Connection system

A connection system includes a current bar, a contact foot, a clamping element, and a bearing bar with an edge, behind which the clamping element reaches, the contact foot is held at the current bar by a resilient clamp connection for simplifying production.

BACKGROUND OF THE INVENTION

Field of the Invention

The invention relates to a connection system with a current bar and a contact foot and with a clamping element and a bearing bar with an edge, whereby the clamping element reaches behind the bearing bar edge and fixes the contact foot at the bearing bar.

A connection system, disclosed in European Patent 0 554 519 B1, corresponding to U.S. Pat. No. 5,334,054 to Conrad et al., for example, is usually part of a protective conductor terminal or a ground conductor terminal that serves for producing a conductive connection between one or more electrical conductors and a protective conductor busbar. To that end, a conductor bar with conductor terminals and a connection system including a mounting foot or contact foot, which is connected to the current bar, are installed in an insulating housing of the protective conductor series terminal or ground series terminal. The metallic mounting foot connects the current bar to the protective conductor busbar, also referred to as a bearing bar or cap bar.

In this prior art connection system, the contact foot and current bar are contacted by a fixed mechanical and, therefore, permanent, connection, for instance, by a weld, solder, or rivet joint between the contact foot and the current bar as according to the German Utility model G 77 12 331 U1, corresponding to U.S. Pat. No. 4,171,861 to Hohorst. Additional assembly devices are needed in order to produce these permanent connections, which leads to an unwanted production expenditure in the assembly of the connection system and thus the assembly of the protective conductor terminal.

SUMMARY OF THE INVENTION

It is accordingly an object of the invention to provide a connection system that overcomes the hereinafore-mentioned disadvantages of the heretofore-known devices of this general type and that simplifies a connection system of the above type with respect to production.

With the foregoing and other objects in view, there is provided, in accordance with the invention, a connection system, including a current bar, a contact foot, a clamping element, a bearing bar having a bearing bar edge, the clamping element extending behind the bearing bar edge and removably fixing the contact foot at the bearing bar, and the contact foot being contacted at the current bar in a resilient clamp connection.

The connection between the contact foot and the current bar of the connection system is constructed as a resilient clamp connection. In such a context, resilient clamp connection also encompasses a catch mechanism whose spring action guarantees not only a secure mechanical retention or fixing but also a reliable electrical contact between the contact foot and the current bar. The clamp connection can be advantageously unmade.

The invention is based on the idea that such a connection system can be simplified with respect to production if the interconnection among its individual parts is achieved simply by putting the parts together. To ensure reliable conductive contact as well as mechanical stability, gaps in the connection between the current bar and the contact foot, which may arise as a result of production tolerances, for example, should be avoided or at least compensated. Such compensation can be easily and reliably achieved by placing at least one of the relevant parts in the connection under a certain initial mechanical tension.

The resilient clamp connection, thus, enables easy assembling of the mounting foot and the current bar without additional assembly devices, and, on the other hand, it enables reliable contacting of the contact foot to the current bar, and, therefore, makes possible a durable electrical current.

In accordance with another feature of the invention, two contact legs are provided, at least one of which is resilient. According to a first variant, both the first contact leg and the second contact leg are formed on the contact foot, whereas, in a second variant, the first contact leg is formed on the contact foot, and the second contact leg is part of the clamping element.

In the first variant, the contact foot is of a resilient material, whereby the two contact legs form a V prior to being contacted with the current bar. After the contact foot, which includes the contact legs, has been connected to the current bar by the squeezing together of the two contact legs and the subsequent insertion of the free ends of the legs into receptive recesses or openings in the current bar, the contact legs in the clamp connection are under initial tension as a result of their spring force being exerted on the wall of the recess or opening. For purposes of accepting the two contact legs, one current bar opening can be provided for each of the free ends, or a common opening can be provided for both free ends.

In the second variant, the second contact leg extends as part of the clamping element parallel to the first leg, which is part of the contact foot, in the clamp connection to the current bar.

In either variant, the clamping element can be attached or disposed at the contact foot in different ways, the connection being either permanent or detachable. In the first variant, the clamping element is, expediently, formed at the contact foot. The clamping element is, then, a united or one-piece component of the contact foot, which makes possible a high degree of pre-production. The contact foot is, then, preferably, a metallic punched profile part.

In the second variant, the clamping element is expediently a separate part of resilient material, preferably, in the form of a steel clamping spring produced from a punch-bent part. In such a case, to guarantee precise positioning, the clamping element including the second contact leg has a recess or holding opening, through which a holding or positioning nose that is formed at the contact foot reaches when these two individual parts have been put together. In the connection to the current bar, the second contact leg—which is united with the clamping element in this variant—is under an initial tension as a result of the spring force of the clamping element that is exerted on the edge of the recess or opening facing the clamping element. The free end of the leg of the clamping element is inserted in the same current bar opening as the free end of the (first) contact leg of the contact foot.

Whereas, in the one-piece variant, the spring effect that is required for the resilient clamp connection is achieved by the two contact legs being moved in the direction of one another and contacted with the current bar during the assembling process, in the two-piece variant, the end of the clamping element near the current bar only is led in the direction of the rigid contact foot, i.e., the first contact leg. To that end, in accordance with a further feature of the invention, the, an abutment is provided at the contact foot in the form of a camber that is directed toward the clamping element. This configuration forms a bending edge for the clamping element during the compressing of the two contact legs for purposes of generating the initial tension required in the clamp connection to the current bar.

Instead of the fixing or receiving opening in the current bar for guaranteeing reliable contacting of the contact foot to the current bar, this can also have collar-type contours that, then, form the corresponding installation surfaces for the free ends of the contact legs. For a catch connection, recesses or fixing openings are, expediently, provided in the current bar, which openings are engaged on the top side of the current bar, which is averted from the contact foot, in the region of their edges by catch elements that are formed on the free ends of the contact legs. In the current bar contacting mechanism, by a catch, one contact opening (catch opening) can be provided for each contact leg, or one opening can be provided for both legs.

In either variant, the clamping element is at least partially arc-shaped or semicircular for purposes of fixing or holding the contact foot at the bearing bar with secure contact. Such a shape makes possible a reliable reach-around at the edge of the bearing bar with sufficient spring force. The arc-shaped or semicircular shape forms a clamping leg with a large clamping power at the free end of the clamping element on the bearing bar side.

With the objects of the invention in view, there is also provided a connection system, including a current bar, a contact foot, a clamping element, a bearing bar having a bearing bar edge, the clamping element extending behind the bearing bar edge and removably fixing the contact foot at the bearing bar, and the contact foot and the clamping element forming a resilient clamp removably contacting the contact foot to the current bar.

With the objects of the invention in view, the connection system is a component of a protective conductor terminal or ground conductor terminal. The connection system is inserted in the isolating housing of the protective conductor terminal and positioned there. Internally, the current bar is conductively connected to connection devices in the form of spring clamps or what are referred to as cage tension springs for the clamp contacting of ground conductors or protective conductors. For the clamp contacting, the protective conductor terminal is snapped onto the bearing bar, usually together with other series mounted devices, particularly for the phase conductors of a three-conductor or four-conductor network.

The advantages of the invention lie specifically in the ability to assemble the individual parts of the connection system easily by virtue of a resilient connection in the form of a plug, clamp, or catch connection between a current bar and a contact foot of a connection system, with or without a separate clamping or spring element. In addition, with few individual parts, a particularly high level of pre-production can be achieved for the connection system, and with it a protective conductor terminal. By developing the individual parts as plug elements, a modular connection system, particularly, for ground conductor terminals, is provided according to a unit assembly system, with which a number of different instances can be realized.

Although the invention is illustrated and described herein as embodied in a connection system, it is, nevertheless, not intended to be limited to the details shown because various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the figures of the drawings, unless stated otherwise, identical reference symbols denote identical parts.

Referring now to the figures of the drawings in detail and first, particularly toFIGS. 1to3thereof, there is shown, a first two-part embodiment—previously referred to as the second variant—of the inventive connection system1. A contact foot or attachment foot2and a clamping element3are disposed between a current bar4and a bearing bar6as separate parts. The top half of the contact foot2, which is the side nearer the current bar, is constructed as a contact leg8, whereas the second half, the side near the bearing bar, forms a contact nose10. The contact foot2is a one-piece component, preferably, a punched part.

The clamping element3, which is produced from a bent or rolled sheet part, is disposed at the contact foot2. The top half of the clamping element3, the side near the current bar, likewise, serves as contact leg12, which is adapted to the shape and curve of the contact or attachment foot2. In the bottom region on the bearing bar side, the clamping element3includes an arc-shaped or U-shaped clamping leg15, whereby a clamp opening14is formed, which leg, in joining with the bearing bar6, reaches around, and makes clamping contact with, the edge6aof the bearing bar6and the contact nose10, which abuts said edge, of the contact foot2.

The clamping element3has a holding opening16aand a positioning opening16b, in the form of rectangular through-opening or recesses on the current bar side and bearing bar side. Corresponding holding noses18aand18bthat are formed at the contact foot2reach through these holding openings16aand16b, respectively, so that the clamping element3is positioned and fixed in place in the assembled condition.

An expediently rectangular fixing or clamping opening20is located in the current bar4. On the free end, which faces the current bar6, of the contact leg8of the contact foot2, a fixing nose22ais formed, which is inserted into the clamping opening20together with a clamping nose24that is realized on the free end of the contact leg12of the clamping element3. To insert the two contact legs8and12into the clamping opening20, the contact leg12and, with it, the clamping nose24, are pressed in a bending direction parallel to the bearing bar6and the current bar4.

The bending, which generates initial spring tension, occurs around a bending edge25, which is formed by a camber27that is formed on the contact foot2in the region of the leg8thereof. The camber27, which is raised in the direction of the clamping element3, thus, serves as an abutment or an abutment cam for the clamping element3for purposes of prestressing it when the contact leg8of the contact foot2and the contact leg12of the clamping element3are pressed together. This prestressing of the clamping element3guarantees a reliable resilient clamp or catch connection and, thus, a reliable contacting of the contact foot2to the current bar4. The spring deflection of the clamping nose24, and, thus, of the contact leg12of the clamping element3, which deflection the resilient clamping element3requires for correction, is blocked by the edge of the fixing or clamping opening20, which acts as a stop.

For fixing the contact foot2to the bearing bar6, the U-shaped clamping leg15of the clamping element3forms a clamping arm28, which is located on the bottom side of the bearing bar6, the side averted from the contact nose10. By swinging out during the insertion of the bearing bar edge6ainto the clamping element opening14, the clamping arm28exerts a clamping pressure on the bearing bar edge6ain the clamping pressure direction30. To guarantee easy insertion of the bearing bar edge6ainto the clamping element opening14, an incline32that runs opposite the clamping pressure direction30is formed on the clamping arm28at the free end thereof.

FIG. 2represents, relatively clearly, the shapes and configurations of the contact foot2and the clamping element12in the two-part variant. The clamp contacting of the contact foot2at the bearing bar6by the separate clamping element3occurs only at one of the two bearing bar edges6aor6b, which is advantageous particularly in view of the small material requirement.

FIG. 3is a detail representation of the clamp connection between the current bar4and the two clamp or contact legs8and12of the contact foot2and the clamping element3in perspective. A cushion-type inwardly bulging edge of the fixing or clamping opening20is evident. This achieves a precise positioning of the free ends of the legs in the form of the fixing nose22aof the contact foot2and the clamping nose24of the clamping element3, which reach through the clamping opening20in the clamp connection. In addition, the two clamp legs8,12are led close to one another in the direction of pressure34, forming only a small clamp gap35, whereby the approximately linear contact leg12of the clamping element3is pressed to the contact foot2.

Due to the camber27acting as an abutment cam, a certain amount of pressure is required to be able to insert the fixing nose22aand the clamping nose24into the fixing opening20. The clamping nose24exerts a clamping pressure on the fixing opening20by way of the spring pressure that is directed against the direction of pressure34. This resilient clamp contact can be unmade by moving the contact leg3further in pressure direction34, whereby the width d of the clamping gap35is reduced, and the clamping between the contact foot2, the clamp element12, and the current bar4is released.

In the one-part embodiment of the connection system1, which is represented inFIGS. 4to6(previously referred to as the first variant), the contact foot2′ and the clamping element3′ are a one-piece or united molded part. In this variant, the clamping element3′ is formed on the contact foot2′ in the region of the contact nose10. This unified contact-clamp element is a punched profile part, preferably, a metallic punched profile part being at least partly of a copper special alloy. In contrast to the variants according toFIGS. 1to3, in this variant, both the first contact leg8′ and the second contact leg12′ are formed on the contact2′. The two contact legs8′,12′ extend substantially parallel to one another in the clamp connection shown inFIGS. 4 and 6, whereas, the contact legs8′ and12′ form an approximate V shape in the initial condition according to FIG.5. Each of the fixing noses22band22cthat are formed on the first contact leg8′ and the second contact leg12′ reaches through a respective fixing opening20aor20bin the current bar4.

The clamping element3′ that is formed on the contact foot2′, in turn, forms an arc-shaped or U-shaped clamping leg15, which, likewise, has an inclination32′ on the free end for inserting the bearing bar edge6a. The clamping element3′, in turn, exerts a clamping force in the clamping direction30upon the bearing bar edge6a, which, analogously to the variant according toFIGS. 1to3, also lies between the contact nose10of the contact foot2′ and the clamping arm28′ of the clamping element3′ in the clamp or catch connection, with the effect that an isolating housing, which accepts the connection system1, of a protective conductor terminal (not represented in detail) is held on or at the bearing bar6in a reliable but detachable fashion. For this reason, the clamping element3′ exhibits the requisite resilient characteristics based on its arch-shape.

FIG. 5represents an insertion gap38between the free end of the clamping arm28′ of the clamping element3′ and the contact nose10of the contact foot2′, whereby, this insertion gap38is smaller than the profile thickness of the bearing bar edge6a. With the insertion or pushing of the bearing bar edge6aalong the inclination32′ into the gap38, the gap38is enlarged or widened under the initial tension of the clamping element3′. In turn, the clamping arm28exerts the requisite holding or fixing pressure on the bearing bar edge6ain clamping pressure direction30based on its resilience. The contact nose10of the contact foot2′ serves as abutment therein.

FIG. 6represents a detail view of the resilient clamp connection that is formed in this variant between the two contact legs8′,12′ of the contact foot2′ and the current bar4. The clamp contact is achieved by way of the two fixing noses22band22cthat are formed at the contact legs8′,12′. For purposes of penetrating the two fixing openings20aand20b, the two contact legs8′,12′, which form a V in their resting position, are moved toward one another with their fixing noses22band22c, whereby, the two fixing noses22band22care pressed in bending directions40and42, respectively. The pressure of the two contact legs8′ and12′ to correct themselves against their respective bending directions40and42gives rise to the resilient clamp contact between the contact foot2′ and the current bar4. In the clamp connection, the two contact legs8′ and2′ are parallel to one another.

Such a resilient clamp contact can also be unmade by moving the two contact legs8′ or12′ in their respective bending directions40,42until the contact between the fixing noses22b,22cand the corresponding fixing openings20aand20bis lost. The two contact legs8′ and12′ can, then, be withdrawn from the corresponding fixing openings20aand20b, whereby the clamping between the contact foot2′ and the current bar4is released.