Connection terminal and spring-loaded terminal contact therefor

Abstract

A spring-loaded terminal contact (3) for contacting electrical conductors having at least one busbar (7) and having at least one clamping spring (9) which has an abutment member (10), a clamping member (12) and a curved resilient member (11) which is arranged between the abutment member (10) and the clamping member (12) is described. The clamping member (12) extends in the direction toward the busbar (7) and has a resilient clamping edge (8) for clamping an electrical conductor which is introduced between the clamping member (12) and the busbar (7) in a conductor insertion direction (L). The busbar (7) has a clamping edge (6) which together with the resilient clamping edge (8) forms a clamping location for the electrical conductor which is intended to be clamped. The busbar (7) has a groove-like recess (14) in the conductor insertion direction (L) upstream of the clamping location adjacent to the clamping edge (6).

Claims

1. A spring-loaded terminal contact for contacting electrical conductors comprising: at least one busbar having a clamping edge; and at least one clamping spring having: an abutment member, a clamping member extending in a direction toward the busbar and having a resilient clamping edge for clamping an electrical conductor introduced between the clamping member and the busbar in a conductor insertion direction (L), and a curved resilient member arranged between the abutment member and the clamping member, wherein the clamping edge of the busbar and the resilient clamping edge of the clamping member together form a clamping location for an electrical conductor to be clamped; and wherein the busbar has a groove-like recess in the conductor insertion direction (L) upstream of the clamping location adjacent to the clamping edge, with the clamping edge extending transversely to the conductor insertion direction and forming the front end of the groove-like recess.

2. The spring-loaded terminal contact as claimed in claim 1, characterized in that the busbar extends transversely relative to the conductor insertion direction (L) and a plurality of groove-like recesses which extend parallel with each other are arranged beside each other on the busbar, wherein a clamping spring is associated with each groove-like recess.

3. The spring-loaded terminal contact as claimed in claim 1, characterized in that the groove-like recess is stamped in the busbar.

4. The spring-loaded terminal contact as claimed in claim 3, characterized in that the groove-like recess is coined or embossed.

5. The spring-loaded terminal contact as claimed in claim 1, characterized in that there is arranged in the conductor insertion direction (L) downstream of the clamping location a retention flap which extends away from the busbar plane, wherein the clamping spring is suspended in the retention flap with the abutment member thereof with spacing from the busbar plane.

6. The spring-loaded terminal contact as claimed in claim 5, characterized in that the retention flap is constructed integrally with the busbar.

7. The spring-loaded terminal contact as claimed in claim 5, characterized in that the retention flap is constructed as a component which is separate from the busbar.

8. The spring-loaded terminal contact as claimed in claim 5, characterized in that the busbar extends transversely relative to the conductor insertion direction (L) and a plurality of groove-like recesses which extend parallel with each other are arranged beside each other on the busbar, wherein a clamping spring is associated with each groove-like recess and wherein a retention flap is provided for each clamping spring, respectively, and the retention flaps are arranged spaced apart from each other with an intermediate space being formed.

9. A connection terminal for electrical conductors having an insulating material housing which has at least one conductor introduction opening for introducing an electrical conductor, characterized in that at least one spring-loaded terminal contact as claimed in claim 1 is integrated in the insulating material housing.

10. The connection terminal as claimed in claim 9, characterized in that at least one pivotably supported actuation lever is integrated in the insulating material housing, wherein the actuation lever has an actuation portion which cooperates with the clamping member of at least one associated clamping spring in order to open the clamping location when the actuation lever is pivoted.

Description

(1) The invention is explained in greater detail below with reference to an embodiment with the appended drawings, in which:

(2) FIG. 1 is a perspective sectioned view of a connection terminal;

(3) FIG. 2 is a lateral sectioned view of the spring-loaded terminal contact of the connection terminal from FIG. 1;

(4) FIG. 3 is a side view of the spring-loaded terminal contact from FIG. 2;

(5) FIG. 4 is a perspective view of the spring-loaded terminal contact from FIGS. 2 and 3;

(6) FIG. 5 is a perspective sectioned view of the spring-loaded terminal contact from FIG. 4;

(7) FIG. 6 is a perspective sectioned view of the spring-loaded terminal contact from FIG. 4 with an actuation lever;

(8) FIG. 7 is a perspective view of the spring-loaded terminal contact from FIG. 5 with an actuation lever.

(9) FIG. 1 is a perspective sectioned view of a connection terminal 1 which has an insulating material housing 2 and a spring-loaded terminal contact 3 integrated therein. Furthermore, pivotably supported actuation levers 4 are integrated in the insulating material housing 2. The insulating material housing 2 has a plurality of conductor introduction openings 5 which are arranged beside each other and which extend parallel with each other and which lead to a terminal location for clamping an electrical conductor which is inserted in the conductor insertion direction L. The clamping location is formed by means of a clamping edge 6 of a busbar 7 which extends transversely relative to the conductor insertion direction and a resilient clamping edge 8 of a respective clamping spring 9. The clamping spring 9 is constructed as a leg spring and has an abutment member 10, a curved resilient member 11 which is adjacent thereto and a clamping member 12 opposite the abutment member 10. The curved resilient member 11 consequently connects the abutment member 10 and the clamping member 12 to each other. It is evident that the clamping member 12 optionally after a plurality of bending portions has the resilient clamping edge 8 at the free end and extends as far as the plane of the busbar 7.

(10) It can further be seen that the abutment member 10 of the clamping spring 9 is suspended in a retention flap 13 which is connected to the busbar 7 and supported at that location. Consequently, a self-supporting spring-loaded terminal contact 3 is produced in which the forces which occur when an electrical conductor is clamped using the clamping force of the clamping spring 9 are transmitted to the insulating material housing 2 only in an insignificant manner.

(11) At the upper side of the busbar 3 which faces the clamping spring 9 and in particular the clamping member 12, there is introduced a groove-like recess 14 which is arranged when viewed in the conductor insertion direction L upstream of the clamping location and the clamping edge 6 of the busbar 3. The groove-like recess extends in this instance in the conductor insertion direction L parallel with the extent direction of the abutment member 10 and the clamping member 12, which direction is illustrated in the busbar plane. As a result of the groove-like recess 14, the clamping edge 6 when viewed in the conductor insertion direction L is released upstream of the clamping edge 6. The groove-like recess 14 with the side walls 17 thereof additionally provides an introduction channel for the free end of an electrical conductor which is intended to be clamped.

(12) It can further be seen that the actuation levers 4 are pivotably supported with a part-circular bearing portion 15 adjacent to the clamping spring 9 in the insulating material housing 2. The part-circular bearing portion 15 is in this instance supported and guided on the outer periphery thereof in the insulating material housing. The conductor introduction opening 5 merges in this instance into the part-circular bearing portion 15 whose outer side also forms a portion of the conductor introduction opening 5 and leads an electrical conductor to the clamping location and into a conductor receiving pocket 16 which is provided behind the clamping location in the insulating material housing 2.

(13) It can further be seen that the groove-like recess 14 merges with the side wall 17 thereof into the face of the part-circular bearing portion 15. The part-circular bearing portion 15 is arranged adjacent to the groove-like recess 14.

(14) Optionally, the insulating material housing 2 has at the front side adjacent to a conductor introduction opening 5 an examination opening 18 which leads to the spring-loaded terminal contact 3. Consequently, using a testing pin which is introduced into the examination opening 18, it is possible to measure whether there is electrical potential at the spring-loaded terminal contact 3.

(15) It can further be seen that the insulating material housing 2 is constructed in two parts with a base member 19 and a rear catch cover 20. The base member 19 has the conductor introduction openings 5. With the catch cover 20 open, the spring-loaded terminal contact 3 and the actuation levers 4 are inserted into the base member 19. Subsequently, the base member 19 is closed with the catch cover 20 at the rear side diagonally opposite the conductor introduction openings 5. In this instance, the catch cover 20 is engaged on the base member 19 using suitable catch elements.

(16) In the upper rear region of the insulating material housing 2, the catch cover 20 engages with the base member 19 using at least one resilient catch arm 30 which is formed from insulating material and which extends in the conductor insertion direction L and adjoins the upper covering plate of the base member 19 in an integral manner. In the unloaded state, the resilient catch arm 30 is planar per se and not as illustrated bent over in the direction toward the free end. At the free end of the at least one catch arm 30 there protrudes a catch projection or a catch web 31 which cooperates and engages with a corresponding stop 32 on a transverse web 33 of the catch cover 20.

(17) It can be seen that the catch cover 20 with a spacing opposite the transverse web 33 has a raised web 34 such that the at least one catch arm 30 is guided between the raised web 34 and the transverse web 33 and is then redirected downward away from the transverse web 33 by the stop 32 which is located behind the raised web 34 and which extends in the direction of the portion of the catch cover 20 which carries the raised web 34. The at least one resilient arm 31 is thereby bent at the free end region so that the catch projection 31 is securely retained by the flexible resilience of the resilient arm 30 behind the stop 32. Using the upstream raised web 34, it is consequently possible for the resilient arm 30 to be tensioned in the catch position on the transverse web 33.

(18) FIG. 2 is a lateral sectioned view of the spring-loaded terminal contact 3 for the connection terminal 1 from FIG. 1. This spring-loaded terminal contact 3 forms a contact insert and has a busbar 7 from which retention flaps 13 which are formed integrally with the busbar 7 protrude. It can be seen that the abutment member 10 of the clamping spring 9 is suspended in a transverse web 21 of the retention flaps 13.

(19) It can be seen that, from the surface of the busbar 7 which faces toward the clamping spring 9, a groove-like recess 14 is stamped. This groove-like recess 14 is in this instance coined in such a manner that in the region of the groove-like recess 14 a portion of the material of the busbar 7 is pressed out from the lower plane of the busbar 7. The groove-like recess 14 has side walls 17 and an inclined face 22 which extends in the direction toward the clamping edge 6.

(20) FIG. 3 shows a side view of the spring-loaded terminal contact 3 from FIG. 2. In this instance, it can be seen that the groove-like recess 14 is stamped from the upper side of the busbar 7 which faces the clamping spring 9 with a material portion 23 which protrudes below the lower busbar plane being formed. It can further be seen that the retention web 13 is bent away in an upward direction from the busbar plane of the busbar 7, wherein the retention flap 13 has two lateral webs 24 which are connected to each other with the upper transverse web 21. In this manner, a conductor through-opening is formed in the retention flap 13 and the abutment member 10 can be suspended below the transverse web 21 in the retention flap 13.

(21) FIG. 4 is a perspective view of the spring-loaded terminal contact 3 from FIG. 3. In this instance, it can be seen that the busbar 7 extends transversely relative to the conductor insertion direction L and a plurality of groove-like recesses 14 are arranged beside each other. In this instance, the groove-like recesses 14 extend in the conductor insertion direction L, wherein a clamping spring 9 is associated with each groove-like recess 14.

(22) In this manner, a plurality of clamping locations for electrical conductors are provided beside each other, wherein the electrical conductors can be connected to each other in an electrically conductive manner by means of the common busbar 7.

(23) It can further be seen that, when viewed in the conductor insertion direction L downstream of the respective clamping location which is formed by a spring clamping edge 8 of the associated clamping spring 9 and the clamping edge 6 of the busbar 7, for each clamping spring 9 a retention flap 13 is bent from the busbar 7. The retention flaps 13 are in this instance arranged spaced apart from each other with an intermediate space 25 being formed.

(24) It can further be seen that the clamping springs in the region of the clamping edge 8 of the clamping member 12 have a width which substantially corresponds to the width of the associated groove-like recess 14 (±10%).

(25) FIG. 5 is a perspective sectioned side view of the spring-loaded terminal connection from FIG. 4. In this instance, it can be seen that the abutment member 10 is suspended with a bending portion on the free end below the transverse web 21 of the associated retention flap 13.

(26) FIG. 6 is a perspective sectioned view of the spring-loaded terminal connection 3 from FIG. 5. In this instance, actuation levers 4 are additionally arranged in the intermediate space between two adjacent clamping springs 9. It can be seen in this instance that the part-circular bearing portion 15 of the pivotably supported actuation levers is supported on the upper side of the busbar 7 directly adjacent to the groove-like recess 14. In this instance, a separate actuation lever 4 is provided for each clamping spring 9.

(27) FIG. 7 is a perspective view of the spring-loaded terminal connection 3 from FIG. 6. It can be seen that the actuation levers 4 each have two part-circular bearing portions 15 which are spaced apart from each other by the intermediate groove-like recess 14 and which a respective arm portion 26 adjoins. At the upper side, the arm portions 26 are connected to each other by a transverse plate 27. The associated clamping spring 9 is in this instance introduced in the space which is surrounded by the arm portions 26 and the transverse plate 27. The actuation levers 4 are in this manner constructed in a very stable and space-saving manner and contribute with the part-circular bearing portions 15 to guiding the electrical conductor.