EP0806812A2 - Spring connector for an electrical conductor having abutment ribs - Google Patents

Abstract

An electrical equipment housing has a built-in power carrying rail (11) and adjacent to this is a metal spring clamp (1) that is formed with a loop shape from strip material. Formed within the housing recess is a reaction block (3) and the spring locates over this. One arm of the spring (18) engages the power rail and the other has an aperture (10). When a tool is inserted from the side (13) m the spring compresses and the aperture becomes aligned with a point of insertion (14) for an external conductor or wire. When the compressive force is released the wire is securely clamped.

Description

The invention relates to a tension spring connection for electrical conductors, in particular for use in fixed-pole housings, according to the preamble of claim 1.

Tension spring connections consist of an approximately loop-shaped tension spring, one end area of which forms a leg for resting on a busbar and the other end area of which forms a leg oriented approximately perpendicular to the busbar. In the leg oriented approximately perpendicular to the conductor rail, a window for the passage of the conductor rail is arranged, the lower edge of which forms a clamping edge for clamping a conductor under the conductor rail.

Tension spring connections of this type are known in their construction and are commercially available. For tension spring connections of this type, it is very important, when actuating the tension spring to insert a conductor, to ensure that an overextension of the tension spring does not exceed permissible values and that there is no deterioration in function due to plastic deformation of the tension spring. For this purpose, the tension spring is supported in its position on the conductor rail in such a way that when it is actuated, in particular during its opening movement, an overextension of the spring is prevented.

In the washer design of connection elements, in which tension springs are often used, multi-pole connection strips are assembled from individual plastic washers, whereby a subassembly, consisting of busbar and tension spring, can be easily inserted into the housing washer from the side, in accordance with the assembly and function. Securing the tension spring against overstretching is problem-free, usually by means of a stop cam molded onto the plastic housing of the disk. This stop cam has a shape adapted to the interior of the tension spring, so that the tension spring can freely deform when actuated in an area that can be defined by the shape of the cam. After this permissible deformation has been exceeded, part of the tension spring contacts the stop cam and can then no longer be deformed. The stop cam extends from a wall of the connecting disk far into the interior enclosed by the tension spring and permits lateral mounting of the tension spring only when the connecting disk is isolated.

In the case of fixed-pole housings, the importance of which in particular in the area of high number of poles and at the same time a very small pitch increases due to manufacturing, functional and installation reasons, such an over-extension protection for the tension spring is not possible, since the conductor rail and tension spring usually have to be inserted from above or below by inserting them and then cannot be plugged onto a plastic cam or the like that projects transversely to the direction of insertion into the interior of the loop-shaped tension spring.

The object of the present invention is therefore to support a tension spring of known construction in a connection element, preferably a connection element with a fixed-pole housing, in such a way that assembly can be carried out by a simple plug-in movement and reliable support of the tension spring against inadmissible deformations during operation is ensured.

The solution of the problem according to the invention results from the characterizing features of claim 1 in cooperation with the features of the preamble.

An essential feature of the invention of the proposed tension spring connection is that the tension spring is inserted into a pocket formed by the housing and, with sections of narrower width formed by edges near the edges, protrudes between stop elements which are fixed on both sides of the pocket and which protrude into the space enclosed by the tension spring and that the tension spring is actuated with sections of greater width can be applied to the stop elements. A tension spring usually consists of a sheet-metal strip made of spring steel wire, which is bent in a loop-shaped manner in a known manner and which has a usually the same width along its entire length. Such a tension spring can only be inserted into a housing pocket if no projections are arranged on the side surfaces of the housing pocket, as is not the case, for example, with the known inner stop cams. However, if the tension spring is provided with recesses in the edge region in certain areas, advantageously before the loop-shaped bending process is shaped, then a projection can be made on the inside of the pocket, at least in the regions in which the recesses come to lie within the pocket after insertion be arranged on the wall surfaces of the pocket, which at least partially protrudes into the interior of the loop-shaped area of the tension spring. In the tension spring connection according to the invention, such projections are provided on both sides on the inner surfaces of the housing pocket, these stop elements corresponding to the sections of the tension spring of smaller width formed by recesses near the edge. This enables the tension spring to be inserted into the housing pocket, sections of the stop elements simultaneously projecting into the interior of the space enclosed by the tension spring and interact with sections of greater width of the tension spring when the tension spring is actuated. Due to the deformation of the tension spring, these sections of greater width are displaced or swiveled within the housing pocket and lie against the stop elements when a permissible deflection is reached. As a result, a further displacement of the section of the tension spring that is movable when actuated is reliably prevented, so that the tension spring cannot be overloaded.

The subclaims show further preferred forms of the invention.

In a particularly preferred embodiment, the recesses close to the edges are arranged in the region of the tension spring which first enters the pocket fixed to the housing when it is inserted. This is usually the section opposite the window of the tension spring, in which the greatest deformation occurs when the tension spring is actuated. By providing the corresponding notches, the stop elements provided on both sides of the housing pockets and the tension spring do not touch in this area, and the freely movable part of the tension spring opposite the busbar can pivot against the stop elements by pivoting.

In a further preferred embodiment, the shape and the alignment of the recesses of the tension spring is primarily predetermined by the direction of insertion of the tension spring into the housing pocket, since pivoting of the tension spring within the housing pocket must be avoided as far as possible in order to achieve simple joining movements, for example a purely linear joining movement.

In a further preferred embodiment, the wider sections of the tension spring, which bear against the stop elements, are arranged adjacent to the recesses of the tension spring near the edges. As a result, the dimensions of the stop elements on the pocket surfaces of the housing can be small, and the corresponding recesses in the tension spring can be limited to smaller sections of the tension spring.

Another preferred embodiment of the tension spring connection has stop elements which extend so far in the direction of insertion of the tension spring that a stop occurs between wider sections of the tension spring and stop elements, preferably in the hump area of the tension spring, which is loaded directly with an actuating tool. This ensures that a correspondingly large counterforce securely supports this load by the point of application of the actuating force of the tension spring, without impermissible deformations occurring due to poor leverage.

Another advantageous embodiment of the tension spring connection has stop elements which extend so far in the direction of insertion of the tension spring that a stop occurs between wider sections of the tension spring and stop elements just above the end of the radius area of the tension spring. In particular, such an arrangement of the stop elements can be reliably prevented that the radially sensitive area of the tension spring is deformed inadmissibly.

In a further embodiment, for safe absorption of the actuating forces, the contact edges of the stop elements are arranged in the housing pocket in such a way that a flat contact between stop elements and wider sections of the tension spring occurs when the stop is struck. As a result, the actuation forces are derived on a surface and not only on individual points and supported securely.

Of particular advantage with the tension spring connection according to the invention is that the pocket-fixed stop elements for sufficient support are only slightly in must protrude the space enclosed by the tension spring, in particular only a few tenths of a centimeter are sufficient. As a result, the tension spring characteristic is only slightly impaired in its tension spring characteristic, at the same time the row spacing can be maintained due to the slight impairment of the spring characteristic of the tension spring.

It is also of particular advantage that the recesses, in cooperation with the stop elements, position the tension spring during assembly in the housing pocket and therefore simple and possible installation without additional shapes on the housing pocket can be achieved.

The drawing shows preferred embodiments of the tension spring connection according to the invention.

Figur 1

eine Prinzipdarstellung des erfindungsgemäßen Zugfederanschlusses im Teilschnitt sowie bei nicht betätigter Zugfeder, vereinfachte Darstellung zu Fig. 5,

Figur 2

eine Prinzipdarstellung gemäß Figur 1 mit betätigter Zugfeder,

Figur 3

ein Anschlußelement für einen Zugfederanschluß im Querschnitt bei unbetätigter Zugfeder und Kabel-/Leiterabgangsrichtung von 180 Grad,

Figur 4

den Zugfederanschluß gemäß Figur 3 mit Zugfeder in betätigter Stellung,

Figur 5

einen Zugfederanschluß entsprechend Figur 3, jedoch mit Leiterabgangsrichtung 90 Grad und unbetätigter Zugfeder,

Figur 6

den Zugfederanschluß gemäß Figur 5 mit betätigter Lage der Zugfeder.

Show it:

Figure 1

2 shows a basic illustration of the tension spring connection according to the invention in partial section and when the tension spring is not actuated, simplified illustration of FIG. 5,

Figure 2

2 shows a basic illustration according to FIG. 1 with the tension spring actuated,

Figure 3

a connecting element for a tension spring connection in cross-section when the tension spring is not actuated and the cable / conductor outlet direction is 180 degrees,

Figure 4

the tension spring connection according to Figure 3 with tension spring in the actuated position,

Figure 5

3 a tension spring connection corresponding to FIG. 3, but with a 90 degree conductor outlet direction and an unactuated tension spring,

Figure 6

the tension spring connection according to Figure 5 with actuated position of the tension spring.

FIG. 1 shows a basic illustration of how the tension spring connection according to the invention enables the tension spring 1 to be supported against inadmissible actuations. The tension spring 1 is shown inserted into a housing pocket 4 formed by the housing 19, the housing 19 being partially cut free for better clarity. The tension spring 1 of basically known construction consists of an insertion area, which is largely covered in FIG. 1 and has a plug-in window 10 (not shown here) for pushing through a conductor (also not shown). The hump area 17 adjoins the window area of the tension spring 1, on which an actuating tool (not shown) for opening the tension spring 1 can engage. The operation with the tool, not shown, takes place here in the direction of arrow 8a or 8b, as a result of which the leg of the tension spring 1 adjoining the hump area 17, essentially vertical in the illustration in FIG. 1, is tilted in the direction of arrow 8b and the window, not shown 10 releases. The other leg of the tension spring 1, which is assigned to the busbar 11, not shown here, is of less importance here and is therefore not described further. It is supported with the busbar 11 against contours fixed to the housing.

In FIG. 1, the insertion opening 9 into the housing-fixed pocket 4 is indicated above the tension spring 1, through which the tension spring 1 can be inserted into the housing pocket 4 in the direction of the mounting direction 7. At the opposite end of the housing pocket 4, here in the lower part of FIG. 1, it is shown in principle how the tension spring 1 is provided with recesses 2 and is arranged relative to stop elements 3, which are also shown in principle in the lower region of the housing pocket 4. The tension spring 1 has been provided with recesses 2 in its area assigned to the lower end of the housing pocket 4 in such a way that the recesses 2 in the inserted position of the tension spring 1 give space for the stop elements 3 which are arranged on the end walls of the tension spring 1 of the walls of the housing pocket 4 are formed. These recesses 2 are produced in an advantageous manner before the tension spring 1 is bent, for example by notching, and are advantageously notched in the range of only a few tenths of a millimeter. Through these recesses 2 on both sides, the tension spring 1 will have a smaller width in this area, so that when the tension spring 1 is inserted into the housing pocket 4 in this area it can protrude between the stop elements 3 without getting jammed between the stop elements 3 of the housing pocket 4. The dimensional design of the stop elements 3 and the recesses 2 is chosen so that the tension spring 1 can be used with little play. The end of the recesses 2 facing the busbar 11, not shown, is arranged above the vertical end of the stop elements 3. On the movable leg of the tension spring 1, which is assigned to the hump area 17, however, the end of the recesses 2 is located in the center area of the stop elements 3, so that when the tension spring 1 is deformed in the direction of the actuation direction 8b, this leg of the tension spring 1 according to a specific deformation path with its wider areas 18 to the stop elements 3 strikes. These wider areas 18 are arranged directly adjacent to the recesses 2 and, when the tension spring 1 is actuated, lie against the associated surfaces of the stop elements 3. This application prevents this leg of the tension spring 1 from further pivoting or deformation, as a result of which the tension spring 1 as a whole cannot be overloaded.

This striking of the movable leg of the tension spring 1 becomes clearer in the illustration in FIG. 2, which is identical to FIG. 1 with the exception of the illustration of the actuated position of the tension spring 1. The movable leg of the tension spring 1 is displaced in the direction of arrow 8b by an actuating tool (not shown), as a result of which the window 10 of the tension spring 1 which has now become visible allows a conductor to be inserted. The wider sections 18 of the tension spring 1 are placed on the movable leg of the tension spring 1 against the stop elements 3, further deformation of the tension spring 1 is only possible against a considerably greater resistance. This reliably prevents an inadmissible deformation of the tension spring 1.

The use of the recesses 2 and stop elements 3 shown in principle in FIGS. 1 and 2 can be clearly seen in FIG. 3 in a constructive design. Here, a connection element is shown, which consists of a housing 19 in which a housing pocket 4 for receiving a tension spring 1 is formed. Above the housing pocket 4, the housing pocket 4 can be closed by means of latching connections 5 with a housing cover 15, an actuating opening 13 for actuating the tension spring 1 and an insertion opening 14 for a conductor (not shown) being formed in the housing cover 15. At the lower end of the housing 19 in FIG. 3, a plug-in tulip 12 is indicated, which can be brought into electrical contact with the tension spring 1 via a busbar 11. The housing 19 can be plugged on by means of latching hooks 16, for example, on corresponding counter contacts, not shown.

In Figure 3, a tension spring 1 is inserted into a housing pocket 4 and is supported on the busbar 11 in a known manner. The tension spring 1 is installed through the plug-in opening 9 which has been opened before the cover 15 is put in place, a combination of plug tulip 12, busbar 11 and tension spring 1 being particularly advantageously inserted into the housing 19. Also within the housing pocket 4, a stop element 3 can be seen, which extends over the entire area of the inner wall of the housing pocket 4 arranged on the front side of the tension spring 1. This stop element 3 corresponds to recesses 2 of the tension spring 1, through which the tension spring 1 has a somewhat smaller width in this area than in the wider ones Sections 18 has. As can be seen from the position of the boundary edges 20 of the recesses 2, the tension spring 1 can be inserted into the housing pocket 4 in the undeformed state in the direction of the mounting direction 7 with a corresponding design of the widths without clamping contact with the stop elements 3. The movable leg of the tension spring 1 has further sections 18 which, when this leg is deformed, can rest against the associated surfaces of the stop elements 3, as can be seen in FIG. 4, which is otherwise identical to FIG. 3. Depending on the vertical length of the stop elements 3 and the permissible pivoted position of the freely movable leg of the tension spring 1, there is a more or less areal contact between the more ready sections 18 of the movable leg of the tension spring 1 and the contact surfaces of the stop elements 3. This is an impermissible actuation of the free leg of the tension spring 1 in the direction of the actuation directions 8 safely prevented.

FIGS. 5 and 6 show a connection element analogous to FIGS. 4 and 5, the undeformed position of the tension spring 1 being indicated in FIG. 5 and the deformed position being shown in FIG. 6. The connecting element in FIGS. 5 and 6 is a connecting element with an actuation primarily in the horizontal direction according to FIG. 5 according to arrow VIII. This results in constructive changes to the busbar 11 and to housing components, which are of no importance in this connection. What is different, however, is the dimensional design of the stop elements 3, which because of the mounting of the tension spring 1 in the direction of the mounting direction 7 do not protrude so far into the interior enclosed by the tension spring 1 and therefore, as can be seen in FIG. 6, a not so clearly large support allow the movable leg of the tension spring 1. The stop element 3 according to FIGS. 5 and 6 can also be varied by constructive measures, in particular the shape of the busbar 11 and the tension spring 1, and a greater overlap between the wider sections 18 of the tension spring 1 and the stop elements 3 can be achieved.

Reference list

1

- tension spring

2nd

- recesses

3rd

- stop elements

4th

- Housing pocket

5

- Locking contours housing

7

- Direction of assembly

8a

- 1st direction of actuation

8b

- 2nd direction of actuation

9

- insertion opening

10th

- Window

11

- track

12th

- Stick tulip

13

- Actuation opening for tension spring

14

- Insert opening for ladder

15

- Housing cover

16

- locking hook

17th

- Hump area of the tension spring

18th

- wider sections of the tension spring

19th

- Casing

20th

- Boundary edges recesses

21

- Radius area of the tension spring

Claims (9)

Tension spring connection for electrical conductors, in particular for use in fixed-pole housings, with an approximately loop-shaped tension spring (1), one end area of which has a leg for bearing on a busbar (11) and the other end area of which is oriented approximately perpendicular to the busbar (11) forms in which there is a window (10) for the passage of the busbar (11), the lower edge of which forms a clamping edge for clamping a conductor under the busbar (11), and with the tension spring (1) interacting stop elements (3) for the Limitation of the spring travel of the tension spring (1) when it is actuated,
characterized in that
the tension spring (1) is inserted into a pocket (4) formed by the housing (19) and, with sections of smaller width formed by recesses near the edge, protrudes between stop elements (3) which are fixed on both sides of the pocket and which each extend into the tension spring (1) protrude enclosed space and that the tension spring (1) can be applied to the stop elements (3) when actuated with sections (18) of greater width. Tension spring connection according to claim 1, characterized in that the recesses (2) close to the edge are arranged in the region of the tension spring (1) which, when inserted, first enters the pocket (4) fixed to the housing. Tension spring connection according to one of claims 1 or 2, characterized in that the shape and orientation of the recesses (2) can be designed in accordance with the direction of insertion (7) of the tension spring (1) into the housing pocket (4). Tension spring connection according to claim 1, characterized in that the wider sections (18) of the tension spring (1) which can be placed against the stop elements (3) are arranged adjacent to the recesses (2) close to the edge. Tension spring connection according to one of the preceding claims, characterized in that the stop elements (3) extend in the insertion direction (7) of the tension spring (1) to such an extent that a stop extends between wider sections (18) of the tension spring (1) and stop elements (3). preferably in the hump area (17) of the tension spring (1). Tension spring connection according to one of the preceding claims, characterized in that the stop elements (3) extend in the insertion direction (7) of the tension spring (1) to such an extent that a stop extends between wider sections (18) of the tension spring (1) and stop elements (3). sets the tension spring (1) just above the end of the radius area (21). Tension spring connection according to one of the preceding claims, characterized in that the contact edges of the stop elements (3) are arranged in the housing pocket (4) in such a way that a flat contact between the stop elements (3) and wider sections (18) of the tension spring (1 ) sets. Tension spring connection according to claim 1, characterized in that the pocket-fixed stop elements (3) protrude only slightly into the space enclosed by the tension spring (1), in particular protrude only a few tenths of a millimeter. Tension spring connection according to claim 1, characterized in that the recesses (2), in cooperation with the stop elements (3), position the tension spring (1) when it is inserted into the housing pocket (4).

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