Stamped and formed contacts for a power connector

A power connector system according to the present invention includes a pin contact having two blades that are located parallel and opposed to each other and attached to each other by an U-shaped bridge. A socket contact is provided having two U-shaped cavities for receiving respectively the two blades. The U-shaped cavities may be formed by a single piece of material formed in a S or W shape or other shapes producing U-shaped cavities. A spring member is received within each U-shaped cavity of the socket connector to provide a frictional fit when the blade is received in the spring member. The pin connector, socket connector and spring member may be stamped and formed from a flat conductive material.

FIELD OF THE INVENTION 
This invention relates to power connectors, and more particularly to the 
design and manufacture of contacts for power connectors. 
BACKGROUND OF THE INVENTION 
Most existing power contacts that have been utilized in connectors are 
produced by a machining process because the contacts are made of a solid 
brass rod. Machining contacts increases the cost and complicates 
automation and mass production of power connectors. 
The present invention provides advantages over the prior art. 
SUMMARY OF THE INVENTION 
A power connector system according to the present invention includes a pin 
contact having two blades that are located parallel and opposed to each 
other and attached to each other by an U-shaped bridge. A socket contact 
is provided having two U-shaped cavities, each for receiving one of the 
two blades. The U-shaped cavities may be formed by a single piece of 
material formed in a S or W shape or other shapes that U-shaped cavities. 
A spring member is received within each U-shaped cavity of the socket 
connector to provide a frictional fit when the blade is received in the 
cavity and spring member. The pin connector, socket connector and spring 
member each may be stamped and formed from a single piece of flat 
electrically conductive material. 
These and other objects, features and advantages of the present invention 
will become apparent from the following brief description of the drawings, 
detailed description and appended claims and drawings.

DETAILED DESCRIPTION 
FIG. 1 illustrates a power connector according to the present invention 
including a pin contact 10, a socket contact 12 and spring members 14 
received in the socket contact 12. The pin contact 10 is made from a 
single piece of stamped flat electrically conductive material and includes 
a termination end 16 for attachment to a wire 18. As shown in FIG. 1, the 
termination end 16 has a "F" crimp provided by a plurality of outwardly 
extending fingers 20 from a rectangular-shaped portion 22. The terminal 
end 16 may be designed to accommodate a variety of attachments such as a 
solderless wire crimp, bus bar, solder, etc., for attachment to a wire 18 
or cable. A transition section 24 extends from the terminal end and 
preferably has a rectangular shape that allows forming of the contact to 
the right angle for the "right angle" wire dressing, avoiding bending in 
the wire as commonly occurs in existing connectors of the prior art. 
"Right angle" wire dressing means that the cable is soldered and crimped 
into the contact crimp barrel and bent to a sharp ninety degree angle away 
from the center line of the contact. The pin contact has two blades 26, 28 
extending from the transition section 24 and connected together by a 
U-shaped bridge 30. 
The socket contact 12 is made from a single piece of stamped flat 
electrically conductive material and also has a termination end 32 for 
connection to a wire 34 or cable. The termination end of the socket 
contact may be of a variety of shapes as described for the termination end 
of the pin contact. As shown in FIG. 1, again the termination end for the 
socket contact has a "F" crimp shape formed by a plurality of outwardly 
extending fingers 36 extending from a rectangular-shaped head portion 38. 
The socket contact also has a transition section 40 which preferably has a 
rectangular shape as for the pin contact. Extending from the transition 
section 40 is a socket component 42. The socket component has defined 
therein two U-shaped cavities 44 and 46. As shown in FIG. 1, the U-shaped 
cavities are defined by a S-shaped socket component 42. The S-shaped 
socket component 42 includes a body portion 48 and two arms 50 and 52 
which extend outwardly in opposite directions from the body portion 48 of 
socket component. Notches 54 are formed in each arm 50 and 52 on both 
edges of the arm and at respective outer ends and a single notch 54 on the 
edge of body portion 48. 
The spring members 14 are each made from a single piece of conductive 
material with good spring characteristics. The spring member is formed 
into a U shape with three tabs 58, 60, 62, extending outwardly and 
perpendicular to the general surface of the spring member for retention 
inside one of the contact cavities 44, 46 and one tab 64 that lies 
parallel to the general surface. Each of the perpendicular tabs has a foot 
66 extending out from one end of the tab with a foot being free on three 
sides. Each foot 66 is bent to lock into a respective notch 54 formed in 
the arms 50, 52 and body portion 48 of the socket component 42 when the 
spring member 14 is placed in one of the cavities 44, 46. The spring 
member 14 has a plurality of cut-out windows 68 at a plurality of webs or 
strips 70 wherein a strip 70 separates adjacent windows 68. Each strip is 
connected to a flat base portion 72 of the spring member. The strip is 
twisted at an angle to the flat base portion 72 so that a portion of the 
strip extends outwardly from the flat base portion 72. The strips 70 
extending outwardly from the flat base portion 72 of the spring member 
provides electrical contact between the pin and socket connectors. 
FIG. 2 shows an alternative form of a socket component 42' wherein the body 
portion 48' of the socket component is folded one way and the arms 50', 
52' are folded in another way to provide a W-shaped socket component 
having two cavities 44', 46' defined therein. 
FIG. 3 illustrates a stamped flat single piece of electrically conductive 
material in a design from which the pin connector according to the present 
invention is formed. FIG. 4 illustrates a stamped flat single piece of 
electrically conductive material from which a socket connector 42 of FIG. 
1 according to the present invention is formed. 
FIG. 6 illustrates a stamped flat single piece of electrically conductive 
material from which a spring member according to the present invention is 
formed. 
FIG. 5 is a side sectional view of a spring member according to the present 
invention having strips 70 formed at an angle to a flat base portion 72 of 
the spring member 14.