EP4189781A1 - Conductor connection terminal - Google Patents

Abstract

The invention relates to a conductor connection terminal (1) comprising: an insulating material housing (2), the insulating material housing (2) having a conductor insertion opening (3) for inserting an electrical conductor in a conductor insertion direction (L); a bus bar (4); a clamping spring (5), the clamping spring (5) having a clamping limb (5c) which, together with the bus bar (4), forms a clamping point (6) for the electrical conductor; and an actuating element (7), the actuating element (7) being mounted so as to be displaceable in the insulating material housing (2) and having an actuating portion (7a) and a sliding portion (7b), the actuating portion (7a) being designed to open and/or close the clamping point (6), the actuating element (7) having a guide pin (8), and the guide pin (8) being mounted so as to be displaceable in a guide contour (9) of the insulating material housing (2) in the conductor insertion direction (L).

Description

conductor terminal

The invention relates to a conductor connection terminal with an insulating material housing, where the insulating material housing has a conductor insertion opening for inserting an electrical conductor in a conductor insertion direction, with a busbar and with a clamping spring, the clamping spring having a clamping leg which, together with the busbar, forms a clamping point for the electrical conductor forms, and with an actuating element, wherein the actuating element is slidably mounted in the insulating housing and has an actuating portion and a sliding portion, wherein the actuating portion is designed to open and / or close the terminal point.

DE 102015 101 893 A1 discloses a conductor connection terminal with a busbar and a clamping spring, with the busbar and the clamping spring forming a clamping point for an electrical conductor to be clamped. The clamping point can be opened by an actuating element mounted in an insulating material housing, the actuating element interacting with a contact leg of the clamping spring. To guide the actuating element, a recess is arranged on the actuating element, with a projection of the busbar being accommodated in the recess.

Proceeding from this, it is the object of the present invention to create an improved conductor connection terminal.

The object is achieved with a conductor terminal with the features of claim 1. Advantageous embodiments are described in the dependent claims. In the case of the conductor connection terminal of the generic type, it is proposed that the actuating element has a guide pin, the guide pin being displaceably mounted in a guide contour of the insulating material housing in the direction of conductor insertion.

Due to the design of the guide pin, the actuating element can be guided from an initial position into an actuating position and back. The initial position is the position in which the clamping point is completely closed. The operating position is the position in which the clamping point is completely open, with the electrical conductor being able to be inserted into the conductor connection terminal.

In this case, a sliding section is arranged on the actuating element, in which case a sliding actuation can be provided. By training the sliding section and mounting it on the outside of the insulating housing, the user can move the actuating element by shifting the sliding section on the insulating housing. By means of a sliding actuation, an alternative actuation option to a handle actuation is provided, with the actuation element being able to be displaced by the user through the sliding section. It is also conceivable that there is a combined slide-handle actuation, so that the user can choose between the slide actuation or the handle actuation, depending on the application.

In the case of a sliding operation, the sliding section for moving the actuating element is easily accessible from the outside for the user. This is moved during the actuation process and is easily accessible to the user even when the clamping point is open. When the handle is actuated, on the other hand, the actuating element is guided inside the insulating housing, with the actuating element being accessible to the user from the outside only via a smaller pressure surface than the sliding section. Furthermore, when the clamping point is open, the actuating element of the handle actuation is mounted within the insulating material housing, so that access for the user is difficult and an additional operating tool may be required to loosen the actuating element.

It is not necessary for the sliding section to rest directly on the insulating material housing. It is conceivable, for example, for the sliding section to be arranged at a distance from the insulating material housing. The actuating element is sufficiently stabilized by the guide pin, with simultaneous guidance of the actuating element from the starting position to the actuating position being able to be guaranteed. The guide pin can be arranged, for example, on the sliding section of the actuating element.

The actuation section can be operatively connected to the clamping leg of the clamping spring in order to open and/or close the clamping point.

The actuation section is in particular the section that can interact with the clamping spring in such a way that the actuation section bears against the clamping leg to open the clamping point. During the actuation process, the clamping leg is shifted into an open position by the actuation section, so that the electrical conductor can be inserted into the conductor connection terminal or can be removed from the conductor connection terminal.

The guide contour can be designed as an elongate recess, the guide contour being designed in such a way that the guide pin is held in a holding position in an open position and/or closed position of the clamping point. A trough can also advantageously be arranged in the guide contour, where the guide pin is held in an open position and/or closed position of the clamping point in the trough.

If the guide pin is transferred into the trough of the guide contour, for example a spring force of the clamping leg can act on the actuation section in such a way that the actuation element is tilted into a holding position. The Actuate supply element is held in the holding position without external influence, so that the electrical conductor can be inserted into or removed from the conductor terminal.

It is also conceivable that a projection is arranged on the guide contour, where the projection makes it difficult to move the guide pin or the actuating element in such a way that an increased force has to be applied, since the guide pin can be used to guide past this projection. It is possible, for example, that in the starting position the projection makes it difficult to move the guide pin, so that the actuating element cannot be unintentionally moved into an actuating position and release an inserted electrical conductor. However, it is also conceivable that the projection makes it difficult for the actuating element to be displaced in the actuating position, so that the actuating element can be held in the open position of the clamping point. In particular, both a trough and a projection on the guide contour can be arranged in order, for example, to place the guide pin in an open position of the terminal and in a closed position of the terminal point in a holding position can be held.

The elongated recess can be designed, for example, as an elongated hole or at least in the manner of an elongated hole, so that the guide pin can be guided in the longitudinal direction of the elongated hole. The direction of longitudinal extension is the direction in which the long hole extends with its largest dimension.

The actuation section and the sliding section can be connected to one another via a connecting web. Further advantageously, the connecting web can protrude essentially perpendicularly from the sliding section in the direction of the actuating section.

The connecting section can be arranged laterally next to the clamping spring, it being possible for the actuating section to be connected to a sliding section lying outside of the insulating material housing, for example. In this way, a sliding actuation can be provided in a simple structural manner. In particular, the connecting web can protrude perpendicularly from the sliding section in the direction of the actuating section. Essentially means in particular that the connecting web does not have to protrude exactly perpendicularly from the sliding section. A deviation of up to 5 degrees, in particular up to 10 degrees, based on a 360° system, is conceivable.

It is conceivable that the guide pin protrudes from the connecting section.

For example, the guide pin can protrude from the connecting web transversely to the conductor insertion direction and thus transversely to the deflection direction of the clamping leg. In this context, transverse means in particular that the guide section protrudes at an angle between 85° and 105°, in particular at an angle of 90°.

The actuating section can bear against the clamping leg of the clamping spring with an actuating contour.

The actuating contour is in particular adapted to the contour of the clamping leg of the clamping spring. Thus, the actuating contour can be designed, for example, as a negative contour of the clamping leg. In this way, the transmission of force from the actuation section to the clamping leg to open the clamping point is further improved.

The sliding section can be mounted such that it can be tilted about a pivot point.

A tilting movement takes place in particular as a rotation through a small angle of rotation. This means that the sliding section can tilt by up to 45°, in particular by up to 25°, in order to get into the locking position or to be guided out of the locking position. In contrast to the tilting movement, a pivoting movement, as is generally used in the case of operating levers, takes place around a larger angle of rotation. During the pivoting movement, the angle of rotation is greater than 60°. Consequently, the sliding section is tilted by a smaller angle than the sliding section is pivoted. Furthermore, no opening and/or closing of the clamping point results from the tilting movement according to the invention. The actuating element is transferred into a latching position by the tilting movement about the support point or is moved out of the latching position so that the actuating element can be held in an open position of the terminal point. When an actuating lever pivots, the pivoting movement causes the clamping point to open or close. In contrast, in the case of the present invention, the opening and/or closing of the clamping point results from a displacement of the actuating element

The pivot point can be arranged in the area of the guide pin. The sliding section can thus be mounted so as to be tiltable about the guide pin. In particular, the sliding section is mounted in the open position of the clamping point, ie in the operating position, such that it can be tilted about the pivot point.

As a result, the actuating element can be moved into a latching position, for example in the actuating position, i.e. when the clamping point is open. The actuating element can be tilted, for example, by the spring force of the clamping leg, in that the spring force of the clamping leg acts on the actuating section when the clamping point is open in such a way that the actuating element is tilted into the locking position about the pivot point. In the detent position, the actuating element is held in the actuating position, so that the electrical conductor can be inserted into the conductor terminal. The tilting of the sliding section about the fulcrum thus represents a tipping, wherein the tilting is the ro tation about the fulcrum, for example in the latching position.

The sliding section can stand up obliquely to the insulating material housing, where the end of the sliding section facing the conductor insertion opening protrudes from the insulating material housing. The sliding section can, for example, be guided out of the locking position again by rotating it in the opposite direction. This can be done, for example, by applying a force to the end of the sliding section that is away. The bearing surface of the sliding section can be designed obliquely. Furthermore, the bearing surface can be V-shaped before geous.

Due to the oblique or V-shaped design, the distance between the sliding section and the insulating material can be reduced section at least on a part of the sliding. Furthermore, the tilting movement about the pivot point can be further improved as a result, since the geometry of the sliding section is thus adapted to the turning movement or rotation.

The insulating housing can have a first housing part and a second housing part. The sliding section of the actuating element can also advantageously be supported on the first housing part, with the guide contour for guiding the actuating element being arranged on the second housing part.

Due to the two-part design of the insulating material housing, the erfindungsge Permitted conductor terminal can be easily assembled by first inserting a contact insert into the first housing part and then terminating the second housing section of the insulating material housing.

By mounting the guide pin on the second housing part and mounting the sliding section on the first housing part, the actuating element can be accommodated captively in the conductor connection terminal, with the guide pin being accommodated in the guide contour in a first assembly step and the second in a second step Housing part closes the guide contour in such a way that the guide pin is captively mounted in the conductor connection terminal.

Alternatively, the guide contour can also be formed by the first and the second housing part, for example a lower contact contour being formed by the first housing part and an upper contact contour, which is opposite the first contact contour, being formed by the second housing part. A reverse variant is also conceivable, in which the guide contour for guiding the actuating element is arranged on the first housing part, with the sliding section of the actuating element being placed on the second housing part.

The bearing surface can be placed on the outside of the insulating material housing, with the sliding section being set up for manual operation. Furthermore, the bearing surface on the outside of the insulating material housing can advantageously be designed to be slidable.

Sliding friction can thus arise between the bearing surface and the outside of the insulating material housing, with the sliding section being able to slide over the outer surface of the housing. The sliding section can also be placed on the outside of the insulating material housing at a distance from it. However, it is also conceivable for the sliding section to be mounted directly on the outside of the insulating material housing.

By being supported on the outside of the insulating material housing, the sliding section remains easily accessible for the user both in the starting position and in the actuating position, whereby the actuating element can thus be guided more easily by the user into the actuating position and back.

The clamping leg can merge into a spring arc, with the spring arc extending into a contact leg, with the contact leg being able to be fixed to a part of the conductor terminal.

The contact leg is designed in particular to contact a part of the conductor connection terminal. The contact leg is preferably designed for contact with the conductor rail.

The busbar and the clamping spring can be designed as a self-supporting contact insert. Spring forces of the clamping spring acting on the housing and/or the actuating element can thus be avoided or at least reduced. In addition, no additional components such as fastening elements for fastening the clamping spring are required.

The indefinite term "a" is to be understood as such and not as a numeral. It is also conceivable that two guide pins are arranged on the actuating element, with both guide pins being displaceably mounted in the insulating housing in a guide contour or in each case in their own guide contour. Wei terhin is conceivable that the conductor terminal is designed as a multi-pole conductor terminal. A 2-pole, a 3-pole or a 6-pole conductor connection terminal with two, three or six corresponding clamping points is conceivable.

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

FIG. 1 shows a conductor connection terminal in a first embodiment in a lateral sectional view with the terminal point closed;

FIG. 2 shows a conductor connection terminal according to FIG. 1 in a lateral sectional view with the terminal point open;

FIG. 3 shows an enlarged section of the conductor connection terminal according to FIG. 2 with an inserted electrical conductor;

FIG. 4a shows an actuating element in a first embodiment in a side view and in a front view;

FIG. 4b shows an actuating element in a second embodiment in a side view and in a front view;

FIG. 5 shows parts of the conductor connection terminal in a side sectional view in an enlarged representation similar to FIG. 3; FIG. 6 shows parts of the conductor connection terminal in a perspective sectional view.

Figure 1 shows a conductor terminal 1 in a first embodiment in a lateral sectional view. The conductor terminal 1 has an insulating housing 2 with a conductor insertion opening 3, wherein an electrical conductor in a direction L Leiterein guide in the conductor terminal 1 can be inserted. A busbar 4 and a clamping spring 5 are arranged in the insulating material housing 2 . The clamping spring 5 has a contact leg 5a, which merges into a spring arc 5b and then extends into a clamping leg 5c. The clamp's angle 5c and the busbar 4 form a terminal point 6 for the electrical conductor to be clamped.

The conductor terminal 1 has an actuating element 7, the actuating element 7 being slidably mounted in the insulating housing 2. The actuating element 7 has an actuating section 7a, the actuating section 7a interacting with the clamping leg 5c in such a way that the actuating section 7a rests against the clamping leg 5c in order to open the clamping point 6. The terminal point 6 is completely closed.

It is clear that a guide pin 8 is arranged on the actuating element 7 , the guide pin 8 being displaceably mounted in a guide contour 9 of the insulating material housing 2 . The guide contour 9 is designed as an elongated Ausneh determination of the insulating material. In this way, the actuating element 7 can be transferred from the initial position, i.e. with the clamping point 6 closed, into the operating position, i.e. with the clamping point 6 open.

It can be seen that both a trough 9a and a projection 9b are arranged within the guide contour 9, with the guide pin 8 being held in the starting position by the projection. Thus, the actuating element 7 cannot be unintentionally transferred from the starting position to the actuating position. the. In order to overcome the projection 9b, an increased force must first be applied so that the guide pin 8 can be moved over the projection 9b.

The operating element 7 can be moved by a user, for example, via a sliding section 7b. A connecting web 7c protrudes perpendicularly from the sliding section 7b, the connecting web 7c connecting the sliding section 7b to the actuating section 7a. It is clear that the bearing surface 7d of the actuating element 7 facing the insulating material housing 2 is arranged at a distance from the insulating material housing 2 . The actuating element 7 can thus only be guided stably from the starting position into the actuating position and back by the mounting of the guide pin 8 in the guide contour 9 of the insulating material housing 2 .

Figure 2 shows a conductor connection terminal 1 according to Figure 1 in a lateral sectional view with the terminal point 6 open, i.e. in the operating position. FIG. 3 shows a conductor connection terminal 1 according to FIG. 2 in a different and enlarged sectional view.

It is clear from FIGS. 2 and 3 that as soon as the actuating element 7 has been transferred into the actuating position, the sliding section 7 tilts about a pivot point 10 , with the pivot point 10 being arranged in the region of the guide pin 8 . If the guide pin 8 is transferred into the trough 9a of the guide contour 9, the spring force of the clamping leg 5c acts on the actuating section 9a in such a way that the actuating element 7 is tilted into a latching position by the sliding section 7b tilting about the pivot point 10 or a rotation 12 the pivot point 10 held det. The actuating element 7 is held in the locking position without external influence, so that an electrical conductor 11 can be inserted into the conductor terminal 1 .

It is also clear that the sliding section 7b stands up obliquely in the locking position relative to the insulating material housing 2 , the end of the sliding section 7b facing the conductor insertion opening 3 protruding from the insulating material housing 2 . The end of the sliding section 7b facing away from the conductor insertion opening 3, on the other hand, is closer to the insulating material housing 2 or can even touch it. The sliding section 7b can be guided out of the locking position again, for example, by a rotation 12 in the opposite direction. This can be done, for example, by applying force to the protruding end in the direction of the insulating material housing 2, ie the end of the sliding section 7b facing the conductor entry opening 3, as illustrated by the force arrow F in FIG

FIG. 4a shows an actuating element 7 according to the invention in a first embodiment in a side view and in a front view. FIG. 4b shows an actuating element 7 according to the invention in a second embodiment in a side view and in a front view. It is clear that both embodiments each have two guide pins 8 and two actuating sections 7a. The actuating elements 7 also each have two connecting webs 7c, each containing a guide pin 8 and an actuating section 7a protruding from one of the connec tion webs 7c. The guide pin 8 and/or the actuation section 7a can protrude perpendicularly from the connecting web 7c. The guide pins 8 and the actuating sections 7a point towards one another. In a mounted state, the clamping spring 5 reaches through the intermediate space between the connecting webs 7c, which are spaced apart from one another.

It is also clear that the bearing surface 7d of the sliding sections 7b is designed at an angle. In particular, the support surface 7d is V-shaped. The inclined support surface 7d can have an angle of X°, where X can preferably have a value between 3° and 15°, in particular a value between 5° and 10°, in relation to a flat support surface 7d. Particularly preferably, X can assume the value of 10°, in particular 5°, in relation to a flat bearing surface 7d.

The formation of the sloping bearing surface 7d allows the distance between the sliding section 7b and an insulating material housing 2 to be reduced at least in part of the sliding portion 7b can be reduced. Furthermore, the tilting movement around a pivot point 10 can be further improved as a result, since the geometry of the sliding section 7b is adapted to the rotational movement or rotation 12 in this way.

The embodiments of the actuating element 7 in FIGS. 4a and 4b differ only with regard to the sliding section 7b. In the first embodiment according to FIG. 4a, a depression is formed on the sliding section 7b, the depression making it possible for the user to have a better grip on the sliding section 7b. In the second embodiment according to FIG. 4b, the sliding section 7b is designed as an elevation, the elevation also leading to improved operability, but at the same time the actuating element 7 in FIG. 4b is designed larger than the actuating element 7 in FIG. 4a.

The actuation section 7a can be guided in a guide contour of the insulating material housing 2, which additionally fixes the actuation section 7a when the clamping point is open and/or supports the aforementioned tilting movement. For example, in the area in which the actuation section 7a is located when the clamping point is open, there can be a trough or depression into which the actuation section 7a lowers when it reaches the open clamping point. This is further illustrated by FIGS. 5 and 6. FIG. 5 shows the conductor terminal 1 in a representation comparable to that in FIG. 3, but without the actuating element 7. It is clear that the guide contour has a trough or depression 13 into which the actuating section 7a dips when it is in the geöff position net clamping point has been reached.

Figure 6 shows this in a perspective view, with clamping spring 5 not being shown in Figure 6, but actuating element 7 being shown. reference list

1 conductor terminal

2 insulating housing

3 wire entry hole

4 power rail

5 clamping spring

5a contact leg

5b spring arch

5c clamp legs

6 clamping point

7 actuator

7a operation section

7b sliding section

7c connecting bridge

7d bearing surface

8 guide pins

9 guide contour

9a hollow

9b protrusion

10 pivot point

11 Electrical Conductor

12 rotating

13 hollow

L Conductor entry direction

F power arrow

Claims

Patent Claims:

1. Conductor terminal (1) with an insulating material housing (2), wherein the insulating material housing (2) has a conductor insertion opening (3) for inserting an electrical conductor's in a conductor insertion direction (L), with a busbar (4) and with a clamping spring ( 5), wherein the clamping spring (5) has a clamping leg (5c) which forms a clamping point (6) for the electrical conductor with the conductor rail (4), and with an actuating element (7), the actuating element (7) being is slidably mounted in the insulating material housing (2) and has an actuating section (7a) and a sliding section (7b), where the actuating section (7a) is designed to open and/or close the clamping point (6), characterized in that the The actuating element (7) has a guide pin (8), the guide pin (8) being slidably mounted in a guide contour (9) of the insulating housing (2) in the conductor insertion direction (L).

2. Conductor connection terminal (1) according to claim 1, characterized in that the actuating section (7a) for opening and/or closing the clamping point (6) is in operative connection with the clamping leg (5c) of the clamping spring (5).

3. Conductor connection terminal (1) according to claim one of the preceding claims, characterized in that the guide contour (9) is designed as an elongated recess, the guide contour (9) being designed in such a way that the guide pin (8) in an open position and /or the closed position of the clamping point (6) is held in a holding position.

4. Conductor connection terminal (1) according to claim 3, characterized in that a trough (9a) is arranged in the guide contour (9), the guide pin (8) in an open position and/or closed position of the clamping point (6) in the trough (9a) is held.

5. Conductor connection terminal (1) according to any one of the preceding claims, characterized in that the actuating section (7a) and the sliding section (7b) are connected to one another via a connecting web (7c).

6. conductor terminal (1) according to any one of claims 5, characterized in that the connecting web (7c) protrudes substantially perpendicularly from the sliding portion (7b) in the direction of the actuating portion (7a).

7. Conductor connection terminal (1) according to any one of the preceding claims, characterized in that the actuating section (7a) with an Actuate supply contour on the clamping leg (5c) of the clamping spring (5) rests.

8. conductor connection terminal (1) according to any one of the preceding claims, characterized in that the bearing surface (7d) of the sliding portion (7b) is formed obliquely.

9. Conductor connection terminal (1) according to one of the preceding claims, characterized in that the sliding section (7b) is mounted tiltably about a pivot point (10).

10. conductor terminal (1) according to claim 8 or 9, characterized in that the bearing surface (7d) is V-shaped.

11. Conductor connection terminal (1) according to one of the preceding claims, characterized in that the insulating housing (2) has a first housing part and a second housing part.

12. Conductor connection terminal according to claim 11, characterized in that the sliding section (7b) of the actuating element (7) is mounted on the first housing part, the guide contour (9) for guiding the actuating element (7) being arranged on the second housing part.

13. conductor terminal (1) according to any one of the preceding claims, characterized in that the bearing surface (7d) on the outside of the insulating housing (2) is supported, wherein the sliding portion (7b) is set up for manual operation.

14. conductor terminal (1) according to claim 13, characterized in that the bearing surface (7d) on the outside of the insulating housing (2) is designed to be slidably displaceable.

15. Conductor connection terminal (1) according to one of the preceding claims, characterized in that the clamping leg (5c) merges into a spring bow (5b), the spring bow (5b) extending into a contact leg (5a), the contact leg (5a ) on a part of the conductor terminal (1) can be fixed.

16. conductor terminal (1) according to any one of the preceding claims, characterized in that the busbar (4) and the clamping spring (5) are designed as a self-supporting contact insert.