Electrical connectors with plate contacts form electrical connections with terminals which are inserted into cavities in the connectors and engage both sides of the plate contacts in the cavities. These types of terminals may be used in power distribution systems which handle high-voltage and high-amperage current. The outer edges of the plate contacts in the cavities are exposed at the cavity mouths before terminals are inserted.
It is desirable to prevent inadvertent contact with plate contacts in the connectors and avoid shocks and short circuits. Touch-safe standards require that electrical connectors prevent an object inserted into a cavity from engaging a plate contact.
A conventional connector has a plastic housing with a plastic rib overlying an end of a plate contact. The rib is not connected to the plate contact and can be displaced to permit contact with the plate contact. Deflectable plastic ribs do not meet touch-safe standards.
The disclosed electrical connector includes an insulating body, a plate in a cavity in the body where the body includes a guard overlying the end of the plate with a physical interlock connection between the guard and the end of the plate securing the guard on the plate against lateral deflection by a probe or object inserted into the cavity mouth. The interlock connection between the guard and the plate may include formed surfaces on the end of the plate and on the inwardly facing surface of the guard which secure the guard on the plate against lateral deflection.
Electrical connector assembly 10 includes two-part insulating body 12 with upper molded plastic body portion 14 and lower molded plastic body portion 16, and a pair of metal contacts 18. See
The upper molded plastic body portion 14 has opposed, parallel end walls 20 and opposed, parallel side walls 22. Center wall 24 extends across the center of the body between the end walls 20. Transverse wall 26 extends across the body between the side walls 22 and intersects center wall 24. Horizontal wall 28 extends between the end and side walls 22 and 24 and joins the center and transverse walls 24 and 26 to form four rectangular terminal cavities 30. Cavities 30 open on the exterior surface 32 of body portion 14 at mouths 34 at the top of the body. An integral plastic terminal guard or rib 36 extends across the center of the mouth of each terminal cavity 30. A lower extension 38 of transverse wall 26 below wall 28 extends between end walls 20 to form two side-by-side cavities 40 at the bottom of body 14.
Lower molded plastic body 16 includes two T-shaped contact receiving shells 50, shown in
Each metal contact 18 includes a flat metal contact plate having opposed contact sides 72. A socket terminal 74 is mounted on and extends downwardly from the bottom of each plate 70.
Assembly 10 is formed by inserting the two metal contacts 18 into terminal portions 52 and barrels 54 in body 16 so that the socket terminals 74 are fitted in barrels 54, and the lower portions of plates 70 are fitted in recesses 80 at the top of body 16. The upper portions of plates 70 extend above body 16.
Upper body 14 is lowered onto lower body 16 and contacts 18. The upper portion of each plate 70 extends through a slot in wall 28 and into two cavities 30 spaced on one side of body 14. Slots 82 extend between end walls 20 in the centers of cavities 30. The upper portions of plates 70 extend upwardly into and across the centers of the terminal cavities 30 as shown in
Each guard 36 extends across the open end of a cavity 30 at cavity mouth 34 and includes two angled interlock surfaces 84 and 86 spaced along the guard edge and facing into the cavity, away from mouth 34. Angled interlock surfaces 84 face toward one side of each cavity, and angled interlock surfaces 86 face toward the opposite side of the cavity. Each surface 84, 86 extends approximately half way across cavity 30.
The top edge of each contact plate 70 includes a pair of angled interlock surfaces 88 and 90 in each cavity 30. Surfaces 88 and 90 each extend approximately half way across each cavity 30. When the metal contacts 18 are inserted in body 16 and body 14 is mounted on the top of the sub-assembly, the angled interlock surfaces 88 and 90 engage angled interlock surfaces 84 and 86 on the inner edge of the guards 36 in each cavity 30, as illustrated in
Angled interlock surface 84 on guard 36 engages interlock surface 88 on plate 70 to prevent displacement of the guard 36 from the plate by a force 92 applied to the side of the guard away from interlock surface 84. See
Probe 96 engages guards 36 and exerts a force 92 on the guard tending to the move the guard away from plate 70. See
A probe may also be inserted into the mouth of the cavity to engage the opposite side of a guard 36 and exert a force 94 on the guard in the opposite direction, as shown in
Electrical connector assembly 10 may be used for forming electrical connections in a powerbus. A plurality of assemblies 10 may be spaced along the bus with pairs of conductor members joining adjacent assemblies. Each conductor member includes an elongate power conductor and terminals on the ends of the conductor. The terminals of two conductor members are inserted in cavities 30 on one side of assembly 10 and make electrical connections with the flat contact surfaces 72 on opposite sides of each contact plate 70. The plates 70 form portions of the elongate power conductors and connect the conductor members. Power from the conductor members is supplied to power consumers or suppliers through contacts inserted through openings 56 to engage socket terminals 74.
The terminals on the ends of the conductor member in the powerbus are inserted into cavities 30 past guards 36 and engage both contact surfaces 72 of plates 70. In order to protect the plates from inadvertent contact, the guards 36 have a minimum thickness substantially the same as the thickness of the plates 70. The guards are made of plastic and are somewhat flexible and, accordingly, may have a thickness somewhat greater than the thickness of the plate 70 to overlie the sides of the plates and provide additional protection against inadvertent contact. Insertion of the connectors on a powerbus over the guards deforms but does not permanently damage the guards.
Plates 70 may have a thickness of 1.00 mm. The guards may have a thickness or width of 1.00 mm or a greater thickness of 1.20 mm.
Engagement between the guards and plates at surfaces 84 and 88 and 86 and 90 form physical interlock connections 100 holding the guards on the upper ends of the plates against lateral deflection.
The angled interlock surfaces on the tops of plates 70 and on the inner edges of guards 36 extend at an angle 102 of 30° to the sides of the plate. The shallow 30° 102 provides an overlap distance 104 between the guard and plate greater than the thickness of the plate. The long overlap distance helps secure the guard on the plate when a deflecting force is applied to the guard.
In electrical connector assembly 10, the guards 36 are held on the tops of plates 70 by two spaced and angled connections at the surfaces 84 and 88 and 86 and 90 to form a physical interlock connection.
Other types of physical interlock connections may be used to secure the guards on the upper ends of the plates.
The physical connection 114 uses inter-engaging curved convex and concave surfaces 116 and 118. These surfaces need not be curved. For instance, the convex surface may be two surfaces which may intersect each other, and the concave surface may be two surfaces complimentary to the convex surface which may intersect each other and which engage the concave surfaces.
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Entry |
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Billman et al., US Patent Application for “Modular Electric Power Distribution System,” U.S. Appl. No. 13/836,074, filed Mar. 15, 2013. |
Number | Date | Country | |
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61901538 | Nov 2013 | US |