates generally to electrical connectors and, more particularly, to connectors into which the edge of a printed circuit card can be inserted with zero insertion force.
It is known in the art that such connectors can be provided with cams and followers for spreading opposed rows of terminals when a card is to be inserted or removed. For example, cams for tensioning as well as spreading the terminals have been disclosed in U.S.-A-4,428,635. In this connector, all of the normal contact force must be supplied at the terminal block, thus requiring thick, costly material in the terminals to obtain that force. Also, the frictional force of the cam followers on the insides of the free ends of the cantilevered arms must be countered before a normal force is applied.
The above and other difficulties have been overcome in an edge card connector of the type having opposed rows of elongated terminals having spaced contacts at their free ends, a cam extending lengthwise of the rows and an elongated cam follower for each row of terminals. The followers are located outside the rows, beneath outwardly bowed portions in the lengths of the terminals, and are adapted to engage the bowed portions and move them into engagement with an inserted card. Then, the bowed portions are stressed to achieve a contact wipe. Shank portions of the terminals extend through a terminal block and present rows of projecting tails below the block adapted for connection to a circuit board. A connector of this type are disclosed in EP-A-0168922 and DE-A-2914167.
As is known from EP-A-0168922 the invention relates to a zero insertion force connector for connecting the edge of a printed circuit card to a circuit board; said connector comprising opposed rows of elongated terminals having shank portions which extend through a terminal block and present rows of projecting tails below the block adapted for connection to the circuit board, outwardly bowed portions above the block and contacts at their upper free ends;
cams extending lengthwise of said rows, one for each row of terminals;
an elongated cam follower for each row of terminals, each follower being positioned outside the rows and beneath the bowed portions of the terminals in one row and being adapted to engage the bowed portions when the follower is raised by the cam and to force the contacts in the two rows towards each other and into wiping contact with the edge of a printed circuit card placed between the rows;
and a housing enclosing the cam followers, the housing having side walls attached to the sides of the terminal block and having top and end walls which are slotted to receive the card, the cams being longitudinally movable within longitudinal channels defined by the rows of terminals, the housing and a top surface of terminal block.
In contrast to the prior art and in accordance with the invention a bar extends between the end walls of the housing beneath the slot in the top wall, the shank portions of the terminals being spaced slightly from said bar before the followers are raised but contacting the bar as the followers are raised, whereby first flexing of the terminals as the followers are raised is adjacent the terminal block but when the terminals contact the bar the bowed portions are stressed and the contacts at the free ends are brought into wiping contact with the card.
The invention may be understood more readily, and various other features and aspects of the invention may become apparent, from consideration of the following description.
An embodiment of the invention will now be described, by way of example only with reference to the accompanying drawings, wherein:-

Figure 1 is a perspective view of the edge card connector of the present invention.
Figure 2 is a schematic representation of the relationship between Figures 2A and 2B.
Figure 2A is a fragmentary side view of the connector shown in Figure 1, parts having been broken away and shown in section. The sections have been taken on irregular line 2A-2A in Figure 3.
Figure 2B is a similar view, the sections having been taken on line 2B-2B in Figure 4.
Figure 3 is a transverse, sectional view taken on line 3-3 in Figure 2A.
Figure 4 is a transverse, sectional view taken on line 4-4 in Figure 2B.
Figure 5 and 6 are side and end views of the long terminals shown in Figures 3 and 4.

Referring to Figure 1, the edge card connector is shown to include a housing 10 for a terminal block 12 and cams 14, 15. Housing 10 has openings 16 for detents 17 on terminal block 12. A handle 18 is pivotally attached at 19 to block 12 and has pin fitted into slots 20 in the cams. Handle 18 is grooved, as shown at 22, to receive one edge of a printed circuit card 24 when the handle is down to a horizontal position. From there, card 24 can be pushed laterally into an open-ended slot 26 in the top wall of housing 10 to the point where it is stopped by a pin 28 and another pin 30 on the card is seated in notches at the other end of housing 10. Then, cams 14,15 are moved to the positions shown in Fig. 1 by raising handle 18.
As shown in Figs. 2A and 2B, cam 14 has ramps 32 which coact with similarly but oppositely configured projections 34 on a cam follower 36 in housing 10. Fingers 38 on follower 36 limit the movements of cam 14 which movements raise and lower the follower. Follower 36 is shown in its lowered position in Fig. 2A and in the raised position in Fig. 2B.
Referring to Figs. 3 and 4, it will be seen that there is another follower 40 associated with cam 15. Thus, there are two rows of opposed terminals and an elongated follower located outside each row. At its top, each follower is recessed to present a comb-like array of thin blades 42 adapted to engage and stress bowed portions 44 of terminals 46 when followers 36,40 are raised from the position shown in Fig. 3 to the position shown in Fig. 4. Seats between the blades 42 engage and stress the bowed portions 48 of terminals 50. In each row, the bowed portions are at different levels, alternately high and low, with a high bowed portion 44 in one row opposite a low bowed portion 48 in the other row. The tops of blades 42 present high surfaces and the space between the blades present low surfaces positioned to engage the bowed portions of the terminals 46,50.
Within and extending from end wall to end wall of housing 10, there is a bar 51 beneath slot 26. As shown in Fig. 3, the shank portions of terminals 46 are spaced slightly from the bar 51. Thus, the first flexing of the terminals 46,50, when the followers are raised, is adjacent terminal block 12. When the terminals contact bar 51, the bowed portions 44,48 are then stressed and the contacts at the free ends are wiped as shown in Fig. 4.
Terminals 50 are relatively short and have straight shank portions 52 leading to solder tails 54. Although solder tails have been shown herein, other configurations such as wire wrap tails, pins or posts could be used. Longer terminals 46 have shank portions 56 bent outwardly (Figs. 3-5) to solder tails 58. Shank portions 52,56 are embedded in the molded terminal block 12 and tails 54,58 project therefrom. Tails 54,58 are adapted for placement in an apertured printed circuit board 59. At its opposite end, each terminal has a card-engaging contact 60 in the form of a coined dimple and is rounded to facilitate entry into the space between partitions 62 in housing 10 as the connector is assembled and as the contacts are spread. Blades 42 on followers 36,40 are also confined between the partitions to insure alignment with the bowed portions. In addition, they prevent longitudinal movement of the followers as they are raised and lowered by cams 14,15.
As best shown in Fig. 6, each long terminal 46 has its tail 58 offset laterally from shank portion 56. The short terminals 50 have similarly offset tails 54. From side-to-side of terminal block 12, the terminals in adjacent longitudinal rows have their tails offset longitudinally in opposite directions. Because of that feature and because of the outwardly extending shank portions 56 in the long terminals 46, there are four tails in each lateral row, i.e., for two rows of opposed terminals, there are four longitudinal rows of tails.
As shown in Figs. 1-4 cam followers 36,40 are enclosed within one-piece, non-moving housing having side walls attached to the sides of terminal block 12 and having top and end walls which are slotted to form slot 26 for the receipt of card 24. The end walls also have openings to accommodate longitudinal movement of cams 14,15 within the housing. As shown in Figs. 3 and 4 terminals 46,50 emerge from the top of terminal block 12 in two rows, and the cams 14,15 are longitudinally movable within longitudinal channels defined by the rows of terminals, the housing 10 and the top surface of the terminal block 12.

Claims

A zero insertion force connector for connecting the edge of a printed circuit card to a circuit board; said connector comprising opposed rows of elongated terminals (46, 50) having
(i) shank portions (56, 52) which extend through a terminal block (12) and present rows of projecting tails (54, 58) below the block (12) adapted for connection to the circuit board,

(ii) outwardly bowed portions (44, 48) above the block (12) and

(iii) contacts (60) at their upper free ends; cams (14, 15) extending lengthwise of said rows, one for each row of terminals;
an elongated cam follower (36, 40) for each row of terminals, each follower being positioned outside the rows and beneath the bowed portions (44, 48) of the terminals in one row and being adapted to engage said bowed portions when the follower (36, 40) is raised by the cam (14, 15) and to force the contacts in the two rows toward each other and into wiping contact with the edge of a printed circuit card placed between the rows
and a housing (10) enclosing the cam followers (36, 40), the housing having side walls attached to the sides of the terminal block (12) and having top and end walls which are slotted to receive the card, the cams being longitudinally movable within longitudinal channels defined by the rows of terminals, the housing and a top surface of terminal block,
characterised by a bar (51) which extends between the end walls of the housing beneath the slot in the top wall, the shank portions (56, 52) of the terminals being spaced slightly from said bar before the followers are raised but contacting the bar (51) as the followers (36, 40) are raised, whereby first flexing of the terminals as the followers are raised is adjacent the terminal block (12) but when the terminals contact the bar (51) the bowed portions (44, 48) are stressed and the contacts (60) at the free ends are brought into wiping contact with the card.
A connector according to Claim 1 wherein the terminal block (12) is a molded block and the shank portions (56, 52) of the terminals (46, 50) have offset portions which are embedded in the terminal block.
A connector according to Claim 1 or 2 wherein the cams (14, 15) have a series of ramps (32) on their upper surface which coact with similar but oppositely configured projections (34) on the lower surface of the followers (36, 40) whereby the followers move vertically as the ramp is moved longitudinally.
A connector according to any one of Claims 1 to 3 wherein the terminals (46, 50) in each row are of two different lengths, alternately long and short, and wherein the bowed portions (44, 48) in each row are at different levels, alternately high and low, with a high bowed portion in one row opposite a low bowed portion in the other row and wherein each follower (36, 40) has a top interrupted by recesses presenting high and lower surfaces positioned to engage the bowed portions (44, 48) of the terminals (46, 50).
A connector according to Claim 4 wherein the shank portions (56, 52) of the long terminals (46) within the terminal block (12) are bent outwardly so as to provide four longitudinal rows of tails (58), and wherein the terminals in adjacent longitudinal rows have their tails offset longitudinally in opposite directions so as to provide lateral rows of four tails each.