DE102018100261B3 - Conductor terminal - Google Patents

Abstract

A conductor terminal (1) with an insulating housing (2), a clamping spring (3) for clamping an electrical conductor and an actuating push-button (10) will be described. The actuating pushbutton (10) is displaceably mounted in the insulating housing (2) and has an actuating portion (11) for acting on the clamping spring (3) and an actuating push head (18) accessible from the outside of the insulating housing (2) with a depression (19) Recording an actuating tool (12). The depression (19) has a depth which increases from the central region (Z) to the edge regions (R).

Description

The invention relates to a conductor terminal with an insulating housing, a clamping spring for clamping an electrical conductor and an actuating pushbutton, which is displaceably mounted in the insulating housing and an actuating portion for acting on the clamping spring and an accessible from the outside of the insulating housing actuating push head with a recess for receiving an actuating tool Has.

Such conductor terminals are known in many forms and are, for example, used as terminal blocks.

DE 10 2015 120 063 B3 shows such a conductor terminal with a pusher, which has an actuating shaft for receiving an actuating tool. The actuating shaft opens into a receiving slot. The actuating head has in this way a funnel-shaped depression, which leads in the central region with the passage opening to the clamping spring.

DE 10 2007 050 683 B4 discloses a conductor terminal with a tiltably mounted in a guide channel actuating push-button. The actuating push-button has on its actuating push-button a recess for receiving the actuating tool, which is slit-shaped or cross-shaped. The bottom of the depression is flat.

DE 10 2013 104 394 A1 shows a conductor terminal with an actuating push-button, which has a groove-shaped recess at its actuating push head, which merges on one side in a spherical recess.

DE 298 19 517 U1 shows a Zugfederanschlussklemme with a locking receptacle having a groove-shaped plug-in receptacle with a matched to the free end of a screwdriver V-shaped opening angle.

DE 20 2009 016 326 U1 discloses a plug assembly having an insulating housing that has a guide channel for an actuating trigger. The actuating handle may have a contour for attaching a tool, such as a screwdriver. In addition, a hole may be provided for test taps in the contour. It is shown a slot-shaped contour with a flat groove bottom.

DE 10 2013 111 574 A1 shows a spring force clamping connection with an actuating push button, which also has a groove-shaped actuating recess.

DE 10 2013 108 952 A1 shows an actuating element for actuating a clamping spring of a terminal having an engagement surface for a tool at its upper end. The engagement surface is configured as a slot distributed in the center with a flat groove bottom.

DE 10 2010 015 457 A1 discloses a spring force clamping connection with an actuating element, which likewise has a slot-shaped engagement groove, which conically tapers towards the groove base, for receiving an actuating tool.

DE 20 2017 103 185 U1 discloses a spring clamp with a pusher having at its upper end a recess for receiving an actuating tool. The bottom of the recess can be conically tapered, ie formed concave.

Based on this, it is an object of the present invention to provide an improved conductor terminal, which ensures a more reliable guidance of the actuating handle when subjected to an actuating tool.

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

It is proposed that the recess on the actuating push head has an increasing depth from the central area to the edge areas. Thus, the force acting on the actuating lever from the operating force is directed substantially in the direction of the longitudinal axis of the actuating lever, even if the actuating tool is not exactly in the alignment of the actuating lever in the direction of extension of the longitudinal axis, but obliquely attached thereto. This prevents the actuating push-button from becoming excessively inclined and possibly abutting components of the conductor connection terminal, such as, for example, a busbar.

This is achieved by sloping surfaces of the soil, i. by forming the bottom plane of the depression with the result that the central region of the depression has a smaller depth than the edge regions of the depression. These surfaces are referred to below as bottom surfaces or surface sections.

The recess may be groove-shaped (and thus forms a groove-shaped contour section on the actuating push-button). The groove bottom of the recess is diametrically opposite from each other Edge regions of the groove-shaped depression to the common central region obliquely to the end face of the actuating push head towards extending. The groove-shaped recess is thus designed as a slot or as a groove, the groove bottom is not flat (ie horizontal plan), but from the opposite edge regions to the common central region has sloping sections.

The actuator head may also have a shaped recess, e.g. is cylindrical or frusto-conical or formed in any other suitable form, which projects beyond the groove-shaped contour portion of the recess. The recess is thus formed on the one hand by the slot and on the other hand by the recess leading into the slot and laterally widening the slot. With such an additional recess in addition, the operation is made possible by a cross-sectionally round actuating tool, such as. A Phillips screwdriver. The recess may be central and lie in the alignment of the central or central axis of the actuating handle.

The depression may have a convexly curved bottom plane. The bottom surfaces of the ground plane are curved and not straight as in a triangular or trapezoidal cross-section. An obliquely attached actuating tool can thus rest only at one point of the ground plane, in order to ensure in this way an acting at the sharpest possible angle to the longitudinal extension direction of the actuating lever actuating force on the actuating lever.

However, the recess can also have a trapezoidal or triangular tapered bottom plane in cross section. The ground plane, which tapers in a triangular cross-section, runs relatively pointedly in the central area. The trapezoidal in cross-section ground level, however, has a flat platform in the central region, which is transverse to the longitudinal direction of the actuating lever. When placing the operating tool on this platform in the central region, the actuating force is then applied perpendicular to the platform in the longitudinal extension direction of the actuating handle, so that in this way tilting of the actuating handle is avoided. If the operating tool obliquely acts on the adjacent to the platform inclined surfaces of the trapezoidal depression in cross-section, the actuating force is still deflected substantially in the longitudinal direction of the actuating lever and prevents excessive tilting of the actuating lever compared to a generally flat bottom plane.

However, the depression can also have a pyramid-shaped, truncated pyramid-shaped, conical, frusto-conical or paraboloidal protruding toward the end face of the actuating push-head. In this embodiment, the bottom sloping toward the edge portions of the recess is provided not only two-dimensionally as in a groove-shaped recess, but three-dimensionally. The risk of tilting or tilting of the actuating handle when moving in a pusher channel of the insulating material is further reduced in this way.

• 1 - Seitenansicht einer Leiteranschlussklemme mit Betätigungswerkzeug in der Schnittlinie C-C;
• 2 - Schnittansicht der Leiteranschlussklemme aus 1 im Schnitt C-C;
• 3 - Seitenansicht der Leiteranschlussklemme aus 1 mit Betätigungswerkzeug in der heruntergedrückten Stellung des Betätigungsdrückers in der Schnittlinie D-D;
• 4 - Schnittansicht der Leiteranschlussklemme aus 3 im Schnitt D-D;
• 5 - Seitenansicht des Betätigungsdrückers für die Leiteranschlussklemme aus 1 bis 4 mit der Schnittlinie E-E;
• 6 - Schnittansicht des Betätigungsdrückers aus 5 im Schnitt E-E;
• 7 - Perspektivische Darstellung des Betätigungsdrückers aus 5 und 6.

The invention will be explained in more detail with reference to an embodiment with the accompanying drawings. Show it:

• 1 - Side view of a conductor terminal with operating tool in the section line CC ;
• 2 - Section view of the conductor connection terminal 1 on average CC ;
• 3 - Side view of the conductor connection terminal off 1 with operating tool in the depressed position of the actuating lever in the cutting line DD ;
• 4 - Section view of the conductor connection terminal 3 on average DD ;
• 5 - Side view of the operating connector for the conductor connection terminal off 1 to 4 with the cutting line EE ;
• 6 - Section view of the actuating lever 5 on average EE ;
• 7 - Perspective representation of the actuating lever from 5 and 6 ,

1 shows a side view of a conductor terminal 1 in the form of a terminal block. The conductor connection terminal 1 has an insulating material housing 2 with conductor connections for connecting electrical conductors. These are in conductor insertion channels of the insulating material 2 led to a nip out of a clamping spring 3 and a power rail 4 is formed. The busbar 4 has openings for insertion of an electrical conductor. A clamping spring 3 is suspended in each case in one of these openings, with a clamping leg 6 one into a conductor entry channel 5 plugged electrical conductor to a clamping edge of the busbar 4 anzuklemmen.

In the illustrated embodiment, the bus bar has 4 in each case a clamping spring 3 a so-called material passage, in the guide walls 7 at the conductor insertion channel 5 diametrically opposite underside of the busbar 4 protrude. This forms a guide channel for the electrical conductor and the current cross section for diverting the current from the electrical conductor via the terminal point in the busbar 4 increased.

The insulating material housing 2 has at the bottom, for example, a snap foot 8th , with which the insulating material housing 2 can be snapped onto a mounting rail (not shown).

In the insulating housing 2 is in each case next to a conductor insertion channel 5 an actuating channel 9 introduced, each to the clamping leg 6 a clamping spring 3 leads or ends there. In this actuation channel 9 is an actuation lever 10 displaceable in the longitudinal direction L the push-button 10 stored. From the push-button 10 is in the side view only one for acting on the clamping spring 3 on the clamping leg 6 mounted operating section 11 to recognize.

The push button 10 is from the outside of the insulating material 2 accessible, leaving an operating tool 12 as shown on the operating handle head (not visible) can be placed. By a in the longitudinal direction L the push-button 10 Actuating force acting on the operating head can be the operating lever 10 now in the longitudinal direction L to the busbar 4 be relocated. This will be the actuating leg 6 the clamping spring 3 against the spring force of the clamping spring 3 to the opposite plant leg 13 the clamping spring 3 moves and the between the end of the clamping leg 6 and the clamping edge of the busbar 4 formed clamping point for clamping an electrical conductor open. As a result, an electrical conductor inserted force-free and vice versa a clamped electrical conductor removed again and from the conductor insertion channel 5 of the insulating material housing 2 be pulled out.

2 shows a sectional view of the conductor terminal 1 out 1 , It becomes clear now that the actuation lever 10 at its lower end a tapered actuating portion 11 Has. This is designed to be in the conductor receiving opening 14 the busbar 4 immerse when the clamping leg 6 the clamping spring 3 with the push button 10 in the longitudinal direction L the push-button 10 down also into the ladder receiving opening 14 is pressed into it.

It becomes clear that the actuation lever 10 longitudinally displaceable in an actuating channel 9 of the insulating material housing 2 is stored. The push button 10 has it in the transition of the operating section 11 to the central section 16 of the push button stop dogs 17 , which together with the insulating material 2 form a stop and slipping out of the actuating handle 10 from the insulating material upwards, ie opposite to the longitudinal direction shown L prevented.

It becomes clear that the actuation lever 10 at its the operating section 11 diametrically opposite end of an actuating push head 18 having. At the front of the operating handle head 18 is a depression 19 introduced, in the front end of an actuating tool 12 , such as a slotted screwdriver, can dip.

It becomes clear that the depression is one of the central area Z to the diametrically opposite edge areas R the depression 19 has increasing depth. The bottom of the depression 19 is thus convexly curved or, as in the example shown, designed to be trapezoidal in cross section. The central area Z is here as a transverse to the longitudinal direction L the push-button 10 newly trained platform 20 designed. At this level platform 20 close obliquely sloping surface sections on the right and left 21 on.

The depression 19 is groove-shaped in the illustrated embodiment, ie it is in the illustrated section from left to right oblong and transverse to the illustrated cutting direction relatively narrow with straight or slightly obliquely inclined side walls.

If now the operating tool 12 as outlined inclined to the longitudinal direction in the depression 19 on the actuating push head 18 is placed, then the operating force of the actuating tool 12 still at a very small acute angle to the longitudinal direction L on the push button 10 exercised. This causes that on the push button 10 effective tilting moment is much more reduced than in a recess with a flat bottom.

The inclined, running towards the central region in the direction of the outer end face of the actuating push head inclined surfaces of the bottom, ie the surface portions 21 , make sure the push button 10 at its displacements towards the busbar 4 much less from the longitudinal direction L Tilted out than this without this specific contour of the recess 19 the case would be. This ensures that the operating section 11 actually in the ladder receiving opening 14 the busbar 4 dips and not on the power rail 4 canted.

3 shows a side view of the conductor terminal 1 out 1 , Here is the operating tool 12 Now continue in the insulating material 2 pushed in to the push button 10 in the direction of the busbar 4 to shift and the clamping leg 6 counteracting the spring force of the clamping spring 3 to the opposite plant leg 13 to push. The terminal point is opened for clamping an electrical conductor.

4 shows a sectional view in section in the in the 3 sketched cut DD , It is now apparent that the actuation lever 10 in the longitudinal direction L to the busbar 4 pushed down. The operating section 11 dive into the ladder receiving opening 14 the busbar 4 together with the clamping leg 6 the clamping spring 3 on. It becomes clear that the actuation lever 10 in this case slightly to the longitudinal direction L or the longitudinal axis of the actuating channel 9 is tilted. This among other things by the inclination of the operating tool 12 with respect to the longitudinal direction L the push-button 10 or the corresponding longitudinal axis of the actuating channel 9 caused tilting moments on the actuating handle 10 but are not that strong that the push-button 10 in its downward shift to the operating position on the busbar 4 abuts.

By training the depression 19 with a convexly curved bottom plane, ie with the surface sections 21 , together with the sketched trapezoidal cross section of the ground plane (surface sections 21 ) are on the push button 10 acting actuating forces as far as possible in the longitudinal direction L effective.

5 shows a side view of the actuating handle 10 the conductor connection terminal 1 from the above figures. It becomes clear that the actuation lever 10 an actuating push head 18 with a cross section extending from the middle section 16 the push-button 10 widened starting. This indicates the actuation head 18 collar-like projections on in the appropriately shaped actuating channel 9 of the insulating material housing 2 can be brought into it.

Diametrically opposite to the actuating push head 18 has the push button 10 one at the middle section 16 subsequent operating section 11 which tapers to the free end. Visible is also the web-like stop 17 on one side of the actuating handle 10 , On the invisible opposite side is also a corresponding web-like stop lug 17 available.

6 shows a sectional view of the actuating handle 10 out 5 in the section line shown there EE , It becomes clear that the operating section 11 at the free end of the push button 10 tapered tapered. Furthermore, in the transition between the operating section 11 and the middle section 16 laterally projecting stop lugs 17 present, which extend in the direction of the web.

Visible is also the operating handle head 18 on the operating section 11 diametrically opposite side of the actuating handle 10 , The operating handle head 18 has at its upper end a groove-shaped in the cut EE from left to right slit-like depression 19 , In the central area of the depression 19 is also a frustoconical central recess 22 introduced, as outlined in the direction of view on the groove-shaped contour of the recess 19 protrudes. The depression 19 is thus in the central area Z essentially by the frusto-conical recess 22 and in the border areas R through the groove-shaped contour with an angle to the edge regions R formed sloping ground levels. In the central area Z the depression 19 is a level platform 20 available. The level of the platform 20 stands transversely to the longitudinal direction L the push-button 10 , An actuating force acting there thus acts essentially in the longitudinal direction of extension L on the central axis M of the actuating lever 10 ,

Through to the edge areas R obliquely to the central axis M Asked areas of the ground level 21 the depression 19 follows an actuating force applied there at an acute angle to the central axis M of the actuating lever 10 , This will cause a tilting moment on the actuation lever 10 reduced compared to a situation where the ground plane (ie the surface sections 21 ) is plane and is perpendicular to the central axis M. One in this case offset to the central axis M to the ground plane (ie the surface sections 21 ) acting force then leads to a larger tilting moment, as this by the inclination to the central axis M occurs.

7 shows a perspective view of the actuating handle 10 out 5 and 6 , It becomes clear that the depression 19 is groove-shaped and one in the operating handle head 18 has transversely extending slot. In the central area has the recess 19 also the frusto-conical recess 22 which the groove-shaped contour of the recess 19 widened laterally out of the slot. This central recess 22 thus protrudes beyond the groove-shaped contour portion of the recess 19 laterally out on both sides and goes into the slot-shaped groove, moreover.

LIST OF REFERENCE NUMBERS

1

Conductor terminal

2

Insulated

3

clamping spring

4

conductor rail

5

Conductor insertion channel

6

clamping leg

7

guide walls

8th

Snap-on foot

9

actuating channel

10

operating pusher

12

operating tool

11

actuating section

13

contact leg

14

Conductor receiving opening

16

Central section

17

stop dogs

18

Operating pusher head

19

deepening

20

platform

21

surface sections

22

drilling

L

Longitudinal extension

R

border areas

Z

central area

Claims (6)

Conductor terminal (1) having an insulating housing, a clamping spring (3) for clamping an electrical conductor and an actuating push-button (10) which is slidably mounted in the insulating housing (2) and an actuating portion (11) for acting on the clamping spring (3) and a from the outside of the insulating housing accessible actuating push head (18) having a recess (19) for receiving an actuating tool (12), characterized in that the recess (19) from the central region (Z) to the edge regions (R) increasing depth , Conductor connection terminal (1) to Claim 1 , characterized in that the recess (19) is groove-shaped and has a to the diametrically opposite edge regions (R) of the groove-shaped recess (19) to the common central region (Z) obliquely to the end face of the actuating push head (18) extending groove base. Conductor connection terminal (1) to Claim 2 , characterized in that the actuating push head (18) has a recess (22) which projects beyond the groove-shaped contour portion of the recess (19). Conductor terminal (1) according to one of Claims 1 to 3 , characterized in that the recess (19) has a convexly curved bottom plane (surface portion 21). Conductor terminal (1) according to one of Claims 1 to 3 , characterized in that the recess (19) has a trapezoidal or triangular in cross section bottom plane (surface portion 21). Conductor connection terminal (1) to Claim 1 , characterized in that the recess (19) has a to the front side of the actuating head towards pyramidal, truncated pyramidal, conical, frusto-conical or paraboloidal projecting ground plane (surface portion 21).

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