DE202019006022U1 - Electrical connection terminal - Google Patents

Abstract

Electrical connection terminal (10)
- with a clamping spring (200) for clamping an electrical conductor (20),
- with an actuating element (400),
- with a coupling element (510, 510', 520, 520', 530, 530', 540) for the mechanical coupling of the actuating element (400) and the clamping spring (200),
- in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), wherein the clamping leg has a clamping edge (240) for clamping the electrical conductor (20),
- in which the clamping leg (210) has a coupling region (600) spaced from the clamping edge (240),
- the coupling region (600) is spaced from the clamping edge (240) perpendicular to the main extension direction (EK) of the clamping leg (210),
- in which the coupling region (600) has a bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) predominantly perpendicular to the main extension direction (EK) of the clamping leg (210) for supporting the coupling element (510, 510', 520, 520', 530, 530', 540),
- in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a bearing area (590), wherein the bearing area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) rests against the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) for storage and/or wherein the bearing area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) at least partially engages around the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) for storage.

Description

From the DE 10 2015 100 823 A1 an electrical connection terminal is known with a connection terminal housing having a conductor insertion opening, with a busbar arranged in the connection terminal housing and with a spring element rotatably mounted in the connection terminal housing. The spring element can be pivoted into an open position and into a closed position, wherein in the closed position a conductor inserted into the conductor insertion opening can be clamped against the busbar by means of the spring element. The connection terminal has an actuating element which is rotatably mounted in the connection terminal housing and by means of which the spring element can be actuated to transfer it into the open position and into the closed position. The actuating element has a base body having a tool insertion opening and an actuating arm. The base body and the actuating arm are designed in two parts, with the actuating arm being designed to be pivotable relative to the base body.

From the DE 10 2017 108 171 A1 a spring-loaded connection for connecting an electrical conductor is known. This comprises a housing part, an electrically conductive contact element arranged on the housing part for electrical contact with a conductor connected to the spring force connection and a spring element. The spring element has a clamping leg that is adjustable relative to the contact element for applying a spring force to a conductor connected to the spring force connection. The spring-loaded connection has an actuating element for adjusting the clamping leg. In addition, a tension element is provided, which is movably coupled and designed to be movable with the actuating element and movably with the clamping leg. When the actuating element is actuated, the tension element exerts a tensile force on the clamping leg in order to adjust the clamping leg to the contact element.

From the WO 2018/010893 A1 a connection terminal for connecting an electrical conductor to a housing is known. The connection terminal has a busbar arranged in the housing, a clamping spring arranged in the housing, and a pivotally mounted actuating lever. The clamp spring can be moved into an open position and into a closed position when the actuating lever pivots. The clamp spring has a clamping leg for clamping a conductor inserted into the housing against the busbar in the closed position. An actuating tab is arranged on the clamping leg in such a way that when the clamp spring is transferred from the closed position to the open position by the actuating lever, a pressure force is exerted on the actuating tab.

The present invention is based on the object of creating an electrical connection terminal that is as improved as possible. This task is solved by the features of independent claim 1. Advantageous further training is the subject of dependent claims.

Accordingly, an electrical connection terminal is provided. The electrical connection terminal has a clamping spring for clamping an electrical conductor. The electrical connection terminal has an actuating element. The electrical connection terminal has a coupling element for mechanical coupling of the actuating element and the clamping spring.

The clamping spring has a clamping leg with a main direction of extension. The clamping leg has a clamping edge for clamping the electrical conductor. The clamping leg has a coupling area spaced from the clamping edge. The coupling area has a bearing edge that is predominantly perpendicular to the main extension direction of the clamping leg for supporting the coupling element.

The coupling element has a storage area. The storage area of the coupling element rests on the bearing edge of the clamping leg for storage and/or the storage area of the coupling element at least partially surrounds the bearing edge of the clamping leg for storage.

According to an advantageous development, one or more bearing edges are formed in a coupling area. For example, one, two or four bearing edges can be formed in the same coupling area. According to an advantageous development, one or more coupling areas are formed.

According to an advantageous development, the clamping edge is formed at a free end of the clamping leg. Advantageously, the clamping edge is arranged against the inserted conductor, preferably at an angle to the insertion direction of the conductor. Preferably, exactly one clamping edge is provided which clamps exactly one assigned conductor. Alternatively, additional clamping edges are formed on the clamping spring in addition to the clamping edge, for example to clamp different conductors.

According to an advantageous development, the clamping leg can be moved from a closed position to an open position and back. Advantage Adherently, the clamping leg is deflected at least for movement from the closed position into the open position by means of the actuating element and the coupling element. Advantageously, an actuating force acts predominantly counter to the spring force for deflection.

According to an advantageous development, the coupling element is designed to transmit force between the actuating element and the clamping leg. Preferably, the coupling element is designed to mechanically couple a pivoting movement of the actuating element with a movement of the deflection of the clamping leg. For example, the coupling element is designed in the form of a joint rod. Advantageously, the coupling element is mounted with its first end on the clamping leg and/or with its second end on the actuating element. The coupling element is advantageously made of plastic or metal.

According to an advantageous development, a first coupling element and a second coupling element are provided, wherein the first coupling element and the second coupling element are designed for mechanical coupling of the actuating element with the clamping spring. The clamping leg preferably has a first coupling area and a second coupling area. Preferably, the first coupling area has a first bearing edge and the second coupling area has a second bearing edge. According to an advantageous development, the first coupling area and the second coupling area are spaced apart from one another at least transversely to the main extension direction of the clamping leg.

According to an advantageous development, the actuating element is designed as a lever. Alternatively, the actuating element is designed as a pusher or the like. Advantageously, the actuating element is designed for at least manual actuation. The actuating element advantageously has a grip area. Alternatively, it is possible for the actuating element to be designed with an interface for an actuating tool.

According to an advantageous development, the coupling area is spaced from the clamping edge in the main extension direction of the clamping leg. Additionally or alternatively, the coupling area is spaced from the clamping edge perpendicular to the main extension direction of the clamping leg. Advantageously, the coupling area is formed outside a conductor insertion area, so that the probability of a collision of the conductor with the coupling element when inserting the conductor is reduced.

According to an advantageous development, the coupling element and the clamping spring are not designed in one piece. Preferably, the coupling element and the clamping spring are separate and preferably made of different material, for example a different metal. According to an advantageous development, the coupling element and the actuating element are designed in several parts. Alternatively, it is possible for the coupling element and the actuating element to be formed in one piece. For example, the coupling element is mechanically coupled to the actuating element by means of a film hinge.

According to an advantageous development, the coupling element and the clamping spring are designed to be movable relative to one another. Preferably, the coupling element and the clamping spring are designed to be at least rotatable relative to one another. Alternatively or in combination, in another development, the coupling element and the clamping spring are translationally movable relative to one another. According to an advantageous development, the coupling element and the clamping spring are designed for releasable mechanical coupling. Advantageously, the coupling element and the clamping spring are designed so that they can be brought into and out of engagement.

According to an advantageous development, the coupling element is designed to transmit a tensile force to deflect the clamping leg of the clamping spring. The tensile force acts in one direction predominantly against the spring force.

According to an alternative or combinable development, the coupling element is designed to transmit a compressive force to deflect the clamping leg of the clamping spring. The compressive force acts in one direction predominantly against the spring force.

According to an advantageous development, the bearing edge in the coupling area is formed by a step between a first area and a second area of the clamping leg that is narrower than the first area. The second region is preferably designed closer to the clamping edge than the first region. A first region and a narrower second region are advantageously formed on both long sides of the clamping leg. Advantageously, the first areas and the second areas are arranged symmetrically, in particular mirror-symmetrically.

According to an advantageous development, the bearing edge in the coupling area is formed by an opening in the clamping leg. Advantageously, the opening is predominantly formed on all sides by Material of the clamping leg. For example, the coupling area of the opening has two bearing edges. For example, two bearing edges are formed on exactly one web of the clamping leg in the coupling area that delimits the opening.

According to an advantageous development, the bearing edge is exposed from the plane of the clamping leg. Advantageously, the bearing edge is designed to point away from the clamping leg.

According to another advantageous development, the bearing edge is formed in the plane of the clamping leg.

According to an advantageous development, the coupling element has a bearing opening. The coupling area with the bearing edge protrudes into the bearing opening. The coupling area is advantageously designed in the form of an exposed extension of the clamping leg. The extension advantageously projects into the bearing opening with two bearing edges.

According to an advantageous development, the bearing edge is formed by a bend, the bearing edge being defined by the outer area of the bend. For example, the clamping leg is bent in the coupling area by an angle between 90° and 180° to form the bearing edge. Due to the larger radius in the outer area of the bend and the absence of burrs, better bearing properties can be achieved.

According to an advantageous development, the coupling element has an arcuate section. The coupling area with the bearing edge is arranged for storage in the arcuate section. For example, the arcuate section is designed in the form of a hook.

According to an advantageous development, the coupling element has a bracket. The bracket is advantageously located on the bearing edge for storage. This prevents the bracket from shifting in the main extension direction when the actuating element is actuated and the clamping leg is coupled from the closed position to the open position.

According to an advantageous development, the electrical connection terminal has a housing. The clamping spring is arranged in the housing. The housing is advantageously made of an electrically insulating material, for example plastic. The electrically conductive components of the connection terminal are advantageously arranged within the housing.

According to an advantageous development, a conductor insertion area is defined by a conductor insertion channel formed in the housing. Within the conductor insertion area, the conductor is guided to a clamping point formed in the area of the clamping edge. The clamping point is defined, for example, by the clamping edge and a busbar section of a busbar. In an alternative development, the clamping spring itself is designed to conduct current.

According to an advantageous development, the coupling area is offset outside the conductor insertion area in the main extension direction of the clamping leg. According to an alternative or combinable development, the coupling area is designed to be offset outside the conductor insertion area perpendicular to the main extension direction of the clamping leg.

According to an advantageous development, the housing has a guide in which the coupling element is positioned. The coupling element is guided in the guide so that the position of the coupling element is defined for each deflection of the clamping leg.

The indefinite article “a” or “an” in the description does not mean a specific number. An electrical conductor is to be understood as meaning at least one electrical conductor, so that exactly one, two or more electrical conductors can be connected through the spring-loaded terminal connection. According to an advantageous development, the connection terminal has a busbar to which the conductor can be electrically connected. A busbar means exactly one, two or more busbars. The power rail can also be called a power bar. The busbar is optimized for electrical contacting and current conductivity and has, for example, copper or a copper alloy.

A clamping spring means exactly one, two or more clamping springs. An actuating element is understood to mean exactly one, two or more actuating elements. The clamping spring is suitable for clamping the electrical conductor. The clamping spring is advantageously formed and bent from spring steel. Advantageously, the clamping spring has exactly one clamping leg for clamping an associated electrical conductor, so that one and the same conductor is not clamped by two or more clamping legs of the clamping spring. According to an advantageous development, the clamping spring has a contact leg. The contact leg of the clamping spring is designed to rest on a stationary area of the connection terminal in order to absorb the retroactive spring force. For example, the The contact leg is attached to the busbar and/or the housing. The connection is advantageously designed to be self-supporting by means of a clamping spring and busbar. The contact leg is connected directly or indirectly to the clamping leg. For example, the contact leg is connected to the clamping leg via a spring arch. Advantageously, the contact leg, spring arch and clamping leg are formed in one piece and bent or alternatively the contact leg and clamping leg are fastened to one another.

The actuating element is designed to be actuated and can be actuated, for example, manually or by means of an actuating tool. The connection terminal has bearings and counter bearings for supporting the actuating element for a pivoting movement. The counter bearing for the actuating element is formed, for example, in the housing and/or in the busbar. The coupling element serves to convert the pivoting movement of the actuating element into the deflection of the clamping leg. For example, the first/second coupling element has one or more joints and/or one or more rigid or at least partially flexible coupling rods and/or one or more bearings or the like. The further developments and features in the claims and in the description, in particular the configurations explained in the figures, can be integrated into the connection terminal individually or in combination. The invention is not limited to the specific embodiments shown in the figures.

• 1 ein Ausführungsbeispiel einer Anschlussklemme,
• 2 ein Ausführungsbeispiel einer Anschlussklemme,
• 3 ein Ausführungsbeispiel einer Klemmfeder,
• 4 ein Ausführungsbeispiel einer Anschlussklemme,
• 5 ein Ausführungsbeispiel einer Anschlussklemme,
• 6 ein Ausführungsbeispiel einer Klemmfeder,
• 7 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 8 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 9 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 10 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 11 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 12 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 13 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 14 ein Ausführungsbeispiel eines Koppelbereichs im Klemmschenkel,
• 15 ein Ausführungsbeispiel einer Anschlussklemme,
• 16 ein Ausführungsbeispiel einer Anschlussklemme,
• 17 ein Ausführungsbeispiel einer Klemmfeder,
• 18 ein Ausführungsbeispiel einer Anschlussklemme,
• 19 ein Ausführungsbeispiel einer Anschlussklemme, und
• 20 ein Ausführungsbeispiel einer Klemmfeder.

Embodiments of the invention are explained in more detail below with reference to the drawings. Show:

• 1 an embodiment of a connection terminal,
• 2 an embodiment of a connection terminal,
• 3 an embodiment of a clamping spring,
• 4 an embodiment of a connection terminal,
• 5 an embodiment of a connection terminal,
• 6 an embodiment of a clamping spring,
• 7 an exemplary embodiment of a coupling area in the clamping leg,
• 8th an exemplary embodiment of a coupling area in the clamping leg,
• 9 an exemplary embodiment of a coupling area in the clamping leg,
• 10 an exemplary embodiment of a coupling area in the clamping leg,
• 11 an exemplary embodiment of a coupling area in the clamping leg,
• 12 an exemplary embodiment of a coupling area in the clamping leg,
• 13 an exemplary embodiment of a coupling area in the clamping leg,
• 14 an exemplary embodiment of a coupling area in the clamping leg,
• 15 an embodiment of a connection terminal,
• 16 an embodiment of a connection terminal,
• 17 an embodiment of a clamping spring,
• 18 an embodiment of a connection terminal,
• 19 an embodiment of a connection terminal, and
• 20 an embodiment of a clamping spring.

In the 1 , 2 , 4 , 5 , 15 , 16 , 18 and 19 Different embodiments of an electrical connection terminal 10 are shown in a simplified partial view. The connection terminal 10 makes it possible to connect a conductor 20 - shown in 2 - to be connected electrically. The conductor 20 is, for example, a cable with one or more wires made of electrically conductive metal that form the core of the cable. The wire is covered by insulating material. For electrical connection, the conductor 20 is clamped by a clamping spring 200. The spring force of the clamping spring 200 has a clamping effect on the conductor 20. For example, a free end of the clamping spring 200 forms a clamping edge 240 which penetrates into the material of the conductor 20 and thus significantly increases a pull-out force.

The connection terminal 10 has a busbar 100 for electrically contacting the conductor. The busbar 100 is advantageously made of a material that has better current conductivity than the clamping spring 200. Accordingly, the conductor 20 is electrically connected to the busbar 100. The busbar 100 also has a further electrical connection (not shown) - for example a fork contact, knife contact or solder connection - for further electrical connection. Alternative to those in the 1 , 2 , 4 , 5 , 15 , 16 , 18 and 19 In the exemplary embodiments shown, the busbar 100 and the clamping spring 200 can consist of one Material can be formed in one piece, which simplifies production.

The connection terminal 10 also has a housing 300, which is shown for example in the 2 is shown schematically. The clamping spring 200 is accommodated in the housing 300. The busbar 100 is accommodated in the housing 300. The housing 300 is advantageously made of an insulating material, for example plastic or ceramic. In low-voltage applications, a housing is not absolutely necessary. In the 2 the housing 300 is shown only partially and in section. The housing 300 has a conductor guide channel 310 for guiding the conductor 20 to the terminal point K. In the 1 , 2 , 4 , 5 , 15 , 16 , 18 and 19 a connection terminal 10 is shown with exactly one busbar 100 and exactly one clamping spring 200. For multi-pole connection options, the connection terminal 10 has a corresponding number of busbars 100 and clamping springs 200, which can be insulated from one another by the housing 300, for example, and/or can be electronically bridged by separate or integrated jumpers.

The clamping spring 200 has a clamping leg 210 and a contact leg 220 connected to the clamping leg 210. Clamping legs 210 and contact legs 220 can be connected to one another by means of a positive connection, for example by means of clinching. Advantageously, clamping legs 210 and contact legs 220 of clamping spring 200 are formed and bent in one piece from a material, for example spring steel. For example, clamping legs 210 and contact legs 220 are connected to one another via a 180° fold. In one embodiment in the 1 to 6 and 15 to 20 is shown that the clamping spring 200 has the clamping leg 210 and the contact leg 220 and a spring arch 230 connecting the clamping leg 210 and the contact leg 220. The clamping spring 200 extends from the contact leg 220 over the spring arch 230 to the clamping leg 210. The main extension direction EK of the clamping leg 210 extends from the spring arch 230 to the clamping edge 240.

The clamping spring 200 is supported via the contact leg 220 against the spring force introduced by the clamping leg 210. The support is advantageously provided by abutting the contact leg 220 on the busbar 100. It is shown that the busbar 100 has a base region 120 and a busbar wall 130 formed at an angle to the base section 120 and a support area 140 adjacent to the busbar wall for supporting the contact leg 200. A section of the contact leg 220 extends along the support area 140. The bottom area 120 of the busbar 100 forms a surface for contacting the conductor 20. For example, an elevation 110 can be provided from the surface of the bottom area 120 in order to define a contact area for the conductor 20 . Of course, the busbar 100 can also be shaped differently and, for example, have an opening into which the contact leg 220 is suspended (not shown).

The connection terminal 10 in the 1 , 2 , 4 , 5 , 15 , 16 , 18 and 19 has a pivotally mounted actuating lever 400 as an actuating element 400. The operating lever 400 has a handle area 410 for manually operating the operating lever 400. The actuating lever 400 is designed to deflect the clamping leg 210 into an open position from a closed position. The 1 , 2 , 4 , 5 , 15 , 16 , 18 and 19 show the clamping leg 210 in the closed position. In the open position, a clamping point K for the electrical conductor 20 defined by clamping legs 210 and busbar 100 is open. In the closed position, however, the clamping point K is not open. The clamping spring 200 is designed to press the previously inserted electrical conductor 20 onto the busbar 100 in the closed position by means of the clamping leg 210. For example, the clamping edge 240 at the free end of the clamping leg 210 presses against the conductor 20, which in turn is pressed against the busbar 100 and forms the electrical contact on the busbar 100.

In the exemplary embodiments, the actuating lever 400 is arranged outside a conductor insertion area 320, so that the conductor 20 does not collide with a part of the coupling element 510, 510 ', 520, 520', 530, 530', 540 and / or the actuating lever 400 during insertion . In this way, the width of the conductor guide channel 310 can be optimized for conductors 20 that are as large as possible.

By manually operating the operating lever 400, the clamping point K can be opened and closed by deflecting the clamping leg 210. If the operating lever 400 is in the closed position, the clamping point K is also closed. If the actuating lever 400 is in the open position, the clamping leg 210 is deflected and the clamping point K is opened. In the open position, the conductor 20 can be inserted into the connecting terminal 10 to the clamping point K or removed from it without any effort, since the actuation of the actuating lever 400 moves the clamping edge 240 from its contact point on the busbar 100 or the contact point on the electrical conductor 20 through the Deflection of the clamping leg 210 is moved away.

In addition, in the exemplary embodiments shown, a single-wire, solid conductor 20 can be plugged in directly, so that in the closed position the conductor 20 is guided through the conductor guide channel 310 and the clamping leg 210 of the clamping spring 200 is deflected by additional feed force, so that the conductor 20 is pushed in as far as it will go can be.

Individual features and differences in the exemplary embodiments are described below 1 to 20 explained in more detail. Different features of the exemplary embodiments can be combined with one another.

In the exemplary embodiment 1 the actuating element is designed as a lever. The lever 400 can be grasped manually in the handle area 410 and adjusted by a pivoting movement. The lever 400 has a pivot bearing 420 for storage. The counter bearing of the lever 400 is not shown. The lever can be mounted, for example, in the housing or in part of the busbar. It is also possible to store the lever 400 on the clamping spring 200. Two coupling elements 510, 510 'are mechanically coupled to the lever 400 by a bearing 431, 511. The coupling elements 510, 510' are designed in the form of a joint rod. For example, the coupling elements 510, 510' are made of plastic or a metal. For storage, the actuating element 400 has a bearing element 431 on both sides. In the exemplary embodiment 1 the bearing element 431 is designed as a pin. Alternatively, the bearing element 431 can be designed as an eyelet, elongated hole or the like (not shown). The coupling element 510, 510 'has an associated counter bearing 511, for example an elongated hole. The coupling element 510, 510 'is rotatably and displaceably mounted relative to the actuating element 400.

In the example of 1 the clamping spring 200 has a clamping leg 210. The clamping leg 210 has a coupling area 600 with a bearing edge 601. The coupling element 510 is mounted on the bearing edge 601. The other coupling element 510' is also mounted on another bearing edge 601', which in 3 The other bearing edge 601' is shown in 1 not visible, as it is covered by the clamping leg 210. In 1 It is shown that the clamping leg 210 has a width in the region of the clamping edge 240 that almost corresponds to the width of the base 120 of the busbar 100. In contrast, the coupling region 600 projects laterally beyond this width.

In the exemplary embodiment 2 a connection terminal 10 with a housing 300 is shown. The housing 300 is shown in a very simplified section. The housing 300 has a conductor guide channel 310, which leads the conductor 20 to the clamping point K when it is inserted in the conductor insertion direction LE. Through the conductor guide channel 310, a section of the bottom region 120 of the busbar 100, the clamping leg 210 and possibly further walls (not shown) of the housing 300 define a conductor insertion region 320.

The coupling element 510 has a storage area 590. The storage area 590 of the coupling element 510 surrounds a bearing edge 601. In the exemplary embodiment, the storage area 590 of the coupling element 510 has the 2 a sheet 591. The arch 591 is in the exemplary embodiment 2 in the form of a hook 591. In the exemplary embodiment the 2 If the lever 400 is pivoted for actuation, the coupling element 510 is displaced and, since the coupling element 510 lies in the deflection direction of the clamping leg 210, exerts a tensile force on the clamping leg 210. The spring force counteracts the tensile force.

If a compressive force is to be exerted on the clamping leg 210, the coupling element 510 would be arranged on the opposite side of the clamping leg 210 (not shown). The lever 400 would also be stored in a different position and press the coupling element in the direction of the clamping leg 210 (not shown).

In the exemplary embodiment 3 a clamping spring 200 is shown. The clamping spring 200 has a contact leg 220, a spring bow 230 adjoining the contact leg 220 and a clamping leg 210 adjoining the spring bow 230. The clamping leg 210 extends at its greatest extent in the main extension direction EK. The clamping leg 210 extends from the spring arch 230 to the clamping edge 240 at the free end of the clamping leg 210. The clamping leg 210 can, for example, be flat. In the exemplary embodiment 3 the clamping leg 210 also has a bend in order to make the clamping edge 240 steeper than the conductor 20. Alternatively to the exemplary embodiment of 3 The clamping spring 200 may have other shapes with a plurality of arcs and/or width changes and/or bends. It is important, however, that the clamping spring 200 has a clamping leg 210 with a clamping edge 240. The clamping edge 240 is, for example, straight, V-shaped or curved.

The clamping leg 210 has a coupling area 600 spaced from the clamping edge 240. The coupling area 600 has a bearing edge 601 on. The bearing edge 601 is predominantly perpendicular to the main extension direction EK of the clamping leg 210. The bearing edge 601 is designed to support the coupling element 510. In the exemplary embodiment 3 the bearing edge 601 is formed predominantly parallel to the clamping edge 240.

In the exemplary embodiment 3 two bearing edges 601, 601 'are formed on the long sides of the clamping leg 210. The two bearing edges 601, 601 'are designed to be mirror-symmetrical to one another. If both coupling elements 510, 510' act equally on the bearing edges 601, 601', the clamping leg 210 is not or only slightly twisted during the deflection.

The exemplary embodiments of the 4 , 5 and 6 show differences from the previous exemplary embodiments. That's how it is in the 4 and 5 each coupling element 520, 520 'is designed differently. Also in the 4 to 6 the coupling area 600 of the clamping leg is designed differently.

The exemplary embodiment of the 4 again shows two coupling elements 520, 520 '. The coupling element 520, 520 'is exclusively rotatably mounted on the actuating element 400.

The coupling area 600 in the exemplary embodiment 5 shows a bearing edge 603, which is formed by cutting and bending through 90 ° from the plane PK of the clamping leg 210. The second bearing edge is in 6 not visible behind the clamping leg 210. The bend creates an indentation 215, 215 'in the clamping leg 210. The bearing edges 603 point in the exemplary embodiment 6 away from the clamping leg 210. Bearing edge 603 and indentation 215, 215' are arranged away from the conductor insertion area in the main extension direction EK.

In the exemplary embodiment 5 the coupling element 510 has an arcuate section 592. The coupling area 600 with the bearing edge 603 is arranged for storage in the arcuate section 592. The coupling element 520 has a bow 592 in the form of a hook 592 which at least partially surrounds the bearing edge 603. Shown in 5 is the closed position, with the bearing edge 603 and bearing area 590 of the coupling element 520 in engagement. In the exemplary embodiment the 5 If a conductor is inserted without first actuating the lever 400, the bearing area 590 of the coupling element 520 and the bearing edge 603 of the clamping leg 210 come out of engagement when the conductor abuts the clamping leg 210 due to the feed movement and deflects it. The coupling element 520 is advantageously guided in the housing (not shown), so that when the lever 400 is actuated after an idle stroke, the bearing area 590 of the coupling element 520 and the bearing edge 603 of the clamping leg 210 come into engagement again. The clamping point K can be opened manually.

The different embodiments of the 7 to 14 each show a section of a clamping leg 210 with a coupling area 600. The coupling area 600 in the exemplary embodiments of 7 to 14 is trained differently. The exemplary embodiments of the 7 to 14 can be combined with each other depending on the geometry of the connection terminal. In the exemplary embodiments of 7 to 14 the coupling area 600 is only formed on one long side of the clamping leg 210. However, the coupling area can alternatively be designed symmetrically or asymmetrically on both long sides of the clamping leg 210.

In the exemplary embodiment 7 the coupling area 600 is formed by material removal by creating a step between a first area with a larger width B1 and a second area with a narrower width B2. In the exemplary embodiment, the stage forms the 7 exactly one bearing edge 601. The bearing edge 601 is in the plane PK of the clamping leg 210.

In the exemplary embodiment 8th the coupling area 600 is formed by bending through 180°. A tongue 620 of the clamping leg 210 is exposed and bent through 180°. The outer radius of the bend forms a bearing edge 602. The bearing edge 602 has a larger radius and no burrs, so that the coupling element can be stored better.

In the exemplary embodiment 9 the coupling area 600 is formed by bending by 90°. A tongue 621 of the clamping leg 210 is exposed and bent by 90°. The bearing edge 603 at the end of the tongue 621 is exposed from the plane PK of the clamping leg 210. The clamping edge 603 therefore points away from the clamping leg 210 and enables particularly secure storage of the coupling element.

In the exemplary embodiments of 7 to 9 the bearing edge 601, 602, 603 is spaced from the clamping edge 240 of the clamping leg 210 at least in the main extension direction EK of the clamping leg 210. In the exemplary embodiment 10 the bearing edge 614 is spaced from the clamping edge 240 by the distance d2 perpendicular to the main extension direction EK. In the exemplary embodiment 10 Bearing edge 614 and clamping edge 240 are aligned. It is shown that the bearing edge 614 and the clamping edge 240 are connected by a small Indentation in the clamping leg 210 are separated from each other. However, the indentation can also be omitted. Advantageously, bearing edge 614 and clamping edge 240 are spaced apart from one another both in the main extension direction EK and perpendicular to the main extension direction EK (in 10 not shown).

In the exemplary embodiment 11 a coupling area 600 with two bearing edges 604, 605 is shown schematically. A coupling element can be mounted on one or both of the bearing edges 604, 605. The coupling area 600 is in the exemplary embodiment 11 in the form of a tongue 620 projecting perpendicular to the main extension direction on the long side of the clamping leg 210.

In the exemplary embodiment 12 the coupling area 600 has four bearing edges 606, 607, 608 and 609. The coupling element (e.g. 510, in 12 not shown) can be mounted on one or more of the bearing edges 606, 607, 608, 609. For example, the bearing area 590 of the coupling element is S-shaped and has two arcuate sections into which the tongues of the coupling area 600 protrude to form the bearing. Each bearing edge 606, 607, 608, 609 is formed in the coupling area 600 by a step between a first area and a second area of the clamping leg 210 that is narrower than the first area.

In the exemplary embodiment 13 the coupling area 600 is formed by an indentation in the clamping leg 210. The indentation is delimited by edges which form the bearing edges 610, 611. The bearing edge 610, 611 is formed in the plane PK of the clamping leg 210. In the area of the indentation, the clamping leg 210 has a narrower width B2 than outside the coupling area 600 with the width B1.

In the exemplary embodiment 14 the bearing edge 612, 613 in the coupling area 600 is formed by an opening 622 in the clamping leg 210. In the exemplary embodiment 14 the opening is rectangular, so that two bearing edges 612, 613 can be used to support the coupling element. The bearing edge 612 is spaced by the distance d1 from the clamping edge 240 of the clamping leg 210 exclusively in the main extension direction EK.

In 15 an embodiment of a connection terminal 10 is shown. The coupling element 530 has a bearing opening 532 into which the coupling region 600 projects with the bearing edge 604, 605. The coupling region 600 is, for example, in accordance with the embodiment of the 11 trained. In 15 it is shown that two coupling elements 530, 530' are arranged symmetrically. Accordingly, the coupling region 600 can also be designed symmetrically. In the embodiment of the 17 the coupling region 600 has the bearing edges 604, 605, 604` 605`, which are mirror-symmetrical.

In the exemplary embodiment 16 is shown that the coupling element 530 has, in addition to the bearing opening 532, a further bearing opening 531 for a bearing element 431 of the actuating element 400. In the exemplary embodiment 16 the actuating element 400 has a bearing element 431 for mechanical coupling to the coupling element 530. The bearing element 431 is designed, for example, as a bearing pin 431. Alternatively, it is possible for the actuating element 400 to have a bearing opening and the coupling element 530 to have a bearing pin (not shown). The coupling element 530 in the exemplary embodiment 16 causes the pivoting movement of the actuating element 400 and the deflection movement of the clamping leg 210 to be firmly coupled. In order to enable the clamping leg 210 to be deflected even when the lever 400 is not actuated, one of the bearing openings 531, 532 can be designed, for example, as an elongated hole.

In the exemplary embodiment 18 the coupling element 540 is designed as a bracket 540. The bracket 540 includes the clamping leg 210. The bracket is rotatably mounted on both sides of the lever 400. The bracket 540 extends from one side of the lever 400 around the clamping leg 210 to the opposite side of the lever 400. The bracket 540 rests on a bearing edge 601 for storage. In the exemplary embodiment 19 it is shown that the bracket 540 cannot be moved in the direction of the spring arch 230 in the storage area 590. Correspondingly, the bracket 540 is fixed in position in the main extension direction EK of the clamping leg 210 by the support on the bearing edge 601 of the clamping leg 210. In the exemplary embodiment 20 the coupling area 600 of the clamping leg 210 has two bearing edges 601, 601 'on which the bracket 540 in the exemplary embodiment 19 is stored. If the lever 400 is actuated, a tensile force F _P in the bracket 540 causes the clamping leg 210 to deflect against the spring force Fs. If a solid conductor is inserted without actuating the lever 400, the clamping leg 210 is deflected by the feed force and the conductor is clamped at the clamping point K . If, on the other hand, a stranded wire is to be clamped as a conductor, the lever 400 is actuated before insertion and the clamping leg 210 is moved into the open position and the stranded wire is then inserted into the connection terminal 10. The coupling area 600 is in the main extension direction EK des Clamping leg 210 is formed offset outside the conductor insertion area. Furthermore, the coupling area 600 is formed offset outside the conductor insertion area 320 perpendicular to the main extension direction EK of the clamping leg 210. In both cases, the risk of a collision of the inserted strand with the bearing edge 601 can be advantageously reduced, so that the probability is lower that individual wires of the strand will get caught or snagged.

After inserting the stranded or solid conductor, the lever 400 is closed and the conductor is clamped. To release the conductor, the lever 400 is actuated again and the clamping point K is opened. During the pivoting movement of the lever 400, the bracket 540 touches the bearing edge 601 again and deflects the clamping leg 210. The conductor is free and can be removed from the connection terminal 10.

Reference symbol list

10

Connection terminal

20

Director

100

busbar

110

survey

120

floor area

130

Busbar wall

140

Support area

200

Clamping spring

210

clamping leg

215, 215'

indentation

220

investment leg

230

Feather arch, feather root

240

clamping edge

300

Housing

310

Conductor routing channel

320

Ladder entry area

400

Actuator

410

Grip area

420

Pivot bearing

431

Bearing element, bearing journal

510, 510', 520, 520', 530, 530', 540

Coupling element

511, 521, 531, 541, 542

counter bearing

532

Pivot bearing

590

storage area

591, 592

bow, hook

600

Coupling area

601, 601', 602, 603, 604, 605, 606, 607, 608, 609, 610, 611, 612, 613, 614

bearing edge

620, 621

Tongue

622

Window opening

EK

Main extension direction

FP

traction

FS

Spring force

K

Terminal point

LE

Conductor insertion direction

PK

level

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102015100823 A1 [0001]
• DE 102017108171 A1 [0002]
• WO 2018/010893 A1 [0003]

Claims (21)

Electrical connection terminal (10) - with a clamping spring (200) for clamping an electrical conductor (20), - with an actuating element (400), - with a coupling element (510, 510', 520, 520', 530, 530', 540) for mechanically coupling the actuating element (400) and the clamping spring (200), - in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), the clamping leg having a clamping edge (240) for clamping the electrical conductor (20), - in which the clamping leg (210) has a coupling area (600) spaced from the clamping edge (240), - in which the coupling area (600) is spaced from the clamping edge (240) perpendicular to the main extension direction (EK) of the clamping leg (210), - in which the coupling area (600) has a bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609) which is predominantly vertical to the main extension direction (EK) of the clamping leg (210), 610, 611, 612, 613, 614) for mounting the coupling element (510, 510', 520, 520', 530, 530', 540), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a storage area (590), the storage area (590) of the coupling element (510, 510', 520, 520', 530 , 530', 540) on the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg ( 210) for storage and/or wherein the storage area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) has the bearing edge (601, 601', 602, 603, 604, 605, 604 ', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) at least partially surrounds for storage. Electrical connection terminal (10). Claim 1 , - in which the coupling area (600) is spaced from the clamping edge (240) in the main extension direction (EK) of the clamping leg (210). Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling element (510, 510', 520, 520', 530, 530', 540) and the clamping spring (200) are not made in one piece. Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling element (510, 510', 520, 520', 530, 530', 540) and the clamping spring (200) are designed to be movable relative to one another. Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling element (510, 510 ', 520, 520', 530, 530', 540) is used to transmit a tensile force (F _P ) to deflect the clamping leg (210). Clamping spring (200) is designed, and / or - in which the coupling element (510, 510 ', 520, 520', 530, 530', 540) is designed to transmit a compressive force to deflect the clamping leg (210) of the clamping spring (200). is. Electrical connection terminal (10) according to one of the preceding claims, - in which the bearing edge (601, 601', 602, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611) in the coupling area (600) through a step between a first area and an opposite one the second region of the clamping leg (210) is formed which is narrower than the first region. Electrical connection terminal (10) according to one of the preceding claims, - in which the bearing edge (601, 601', 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) is in the plane (PK) of the clamping leg (210) is trained. Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling element (510) has an arcuate section (591) in which the coupling area (600) with the bearing edge (601) is arranged for storage. Electrical connection terminal (10) according to one of the preceding claims, - with a housing (300) in which the clamping spring (200) is arranged, - in which a conductor insertion area (320) is defined by a conductor insertion channel (310) formed in the housing, which leads the conductor (20) to a clamping point (K) formed in the area of the clamping edge (240). Electrical connection terminal (10). Claim 13 , - in which the coupling area (600) is offset outside the conductor insertion area (320) perpendicular to the main extension direction (EK) of the clamping leg (210). Electrical connection terminal (10) according to one of the preceding claims, - in which the clamping leg (210) of the clamping spring (200) has a first coupling area and a second coupling area, - in which the first coupling area has a first bearing edge (601, 604) and the second Coupling area has a second bearing edge (601 ', 604'), - in which the first coupling area and the second Coupling area are spaced apart from one another at least transversely to the main extension direction (EK) of the clamping leg (210). Electrical connection terminal (10) according to one of the preceding claims, - in which the first bearing edge (601, 604, 605) and the second bearing edge (601 ', 604', 605') are formed on the long sides of the clamping leg (210) and are mirror-symmetrical to one another. Electrical connection terminal (10) according to one of the preceding claims, - in which the actuating element is designed as a lever (400), - in which the actuating element has a grip area (410). Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling element and the actuating element are designed in several parts, or - in which the coupling element and the actuating element are designed in one piece. Electrical connection terminal (10) according to one of the preceding claims, - in which the bearing edge (601) is predominantly designed parallel to the clamping edge (240). Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling region (600) is designed in the form of a tongue (620) protruding perpendicular to the main extension direction (EK) on the long side of the clamping leg (210). Electrical connection terminal (10) according to one of the preceding claims, - in which the coupling area (600) has two bearing edges (604, 605), - in which the coupling element is mounted on one or both of the bearing edges (604, 605). Electrical connection terminal (10) - with a clamping spring (200) for clamping an electrical conductor (20), - with an actuating element (400), - with a coupling element (510, 510', 520, 520', 530, 530', 540) for mechanically coupling the actuating element (400) and the clamping spring (200), - in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), the clamping leg having a clamping edge (240) for clamping the electrical conductor (20), - in which the clamping leg (210) of the clamping spring (200) has a first coupling area spaced from the clamping edge (240) and a second coupling area spaced from the clamping edge (240), - in which the first coupling area has a first bearing edge (601, 603, 604) which is predominantly perpendicular to the main extension direction (EK) of the clamping leg (210) for supporting the coupling element (510, 520, 530), - in which the second coupling area has a second bearing edge (601', 603', 604') which is predominantly perpendicular to the main extension direction (EK) of the clamping leg (210) for supporting the coupling element (510', 520', 530'), - in which the first coupling area and the second coupling area are spaced apart from one another at least transversely to the main extension direction (EK) of the clamping leg (210), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a storage area (590), the storage area (590) of the coupling element (510, 510', 520, 520', 530 , 530', 540) on the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg ( 210) for storage and/or wherein the storage area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) has the bearing edge (601, 601', 602, 603, 604, 605, 604 ', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) at least partially surrounds for storage. Electrical connection terminal (10) - with a clamping spring (200) for clamping an electrical conductor (20), - with an actuating element (400), - with a coupling element (510, 510 ', 520, 520', 530, 530', 540 ) for mechanical coupling of the actuating element (400) and the clamping spring (200), - in which the coupling element and the actuating element are formed in one piece, - in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), where the clamping leg has a clamping edge (240) for clamping the electrical conductor (20), - in which the clamping leg (210) has a coupling area (600) spaced from the clamping edge (240), - in which the coupling area (600) has a direction of extension relative to the main direction of extension (EK) of the clamping leg (210) predominantly vertical bearing edge (601, 601 ', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614). Storage of the coupling element (510, 510', 520, 520', 530, 530', 540), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a storage area (590 ). ', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) rests for storage and / or the storage area (590) of the coupling element (510, 510 ', 520, 520', 530, 530', 540) the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) at least partially covered for storage. Electrical connection terminal (10) - with a clamping spring (200) for clamping an electrical conductor (20), - with an actuating element (400), - with a coupling element (510, 510', 520, 520', 530, 530', 540) for mechanically coupling the actuating element (400) and the clamping spring (200), - in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), the clamping leg having a clamping edge (240) for clamping the electrical conductor (20), - in which the clamping leg (210) has a coupling area (600) spaced from the clamping edge (240), - in which the coupling area (600) is designed in the form of a tongue (620) projecting perpendicular to the main extension direction (EK) on the long side of the clamping leg (210). - in which the coupling area (600) has two bearing edges (604, 605, 604', 605') that are predominantly perpendicular to the main extension direction (EK) of the clamping leg (210), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) is mounted on one or both of the bearing edges (604, 605, 604', 605'), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a storage area (590), the storage area (590) of the coupling element (510, 510', 520, 520', 530 , 530', 540) rests on the bearing edge (604, 605, 604', 605') of the clamping leg (210) for storage and/or the bearing area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) at least partially surrounds the bearing edge (604, 605, 604', 605') of the clamping leg (210) for storage. Electrical connection terminal (10) - with a clamping spring (200) for clamping an electrical conductor (20), - with an actuating element (400), - with a coupling element (510, 510', 520, 520', 530, 530', 540) for mechanically coupling the actuating element (400) and the clamping spring (200), - in which the clamping spring (200) has a clamping leg (210) with a main extension direction (EK), the clamping leg having a clamping edge (240) for clamping the electrical conductor (20), - in which the clamping leg (210) has a coupling area (600) spaced from the clamping edge (240), - in which the coupling area (600) has a bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609) which is predominantly vertical to the main extension direction (EK) of the clamping leg (210), 610, 611, 612, 613, 614) for mounting the coupling element (510, 510', 520, 520', 530, 530', 540), - in which the coupling element (510, 510', 520, 520', 530, 530', 540) has a storage area (590), the storage area (590) of the coupling element (510, 510', 520, 520', 530 , 530', 540) on the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg ( 210) for storage and/or wherein the storage area (590) of the coupling element (510, 510', 520, 520', 530, 530', 540) has the bearing edge (601, 601', 602, 603, 604, 605, 604', 605', 606, 607, 608, 609, 610, 611, 612, 613, 614) of the clamping leg (210) at least partially encompasses for storage, - in which the coupling element (510) has an arcuate section (591) as a storage area (590), in which the coupling area (600) of the clamping leg (210) with the bearing edge (601) is arranged for storage.

Images