FR3017494A1 - TETRAPOLAR CONNECTOR WITH COMMON CLAMP FOR NEUTRAL CABLE DISTRIBUTED - Google Patents

Abstract

The present invention relates to a four-pole connector comprising: - a common clamping through all the elements; - two outdoor trays; - two electrically-connected connection elements separated from each other and each connecting a main conductor with one or more branch conductors; - two insulating central elements intersecting with each other and both traversed by the common clamping element; and - a clamping on a convex range allowing an inclination of the outer plates as a function of the differences in section of the main conductors. It also relates to a method of mounting and connecting such a four-pole connector.

Description

The present invention relates to a four-pole connector comprising: a common clamping element passing through all the elements; - two outdoor trays; - two electrically-connected connection elements separated from each other and each connecting a main conductor with one or more branch conductors; - two insulating central elements intersecting with each other and both traversed by the common clamping element; and - a clamping on a convex range allowing an inclination of the outer plates as a function of the differences in section of the main conductors.

It also relates to a method of mounting and connecting such a four-pole connector. State of the art In the distribution networks of electrical energy, the final distribution is in a so-called "low voltage" form, generally between 110V and 600V, very often buried. Most often, this low voltage is distributed in a three-phase form, and often with neutral distributed as is the case in France. The cables provided for three-phase and neutral thus comprise four conductors, including three phase conductors and a neutral conductor. These conductors comprise a conductive metal core coated with an insulating plastic sheath, or possibly lead for the neutral conductor. The assembly formed by the four conductors is surrounded by a shielding screen and then by an outer envelope of insulating plastic material. The conductors themselves have fairly large sections, which can vary for example from 50mm2 to 240mm2. Particularly for large sections, the phase conductors generally have a quarter-disc-shaped profile for reasons of space. The neutral conductor is generally of smaller section than the phase conductors and has a round profile. To make branch connections on these cables, a so-called four-pole connector is used, which phase-to-phase connects each conductor of a so-called main cable with one of the conductors of a branch cable, often of smaller cross-section and with round profiles. Such connectors generally operate by bringing branch conductors along the main conductors. They are connected together by perforation of the main cable as well as the derived cable or cables via combs made of conductive material teeth. Thus, it is not necessary to cut the main conductors, the connections are simplified and can be powered. Different architectures exist for such a four-pole branch connector. Some, as in EP 1 513 226, have pivoting jaws which surround the main cable and receive the bypass leads from the outside. Others comprise several elements stacked in the same direction and are then clamped together, by several screwing means as in FR2901415 or by one as in GB1260902. An object of the invention is to overcome the disadvantages of the state of the art. It aims in particular to increase the possibilities offered by such a four-pole connector, its flexibility and ease of use, while maintaining or improving the simplicity, robustness, compactness and / or the cost of such a device. DESCRIPTION OF THE INVENTION The invention proposes a four-pole electrical connection device 30 for connecting a main electrical cable comprising four so-called main conductors with at least one electrical branch cable comprising four so-called shunt conductors. This device is of the type comprising: - 3 - an insulating central element said horizontal having two opposite faces, which is inserted between two pairs of two main conductors, and which receives said main conductors in four locations electrically isolated from each other and carried by said opposite faces, and - two outer plates arranged vis-à-vis each of said opposite faces of the horizontal central element, each of said outer plates having a so-called inner face directed towards said horizontal central element and receiving at least one pair two branch conductors in two isolated bypass locations. More specifically, each pair of branch conductors is separated from the pair of main conductors to which it is connected by a connecting element comprising two conductive contact elements insulated from each other and each making an electrical contact between a conductor main and a bypass conductor, typically by contact by means of two conductive penetration surfaces. In addition, in this device, the maintenance of the assembly and the electrical contacts is obtained under the effect of a clamping exerted between said outer plates by the same elongated clamping element. This clamping element passes through both said outer plates, said connecting elements and said horizontal central element, passing between the two conductors of each of the two pairs of main conductors and between the two conductors of each of the two pairs of branch conductors. .

This clamping element typically comprises a single rod or a single axis and which is tensioned in different ways, by approaching its ends for example by a screw-nut type system or by a cam mechanism or clamping ramps . Preferably this element is actuated by a single maneuver and / or comprises a single cooperation producing the approximation. Although the entire assembly is tightened by the same clamping element, the invention optionally provides the use of several copies, for example arranged parallel to each other at several locations along the longitudinal axis of the main cable. According to the invention, this device is characterized in that the device further comprises another vertical insulating central element, inserted between the conductors of the main cable, transversely to the horizontal central element, so as to separate the conductors. from each other within each of the main lead pairs. According to the invention, one (2) of said horizontal and vertical central elements (preferably the second) has an opening allowing it to be traversed by the other once in place between the main conductors. invention, one or both outer trays receive the clamping or tightening elements on a convex range to achieve a tightening in several positions of different inclinations, around the longitudinal axis of the main cable, from to at least one of said outer plates with respect to the axis of the clamping element, and through an opening having an angular clearance around said clamping element. The connector according to the invention can thus adapt to different sizes of main conductors without compromising the distribution of the clamping between them and the quality of the electrical connection. Such a connector is adapted to the conductors of the main cable with an internal swivel, which avoids or limits the need to insert specific shims dedicated to each main cable configuration. Indeed, the outer plates allow angular movement around the longitudinal axis of the main cable, to make up the difference in section of one of its conductors, typically the neutral conductor. It is thus possible to ensure equivalent clamping on the four main cable conductors, while minimizing specific parts and additions of additional parts that may present risks of loosening or poor quality of contact. It should be noted that the names "vertical" and "horizontal" are here arbitrarily defined, considering that the outer plates are horizontal and that the clamping is done along a vertical axis. This definition does not prejudge in any way the positioning position of such a connector on the field. Nor does it mean that the "vertical" element and the "horizontal" element are exactly perpendicular to each other, since they do not form a zero angle. Such an angle can be for example at least 45 ° or more than 60 °.

Preferably, one or the other of the central insulating elements, or both, has a generally flattened shape, the two largest faces bear against the main conductors that it separates. Such a flattened general shape may be defined as having, in its outer dimensions, a dimension which is small vis-à-vis the other two, for example at least a factor of three, which will be called "thickness". This flattened shape allows inter alia good position stability between the main conductors and limits the bulk.

According to another aspect, the invention proposes a method of electrical connection between a four-pole cable and one or more shunt cables, preferably using a four-pole connector as described herein, and comprising the following steps: - insertion a vertical insulating central element between two pairs of main conductors, so as to achieve a physical separation of said pairs. Preferably, this vertical central element has a small thickness between two opposite faces, which each bear against one of these main pairs; inserting a horizontal central element between the two conductors of each of said pairs of main conductors, passing through an opening carried by said vertical insulating central element, so as to achieve a physical separation of said conductors within each of said pairs; - assembling, around the main cable and on each side of the first central insulating element, an outer plate provided for clamping a pair of branch conductors and a pair of conductors against said first central; - tightening the assembly by screwing at least one screw-nut clamping element which passes through both said outer plates, said connecting elements and said first central element, passing between the two conductors of each of the two pairs of main conductors and between the two conductors of each of the two pairs of branch conductors Various embodiments of the invention are provided, integrating, according to all of their possible combinations, the various optional features disclosed herein.

List of Figures Other features and advantages of the invention will become apparent from the detailed description of a non-limiting embodiment, and the accompanying drawings in which: FIGURE 1 to FIGURE 8 illustrate the introduction and the assembly of a four-pole connector, in a first exemplary embodiment of the invention; FIGURE 9 to FIGURE 11 illustrate the introduction and assembly of a four-pole connector in a second exemplary embodiment of the invention.

DESCRIPTION OF AN EXAMPLE EMBODIMENT FIG. 1 illustrates the insertion of the vertical insulating central element 2 between two pairs 9c and 9d of main conductors, once these are stripped of the common protection of the main cable 9.

FIG. 2 illustrates the insertion of the horizontal insulating central element between the two complementary pairs 9a and 9b of main conductors and through the vertical central element 2. FIG. 3 illustrates in more detail the insertion, according to the direction D1 and in the absence of the main cable 9, the horizontal shim 1 in the housing 21 of the vertical shim 1. According to a feature of the invention, that of the horizontal central elements 1 and vertical 2 which passes through the other, here the horizontal wedge 1, has a shape abutting on the other in its assembled position, here the extra thickness El abutting on one side of the vertical wedge. It is held in this position by at least one resilient part making a clipping, here the elastic tongue 19 locking on the other side of the vertical block 2. The interlocking of the two shims 1 and 2 allows to center the l assembly of the connector relative to the main cable 9. The vertical central element 2 comprises at least one through opening 211, 212 one per clamping member of the outer plates 4, 6, which receives this element 71, 72 clamping, so holding it in position before clamping and keeping it away from the main conductors 91, 92, 93, 94 and optionally bypass, thereby providing insulation between the conductors and the metal of the clamping screws. The horizontal central element 1 has a plurality of housings 111, 112 receiving the clamping elements of the outer plates thereby maintaining the interlocking assembly of said horizontal central elements 1 and vertical 2. As can be seen in the figures, the vertical central element 2 has, in the plane of its generally flattened shape, a through opening which forms a housing 21 accommodating the horizontal central element 1.

Alternatively and unlike the present example, the horizontal central element could carry a housing in which would be inserted the central vertical element. According to the invention, the vertical central element has, for each clamping element 71, 72, at least one cylindrical bore 211, 212 through, embedded in its thickness and with an axis parallel to the driving direction D2 of said central element. vertical, and which crosses said housing 21 receiving the horizontal central element. This vertical central element here is a shim 2 having a rectangular parallelepiped medial portion, which includes the housings 211 and 212 of the clamping screws 71 and 72. This middle portion extends in the direction of insertion D2 and in both meaning, in two pillars extending the two outer edges of the parallelepiped. According to one particularity of the invention, one or the other of the two horizontal insulating central elements 1 and 2, or both, has, in its direction D1, D2 of insertion between the main conductors, a increasing thickness profile producing a wedge effect allowing it to separate the main conductors from one another when inserted into the main cable between said main conductors.

In this embodiment, the vertical shim 2 is generally flattened and has a greater thickness E2 in its central portion than in its ends, symmetrically around its median main plane. The horizontal wedge 1 has a thickness El increasing from its foremost end towards its rear end with respect to its direction of insertion Dl. This thickness variation is located only towards one 101 of its main faces. It helps to separate the main conductors from the pairs 9a and 9b, and partially offsets the lower thickness of the main neutral conductor 94.

FIG. 4 is a cross sectional view of the main cable, illustrating the two central insulating elements 1 and 2 when assembled between the main conductors 91 to 94. As can be seen, the vertical wedge 2 is supported by one 202 of its main faces on the phase conductors 91 and 92 forming the pair 9d, and the other 201 of its main faces on the phase conductor 93 and the neutral conductor 94 forming the pair 9c. The horizontal shim 1 is supported by one of its main faces 102 on the phase conductors 92 and 93 forming the pair 9b, and the other 101 of its main faces on the phase conductor 91 and the neutral conductor 94. forming the pair 9a. FIG. 5 illustrates the assembly of the outer plates 4 and 6, with their respective connecting elements 3 and 5, and the elongated parts of two clamping elements, here the rods of the screws 71 and 72 which pass through the bores 211 and 212 of the vertical shim 2. The lower plate 4 is positioned and clipped together on the lower connection element 3 to form the lower part. The screws 71 and 72 are inserted and assembled by threading the screws into the housings 211 and 212 of the vertical central block 2 according to the upward arrow. This lower part, the plate or the connecting element, is then clipped to the ends of the lower pillars of the vertical shim 2. Similarly, the upper plate 6 is assembled with the upper connecting element 4 to form the upper part. It is then positioned with the screws 71 and 72 through the openings 609 of the plate, then is clipped in the same way on the vertical central block 2. FIGURE 6 illustrates the connector after insertion of the conductors of two branch cables 8 and 8 ', and during the insertion of a cablet 7 of grounding. A first derivative cable 8 comprises the derived conductors 81 to 84. A second derivative cable 8 'comprises the derived conductors 81' to 84 '. Fusible sockets 719 and 729 are positioned by taking one or two threads on the ends of the screws 71 and 72. The derived conductors are positioned inside the upper and lower parts, each between a connection element and the outer plate which corresponds to him. In this embodiment, during a double derivative assembly, these conductors will be placed side by side, for example 83 and 83 ', taking care to extend their ends of the connector. Housings formed in the form of connecting elements and outer trays position the conductors, and can also maintain them in position.

As can be seen, a grounding cablet 7 can be positioned opposite the neutral conductor 84 and 94, for example by inserting its comb 74 into a specific housing provided in the form of a terminal. a connection element 4 (or possibly a plate), for example on the side of the neutral bypass conductors 84 and 84 '(or possibly on the side of the main neutral conductor 94. FIG. 7 is a half cross-sectional view illustrating the upper part of the assembled connector before clamping.It shows the positioning of the derived conductors 92, 82 ', 93 and 93' in the upper part 4, 6 in the case of a double derivative version.

As can be seen, the derived conductors 83 and 83 'are in electrical contact with the teeth of a conductive contact element 53, or metal comb, which pierces their insulating sheath and is carried by an insulating connection element 5, or comb holder. This comb 53 is in electrical contact with the corresponding main conductor 93 by piercing its insulating sheath. The combs 52 and 53 of different phases 82, 93 or neutral are isolated from each other by the material of the comb holder 5. For example, the one or more clamping elements comprise a threaded screw 71, 72 interacting with a nut 719, 729, at least one of which is connected to a maneuvering part by means of a shape having a determined section to break under the effect of a determined tightening torque. In the present example, these are sockets 719, 729 said fuses, having a smaller section and a value calculated to torsionally torsion to the desired torque for clamping.

FIGURE 8 is a cross-sectional view illustrating the connector after final tightening of the clamping members. Once positioned all of the derived conductors 81 to 84 'and the cablet of neutral 7, we screw the fuses 719 and 729 which will break at the recommended torque, thus ensuring having undergone optimum tightening. As can be seen, the allowance E 1 of the horizontal wedge 1 is not sufficient to compensate for the smaller thickness of the main neutral conductor 94. The angle of inclination A7 of the lower plate 4 with respect to the axis D71 of the clamping screw or relative to the other plate 6 allows its connection element 3 to take the same inclination. The tips of its combs 31 and 34 can thus come to bear with the same force on their respective main conductors 91 and 94. It is thus seen how the invention makes it possible to make up the difference in section of the neutral conductor 94 even when the extra thickness of the horizontal wedge 1 is not enough, and without adding wedge or other additional room.

Preferably, the connecting elements 3, 5 or comb supports also have a rounded internal shape which makes it possible to obtain a balanced contact with the different main conductors. Preferably, the connection elements 3, 5 also have a rounded outer shape and the trays 4, 6 or shoes also have a rounded inner shape, which makes it possible to obtain a balanced contact with the various derived conductors. FIGS. 9 and following illustrate a second exemplary embodiment, which will be described only in its differences.

FIGURE 9 illustrates the two central elements 1 and 2 in place, and the two connection elements 3 and 5 before assembly. As can be seen, the vertical wedge 2 has a constant thickness on its middle part and its rear part. The horizontal wedge 1 is shown in assembled position and before insertion. In this embodiment, the through openings 111 and 112 are formed by notches that open laterally to the side of the workpiece. FIG. 10 illustrates the assembly of the two outer plates and the clamping elements, in the embodiment of FIGURE 9. The lower plate 4 and its connecting element 3 are in place with the derived conductors 81, 84, 81 ' and 84 '. During a double derivative assembly, the derived conductors are presented in position and then cut at a mark inscribed in the center of the comb holder 5. They are then positioned abutting against a cable stop 28 which is inserted in a vertical groove. 29 when opening in a single derivative, this same cable stop 28 is arranged to be positioned at the unoccupied end of the derived conductor housing and to form a shutter. FIGURE 11 is a cross-section illustrating the embodiment of FIGURE 9 being tightened before rupture of the fuse actuating portion 719, 729 of the screws 71 and 72.

As can be seen, in this embodiment also, the connector according to the invention consists of several subassemblies to be assembled during the implementation thereof: - Placement of vertical and horizontal wedges . Due to its shape and structure the vertical wedge can replace the tools used to separate the conductors of the main cable. - Positioning, one after the other, two connection elements, or satellites or combs, which have connectors on both sides. By their forms and their design, these toothed connectors, also called combs, make it possible to make an electrical connection between the main conductors and the derived conductor (s), by perforating the insulation sleeves of the conductors. - Placement of the plate or lower pressure shoe then the upper press shoe equipped with two screws with fuse heads. - Tighten the assembly using the two screws with calibrated breaking heads.

All these operations can be carried out under electrical tension, easily and safely. No mechanical stress is exerted before tightening the two screws. There is no risk that an electrical potential is accessible before tightening these screws, which alone triggers the perforation of the insulators.

Grounding (MALT) can be done via a comb with a grounding braid connected to it. This comb makes it possible to make a contact between the main conductor of Neutral and the driver (s) derived from Neutral, as well as to realize an equipotential bonding. By design, the assembled assembly constituting the four-pole connector has an inclination making it possible to overcome the inconvenience that can be caused by the particularity of cables with conductors of different cross-sections, and in particular main conductors of neutral conductor network. reduced section, for example cables according to the NFC 33-210 standard. Of course, the invention is not limited to the examples which have just been described and many adjustments can be made to these examples without departing from the scope of the invention.

Claims (10)

REVENDICATIONS1. A four-pole electrical connection device for connecting a main electrical cable (9) comprising four main conductors (91, 92, 93, 94) with at least one electrical branch cable (8) comprising four so-called shunt conductors (81, 82 , 83, 84), said device comprising: - a horizontal said insulating central element (1) having two opposite faces (101, 102), which is inserted between two pairs of two main conductors (9a; 9b), and which receives said two main conductors (91, 92, 93, 94) in four locations electrically insulated from each other and carried by said opposite faces, and - two outer plates (4, 6) disposed opposite each of said opposite faces ( 101, 102) of the horizontal central element (1), each (4, 6) of said outer plates having a so-called inner face (401, 601) facing said horizontal central element (1) and receiving at least a pair of two co shunt generators (8a, 8b) at two shunt locations isolated from one another; wherein each pair of branch conductors (8a, 8b) is separated from the pair of main conductors (9a, 9b) to which it is connected by a connecting element (3, 5) comprising at least two conductive contact elements ( 32 and 34; 52 and 53) isolated from each other, each contact element making electrical contact between one of the main conductors and the corresponding branch conductor, and wherein the maintenance of the assembly and the electrical contacts is obtained under the effect of a clamping exerted between said outer plates (4, 6) by the same elongated clamping element (71, 72) which passes through both said outer plates (4, 6), said elements of connection (3, 5) and said horizontal central element (1), passing between the two conductors of each of the two pairs of main conductors (9a, 9b) and between the two conductors of each of the two pairs of branch conductors ( 8a, 8b); said device characterized in that the device further comprises another so-called vertical insulating central element (2) inserted between the conductors of the main cable (9), transversely to the horizontal central element (1), so as to separate the conductors of each other within each of the pairs of main conductors (9a, 9b), in that one (2) of said horizontal and vertical central elements has an opening (21) allowing it to be traversed by the other (1) once in place between the main conductors, and in that one or both outer plates (4, 6) receive the tightening of the one or more clamping elements (71, 72) on a convex reach (402, 602) for clamping in a plurality of different inclination positions (A7) of at least one (4) of said outer plates with respect to the axis (D71) of the clamping member (71); ) (around the longitudinal axis of the main cable), and through an opening (40 9) having an angular clearance around said clamping member (71, 72). 2. Device according to the preceding claim, characterized in that one or the other of the central insulating elements (1, 2), or both, has a generally flattened shape, the two largest faces bear against the main drivers that he separates. 3. Device according to one of the claims, characterized in that at least one of the central insulating elements horizontal (1) and vertical (2) or both has, in its direction (D1, D2) depression between the main conductors, a thickening profile (E2) producing a wedge effect allowing it to separate the main conductors from each other when inserted into the main cable between said main conductors. 4. Device according to any one of the preceding claims, characterized in that the vertical central element (2) comprises at least one through opening (211, 212) which receives the element (71, 72) for clamping the outer trays. (4, 6) so as to hold it in position before clamping and keep it away from the main conductors (91, 92, 93, 94). 5. Device according to any one of the preceding claims, characterized in that the horizontal central element (1) has one or more recesses (111, 112) receiving one or more clamping elements of the outer trays or receiving the central element. vertical (2), thus maintaining a maintenance of the interlocking assembly of said horizontal central elements (1) and vertical (2). 6. Device according to any one of the preceding claims, characterized in that the vertical central element (2) has on the one hand, in the plane of its general shape, an opening or a notch through which forms a housing (21). ) accommodating the horizontal central element (1), and on the other hand, for each clamping element (71, 72), at least one cylindrical bore (211, 212) passing through, embedded in its thickness and having an axis parallel to the driving direction (D2) of said vertical central element, and which crosses said housing (21) receiving the horizontal central element, and in that the horizontal central element (1) has, in the plane of its general shape, for each clamping member (71, 72), at least one aperture or through-notch (111, 112) positioned to be aligned with the cylindrical bore (211, 212) receiving said clamping member (71, 72) in the vertical central element (2) when assembled. 7. Device according to any one of the preceding claims, characterized in that that of the horizontal central elements (1) and vertical (2) which passes through the other has a shape abutting on the other in its assembled position and is maintained in this position by at least one elastic part making a clipping. 8. Device according to any one of the preceding claims, characterized in that the outer plates (4, 6) and / or the connecting elements (3, 5) have, for each branch location, two housings of a shape provided to receive two branch conductors (83 and 83 ') from two different branch cables (8 and 8'), and to connect them both to the same main conductor (93), for example by the same contact element (53). 9. Device according to any one of the preceding claims, characterized in that the or the clamping elements comprise a threaded screw (71, 72) alone or interacting with a nut (719, 729), at least one of which is connected to a maneuvering part via a shape having a determined section to break under the effect of a given tightening torque. 10. A method of electrical connection between a four-pole cable and one or more shunt cables, comprising the following steps: - insertion (D2) of a so-called vertical insulating central element (2) between two pairs (9c, 9d) of main conductors , so as to achieve a physical separation of said pairs (9c, 9d); inserting (D1) a horizontal central element (1) between the two conductors (91 and 94; 92 and 93) of each of said pairs of main conductors (9c, 9d), passing through an opening (21); ) carried by said vertical insulating central element (2), so as to achieve a physical separation of said conductors within each of said pairs (9c, 9d); - assembling, around the main cable (9) and on each side of the vertical insulating central element, an outer plate provided for gripping a pair of branch conductors and a pair of conductors against said first central; - tightening the assembly by screwing at least one screw-nut clamping element which passes through both said outer plates (4, 6), said connecting elements (3, 5) and said vertical insulating central element (2), passing between the two conductors of each of the two pairs of main conductors (9a, 9b) and between the two conductors of each of the two pairs of branch conductors (8a, 8b).