DE102019109467A1 - Conductor connection terminal - Google Patents

Abstract

The invention relates to a conductor connection terminal (1) for connecting an electrical conductor with spring force clamping, having at least one clamping spring (4) and an actuating lever (5) which can be pivoted over a pivoting range and pivoted between an open position and a closed position, wherein the clamping spring (4) can be deflected at least in the open position by actuating the actuating lever (5), characterized in that the conductor connection terminal (1) has a pivotably mounted spring actuator (6) as a further component, by means of which a pivoting movement of the actuating lever ( 5) can be transferred to the clamping spring (4) in order to deflect it, the actuating lever (5) being coupled to the spring actuator (6) via a gear mechanism (7, 51, 54, 56, 61, 64, 66), whereby through the gear mechanism (7, 51, 54, 56, 61, 64, 66) a pivoting movement of the actuating lever (5) into a pivoting movement of the spring actuator (6) is nkable.

Description

The invention relates to a conductor connection terminal for connecting an electrical conductor with spring force clamping, comprising at least one clamping spring and an actuating lever which can be pivoted over a swivel range and can be swiveled between an open position and a closed position, the clamping spring being at least in the open position is deflectable.

Such conductor terminals are known, for. B. by the conductor connection terminals of the 221 series of the applicant.

On the basis of this, a further improved conductor connection terminal is to be specified.

This object is achieved in a conductor connection terminal of the type mentioned at the outset in that the conductor connection terminal has a pivotably mounted spring actuator as a further component, by means of which a pivoting movement of the actuating lever can be transmitted to the clamping spring in order to deflect it, the actuating lever being connected to the spring actuator via a gear mechanism is coupled, wherein a pivoting movement of the actuating lever can be deflected into a pivoting movement of the spring actuator by the gear mechanism. The invention has the advantage that a known, previously one-piece actuating mechanism of a clamping spring, which comprises only a one-piece embodiment of an actuating lever, can be divided into two parts, namely the actuating lever and the spring actuator. Such an at least two-part embodiment of the actuation mechanism enables more flexible design options for the actuation mechanism and for the entire conductor connection terminal. In addition, the design and arrangement of the pivoting movements of the individual parts, d. H. of the operating lever and the spring actuator, more flexible and thus more universal. By using a gear mechanism, more flexible design options for a translation of force and / or distance between the actuating lever and the spring actuator are made possible.

The gear mechanism can be implemented as a separate component of the conductor connection terminal or as parts that are structurally combined with the operating lever and / or the spring actuator, e.g. B. by respective toothings on the outer circumference of the operating lever and / or the spring actuator. The transmission ratio between the operating lever and the spring actuator, i.e. H. the transmission ratio of the gear mechanism can in particular deviate from the value 1: 1.

In the case of the described actuation mechanism comprising an actuation lever and a spring actuator, the actuation lever can also be viewed as a handle section of the actuation arrangement and the spring actuator as an actuation section of the actuation arrangement. The handle section is used for the manual gripping and actuation of the actuation arrangement, the actuation section for the actual application of the clamping spring.

The clamping spring can have a contact limb, a clamping limb and a spring arch connecting the contact limb to the clamping limb. The contact leg is used to fix the clamping spring within the conductor connection terminal, for. B. on a housing or on a busbar of the conductor connection terminal. The clamping leg is used to clamp an electrical conductor, for. B. by means of the free end of the clamping leg. The clamping leg can have a clamping edge at the free end in order to effect a secure clamping of the electrical conductor. If the conductor connection terminal has a busbar, the electrical conductor can be clamped against the busbar by means of the clamping leg. A clamping point of the electrical conductor is then formed between the clamping leg or its free end and the busbar.

In particular, the clamping leg can be deflected by the spring actuator. The clamping spring can have at least one actuating leg, which can be acted upon by the spring actuator in order to effect the deflection of the clamping spring or the clamping leg. Such an actuating leg or actuating section can e.g. Branch off to the side of the clamp leg. If the clamping spring is designed without an actuating limb, the spring actuator can also act directly on the clamping limb in order to effect the deflection of the clamping spring or the clamping limb.

According to an advantageous An embodiment of the invention provides that the direction of rotation of the pivoting movement of the actuating lever is opposite to the direction of rotation of the pivoting movement of the spring actuator. The direction of rotation between the actuating lever and the spring actuator is thus deflected by the gear mechanism. If the actuating lever is pivoted, for example, in a clockwise direction, this leads to a pivoting of the spring actuator in an anti-clockwise direction. The same applies to the reverse pivoting direction. The transmission mechanism can thus be designed in particular as a deflection gear.

The conductor connection terminal can have a housing. The housing can be designed as an insulating material housing. According to an advantageous embodiment of the invention it is provided that the actuating lever is pivotably received in the housing. Accordingly, the operating lever is at least partially accommodated in the housing. A part of the operating lever can also protrude from the housing, e.g. B. a manual actuator. In particular, the mounting of the actuating lever can be arranged in the housing.

According to an advantageous embodiment of the invention it is provided that the actuation lever is loosely coupled to the spring actuator. This includes e.g. the embodiment that the actuating lever has no fixed connection to the spring actuator. Such a loose coupling includes in particular the embodiment that the point of engagement between the actuating lever and the spring actuator is variable and in particular is variable relative to the actuating lever and / or to the spring actuator during a pivoting movement. The loose coupling allows simple assembly of the conductor connection terminal. If the conductor connection terminal is dismantled, no special work is required for releasing the spring actuator from the actuating lever, as these parts can be easily removed from one another due to their loose coupling, or they can be disconnected from each other when the conductor connection terminal is dismantled.

The actuating lever can be mounted loosely or floating inside the conductor connection terminal. The spring actuator can be mounted loosely or floating in the conductor connection terminal.

According to an advantageous embodiment of the invention it is provided that the actuation lever is mounted with a fixed axis of rotation and / or the spring actuator is mounted with a fixed axis of rotation. This has the advantage that the gear mechanism can be designed relatively simply and inexpensively.

According to an advantageous embodiment of the invention, it is provided that the transmission mechanism is designed as a gear transmission. For example, a toothed wheel can be attached to the actuating lever and a corresponding toothed wheel can be attached to the spring actuator, these toothed wheels being in engagement with one another. It can also be formed directly a toothing on the operating lever and the spring actuator, for. B. by such gears in the production of the operating lever and the spring actuator as plastic components are produced in one piece with the respective component directly in the manufacturing process, z. B. in an injection molding production.

According to an advantageous embodiment of the invention, it is provided that the gear mechanism has respective cam tracks corresponding to one another on the actuating lever and on the spring actuator. This also allows a reliable transmission of a movement in the opposite direction from the actuating lever to the spring actuator. Corresponding cam tracks of this type can also be implemented in a relatively robust manner when using plastic material for the gear mechanism. For example, the curved paths can be designed as elliptical curved paths.

According to an advantageous embodiment of the invention it is provided that the gear mechanism is formed by surfaces of the actuating lever and the spring actuator which are in contact with one another, each of which has an increased roughness and for example form a type of friction gear. In this way, a particularly cost-effective gear mechanism can be implemented.

If the gear mechanism has, for example, a gear on the actuating lever and a corresponding gear on the spring actuator, both gears can be provided with teeth on the outer circumference. Alternatively, one gear can also be provided with internal teeth and the other with external teeth, so that the gear with the external teeth is arranged at least partially within the gear with the internal teeth. In this way, the gear mechanism can be implemented in a particularly space-saving manner. In this embodiment, the gear transmission can be designed, for example, as a planetary transmission.

Also in the other embodiments of the transmission mechanism, the aforementioned arrangement of one element can be realized within the other element, e.g. B. in that the one curved path is arranged within the other curved path. The same applies to the surfaces in contact with one another, which can optionally be arranged on the outer circumference of the operating lever and the spring actuator, or at least on the inner circumference of a cavity of one of the actuating lever or spring actuator elements.

In the context of the present invention, the indefinite term “a” is not to be understood as a numerical word. So if e.g. When speaking of a component, this is to be interpreted in the sense of “at least one component”. As far as angles are given in degrees, these refer to a circle of 360 degrees (360 °).

The invention is explained in more detail below on the basis of exemplary embodiments using drawings.

Figure list

• 1 a conductor connection terminal in a first side view and
• 2 the conductor connection terminal according to 1 in a second side view and
• 3 the conductor connection terminal according to 1 in a perspective view and
• 4th , 5 further embodiments of transmission mechanisms.

List of reference symbols

1

Conductor connection terminal

2

casing

3

Busbar

4th

Clamp spring

5

Operating lever

6th

Spring actuator

7th

Connection section

20th

Conductor entry opening

21st

Conductor entry channel

30th

Clamping area

31

Holding area

40

Contact leg

41

Spring bow

42

Clamp leg

43

Clamping edge

50

Operating range

51

Base body

52

Journal

53

Axis of rotation

54

Interlocking

56

Curved path

61

Base body

62

Journal

63

Axis of rotation

64

Interlocking

65

Spring carrier

66

Curved path

With reference to the 1 to 3 becomes a conductor connection terminal 1 described in which a gear mechanism is implemented in a first embodiment. The conductor connection terminal 1 has a housing 2 , a busbar 3 , a spring clip 4th , an operating lever 5 and a spring actuator 6th on. The power rail 3 , the clamp spring 4th , the operating lever 5 and the spring actuator 6th can be completely or at least partially in the housing 2 be arranged.

The clamping spring 4th has an abutment leg 40 , one on the contact leg 40 subsequent spring bow 41 and one at the feather bow 41 subsequent clamping leg 42 on. The clamp leg 42 ends at its free end with a clamping edge 43 .

The power rail 3 is designed as a frame-shaped metal part that has a holding frame for the clamping spring 4th forms. The power rail 3 has a clamping area 30th on, together with the clamping leg 42 a clamping point for clamping an electrical conductor is formed. The electrical conductor can be between the clamping edge 43 and the clamping area 30th be clamped. The power rail 3 extends over several bends towards a holding area 31 on which the clamping spring 4th with their contact leg 40 on the power rail 3 attached, fixed or hung. The clamping spring 4th is in this embodiment accordingly in the frame-like structure of the busbar 3 fixed so that the forces of the clamping spring 4th not on the case 2 be transmitted.

The case 2 has a conductor entry opening 20th to which a conductor entry channel is attached 21st connects. An electrical conductor can through the conductor insertion opening 20th in the housing 2 are introduced and at the clamping point by means of the clamping spring 4th and the power rail 3 be fixed.

The conductor connection terminal 1 points to the deflection of the clamping leg 42 , ie the spring actuator to open the clamping point 6th on. The spring actuator 6th has a base body 61 on which a spring follower 65 is arranged. The spring driver 65 can for example laterally of the base body 61 protrude and accordingly in contact with the clamping leg 42 come. Like in particular the 3 shows the spring follower extends 65 only over part of the width of the clamp leg 42 so that there is enough space left for the arrangement of the electrical conductor.

The base body 61 of the spring actuator 6th is around an axis of rotation 63 pivotable, ie about this axis of rotation 63 rotatable. For the rotatable mounting of the spring actuator 6th around the axis of rotation 63 can the base body 61 for example a bearing journal 62 or one through the base body 61 have wholly or partially continuous shaft. The spring driver 65 is eccentric to the axis of rotation 63 on a side surface of the base body 61 arranged.

The operating lever 5 has a manual operating area 50 on which the operating lever 5 is to be operated by a user. The manual actuation area extends at least partially out of the housing 2 so that it can be easily grasped by the user. The operating lever 5 has one with the manual operating area 50 connected base body 51 on. The operating lever 5 is around an axis of rotation 53 pivotable, ie about this axis of rotation 53 rotatable. The operating lever 5 can for example by a bearing pin 52 or one entirely or partially through the base body 51 be rotatably mounted through shaft. The base body 51 is via a gear mechanism with the spring actuator 6th or with its base body 61 coupled. In this exemplary embodiment, the transmission mechanism is designed as a gear transmission. The base body has accordingly 51 of the operating lever 5 a toothing on the outer circumference 54 on. The base body 61 of the spring actuator 6th has a toothing on the outer circumference 64 on, with the gearing 64 of the base body 61 as a counterpart to the toothing 54 of the base body 51 is trained. The teeth 54 , 64 are in engagement with each other.

The figures show the operating lever 5 each in the closed position. The operating lever 5 can be pivoted into an open position by turning at an angle that is e.g. B. can be in the range of 45 ° to 135 °, is pivoted such that the manual operating range 50 upwards, ie from the housing 2 away, is moved. In other words, in the representation of the 1 becomes the operating lever 5 pivoted clockwise when it is moved from the illustrated closed position to the open position. Through the gear mechanism with the teeth 54 , 64 becomes the pivoting movement of the base body that is generated 51 in a pivoting movement of the spring actuator 6th diverted. This becomes the spring driver 65 against the clamp leg 42 pressed and deflects this upwards, ie the clamping leg 42 is by the spring driver 65 from the clamping area 30th the power rail 3 moved. In the view according to 2 the spring actuator leads 6th when moving the operating lever 5 from the closed position to the open position, for example, a clockwise rotation. When the operating lever is moved 5 from the open position to the closed position there is accordingly a reversed pivoting movement both in the case of the actuating lever 5 as well as the spring actuator 6th carried out.

That in the embodiment of 1 to 3 realized gear transmission with the gears 54 , 64 can also be implemented in such a way that at least one of the toothings 54 , 64 is designed as internal teeth. In this case, the corresponding base body 51 , 61 an interior space on whose inner circumference the respective toothing 54 , 64 is trained. The other element with the toothing assigned as a counterpart is then made correspondingly smaller and protrudes into the interior space and is in engagement with the internal toothing. There can also be other gear elements in this interior, for. B. such that a planetary gear is implemented therein.

The 4th and 5 show alternative embodiments of gear mechanisms on the basis of detail representations of a conductor connection terminal. The conductor connection terminals with the gear mechanisms of the 4th and 5 can also be designed in a manner comparable to the conductor connection terminal 1 as they were previously based on the 1 to 3 has been described.

In the 4th the gear mechanism is formed in that the base body 51 of the operating lever 5 via a flexible connection section 7th with the base body 61 of the spring actuator 6th connected is. The connecting section 7th is made of a suitable flexible material, e.g. B. in the form of a flexible tape, which for example in a two-component injection molding process with the base body 61 of the spring actuator 6th and the base body 51 of the operating lever 5 can be connected. This also enables a gear mechanism with the corresponding deflection of a pivoting movement of the actuating lever 5 in a pivoting movement of the spring actuator 6th will be realized.

In the 5 is the gear mechanism by means of corresponding cam tracks 56 , 66 on the operating lever 5 or its base body 51 and on the spring actuator 6th or its base body 61 realized. The curved tracks 56 , 66 can e.g. B. be designed as elliptical, pressure-stressed cam tracks. The desired deflection can also be realized in this way.

Claims (8)

Conductor connection terminal (1) for connecting an electrical conductor with spring force clamping, having at least one clamping spring (4) and an actuating lever (5) which can be pivoted over a pivoting range and between a The open position and a closed position can be pivoted, the clamping spring (4) being deflectable at least in the open position by actuating the actuating lever (5), characterized in that the conductor connection terminal (1) is a further component of a pivotably mounted spring actuator ( 6), by means of which a pivoting movement of the actuating lever (5) can be transmitted to the clamping spring (4) in order to deflect it, the actuating lever (5) via a gear mechanism (7, 51, 54, 56, 61, 64, 66) is coupled to the spring actuator (6), with the gear mechanism (7, 51, 54, 56, 61, 64, 66) converting a pivoting movement of the actuating lever (5) into a pivoting movement of the spring actuator (6). Conductor connection terminal according to Claim 1 , characterized in that the direction of rotation of the pivoting movement of the actuating lever (5) is opposite to the direction of rotation of the pivoting movement of the spring actuator (6). Conductor connection terminal according to one of the preceding claims, characterized in that the conductor connection terminal (1) has a housing (2) in which the actuating lever (5) is pivotably received. Conductor connection terminal according to one of the preceding claims, characterized in that the actuating lever (5) is loosely coupled to the spring actuator (6). Conductor connection terminal according to one of the preceding claims, characterized in that the actuating lever (5) is mounted with a fixed axis of rotation (53) and / or the spring actuator (6) is mounted with a fixed axis of rotation (63). Conductor connection terminal according to one of the preceding claims, characterized in that the gear mechanism (7, 51, 54, 56, 61, 64, 66) is designed as a gear drive. Conductor connection terminal according to one of the preceding claims, characterized in that the gear mechanism (7, 51, 54, 56, 61, 64, 66) has respective mutually corresponding cam tracks (56, 66) on the actuating lever (5) and on the spring actuator (6). Conductor connection terminal according to one of the preceding claims, characterized in that the gear mechanism (7, 51, 54, 56, 61, 64, 66) is formed by surfaces of the actuating lever (5) and the spring actuator (6) which are in contact with one another, each of which have an increased roughness.

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