DE102019109974A1 - Electrical connection terminal - Google Patents

Abstract

The invention relates to an electrical connection terminal (100) for connecting a conductor (200) with a busbar (10), a clamping spring (11), by means of which the conductor (200) is clamped against the busbar (10) in a clamped state , and an actuating element (32) by means of which the clamping spring (11) can be transferred from the clamped state to a non-clamped state, the clamping spring (11) being designed as a leaf spring and that a receiving element (12) is provided on which the Clamping spring is attached, the receiving element (12) having a holding element (16) on which the clamping spring (11) is held in the non-clamped state and from which the clamping spring (11) is released in the clamped state, the holding element ( 16) can be pivoted to release the clamping spring (11) from the holding element (16), the holding element (16) having a pressure surface (21) which can be connected by means of the to perform the pivoting movement ßenden conductor (200) can be actuated.

Description

The invention relates to an electrical connection terminal for connecting a conductor, which has a busbar, a clamping spring, by means of which the conductor is clamped against the busbar in a clamped state, and an actuating element, by means of which the clamping spring can be transferred from the clamped state to a non-clamped state is, has.

Such connection terminals usually have a leg spring having a retaining leg and a clamping leg, a conductor inserted into the connection terminal being able to be clamped against the busbar by means of the clamping leg. If flexible conductors in particular are clamped, the clamping spring must be actuated by means of the actuating element before the conductor is inserted in order to pivot the clamping spring or the clamping leg away from the busbar so that the conductor can be inserted into the space between the busbar and the clamping spring. Only in the case of rigid and therefore stable conductors can the conductor apply sufficient force to the clamping spring or the clamping leg of the clamping spring to be able to pivot the clamping leg away from the busbar without the operator having to operate the actuating element. In the case of flexible conductors, the user must first pivot the clamping spring away from the busbar by actuating the actuating element so that the flexible conductor can be inserted and clamped. The actuation of the actuating element by the user complicates the assembly or connection of the conductor for the user, since the handling is cumbersome and the expenditure of time increases.

The invention is therefore based on the object of providing an electrical connection terminal in which the connection of flexible conductors can be simplified.

The object is achieved according to the invention with the features of the independent claim. Appropriate configurations and advantageous developments of the invention are specified in the subclaims.

The electrical connection terminal according to the invention is characterized in that the clamping spring is designed as a leaf spring and that a receiving element is provided to which the leaf spring is attached, the receiving element having a holding element on which the clamping spring is held in the non-clamped state and from which the clamping spring is released in the clamped state, the retaining element being pivotable for releasing the clamping spring from the retaining element, the retaining element having a pressure surface which can be actuated to perform the pivoting movement by means of the conductor to be connected.

By means of the connection terminal according to the invention, a flexible conductor can now also be connected in the connection terminal and clamped against the busbar without actuating the actuating element. The clamping spring is not designed as a leg spring but as a leaf spring which is elongated. The clamping spring thus has a leaf-shaped or strip-shaped contour. At a first end section, the clamping spring, designed as a leaf spring, has a fastening area via which the clamping spring is fastened to a receiving element. At a second end section opposite the first end section, the clamping spring has a clamping area which, in the clamped state, has direct contact with the conductor in order to clamp the conductor against the busbar. The receiving element, to which the clamping spring is fastened with its first end section, has a holding element on which the clamping spring is held with its second end section in the clamped state in such a way that the clamping spring, in particular with its second end section forming the clamping area, is pivoted away from the busbar , so that the conductor, in particular a flexible conductor, can be inserted into the space thus formed between the conductor rail and the clamping spring without the clamping spring having to be actuated beforehand with the actuating element. The holding element has a pressure surface which is arranged in the region where the conductor is inserted into the connection terminal, so that the conductor strikes the pressure surface when it is inserted into the connection terminal. By applying a pressure force to the pressure surface by means of the conductor, the holding element can be set in a pivoting movement, so that the holding element is pivoted away in the direction of insertion of the conductor. By pivoting the holding element, the clamping spring can be released from the holding element so that the clamping spring can move with its clamping area in the direction of the inserted conductor, in particular can pivot, and thereby clamp the inserted conductor against the busbar. By means of this special mechanism, a flexible conductor can be connected particularly simply by the insertion movement of the conductor alone, without a user having to actuate further elements, such as the actuating element, on the connecting terminal. This makes the terminal easier to handle and also saves time when connecting a conductor. In order to release the conductor to be connected from the clamped state again, the clamping spring with its Clamping area are pivoted back in the direction of the holding element and fixed in position on the holding element, in particular locked.

The receiving element preferably has a receiving pocket in which the clamping spring can be inserted, wherein a spring-elastic web can be formed on the receiving pocket, on which the holding element can be arranged. The receiving pocket is preferably designed in such a way that it surrounds the clamping spring inserted into the receiving pocket on the circumferential side, so that the clamping spring can be held securely in position in the receiving pocket. A resilient web, at the end of which the holding element can be arranged, can be molded onto this receiving pocket. This resilient web enables a spring movement of the holding element relative to the receiving pocket, whereby the pivoting movement of the holding element for releasing the clamping spring from the holding element can also be made possible. The holding element can thus execute a pivoting movement relative to the receiving pocket. The receiving pocket, the resilient web and the holding element are preferably formed in one piece with one another.

In order to be able to further improve the spring action of the resilient web, the spring-elastic web can have a cross-section reduction along its length. The cross-sectional reduction can be designed in the form of a constriction, so that the width of the web changes along its length. The reduction in width and thus the reduction in cross section are preferably carried out in the direction of the holding element, so that the web has a greater width in the area of the connection of the web to the receiving pocket than in the area of the connection of the web to the holding element.

In order to hold the clamping spring in the clamped state, the holding element can have two oppositely located latching lugs, wherein the latching lugs can be designed to be curved towards one another. The locking lugs can each have an undercut, on which the clamping spring can be held with its clamping area in the non-clamped state, in particular can be locked. The retaining element can be U-shaped, with the latching lugs being able to be formed on the two opposing legs of the U-shape of the retaining element. A first latching lug can be formed on a first leg and a second latching lug can be formed on a second leg of the U-shaped holding element opposite the first leg. The legs preferably run parallel to one another. The latching lugs, on the other hand, can be designed to be curved towards one another, so that they can be directed towards one another starting from the connection to the legs. The locking of the clamping spring on the locking lugs can be improved.

The clamping spring can have a clamping area by means of which the conductor can be clamped against the busbar in the clamped state, wherein the clamping area can have two actuating surfaces formed laterally on the clamping area for actuating the clamping spring by means of the actuating element. Due to the laterally molded actuation surfaces, the clamping spring can have a greater width in its clamping area than the rest of the clamping spring. The actuation surfaces can form a pressure surface for the actuation element, so that the actuation element can actuate the clamping spring at the level of its clamping area. The strength of the compressive force to be applied to the clamping spring by means of the actuating element for transferring the clamping spring from the clamped state to the non-clamped state can thereby be reduced.

It is also possible that the busbar is also attached to the receiving element. The busbar, like the clamping spring, can be inserted into the receiving pocket of the receiving element. The clamping spring can be arranged on a bottom section of the receiving pocket and the busbar can be arranged on a ceiling section of the receiving pocket opposite the bottom section, so that the clamping spring and the busbar are opposite one another. In particular in the non-clamped state, the clamping spring and busbar can be arranged to run essentially parallel to one another. The busbar can be fastened to the receiving element by means of a latching connection.

The actuating element is preferably provided in such a way that the actuating element has an actuating direction which is designed transversely to an insertion direction of the conductor to be connected into the electrical connection terminal. The actuation element is preferably actuated along its longitudinal axis, so that the actuation element is preferably arranged in the connecting terminal such that it can be moved longitudinally. The actuating element is preferably arranged to be longitudinally displaceable in a direction transverse to the direction of insertion of the conductor. The actuation direction of the actuation element is thus preferably not configured parallel to the insertion direction of the conductor.

The actuating element preferably has two actuating fingers lying opposite one another for actuating the clamping spring, a free space being formed between the two actuating fingers for the conductor to be connected to be passed through can be. To actuate the clamping spring, the actuating element can thus be guided past the conductor laterally with its two actuating fingers. A particularly compact design of the connecting terminal can be achieved through this design of the actuating element. The two actuating fingers preferably extend in the direction of the longitudinal axis of the actuating element and can thus form a type of extension of the actuating element.

Furthermore, it is preferably provided that the connecting terminal has an insulating material housing within which the busbar, the clamping spring, the actuating element and the receiving element can be arranged. The insulating material housing can have a conductor insertion opening and a receiving opening for the actuating element, wherein the conductor insertion opening can be formed on a first side of the insulating material housing and wherein the receiving opening can be formed on a second side of the insulating material housing extending transversely to the first side.

The invention is explained in more detail below with reference to the accompanying drawings using a preferred embodiment.

• 1 eine schematische Darstellung einer elektrischen Anschlussklemme gemäß der Erfindung in einer perspektivischen Ansicht mit der Klemmfeder im nicht geklemmten Zustand,
• 2 eine schematische Darstellung der in 1 gezeigten Anschlussklemme in einer Seitenansicht,
• 3 eine schematische Darstellung der in 1 und 2 gezeigten Anschlussklemme mit einem Isolierstoffgehäuse,
• 4 eine schematische Darstellung der Anschlussklemme gemäß der Erfindung in einem geklemmten Zustand der Klemmfeder mit einem angeschlossenen Leiter,
• 5 eine schematische Darstellung der in 3 gezeigten Anschlussklemme mit Isolierstoffgehäuse und Betätigungselement, und
• 6 eine schematische Darstellung der Anschlussklemme beim Überführen der Klemmfeder von dem geklemmten Zustand zurück in den nicht geklemmten Zustand.

Show it:

• 1 a schematic representation of an electrical connection terminal according to the invention in a perspective view with the clamping spring in the unclamped state,
• 2 a schematic representation of the in 1 shown connection terminal in a side view,
• 3 a schematic representation of the in 1 and 2 connection terminal shown with an insulating housing,
• 4th a schematic representation of the connection terminal according to the invention in a clamped state of the clamping spring with a connected conductor,
• 5 a schematic representation of the in 3 Connection terminal shown with insulating housing and actuating element, and
• 6 a schematic representation of the connection terminal when transferring the clamping spring from the clamped state back into the unclamped state.

1 shows an electrical connection terminal 100 for connecting an electrical conductor 200 showing a busbar 10 and spring clip 11 having, for connecting the conductor 200 this by means of the clamping spring 11 against the busbar 10 is clamped. Both the clamp spring 11 as well as the power rail 10 are on a receiving element 12 arranged.

The clamping spring 11 is designed as a leaf spring which is leaf-shaped or strip-shaped. The clamping spring 11 is in the receiving element 12 inserted and on the receiving element 12 attached. The clamping spring 11 points for this at a first end section 13 a fastening area by means of which the clamping spring 11 on the receiving element 12 is attached. At one of the first end sections 13 opposite second end portion 14th forms the clamping spring 11 their clamping area, with which the clamping spring in the clamped state 11 into the connection terminal 100 introduced head 200 against the busbar 10 clamps and thus connects with electrical contact. At its second end section forming the clamping area 14th has the clamping spring 11 two laterally molded actuation surfaces 30th , 31 to operate the clamping spring 11 by means of an actuating element 32 on.

The receiving element 12 has a storage pocket 15th and a holding element 16 on, with the receiving pocket 15th with the holding element 16 via a spring-elastic web 17th are connected to each other.

The holding element 16 serves to hold the clamping spring 11 in an unclamped state, that is, when the clamping spring 11 no ladder 200 against the busbar 10 clamped to hold, in particular at its second end portion forming the clamping area 14th to keep so that a free space or space between the busbar 10 and the clamp spring 11 is formed, for example in 1 can be seen in which a ladder 200 can be introduced.

The holding element 16 is U-shaped. On one between two parallel legs 18th , 19th trained wall 20th has the holding element 16 a printing area 21st on which in the direction of a conductor to be introduced 200 is directed. When inserting a conductor to be connected 200 into the connection terminal 100 can this head 200 against the printing surface 21st press, whereby the entire retaining element 16 from the head 200 and thus also from the clamping spring 11 in swivel direction S. can be pivoted away, so that the clamping spring 11 of the holding element 16 is released and thereby with its second end portion 14th towards the power rail 10 can be moved to the inserted head 200 against the busbar 10 to clamp.

On both thighs 18th , 19th of the holding element 16 is each a locking lug 22nd , 23 formed, which each have a rear grip on which the clamping spring 11 can snap behind in the unclamped state to the retaining element 16 to be held. The locking lugs 22nd , 23 run in contrast to the thighs 18th , 19th not parallel to one another, but rather are curved to one another so that they are directed towards one another.

By means of the spring-elastic web 17th is the holding element 16 relative to the receiving pocket 15th movable, in particular designed to be pivotable. The holding element 16 itself is rigid. The spring-elastic bridge 17th thus enables a pivoting movement of the holding element 16 in swivel direction S. when a head 200 against the retaining element 16 presses and the bridge 17th allows the retaining element 16 when the head 200 is no longer clamped against the pivoting direction S. pivoted back into its starting position so that the clamping spring is again on the holding element in the non-clamped state 16 can be held or locked.

To increase the spring effect, the spring-elastic web has 17th a reduction in cross section 24 along its length so that the web 17th is designed waisted, as in particular in 6 can be seen. The reduction in cross section 24 is in the direction of the retaining element 16 formed so that in the area of the connection of the web 17th to the holding element 16 the bridge 17th has a smaller cross section and thus a smaller width than in the area of the connection of the web 17th to the storage pocket 15th .

The receiving pocket 15th is designed in such a way that it is placed in the receiving pocket 15th inserted clamping spring 11 encloses the circumference. The receiving pocket 15th also forms a window-like opening 25th from which the conductor to be connected 200 when connecting is performed as in 4th can be seen. The window-like opening 25th is formed closed on its circumference. The receiving pocket 15th is just like the retaining element 16 rigid.

Also the busbar 10 is on the receiving element 12 held by the power rail 10 on the receiving pocket 15th is attached. The power rail 10 is just like the clamp spring 11 in the receiving pocket 15th of the receiving element 12 inserted. The clamping spring 11 is on a floor section 26th the receiving pocket 15th arranged and the busbar 10 is on one of the floor sections 26th opposite ceiling section 27 the receiving pocket 15th arranged so that the clamping spring 11 and the power rail 10 opposite. The power rail 10 is by means of a latching connection on the receiving element 12 be attached. In the area of the receiving pocket 15th has the receiving element 12 therefor two opposite recesses 28 , 29 on which the busbar 10 is locked.

2 shows a side view of the in 1 terminal shown 100 , it can be seen here that the clamping spring 11 in the area of their first end section 13 flat on the receiving element 12 , especially on the receiving pocket 15th of the receiving element 12 rests.

3 shows an insulating housing 33 the connection terminal 100 in which the busbar 10 , the clamp spring 11 , the receiving element 12 and the actuator 32 are arranged. The insulated housing 33 has a conductor entry opening 34 for inserting the conductor 200 into the connection terminal 100 and a receiving opening 35 , in which the actuator 32 Is guided in a longitudinally displaceable manner, the conductor entry opening 34 on a first page 36 of the insulating housing 33 is formed and wherein the receiving opening 35 on one across the first page 36 extending second side 37 of the insulating housing 33 is trained. The actuator 32 thus has a direction of actuation B. on which transverse to an insertion direction E. of the conductor to be connected 200 into the connection terminal 100 is trained.

The actuator 32 is designed in the form of a pusher. The actuator 32 points on his in the direction of the clamping spring 11 pointing end two opposite actuating fingers 38 , 39 on, being between the actuating fingers 38 , 39 a space for the conductor to be connected through 200 is formed, for example in 5 can be seen. For transferring the clamping spring 11 the actuating fingers can move from the clamped state to the non-clamped state 38 , 39 a compressive force on the actuating surfaces 30th , 31 the clamping spring 11 raise this up from the head 200 get away and again with their second end section 14th on the holding element 16 to lock into place.

4th and 5 point one into the connector 100 introduced head 200 which against the printing surface 21st of the holding element 16 presses and thereby the holding element 16 pivoted or backwards in the pivoting direction S. deflects so that the clamping spring 11 with its second end section 14th and thus with their clamping area from the locking lugs 22nd , 23 of the holding element 16 is released to the head 200 against the busbar 10 to clamp.

Becomes the leader 200 back out of the connection terminal 100 removed, the clamping spring 11 by actuation by means of the actuating element 32 , as in 6 can be seen, back in the direction of the holding element 16 are moved and on the holding element 16 be locked.

List of reference symbols

100

Terminal

10

Busbar

11

Clamp spring

12

Receiving element

13

First end section

14th

Second end section

15th

Receiving pocket

16

Retaining element

17th

web

18th

leg

19th

leg

20th

wall

21st

Printing area

22nd

Locking lug

23

Locking lug

24

Cross-section reduction

25th

opening

26th

Floor section

27

Ceiling section

28

Recess

29

Recess

30th

Operating area

31

Operating area

32

Actuator

33

Insulated housing

34

Conductor entry opening

35

Receiving opening

36

First page

37

Second page

38

Operating finger

39

Operating finger

200

ladder

B.

Operating direction

E.

Direction of introduction

S.

Swivel direction

Claims (9)

Electrical connection terminal (100) for connecting a conductor (200), with a busbar (10), a clamping spring (11) by means of which the conductor (200) is clamped in a clamped state against the busbar (10), and an actuating element ( 32), by means of which the clamping spring (11) can be transferred from the clamped state to a non-clamped state, characterized in that the clamping spring (11) is designed as a leaf spring and that a receiving element (12) is provided to which the clamping spring is attached wherein the receiving element (12) has a holding element (16) on which the clamping spring (11) is held in the unclamped state and from which the clamping spring (11) is released in the clamped state, the holding element (16) can be pivoted to release the clamping spring (11) from the holding element (16), the holding element (16) having a pressure surface (21) which is used to execute the pivoting movement by means of the cable to be connected ters (200) can be actuated. Electrical connection terminal (100) Claim 1 , characterized in that the receiving element (12) has a receiving pocket (15) in which the clamping spring (11) is inserted, with a spring-elastic web (17) formed on the receiving pocket (15) on which the holding element (16 ) is arranged. Electrical connection terminal (100) Claim 2 , characterized in that the spring-elastic web (17) has a cross-section reduction (24) along its length. Electrical connection terminal (100) according to one of the Claims 1 to 3 , characterized in that the holding element (16) has two opposing locking lugs (18, 19) for holding the clamping spring (11) in the clamped state, the locking lugs (18, 19) being designed to be bent towards one another. Electrical connection terminal (100) according to one of the Claims 1 to 4th , characterized in that the clamping spring (11) has a clamping area by means of which the conductor (200) is clamped against the busbar (10) in the clamped state, the clamping area being actuated by two actuating surfaces (30, 31) formed on the side of the clamping area the clamping spring (11) by means of the actuating element (32). Electrical connection terminal (100) according to one of the Claims 1 to 5 , characterized by that the busbar (10) is attached to the receiving element (12). Electrical connection terminal (100) according to one of the Claims 1 to 6 , characterized in that the actuating element (32) has an actuating direction (B) which is designed transversely to an insertion direction (E) of the conductor (200) to be connected into the electrical connection terminal (100). Electrical connection terminal (100) according to one of the Claims 1 to 7th , characterized in that the actuating element (32) has two opposing actuating fingers (38, 39) for actuating the clamping spring (11), with a free space being formed between the two actuating fingers (38, 39) for the conductor (200) to be connected through . Electrical connection terminal (100) according to one of the Claims 1 to 8th , characterized in that an insulating material housing (33) is provided, within which the busbar (10), the clamping spring (11), the actuating element (32) and the receiving element (12) are arranged.

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