CONDUCTOR TERMINAL AND METHOD OF ASSEMBLING A CONDUCTOR TERMINAL

Abstract

A conductor terminal with at least one spring force terminal connection for the connection of an electrical conductor via spring force clamping. The spring force terminal connection has a clamping spring. The conductor terminal has a housing and an actuating lever which is pivotably mounted in a pivoting plane in the housing for actuating the clamping spring. The actuating lever is formed with at least one clamping spring actuator element and at least one control element. The clamping spring actuator element actuates the clamping spring and the control element has at least one handle portion for manually actuating the actuating lever. The control element and the clamping spring actuator element have mutually corresponding fastening elements, via which the control element and the clamping spring actuator element are form-fittingly and/or force-fittingly connected to one another.

Claims

1. A conductor terminal comprising: at least one spring force terminal connection for connection of an electrical conductor via spring force clamping; a clamping spring; a housing; and an actuating lever that is pivotably mounted in the housing in a pivoting plane for actuating the clamping spring, the actuating lever being formed at least in two parts with at least one clamping spring actuator element and at least one control element, wherein the clamping spring actuator element has at least one actuating section to actuate the clamping spring, and the control element has at least one handle portion for manual operation of the actuating lever, and wherein the control element and the clamping spring actuator element comprise mutually corresponding fastening elements via which the control element and the clamping spring actuator element are mutually connected in a form-fitting and/or force-fitting manner and are fixed in position to each other at least in a pivoting plane of the actuating lever.

2. The conductor terminal according to claim 1, wherein the control element and the clamping spring actuator element are fixed in position to each other in a form-fitting and/or form-fitting connection via the mutually corresponding fastening elements in all spatial directions.

3. The conductor terminal according to claim 1, wherein the clamping spring actuator element has two spaced-apart bearing disks that are pivotably mounted on portions of the conductor terminal, and wherein the actuating section extends between the bearing disks.

4. The conductor terminal according to claim 3, wherein the bearing disks each have a part-circular outer contour.

5. The conductor terminal according to claim 1, wherein the bearing disks each have fastening elements which correspond with fastening elements of the control element so that the control element is connectable form-fittingly and/or force-fittingly with the bearing disks.

6. The conductor terminal according to claim 3, wherein a passage space is provided between the bearing disks for passing an electrical conductor through to a clamping point of the spring force terminal connection.

7. The conductor terminal according to claim 1, wherein the clamping spring actuator element is at least partially supported and/or mounted on a portion of the clamping spring.

8. The conductor terminal according to claim 1, wherein the form-fitting and/or force-fitting connection between the control element and the clamping spring actuator element is releasable or non-releasable.

9. The conductor terminal according to claim 1, wherein the conductor terminal is composed of a first and a second assembly module.

10. The conductor terminal according to claim 9, wherein the first assembly module has a first housing part of the housing of the conductor terminal, the clamping spring and the clamping spring actuator element.

11. The conductor terminal according to claim 9, wherein the second assembly module has a second housing part of the conductor terminal housing, a busbar and the control element.

12. A method for assembling a conductor terminal according to claim 1, the method comprising: providing a first assembly module; providing a second assembly module; and joining the first and second assembly module, wherein the control element and the clamping spring actuator element are form-fittingly and/or force-fittingly connected and are fixed in position to each other at least in the pivoting plane of the actuating lever.

13. A method according to claim 12, wherein the first assembly module is formed with the following steps: providing the first housing part; inserting the clamping spring (4) into the first housing part; deflecting the clamping leg of the clamping spring away from the contact leg of the clamping spring and inserting the clamping spring actuator element through a free space formed between the clamping leg and the contact leg into an area between the clamping leg and the contact leg; and if necessary, aligning the clamping spring actuator element into an assembly position in which the clamping spring actuator element is form-fittingly and/or force-fittingly connected to the control element.

14. The method according to claim 12, wherein the second assembly module is formed with the following steps: inserting the busbar into the second housing part, inserting the control element of the actuating lever into the actuation opening of the second housing part; and if necessary, aligning the control element into an assembly position in which the clamping spring actuator element is form-fittingly and/or force-fittingly connected to the control element.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0031] The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus, are not limitive of the present invention, and wherein:

[0032] FIGS. 1A and 1B show an actuating lever in different perspective views;

[0033] FIGS. 2A and 2B show an actuating lever in a perspective view and a sectional view;

[0034] FIG. 3 shows a conductor terminal in a perspective view;

[0035] FIG. 4 shows the conductor terminal according to FIG. 3 in a front view;

[0036] FIG. 5 shows a sectional side view of the conductor terminal according to FIGS. 3 and 4 in the sectional plane A-A illustrated in FIG. 4;

[0037] FIG. 6 shows a sectional side view of the conductor terminal according to FIGS. 3 and 4 in the sectional plane E-E illustrated in FIG. 4;

[0038] FIG. 7 shows a sectional side view of a first assembly module of the conductor terminal in the sectional plane A-A;

[0039] FIG. 8 shows a sectional side view of the first assembly module in the sectional plane E-E; and

[0040] FIG. 9 shows the first assembly module in a perspective view.

DETAILED DESCRIPTION

[0041] The actuating lever 5, 6 shown in FIG. 1 has a control element 5 and a clamping spring actuator element 6. The control element 5 and the clamping spring actuator element 6 are designed as separate components which can be joined to form the actuating lever 5, 6 by being locked together. For example, these components can be designed as individual plastic injection-molded components.

[0042] The control element 5 has a handle portion 50 on which the control element 5 or the entire actuating lever can be operated manually by a user. Two fastening arms 51, 52 extending at a distance from one another protrude laterally from the handle portion 50 and extend at an angle to the handle portion 50. The fastening arms 51, 52 can for example run parallel to one another. The fastening arms 51, 52 have respective fastening elements 54 of the control element 5 in the region of their free end, for example in the form of regions provided with latching tabs. Also, additional fixing pins 56 extend adjacent to the fastening elements 54 from the respective fastening arm 51, 52.

[0043] The clamping spring actuator element has two bearing disks 61, 62 spaced apart from one another. An actuating section 60, which is used to actuate a clamping spring 4 of a conductor terminal 1, extends between the bearing disks 61, 62. In the exemplary embodiment shown, the actuating section 60 bridges a space 63 formed between the bearing disks 61, 62. The space 63 forms a passage space for passing through an electrical conductor. The bearing disks 61, 62 have respective part-circular outer contours 65 with which they can be pivotably mounted on parts of the conductor terminal, so that the actuating lever 5, 6 moves essentially on a circular path during a pivoting movement. The outer contours 65 of the bearing disks 61, 62 can alternatively also have an eccentric contour, for example, so that the movement path of the actuating section 60 can be influenced in a targeted manner in terms of construction.

[0044] The bearing disks 61, 62 also have fastening elements 64 which are designed as counterparts to the fastening elements 54 of the control element 5. The fastening elements 64 are designed, for example, as recesses or grooves in the bearing disks 61, 62, so that the corresponding fastening elements 54 of the control element 5 can be inserted therein. For additional fixing of the control element 5 on the clamping spring actuator element 6, the bearing disks 61, 62 have recesses 66. With regard to their shape, the recesses 66 are designed as a counterpart to the fixing pins 56 of the control element 5. If the control element 5 is latched to the clamping spring actuator element 6 via the fastening elements 54, 64, the fixing pins 56 fully engage in the recesses 66. An outer contour 68 of the bearing disks 61, 62 facing the fastening arms 51, 52 then advantageously rests against an outer contour 57 of the fastening arms 51, 52 facing the bearing disks 61, 62, wherein the area of the outer contour 68 of the bearing disks 61, 62 can be larger in each case than the areas of the outer contour 57 of the fastening arms 51, 52. This has the advantage that the mutual contact of the outer contours 68 and 57 creates additional support for the transmission of forces during a pivoting movement of the actuating lever 5, 6.

[0045] FIG. 2 shows an alternative embodiment of an actuating lever 5, 6. Whereas in the embodiment of FIG. 1, the fastening elements 54, 64 have a latching effect and thus comprise the latch in the radial direction with respect to the part-circular outer contour 65 of the bearing disks, in the embodiment of FIG. 2, an axial direction of the latching is shown.

[0046] The control element 5 in turn comprises the handle portion 50 and the fastening arms 51, 52 protruding therefrom. The fastening elements 54 of the control element 5 present on the fastening arms 51, 52 in this case laterally project from the fastening arms, i.e. with respect to the pivoting plane of the actuating lever and the part-circular outer contour 65 of the bearing disks 61, 62, in the axial direction of a pivot axis. In the embodiment shown, the fastening elements 54 point away from one another, i.e. they are arranged on surfaces of the fastening arms 51, 52 pointing away from one another. One or both of the fastening elements 54 can also be on the opposite surface such that one or both of the fastening elements extend into the area between the fastening arms 51, 52.

[0047] The clamping spring actuator element 6 in turn has two bearing disks 61, 62, which are spaced apart from one another by a space 63. In this case, the actuating section 60 is designed in two parts, namely as a respective pin protruding from a bearing disk 61, 62 into the space 63, but it can alternatively also be designed in one piece as in the first exemplary embodiment. Correspondingly, in this embodiment the actuating lever 5, 6 is also designed in three parts, namely on the one hand with the control element 5 and on the other hand with the respective bearing disks 61, 62 with their portions of the actuating section 60, which are designed as separate components. Alternatively, the control element 5 can also be designed in two parts, namely with a dividing plane in the pivoting plane of the actuating lever, so that one part comprises the fastening arm 51 and the other part the fastening arm 52, with a respective half section of the handle portion 50 connecting to the respective fastening arms 51, 52.

[0048] The bearing disks 61, 62 in turn have fastening elements 64, which can be designed, for example, as recesses with a latching edge. If the fastening arms 51, 52 with their fastening elements 54 are inserted into these recesses, the fastening elements 54 snap into place behind the respective latching edges 67.

[0049] FIG. 3 shows a conductor terminal 1 with a housing 2 and an actuating lever, of which only the control element 5 can be seen in FIG. 3. The control element 5 extends through an actuation opening 24 of the housing 2 into the interior of the housing 2.

[0050] In the exemplary embodiment shown, the conductor terminal 1 has a plug-in section 20 which ends with a plug-in opening 29. In this way, the conductor terminal 1 can be designed as an electrical plug connector with a spring force terminal connection. The plug-in section 20 can be plugged together with the plug-in opening 29 using a connector assigned as a counterpart.

[0051] FIG. 4 shows the conductor terminal 1 in a front view of the plug-in section 20 and the plug-in opening 29. In FIG. 4, two sectional planes A-A and E-E are defined, on the basis of which the internal structure of the conductor terminal 1 is to be explained below. The section plane A-A goes through the plane of the fastening arm 51 and the bearing disk 61; the section plane E-E is a central section plane through the conductor terminal 1.

[0052] FIG. 5 shows the sectional view along the sectional plane A-A. As FIG. 5 shows, the housing 2 is designed in two parts with a main housing part 21 and a closure part 22. The closure part 22 is inserted into the main housing part 21 when the components which are explained below and arranged therein are installed. The main housing part 21 has the plug-in section 20. In addition, the main housing part 21 includes the actuation opening 24. As can be seen, the control element 5 extends through the actuation opening 24 to the clamping spring actuator element 6. In particular, the form-fitting connection between the fastening elements 54, 64 and, in addition, the support of the control element 5 via the fixing pins 56 inserted into the recesses 66 can be seen.

[0053] It can also be seen in FIG. 5 that the outer contour 68 facing the fastening arm 51, with its surface protruding from the outer contour 57 of the fastening arm 51, is supported at least in the illustrated closed position of the actuating lever 5, 6 on a protruding edge 25 located inside the main housing part 21. This advantageously ensures that the actuating lever 5, 6 cannot be removed or fall out of the housing 2 via the actuation opening 24.

[0054] The housing 2 has a conductor insertion opening 23 through which an electrical conductor can be inserted into the conductor terminal 1 in a conductor insertion direction L and can be fixed at a clamping point by means of spring force clamping. The conductor insertion opening 23 can, for example, be part of the closure part 22.

[0055] In the housing 2 there is a busbar 3 and a clamping spring 4, of which essentially a contact leg 41, a connecting section 40 and a spring arch 42 can be seen in the illustration in FIG. 5. The contact leg 41 is connected to the spring arch 42 via the connecting section 40.

[0056] Pursuant to the other sectional plane E-E, FIG. 6 shows further details of the clamping spring 4 and the busbar 3. It can be seen that the clamping spring 4 has a clamping leg 43 following the spring arch 42. The clamping leg 43 can be acted upon by the actuating section 60 and be deflected at a pivoting of the actuating lever 5, 6. As a result, the clamping leg 43 is moved away from the contact leg 41.

[0057] The busbar 3 has a conductor clamping section 30. The conductor clamping section 30 together with the clamping leg 43 forms a clamping point for clamping an electrical conductor. The busbar 3 extends from the conductor clamping section 30 over an intermediate area 31 to an electrical plug contact 32, which, for example, can be formed by fork tongues. The intermediate area 31 can also serve as a conductor stop to limit the insertion depth of an electrical conductor into the conductor terminal 1.

[0058] From the busbar 3, viewed in the conductor insertion direction L, in this embodiment two tabs 33 are bent laterally behind the bearing disks 61, 62 in the direction of the actuation opening 24, preferably at right angles. When viewed in the conductor insertion direction L, these tabs are aligned with the plane of the bearing disks 61, 62 and thus advantageously form a guide for the electrical conductor, in particular for stranded or finely stranded electrical conductors, which consist of a large number of individual strands.

[0059] The connecting section 40 can, for example, have an opening or recess through which an electrical conductor can be inserted through the conductor insertion opening 23 in the conductor insertion direction L and can be guided to the clamping point between the clamping leg 43 and the conductor clamping section 30. The busbar 3 can be narrow enough that it extends through the space 63 between the bearing disks 61, 62. The contact leg 41 can rest on the busbar 3 on the side of the busbar 3 facing away from the clamping leg 43.

[0060] It can also be seen that the conductor insertion opening 23 tapers in the interior of the closure part 22 in a funnel shape in the direction of the opening or the recess of the connecting section 40. The funnel-shaped tapering is designed in such a way that an area of the closure part 22 is arranged in front of the actuating section 60, as viewed in the conductor insertion direction L, so that the actuating section 60 is covered by a portion of the closure part 22 in the conductor insertion direction. The actuating section 60 thus advantageously does not represent an obstacle to the introduction of the electrical conductor.

[0061] FIGS. 7 to 9 each show the first assembly module of the conductor terminal 1. The first assembly module has the closure part 22 as the first housing part. The clamping spring 4 and the clamping spring actuator element 6 are already arranged in the closure part 22. The clamping spring actuator element 6 has been aligned in an assembly position in which the fastening element 64 and the recess 66 point in the direction of a space which is formed between the clamping leg 43 and the contact leg 41. Through this space, the control element 5, preceding its fastening element 54 and the fixing pin 56, can then be inserted into the fastening element 64 and the recess 66, whereby the at least form-fitting connection between the control element 5 and the clamping spring actuator element 6 is established. The clamping spring actuation element 6 is fixed in this first assembly module in that it is held between the clamping leg 43 and the contact leg 41 by the clamping spring 4 and is additionally supported by the connecting section 40.

[0062] The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are to be included within the scope of the following claims.