EP3183777A1 - Electrical connection terminal - Google Patents

Abstract

The invention relates to an electrical connection terminal (100) having a housing (10) which has at least one conductor insertion opening (11a, 11b), having a busbar (12) which is arranged in the housing (10), having at least one conductor clamping apparatus (13a, 13b) which is rotatably mounted in the housing (10) and can be pivoted into an open position and a closed position, wherein, in the closed position, a conductor (200a, 200b, 200c, 200d) inserted into the conductor insertion opening (11a, 11b) can be clamped against the busbar (12) by means of the conductor clamping apparatus (13a, 13b), and having at least one actuating element (25a, 25b) which is rotatably mounted in the housing (10) and can be used to actuate the conductor clamping apparatus (13a, 13b) to change to the open position and the closed position, wherein the conductor clamping apparatus (13a, 13b) has at least one first spring element (15a, 15b), wherein the first spring element (15a, 15b) has a clamping limb (17a, 17b) which has a first clamping region (21a, 21b) for clamping an inserted conductor (200a, 200b, 200c, 200d) against the busbar (12) and, at a distance from the first clamping region (21a, 21b), has a second clamping region (22a, 22b) for clamping an inserted conductor (200a, 200b, 200c, 200d) against the busbar (12).

Description

 Electrical connection terminal

The invention relates to an electrical terminal with a housing having at least one conductor insertion opening, with one arranged in the housing

 Conductor rail, with at least one rotatably mounted in the housing guide clamping device which is pivotable in an open position and in a closed position, wherein in the closed position in the

Conductor insertion opening inserted conductor by means of

Laderklemmvorrichtung is clamped against the busbar, and with at least one rotatably mounted in the housing actuating element, by means of which

 Laderklemmvorrichtung for transfer to the open position and the closed position is actuated, wherein the conductor clamping device has at least a first spring element.

Such an electrical terminal is

For example, from DE 10 2008 039 868 AI, in which a designed as a leg spring spring element by means of an actuating element for clamping a conductor inserted into the housing in an open position and a closed position is pivotable. The

Spring element has a clamping leg, a

 Actuating leg and one of the two legs

interconnecting arcuate portion, wherein the clamping leg a nip for a

forms to be connected stripped conductor. In the housing, a bearing pin is formed on which the spring element is pivotably mounted such that the spring element can be pivoted from a first open position to a second closed position. In the first position of the spring element can through the

Conductor insertion opening introduced stripped

electrical conductor are inserted into the terminal point without the clamping leg must be deflected against its spring force and the spring force of the spring element. In the second position of the spring element of the

electrical conductor between an end portion of the

Clamping leg and a conductor rail positioned in the conductor rail electrically conductively clamped, wherein the clamping leg is deflected from its rest state.

The invention has for its object to provide an electrical terminal available by means of which conductors can be securely clamped with different sized cross-sections.

In an electrical terminal of the type described in more detail, this object is achieved in that the first spring element has a clamping leg, which has a first terminal region for clamping an inserted conductor against the busbar and spaced from the first terminal region a second

Clamping area for clamping an inserted conductor against the busbar has.

Advantageous embodiments and advantageous

Further developments of the invention are specified in the subclaims.

The first spring element of the conductor clamping device of the electrical terminal is characterized essentially by the fact that this now not only one Clamping region, but two clamping regions for inserted into the conductor insertion opening conductor. The two clamping areas are preferably for conductors with

provided in different cross-sections, so that the first clamping area is preferably used for clamping conductors with a smaller conductor cross section and the second clamping area is preferably used for clamping conductors with a larger conductor cross-section. The two clamping areas are along the length of the clamping leg of the first

Spring element formed, wherein it is preferably

is provided that the second clamping area on the

Clamping leg of the first spring element closer to the

Fulcrum or the bearing journal, on which the

Laderklemmvorrichtung or the spring element is rotatably mounted, arranged or designed as the first clamping area. By training the second

Clamping area, which is provided in particular for conductors with a larger conductor cross-section, closer to the pivot point of the spring element, the required

Deflection of the clamping leg of the spring element can be reduced at a clamping of a conductor with a larger conductor cross-section, whereby the force acting on the clamping leg and thus on the spring element load can be reduced at a clamping of a conductor with a larger cross-section. The fact that the clamping leg of the spring element now has two clamping areas, is for each conductor cross section, in particular for

Conductor cross sections from 10 mm ² to 95 mm ² a safe

Clamping possible by the clamping for the

different conductor cross sections through the at two different positions on the clamping leg

arranged clamping areas can be customized. It is preferably provided that the first clamping region is formed on an edge region of an end portion of the clamping leg of the first spring element. Characterized in that the first clamping region at an edge region of a

 End portion of the clamping leg is formed in the clamping of a conductor with a small

Conductor cross section only a small deflection of the

Clamping leg of the spring element necessary to secure clamping of the conductor with a small

 To realize conductor cross section. The clamped conductor can be kept clamped by the clamp on the edge region against pulling forces acting on the conductor, whereby a self-locking clamping of the conductor can be formed.

Further, it is preferably provided that the clamping leg has a U-shaped or V-shaped curvature, wherein at the curvature preferably the second clamping region of the clamping leg of the first spring element is formed. The U-shaped or V-shaped curvature is preferably formed in the direction of the busbar and thus the imported, to be clamped conductor, so that the clamping leg in the region of the curvature and thus closer with its second clamping region in the direction of

 Conductor designed directed as the remaining part of the clamping leg. This can ensure that a conductor with a larger

Conductor cross section at introduction to the

Conductor insertion opening via the second clamping portion of the clamping leg of the first spring element against the

Busbar can be clamped. Due to the formation of the second clamping region in the region of a curvature of the Clamping leg can be achieved that a high

Clamping pressure can be applied by means of the clamping leg on the conductor. The vault extends

preferably over the entire width of the clamping leg, so that the second clamping region of the clamping leg extends over the entire width of the clamping leg, whereby a flat clamping or a flat pressure surface over the width or the cross section of the conductor can be applied to the conductor. This can be on the

inserted conductor can be increased clamping force and in particular can also the risk of slippage or tilting of a clamped conductor due to the flat contact pressure of the conductor over the second

Clamping area of the clamping leg in the direction of

Busbar be reduced.

The conductor clamping device preferably has at least one second spring element, wherein preferably the first spring element and the second spring element are mounted as a spring assembly about a jointly formed in the housing pivot point. The spring elements of the spring assembly are preferably directly adjacent to each other, so that by using a spring assembly of two or more than two spring elements on the head to be clamped

applied spring force or contact force can be increased, which in particular for large conductor cross sections, the contact force for secure clamping of imported

Ladder can be further increased. To directly plug conductors with a small one

To allow conductor cross-section, the spring elements of the spring assembly preferably protrude differently far into the conductor insertion opening by the length of the Clamping leg of the individual spring elements of the spring assembly is different in size. With more than two spring elements, the spring elements preferably protrude in a stepped length into the conductor insertion opening. The first spring element with the two clamping regions preferably protrudes furthest into the conductor insertion opening. Ladder with a small conductor cross section will then be

Preferably only with a spring element or a

Clamping leg of a spring element of the spring assembly,

in particular the first spring element with the two

 Clamping areas, pressed against the busbar, whereby a direct insertion of the conductor to be clamped can be made possible. For conductors with a large conductor cross-section, however, they can work with several or all

Spring elements and thus with several or all

 Clamping legs of the spring elements of the spring assembly are pressed against the busbar. This allows a particularly secure clamping of conductors with different sized conductor cross sections by means of the electrical

Terminal can be achieved. The second spring element of the conductor clamping device is preferably designed to clamp conductors with a large conductor cross-section. For this purpose, it is preferably provided that the second

Spring element has a clamping leg whose length is shorter than the length of the clamping leg of the first spring element. Become a leader with a small one

Clamped conductor cross section, the clamping is done

preferably exclusively by means of the first

Spring element, so that no contact between the second spring element and the conductor is formed. If conductors are clamped with a larger conductor cross-section, the clamping of the conductor is preferably carried out both by means of the first spring element and by means of the second spring element. The clamping leg of the second spring element is

preferably substantially rectilinear with one

Clamping area formed at an edge region of an end portion of the clamping leg. When clamping a conductor with a large conductor cross-section, the clamping of the conductor takes place at the edge region of the end portion of

Clamping leg of the second spring element and the second clamping region of the first spring element, which preferably not at an edge region of a

End portion of the clamping leg of the first

Spring element, but between the edge region of the end portion of the clamping leg and the pivot point of the first spring element or the conductor clamping device is formed. The second clamping area of the first

 Spring element forms an additional pressure point on the conductor for the clamping region of the second spring element acting on the conductor. The clamping of the conductor via the second clamping region of the first spring element and the clamping of the conductor via the clamping region of the second spring element preferably take place as close together as possible by the second clamping region of the first

Spring element immediately adjacent to the clamping region of the second spring element on the imported, too

clamped conductor acts. This makes it possible for the required stripping length of the inserted, too

clamping conductor can be reduced. In particular, the required stripping length of the conductor to be clamped can preferably be reduced to a minimum. This also makes it possible to clamp the conductor with a

To provide end sleeve. In addition, by reducing the necessary stripping length of the conductor, the necessary length for insertion of the conductor can be reduced in turn, the entire terminal can be made smaller and thus made more compact.

Further, it may be preferably provided that the housing has two conductor insertion openings and two conductor clamping devices and two actuating elements are arranged in the housing, wherein the two actuating elements are preferably opposite each other and are arranged rotatably opposite to each other. Due to this special arrangement with multiple actuators in one

 Housing a terminal, the necessary space can be divided as space-saving with a provision of two wire connections, whereby the entire

electrical terminal can be made very compact.

Hereinafter, the invention with reference to the accompanying drawings by way of a preferred

Embodiment explained in more detail.

Show it:

Fig. 1 is a schematic sectional view of a

 electrical terminal according to the invention with an inserted, a first

 Conductor cross-section conductor,

2 is a further schematic sectional view of the electrical terminal shown in Fig. 1 according to the invention with an inserted conductor having a second conductor cross-section, 1 shows a further schematic sectional view of the electrical terminal according to the invention shown in FIG. 1 with an inserted conductor having a third conductor cross-section,

1 is a schematic sectional view of the electrical terminal shown in FIG. 1 according to the invention with an inserted, a conductor cross-section corresponding to the conductor shown in Figure 3 conductor, wherein on the conductor a wire end sleeve is arranged, and a schematic single representation of a first spring element of in Figure 1 to 4 shown electrical terminal.

1 to 4 is a sectional view of an electrical terminal 100 according to the invention is shown, which has a housing 10 with a first

Conductor opening IIa and a second

 Conductor insertion opening IIb has. In the housing 10, a bus bar 12 is arranged, against which inserted into the conductor insertion openings IIa, IIb conductors 200a, 200b, 200c, 200d with different

Conductor cross sections can be clamped contacting.

In the embodiments shown here, the bus bar 12 extends from the first conductor insertion opening IIa up to the second conductor insertion opening IIb, so that in the first conductor insertion opening IIa

inserted conductor to the same power rail 12th

contacting can be clamped as the introduced into the second conductor insertion opening IIb conductor. Further, in the housing 10, a first

Conductor clamping device 13a and a second

Conductor clamping device 13b arranged, wherein the first conductor clamping device 13a is arranged opposite to the second conductor clamping device 13b. The two

Laderklemmvorrichtungen 13 a, 13 b are each rotatably mounted on a bearing pin 14 a, 14 b, so that the

Laderklemmvorrichtungen 13a, 13b separated from each other in a closed position and in an open position can be transferred. In Figs. 1 to 4 are the

Laderklemmvorrichtungen 13a, 13b each in one

shown closed position. The conductor clamping devices 13a, 13b each have a first spring element 15a, 15b and a second spring element 16a, 16b. The spring elements 15a, 15b, 16a, 16b each of a conductor clamping device 13a, 13b are arranged here in each case combined to form a spring assembly, wherein the first spring element 15a, 15b rests against an inner surface of the second spring element 16a, 16b.

The spring elements 15a, 15b, 16a, 16b are as

Leg springs trained, each one

Clamping legs 17a, 17b, 18a, 18b and a

 Actuating legs 19a, 19b, 20a, 20b have. By means of the clamping leg 17a, 17b, 18a, 18b is in the

Conductor insertion opening IIa, IIb inserted conductor 200a, 200b, 200c, 200d clamped against the busbar 12. In this case, the clamping leg 17a, 17b of the first, inner spring element 15a, 15b has a greater length than the clamping leg 18a, 18b of the second, outer

Spring element 16a, 16b, so that when clamping conductors with a small conductor cross-section they are clamped only by means of the clamping leg 17a, 17b of the first spring element 15a, 15b against the busbar 12 and the terminals of conductors with a large conductor cross-section by means of the clamping leg 18a, 18b of the second

 Spring element 16a, 16b and the clamping leg 17a, 17b of the first spring element 15a, 15b are clamped against the busbar 12. The first spring element 15a, 15b, which is shown once again in a detail in FIG. 5, has at its clamping leg 17a, 17b a first clamping region 21a, 21b for clamping an inserted conductor 200a, 200b with a small conductor cross-section against the busbar 12 and spaced from the first clamping region 21a, 21b a second clamping region 22a, 22b for clamping an inserted conductor 200c, 200d with a large

Conductor cross section against the busbar 12. Conductors 200a, 200b with a small conductor cross-section preferably have a conductor cross-section -S 40 mm ² . Conductors 200c, 200d with a large conductor cross section preferably have a conductor cross section> 40 mm ² . The first clamping region 21a, 21b of the first spring element 15a, 15b is formed on an edge region of an end portion of the clamping leg 17a, 17b of the first spring element 15a, 15b. The first clamping region 21a, 21b serves in particular for conductors with a small

Clamping conductor cross-section as shown in particular in Fig. 1 and Fig. 2, by only the first

Clamping area 21a, 21b against the inserted conductor 200a, 200b jams to the conductor 200a, 200b against the Power rail 12 to press. By contrast, the second clamping region 22a, 22b has no contact with the latter in the case of these conductors 200a, 200b with a small conductor cross-section

inserted conductor 200a, 200b. In the embodiment shown in Fig. 1, the conductor 200a preferably has a conductor cross section of about 10 mm ² and the conductor 200b shown in Fig. 2 has approximately one

Conductor cross section of 35 mm ² on. The second clamping region 22a, 22b of the first spring element 15a, 15b is spaced from the edge region of the

End portion of the clamping leg 17a, 17b and thus closer to that formed by the bearing pin 14a, 14b

Fulcrum of the spring element 15a, 15b or the

Conductor clamping device 13a, 13b arranged as the first clamping portion 21a, 21b of the clamping leg 17a, 17b of the first spring element 15a, 15b.

To form the second clamping region 22a, 22b, the clamping leg 17a, 17b has a U-shaped or V-shaped

Vault 23a, 23b on. The curvature 23a, 23b is formed in the direction of the busbar 12, so that in the region of the curvature 23a, 23b of the clamping legs 17a, 17b closer in

Direction of the busbar 12 and thus the inserted conductor 200a, 200b is directed than the remaining area of the clamping leg 17a, 17b.

For conductors 200c, 200d with a large conductor cross-section, as shown for example in Fig. 3 and Fig. 4, wherein here in each case a conductor 200c, 200d with a

Conductor cross-section of approximately 50 mm ^{2 is} shown, the clamping via the second clamping portion 22a, 22b of the clamping leg 17a, 17b of the first spring element 15a, 15b is carried out and simultaneously via the single clamping portion 24a, 24b of the clamping leg 18a, 18b of the second spring element 16a, 16b, which is formed on an edge region of an end portion of the clamping leg 18a, 18b.

As shown in Fig. 3 and Fig. 4, the second clamping portion 22a, 22b of the clamping leg 17a, 17b of the first spring element 15a, 15b acts immediately adjacent to the clamping portion 24a, 24b of the clamping leg 18a, 18b of the second spring element 16a, 16b the inserted conductor 200c, 200d. In this way, a particularly good clamping action can be achieved on an inserted conductor 200c, 200d with a large conductor cross-section and, moreover, in particular with conductors 200c, 200d with a large conductor

Conductor cross section the necessary length for stripping the inserted conductor 200c, 200d are reduced to a minimum.

As shown in particular in FIG. 4, in the case of the first spring element 15a, 15b, only the second one acts

Clamping portion 22a, 22b of the clamping leg 17a, 17b on the inserted conductor 200d, wherein the first clamping portion 21a, 21b of the clamping leg 17a, 17b of the first spring element 15a, 15b no longer contact with the inserted conductor 200d and thus no contact force on the inserted conductor 200d. Thereby, the required length for stripping the conductor 200d can be further reduced, and moreover, the conductor 200d can be provided with a wire end ferrule 210 as shown in FIG. The conductor 200d shown in Fig. 4 is also inserted by means of an insertion bridge 300 in the conductor insertion opening IIa. To actuate the conductor clamping device 13a, 13b and thus of the spring elements 15a, 15b, 16a, 16b, two actuating elements 25a, 25b designed as eccentrics are arranged in the housing 10. The actuating elements 25a, 25b are rotatably mounted in the housing 10 via bearing journals 26a, 26b. The actuating elements 25a, 25b have a main body 27a, 27b and an actuating arm 28a, 28b integrally formed on the main body 27a, 27b, which has a smaller thickness than the main body 27a, 27b. The actuating arm 28a, 28b is in the direction of the conductor clamping device 13a, 13b, in particular in the direction of the second spring element 16a, 16b of the conductor clamping device 13a, 13b, formed bent and serves to the second spring element 16a, 16b and thus the entire conductor clamping device 13a, 13b to solve a catch when the

 Conductor clamping device 13a, 13b of the closed

Position is to be transferred to the open position by a formed on the actuating limb 19 a, 19 b of the second spring element 16 a, 16 b holding portion 29 a, 29 b of the second spring element 16 a, 16 b by means of

Actuating arm 28a, 28b in the direction of the superimposed actuating legs 19a, 19b, 20a, 20b of the two spring elements 15a, 15b, 16a, 16b is bent. Once the holding portion 29a, 29b is released from a latch, the second spring element 16a, 16b together with the first spring element 15a, 15b can pivot upward in the direction of the actuating element 25a, 25b by the

Spring elements 15a, 15b, 16a, 16b in a on the

Actuator 25a, 25b formed free space

swing in, without a twisting motion of the

 Actuator 25a, 25b trigger. To the

Ladder clamping device 13a, 13b to move from the open position back to the closed position, the Actuator 25a, 25b are rotated so that it preferably with its base body 27a, 27b presses against the actuating limbs 19a, 19b of the second spring element 16a, 16b and this together with the

Actuating legs 20a, 20b of the first spring element 15a, 15b pushes down.

The rotational movement of the actuating element 25a, 25b can by means of a tool, in particular a

Screwdriver done by this in a formed on the actuating element 25 a, 25 b

 Tool insertion opening 30a, 30b is introduced, wherein the tool insertion opening 30a, 30b on the base body 27a, 27b of the actuating element 25a, 25b is formed.

In the embodiment shown in FIGS. 1 to 4, the electrical connection terminal 100 has a housing 10 with two opposite conductor insertion openings IIa, IIb, two opposite conductor clamping devices 13a, 13b and two opposite ones

 Actuators 25a, 25b. About the

Conductor insertion openings IIa, IIb can each be introduced a conductor 200a, 200b, 200c, 200d, so that by means of a terminal 100, two conductors 200a, 200b, 200c, 200d can be clamped simultaneously against a busbar 12. The two actuating elements 25a, 25b and also the two conductor clamping devices 13a, 13b can be actuated or moved separately from each other. The two actuating elements 25a, 25b are opposite to each other rotatable and face each other in such a way that the actuating arms 28a, 28b of the actuating elements 25a, 25b are arranged one behind the other in the direction of division. The design of the terminal 100 is not on the embodiment shown here with two

Conductor entry openings IIa, IIb, two

Conductor clamping devices 13a, 13b and two

Actuators 25a, 25b limited. It is also possible for the terminal 100 to have one or more than two conductor insertion openings IIa, IIb with one or more than two conductor clamping devices 13a, 13b and one or more than two actuating elements 25a, 25b

train.

FIG. 5 again shows a first spring element 15a, 15b shown alone. In the area of

Actuating leg 20a, 20b, the first spring element 15a, 15b, an opening 31a, 31b, over which the first

Spring element 15a, 15b can be connected to the second spring element 16a, 16b. Between the actuating limb 20a, 20b and the clamping leg 17a, 17b of the spring element 15a, 15b, a bent portion 32a, 32b is formed. The bent portion 32a, 32b has a greater width than the actuating legs 20a, 20b and also as the clamping legs 17a, 17b, so that in the

Transition region between the bent portion 32 a, 32 b and the actuating legs 20 a, 20 b and the clamping legs 17 a, 17 b each have a step-shaped constriction

is trained.

The clamping leg 17a, 17b of the first spring element 15a, 15b is not formed in a straight line as in the second spring element 16a, 16b, but has a curved

Course with a U-shaped or V-shaped curvature 22a, 22b, which forms the second clamping portion 22a, 22b of the clamping leg 17a, 17b. Between the vault 23a, 23b and the connection of the clamping leg 17a, 17b to the bent portion 32a, 32b of the clamping legs 17a, 17b is also formed bent. Furthermore, the

Clamping legs 17a, 17b also a bend between the

Buckle 23a, 23b and the first clamping portion 21a, 21b of the clamping leg 17a, 17b, which at an edge portion of an end portion of the clamping leg 17a, 17b

is trained. The first bend 33 between the camber 23a, 23b and the connection of the clamping leg 17a, 17b to the bent portion 32a, 32b is the same

Direction to the second bend 34 between the buckle 23 a, 23 b and the first clamping portion 21 a, 21 b formed. However, the bends 33, 34 are both each

formed opposite to the curvature 23a, 23b. In addition, the width of the clamping leg 17a, 17b tapers from the bulge 23a, 23b or from the bend 34

Direction of the first clamping portion 21a, 21b, so that over the width of the clamping leg 17a, 17b

extending length of the first clamping portion 21a, 21b is shorter than the length of the second clamping portion 22a, 22b.

Reference sign list

Electrical connection terminal 100

Housing 10 conductor insertion opening IIa, IIb

Busbar 12

Conductor clamping device 13a, 13b

Bearing journals 14a, 14b

First spring element 15a, 15b Second spring element 16a, 16b

Clamping legs 17a, 17b

Clamping legs 18a, 18b

Actuating arms 19a, 19b

Actuating arms 20a, 20b First clamping area 21a, 21b

Second clamping area 22a, 22b

Vault 23a, 23b

Clamping area 24a, 24b

Actuator 25a, 25b bearing pin 26a, 26b

Base body 27a, 27b

Actuating arm 28a, 28b

Holding section 29a, 29b

Tool insertion opening 30a, 30b opening 31a, 31b

Bent section 32a, 32b

First bend 33

Second bend 34

Wire 200a, 200b, 200c, 200d wire end ferrule 210

Loading bridge 300

Claims

claims

1. Electrical connection terminal (100),

 with a housing (10) having at least one conductor insertion opening (Ha, IIb),

 with a busbar (12) arranged in the housing (10),

 with at least one in the housing (10) rotatably mounted conductor clamping device (13a, 13b) which in an open position and in a closed position

 Position is pivotable, wherein in the closed position an inserted into the conductor insertion opening (IIa, IIb) conductor (200a, 200b, 200c, 200d) by means of the conductor clamping device (13a, 13b) against the

 Power rail (12) is clamped, and

 with at least one in the housing (10) rotatably mounted actuating element (25a, 25b), by means of which the conductor clamping device (13a, 13b) for

 Transfer to the open position and the

 closed position is actuated,

 wherein the conductor clamping device (13a, 13b) has at least one first spring element (15a, 15b),

 characterized in that the first spring element (15a, 15b) has a clamping limb (17a, 17b), which has a first clamping region (21a, 21b) for

 Clamping an inserted conductor (200a, 200b, 200c, 200d) against the bus bar (12) and spaced from the first clamping region (21a, 21b) a second one

 Clamping area (22a, 22b) for clamping an inserted conductor (200a, 200b, 200c, 200d) against the bus bar

(12). Electrical connection terminal (100) according to claim 1, characterized in that the first clamping area

(21a, 21b) at an edge portion of an end portion of the clamping leg (17a, 17b) of the first spring element

(15a, 15b) is formed.

Electrical terminal (100) according to claim 1 or 2, characterized in that the clamping leg (17a 17b) has a U-shaped or V-shaped curvature

(23a, 23b), wherein at the curvature (23a, 23b) of the second clamping portion (22a, 22b) of the clamping leg

(17a, 17b) is formed.

Electrical terminal (100) according to one of claims 1 to 3, characterized in that the conductor clamping device (13a, 13b) at least one second spring element (16a, 16b), wherein the first spring element (15a, 15b) and the second

Spring element (16a, 16b) are mounted as a spring assembly about a common in the housing (10) formed fulcrum.

Electrical connection terminal (100) according to claim 4, characterized in that the second spring element

(16a, 16b) has a clamping leg (18a, 18b) whose length is shorter than the length of

Clamping leg (17a, 17b) of the first spring element

(15a, 15b).

Electrical terminal (100) according to claim 5, characterized in that the clamping leg (18a, 18b) of the second spring element (16a, 16b) in

Substantially rectilinear, with a clamping region (24a, 24b) is formed at an edge portion of an end portion of the clamping leg (18a, 18b).

Electrical connection terminal (100) according to one of

Claims 1 to 6, characterized in that the housing (10) has two conductor insertion openings (IIa, IIb) and in the housing (10) has two

Conductor clamping devices (13a, 13b) and two

Actuating elements (25a, 25b) are arranged, wherein the two actuating elements (25a, 25b)

are opposite and rotatably arranged opposite to each other.