FR2875647A1 - METHOD FOR DISTRIBUTING DISTRIBUTION OF ELECTRICAL ENERGY - Google Patents

Abstract

The invention concerns a method for distributed delivery of electric power which consists in simultaneously using the intrinsic equipotentiality of a current supply conductor (1) and an electrical connection by ultrasonic bonding of the end of at least one supply electrical conductor (2) on said current supply electrical conductor (1).

Description

The present invention relates to a distributed distribution method of

  the electrical energy based on the intrinsic equipotentiality of the current lead conductor.

  It is particularly suitable for producing electric power supply cables for subassemblies, for example integrated modules in bays.

  In general, it is known that to obtain this result, the current technical response consists in interposing equipotential electrical conductors between the current supply conductor and the electric conductors for supplying electrical energy to the subassemblies.

  These equipotential electrical conductors, allowing the distribution of electrical energy, generally consist of rigid conductors, such as "bus-bar", or semi-rigid or flexible conductors, and connectors, terminal block type; Moreover, the terminal blocks themselves may comprise rigid conductors, "bus-bus" type, which terminal blocks are interconnected by rigid, semi-rigid or flexible electrical conductors thus constituting jumpers or "straps".

  The electrical contacts between the various elements to be connected are ensured either directly by electrically conductive clamping screws or by electrically conductive clamps, themselves actuated, either by clamping screws or by springs. support.

  However, these solutions are not entirely satisfactory for the following reasons: the implementation time is important and despite the modularity of the different interconnection elements, the multiplicity of connections between the different interconnection elements does not allow the compactness, the visibility necessary for maintenance is difficult to obtain, the reliability of screw tightening is poor, especially in case of significant variation in the currents resulting in dimensional variations of the conductive elements, the heating generated by the electrical contact resistances between metals of different types, which can cause ignition of the insulating sheaths surrounding electrical conductors.

  The object of the invention is therefore more particularly to eliminate these disadvantages.

  For this purpose, it proposes a distributed distribution method of the electrical energy for associating at least one electrical supply conductor with the current conducting conductor under extremely simple operating conditions.

  It is based on the fact that the electrical current supply conductor has an intrinsic equipotentiality allowing the electrical conductors of the power supply to be directly connected by an electrical connection and thereby eliminating intermediate elements such as "barbs". bus "or terminal blocks associated with jumpers.

  It consists in simultaneously using the intrinsic equipotentiality of a current supply conductor and an electrical connection by ultrasonic welding of the end of at least one electrical supply conductor on said current supply electrical conductor.

  The process according to the invention may then comprise the following operating phases: removal in the zone where the electrical connection of the aforesaid electrical supply conductor to the aforesaid electrical conductor for supplying current is to be located, of a section of the electrical insulation sheath of said electrical current supply conductor, removal of a section of the electrical insulation sheath of the aforesaid electrical supply conductor, in the vicinity of its end to be connected to the aforesaid electric supply conductor current, of length less than the length of the aforesaid section of electrical insulation sheath of said previously removed electrical current supply conductor, placed around the electrical conductor of current supply of a heat-shrinkable sheath, of length at least greater than the length of the aforesaid section of electrical insulation sheath of said electrical supply conductor of formerly removed, and of diameter at least equal to the sum of the diameters of the aforesaid electrical conductors supplying current and power supply, ultrasonic welding of the previously stripped end of the aforesaid electrical supply conductor to the previously stripped portion of the aforesaid current supply conductor, installation of the above-mentioned heat-shrinkable sheath in the vicinity of the aforesaid ultrasonic welding so as to cover the aforesaid 2875647 4 stripped portions of the aforesaid electrical conductors for supply of current and power supply, and heating of the aforesaid heat-shrinkable sheath.

  Advantageously, a plurality of electrical supply conductors will be electrically bonded by ultrasonic welding of said electrical current supply conductor.

  Moreover, the aforesaid electrical supply conductors will be distributed along the electrical conductor of current supply being closer to their subset to supply electrical energy.

  Advantageously, the sum of the sections of the cores of said supply conductors will be at least equal to the section of the core of said electrical current supply conductor.

  Thus, this method allows: a direct connection between said electrical conductors supply current and power, through the elimination of any intermediate mechanical part, a positioning closer to the collection of electrical energy, the sub together to supply, an improvement in the compactness of the connections while ensuring a satisfactory visibility necessary for the maintenance of said connections, an improvement in the reliability of the connections by eliminating any mechanical clamping element, an improvement in the time required and - the suppression of the contact resistances generated by the metals 30 of different nature.

  An embodiment of the invention will be described hereinafter, by way of non-limiting example, with reference to the drawings in which: FIG. 1 represents the first operating phase according to the invention, FIG. represents the second operating phase according to the invention, FIG. 3 represents the third operating phase according to the invention, - FIG. 4 represents the fourth operating phase according to the invention, FIG. 5 represents the fifth operating phase according to the invention. and Figure 6 shows an exemplary embodiment of a power supply wiring of four subassemblies.

  In the example shown in Figure 1, an electrical conductor of current supply 1 consists of a core of electrically conductive material surrounded by a sheath of electrically insulating material 1b; in a zone Z1 where the electrical connection of an electrical supply conductor, not shown, must be located on said electrical current supply conductor 1, a section of the sheath of electrically insulating material 1b has been removed.

  In the example shown in FIG. 2, an electrical supply conductor 2 consists of a core of electrically conductive material 2a surrounded by a sheath made of electrically insulating material 2b; in an end zone Z2 of said conductor 2 where the electrical connection of an electrical current supply conductor, not shown, is to be located on said electrical supply conductor 2, a section of the sheath of electrically insulating material 2b has been kidnapped.

  In the example shown in FIG. 3, a heat-shrinkable sheath 3, of length at least greater than the length of the aforesaid sheath section of electrically insulating material 1b of the electrical current supply conductor 1 previously removed, and of diameter at least equal to the sum of the diameters of the aforesaid electrical conductors 1, 2, is placed around the conductor 1.

  In the example shown in FIG. 4, an ultra-sonic weld electrically bonds the previously stripped end of the electrical supply conductor 2 to the previously stripped portion of the current-conducting electrical conductor 1.

  In the example shown in FIG. 5, the aforementioned heat-shrinkable sheath 3 is positioned in the vicinity of the above-mentioned ultra sonic weld so as to cover said stripped portions of the electrical conductors 1, 2; it is then heated so as to marry on one side the electrical conductor 1, and on the other side, the electrical conductor 1 and the end of the electrical conductor 2.

  In the example shown in FIG. 6, four subsets SE1, SE2, SE3, SE4 are supplied with single-phase electrical energy from two electrical current supply leads Ci (called phase) and CN (called neutral). of an electrical conductor of mass CM.

  Four disconnectors DI1, DI2, DI3, DI4, responsible for detecting a possible electrical current shunt between the CN conductor and earth, and for measuring the intensity of the electric current flowing through the CN conductor, are arranged opposite the four subsystems SE respectively. ], SE2, SE3, SE4, symmetrically on both sides of the electrical conductors C1, CN, CM.

  In the vicinity of the pair SE1, DII, the three electrical conductors C1, CN, CM are stripped along three sections respectively T11, TIN, TiM.

  Three electrical supply conductors C11, CN1, CM1 are respectively welded to the sections T11, TIN, T1M, respectively associated with the three electrical conductors C1, CN, CM.

  The electrical conductors CN1, CM1 lead to the discontactor DI1; the electrical conductor Cil leads to the subset SEI; an electrical conductor CNI 'connects the DI1 discontactor to the subset SEI.

  Thus, the subset SEI is powered by the aforesaid electrical conductors C11 (phase), CN1 '(neutral); the discontactor DI1 measures the current flowing in the neutral (electrical conductors CN 1, CN 1 ') and detects a possible electrical current bypass between the neutral (CN1 conductor) and the ground (CMI electrical conductor).

  In the vicinity of the pair SE2, DI2, the three electrical conductors CI, CN, CM are stripped along three sections respectively T21, T2N, T2M.

  Three electrical supply conductors C12, CN2, CM2 are respectively welded to the sections T21, T2N, T2M, respectively associated with the three electrical conductors CI, CN, CM.

  The electrical conductors CN2, CM2 lead to the discontactor DI2; the electrical conductor C12 leads to the subset SE2; an electrical conductor CN2 'connects the discontactor DI2 to the subset SE2.

  Thus, the subset SE2 is powered by the aforesaid electrical conductors C12 (phase), CN2 '(neutral); the discontactor DI1 measures the current flowing in the neutral (electrical conductors CN2, CN2 ') and detects a possible electrical current derivation between the neutral (CN2 conductor) and the earth (CM2 electrical conductor).

  In the vicinity of the pair SE3, DI3, the three electrical conductors CI, CN, CM 30 are stripped along three sections respectively T31, T3N, T3M.

  Three electrical supply conductors C13, CN3, CM3 are respectively welded to the sections T31, T3N, T3M, associated respectively with the three electrical conductors C1, CN, CM.

  The electrical conductors CN3, CM3 lead to the discontactor DI3; the electrical conductor C13 leads to the subset SE3; an electrical conductor CN3 'connects the discontactor DI3 to the subset SE3.

  Thus, the subset SE3 is powered by the aforesaid electrical conductors C13 (phase), CN3 '(neutral); the discontactor DI3 measures the current flowing in the neutral (electrical conductors CN3, CN3 ') and detects a possible electrical current bypass between the neutral (CN3 conductor) and the earth (CM3 electrical conductor).

  In the vicinity of the pair SE4, DI4, the three electrical conductors C 1, CN, CM are stripped along three sections respectively T41, T4N, T4M.

  Three electrical supply conductors C14, CN4, CM4 are respectively welded to the sections T41, T4N, T4M, respectively associated with the three electrical conductors C1, CN, CM.

  The electrical conductors CN4, CM4 lead to the DI4 discontactor; the electrical conductor C14 leads to the subset SE4; an electrical conductor CN4 'connects the DI4 discontactor to the subsystem SE4.

  Thus, the subset SE4 is powered by the aforesaid electrical conductors C14 (phase), CN4E (neutral); the DI4 discontactor measures the current flowing in the neutral (electrical conductors CN4, CN4 ') and detects a possible electrical current bypass between the neutral (CN4 conductor) and the earth (CM4 electrical conductor).

  Thus, thanks to nine ultrasonic welds, four subsets will be supplied with electrical energy, between phase and neutral, through a control of the intensity of the electric current flowing through the neutral and a control of a possible derivation between the neutral and the earth.

  Moreover, the implantation of the various elements (subassemblies, discontactors, electrical conductors), as shown in FIG. 6, allows: a direct connection between said electrical conductors for supplying current and power; power supply, thanks to the elimination of any intermediate mechanical part, positioning as close as possible to the extraction of electrical energy, the subassembly to be supplied, an improvement in the compactness of the connections while ensuring a satisfactory visibility necessary for maintenance said connections, an improvement of the reliability of the connections through the removal of any mechanical clamping element, an improvement in the implementation time, and the elimination of the risk of overheating in the vicinity of the electrical connections.

Claims (6)

- 10-Claims   1. Distributed distribution method of the electrical energy, characterized in that it consists in simultaneously using the intrinsic equipotentiality of a current supply conductor (1) and an electrical connection by ultrasonic welding of the end of at least one electrical supply conductor (2) on said electrical current supply conductor (1).   2. Method according to claim 1, characterized in that it comprises the following operating phases: - removal in a zone (Z 1) where must be located the electrical connection of the aforesaid power supply conductor (2) on the aforesaid driver electric current supply (1), a section of the electrical insulation sheath (1b) of said electric current supply conductor (1), removal of a section of the electrical insulation sheath (2b ) of the aforesaid electrical supply conductor (2), in the vicinity of its end to be connected to the aforesaid electrical current supply conductor (1), of length less than the length of the aforesaid section of electrical insulation sheath of said conductor electric current supply (1) previously removed, placed around the electrical current supply conductor (1) of a heat-shrinkable sheath (3), of length at least greater than the length of the aforesaid sheath section of electrical insulation of said current supply conductor (1) previously removed, and having a diameter at least equal to the sum of the diameters of the aforesaid current supply (1) and power supply (2) conductors, ultrasonic welding of the previously stripped end of the aforesaid electrical supply conductor (2) on the portion 2875647 -11- previously stripped of the aforesaid current supply conductor (1), - introduction of the aforesaid heat-shrinkable sheath (3) to the in the vicinity of said ultrasonic weld so as to cover said stripped portions of said electrical current supply (1) and supply (2) conductors, and heating of said heat-shrinkable sheath (3).   3. Process according to claims 1 and 2,   characterized in that it consists in performing a plurality of electrical connections by ultrasonic welding of the ends of a plurality of electrical supply conductors (2) on the aforesaid supply conductor (1).   4. Process according to claims 1 and 2,   characterized in that it consists in performing the electrical connection by ultrasonic welding of the end of the aforesaid electrical supply conductor (2) on the aforesaid current supply conductor (1) in the vicinity of the energy sampling point electric power closest to the use of said electrical energy.   5. Process according to claims 1, 2 and 3,   characterized in that the sum of the sections of the cores of said power supply conductors (2) is at least equal to the section of the core of said current supply conductor (1).   6. Application of the method according to one of the preceding claims, the wiring of electrical equipment racks and / or electronic.