DE102015118033B4 - conductor terminal - Google Patents

Abstract

Conductor connection terminal (1) with an insulating material housing (2), with a spring-cage terminal connection (4) which has a clamping spring (5) for clamping an electrical conductor, and with an actuating lever ( 15) which has a lever arm section (17) and an actuating section (19) which acts together to apply force to the associated clamping spring (5), the actuating lever (15) having a free space (20) in the center of rotation (18) and the center of rotation (18 ) between the operating section (19) and the lever arm section (17), characterized in that a curved section of the clamping spring (5) is positioned in the free space (20) of the operating lever (15), that the free space (20) has a curved inner contour has, which is adjacent to the curved portion of the clamping spring (5), and that the actuating portion (19) forms the trailing end of the curved inner contour.

Description

The invention relates to a conductor connection terminal with an insulating material housing, with a spring-loaded terminal connection which has a clamping spring for clamping an electrical conductor, and with an actuating lever which is mounted in the insulating material housing such that it can pivot about a center of rotation and which has a lever arm section and an actuating section which interacts to apply force to the associated clamping spring. The operating lever has a clearance at the center of rotation. The center of rotation is between the operating section and the lever arm section.

Conductor connection terminals of this type are used in a variety of forms, such as plug connectors, series terminals, box terminals or terminals built into the housing of electrical or electronic devices.

WO 2014/170273 A1 shows a spring-loaded clamping element with a pivoting lever which is installed laterally next to a leg spring bent in a U-shape in an insulating material housing. The actuating lever has a contact geometry on which the clamping leg rests at least partially and presses against the pivoting direction on the contact geometry in order to pivot the pivoted lever back with the aid of the clamping spring.

The spring arc of the torsion spring is accommodated in a curved free space in the insulating material housing.

DE 10 2010 048 698 B4 discloses an electrical connection terminal with an insulating housing and at least one spring clamp connection in the insulating housing. The spring clip connector has a cage clamp with a tab protruding forward from the actuating leg. The tab is accommodated in a free space in the operating lever that is created by a recess in the bearing shaft. The top of the space serves as a support for the tab. In this way, the actuating lever can be arranged in front of the cage clamp spring adjacent to a tab extending forward from the actuating leg away from the rear spring bow.

DE 10 2012 110 759 A1 describes a spring clamp connection with a bearing arm which extends from the direction of a busbar through a slot in the clamping section of the clamping spring or in the actuating section of the clamping spring. An actuating element is mounted on the bearing element in such a way that it acts on the actuating section of the clamping spring.

DE 10 2007 050 936 A1 discloses a connecting terminal with a cage clamp and an actuating element which is accommodated in the insulating material housing so that it can pivot on an axis of rotation. The actuating element has a control disk which rests against an actuating section of the clamping spring, which is connected to the actuating lever and is mounted with an axis of rotation in the insulating material housing. The axis of rotation is above the cage clamp.

Proceeding from this, it is the object of the present invention to create an improved conductor connection terminal with a structure that is as simple, robust and compact as possible.

The object is achieved with the conductor terminal with the features of claim 1. Advantageous embodiments are described in the dependent claims.

In a generic conductor terminal, a bent section of the clamping spring is positioned in the free space of the actuating lever. The free space has a curved inner contour that lies adjacent to the curved section of the clamping spring. The actuating section forms the outgoing end of the curved inner contour.

In this way, the bent section of the clamping spring is accommodated in the free space and a significantly more compact and kinematically improved conductor connection clamp can be provided.

The clamping spring can be a leg spring bent in a U-shape with a contact leg, a spring bow adjoining the contact leg and a clamping leg adjoining the spring bow and lying opposite the contact leg. Then the spring bow is positioned in the free space. The free space of the actuating lever thus encompasses the spring arc in such a way that the actuating section of the actuating lever is designed to apply force to the clamping leg in order to exert an actuating force acting on the clamping leg in the direction of the contact leg when the actuating lever is pivoted about the center of rotation.

While the actuating lever is thus pivoted about the center of rotation lying in the region of the spring bow, the actuating section then engages the clamping leg adjoining the spring bow. The actuating section and the lever arm section are thus each located on opposite sides of the spring bow. This enables a very compact on construction with a force-optimized and stable actuation of the clamping spring to open the clamping point formed with the clamping leg for clamping an electrical conductor.

The spring-loaded terminal connection can have a busbar piece, so that the clamping point for connecting an electrical conductor is formed between a clamping edge of the clamping leg and the busbar piece.

In such an embodiment of the spring-loaded terminal connection with a current piece, the clamping spring cannot only be designed as a leg spring bent in a U-shape. It is also conceivable that the clamping spring has a cage tension spring with a contact leg mounted on the busbar piece, a spring bow adjoining the contact leg, an actuating leg adjoining the spring bow and opposite the contact leg, and a clamping leg adjoining the actuating leg after a bend. The clamping leg is provided with a conductor feed-through opening and extends to the busbar piece. The busbar piece is guided through the conductor feedthrough opening.

With such a cage clamp spring, the bend is positioned in the free space of the actuating lever at least in the rest position of the actuating lever. The actuating section of the actuating lever is designed to apply force to the actuating arm in order to exert an actuating force acting on the actuating arm in the direction of the contact arm when the actuating lever is pivoted about the center of rotation.

The application of force to the cage clamp spring with the actuating section of the actuating lever thus does not take place via a tab, but on the area of the actuating leg following the bend. Good actuation kinematics with an optimal flow of forces are thus achieved with a very compact design.

The operation portion of the operation lever may be formed as a protruding bead. This improves the stability of the actuating lever, in particular when it is formed in plastic injection molding.

The actuating lever can have side wall sections which, in the resting state, lie in the area of the center of rotation on both sides next to the bend. The side wall sections are connected to one another above the bend with a transverse web. The actuating section is then formed on an end face of the transverse web. With the help of such side wall sections connected to one another via a crossbar, stable mounting of the operating lever in the insulating material housing is achieved while at the same time stiffening the operating section and its transition to the operating arm section. In this way, the bending of the cage clamp spring is introduced into the free space delimited by the side wall sections and the transverse web.

The lever arm section can be connected to the cross bar between the side wall sections and can extend from the cross bar to the free end of the actuating lever. In this way, the actuating arm is not arranged laterally in the area of the side wall sections, but in the more central area. Due to the fact that the lead-through opening extends into the bend, the actuating arm section can dip into this lead-through opening in the region of the bend when the actuating lever is in the idle state. The height of the conductor connection terminal, which is influenced by the actuating lever, can be reduced in this way.

However, it is also conceivable that the side wall sections extend towards the free end of the actuating lever and also form the lever arm section. The lever arm section is thus a continuation of the side wall sections. It is optionally conceivable that the transverse web between the side wall sections continues up to the free end of the actuating lever in order to form a stable lever arm section with a U-shaped cross section.

The actuating lever can have pivot bearings for pivoting about a defined axis of rotation. However, it is also advantageous if the actuating lever is mounted in a floating manner in the insulating material housing. The actuating lever is then pivoted not about a defined axis of rotation, but rather along a pivotable axis in the center of rotation.

The actuating lever and the insulating material housing can have mutually interacting latching contours for locking the actuating lever in an open position, in which the actuating arm is pivoted pointing away from the insulating material housing and exerts an actuating force on the clamping spring. It is thus possible in the open position to hold the spring-loaded terminal connection in the open position and to insert or remove an electrical conductor without grasping the actuating lever.

For this purpose, the actuating lever can have a protrusion and the insulating material housing can have an indentation to form the latching contours. A reverse variant with a single book is also conceivable direction of the actuating lever, into which a protrusion of the insulating material immerses in the open position. The protrusion can be designed, for example, as a rounded contour or as a locking lug with a stop surface.

The insulating-material housing can have a plurality of spring-cage terminal connections and respectively associated actuating levers, which are arranged next to one another in the insulating-material housing.

For the purposes of the present description of the patent claims, an indefinite term “a” is not to be understood as a numeral. Rather, this is to be interpreted in the sense of "at least one".

With a plurality of spring-loaded terminal connections, it is conceivable that adjacent actuating levers interlock and in the interlocking area of the actuating levers a pivot bearing is formed for pivoting individual actuating levers independently of the at least one adjacent actuating lever. The adjacent operating levers are thus pivotally mounted on each other. Only the outer operating levers are then pivotally connected to a pivot bearing on the insulating housing.

• 1 - Seiten-Schnittansicht einer ersten Ausführungsform einer Leiteranschlussklemme mit Schenkelfeder;
• 2 - Schnittansicht der Leiteranschlussklemme aus 1 im Schnitt D-D;
• 3 - perspektivische Ansicht einer Anzahl nebeneinander angeordneter Betätigungshebel für die Leiteranschlussklemme aus 1;
• 4 - perspektivische Schnittansicht der Betätigungshebel aus 3;
• 5 - perspektivische Ansicht eines Paares von Betätigungshebeln für die Leiteranschlussklemme aus 1;
• 6 - Seiten-Schnittansicht einer zweiten Ausführungsform einer Leiteranschlussklemme mit Schenkelfeder;
• 7 - Seiten-Schnittansicht der Leiteranschlussklemme aus 6 mit vorderem Betätigungshebel in Offenstellung;
• 8 - perspektivische Ansicht einzeln nebeneinander angeordneter Betätigungshebel für die Leiteranschlussklemme aus 6 und 7;
• 9 - perspektivische Schnittansicht der Betätigungshebel aus 8;
• 10 - Seiten-Schnittansicht einer dritten Ausführungsform einer Leiteranschlussklemme mit Schenkelfeder;
• 11 - Seiten-Schnittansicht einer vierten Ausführungsform einer Leiteranschlussklemme im Ruhezustand;
• 12 - Seiten-Schnittansicht der Leiteranschlussklemme aus 11 im Offenzustand;
• 13 - Seiten-Schnittansicht einer fünften Ausführungsform einer Leiteranschlussklemme mit Käfigzugfeder;
• 14 - perspektivische Ansicht eines Betätigungshebels für die Leiteranschlussklemme aus 13;
• 15 - Schnittansicht eines Ausschnitts der Leiteranschlussklemme aus 13.

The invention is explained in more detail below using exemplary embodiments with the accompanying drawings. Show it:

• 1 - Side sectional view of a first embodiment of a conductor terminal with torsion spring;
• 2 - Sectional view of the conductor connection terminal 1 on average DD;
• 3 - Perspective view of a number of juxtaposed actuating lever for the conductor terminal from 1 ;
• 4 - perspective sectional view of the operating lever 3 ;
• 5 - perspective view of a pair of operating levers for the conductor terminal 1 ;
• 6 - Side sectional view of a second embodiment of a conductor terminal with torsion spring;
• 7 - Side sectional view of the conductor terminal 6 with front actuating lever in open position;
• 8th - Perspective view of actuating levers arranged next to one another for the conductor connection terminal 6 and 7 ;
• 9 - perspective sectional view of the operating lever 8th ;
• 10 - Side sectional view of a third embodiment of a conductor terminal with torsion spring;
• 11 - Side sectional view of a fourth embodiment of a conductor terminal in the rest state;
• 12 - Side sectional view of the conductor terminal 11 in the open state;
• 13 - Side sectional view of a fifth embodiment of a conductor terminal with cage clamp;
• 14 - Perspective view of an actuating lever for the conductor terminal 13 ;
• 15 - Sectional view of a section of the conductor connection terminal 13 .

1 shows a side sectional view of a first embodiment of a conductor terminal 1 recognize. The conductor connection terminal 1 has an insulating material housing 2 with a conductor entry opening 3 on the front side of the insulating material housing 2. The conductor entry opening 3 serves to insert an electrical conductor to a spring-loaded terminal connection 4. This spring-loaded terminal connection 4 consists of a clamping spring 5 in the form of a U-shaped torsion spring and a Busbar section 6 formed. The clamping spring 5 has a contact section 7 for contacting the busbar piece 6. For this purpose, the busbar piece 6 has a conductor feedthrough opening 8 into which the clamping spring 5 is suspended. An angled end 9 of the contact leg 7 rests against a narrow side edge of the conductor feedthrough opening 8 in order to fix the leg springs in terms of their position on the busbar piece 6 in this way.

A spring bow 10 connects to the contact leg 7 and merges into a clamping leg 11 . The clamping leg 11 is located opposite the contact leg 7 and extends back to the conductor lead-through opening 8 of the busbar piece 6 . In the exemplary embodiment shown, the free end area of the clamping leg 11 extends through the conductor feedthrough opening 8 into a conductor collecting pocket 12 of the insulating material housing 2 . The free end of the clamping leg 11 has a clamping edge which, together with the edge of the conductor feedthrough opening 8 opposite the contact leg 7, forms a clamping point for clamping an electrical conductor.

It is clear that a material tab 13 is bent out of the conductor feed-through opening 8 of the busbar piece 6 and extends towards the conductor collecting pocket 12 in the direction of conductor insertion. This material tab 13 provides a conductor guide surface and a contact clamping edge for clamping an electrical conductor.

In the area adjoining the contact leg 7 , the busbar piece 6 has a further material tab 14 which is bent in the direction of the center of rotation of an actuating lever 15 . With the help of this flap of material 14, the spring-loaded terminal connection 4 is positioned in the insulating material housing 2 and held in position. Furthermore, a contact pin 16 protrudes from the busbar piece 6 , which extends in the opposite direction of the further material tab 14 and protrudes from the insulating material housing 2 on the rear side, which is opposite the front side with the conductor entry opening 3 . This contact pin 16 is optional. It is also conceivable that there is no external contact possibility, but that at least two spring-loaded terminal connections of the conductor connection terminal 1 arranged next to one another are electrically conductively connected to one another, e.g. via a common busbar piece 6 . Instead of a contact pin 16, other types of connection can also be provided, such as plug-in contacts.

In order to now open the clamping point formed between the clamping limb 11 and the busbar piece 6, in particular for removing an electrical conductor, the clamping limb 11 must be shifted in the direction of the contact limb 7, as shown. This is achieved with the operating lever 15. The actuating lever 15 is accommodated in the insulating material housing 2 such that it can pivot. It has a lever arm section 17 which merges into a center of rotation 18 . On the side of the center of rotation 18 opposite the lever arm section 17 there is an operating section 19 . It can be seen that a bent section of the clamping spring 5 in the form of the spring bow 10 dips into a free space 20 of the center of rotation 18 . The actuating lever 15 is then positioned in this bent section of the clamping spring 5 and is pivoted about the center of rotation 18 lying in the area of the spring bow 10 . As a result, the actuating portion 19 opposite the lever arm portion 17 exerts an actuating force on the clamping leg 11 in the area adjoining the spring arc 10 . As a result, the actuating leg 11 is displaced in the direction of the contact leg 7 against the clamping force of the clamping spring 5, as shown, and the clamping point is opened for removing an electrical conductor.

In the exemplary embodiment shown, the contact leg 7 is supported on the one hand on the edge of the conductor feedthrough opening 8 and on the other hand on the additional material tab 14 .

In order to keep the terminal point in the open position without further application of force to the actuating lever 15, there are corresponding locking elements on the actuating lever 15 and the insulating material housing 2 in the form of a locking lug 21 on the actuating lever 15 and a locking opening 22 in the insulating material housing 2. The wedge-shaped latching lug 21 having a stop surface dips into the latching opening 22 in the illustrated open position, in which the clamping point is open.

It can be seen that the actuating lever 15' located behind it of the further spring-loaded terminal connection is in the rest position. In this rest position, the associated clamping leg 11 'springs back towards the clamping projection on the busbar piece 6.

To equip the actuating lever 15, 15', a longitudinal web 23 is present on the upper side of the lever arm section 17'.

2 omits a sectional view through the conductor terminal 1 1 recognize in the cut DD. It is clear that two spring-loaded terminal connections are built into the insulating housing 2 next to one another with associated actuating levers 15 .

The center of rotation 18 has bearing elements for pivoting the actuating lever 15 about a defined axis of rotation. Adjacent actuating levers 15 are mounted on one another on the sides that point towards one another, in that the corresponding bearing elements 24 engage in one another, for example a bearing pin can dip into a bearing opening. The outer sides of a group of such actuating levers 15 are then mounted on the insulating material housing 2, in which laterally projecting bearing pins, e.g. bearing openings in side walls 25 of the insulating material housing 2, dip. However, a reverse variant is also conceivable, in which projecting bearing journals of the insulating material housing 2 dip into bearing openings of the actuating lever 15 .

It becomes clear that the bearing elements 24 extend through the free space 10 in the center of rotation 18 of the actuating lever 15 . In this free space 20, a spring arc 10 is arranged, which has a bearing element 24 z. B. encloses in the form of a bearing journal over a partial circumference.

3 omits a number of actuating levers 15 arranged next to one another for the conductor connection terminal 1 1 recognize. In this case, pairs of actuating levers 15 are always arranged directly adjacent to one another and are pivotably mounted independently of one another. A bearing element 24 for mounting in a side wall 25 of the insulating material housing 2 protrudes on the outside of each pair of actuating levers 15 .

It can also be seen that the lever arm section 17 is bent and stabilized by a longitudinal web 23 . In the transition from the lever arm section 17 to the actuating section 19, a latching element in the form of a latching lug 21 protrudes on the outside. This latching lug 21 can, for example, be wedge-shaped.

4 omits a sectional view through the plurality of operation levers 15. FIG 3 recognize. It is clear here that the actuating levers 15 arranged next to one another are each pivotably mounted on one another by bearing elements 24 engaging in one another. These bearing elements 24 extend through the free space 20 which is provided for receiving a bent section of the clamping spring.

5 shows a perspective view of the operating levers 15 from the right and left side. Here it becomes even clearer that a bearing element 24 in the form of a bearing pin is located in the center of rotation, which has a bearing opening 26 on one side for receiving a bearing pin 27 of the adjacent bearing element 24 . These bearing elements 24 form the center of rotation of the actuating lever 15, in which there is also the free space 20 for receiving a bent section of the clamping spring.

It is also clear that gripping elements 28, e.g. in the form of knobs or webs, are arranged on the upper side of the lever arm section 17 in the free end area.

6 shows a side sectional view of a second embodiment of a conductor terminal 1 recognize. This in turn has an insulating material housing 2 with at least one spring clamp connection 4 built into it, which is formed from a busbar piece 6 and a torsion spring 5 bent in a U-shape. For the construction of the torsion spring 5 and the busbar piece 6, reference can essentially be made to the embodiments for the first embodiment.

Again, the operating lever 15 has a free space 20 in its center of rotation 18, in which the spring bow 10 of the U-shaped torsion spring 5 is accommodated. In contrast to the first embodiment, however, no pivot pin extends into this free space 20. Rather, the free space 20 is completely open in the direction of the conductor feedthrough opening 8 of the busbar piece 6. The free space 20 is in turn delimited by a curved inner wall which is adapted to the curved section of the spring clip 5 in the form of the spring bow 10 . Here, too, the center of rotation of the actuating lever 15 is in the area of the free space 20 and the spring bow 10 arranged thereon.

The front operating lever 15 is in the rest position, in which the operating section 19 of the operating lever does not exert any operating force on the clamping section 7 of the clamping spring 5 .

7 shows the wire connection terminal 1 6 with the operating lever 15 folded up into the open position. The operating section 19 lying opposite the lever arm section 17 rests against the clamping leg 11 and exerts an operating force directed in the direction of the contact leg 7 . In this way, the clamping limb 11 is displaced in the direction of the contact limb 7 in order to open the clamping point for connecting an electrical conductor.

It is clear that the center of rotation with the free space 20 is located between the actuating section 19 and the lever arm section 17 whose free end extends away from the insulating material housing 2 . As a result, the lever arm 15 rotates around the spring arc 10 and the actuating force exerted on the free end of the lever arm section 17 is converted into an oppositely directed force acting on the clamping leg 11 .

8th omits a perspective view of a number of operating levers for the conductor terminal 1 arranged next to one another 6 and 7 recognize. It is clear that here too there is a locking lug 21 on the outside of the actuating lever and the contour of the actuating lever is in principle comparable to the actuating lever of the first embodiment. However, the actuating levers 15 are all arranged at a small distance from one another. The actuating levers 15 each have side walls 28 delimiting the free space 20 laterally (left and right) in the direction of the axis of rotation, on the outer sides of which there is in each case a bearing element 24 in the form of a bearing journal. The trunnion more visible on the left is tubular with a circular cross-section opening for receiving a complementary trunnion.

9 omits a sectional perspective view of the plurality of operating levers 15. FIG 8th recognize. It can be seen there that the actuating levers 15 each have corresponding bearing elements 24 on their side walls in the area of the center of rotation 18 with a tubular bearing pin on one side and a cylindrical bearing pin on the opposite side. The cylindrical bearing journal has a diameter adapted to the bore of the tubular complementary bearing journal in order to dip into it and form a pivot bearing between the adjacent operating levers 15 .

It becomes clear that the free space 20 in the center of rotation 18 is completely free in this exemplary embodiment and is not partially filled with a bearing element.

10 shows a side sectional view of a third embodiment of a conductor connection terminal 1 with at least one spring clamp connection 4 in an insulating material housing 2 and an associated actuating lever 15. The basic structure of the conductor connection terminal 1 is comparable to the first and second exemplary embodiment, so that essentially reference can be made to the previous statements. In this exemplary embodiment, the free space 20 in the center of rotation is also not filled with rotating elements. The spring arc 10 of the U-shaped torsion spring 5 is in turn accommodated in the correspondingly curved free space 20 of the actuating lever 15 and lies in the center of rotation 18 of the actuating lever 15. The lever arm section 17 and the actuating section 19 lie on opposite sides of the center of rotation. The actuating section 19 is arranged in such a way that it is supported on the area of the clamping leg 11 adjoining the spring arc 10 and exerts an actuating force on this clamping leg 11 when the actuating lever 15 is pivoted.

Unlike in the first two embodiments, the conductor rail piece 6 is not extended by a contact pin protruding from the insulating housing 2 . Rather, at least two spring-loaded terminal connections 4 arranged next to one another are electrically conductively connected to one another via a common busbar piece 6 .

11 shows a fourth embodiment of a conductor terminal 1 in the side sectional view. In this embodiment too, a torsion spring 5 bent in a U-shape is built into the insulating material housing 2 . It rests with its contact leg 7 on a support section 29 of a busbar piece 6. This busbar piece 6 is cage-shaped and has a contact base 30 opposite the support section 29 with a contact projection 31. The free end of the clamping leg together with this contact projection 31 forms a clamping point for clamping a introduced into the front conductor entry opening 3 electrical conductor.

A fork contact 32 is formed on the busbar section 6 opposite the conductor insertion opening 3 . The fork contact 32 has two opposing fork tongues 33a, 33b which interact in an elastically resilient manner. A contact pin receiving opening 34 is provided on the side of the insulating material housing 2 opposite the conductor insertion opening 3 in order to insert a contact pin or electrical conductor or the like into the interior of the insulating material housing 2 for contacting the fork contact 32 .

In this respect, the side opposite the conductor entry opening 3 forms a connector for plugging in or plugging onto a corresponding mating connector.

To open the terminal point formed by the clamping spring 5 and the busbar piece 6 for connecting an electrical conductor, an actuating lever 15 is in turn mounted pivotably in the insulating housing 2 . This is in turn mounted floating around a center of rotation 18 located in the region of the spring arc 10 without a fixed pivot bearing in the insulating housing 2 . The operating section 19 of the operating lever 15 acting on the clamping leg 11 and the lever arm section 17 with the free end for grasping the operating lever 15 are located opposite one another with the center of rotation 18 of the operating lever 15 lying in between. In this center of rotation 18, the actuating lever 15 in turn has a bay-like vaulted free space 20, in which the spring arc 10 of the clamping spring 5 dips. It can be seen that the curvature of the inner wall of the free space 20 is adapted to the curvature of the spring bow 10 in such a way that the spring bow 10 rests on this curved inner wall of the free space 20 of the actuating lever 15 . In this way, the actuating lever 15 is pivotally mounted on the spring bow 10 in the rest position.

On the side opposite the free space 20, the actuating lever 15 has a latching element 34 in the form of a projection. This projection is narrower than the width of the adjoining area of the actuating lever 15. This latching element 34 in the form of the projection is adapted to the contour of the insulating material housing 2 in this area in order to immerse a corresponding latching element 35 in the insulating material housing 2 and latch there. This corresponding locking element 35 is designed as a recess whose width the width of the projection (locking element 34) is adjusted. So that the projection (locking element 34) can dip into the corresponding locking element 35 (recess) when the actuating lever 15 is pivoted, the corresponding locking element 35 is adjoined by a channel 36 leading to the upper side of the insulating material housing 2 . On the other hand, the arcuate section 55 located to the side of the latching element 34 on the actuating lever 15 slides along an inner wall 56 of the insulating material housing 2 during the opening movement of the actuating lever 15 .

12 shows the wire connection terminal 1 11 with the actuating lever 15 pivoted into the open position. It is clear that the actuating section 19 now rests on the clamping leg 11 and exerts an actuating force that displaces the clamping leg 11 in the direction of the contact leg 7 . As a result, the clamping point formed between the free end of the clamping leg 11 and the clamping projection 31 is opened for clamping an electrical conductor.

In this open position, the latching element 34 (projection) of the actuating lever 15 enters the corresponding latching element 35 (recess) of the insulating material housing 2 and holds the actuating lever 15 in the open position, even if the clamping spring 5 exerts a restoring force on the actuating lever 15. The actuating lever 15 is thus locked in the open position by the floating displacement and the corresponding locking elements 34, 35. It becomes clear that the spring arc 10 is also positioned in the free space 20 in the center of rotation 18 of the actuating lever 15 in this open position. The actuating lever 15 is, however, pivoted away from the spring bow 10 so that there is now a distance between the inner wall of the curved free space 20 and the spring bow 10 . In this open position, the actuating lever 15 is no longer guided or supported on the spring bow 10. The actuating lever 15 only interacts there with its actuating section 19 with the clamping leg 11.

It can also be seen that the projection 34 is the extended part of a transverse bar which extends over a substantial part of the length of the lever arm section 17 and improves the buckling stability of the actuating lever 15 .

13 shows a side sectional view of a fifth embodiment of a conductor terminal 1 recognize. In this embodiment, the clamping spring is designed as a cage tension spring 38 which has a contact leg 39 mounted on a busbar piece 6 , an adjoining spring bow 40 , an actuating leg 41 adjoining the spring bow 40 and a clamping leg 42 . The actuating leg 41 and the clamping leg 42 merge into one another with a bend 43 . In the clamping leg 42 there is a conductor bushing opening through which the busbar piece 6 and optionally also a part of the contact leg 39 extends.

The insulating housing 2 in turn has a conductor insertion opening 3, which leads to a terminal point for connecting an electrical conductor. The clamping point is formed by a protrusion 43 of the busbar piece 6 and a lower edge of the transverse web delimiting the end of the conductor insertion opening 3 on the clamping leg 42 .

In order to now move this transverse web away from the busbar piece 6 and to open the clamping point, the actuating leg 41 must now be moved in the direction of the contact leg 39 . With the relatively large clamping force of a cage clamp, this requires relatively large actuating forces, which are applied by the actuating lever 15 pivotably mounted in the insulating material housing 2 . This in turn has a lever arm section 17 on one side and an actuating section 19 on the opposite side. The actuation section 19 is designed as a bead on a transverse web 45 which connects two opposite side walls 46 of the actuation lever 15 . In their extension, the side walls 46 form two opposing wall sections of the lever arm section 17.

It is clear that in the center of rotation 18 of the actuating lever 15 there is again a free space 20 which is delimited at the top by the transverse web 45 and into which the bend 43 of the cage clamp spring 38 dips. The actuating section 19 rests on the area of the actuating leg 41 adjoining the bend 43 .

14 omits a perspective view of one also for the conductor terminal 1 13 suitable operating lever 15 recognize. It is clear that the lever arm section 17 is connected in one piece (integrally and materially) to the crossbar 45 in the middle region of the actuating lever 15 . On the outer sides of the transverse web 45 there are in each case at least partially circular or preferably fully circular side wall sections 46 which are used for the pivot mounting of the actuating lever 15 in the insulating material housing 2 . The lever arm section 17 is placed transversely with respect to the curved plane of the transverse web 45 in order to improve the buckling stability when the lever arm 15 is actuated and pivoted. It becomes clear that in the interval between A free space 20 for receiving a curved section or the bend 43 of the cage clamp spring 38 is formed between the side wall sections 46 and the curved transverse web 45 . This free space is partially filled by the lever arm section 17 adjoining the transverse web 45 .

15 omits a front sectional view of a detail of the conductor connection terminal 1 13 recognize. It is clear that the clamping leg has a conductor feedthrough opening 49 delimited by mutually opposite side webs 47 and a transverse web 48 at the end which connects the side webs 47 to one another. The edge of the transverse web 48, which delimits the conductor feed-through opening 49, lies on the busbar piece 6 in the rest position shown without a conductor being clamped on.

The conductor feedthrough opening 49 extends into the bend 43, so that the lever arm section 17 of the actuating lever 15 in the illustrated rest position dips into the conductor feedthrough opening 49 in the region of the bend 43.

It can also be seen that the side wall sections 46 dip into corresponding bearing openings 50 of the insulating material housing 2 in order to form a pivot bearing for the actuating lever 15 in the insulating material housing 2.

The illustrated conductor terminal 1 is designed as a socket terminal, in which at least two spring-cage terminal connections arranged adjacent to one another are electrically conductively connected via a busbar section 51 extending transversely to the spring-cage terminal connections.

Claims (14)

Conductor connection terminal (1) with an insulating material housing (2), with a spring-cage terminal connection (4) which has a clamping spring (5) for clamping an electrical conductor, and with an actuating lever ( 15) which has a lever arm section (17) and an actuating section (19) which acts together to apply force to the associated clamping spring (5), the actuating lever (15) having a free space (20) in the center of rotation (18) and the center of rotation (18 ) between the operating section (19) and the lever arm section (17), characterized in that a curved section of the clamping spring (5) is positioned in the free space (20) of the operating lever (15), that the free space (20) has a curved inner contour has, which is adjacent to the curved portion of the clamping spring (5), and that the actuating portion (19) forms the trailing end of the curved inner contour. Conductor connection terminal (1) according to claim 1 , characterized in that the clamping spring (5) is a leg spring bent in a U-shape with a contact leg (7), a spring bow (10) adjoining the contact leg (7) and a spring bow (10) adjoining and the contact leg ( 7) opposite clamping leg (11), the spring bow (10) being positioned in the free space (20) and the actuating section (19) being designed to apply force to the clamping leg (11) in order to pivot the actuating lever (15) about the center of rotation (18) to exert an actuating force acting on the clamping leg (11) in the direction of the contact leg (7). Conductor connection terminal (1) according to claim 2 , characterized in that the center of rotation (18) of the actuating lever (15) is arranged in the area encompassed by the spring bow (10). Conductor connection terminal (1) according to claim 1 , characterized in that the spring clamp connection (4) has a busbar piece (6) and the clamping spring (5) has a cage tension spring (38) with a contact leg (39) mounted on the busbar piece (6) and a contact leg (39) adjoining it Spring bow (40), an actuating limb (41) adjoining the spring bow (40) and opposite the contact limb (39) and a clamping limb (42) adjoining the actuating limb (41) after a bend (43), which has a conductor feedthrough opening ( 49) and extends to the busbar piece (6), the busbar piece (6) being passed through the conductor lead-through opening (49) and the bend (43) being positioned in the free space (20) and the actuating section (19) of the actuating lever (15) for applying force to the actuating arm (41) is designed to pivot the actuating lever (15) about the center of rotation (18) on the actuation leg (41) in the direction of the contact leg (39) to exert actuating force acting. Conductor connection terminal (1) according to claim 4 , characterized in that the conductor lead-through opening (49) extends into the bend (43) and the actuating lever (15) in the rest state, in which no force is applied to the clamping spring (5) by the actuating lever (15), in the region of the bend ( 43) into the conductor lead-through opening (49). Conductor connection terminal (1) according to claim 4 or 5 , characterized in that the operating portion (19) of the operating lever (15) is formed as a protruding bead. Conductor terminal (1) according to one of Claims 4 until 6 , characterized in that the actuating lever (15) has side wall sections (46) which, in the rest state, lie in the area of the center of rotation (18) on both sides next to the bend (43), and in that the side wall sections (46) above the bend (43) with a Crossbar (45, 48) are connected to one another, the actuating section (19) being formed on an end face of the crossbar (45, 48). Conductor connection terminal (1) according to claim 7 , characterized in that the lever arm section (17) is connected to the crossbar (45, 48) between the side wall sections (46) and extends from the crossbar (45, 48) to the free end of the actuating lever (15). Conductor connection terminal (1) according to claim 7 , characterized in that the side wall sections (46) extend towards the free end of the actuating lever (15) and form the lever arm section (17). Conductor connection terminal (1) according to one of the preceding claims, characterized in that the actuating lever (15) is mounted in a floating manner in the insulating material housing (2). Conductor connection terminal (1) according to one of the preceding claims, characterized in that the actuating lever (15) and the insulating material housing (2) have mutually interacting latching contours for latching the actuating lever (15) in an open position, in which the actuating arm moves away from the insulating material housing (2). pointing is pivoted and exerts an actuating force on the clamping spring (5). Conductor connection terminal (1) according to claim 11 , characterized in that the actuating lever (15) has a protrusion (34) and the insulating housing (2) has an indentation (35) to form the latching contours. Conductor connection terminal (1) according to one of the preceding claims, characterized in that the insulating material housing (2) has a plurality of spring-cage terminal connections (4) and respectively associated actuating levers (15) which are arranged next to one another in the insulating material housing (2). Conductor connection terminal (1) according to Claim 13 , characterized in that adjacent actuating levers (15) intermesh and in the intermeshing area of the actuating levers (15) a respective pivot bearing for pivoting individual actuating levers (15) independently of the at least one adjacent actuating lever (15) is formed.

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