Printed circuit board and outrigger edge connector assembly and method of assembling the same

An outrigger electrical connector includes a housing and electrical contacts. The housing is adapted to be fixedly connected to a side of a daughter printed circuit board between two rows of contact pads at a card edge connection area of the daughter printed circuit board. The housing has a downwardly extending ledge laterally spaced from the first side. The contacts have a top portion at a top of the housing at the housing first side and a bottom contact portion extending down along the housing ledge.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to electrical connectors and, more 
particularly, to an outrigger edge connector for use in connecting a 
daughter printed circuit board to a mother printed circuit board. 
2. Prior Art 
U.S. Pat. No. 4,932,888 to Senor discloses an electrical connector with a 
second housing that partially fits inside a first housing and has fingers 
to contact a side of a printed circuit board. U.S. Pat. No. 4,806,110 to 
Lindeman discloses a circuit board assembly with a connector fixedly 
attached to a circuit board. U.K. Patent Application 2163305 to Teradyne 
Inc. discloses an upper daughter board connector element fixedly connected 
to a daughter board that is inserted into a lower backplane connector 
element. U.S. Pat. No. 4,392,700 to Showman et al. discloses a cam 
actuated zero insertion force connector with a plug connector mounted on 
an edge of a daughter board that is inserted into a receptacle assembly. 
U.S. Pat. No. 4,869,672 to Andrews Jr. discloses a dual purpose card edge 
connector that can receive either of two different types of printed 
circuit boards. Other relevant art includes U.S. Pat. Nos. 4,981,449; 
4,907,975; 5,024,609; 4,298,237; 4,996,766; and 4,934,961. 
Problems exists in the art in that there is a need for a new system and 
method for connecting a daughter printed circuit board to a mother printed 
circuit board that has a relatively large number of contacts, can accept 
different types of daughter printed circuit boards, can be connected with 
different types of edge card socket connectors, and can do so in a limited 
amount of space. 
SUMMARY OF THE INVENTION 
The foregoing problems are overcome and other advantages are provided by a 
new and improved printed circuit board and outrigger edge connector 
assembly and method of assembling the same. 
In accordance with one embodiment of the present invention, an outrigger 
connector for use with a daughter printed circuit board having a card edge 
connection area is provided. The outrigger connector generally comprises a 
housing and at least one electrical contact connected to the housing. The 
housing is comprised of a dielectric material and has a first side adapted 
to be fixedly connected to a side of the daughter printed circuit board 
between two rows of contact pads at the card edge connection area. The 
housing has a downwardly extending ledge laterally spaced from the first 
side. The electrical contact includes a top contact portion at a top of 
the housing at the housing first side and a bottom contact portion 
extending down along the housing ledge. 
In accordance with another embodiment of the present invention, a daughter 
printed circuit board assembly is provided. The assembly comprises a first 
portion, a second portion, and means for connecting. The first portion has 
at least two rows of contact pads thereon. The second portion is fixedly 
connected to the first portion at an area above a bottom row of contact 
pads. The second portion has a housing and electrical contacts thereof. 
The means for connecting can connect at least some of the contact pads to 
either a first type of connector or a second type of connector. The means 
for connecting comprises an open area between a lower section of the first 
portion and a lower section of the second portion such that the lower 
section of the first portion can be received into a card edge receiving 
area of the first type of connector with the lower section of the second 
portion being located substantially outside of the first type of connector 
and, the lower sections of the first and second portions can both be 
received into card edge receiving areas of the second type of connector. 
In accordance with another embodiment of the present invention, a card edge 
connector is provided for making electrical connection between a mother 
printed circuit board and a daughter printed circuit board. The connector 
comprises a housing, and at least four rows of contacts connected to the 
housing. The housing is comprised of dielectric material and has at least 
three parallel rows of card edge receiving slots. The at least four rows 
of contacts includes two of the rows being located at a center slot of the 
card edge receiving slots and adapted to contact a portion of a daughter 
printed circuit board inserted into the center slot. 
In accordance with another embodiment of the present invention, a daughter 
printed circuit board assembly is provided. The assembly comprises a main 
body, and an outrigger. The main body has a card edge connection area. The 
outrigger is fixedly connected to the main body at the card edge 
connection area. The outrigger extends away from the main body and has a 
downwardly extending ledge parallel to, but spaced from, a bottom portion 
of the card edge connection area such that the contact areas on the bottom 
portion of the card edge connection area and contact areas on the ledge 
can make contact with a card edge connector in a substantially parallel 
simultaneously manner. 
In accordance with one method of the present invention, a method of 
assembling a printed circuit board and connector outrigger assembly is 
provided. The method comprises steps of providing a printed circuit board 
of the card edge connection type having a main body portion, the main body 
portion including a card edge connection area and two rows of contact pads 
thereon; providing a connector outrigger with a housing and electrical 
contacts thereon; and fixedly connecting the outrigger to the main body 
portion at the card edge connection area, the outrigger being located 
above a bottom row of the contact pads at the main body portion, extending 
outwardly from the main body portion, and having a ledge extending down 
and parallel to a bottom portion of the main body portion.

DETAILED DESCRIPTION OF THE INVENTION 
Referring to FIG. 1, there is shown an exploded perspective view of a 
system for making contact between a daughter printed circuit board and a 
mother printed circuit board. Although the present invention will be 
described with reference to the embodiments shown in the drawings, it 
should be understood that the present invention can be embodied in various 
different forms and embodiments. In addition, any suitable size, shape, or 
type of materials or elements can be used in various different types of 
embodiments of the invention. 
The system shown in FIG. 1 generally comprises a card edge connector 10, 
and outrigger connectors 12 to connect a daughter printed circuit board 14 
(of which only a card edge connection area 16 is shown) to a mother 
printed circuit board 18 (see FIG. 4). The outrigger connectors 12 are 
fixedly connected to the card edge connection area 16 to form an assembly 
20 as shown in FIG. 2. The daughter printed circuit board 14, in the 
embodiment shown, generally comprises two rows of contacts pads 22 on each 
side of the board 14; an upper row 24 and a lower row 26. The board 14 has 
slots 28 extending into the connection area 16 from its leading edge 30 
and holes 32 located above the slots 28. The slots 28 are generally used 
to polarize insertion of the edge 30 into connector 10 as is known in the 
art and help properly position the edge 30 in the connector 10 such that 
contacts in the connector 10 are properly connected to respective pads 24 
and 26 on the board 14. However, any suitable type of daughter board could 
be used as further understood from the description below. 
Referring particularly to FIGS. 1 and 2, the assembly 20, in the embodiment 
shown, includes four outrigger connectors 12. However, any suitable number 
of outrigger connectors 12 could be provided such as one, two, three, or 
more than four. In the embodiment shown, two types of outrigger connectors 
are provided; a first type 34 and a second type 36. However, only one 
type, or more than two types, could be provided. Each outrigger connector 
12 includes a housing 38 and a plurality of electrical contacts 40. The 
housings 38 are preferably comprised of a molded dielectric material. Each 
of the housings 38 include a first side 42 adapted to be positioned 
against a side of the daughter board 14 between the upper row of pads 24 
and the lower row of pads 26. The housings 38 each also have a middle 
section 44 that extends away from the first side 42 and a ledge 46 that 
extends down from the middle section 44. The ledges 46 are laterally 
offset from the first sides 42 as shown. Each middle section 44 include a 
row of contact channels 48 such that the contacts can be fixedly attached 
to the housings 38 therein. Each housing 38 also includes divider walls 50 
to help keep the contacts separated. The housings 38, in the embodiment 
shown, include blocks 52 at their ends and centers. The blocks 52 have 
holes 54 therein for receiving rivets 56. The first type of outrigger 
connectors 34, in the embodiment shown, have a pin section 58 extending 
from their first sides 42 at their center block 60. The second type of 
outrigger connectors 36 have holes 62 at their center block 60 for 
receiving the pin section 58. However, the pin sections 58 and the holes 
62 need not be provided. In addition, any or all of the blocks 60 could 
have pin sections 58 and holes 62. 
Each first side 42 of the housings 38 also include a preload section 64 
such that the contacts 40 can be preloaded or prestressed against preload 
section 64 prior to connection of the outrigger connectors 12 to the 
daughter board 14 to obtain good contact with upper pads 24 when 
connection is made. However, preloading of the contacts 40 need not be 
provided. The first sides 42 of the housings 38 also have ridges 68 
adapted to be located in the upper part of the daughter board slots 28. 
The daughter board 14 was originally designed to be inserted in a card 
edge receiving area having a single slot of a dual level card edge 
connector (not shown) having a larger height than the card edge connector 
10. Thus, the ridges 68 occupy the upper space of the slots 28 that would 
otherwise be empty when connected to connector 10. This allows for a good 
seat of the assembly 20 on the polarizing ridges 67. The leading edge of 
the ledges 46 also have notches 66 to accommodate polarizing/location 
ridges 67 in the card edge connector 10. 
The contacts 40 are generally comprised of an electrically conductive 
material, such as metal, and may have certain contact areas plated with 
good conductors, such as gold. Each contact has a center section 70, a 
bottom section 72, and a top section 74. Each center section 70 is fixedly 
connected to the housing 38 inside an individual contact channel 48. The 
bottom section 72 of each contact extends down along the outside 76 of 
ledge 46 and wraps partially around the bottom or leading edge of its 
ledge. However, in an alternate embodiment of the outrigger connectors, 
the contact bottom sections 72 could extend along the inside 78 of their 
ledges. In another alternate embodiment, the bottom section 72 need not 
wrap around the leading edge of the ledge. In one type of embodiment, 
suitable means can be provided to prevent movement of bottom sections 72 
on their ledges. The top sections 74 are preloaded against preload 
sections 64 and have a curved tip 80 for contacting upper row pads 24. 
However, as noted above, the contacts 40 need not be preloaded and, the 
tip 80 need not be curved. In an alternate embodiment of the invention 
alternative means other than spring surface contact between contacts 40 
and upper pads 24 could be provided, such as a through-hole contact. The 
top sections 74 are adapted to deflect in a spring contact fashion when 
the outrigger connector is attached to the daughter board 14. 
In order to form the assembly 20, in the embodiment shown, a first type of 
outrigger connector 34 and a second type of outrigger connector 36 are 
located on opposite sides of the daughter board 14. The pin section 58 is 
positioned into an upper hole 32 of the daughter board and hole 62 of the 
second type of outrigger connector 36. The two outrigger connectors are 
pressed towards each other, sandwiching a portion of the board 14 
therebetween. The rivets 56 are then inserted and attached to the 
outrigger connectors to fixedly and stationarily mount the two outrigger 
connectors on the sides of the daughter board 14. Of course, alternative 
or additional means for mounting the outrigger connectors to each other or 
the daughter board 14 could be provided. As can be seen in FIG. 2, with 
the outrigger connectors 12 attached to the daughter board 14, a space or 
open area 82 is formed on each side of the daughter board between a lower 
section of the daughter board 14 and a ledge 46. These open areas 82 are 
adapted to receive portions of card edge connectors such as a first type 
of connector 84 shown in FIG. 3 or the second type of connector 10 shown 
in FIG. 4. Of course, as described above, the daughter board 14 can be 
inserted into a third type of connector (not shown) when the outrigger 
connectors are not attached to the daughter board 14. 
Referring to FIG. 3, the assembly 20 is shown electrically and mechanically 
connected to the first type of card edge connector 84. A similar type of 
card edge connector is described in U.S. Pat. No. 5,041,023 which is 
incorporated by reference in its entirety. The connector 84 has a housing 
86 and two rows of spring contacts 88 that extend into a card edge 
receiving area 90 of the housing 86. The connector 84 is fixedly mounted 
to the mother board 18 and has solder tails 94 of the contacts 88 
electrically connected to the mother board 18. In an alternate embodiment, 
the solder tails may be provided as surface mount contact sections rather 
than the through-hole type shown. Connection of the assembly 20 to the 
connector 84 is substantially similar to connection of a daughter printed 
circuit board to the connector 84. 
The leading edge 30 of the daughter board 14 is merely inserted into 
receiving slot 90 and wedges the contacts 88 apart. However, in addition 
to having the leading edge 30 stop upon reaching the bottom of slot 90, 
the bottom of the outrigger connector housings 38, in the open areas 82, 
contact the top of the housing 86. This helps to stabilize the assembly 20 
on the first type of connector 84. As can be seen, the ledges 46 are 
located outside the connector 84. Therefore, although electrical 
connection is made between contacts 88 and the lower row of pads 26, 
electrical connection is not made between upper row of pads 24 and the 
first type of connector 84. However, the outrigger connectors 12 
nonetheless allow connection of daughter board 14 to the first type of 
connector 84. 
Referring to FIG. 4, the assembly 20 is shown electrically and mechanically 
connected to the second type of card edge connector 10. The second type of 
connector 10 has a housing 92 and spring contacts 94. The housing is 
preferably comprised of molded dielectric material and includes three 
slots 96, 97, 98. The center slot 97 is adapted to receive the lower 
portion of the daughter board 14. The other two slots 96 and 98 are 
adapted to receive the ledges 46. In the embodiment shown, the center slot 
97 and its spring contacts 94 are substantially identical to a CEE card 
edge connector also known as a MICRO CHANNEL connector. MICRO CHANNEL is a 
registered trademark of International Business Machines Corporation of 
Armonk, N.Y. However, the center slot 97 and its spring contacts can have 
any suitable configuration including extended industry standard 
architecture (EISA), industry standard architecture (ISA), or any suitable 
type of architecture. The slot 97 may also be adapted to receive a plug 
rather than a connection edge of a daughter board as further described 
below. The spring contacts 94 each include a solder tail section 100, a 
middle section 102, and a top section 104. The solder tail sections 100 
are electrically connected to the mother board 18. The middle sections 102 
are fixedly connected to the housing 92. The top sections 104 are adapted 
to be deflected by the daughter board 14 and ledges 46 when inserted in 
slots 96, 97, 98. In the embodiment shown, the center slot 97 has two rows 
of contacts 106, 107 on opposite sides of the slot 97 to contact both 
sides of the daughter board 14. The other two slots 96, 98 each have one 
row of contacts 108 and 109, respectively. The two outer rows of contacts 
108 and 109 are both adapted to make contact with the bottom sections 72 
of the contacts 40 when the ledges 46 are located in the slots 96 and 98. 
Since the contacts 40 are connected to the upper row of pads 24, and the 
contacts 94 are connected to the contacts 40 and the mother board 18, the 
upper row of pads 24 are thus connected to the mother board 18. 
Connection of the assembly 20 to the second type of connector 10 merely 
comprises inserting the ledges 46 and lower portion of the daughter board 
14 into the slots 96, 97, 98. This displaces or wedges the contacts 94 
from home positions to their connection positions shown in FIG. 4. 
Insertion is stopped by contact of the leading edges of the daughter board 
and ledges with the bottoms of their respective slots, contact of the 
ridges 42 (see FIG. 1) with polarizing ridges 67, and contact of outrigger 
connector stop surfaces 110 with the top surface of the connector 10. 
However, the outer stop surfaces 110 need not be provided. In the 
embodiment shown, the leading edge 30 of the daughter board 14 is longer 
than the ledges 46. This allows the center two rows of contacts 94 to be 
deflected prior to the outer two rows of contacts. This stepped method of 
deflection allows easier connection of the assembly 20 to the connector 
10. Center slot 97 is deeper than outer slots 96, 98 to accommodate the 
relatively longer daughter board lower section. However, in alternate 
embodiments, the slots 96-98 may have the same depth or, the center slot 
97 could have a shallower depth than the outer slots 96 and 98. Of course, 
the multistep method of deflection need not be provided either. In the 
embodiment shown, the lower level of contact pads 26 on the bottom portion 
of the card edge connection area and the contact areas on the ledges 46 
make electrical contact with the contacts 94 of the second type of card 
edge connector 10 in a substantially parallel simultaneous manner. 
Referring now to FIG. 5, there is shown an alternate embodiment of a card 
edge connector 112. In the embodiment shown, the connector 112 includes a 
housing 114 and four rows of contacts 116, 117, 118, 119. The housing 114 
is similar to the housing 92 shown in the embodiment in FIG. 4 in that it 
comprises three parallel slots 120, 121, 122 extending into the housing 
114 from its top. However, in the embodiment shown in FIG. 5, the right 
side slot 122 and its contact receiving area 124 are substantially the 
same as the left side of the housing 114, rather than being a mirror 
image. The right row of contacts 119 project towards the lateral right 
side 126 of the housing rather than towards the longitudinal center of the 
housing 114. This embodiment illustrates that the card edge connector 
contacts need not be solely biased towards the longitudinal center of the 
housing. Such a configuration would include the situation where the 
contacts 40 (see FIG. 2) of the outrigger connectors extended along the 
inside 78 of the ledges 46. However, any suitable type of configuration 
could be provided. In addition, the outer slots 120 and 122 need not have 
merely one row of contacts, but may each have two or more rows of 
contacts. The center slot 121 may also have more than two rows of 
contacts. 
Referring now to FIG. 6, there is shown an alternate embodiment of an 
outrigger connector 130. The connector 130 is substantially similar to 
connector 12 shown in FIG. 4. However, the connector housing 132 does not 
have an outer extension with a stop surface and, the connector 130 has 
contacts 134 and 135 that extend along both the inside and outside of the 
ledge 136. This type of outrigger connector can be used with a card edge 
connector having outer slots with two rows of contacts on opposite sides 
of the outer slot. 
Referring to FIG. 7, another alternate embodiment of the present invention 
is shown in a schematic view. The assembly 140 has a daughter board 14 
with a plug 142 attached to it. These types of plugs are generally known 
in the art as shown by U.S. Pat. No. 4,710,133. In the embodiment shown, 
the outrigger connectors 144 are connected to the plug 142. Thus, as can 
be seen, the outrigger connectors need not be connected directly to the 
daughter board. The plug 142 is fixedly connected to the main body 14 of 
the assembly 140 at its card edge connection area. The outrigger 
connectors 144 are fixedly connected to the plug connector 142 with ledges 
146 spaced from, but parallel to, the bottom portion 148 of the plug 
connector 142. 
Referring to FIG. 8, another alternate embodiment of the present invention 
is shown. In the embodiment shown, the outrigger connector 150 has a 
single housing 152 with three downward extending ledges 154 and a daughter 
board receiving slot 156. Contacts 158 extend along the outer ledges 154 
and contacts 160 extend along the inner ledge 154. Thus, even if it is 
desired to contact pads on both sides of a daughter board, only one 
outrigger connector need be necessary. 
Let it be understood that the foregoing description is only illustrative of 
the invention. Various alternatives and modifications can be devised by 
those skilled in the art without departing from the spirit of the 
invention. Accordingly, the present invention is intended to embrace all 
such alternatives, modifications and variances which fall within the scope 
of the appended claims.