DE102025117910A1 - conductor connection terminal - Google Patents

Abstract

The invention relates to a conductor terminal with an insulating housing which has at least one conductor entry opening for receiving an electrical conductor in a conductor entry direction, wherein at least one spring-loaded clamping connection for connecting an electrical conductor by means of spring force is arranged in the insulating housing, wherein the spring-loaded clamping connection has at least one busbar and a clamping spring which has a clamping leg with a clamping edge for clamping an electrical conductor at a clamping point on a contact section of the busbar.

Description

The invention relates to a conductor terminal with an insulating housing which has at least one conductor entry opening for receiving an electrical conductor in a conductor entry direction, wherein at least one spring-loaded clamping connection for connecting an electrical conductor by means of spring force is arranged in the insulating housing, wherein the spring-loaded clamping connection has at least one busbar and a clamping spring which has a clamping leg with a clamping edge for clamping an electrical conductor at a clamping point on a contact section of the busbar.

Such a conductor terminal block is made from the DE 10 2020 119 372 A1 This is a conductor terminal with automatic connection of the electrical conductor to be connected when it is inserted into the terminal. Inserting the conductor automatically releases the clamping arm of the spring, which is held in an open position, thus clamping the conductor securely.

Based on this, the object of the present invention is to provide a further improved conductor terminal.

This problem is solved by arranging a driver on the clamping arm. This driver has a deflecting surface projecting from the clamping arm on the side facing away from the contact section (and thus the clamping point). The clamping arm can be moved from a clamped position to an open position by an actuating force applied to the deflecting surface in the conductor insertion direction. In this way, proven conductor connection terminals of known design can be easily modified to include manual actuation. Advantageously, the clamping arm can then be actuated, for example, from the conductor insertion side of the insulating housing.

The invention is suitable, for example, for compact junction box terminals, e.g., those with leaf spring connection, in which the clamping leg is connected to a support section of the clamping spring without a spring arc known in many conductor connection terminals, which extends over an angle range of more than 180°.

According to an advantageous embodiment, the clamping spring is supported at a support point on the busbar, for example, by having a bearing section with which it is supported and thus supported on the busbar. In this case, the deflection surface can be located closer to the clamping leg than at the support point. This applies to the clamping position and/or the open position of the clamping leg, or to all actuation positions of the clamping leg. This enables reliable actuation of the clamping leg with a compact design of the conductor terminal.

According to an advantageous embodiment, the release surface can be connected to the clamping arm via a rigid connection, in particular such that the deflection surface is rigidly connected to the clamping arm via at least one connecting arm of the actuator. In this way, the actuating movement exerted on the deflection surface can be transmitted unchanged to the clamping arm.

According to an advantageous embodiment of the invention, the deflection surface can be subjected to an actuating force on a surface facing the clamping leg. A gap is formed between the surface of the deflection surface facing the clamping leg and the clamping leg, into which a tool suitable for actuating the clamping leg or a push button of the conductor terminal can be inserted. The tool or push button thus engages under the deflection surface, i.e., in the gap arranged between the deflection surface and the clamping leg, and, upon actuation, lifts the deflection surface and thus the clamping leg.

According to an advantageous embodiment of the invention, the driver is formed integrally with the clamping arm, or the driver is designed as a separate component from the clamping spring, which is attached to the clamping arm. This allows for a variety of design options for the clamping spring and the driver. If the driver is formed integrally with the clamping arm, it can, for example, be designed as an extended section of material from the clamping arm, diametrically opposed to the side of the clamping edge. If the driver is designed as a separate component, it can, for example, be attached to the clamping arm by positive-locking fixing elements.

According to an advantageous embodiment of the invention, the driver is fixed at a fastening point on the clamping leg, at least against forces acting in the conductor insertion direction, wherein at least one connecting arm of the driver extends from the fastening point to the deflection surface. When the actuating force is applied to the deflection surface, the connecting arm is subjected to a tensile force; that is, the connecting arm pulls the clamping leg into the open position via this tensile force when the deflection surface is actuated. This allows for favorable lever ratios for deflecting the clamping leg when force is applied to the deflection surface. Depending on the design of the actuator, it can, for example, have a central connecting arm or two connecting arms extending laterally along the clamping leg.

According to an advantageous embodiment of the invention, the at least one connecting arm is arranged orthogonally to the planar extent of the clamping leg and/or orthogonally to the planar extent of the deflection surface. This enables good force transmission and absorption at the deflection surface when the driver is actuated. Furthermore, the area moment of inertia of the driver in the longitudinal direction of the clamping leg can be increased with minimal effort.

According to an advantageous embodiment of the invention, the at least one connecting arm has a higher area moment of inertia in the longitudinal direction of the clamping leg than the clamping leg itself. This ensures that when the driver is actuated, it is essentially the clamping leg that bends, and the driver remains at least undeformed (no elastic and/or plastic deformation). To increase the area moment of inertia, stiffening elements, such as beads and/or embossing, extending longitudinally, can be formed in the at least one connecting arm.

According to an advantageous embodiment of the invention, the at least one connecting arm has an elongated slot into which an actuating projection extending laterally from the clamping leg projects. This creates a torsionally rigid connection between the driver and the clamping leg. During the deflection movement of the clamping leg by the driver, the driver cannot pivot relative to the clamping leg; instead, both elements—driver and clamping leg—perform the same pivoting movement until the open position is reached. The elongated slot can be designed as a through hole or as a blind hole, i.e., as an elongated groove on the side of the connecting arm facing the clamping leg. The actuating projection can substantially fill the elongated slot.

According to an advantageous embodiment of the invention, the insulating housing has at least one actuating channel in which an actuating tool, which is not part of the conductor terminal, or a push button designed as part of the conductor terminal, can be arranged for actuating the clamping arm. The actuating channel thus allows the actuator at the deflection surface to be subjected to an actuating force. If an actuating tool, e.g., a screwdriver, is used, it can be inserted into the actuating channel as needed. The actuating tool then does not have to remain attached to the conductor terminal. An electrical conductor with sufficient stiffness can also be used as an actuating tool.

If the conductor terminal has its own push button for actuating the clamping arm, this button can be permanently located in the actuating channel. In this case, the user must apply manual actuating force to an actuating surface of the push button, either directly with a finger or with a suitable tool.

According to an advantageous embodiment of the invention, the deflection surface projects into the actuating channel or at least into a housing section of the insulating housing that is arranged as an extension of the actuating channel. The actuating tool or push button is thus guided precisely to the deflection surface by the actuating channel, ensuring reliable opening of the clamping point.

According to an advantageous embodiment of the invention, the actuating channel is accessible via an actuating opening in the insulating housing, which is arranged on the side of the housing where the conductor entry opening is located.

According to an advantageous embodiment of the invention, the conductor terminal has a retaining element designed to hold the clamping arm in the open position. This retaining element allows the clamping arm to remain in the open position even when no actuating force is applied to the actuator. Such a design enables the integration of a technology for automatically connecting a conductor in spring-loaded terminals and conductor terminals of various designs. In particular, proven conductor terminals of known design can thus be easily upgraded to include an automatic release function, i.e., automatic connection of the electrical conductor to be clamped.

The retaining element can be movably arranged, e.g., sliding, pivoting, or otherwise deflectable, so that it can be easily deflected by the inserted conductor to achieve the desired release of the clamping arm from the retaining element. The retaining element can be slidably mounted, e.g., in a linear or arc-shaped direction. The retaining element can be pivotally mounted. In this case, the retaining element can pivot about a fixed or variable pivot axis. In the case of a variable pivot axis, the retaining element can, for example, be floatingly pivotable. The retaining element can also perform a combined sliding and pivoting movement. The retaining element can also be movably mounted in another way so that it can be deflected sufficiently to release the locking of the clamping arm from the retaining element.

The actuator allows the clamping arm to be moved into the open position against the spring force of the clamping spring when manually actuated. In this open position, the clamping arm can then be held by the retaining element, even without further manual actuation of the mechanism, so that the electrical conductor can be inserted at any time without requiring any special force. For example, the clamping arm can be locked onto the retaining element in the open position.

The clamping arm, together with the contact section of the busbar, can form a clamping point for connecting an electrical conductor between the clamping arm and the contact section. In the open position, at least the clamping edge of the clamping arm is pivoted away from the contact section of the busbar. The clamping arm can be pivoted, for example, between an open position in which the electrical conductor is freely movable between the clamping arm and the contact section, and a clamped position in which the clamping arm clamps the electrical conductor to the contact section.

The retaining element can, for example, act directly on the clamping leg to hold it in the open position. Thus, for instance, a first locking element can be arranged on the clamping leg and a second locking element on the retaining element, with the first and second locking elements being able to interlock in the open position. The first locking element can be designed as a locking projection or locking hook. The second locking element can be designed as a locking edge or locking opening.

The retaining element can be a separate component, attached, for example, to the insulating housing of a conductor terminal block, to the busbar, or to another component. Alternatively, the retaining element can be integrally formed with the clamping spring.

According to an advantageous embodiment of the invention, the retaining element is arranged behind the clamping point or behind the majority of the busbar in the direction of conductor insertion into the spring-loaded clamping connection. In this way, the retaining element does not obstruct the insertion of the electrical conductor. For example, in the open position, i.e., when the clamping leg is locked onto the retaining element, the retaining element, when viewed in the direction of conductor insertion, may not protrude into a conductor receiving space, or may only protrude slightly, relative to the clamping leg.

According to an advantageous embodiment of the invention, the spring-loaded clamping connection has a release element, the actuation of which deflects the retaining element sufficiently to release the clamping leg held on the retaining element. The release element may have a release section. The clamping leg, held on the retaining element in the open position, can be released from the retaining element by means of the release element when an electrical conductor to be connected exerts an actuating force on the release section. This allows the clamping leg to be automatically released from the retaining element by inserting the electrical conductor. The release section can be actuated by a separate tool, a component of the conductor connection terminal, such as an actuating element, or directly by the inserted electrical conductor itself, thereby causing the clamping leg to be released from the retaining element. The release element allows the clamping leg, which is held in the open position on the retaining element, to be released from the retaining element by applying pressure to the release section in the conductor entry direction (L) of the electrical conductor to be connected. Depending on the design of the spring-clamp connection, the release element can be formed as part of the clamping spring, e.g., as a release element integrally formed with the clamping spring, or as a separate component.

According to an advantageous embodiment of the invention, the release element is an integral part of the component or assembly of the spring-clamp connection that includes the retaining element. This minimizes the design and assembly effort for the spring-clamp connection. In particular, two separate components are not required for mounting the release element and the retaining element. Components or assemblies are not assembled, but only one. For example, the release element can be formed as a single piece with the retaining element. The component or assembly can be made of, for example, plastic or metal, or a combination of such materials.

According to an advantageous embodiment of the invention, the clamping spring has a support section designed to support the clamping spring on the busbar. This support section ensures secure support of the clamping spring and provides sufficient resistance to the spring force exerted by the clamping leg.

According to an advantageous embodiment of the invention, the support section comprises a base section and a mounting section, wherein the clamping leg branches off from the base section and the support section, with its mounting section, engages behind the busbar, so that the busbar rests on the mounting section and is at least partially arranged between the base section and the mounting section. The clamping leg can branch off from the base section, in particular without a 180° spring arc. For example, the clamping leg can branch off from the base section at an acute angle, which, for instance, may be less than 60° in the open position. The base section can be connected to the mounting section via a connecting section. For example, the base section can run substantially parallel to the mounting section or at a slight angle to it, in particular an angle of less than 20°.

According to an advantageous embodiment of the invention, a conductor guidance channel for guiding the electrical conductor to be clamped to the contact section can be formed in the insulating material housing, wherein the release section of the release element is arranged in the conductor guidance channel or at least projects into the conductor guidance channel or is arranged at least in extension of the conductor entry channel.

According to an advantageous embodiment of the invention, the release section of the release element can be arranged behind the contact section or at least behind the clamping point in the conductor insertion direction.

For the purposes of the present invention, the indefinite term "a" is not to be understood as a numeral. Therefore, when, for example, reference is made to a component, this is to be interpreted as "at least one component". Where angles are specified in degrees, these refer to a circle of 360 degrees (360°).

The invention is explained in more detail below with reference to exemplary embodiments and drawings.

• 1 eine Leiteranschlussklemme in seitlicher Schnittansicht in der Klemmstellung,
• 2 einen Federkraftklemmanschluss der Leiteranschlussklemme gemäß 1 in Seitenansicht,
• 3 die Leiteranschlussklemme gemäß 1 in der Offenstellung mit eingeführtem Werkzeug,
• 4 die Leiteranschlussklemme gemäß 1 in einer perspektivischen Schnittansicht,
• 5 eine Klemmfeder in perspektivischer Ansicht,
• 6 eine Stromschiene in perspektivischer Ansicht,
• 7 ein kombiniertes Halte-Löse-Element in perspektivischer Ansicht,
• 8 einen Mitnehmer in perspektivischer Ansicht.

They show

• 1 a conductor terminal block in a side sectional view in the clamping position,
• 2 a spring-loaded clamp connection of the conductor terminal according to 1 in side view,
• 3 the conductor terminal according to 1 in the open position with the tool introduced,
• 4 the conductor terminal according to 1 in a perspective sectional view,
• 5 a clamping spring in perspective view,
• 6 a power rail in perspective view,
• 7 a combined holding and releasing element in perspective view,
• 8 a drive unit in perspective view.

The 1 Figure 1 shows a conductor terminal 1 which has an insulating housing 2. The insulating housing 2 has a conductor entry opening 20 on one conductor entry side, through which an electrical conductor can be inserted into the insulating housing 1 in a conductor entry direction L and clamped to a spring-loaded terminal.

A spring-loaded clamping connection is visible in the insulating housing 2, comprising a clamping spring 4 and a busbar 3. The clamping spring 4 has a support section 41, via which the clamping spring 4 is supported on the busbar 3. The clamping spring 4 also has a clamping leg 43 branching off from the support section 41 at an acute angle. The clamping leg 43 extends to a free end, at which the clamping leg 43 has a clamping edge 46 for clamping the electrical conductor. In the 1 In the clamping position shown, the clamping leg 43 with the clamping edge 46 rests against a contact section 31 of the busbar 3 when no electrical conductor is inserted. An electrical conductor can be clamped between the clamping leg 43 or the clamping edge 46 and the contact section 31 at a clamping point 30.

As the 2 To further illustrate, the support section 41 extends from a base section 40, from which the clamping leg 43 branches off, to a connecting section 42 arranged at an angle to it. The connecting section 42 transitions into a fastening section 44 arranged at an angle to the connecting section 42. The fastening section 44 engages behind the busbar 3, i.e., it rests against the back of the busbar 3 on a side facing away from the clamping point 30. Viewed from the side, the clamping spring 2 thus essentially has a U-shape open in the opposite direction to the conductor insertion L.

The conductor terminal 1 has a mechanism for moving the clamping leg 43 from the clamping position to the open position, as shown in the 1 and 2 The mechanism includes a driver 6, which can be formed integrally with the clamping spring 4 or, as illustrated in the embodiment shown, can be a separate component from the clamping spring 4, e.g., a sheet metal component that can be manufactured as a stamped and bent part. The driver 6 has a deflection surface 60 at which the driver 6 can be actuated by an actuating force B. The actuating force B can be transmitted to the deflection surface 60 via an actuating opening or an actuating channel 22 in the insulating housing 2, for example, by means of a tool inserted into the actuating channel 22. The actuating force B transmitted to the deflection surface 60 moves the clamping leg 43 away from the contact section 31 until it reaches the 3 The disclosure shown is located there.

The deflection surface 60 is, as can be seen, clearly separated from the clamping leg 43 by a gap. To bridge this gap, the driver 6 has at least one connecting arm 61, and it is advantageous to design the driver 6 symmetrically with two laterally arranged connecting arms 61. The connecting arm 61 has a fastening element 62 with which the connecting arm 61 can be positively attached to the clamping leg 43. The fastening element 62 has an elongated hole 63 into which an actuating projection 45, extending laterally from the clamping leg 43, projects.

The conductor terminal 1 also has a retaining element 5 by which the clamping leg 43 can be held in the open position. The retaining element 5 has a locking element 50 which can engage with a corresponding locking element on the clamping leg 43 in the open position. The clamping leg 43 cannot then easily move back into the clamped position. The locking element formed on the clamping leg 43 can, for example, be formed by the clamping edge 46, as illustrated in the figures. However, at least one separate locking element can also be formed on the clamping leg 43, for example, in the form of a projecting locking tab, which can then be engaged with the locking element 50.

The conductor terminal 1 also has a release element 8, which serves to release the locking mechanism of the clamping leg 43 on the retaining element 5. In this case, the release element 8 is integrally formed with the retaining element 5 to form a combined retaining-release element 5, 8, which will be explained in more detail below. The release element 8 has a release section 80, which can be actuated by the inserted electrical conductor. If an electrical conductor exerts a compressive force on the release section 80, the retaining element 5 with the locking element 50 is thereby displaced slightly towards a rear housing wall 21 of the insulating housing 2 until the clamping leg 43 can release from the locking element 50. The clamping leg 43 then springs out until it rests against the inserted electrical conductor and presses it against the contact section 31.

As in 3 As can be seen, the driver 6 can be deflected by means of a tool 7 by applying the actuating force B to the deflection surface 60, thereby moving the clamping leg 43 into the open position. As can be seen, the tool 7 is supported against an inner wall of the actuating channel 22 in order to absorb the forces of the deflected clamping spring 4.

The 4 further clarifies the arrangement of the elements already explained in a perspective view.

The 5 Figure 4 shows an example of a clamping spring 4 in which two clamping legs 43 are implemented in a single-piece assembly. The clamping spring 4 is thus suitable for two adjacent spring-loaded clamping connections. The clamping spring 4 can be used with all previously described conductor connection terminals. The various sections of the support section 41 are visible, namely the base section 40, the connecting section 42, and the fastening section 44. Also visible are the molded-on receptacles 47 on the connecting section 42, which serve to receive and support the retaining element 5, as will be explained below.

The 6 Figure 3 shows a busbar 3 which offers two adjacent receiving points for electrical conductors at its contact section 31 and is therefore suitable for the in 5 The clamping spring 4 shown is suitable for clamping two next to each other. to realize the arranged spring-loaded clamping connections. On the busbar 3, in particular on the area facing the release element 8, brackets 34 for holding the combined retaining-releasing element 5, 8 can be integrally formed.

The 7 Figure 1 shows a combined holding-release element 5, 8, which can be used with the conductor connection terminals described above. The holding-release element 5, 8 has a holding element 5, which is formed with the aforementioned locking element 50 at its free end. The area of the holding element 5 formed with the locking element 50 has positive-locking connecting elements 51, which can be inserted into the receiving elements 47 of the support section 41. This allows the locking element 50 to be supported against the spring force exerted by the clamping leg 43 in the open position on the support section 41, in particular on the connecting section 42. The holding element 5 transitions via upper longitudinal sections 52 into the release element 8, on which the release section 80 is arranged. The release section 80 is connected on its opposite side via lower longitudinal sections 53 to a fastening section 54 of the retaining-release element 5, 8, which can be hooked into one of the brackets 34 on the busbar 3. This fixes the entire retaining-release element 5, 8 to the busbar 3.

When the release section 80 is subjected to force by the electrical conductor 9, the lower part of the retaining-release element 5, 8, which is attached to the bracket 34 via the fastening section 54, is fixed and cannot be deflected. Accordingly, only the upper part of the retaining-release element 5, 8 with the locking element 50 is deflected by the inserted electrical conductor 9 and the release section 80.

One can recognize in the 7 Furthermore, the combined retaining-release element 5, 8 in the area of the upper longitudinal sections 52 can be designed as a continuous sheet metal part, but can have a first recess 55 between the upper longitudinal sections 52. Similarly, the combined retaining-release element 5, 8 in the area of the lower longitudinal sections 53 can be designed as a continuous sheet metal part, but can have a second recess 56 between the lower longitudinal sections 53. The first and/or second recess 55, 56 increases the elasticity of the retaining-release element 5, 8, thereby reducing the required release forces that must be applied to the release section 80 by the inserted electrical conductor 9. Another advantage of the first and/or second recess 55, 56 is that a viewing window is provided through which it can be visually checked whether the electrical conductor 9 is inserted sufficiently far into the insulating housing 2, at least if a transparent housing material is used in this area.

The 8 Figure 1 shows the driver 6 with the deflection surface 60 already described. A connecting arm 61 projects from each of the opposite sides of the deflection surface 60, extending essentially perpendicular to the deflection surface 60. The connecting arms 61 have the previously described elongated holes in the fastening elements 62, with which the driver 6 can be attached to the actuating projections 45 of the clamping leg 43.

Reference symbol list:

1

conductor connection terminal

2

Insulating housing

3

busbar

4

Clamping spring

5

retaining element

6

drive

7

Tool

8

Solvent

20

conductor entry opening

21

rear case wall

22

Actuating channel

30

Clamping point

31

Contact section

34

bracket

40

Basic section

41

Support section

42

Connection section

43

Clamping leg

44

Fastening section

45

Operational advantage

46

Clamping edge

47

Recording

50

Latching element

51

Connecting element

52

upper longitudinal section

53

lower longitudinal section

54

Fastening section

55

first recess

56

second recess

60

Deflection surface

61

Connecting arm

62

Fixing element

63

Slotted hole

80

Solution section

B

Actuating force

L

ladder insertion direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents cited by the applicant was automatically generated and is included solely for the reader's convenience. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• DE 10 2020 119 372 A1 [0002]

Claims (16)

A conductor terminal (1) with an insulating housing (2) having at least one conductor entry opening (20) for receiving an electrical conductor in a conductor entry direction (L), wherein at least one spring-loaded clamping connection for connecting an electrical conductor by means of spring force is arranged in the insulating housing (2), wherein the spring-loaded clamping connection has at least one busbar (3) and a clamping spring (4) having a clamping leg (43) with a clamping edge (46) for clamping an electrical conductor at a clamping point on a contact section (31) of the busbar (3), characterized in that a driver (6) is arranged on the clamping leg (43), which has a deflection surface (60) projecting from the clamping leg (43) on the side of the clamping leg (43) facing away from the contact section (31) for deflecting the clamping leg (43), wherein the clamping leg (43) is guided onto the deflection surface by a force in the conductor entry direction (L). (60) the applied actuating force (B) can move from a clamping position to an open position. conductor terminal block according to Claim 1 , characterized in that the deflection surface (60) can be subjected to the actuating force (B) on a surface side facing the clamping leg (43). Conductor terminal according to one of the preceding claims, characterized in that the driver (6) is formed integrally with the clamping leg (43) or the driver (6) is designed as a component separate from the clamping spring (4) which is attached to the clamping leg (43). Conductor terminal according to one of the preceding claims, characterized in that the driver (6) is fixed at a fastening point on the clamping leg (43) at least against forces acting in the conductor insertion direction (L), wherein at least one connecting arm (61) of the driver (6) extends from the fastening point to the deflection surface (60). conductor terminal block according to Claim 4 , characterized in that the at least one connecting arm (61) is arranged orthogonally to the planar extension of the clamping leg (43) and/or orthogonally to the planar extension of the deflection surface (60). conductor terminal according to one of the Claims 4 until 5 , characterized in that the at least one connecting arm (61) has a higher area moment of inertia in the longitudinal direction of the clamping leg (43) than the clamping leg (43). conductor terminal according to one of the Claims 4 until 6 , characterized in that the at least one connecting arm (61) has an elongated hole (63) into which an actuating projection (45) extending laterally from the clamping leg (43) projects. Conductor terminal according to one of the preceding claims, characterized in that the insulating housing (2) has at least one actuating channel (22) in which an actuating tool (7) which is not part of the conductor terminal (1) or a push button designed as part of the conductor terminal (1) for actuating the clamping leg (43) can be arranged. conductor terminal block according to Claim 8 , characterized in that the deflection surface (60) projects into the actuating channel (22) or at least into a housing section of the insulating housing (2) which is arranged in extension of the actuating channel (22). conductor terminal according to one of the Claims 8 until 9 , characterized in that the actuating channel (22) is accessible via an actuating opening of the insulating housing (2) which is arranged on the side of the housing on which the conductor entry opening (20) is located. Conductor terminal according to one of the preceding claims, characterized in that the conductor terminal (1) has a retaining element (5) which is designed to hold the clamping leg (43) in the open position. conductor terminal block according to Claim 11 , characterized in that the retaining element (5) is arranged in the conductor insertion direction (L) behind the clamping point or behind the predominant part of the busbar (3). Conductor terminal according to one of the preceding claims, characterized in that the spring-loaded clamping connection has a release element (8) by actuation of which the retaining element (5) can be deflected to such an extent that the clamping leg (43) held on the retaining element (5) is released from the retaining element (5). conductor terminal block according to Claim 13 , characterized in that the clamping leg (43) held on the retaining element (5) in the open position can be detached from the retaining element (5) when an electrical conductor to be clamped is exerts actuating force on a release section (80) of the release element. Conductor terminal according to one of the preceding claims, characterized in that the clamping spring (4) has a support section (41) which is designed to support the clamping spring (4) on the busbar (3). conductor terminal block according to Claim 15 , characterized in that the support section (41) has a base section (40) and a fastening section (44), wherein the clamping leg (43) branches off from the base section (40) and the support section (41) with its fastening section (44) engages behind the busbar (3), so that the busbar (3) rests on the fastening section (44) and is at least partially arranged between the base section (40) and the fastening section (44).