Electrical power supply system with alterable capacity

The invention claimed is: 1. An apparatus comprising an electrical power supply system having alterable capacity, said electrical power supply system comprising electrical energy storage modules, and an interconnection interface, wherein each of said electrical energy storage modules comprises two connection terminals of opposite polarities and an electrical energy storage element connected between said two terminals, wherein said interconnection interface comprises two pairs of input terminals and two output terminals for a power supply of an electrical load, wherein each pair of input terminals is connected in a removable manner to connection terminals of a respective electrical energy storage module, wherein said interconnection interface forms branches connected in parallel between said two output terminals, each branch including one of said electrical energy storage elements, wherein each of said branches comprises a rheostat connected in series with a corresponding electrical energy storage element of said branch, wherein said interconnection interface further comprises a device for measuring current passing through each of said branches, and a control circuit configured for controlling resistances of said rheostats of said branches as a function of said measured current so as to maintain a current intensity passing through said rheostats to be below a protection threshold. 2. The apparatus of claim 1 , wherein said electrical energy storage elements comprise electrochemical accumulators. 3. The apparatus of claim 2 , wherein said electrochemical accumulators are of LiFePO4 type. 4. The apparatus of claim 1 , wherein each of said rheostats is included in said interconnection interface and is connected between a respective input terminal and an output terminal. 5. The apparatus of claim 1 , wherein each of said rheostats comprises a MOS transistor whose resistance is defined by application of a gate/source voltage by said control circuit. 6. The apparatus of claim 5 , wherein each of said rheostats comprises two MOS transistors connected head-to-tail in series, and wherein a resistance of each of said two transistors is defined by said application of said gate/source voltage by said control circuit. 7. The apparatus of claim 1 , further comprising a thermal dissipater, and two thermal absorption elements coupled thermally to said thermal dissipater, wherein each thermal absorption element is thermally coupled to a corresponding rheostat. 8. The apparatus of claim 7 , wherein said thermal absorption elements are thermally coupled to said thermal dissipater by way of a thermally conducting and electrically insulating layer. 9. The apparatus of claim 1 , wherein said control circuit is configured to maintain said current intensity passing through a rheostat to be below a first protection threshold when said rheostat is traversed by a discharge current of said associated electrical energy storage module, and wherein said control circuit is configured to maintain a current intensity passing through said rheostat to be below a second protection threshold when said rheostat is traversed by a charge current, said first and second protection thresholds being different. 10. The apparatus of claim 1 , wherein said control circuit is configured to allow discharge of an electrical energy storage module having a higher state of charge towards an electrical energy storage module having a lower state of charge in the absence of an electric load connected to said output terminals of said interconnection interface. 11. The apparatus of claim 1 , wherein each of said branches comprises a fuse connected in series with one of said electrical energy storage elements and a rheostat, a cut-out threshold of said fuse being greater than said protection threshold. 12. The apparatus of claim 1 , further comprising a protection casing in which said input terminals of said interconnection interface are housed, wherein said protection casing is configured to guide said electrical energy storage modules by sliding so that connection terminals of an electrical energy storage module at an extremity of sliding travel thereof connect to a respective pair of input terminals of said interconnection interface. 13. The apparatus of claim 1 , wherein said electrical energy storage modules comprise a casing in which said electrical energy storage element is housed in a removable manner, wherein said electrical energy storage element comprises electrochemical cells, and a management device for said electrochemical cells, wherein said casing comprises a supervision device, and a connection facility electrically connecting said electrical energy storage element to said two connection terminals of opposite polarities of said electrical energy storage module, wherein said management device is programmed to implement a function selected from the group consisting of measurement of voltage of said electrochemical cells, measurement of temperature of said electrochemical cells, making said cells safe in case of excessive charge or discharge current, making said cells safe in case of too high or too low voltage of an electrochemical cell, and balancing voltages of said electrochemical cells, wherein said supervision device is programmed to implement a functionality selected from the group consisting of measurement of current passing through said storage element, calculation of said remaining energy in said storage element, calculation of charge/discharge power of said storage element, and recording of said electrical energy storage module's usage data.