EP3454422A1 - Cable connection terminal - Google Patents

Abstract

The invention relates to a conductor connection terminal (9) having at least one spring terminal connection (1, 2) which has at least one clamping spring (11, 21) and at least one bus bar (3), wherein a clamping leg (12, 22) of the clamping spring (11, 21 ) is biased relative to the busbar (3), so that an electrical conductor under spring force between the clamping legs (12, 22) and a conductor terminal side (39) of the busbar (3) can be clamped, characterized in that the conductor terminal (9) as a further Component has at least one support plate (8) through which the busbar (3) against a by the clamping spring (11, 21) caused deformation of the busbar (3) is supported.

Description

The invention relates to a conductor terminal with at least one Federkraftklemmanschluss having at least one clamping spring and at least one bus bar, wherein a clamping leg of the clamping spring is biased against the busbar, so that an electrical conductor is clamped under spring force between the clamping leg and a conductor terminal side of the busbar.

A generic conductor terminal is in the form of a connection terminal of the WO 2017/081001 A1 known.

The invention has for its object to provide a conductor terminal, e.g. a connecting terminal to further optimize in terms of production costs and size.

This object is achieved with a conductor connection terminal of the type mentioned above in that the conductor connection terminal has as a further component at least one support plate, by which the busbar is supported relative to a deformation of the busbar caused by the clamping spring. By adding the support plate to such a conductor terminal, a more compact overall, ie smaller construction embodiment can be realized at the same time low production costs. Through the support plate, a mechanically stable connection of the busbar with the clamping spring, or at a connection terminal with the clamping springs, can be provided. The busbar itself does not have to be excessively mechanically stable for this purpose; increased stability is provided by the support plate. By such a support plate can thus for a safe Clamping an electrical conductor required high spring forces are absorbed.

Another advantage is that the support plate supports the busbar with additional electrical load as well as with increased thermal stress, e.g. in case of permanent short circuit. Heat can be dissipated via the support plate. In addition, the electrical connection provided by the busbar is further improved by means of the support plate. A conductor terminal with such a construction can also be mounted by means of a machine. The conductor terminal can also be provided with a self-supporting contact system.

A support plate according to the invention may e.g. be a device that is flat and / or U-shaped or in any other suitable form and consists of electrically conductive or non-conductive material.

According to an advantageous development of the invention, it is provided that the support plate is arranged on the side of the busbar facing away from the conductor connection side of the busbar. In this way, the support plate does not interfere with the insertion or removal of an electrical conductor at a nip.

Between the support plate and the busbar one or more other components may be arranged. In this case, however, it must be ensured that a sufficient force transmission between the support plate and the busbar is possible, so that the support plate can fulfill its function of reducing or preventing a deformation of the busbar caused by the clamping spring. As other components in the aforementioned sense, e.g. below the busbar, ie between busbar and support plate, mounted conductive or non-conductive elements. Conductive elements can serve to provide a branch and thus a further connection possibility.

According to an advantageous embodiment of the invention it is provided that the support plate rests directly on the busbar. In this way, the support plate can support the busbar directly, ie it is an immediate Power transmission between the busbar and the support plate possible. In addition, the heat dissipation via the support plate and the support of the electrical properties of the busbar are optimized.

According to an advantageous embodiment of the invention it is provided that the support plate has at least one substantially parallel to the busbar extending support surface and optionally at least one relative to the support surface angled reinforcing portion through which the area moment of inertia of the support plate is increased at least in the longitudinal direction of the busbar. In this way, the support plate with simple design and manufacturability exert a high support effect with respect to the busbar. The area moment of inertia of the support plate is increased by the angled reinforcing section or the edge resulting from the angling in comparison with an embodiment of the support plate without such an angling. Advantageously, the angled reinforcing section also extends in the longitudinal direction of the busbar, wherein slight deviations from the longitudinal direction of the busbar (oblique arrangement) are also possible. The support plate may, for example, on both sides of the support surface each having an angled reinforcing portion, so that the support plate has a U-shape in cross section. The lateral angled reinforcing sections, e.g. in the form of webs (u-shape), are not mandatory, but make the support plate more stable.

According to an advantageous embodiment of the invention it is provided that the support plate has at least one substantially parallel to the busbar extending support surface which has at least one recess, and the support plate is fixed by means of at least one protruding through the recess fixing on the busbar. This allows a simple and reliable fixation of the support plate to the busbar at the same time favorable power transmission between the support plate and busbar. The support plate is in this way easy, especially automated, mounted on the busbar. In this way, at the same time the clamping spring can be attached to the arrangement formed by the busbar and the support plate.

According to an advantageous development of the invention it is provided that the support plate is fixed by the protruding fixing element by means of a positive connection to the busbar. This allows a particularly reliable fixation of the support plate to the busbar, which allows a high power transmission between the busbar and the support plate.

The protruding fixing element may additionally protrude through an opening in the busbar. The protruding fixing element can also be designed as a fixing element protruding from the busbar.

According to an advantageous embodiment of the invention, it is provided that the protruding fixing element is an integral part of the clamping spring, in particular part of an extended end portion of a contact leg of the clamping spring. This allows a simple and reliable fixation of the support plate to the busbar at the same time favorable power transmission to the busbar. The support plate is in this way easy, especially automated, mounted on the busbar. In addition, no separate component must be used to provide the fixing element. Instead, the clamping spring can be used for this purpose, which also simplifies the installation of the conductor terminal.

According to an advantageous development of the invention, it is provided that the protruding fixing element has a mushroom-head shape in cross section at least in its region projecting through the recess. This allows a particularly reliable positive fixing of the support plate to the busbar at the same time easy mountability of the arrangement. The protruding fixing element forms by its mushroom head form a mushroom pin, with which a mushroom lock on the support plate can be realized. The protruding fixing element can, in the region of its mushroom-head shape, be made e.g. be formed as a flat sheet metal part. The mushroom head shape can be defined by a narrow point in the end region of the fixing element (Mae West Form), recesses or other suitable shapes for realizing a positive connection.

According to an advantageous embodiment of the invention it is provided that the support plate by a linear movement and / or a rotational movement by means of Fixing element can be fixed to the busbar. The support plate can for example also be fixed by a combination of linear movement and rotational movement by means of the fixing element on the busbar. Such movement processes can be performed easily and quickly both by a person and by an automated production facility.

1. a) die Verbindungsklemme weist ein Isolierstoffgehäuse mit wenigstens einer ersten und einer zweiten Leitereinführungsöffnung auf,
2. b) die erste und die zweite Leitereinführungsöffnung sind an einander gegenüberliegenden Gehäuseseiten des Isolierstoffgehäuses angeordnet,
3. c) in dem Isolierstoffgehäuse sind ein erster Federkraftklemmanschluss zur elektrischen Kontaktierung eines durch die erste Leitereinführungsöffnung eingeführten ersten elektrischen Leiters und einen zweiter Federkraftklemmanschluss zur elektrischen Kontaktierung eines durch die zweite Leitereinführungsöffnung eingeführten zweiten elektrischen Leiters angeordnet,
4. d) der erste Federkraftklemmanschluss ist mit dem zweiten Federkraftklemmenanschluss über dieselbe durchgehende Stromschiene elektrisch verbunden.

According to an advantageous development of the invention, it is provided that the conductor connection terminal is designed as a connection terminal for connecting at least two electrical conductors to one another, with the following features:

1. a) the connection terminal has an insulating housing with at least a first and a second conductor insertion opening,
2. b) the first and the second conductor insertion openings are arranged on opposite housing sides of the insulating housing,
3. c) a first spring terminal connection for electrically contacting a first electrical conductor inserted through the first conductor insertion opening and a second spring terminal connection for electrically contacting a second electrical conductor inserted through the second conductor insertion opening are arranged in the insulating housing,
4. d) the first spring clamp terminal is electrically connected to the second spring terminal terminal via the same continuous bus bar.

In this way, the advantages explained above can also be realized with a connection terminal. Especially in connection terminal is a significant advantage in a particularly small-sized arrangement and a cost-effective production to see.

In the connection terminal thus the first spring terminal connection can be formed as the spring terminal connection of the conductor connection terminal mentioned above, in addition, the second spring terminal connection can be formed like the spring terminal connection of the conductor connection terminal mentioned above. The above-mentioned busbar of the conductor terminal is then a single continuous busbar at the connection terminal, which thus connects the two Federkraftklemmanschlüsse electrically and to some extent also mechanically.

For this purpose, the first spring terminal connection may have a first clamping spring, which has a clamping leg for clamping the first electrical conductor against a first clamping point of the busbar and a bearing limb for supporting the clamping spring. The second spring terminal connection may comprise a second clamping spring having a clamping leg for clamping the second electrical conductor against a second clamping point of the bus bar and a bearing leg for supporting the second clamping spring.

According to an advantageous embodiment of the invention it is provided that the bus bar has at least one passage opening which is arranged between the first and the second nip, wherein an extended end portion of the abutment leg of the first and / or the second clamping spring is guided through the through hole of the busbar and is attached as fixing on the support plate. The passage opening of the busbar can in particular be arranged at least substantially flush with the recess of the support plate, so that one and the same fixing element can be guided through the passage opening of the busbar and the recess of the support plate. In the case of a connecting terminal, both the first and the second clamping spring may have a fixing element as an integral part of the respective clamping spring, in particular in the form of an extended end portion of a contact leg of the clamping spring.

According to an advantageous development of the invention, it is provided that the support plate extends along the busbar from the first spring terminal connection to the second spring terminal connection. In this way, the support plate, similar to the busbar, may be formed as a continuous component, which exerts its supporting effect both in the region of the first and in the region of the second spring terminal connection.

According to an advantageous embodiment of the invention it is provided that the first and / or the second clamping spring is formed loop-shaped, wherein the respective abutment leg is bent in an extended end portion of the respective clamping spring in the direction of the busbar. This way you can the clamping spring may be formed integrally with the fixing element for fixing the support plate to the busbar in a favorable manner.

According to an advantageous development of the invention, it is provided that the first clamping spring touches the second clamping spring in the region of its respective bearing limb. This has the advantage that the first and second clamping springs can be mutually supported, i. one clamping spring can absorb pressure forces of the other clamping spring. This also allows a material saving and a compact design of the connection terminal can be realized. In addition, the load of the insulating material is minimized by spring forces, so that the insulating material can also be simplified.

Figur 1

- eine Leiteranschlussklemme in seitlicher Schnittdarstellung und

Figuren 2, 3

- den Kontakteinsatz der Leiteranschlussklemme gemäß Figur 1 in unterschiedlichen perspektivischen Ansichten und

Figuren 4, 5

- Betätigungshebel in perspektivischen Ansichten und

Figur 6

- eine weitere Ausführungsform einer Leiteranschlussklemme in seitlicher Schnittansicht.

The invention will be explained in more detail by means of embodiments using drawings. Show it:

FIG. 1

- A conductor terminal in side sectional view and

FIGS. 2, 3

- the contact insert of the conductor terminal according to FIG. 1 in different perspective views and

FIGS. 4, 5

- Operating lever in perspective views and

FIG. 6

- Another embodiment of a conductor terminal in side sectional view.

1

- erster Federkraftklemmanschluss

2

- zweiter Federkraftklemmanschluss

3

- Stromschiene

4

- Gehäuseoberteil

5

- Bodenteil

6

- Betätigungshebel

8

- Stützblech

9

- Leiteranschlussklemme

10

- erste Leitereinführungsöffnung

11

- erste Klemmfeder

12

- Klemmschenkel

13

- Beaufschlagungsbereich

14

- Federbogen

15

- Anlageschenkel

16

- Endabschnitt

17

- Vertikalbereich

18

- Endstück des Endabschnitts

19

- Betätigungshebel

20

- zweite Leitereinführungsöffnung

21

- zweite Klemmfeder

22

- Klemmschenkel

23

- Beaufschlagungsbereich

24

- Federbogen

25

- Anlageschenkel

26

- Endabschnitt

27

- Vertikalbereich

28

- Endstück des Endabschnitts

29

- Betätigungshebel

30

- Durchgangsöffnung

31

- erste Klemmstelle

32

- zweite Klemmstelle

39

- Leiteranschlussseite der Stromschiene

41

- innerer Wandbereich

42

- innerer Wandbereich

50

- Rastelemente

60

- manueller Betätigungsbereich

61

- Lagerungsachse

62

- Betätigungsbereiche des Betätigungshebels

63, 64

- Lagerbereiche

65

- ausgesparter Bereich

71, 72

- Endstücke

73, 74

- herausgestellte Materialbereiche

80

- Stützfläche

81

- Verstärkungsabschnitt

82

- Aussparung

In the figures, like reference numerals are used for corresponding elements having the following assignment:

1

- first spring clamp connection

2

- Second spring clamp connection

3

- busbar

4

- Housing top

5

- bottom part

6

- Operating lever

8th

- Support plate

9

- conductor connection terminal

10

- first ladder opening

11

- first clamping spring

12

- clamping legs

13

- loading area

14

- bow

15

- Plant leg

16

- End section

17

- vertical area

18

- End piece of the end section

19

- Operating lever

20

- second conductor opening

21

- second clamping spring

22

- clamping legs

23

- loading area

24

- bow

25

- Plant leg

26

- End section

27

- vertical area

28

- End piece of the end section

29

- Operating lever

30

- Through hole

31

- first nip

32

- second nip

39

- Conductor connection side of the busbar

41

- inner wall area

42

- inner wall area

50

- locking elements

60

- manual operating range

61

- bearing axis

62

- Operating areas of the operating lever

63, 64

- Storage areas

65

- recessed area

71, 72

- Tails

73, 74

- exposed material areas

80

- Support surface

81

- Reinforcement section

82

- recess

In the FIG. 1 illustrated conductor terminal 9 is formed as a connection terminal. It is constructed substantially symmetrically with respect to a vertical axis of symmetry and has in each case left and right of the vertical axis of symmetry, a first spring terminal connection 1 and a second spring terminal connection 2. The first and second spring terminal connections 1, 2 are arranged in an insulating housing 4, 5 of the conductor connection terminal 9. The insulating housing 4, 5 may be formed, for example at least in two parts, for example, a housing upper part 4 and a connectable by latching elements 50 with the upper housing part 4. bottom part 5. The conductor terminal 9 may also be formed such that on one side a spring force terminal connection and on the other side another electrically conductive connection is present, eg a screw connection. The support plate function is retained.

The first spring terminal connection 1 has a loop-shaped multi-angled first clamping spring 11. The first clamping spring 11 has at one end a clamping leg 12 which serves for clamping an electrical conductor inserted through a first conductor insertion opening 10 against a first clamping point 31 of a busbar 3. The electrical conductor can be clamped in this way to a conductor connection side 39 of the busbar 3. In the region of the clamping leg 12 there is a loading area 13 of the first clamping spring 11, on which the clamping leg 12 can be actuated for opening and closing the first spring terminal connection 1 via an actuating lever 19.

At the clamping leg 12 of the first clamping spring 11 is followed by a spring bow 14 to which then an abutment leg 15 of the first clamping spring 11 connects. The first clamping spring 11 extends in the region of the abutment leg 15 further into an extended end portion 16, in which the material of the first clamping spring 11 is finally bent in a vertical region 17 in the direction of the busbar 3. The end portion 16 of the abutment leg 15 extends beyond the vertical region 17 further down through a through hole 30 of the busbar 3 to the end piece 71 of the first clamping spring eleventh

Below the busbar 3, i. on the side facing away from the conductor connection side 39 of the busbar 3, there is the support plate 8. The support plate 8 rests with its support surface 80 on the busbar 3 at. As can be seen, the support plate 8 extends substantially from the first nip 31 to the second nip 32. The end portion 16 extends through the recess 82 in the support surface 80, so that the end piece 71 terminates below the support surface 80.

The second clamping spring 21 may for example be shaped as well as the first clamping spring 11. For this purpose, it is provided that the second spring terminal connection 2 a loop-shaped multi-angled second clamping spring 21 has. The second clamping spring 21 has at one end a clamping leg 22, which serves for clamping an inserted through a second conductor insertion opening 20 electrical conductor against a second clamping point 32 of the busbar 3. Again, the electrical conductor to the conductor connection side 39 of the busbar 3 can be clamped. In the region of the clamping leg 22 there is a loading area 23 of the second clamping spring 21, on which the clamping leg 22 can be actuated for opening and closing the second spring terminal connection 2 via an actuating lever 29.

At the clamping leg 22 of the second clamping spring 21, a spring bow 24 connects to which then an abutment leg 25 of the second clamping spring 21 connects. The abutment leg 25 bears against an inner wall region 42 of the insulating housing 4, 5 and is supported thereon, at least in part, with respect to the forces received by the clamping leg 22. The second clamping spring 21 extends in the region of the abutment leg 25 further into an extended end portion 26, in which the material of the second clamping spring 21 is finally bent in a vertical region 27 in the direction of the busbar 3. The end portion 26 of the abutment leg 25 extends beyond the vertical portion 27 further down through the through hole 30 of the bus bar 3 and the recess 82 in the support surface 80 up to the end piece 72 of the first clamping spring 21, so that the end piece 72 below the support surface 80 ends.

The FIG. 1 shows the first Federkraftklemmanschluss 1 and the second Federkraftklemmanschluss 2 shown in the closed state, ie, the first and the second operating lever 19, 29 is in the closed position. In this state, the clamping leg 12 of the first clamping spring 11 contacts the first terminal point 31 of the busbar 3 at the end, and the clamping leg 22 of the second clamping spring 21 touches the second terminal point 32 of the busbar 3 at the end.

Like in the FIG. 1 can be seen, it is not necessary in this embodiment, that the abutment legs 15, 25 abut against wall regions of the insulating housing 4, 5 or are supported on it. Instead, a self-supporting construction of the clamping springs 11, 21 can be realized.

It can also be seen that the busbar 3 in the region of its first and second clamping points 31, 32 indentations, through which the material of the busbar 3 upwards, i. in the direction of the respective clamping leg 12, 22, something is exposed. As a result, the clamping of a connected electrical conductor is improved.

The busbar 3 is integrally formed as flat-forming short busbar piece. By the support plate 8, the busbar 3 is mechanically stabilized in this area and also optimized in terms of electrical conduction and heat dissipation.

The connection terminal described may also be formed double connection terminal or multiple connection terminal. When executed as a double connection terminal two juxtaposed terminal points are present at each Leiteinsführseite, accordingly, the arrangement of the first clamping spring on the one hand and the second clamping spring on the other hand, double exists. This is in the representations of FIGS. 2 and 3 recognizable. As can be seen, in each case two juxtaposed clamping springs 11 and 21 are connected to each other via a common, continuous width in the vertical region 17 and 27 and fixed thereto on the busbar 3. Each vertical region 17, 27 has, for. B. at a central location, said, through-inserted through the through hole 30 of the busbar 3 and the recess 82 of the support plate 8 End piece 71 or 72 on. The juxtaposed clamping springs 11 and 21 are independently operable, ie they are not connected to each other in the other areas, beyond the common vertical areas 17 and 27, respectively.

How to get in the FIG. 3 detects, the end pieces 71, 72 are formed in mushroom head shape. In this way, the respective end pieces 71, 72 at the same time form fixing elements for the positive connection of the support plate 8 with the busbar. As a result, in addition, the clamping springs 11, 21 are fixed to the arrangement of the busbar 3 and the support plate 8.

If the connection terminal is designed as a multi-terminal, there are more than two juxtaposed terminal points on each conductor insertion side, z. B. 3, 4, 5 or more. In this case, a common passage opening in the busbar 3 and the support plate 8 may be present for groups of clamping springs or for all clamping springs for fixing them to the busbar in each case for groups.

• Zunächst werden die Klemmfedern 11, 21 in der in den Figuren 2 und 3 erkennbaren Anordnung zueinander ausgerichtet, d.h. derart, dass die Klemmfedern 11, 21 über ihre Vertikalbereiche 17, 27 sozusagen Rücken an Rücken aneinander anliegen.
• Dann kann die Stromschiene 3 mit ihrer Durchgangsöffnung 30 sowie das Stützblech 8 mit seiner Aussparung 82 über die Endstücke 71, 72 geführt werden. Hierbei können die Klemmfedern 11, 21 mit Dornen ausgelenkt werden.
• Dies erfolgt beispielsweise derart, dass die Stromschiene und das Stützblech zunächst in einer um 90 Grad gedrehten Lage über die Endstücke 71, 72 geführt werden und dann um 90 Grad in die in Figur 3 erkennbare Lage gedreht werden, so dass eine Verriegelung der Klemmfedern 11, 21 über die Pilzkopf-förmigen Endstücke 71, 72 mit der Stromschiene 3 und dem Stützblech 8 erfolgen kann. Hierfür ist es vorteilhaft, wenn die Durchgangsöffnung 30 und die Aussparung 82 schmal und schlitzfömig ausgebildet sind. Alternativ kann die Durchgangsöffnung 30 sowie die Aussparung 82 in Draufsicht eine T-Form aufweisen, d.h. eine Aussparung mit einem breiten und einem sich daran anschließenden schmalen Bereich. In diesem Fall können die Stromschiene 3 und das Stützblech 8 ohne Drehbewegung über die Endstücke 71, 72 geführt werden, indem die Endstücke 71, 72 zunächst über den breiten Bereich der Aussparung geführt werden und dann durch eine Verschiebebewegung die Stromschiene 3 und das Stützblech 8 derart verschoben werden, dass die Endstücke 71,72 dann in dem schmaleren Bereich der Aussparung angeordnet sind.
• Die Betätigungshebel 19, 29 können in einer Lage, die der geschlossenen Stellung entspricht, über die Anlageschenkel 15, 25 bis auf die Stromschiene 3 bewegt werden;
• Die Klemmfedern 11, 21 werden durch Schwenken der Betätigungshebel 19, 29 in (vollständige) Offenstellung bewegt;
• Ggf. genutzte Dorne werden zurückgezogen;
• Die nun vormontierte Einheit mit Stromschiene 3, Klemmfedern 11, 21 und Betätigungshebeln 19, 29 (in Offenstellung) wird auf das auf Bodenteil 5 gesetzt;
• Das Gehäuseoberteil 4 wird übergestülpt;
• Die Betätigungshebel 19, 29 werden in die geschlossene Stellung geschwenkt.

The assembly of the conductor connection terminal 9 can be carried out, for example, as follows:

• First, the clamping springs 11, 21 in the in the FIGS. 2 and 3 recognizable arrangement aligned with each other, ie, such that the clamping springs 11, 21 via their vertical portions 17, 27, so to speak, abut each other back to back.
• Then, the busbar 3 with its passage opening 30 and the support plate 8 with its recess 82 via the end pieces 71, 72 are performed. Here, the clamping springs 11, 21 are deflected with thorns.
• This is done, for example, such that the busbar and the support plate are first performed in a rotated position by 90 degrees on the end pieces 71, 72 and then 90 degrees in the in FIG. 3 be seen recognizable position, so that a locking of the clamping springs 11, 21 on the mushroom-shaped end pieces 71, 72 can be done with the busbar 3 and the support plate 8. For this purpose, it is advantageous if the passage opening 30 and the recess 82 are narrow and schlitzfömig. Alternatively, the passage opening 30 and the recess 82 in plan view have a T-shape, ie a recess with a wide and an adjoining narrow area. In this case, the busbar 3 and the support plate 8 without rotation about the end pieces 71, 72 are performed by the end pieces 71, 72 are first performed over the wide region of the recess and then by a sliding movement of the busbar 3 and the support plate 8 such be shifted, that the end pieces 71,72 are then arranged in the narrower portion of the recess.
• The actuating lever 19, 29 can be moved in a position corresponding to the closed position, via the plant legs 15, 25 to the busbar 3;
• The clamping springs 11, 21 are moved by pivoting the actuating lever 19, 29 in (full) open position;
• Possibly. used thorns are withdrawn;
• The now preassembled unit with busbar 3, clamping springs 11, 21 and operating levers 19, 29 (in the open position) is placed on the bottom part 5;
• The upper housing part 4 is slipped over;
• The operating levers 19, 29 are pivoted to the closed position.

The first clamping spring 11 is supported in the vertical region 17 on the vertical region 27 of the second clamping spring 21, that is, the clamping springs 11, 21 are mutually supported in the region of their vertical sections 17, 27. The vertical region 17 also forms a conductor stop when inserting the first conductor into the insulating material housing. The vertical region 27 also forms a conductor stop when inserting the second conductor into the insulating material housing.

The conductor terminal 9 may be formed as a simple conductor terminal, in each case a conductor insertion opening 10, 20 is present on each side. It can also be designed as a double or multiple clamp. In this case, two or more first conductor insertion openings 10 and two or more second conductor insertion openings 20 are provided side by side on each side. For such embodiments, another embodiment of the respective actuating lever 19, 29 may be advantageous.

The FIG. 5 shows an advantageous embodiment of an actuating lever 6, which can be used as a first or second operating lever 19, 29, namely in the event that the conductor terminal has only one conductor insertion opening 10, 20 on each side. The operating lever 6 has a manual operating portion 60 (handle portion) on which the operating lever 6 can be operated by a user. The actuating lever 6 also has a bearing axis 61, via which it can be mounted insulating housing 4, 5. The actuating lever 6 is fork-shaped in the region of the bearing axis 61, with a recessed area in the middle 65, with which the actuating lever 6 can be slipped over the intermediate clamping spring. The clamping spring then has laterally projecting Beaufschlagungsbereiche 13 and 23, respectively, on which the clamping spring can be acted upon by operating portions 62 of the actuating lever 6. A rearward contour of the actuating lever 6 has two bearing areas 63, 64 arranged at an angle to one another via which the actuating lever is mounted in the insulating housing and / or on the busbar 3. In the closed actuation position, the actuation lever 6 rests with the bearing region 63 in the open position with the bearing region 64. The bearing axis 61 is accommodated in a groove (not shown) aligned substantially perpendicularly to the busbar 3 in the housing upper part 4 by the bearing portions 63, 64, which slide on the busbar 3 during the pivoting movement of the actuating lever 19, 29, conditional during the pivotal movement of the actuating lever 19, 29 to absorb occurring deflection.

The FIG. 4 shows an embodiment of an actuating lever 6, which is designed for a conductor terminal, in which two juxtaposed spring terminal connections per side of the housing are present. Accordingly, the entire operating lever 6 is formed wider and has two adjacent, recessed areas 65, in which respective clamping springs can be passed. Corresponding three loading areas 62 are provided. In this case, the middle application region 62 simultaneously acts on the two adjacent clamping springs on one side of the conductor connection terminal 9.

The conductor terminal 9 according to FIG. 6 corresponds in its essential structure of the previously based on the FIGS. 1 to 3 explained conductor terminal 9. Therefore, in the following essentially the differences will be discussed. The FIG. 6 shows the first Federkraftklemmanschluss 1 with the first operating lever 19 open, such that the first nip 31 is not touched by the clamping leg 12 and an optionally previously clamped there electrical conductor can be removed. It can be seen that the clamping leg 12 of the first clamping spring 11 is then removed from the first clamping point 31. The second spring clamp terminal 2 is shown in the closed state, that is, the second operating lever 29 is in the closed position. In this state, the clamping leg 22 of the second clamping spring 21 contacts the second terminal point 32 of the busbar 3 at the end.

The plant leg 15 abuts against an inner wall portion 41 of the insulating housing 4, 5 and is supported thereon, at least in part, with respect to the forces received by the clamping leg 12. The abutment leg 25 bears against an inner wall region 42 of the insulating housing 4, 5 and is supported thereon, at least in part, with respect to the forces received by the clamping leg 22.

The end portion 16 of the abutment leg 15 extends further beyond the vertical portion 17 down through the through hole 30 of the bus bar 3 and the recess 82 of the support plate 8 and is finally hooked in the recess 82, e.g. by an end piece 18 of the end portion 16 is further angled, and thus the recess 82 engages behind. The end portion 26 of the abutment leg 25 extends beyond the vertical portion 27 further down through the through hole 30 of the bus bar 3 and the recess 82 of the support plate 8 and is finally suspended in the recess 82, e.g. by an end piece 28 of the end portion 26 is further angled, and thus the recess 82 engages behind.

The clamping springs 11, 21 may initially, ie, before they are attached to the busbar 3, in their respective end pieces 18, 28 not yet bent outwardly as in FIG. 1 is recognizable. They can initially run essentially straight. After mounting the clamping springs 11, 21 in the through hole 30 of the busbar 3 is another manufacturing step by the end pieces 18, 28th towards the outside, ie in the direction of the respective conductor insertion opening 10, 20, are bent and then engage behind the recess 82.

Claims (14)

Conductor terminal (9) having at least one spring terminal connection (1, 2), the at least one clamping spring (11, 21) and at least one bus bar (3), wherein a clamping leg (12, 22) of the clamping spring (11, 21) relative to the busbar (3) is biased, so that an electrical conductor under spring force between the clamping legs (12, 22) and a conductor connection side (39) of the busbar (3) can be clamped, characterized in that the conductor terminal (9) as a further component at least one support plate (8), by which the busbar (3) against a by the clamping spring (11, 21) caused deformation of the busbar (3) is supported. Conductor terminal according to the preceding claim, characterized in that the support plate (8) on the conductor connection side (39) of the busbar (3) facing away from the busbar (3) is arranged. Conductor terminal according to one of the preceding claims, characterized in that the support plate (8) rests directly on the busbar (3). Conductor terminal according to one of the preceding claims, characterized in that the support plate (8) has at least one substantially parallel to the busbar extending support surface (80) and optionally at least one relative to the support surface (80) angled reinforcing portion (81) through which the area moment of inertia of Supporting plate (8) is increased at least in the longitudinal direction of the busbar (3). Conductor terminal according to one of the preceding claims, characterized in that the support plate (8) has at least one substantially parallel to the busbar extending support surface (80) having at least one recess (82), and the support plate (8) by means of at least one of the Recess (82) protruding fixing element (18, 28, 71, 72) is fixed to the busbar (3). Conductor terminal according to the preceding claim, characterized in that the support plate (8) is fixed by the protruding fixing element (18, 28, 71, 72) by means of a positive connection to the busbar (3). Conductor terminal according to one of claims 5 to 6, characterized in that the protruding fixing element (18, 28, 71, 72) is an integral part of the clamping spring (11, 21), in particular part of an extended end portion (16, 26) of a support leg (15 , 25) of the clamping spring (11, 21). Conductor terminal according to one of claims 5 to 7, characterized in that the protruding fixing element (18, 28, 71, 72) at least in its through the recess (82) projecting portion in cross section has a mushroom head shape. Conductor terminal according to one of claims 5 to 8, characterized in that the support plate (8) by a linear movement and / or a rotational movement by means of the fixing element (18, 28, 71, 72) on the busbar (3) is fixable. Conductor terminal according to one of the preceding claims, wherein the conductor terminal (9) is designed as a connection terminal for connecting at least two electrical conductors to one another, with the following features: a) the connection terminal has an insulating material housing (4, 5) with at least a first and a second conductor insertion opening (10, 20), b) the first and second conductor insertion openings (10, 20) are in contact with each other opposite housing sides of the insulating housing (4, 5) arranged, c) in the insulating housing (4, 5) are a first spring terminal connection (1) for electrically contacting a through the first conductor insertion opening (10) inserted first electrical conductor and a second spring terminal connection (2) for electrically contacting a through the second conductor insertion opening (20) arranged second electrical conductor, d) the first spring terminal connection (1) is electrically connected to the second spring terminal terminal (2) via the same continuous busbar (3). Conductor terminal according to the preceding claim, characterized in that the busbar (3) has at least one through-hole (30) arranged between the first and second nip (31, 32), an extended end portion (16, 26) of the abutment leg (15, 25) of the first and / or the second clamping spring (11, 21) through the passage opening (30) of the busbar (3) is guided and as a fixing element (18, 28, 71, 72) attached to the support plate (8) is. Conductor terminal according to one of claims 10 to 11, characterized in that extending the support plate (8) along the busbar (3) from the first spring terminal connection (1) to the second spring terminal terminal (2). Conductor terminal according to one of claims 10 to 11, characterized in that the first and / or the second clamping spring (11, 21) is loop-shaped, wherein the respective abutment leg (15, 25) in an extended end portion (16, 26) of the respective Clamping spring (11, 21) is bent in the direction of the busbar (3). Conductor terminal according to one of claims 10 to 12, characterized in that the first clamping spring (11) contacts the second clamping spring (21) in the region of its respective bearing limbs (15, 25).

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