The invention relates to an electrical connection terminal between two conducting elements.
The invention also relates to a connection module for an electrical contactor including a terminal of this type. Electrical contactors are used in motor starter sets to control industrial electric motors, such as asynchronous motors. An electrical set of this type typically comprises a contactor to interrupt selectively the supply of the electric charge in response to a control signal.
The connection module includes a plurality of power conductors, in particular one conductor for each phase of the electric current. Each of the power conductors is intended to be connected, on the one hand, to a matching power conductor of the contactor and, on the other hand, to an external electrical cable. The connection between the power conductors and the electrical cables is established by means of the electrical connection terminal of the module.
The connection module is advantageously equipped with integrated measurement means, including, for example, a Rogowski sensor to measure the intensity of the electric current. These measurements are used in practice to guide an automatic control of the contactor. This type of sensor imposes a particular power conductor geometry, the shape of which is not suitable for implementing an electrical connection with a conventional clamping terminal of the type disclosed, in particular, in EP-A-0 148 056. In fact, there may be a significant cross-sectional difference between the power conductor and the electrical cable, so that it is difficult to position the cable in contact with the conductor during the clamping. The electrical connection is then not, or at least not very well, established.
As an alternative to clamping terminals, terminals known as lift cage terminals exist, as described, for example, in FR-A-2 740 265. In this document, the terminal includes a casing defining three chambers, each corresponding to an electric pole. Each of the chambers includes a connector for the electrical connection of the cables. Each connector includes a cage and a slide clamp, translationally movable, one towards the other, during the tightening of a screw. The slide is disposed inside the cage and a fixed conducting wall divides the cage into two. However this type of lift cage terminal cannot be used for reasons of compactness.
The invention aims more particularly to overcome these disadvantages by proposing a compact electrical connection terminal providing a satisfactory electrical connection regardless of the geometry and cross section of the power conductor to be connected.
For this purpose, the invention relates to an electrical connection terminal between two conducting elements, this terminal including:
By means of the invention, the tightening of the screw causes the tightening of the first conducting element between the clamp and the connector and the tightening of the second conducting element between the two levels of the connector. The second conducting element is then pinched between the two levels of the connector, thereby establishing a reliable electrical connection between the connector and the second conducting element. The connector has a shape suitable for an electrical connection to a cable, in this case the first conducting element, so that the first conducting element and the second conducting element can be connected by means of a screw-clamp assembly.
According to advantageous but not obligatory aspects of the invention, an electrical connection terminal of this type may incorporate one or more of the following characteristics, taken in any technically admissible combination:
The invention also relates to a connection module for an electrical contactor, this module including a connection terminal as previously described.
The invention finally relates to a set including an electrical contactor and a connection module as previously described.
The invention and its other advantages will become clearer in the light of the description that follows of an embodiment of an electrical connection terminal according to its principle, given only by way of example and described with reference to the attached drawings, in which:
The module 2 advantageously includes integrated measurement means (not shown) to measure one or more electrical parameters, such as the voltage or intensity of the electric current. In the example, these means include a Rogowski sensor. The measurements are used in practice to guide an automatic control of the contactor (not shown).
The conductor 4.3 is shown alone in
The connection model 2 includes an electrical connection terminal 20 to connect each of the first conducting elements 4.1, 4.2 and 4.3 respectively to a second conducting element 12.1, 12.2 or 12.3. In the example, each of the second conducting elements 12.1, 12.2 and 12.3 is a cable with a circular cross section.
The connection terminal 20 includes three compartments, 20.1, 20.2 and 20.3 respectively. Each of the compartments 20.1, 20.2 and 20.3 of the electrical connection terminal 20 includes a clamping screw 6, a clamp 8 and a connector 10.
As shown in
The clamp 8 is mounted around the screw 6, particularly in the area of the part 66, and includes two wings 8a and 8b which extend on either side of the screw 6 in a direction which is inclined in relation to the axis X6 of the screw 6. The clamp 8 is translationally fixed along the screw 6. Conversely, it is mounted with a radial clearance around the screw 6, in such a way as to be able to tilt on one side or the other. This advantageously allows cables having different cross sections to be clamped on either side of the screw 6 without the cable which has a smaller cross section being less tightly clamped.
The connector 10 is made from an electrically conducting material. It is disposed at one end of the screw 6 opposite the screw head 62. It includes a first level 10a, delimiting a reception tapping 102 for the clamping screw 6. The tapping 102 is centred on an axis combined with the axis X6 and has a screw thread matching that of the tapping 60 of the screw. The connector 10 also includes a second level 10b which is disposed between the first level 10a and the clamp 8. The second level 10b includes a passage hole 100 for the screw 6 which is aligned with the thread 102 following the axis X6. The hole 100 has a wider diameter than that of the screw 6. The first level 10a is movable in relation to the second level 10b in a direction parallel to the axis of the screw X6 under the effect of the tightening of the screw 6.
The two levels 10a and 10b of the connector 10 are advantageously parallel and perpendicular to the axis of the screw X6.
The clamp 8 and the second level 10b of the connector 10 define between them at least one, preferably two, housings 24, each configured for a first conducting element, from the cables 12.1, 12.2 and 12.3. The housings 24 are defined respectively between the wings 8a and 8b of the clamp and the second level 10b of the connector 10. In the example, only one of the two housings receives a cable. However, even if this configuration is not shown in the figures, each compartment of the terminal 20 allows a minimum of two cables to be connected, on either side of the screw 6, with the corresponding first conducting element, from the elements 4.1, 4.2 and 4.3.
As shown in
The two levels 10a and 10b of the connector 10 are advantageously contiguous. In particular, the connector 10 is C-shaped, the two levels 10a and 10b of the connector 10 then forming the parallel arms of the C.
In the example, the connection terminal 20 includes a seat 28 on which the connector 10 rests. This seat 28 is configured to prevent the movement of the first level 10a in an axial direction opposite to the second level 10b during the tightening of the screw 6.
As shown in
In each compartment, the screw 6 passes through the conducting element 4.1, 4.2 and 4.3. Thus, as shown in
In order to establish an electrical connection between two conducting elements, for example between the conducting elements 12.2 and 4.2, it is expedient to position the conducting element 12.2 between the clamp 8 and the connector 10 on one side or the other of the screw 6, then to tighten the screw 6. The tightening of the screw 6 causes the movement of the first level 10a of the connector 10 towards the second level 10b. The level 10a detaches from the seat 28 and the conducting element 4.2 is pinched between the two levels 10a and 10b of the connector 10, thereby providing a reliable electrical connection between the conductor 4.2 and the connector 10. In parallel, the clamp 8 moves axially towards the connector 10, thereby clamping the conducting element 12.2 between the clamp 8 and the connector 10.
When the screw 6 is loosened, for example to remove the cable, the first level 10a abuts against the seat 28 and the screw 6 slides across the level 10a.
In one variant (not shown), the electrical connection terminal 20 is completely independent, i.e. does not form an integral part of a connection module for a contactor.
According to a different variant (not shown), the connection terminal 20 includes a number of compartments other than three. In particular, the connection terminal 20 may include a single compartment or only two compartments.
According to a different variant (not shown), the housing 106 of each connector 10 may be configured to receive a plurality of conducting elements.
According to a different variant (not shown), the levels 10a and 10b of the connector 10 are separate. The level 10b is then translationally immobilised according to the axis X6, for example fixed to the terminal 20.
The characteristics of the embodiment and the different variants envisaged above can be combined with one another in order to generate new embodiments of the invention.
Number | Date | Country | Kind |
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16 62232 | Dec 2016 | FR | national |