DE102008032267A1 - Connector, for two bare wires, has a housing with offset openings at the ends for the wires to be pushed in against a collector and be clamped against it by springs - Google Patents

Abstract

The wire push plug connector has a housing with a hollow interior and two wire insertion openings with their centers and longitudinal axes radially offset against each other. A collector (86) is fitted within the housing, with an upper (102) and a lower (104) surface in contact with the bare ends of the wires pushed into the openings. The ends of the wires are clamped against the surfaces by springs (98).

Description

The This application claims the benefit of the provisional U.S. Application Serial No. 60 / 948,585, filed on Jul. 9, 2007, the incorporated herein by reference.

The The present invention relates to indentation wire connectors. With push-in connectors, as already the name simply indicates the stripped ends of two or more wires or conductors pressed into a connector. Except pushing the wires into the connector are no operations for clamping, crimping, Bending, moving the insulation cover or other manipulations the connector required to connect what a push-in connector with regard to the required Time-consuming for the installation makes advantageous. Push-in connectors often have multiple task such as the electric Isolate the conductor from the environment, holding the Head in the connector and providing a good electrical Conductivity between the conductors meet.

The The task of electrical insulation is usually by a housing made of an electrically insulating material Fulfills. The housing generally has a hollow Interior on. About openings in the housing The stripped ends of two or more electrical Ladders are introduced into the interior. Within the Housing are the stripped ends of the ladder completely through Surround the insulating housing.

The The task of providing an electrical conductivity is fulfilled by an electrically conductive short-circuit element. The shorting element, often referred to as a busbar is disposed within the housing such that it connects to all the ladders plugged into the housing can be. The shorting member sees a conductive path between all inserted ladders. Because the primary task the busbar is to provide a conductivity, it is usually made of a conductive material such as copper or tinned copper. But also a very senior Busbar does not provide good conductivity when the conductors are not kept in firm contact with the busbar become. Therefore usually a spring member is provided, which cooperates with the busbar to hold the conductors firmly against to push the busbar. There are different arrangements of the Spring member possible, where it is integrated in the housing may be integrated in the busbar or as a separate Component be mounted in the interior of the housing can. In any case, the spring member pushes all conductors in a reliable mechanical and electrical connection with the shorting member.

The The task of holding the conductor in the housing is through a holding member is met, which is inserted against the ends of the Head presses and pulling out the ladder in the axial Direction out of the case prevented. As the spring member can Also, the holding member may be integrated in the housing. alternative For this purpose, the holding member and the spring member as a combined unit be configured in the housing. In In any case, the holding member holds the ladder and prevents accidentally pulling the conductors out of the housing. In some embodiments, the retaining member may be released so that the conductors are optionally removed from the housing can damage components without causing damage become. In other embodiments, it is desirable Under no circumstances should the conductors be removed from the connector can be so that the retaining member is not solvable is provided.

As mentioned above, the holding member is often in combination configured with the spring member to exert a force the inserted conductor into contact with the shorting member pushes and prevents withdrawal of the conductor. A usual Configuration sees an elastic metal retaining member with formed therein Spring fingers in front. When a conductor is plugged into the case presses it against a spring finger and flexes it a resting position out. By bending the spring finger is generates a compressive force against the conductor, which is the conductor in a reliable contact with the busbar presses. The spring finger is arranged at an angle to the impressions of the Head to allow the finger over in one direction, but pulling out the conductor in the opposite direction due to the self-locking configuration of the spring finger too prevention. Pressing the spring finger against the conductor So fulfills the two tasks of pressing the Conductor against the busbar and preventing pulling out of the conductor from the housing.

For the pressing of the conductor against the busbar of course, a stable structure is required, which withstands the compression force of the spring finger. A strong hold for the busbar may be provided by the spring member and / or the housing, where a problem may arise when the connector is used in conjunction with a stranded wire. Laced wires tend to flatten or spread when exposed to the compressive force of the spring finger. Because the compression and resistance forces of the spring finger are generated only at a bend of the spring fingers, reduced or a spread of the stranded wire lifts this bend, so that the two tasks of the spring finger are not met. The present invention addresses this problem.

Another problem with some conventional push-in wire connectors is that while they are configured to accommodate different numbers of wires, the connector housings are arranged to receive all the incoming wires from the same direction. In other words, the openings in the connector housings are all aligned in the same direction. When wires from other directions approach the connector, the ends of at least some of them must be bent 180 ° back so that the wire can be inserted into the connector. Therefore, additional time is required to install the connector. The U.S. Patent No. 6,132,238 gives an example of such a connector. The U.S. Patents No. 6,093,952 and 4,133,595 however, there are examples of connectors whose wire openings are oriented in different directions.

Other Problems with existing push-in connectors are given by the fact that they are relatively bulky. Therefore, they are difficult to install in tight spaces. There is also more material for the production required, which increases costs. A similar problem is given by the comparatively expensive metals that used in the connectors of the prior art. Some connectors contain complex contacts or connectors made of copper or similar materials. These contacts will be often by multiple bending or folding from blanks formed so that often several layers of material are superimposed. Even the blanks have complex shapes that punching require from a sheet, which in turn excessive Waste quantities are generated. For many of these contact structures Material is wasted, reducing the overall cost of the connector uselessly increased.

The The present invention provides a push-in wire connector with an improved housing, which consists of a left and a right housing part which is permanently connected to each other are. Each housing part has a unidirectional opening and a wire receiving box oriented in a different direction on. Each wire receiving box is with the wire opening the opposite housing part and thus in a different direction than the wire entrance opening arranged the housing part.

A Terminal arrangement is mounted in the housing. The connection arrangement includes a spring which is attached to a busbar. The feather has spring fingers on opposite sides of the busbar on. The spring fingers are aligned with a wire opening and push against plugged into the housing Conductor to press these into contact with the busbar. The busbar has an upper surface and a lower surface Surface up. The upper surface and the lower surface each define an entry edge, a trailing edge and at least one wire crossing axis extending from the leading edge extends to the trailing edge. The entry edges of the upper and the lower surface lie on opposite sides Sides of the busbar.

The through opposite openings in the connector incoming wires overlap one another to a to provide the shortest possible housing. The connection structure enables optimal use of metal materials, so that the cost of the connector are minimized. The busbar is at an angle of about 17 degrees to the axis the wire entrance openings arranged. The busbar is therefore partially located in the path of the wire and sees a projecting / angled surface in front, over the wire must go, with the spring member the wire against the projecting / angular surface presses.

1 Fig. 12 is a perspective view of the push-in connector of the present invention.

2 is a sectional view through the middle in the longitudinal direction of 1 ,

3 is a side view of the right housing part.

4 is a plan view of the right housing part.

5 is a bottom view of the right housing part.

6 is a right end view of the right housing part.

7 is a left end view of the right housing part.

8th is a sectional view taken along the line 8-8 of 6 ,

9 is a sectional view taken along the line 9-9 of 6 ,

10 is a sectional view taken along the line 10-10 of 6 ,

11 is a side view of the left housing part.

12 is a plan view of the left housing part.

13 is a bottom view of the left housing part.

14 is a right end view of the left housing part.

15 is a left end view of the left housing part.

16 is a sectional view taken along the line 16-16 of 14 ,

17 is a sectional view taken along the line 17-17 of 14 ,

18 is a sectional view taken along the line 18-18 of 14 ,

19 is a sectional view taken along the line 19-19 of 14 ,

20 is a perspective view of a terminal assembly.

21 is an end view of the terminal assembly of 20 ,

22 is a side view of the terminal assembly.

23 is a view along the line 23-23 of 22 ,

24 is a sectional view taken along the line 24-24 of 21 ,

25 is a perspective view of an alternative embodiment, that of 1 similar, but has six wire openings.

26 Figure 4 is a perspective view of another alternative embodiment showing a push-in connector with three poles and two openings for a circuit.

27 is a sectional view through one of the poles of the connector of 26 ,

28 is a perspective view of an alternative embodiment of a terminal assembly.

29 is a sectional view through the terminal assembly of 28 along the line 29-29 of 30 ,

30 is a side view of the busbar in the terminal assembly of 28 ,

31 is a plan view of the busbar of the terminal assembly of 28 ,

32 is a perspective view of an alternative embodiment of a housing part.

33 is an exploded perspective view of the housing part of 32 ,

34 is perspective view of another alternative embodiment of a housing part.

35 is an exploded perspective view of the housing part of 34 ,

36 is a side view of the housing part of 34 ,

1 shows the push-in connector 10 of the present invention. The push-in connector has a reference numeral 12 specified housing on. In this embodiment, the housing is formed of two parts and includes a right housing part 14 and a left housing part 16 , Each housing part has a unidirectional wire entry opening and a wire receiving box aligned in the other direction. A probe opening is formed adjacent to the wire entrance opening.

Details of the right housing part 14 are in 2 - 10 shown. As in 3 As shown, the housing part generally has a lower portion on the left side, which merges into a central portion, which in turn is connected to an upper portion on the right side. The lower section is defined by a generally U-shaped wall 18 educated. The wall 18 is at the middle section through locking openings 20A . 20B limited. The middle section includes a wire receiving box 22 that has an end wall 24 and a U-shaped guide wall 26 having. These walls define a hollow chamber which receives the end of a wire inserted into the connector. The guide wall 26 tilts like in 8th Slanted left down to guide an inserted wire into the box 22 to support. The left end of the guide wall 26 ends at an angular spring holding surface 28 , The upper surfaces of the guide wall form a pair of laterally spaced shoulders 30 , In 8th You can clearly see that the wire receiving box 22 in the figure opens to the left or aligned in this direction is.

As continues in 8th is shown above the guide wall 26 and next to the upper heels of the U-shaped wall 18 an S-shaped external flange 32 intended. This flange abuts against a corresponding flange of the left housing part, which will be explained below. The flange 32 merges into the upper section, which is a generally oval shell 34 includes. In the left end of the shell is a second spring retaining surface 36 provided what works best in 7 can be seen. The right end of the shell is through an end wall 38 covered. A wire entrance opening 40 is through a wire tube 42 Are defined. The inner end of the pipe 42 rejuvenates as in 8th shown and adjacent to a wire holding block 44 , The wire holding block is directly over the heels 30 intended. A test probe opening 46 is through a test tube 48 Are defined ( 6 ).

11 - 19 show details of the left housing part 16 , A main body part 50 has a wire receiving box 52 on, which protrudes from the body part upwards. The wire receiving box has an end wall 54 on ( 16 ). An arched butt piece 56 extends from the wire receiving box. An inner flange 58 is on the body part 50 and the bumper part 56 attached. The inner flange is slightly recessed from the outer edges of the body and the butt part, as best in 14 can be seen. The flange is as in the side view of 11 shown slightly S-shaped to the shape of the outer flange 32 correspond to. A curved edge 60 extends below the body part. Two arms 62 extend from the edge 60 Forward. The arms end in outward hooks 64 ,

When the housing parts are connected together, the inner flange fits 58 in the outer flange 32 the right housing part, wherein the outer flange abuts against the end surfaces of the abutting part and the body part. The edge 60 and the arms 62 fit in the U-shaped wall 18 the right case. The hooks 64 slip into the locking holes 20A . 20B to get into the ends of the wall 18 to intervene and hold the two housing parts together.

A U-shaped neckline 66 ( 15 ) is in an end wall 68 of the main body part defined. Directly above the clipping 66 is a wire entrance opening 70 provided, which extends through the main body part. The interior of the body has a tapered ring 72 on, which defines the inner end of the wire opening. The right end face of the ring defines a spring retention surface 74 , A wire holding block 76 is at the top of the tapered ring 72 attached. The wire holding block 76 , the upper part of the ring 72 , the wire storage box 52 and the end wall 54 define a hollow chamber that receives the end of a wire inserted into the connector. Under the internal flange are a central rib 78 and two angular spring retaining ribs 80 intended. Ribs 80 are with the paragraphs 82 connected. The heels and the wire holding block 76 support the positioning of the busbar, which is described below.

In 20 - 24 is a connection arrangement 84 shown. The connection arrangement comprises a busbar 86 resting on a spring link 88 is held. The spring member comprises a foot 90 at a first fold line with a first, upwardly directed leg 92 and at a second fold line with a second, downwardly directed leg 94 connected is. The foot has a pair of spaced bands 96 on. The bands have openings (not shown) to receive rivets of the busbar as described below. Every thigh 92 . 94 includes a U-shaped slot, which has a spring finger 98 Are defined. The spring finger is integrally connected at one end to the leg and has an opposite free end 100 on. As in 22 and 24 shown are the spring fingers 98 from the plane of the thighs 92 . 94 bent out. The free end 100 may also be disposed somewhat angled to the rest of the finger to provide an optimum angle for pressing against a wire inserted under the spring finger. The spring link 88 is preferably formed of an elastic material such as stainless steel.

The spring finger installed in the case 92 lies the wire entrance opening 40 opposite so that a plugged into the right housing part wire strikes the spring finger and moves it up when the wire enters the housing. The free end of the spring finger 92 pushes against the conductor, thereby preventing the conductor from being pulled out of the housing, and the conductor into a reliable connection with the upper surface of the busbar 86 is pressed. A spring finger 94 is similarly opposite the wire opening 70 arranged. One in the opening 70 the left housing part inserted wire meets spring fingers 94 and push it down. The free end of the spring finger 94 holds the conductor in the housing and presses it into connection with the lower surface of the busbar.

The following are details of the busbar 86 described. The busbar is a generally rectangular member of tinned copper. The busbar defines a thickness between an upper surface 102 and a lower surface 104 , It should be noted that the information "above" and "Bottom" is for illustrative purposes only and does not refer to the actual orientation of the installed busbar 86 further defines an entrance edge 106A , a trailing edge 108A and one the wire crossing axis 110A extending from the leading edge to the trailing edge. Under the leading edge is here to be understood the edge of the busbar, which is first crossed by a conductor entering the housing, while the exit edge is to be understood as the edge of the busbar that is crossed last by an incoming conductor. The wire extends along the wire crossing axis, due to the structure of the housing and the position of the bus bar in the housing. The lower surface of the busbar 86 accordingly defines an entry edge 106B , a trailing edge 108B and a wire crossing axis 110B extending from the leading edge to the trailing edge. It should be noted that the entry edges 106A . 106B lie on opposite sides of the busbar.

The busbar 86 is at the foot 90 of the spring member 88 by riveting 112 fastened, which extend into the openings of the foot described above. The rivets 112 on the upper surface 102 can be formed by bending a part of the busbar accordingly. It should be noted that other methods of securing the busbar to the spring member may be used, such as crimping, gluing, etc. Alternatively, the busbar may not be fixed to the spring at all. Instead, it can be held by the housing.

As in 22 and 24 shown, the bus bar has a wire receiving pocket 114 which extends under each surface and on each wire crossing axis. In addition, a Drahtdrückvorsprung extends 116 over each face on each of the wire crossing axes. The bags 114 and the projections 116 may be formed by embossing the busbar, creating a swap on one surface and a corresponding protrusion on the other surface of the busbar. As shown, the bags make up 114 and the projections 116 a snake-shaped path for the ladder, which must cover this over the surface of the busbar. This configuration supports the spring finger 98 keeping the wires in the case. The bags 114 surround the conductor at least partially on three sides to prevent spreading of a stranded wire. Further details of this construction are given in U.S. Patent Application Serial No. 11 / 763,096, filed Jul. 14, 2007, incorporated herein by reference.

2 shows the assembled connector and explains how the individual parts interact. As mentioned above, the outer flange fits 32 of the right housing part over the inner flange 58 of the left housing part and adjacent to the abutting part 56 and the body part 50 of the left housing part. The hooks 64 hold the two housing parts together. The spring link 88 is held fixed between the housing parts. The busbar 86 becomes lateral on the left side through the support block 76 and on the right side through the support block 44 held. The paragraphs 82 and 30 prevent upward or downward movement of the busbar. The upward leg 92 the spring member is between the spring retaining surface 36 of the right housing part and the spring retaining ribs 80 of the left housing part caught. The downward leg 94 is between the spring holding surface 28 the right housing part and the spring holding surface 74 of the left housing part caught.

The following describes the usage, operation and function of the connector. The stripped end of a wire is inserted into the wire entrance opening 40 of the right housing part introduced. It hits the spring finger 98 of the thigh 92 and pushes the finger upwards as it is inserted further into the housing. The end of the conductor finally enters the wire receiving box 52 of the left housing part, whereby it is anchored in position and spreading of a stranded wire is prevented. The stripped end of a second wire becomes the wire trap 70 introduced the left housing part. It hits the spring finger 98 of the thigh 94 and pushes the finger down as it is inserted further into the housing. The end of the conductor enters the wire receiving box 22 of the right housing part, whereby it is anchored in position and spreading of a stranded wire is prevented.

It should be noted that the wire entrance openings and the bus bar are arranged such that the bus bar is disposed at an angle of approximately 17 ° to the axes of the wire openings. That is, the busbar is disposed at an angle of about 17 degrees and therefore interferes with the path of movement of the wire by providing a protruding / angular surface over which the wire must pass while the spring member pushes the wire into the protruding / angular surface , This improves the holding force of the spring and the electrical contact between the busbar and the conductor. The busbar is between the bottom edge of the opening 40 and the tangential line to the top of the opening 70 arranged. Accordingly, the conductors contact the bus bar on opposite sides This allows efficient use of the bus bar material with the conductors overlapping each other to allow for a smaller length of housing. By the wire opening in a housing part and the receiving box are formed in the other housing part, a more compact construction of the housing can be provided. The structure of the housing also makes it possible to dispense with a cover for the rear ends, ie the wire input ends of the housing parts. The reason for this is that the connection arrangement is held between the housings, so that no separate holding cover is required.

25 shows a version with six openings of a push-in connector 118 for a circuit. The structure of the housing and the terminal is substantially identical to that of the previously described embodiment, but the devices are doubled to provide two additional wire openings in each housing and two additional spring fingers at the top and bottom of the spring member.

26 and 27 show a further alternative embodiment. This is a push-in connector 120 with three poles and two openings for a circuit. The construction of the poles is identical to that of the embodiment of FIG 1 , There is a left housing part 122 and a right housing part 124 intended. Each housing part has a wire inlet opening 126 and a wire receiving box 128 opposite to the wire inlet opening of the other housing part. The electrical connection 130 is largely identical to that of the terminal 84 , There are three separate connections 130 provided, each receiving two wires. This connector thus provides separate connections between three wire pairs. The poles are spaced apart at an angle of 120 ° in a plane transverse to the longitudinal axis. This arrangement allows the placement of three separate poles in a compact construction. Further details of the angled arrangement are described in U.S. Patent Application Serial No. 11 / 774,858 dated July 9, 2007, which is incorporated herein by reference.

28 and 29 show an alternative embodiment of an electrical connection arrangement 132 , This connection is the connection 84 but it differs in the relationship between the busbar and the spring. The connection arrangement 132 has a busbar 134 on that on a spring link 136 is held. The spring member comprises a foot 138 , with an upright thigh 140 and a downturned leg 142 connected is. The foot has a pair of spaced bands 144 on. A U-shaped slot in each leg defines a spring finger 146 , The spring finger has a free end 148 on.

The busbar 134 has an upper surface 150 and a lower surface 152 on. As before, the words "top" and "bottom" are used for illustrative purposes only. As in 30 and 31 shown, defines the top surface 150 the busbar 134 furthermore an entry edge 154A and a trailing edge 156A , Again, the leading edge is understood to mean the edge of the busbar that is first crossed by a conductor entering the housing part, while the trailing edge means the edge of the busbar that is crossed last by an incoming conductor. The lower surface of the busbar 152 accordingly defines an entry edge 154B and a trailing edge 156B , It should be noted that the entry edges 154A and 154B lie on opposite sides of the busbar.

The busbar 134 is at the foot 138 of the spring member 88 by riveting 158 fastened, which extend in openings in the foot.

As in 28 - 31 shown, the bus bar has a wire receiving pocket 160 which extends below each surface. In addition, a wire-pressing projection 162 provided extending over each surface. The bags 160 and the projections 162 may be formed by embossing the busbar, creating a pocket on one surface and a corresponding protrusion on the other surface. The pocket on one face is aligned with the projection on the other face to provide the faces generally symmetrical.

32 and 33 show an alternative embodiment of the housing. It is a two-part snap-in housing 164 , the general a construction as in 1 - 19 shown but has a different locking arrangement. There is a left housing part 166 and a right housing part 168 intended. The left housing part has an upper wire entry opening 170 and a wire receiving box 172 on. The right housing part has a wire inlet opening 174 and a wire receiving box 176 opposite the upper wire entry opening 170 of the other housing part. The wire entrance openings are oriented in opposite directions. The electrical connection 132 fits into the interior of the housing part. At the top of the left housing part is a locking plate 178 with an upward hook 180 intended. The plate fits through a latch 182 on the right housing part, so the hook 180 can be connected to the latch to zusammenzuhal the housing parts th. A corresponding locking plate 184 is provided near the left housing part, where it is fitted with a latch 186 can be connected to the lower side of the right housing part.

Another alternative embodiment of a housing is indicated by the reference numeral 188 in 34 - 36 specified. This housing is that of 1 - 19 similar in that it has an upper and a lower opening 190 . 192 and wire storage boxes 194 . 196 having. Instead of the snap-fit described above, the housing 188 however, an upper and a lower half of the housing 198 . 200. on that along connecting surfaces 202 are ultrasonically welded. This provides a particularly compact structure. The electrical connection 132 fits inside the case. As in 35 shown points the interior of the lower half of the housing. a seat 204 for holding the bus bar on a foot part of the terminal. paragraphs 206 between the seat 204 hold the downturned thigh 142 the feather 136 while a top wall 208 the upturned leg 140 holds. Similar surfaces in the upper case 198 serve to hold the connector in place.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• US 6132238 [0008]
• - US 6093952 [0008]
• - US 4133595 [0008]

Claims (21)

A push-in type wire connector comprising: a housing ( 12 ) having a hollow interior and at least a first and a second wire opening ( 40 . 70 ), can be inserted through the wire ends in the housing, wherein the wire openings ( 40 . 70 ) are aligned in opposite directions, wherein the centers of the first and the second wire openings ( 40 . 70 ) are radially spaced from each other, wherein the first and the second wire opening ( 40 . 70 ) each define a longitudinal axis, and a busbar ( 86 ), which has an upper surface ( 102 ) and a lower surface ( 104 ), the surfaces ( 102 . 104 ) each with the in the first and the second wire opening ( 40 . 70 ) inserted wires and wherein the busbar ( 86 ) in the interior of the housing ( 12 ) is mounted. Push-in wire connector according to claim 1, further characterized by a first spring member ( 98 ), which in the interior of the housing ( 12 ) and is configured to pass through the first wire opening ( 40 ) inserted wire end in a connection with the upper surface ( 102 ) of the busbar ( 86 ), and by a second spring member ( 98 ) mounted in the interior of the housing and configured to pass through the second wire opening (FIG. 70 ) inserted wire end in a connection with the lower surface ( 104 ) of the busbar ( 86 ). Push-in wire connector according to claim 2, characterized in that the first and the second spring member ( 98 ) are interconnected. Push-in wire connector according to claim 2, characterized in that at least one of the spring members ( 98 ) on the busbar ( 86 ) is attached. Push-in wire connector according to claim 1, characterized in that the upper and lower surfaces ( 102 . 104 ) of the busbar ( 86 ) each have a wire receiving pocket ( 114 ) and a Drahtdrückvorsprung ( 116 ) exhibit. Push-in wire connector according to claim 5, characterized in that the wire receiving pockets ( 114 ) and the wire press projections ( 116 ) of the upper and lower surfaces ( 102 . 104 ) by embossing in the busbar ( 86 ) are formed. Push-in wire connector according to claim 5, characterized in that at least a part of the wire receiving pocket ( 114 ) of the upper surface ( 102 ) the wire-pressing projection ( 116 ) of the lower surface ( 104 ) and at least part of the wire receiving pocket ( 114 ) of the lower surface ( 104 ) the wire-pressing projection ( 116 ) of the upper surface ( 102 ). Push-in wire connector according to claim 1, characterized in that the housing ( 12 ) a first test opening, which at a distance to the first wire opening ( 40 ) and extending in the same direction as this, and a second test opening, which is at a distance from the second wire opening ( 70 ) is arranged and extends in the same direction as this. Push-in wire connector according to claim 1, characterized in that the housing ( 12 ) a first wire receiving box ( 22 ) configured to receive a first wire end passing through the first wire opening (Fig. 40 ) into the connector ( 10 ), and a second wire receiving box ( 52 configured to receive a second wire end passing through the second wire opening (Fig. 70 ) into the connector ( 10 ) is inserted. Push-in wire connector according to claim 1, characterized in that a part of the upper surface ( 102 ) of the busbar ( 86 ) at an angle with respect to the longitudinal axis of the first wire opening ( 40 ), and a part of the lower surface ( 104 ) of the busbar ( 86 ) at an angle with respect to the longitudinal axis of the second wire opening ( 70 ). Terminal assembly for use in a push-in wire connector, comprising: a foot ( 90 ) having opposed first and second end portions and upper and lower surfaces, a first upright leg (FIG. 92 ) extending from the first end of the foot ( 90 ) extends in a first direction, and a second downwardly directed leg ( 94 ) extending from the second end of the foot ( 90 ) extends in a second direction, which is generally opposite to the first direction, wherein the first and the second leg ( 92 . 94 ) each have a spring member ( 98 ), a busbar ( 86 ) with the upper and lower surfaces of the foot ( 90 ), the busbar ( 86 ) an upper surface ( 102 ) and a lower surface ( 104 ), and a first spring member connecting a first wire end to a connection with the upper surface (Fig. 102 ) of the busbar ( 86 ), and a second spring member which couples a second wire end into communication with the lower surface (FIG. 104 ) of the busbar ( 86 ) presses. Connection arrangement according to claim 11, since characterized in that the upper surface ( 102 ) and the lower surface ( 104 ) of the busbar ( 86 ) each have a wire receiving pocket ( 114 ) and a Drahtdrückvorsprung ( 116 ). Connection arrangement according to claim 12, characterized in that the wire receiving pockets ( 114 ) and the wire press projections ( 116 ) of the upper and lower surfaces ( 102 . 104 ) in the busbar ( 86 ) are coined. Connection arrangement according to claim 13, characterized in that a part of the upper surface ( 102 ) of the busbar ( 86 ) at an angle with respect to the foot ( 90 ) and that part of the lower surface ( 104 ) of the busbar ( 86 ) at an angle with respect to the foot ( 90 ). Connection arrangement according to claim 12, characterized in that at least a part of the wire receiving pocket ( 114 ) of the upper surface ( 102 ) the wire-pressing projection ( 116 ) of the lower surface ( 104 ) and that at least a part of the wire receiving pocket ( 114 ) of the lower surface ( 104 ) the wire-pressing projection ( 116 ) of the upper surface ( 102 ). A push-in type wire connector comprising: a housing ( 188 ), which has at least one upper opening ( 190 ) and a lower opening ( 192 ), wherein the openings ( 190 . 192 ) each define an axis and wherein via the openings ( 190 . 192 ) Wire ends in the housing ( 188 ), wherein the axes of the openings are spaced from each other and wherein the upper and the lower opening ( 190 . 192 ) are oriented in opposite directions, a busbar ( 86 ), which in the interior of the housing ( 12 ) is mounted, wherein the busbar ( 86 ) an upper surface ( 102 ) and a lower surface ( 104 ), wherein the upper surface ( 102 ) a first leading edge ( 106A ) at the one in the upper opening ( 40 ) inserted wire first the upper surface ( 102 ) of the busbar ( 86 ), the lower surface ( 104 ) a second leading edge ( 106B ) defined at the one in the lower opening ( 70 ) inserted wire first the lower surface ( 104 ) of the busbar ( 86 ), wherein the first and the second leading edge ( 106A . 106B ) on opposite sides of the busbar ( 86 ), and a spring member in the interior of the housing ( 188 ) is mounted and an upwardly directed leg ( 92 ) in proximity to the first leading edge ( 106A ) and a downwardly directed leg ( 94 ) in the vicinity of the second leading edge ( 106B ), wherein the upwardly directed leg ( 92 ) a spring finger ( 98 ), which against one in the upper opening ( 40 ) inserted wire can be used to connect the wire in a connection with the upper surface ( 102 ) of the busbar ( 86 ) and with the downwardly directed leg ( 94 ) a spring finger ( 98 ), which against one in the second opening ( 70 ) inserted wire can be used to connect the wire in a connection with the lower surface ( 104 ) of the busbar ( 86 ). Push-in wire connector according to claim 16, characterized in that the busbar ( 86 ), one below the upper surface ( 102 ) extending wire receiving pocket ( 114 ), one above the upper surface ( 102 ) extending wire pushing projection ( 116 ), one under the lower surface ( 104 ) extending wire receiving pocket ( 114 ) and one above the lower surface ( 104 ) extending wire pushing projection ( 116 ). Push-in wire connector according to claim 17, characterized in that the wire receiving pocket ( 114 ) in the upper surface ( 102 ) above the wire-pressing projection ( 116 ) on the lower surface ( 104 ) and that the Drahtdrückvorsprung ( 116 ) on the upper surface ( 102 ) above the wire receiving pocket ( 114 ) in the lower surface ( 104 ) is located. A push-in type wire connector comprising: a housing ( 188 ) with at least one upper opening ( 190 ) and a lower opening ( 192 ), the openings ( 190 . 192 ) each define an axis and wherein via the openings ( 190 . 192 ) Wire ends in the housing ( 12 ), the axes of the openings ( 190 . 192 ) are spaced apart from each other and wherein the upper and the lower opening ( 190 . 192 ) are oriented in opposite directions, a busbar ( 86 ) fixed in the interior of the housing ( 188 ) is mounted, wherein the busbar ( 86 ) an upper surface ( 102 ) and a lower surface ( 104 formed by a first and a second edge on opposite sides of the busbar (FIG. 86 ), and a spring member having a foot attached to the bus bar ( 90 ) and an upwardly directed leg ( 92 ), which is attached to the foot ( 90 ) in the vicinity of the first edge of the busbar ( 86 ) and a downwardly directed leg ( 94 ), which is adjacent to the second edge of the busbar ( 86 ) is attached, wherein the upwardly directed leg ( 92 ) a spring finger ( 98 ) which can press against a wire inserted into one of the openings to connect the wire to a connection with the upper surface ( 102 ) of the busbar ( 86 ) and with the downwardly directed leg ( 94 ) a spring finger ( 98 ), which against one in the other opening plugged wire can push the wire into a connection with the bottom surface ( 104 ) of the busbar ( 86 ). Push-in wire connector according to claim 19, characterized in that the busbar ( 92 ), one below the upper surface ( 102 ) extending wire receiving pocket ( 114 ), one above the upper surface ( 102 ) extending wire pushing projection ( 116 ), one under the lower surface ( 104 ) extending wire receiving pocket ( 114 ) and one above the lower surface ( 104 ) extending wire pushing projection ( 116 ). Push-in wire connector according to claim 20, characterized in that the wire receiving pocket ( 114 ) in the upper surface ( 102 ) above the wire-pressing projection ( 116 ) on the lower surface ( 104 ) and the Drahtdrückvorsprung ( 116 ) on the upper surface ( 102 ) above the wire receiving pocket ( 114 ) in the lower surface ( 104 ) is located.