The invention relates to a connecting terminal comprising a housing comprising a conductor inlet opening configured to receive a conductor to be clamped, the housing comprising a conductor clamping region extending from the conductor inlet opening in an insertion direction of the conductor to be clamped; a current rail disposed in the housing and forming at least a first boundary of the conductor clamping region; and a spring clamp disposed in the housing and configured to exert a clamping force towards the first boundary of the conductor clamping region.
A connecting terminal designed in the way described above serves to clamp a conductor to a current rail by means of a spring clamp in order to produce an electrical connection. When inserting the conductor to be clamped into the conductor inlet opening, the tip of the conductor reaches the clamping region which is bounded by the current rail. It is then pushed between the spring clamp and the current rail and is fixated to the current rail by means of the spring force. Often, the spring clamp is configured in the form of a barbed hook so that the conductor cannot be pulled out easily.
A connecting terminal of the kind described above is known in the prior art. Often, the conductor clamping region is further bounded by a wall of the housing which is extends from the conductor inlet so it covers the side of the clamping region. This extension serves as a guide for both the conductor and the spring clamp during their respective movement.
However, known designs suffer from disadvantages: First, if the spring clamp twists in operation there is a chance that it will “bite” into the plastic surface of the extension and damage it. Because of this damage, the spring operation in subsequent inserting and extracting operations may get obstructed. Second, and even worse, when a maximum size conductor is inserted in the conductor inlet, the spring is deflected to its extreme position. In this position there is a chance that the spring reaches a position in which it was inserted and thus may come out of the plastic body as there is no restriction available in the lateral direction.
The problem the invention wants to solve is therefore to provide a connecting terminal of the kind described above which provides a more reliable operation over an extended period of time, in particular with maximum size conductors.
This problem is inventively solved by the current rail comprising a first extension forming a second boundary of the conductor clamping region.
The invention is based on the idea that the problem of the spring clamp leaving its position when a maximum size conductor is inserted is caused by the specific way of assembling the terminal connector: In the prior art, the spring clamp is fitted inside the plastic housing by compressing it and then inserting it through an opening in the side of the plastic housing which has the same contour as the compressed spring clamp. After the spring clamp is inserted, it is then released inside the plastic body and expands towards the clamping region. However, as indicated above, if a maximum sized conductor is inserted into the terminal, the spring may be compressed into its original inserting position and fall out through the still existing opening. To prevent this, the opening through which the spring is inserted should be closed. However, this should by done without complicating the assembly process. The inventors have recognized that this is possible by modifying the current rail which is also inserted into the plastic housing. The current rail comprises an extension that also bounds the conductor clamping region. Since the current rail is inserted afterwards, its extension can seal the opening through which the spring clamp was inserted.
In addition, the extension of the current rail also solves the second problem mentioned above: The “biting” of the spring clamp into the housing is mainly caused because the housing is made of plastic and plastic is a softer surface material than the spring material. Since the extension of the current rail now serves as a guide for the spring clamp and is made of a harder material, the spring clamp cannot damage its surface.
Advantageously, the first boundary of the conductor clamping region which comprises the current rail plane is perpendicular to the second boundary created by the extension. In other words: The extension extends perpendicularly from the current rail plane. In this way, the extension can serve perfectly as a guide for the spring because it extends in the direction of the spring clamp movement.
Furthermore, the housing advantageously comprises a first wall forming a third boundary of the conductor clamping region, wherein the first and third boundaries are located on opposite sides of the conductor clamping region. The spring clamp movement is therefore guided on one side by the extension of the current rail, and on the other side by the wall of the housing.
Advantageously, the first extension of the current rail is configured to limit a movement of the spring clamp in a direction perpendicular to the direction of the clamping force. In particular, this means that it is located such that it indeed guides the movement of the spring clamp, i.e. adjacent to at least the tip of the spring clamp, and is dimensioned such that it remains in close contact with at least the tip of the spring clamp even if the spring clamp is compressed by insertion of a conductor.
Furthermore, the current rail is advantageously L-shaped in the vicinity of the conductor clamping region. In other words, it is configured as a band that bends around the conductor clamping region in a 90° angle. This does not exclude that the current rail does have other forms further away from the conductor clamping region.
In a first advantageous embodiment, the first extension of the current rail forms a cantilever located adjacent to a first end of the spring clamp. This means that the extension is configured in the style of a small bar that extends over the spring clamp tip and guides its movement there.
Furthermore, in an embodiment with an L-shaped current rail, advantageously the first extension extends from a first leg of the L-shaped current rail and additionally, the current rail advantageously comprises a second extension extending from a second leg of the L-shaped current rail and forming a cantilever located adjacent to a second end of the spring clamp. Thus, there are two extensions of the current rail, one at each leg of the L-shaped current rail, each of them guiding and holding one tip of the spring clamp. That way, both ends of the spring clamp are fixated after insertion of the current rail into the housing.
Furthermore the housing comprises a second wall extending the second boundary of the conductor clamping region, i.e. of the boundary defined by the extension. In other words, the second wall forms a plastic surface which also guides the spring clamp. The extension of the current rail and the plastic surface lie in the same plane so that they together form a spring guiding surface.
In a second, alternative advantageous embodiment, the first extension forms a bridge connecting the first leg and the second leg of the L-shaped current rail. This way, there is no need for an additional housing surface to guide the spring clamp. The bridge connecting both legs of the L-shaped current rail may be configured broad enough to guide the spring clamp over its entire movement range.
In order to allow the abovementioned assembly of the connecting terminal, the housing comprises a spring clamp insertion opening which extends along the entire contour of the spring clamp when no conductor is clamped in the conductor clamping region. The opening is located in the plane of the first extension and therefore, when the current rail is not yet inserted into the housing, the spring clamp can be inserted. After the spring clamp is inserted into the housing, the current rail is inserted.
The first extension then advantageously covers at least part of the spring clamp insertion opening such that the inserted spring clamp is securely guided and secured inside the housing.
In an advantageous embodiment the housing is made of a plastic material. It can be produced in large quantities e.g. by casting, injection molding or by 3D-printing. The housing advantageously forms a one-piece arrangement with all abovementioned parts of it.
The spring clamp and/or the current rail are advantageously made of a metallic material. The current rail is designed to carry electric current.
Advantageously, a method of manufacturing the connecting terminal described above comprises the steps of providing the housing; inserting the spring clamp through the spring clamp insertion opening; installing the current rail such that the first extension limits a movement of the spring clamp in a direction perpendicular to the direction of the clamping force.
A computer-readable file advantageously comprises instructions which, when loaded by a computer, cause a 3D-printer under the control of the computer to print a housing suitable for the described connecting terminal. This means that the housing comprises the features described above as being part of the housing. A corresponding file comprises a 3D model of the housing and can for example be provided for download on the internet. A such file may for example be a STL (Standard Triangulation Language) file and may be loaded into a Computer Aided Design software.
The advantages achieved by the present invention are in particular that by replacing a part of the plastic housing which partly bounds the conductor clamping region by an extension of the current rail in order to guide the movement of the spring clamp in the connection terminal, the spring clamp can be securely fastened and guided, and can cause no damages in the interior of the housing which would hamper movement of the spring clamp.
Furthermore, the metal extension of the current carrying element helps in making a secondary contact of the conductor with the current rail which is in addition to the lateral connection area that is available in the design. Thus, the electrical connection is also improved.
Exemplary embodiments of the invention are described in the following in relation to figures, in which
The current rail 3 is formed from a narrow metal band and bent in the shape of an L. In its state when inserted into the housing 1, as shown in
The spring clamp 4 is designed in the form of a leg spring with a retention leg 20 and a clamping member 6. The spring clamp 4 is pushed open onto a retention element 7 formed in the housing 1, which retention element 7 is formed integrally with the housing 1. In order to slide the spring clamp 4 onto the retention element 7, the spring clamp 4 is also inserted into the housing 1 via the side opening 21.
In the housing 1 itself, a conductor inlet opening 8 is formed, via which a conductor 9 to be clamped, as shown in
Furthermore, the connecting terminal A has a spring guiding surface on its front side in
The spring guiding surface comprising the metal extension 27 and the front plastic surface 10 is formed such that it laterally borders, in the direction of the side opening 21 in the housing 1, the conductor clamping region formed between the clamping member 6 and the current rail 3. The clamping member 6 of the spring clamp 4 and the lateral face 13 of the current rail 3, to which the conductor 9 is clamped, are located opposite one another such that the spring guiding surface is arranged off-centre between the clamping member 6 of the spring clamp 4 and the current rail 3. As can be seen in
Furthermore, the spring guiding surface comprising the metal extension 27 and the front plastic surface 10 acts as a retainer for the spring clamp 4 since the spring clamp 4 is prevented from sliding forwards from the retention element 7. For the first few millimeters of spring displacement when the conductor 9 is inserted, this is achieved by the metal extension 27 since the clamping member 6 of the spring clamp 4 is arranged behind the metal extension 27 and can be activated there by means of the conductor 9 or a release tool, for example a trigger 12. Thus, if the clamping member 6 twists on insertion of the conductor 9, it will be first guided and restricted by the metal extension 27 of the current rail 3. It gets further support from the cantilevered front plastic surface 10. However, the main guiding force comes from the metal extension 27. Due to this, even if the spring clamp 4 twists, it cannot “bite” into the front plastic surface 10 as the metal extension 27 will restrict it. Hence, no structural damage can happen to the front plastic surface 10, thereby ensuring smooth subsequent spring actions.
The front plastic surface 10 is formed at a distance from the interior wall 5 of the housing 1, such that a clearance or gap 22 is formed between the longitudinal side 14 of the front plastic surface 10, which side points towards the interior wall 5 of the housing 1, and the interior wall 5 of the housing 1 in the clamping direction of the clamping member 6 of the spring clamp, as well as a clearance or gap 23 between the lower side 15 of the front plastic surface 10 and the interior wall 5, formed as the floor surface, of the housing 1 in the conductor insertion direction. The current rail 3 can be inserted into the housing 1 via the gap 22 and the gap 23 between the conductor guide 10 and the interior wall 5 of the housing 1.
In its inserted state, the current rail 3 is fastened to the housing 1 by a latching mechanism (not shown). The current rail 3 also has a second metal extension 28 located on the lower leg of the L-shaped current rail 3. It is formed just as the first metal extension 27, i.e. as a perpendicular cantilever extending from the current rail in the plane of the spring guiding surface. However, the second metal extension is located adjacent to the tip of the retention leg 20 such that it prevents a side movement of the retention leg 20. From
In the housing 1, adjacent to the front plastic surface 10, a spring limiting element 18 is formed, which is integrally moulded with the housing 1. The spring limiting element 18 limits the maximum deflection of the clamping member 6 of the spring clamp 4 (see spring clamp position in
Referring to
In the following, the embodiment of
As can be seen in
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/IN2019/050049 | 1/22/2019 | WO | 00 |