FR2680286A1 - Electrical connection system having a continuously variable connection point - Google Patents

Abstract

The invention relates to an electrical connection system having a continuously variable connection point. It is characterised in that it comprises an electrically conducting assembly which includes, embedded in an insulating material (10, 42), two conducting cores (12, 14; 48, 50) arranged parallel to each other, each core being constituted by two juxtaposed separate conducting elements (20 to 26; 52 to 58) and a movable connector assembly (60) comprising a connector body (socket) (62) and two conducting pins (66, 68) which are positioned on the connector body so that each pin can pierce the said insulating material and so that its end is lodged between the said juxtaposed conducting elements, thereby establishing electrical contact between the end of each pin and the corresponding core.

Description

POINT ELECTRICAL CONNECTION SYSTEM
CONTINUOUSLY VARIABLE CONNECTION
The present invention relates to an electrical connection system with a continuously variable connection point.

 More specifically, the present invention relates to an electrical connection system in which a connector element, for example of the electrical outlet type or of the light fitting socket type, can be connected at any point of a conductor power supply to power the connector assembly.

 Electrical connection installations are already known in which there is an electrical supply cable constituted by a perforable insulating sheath in which two conductive cores are embedded. The connector element comprises a base provided with two electrical conductive pins capable of perforating the insulation sheath of the electric cable. The two pins are positioned in the base in such a way that each of them comes into electrical contact with one of the cores of the cable. Such an installation is of course very useful when it is desired to be able to mount a connection assembly at any point of the electrical distribution cable.

 However, known installations have a number of drawbacks. On the one hand, the penetration of the pins in the insulating sheath of the cable does not usually alone enable the mechanical assembly of the connector assembly on the cable. It is necessary to provide special mechanical devices to ensure this connection or this attachment. Another disadvantage consists in the fact that the penetration of the end of the point-shaped spikes into the conductor's cores, if it is repeated a significant number of times, risks causing a rupture of one of the cores of the electric cable. and therefore make the installation unusable.

 To overcome these drawbacks, an object of the present invention is to provide an electrical connection system of the type mentioned above which, on the one hand, makes it possible to effectively obtain a mechanical connection between the connector element and the cable d 'power supply and which, in addition, eliminates the risk of cutting one of the souls of the electric cable as and when connecting a connector element of the cable.

 To achieve this object, according to the invention, the electrical connection system with a continuously variable connection point is characterized in that it comprises an electrical conductor assembly comprising, embedded in an insulating material, two conductive cores arranged parallel to one another. the other, each core being constituted by two separate conductive elements juxtaposed and a movable connector assembly comprising a base and two conductive pins positioned on the base so that each pin can pierce said insulating material and that its end is housed between said conductive elements juxtaposed, whereby an electrical contact is established between the end of each pin and the corresponding core.

 We understand that, thanks to the particular constitution of each of the two cores which are each constituted by two electrical conductive assemblies juxtaposed, the tips of the pins do not pass through the conductive elements forming the cores but are inserted between these two conductive elements thus ensuring a electrical contact without risking breaking the electrical continuity thereof.

 According to a preferred embodiment, each separate conductive element forming a core is constituted by a single rigid electrical conductor. It is understood that thus the mechanical connection between the connector assembly and the electrical cable will be improved due to the rigidity of the two juxtaposed conductive elements forming a same core, the end of the pins being pinched between the two rigid electrical conductive elements.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description of an embodiment of the invention given by way of non-limiting example. The description refers to the appended figures in which
FIG. 1 is a cross-sectional view of an electric cable usable in the installation according to the invention and
- Figure 2 shows an example of mounting a connector assembly on an electric cable according to the invention.

 Referring first to Figure 1, we will describe an electric cable structure forming part of the system according to the invention. The electrical cable is constituted by an insulating sheath 10 inside which are embedded two conductive cores 12 and 14. As shown in FIG. 1, preferably, the cable, in cross section, has two planar faces 16 and 18 substantially parallel to each other, these faces being parallel to the plane PP 'of the cable containing the cores 12 and 14.

According to the invention, each core, respectively 12 and 14, is constituted by two separate conductive elements referenced 20 and 22 for the core 12 and 24 and 26 for the core 14. According to the embodiment shown in the figure 1, each conductive element 20 to 26 consists of a single strand or rigid conductive wire of circular section, the two conductive elements forming the same core being tangent. In addition, according to a preferred embodiment, all of the two conductive elements forming the same core, respectively 20, 22; 24, 26, is surrounded by an insulating envelope, respectively referenced 28 for the core 12 and 30 for the core 14.

 According to the particular embodiment shown in FIG. 1, the width L of the insulating sheath is equal to 9.4 mm, the thickness E of the insulating sheath is equal to 4.5 mm, the thickness of the individual sheaths 28 and 30 is of the order of 0.6 mm and the diameter of each of the conductive elements 20 to 26 is of the order of 1.3 mm. It is understood that, if the insulating outer casing 10 and the individual casings 28 and 30 are made to penetrate the cores of the sharp pins to ensure an electrical connection, the ends of the pins tend to separate the conductive elements forming the same core , which ensures good electrical contact. In addition, and above all, this electrical contact is established without there being any perforation of the conductive element, which avoids any risk of it breaking.

 Referring now to Figure 2, we will describe an example of connection on a cable, according to the invention, an electric bulb. The conductive cable 40 comprises an external insulating sheath 42 comprising two flat external faces 44 and 46.

The conductor 40 comprises two cores 48 and 50 respectively constituted by the conductive elements 52, 54 and 56, 58. In this embodiment, the cores are not surrounded by a particular insulating sheath. The element to be connected, which is referenced 60, comprises a base 62 on which is mounted an electric bulb 64. Two conductive pins 66 and 68 protrude from the underside 62a of the base 62. These pins are electrically connected by the conductors 70 and 72 to the bulb 64. According to this embodiment, it can be seen that each pin has a sharp end 66a and 68a, and near this end, a groove 66b and 68b. The grooves 66b and 68b are positioned on the pins so that, when the face 62a of the base is in contact with the upper face 44 of the cable 40, these grooves are arranged between the rigid conductive elements 52, 54 and 56, 58. One thus obtains a locking effect of the pins 66 and 68 between the rigid conducting elements constituting the two cores which, under the effect of the insulating sheath 46, tend to approach under the effect of the material constituting the insulating sheath .

 It can be seen that, thanks to the particular provisions of this embodiment of the invention, the mechanical connection between the connector element and the electric cable is further improved, which makes it possible to avoid the installation of means of specific fixing of the connector element on the conductor cable.

 It goes without saying that we would not depart from the invention if the conductive elements forming the cores were of the multi-strand type.

Claims (5)

 1. Electrical connection system with continuously variable connection point, characterized in that it comprises an electrical conductor assembly comprising, embedded in an insulating material (10, 42), two conductive cores (12, 14; 48, 50) arranged parallel to each other, each core being constituted by two separate juxtaposed conductive elements (20 to 26; 52 to 58) and a movable connector assembly (60) comprising a base (62) and two conductive pins (66, 68 ) positioned on the base so that each pin can pierce said insulating material and its end is housed between said juxtaposed conductive elements, whereby an electrical contact is established between the end of each pin and the corresponding core.  2. System according to claim 1, characterized in that each conductive element consists of a single rigid electrical conductor (20 to 26).  3. System according to claim 1, characterized in that each conductive element consists of a plurality of strands.  4. System according to claim 2, characterized in that the pairs of conductive elements (20 to 26) forming a core are surrounded by an insulating sheath (28, 30) itself embedded in said insulating material (10).  5. System according to any one of claims 1 to 4, characterized in that each pin (66, 68) has a sharp end (66a, 68a) for piercing said insulating material (42) and a portion of reduced diameter (66b , 68b) to be housed between the two conductive elements (52, 54, 56, 58).