Energy storage system and applications

What is claimed is: 1. A power transfer system, comprising: a plurality of generator circuits ( 3103 A-C) configured to generate a plurality of time-varying direct current (DC) voltages; a first converter circuit ( 3101 ) that includes a plurality of first converter circuits ( 3203 A-C), each first converter circuit including: a first input circuit ( 3401 ) configured to receive one of the time-varying DC voltages, and a first output circuit ( 3419 ) galvanically isolated from the input circuit and configured to generate a first corresponding DC voltage derived from the time-varying DC voltage received by the first input circuit, wherein the first converter circuit is configured to combine the first corresponding DC voltages of the first output circuits to generate a transmit voltage and drive a transmission line ( 3106 ); and a second converter circuit ( 3102 ) that includes a plurality of second converter circuits, each second converter circuit including: a second input circuit ( 3401 ) configured to receive a portion of the transmit voltage, and a second output circuit ( 3419 ) galvanically isolated from the second input circuit and configured to generate a second corresponding DC voltage derived from the portion of the transmit voltage received by the second input circuit, wherein the second converter circuit is configured to deliver the second corresponding DC voltages of the second output circuits on a common power bus; and a load ( 3104 ) coupled to the common power bus. 2. The power transfer system of claim 1 , wherein each first converter circuit further includes a transformer, wherein the first input circuit is further configured to induce, using the time-varying DC voltage received by the first input circuit, a first current in a primary coil of the transformer, and wherein the first output circuit is further configured to generate the first corresponding DC voltage using a second current induced in a secondary coil of the transformer. 3. The power transfer system of claim 2 , wherein to generate the first corresponding DC voltage, the first output circuit is further configured to: rectify the second current to generate an internal supply voltage; and generate the first corresponding DC voltage using the internal supply voltage. 4. The power transfer system of claim 1 , wherein the load includes a heating element configured to receive the second corresponding DC voltages via the common power bus to heat a thermal storage medium. 5. The power transfer system of claim 4 , wherein the load includes an electric vehicle charger configured to charge at least one battery using the second corresponding DC voltages. 6. An apparatus, comprising: a first plurality of converter circuits ( 3203 A-C), each converter circuit including: an input circuit ( 3401 ) configured to receive a direct current (DC) input voltage from a renewable energy source; and an output circuit ( 3419 ) galvanically isolated from the input circuit and configured to generate a DC output voltage derived from the DC input voltage; wherein the output circuits of the first plurality of converter circuits are coupled in series to combine respective DC output voltages to produce a transmit voltage; and a thermal storage unit ( 3104 ) including a heating element ( 3112 ) configured to receive the transmit voltage to heat a thermal storage medium ( 3111 ). 7. The apparatus of claim 6 , wherein each converter circuit further includes a transformer, wherein the input circuit is further configured to induce, using the DC input voltage, a first current in a primary coil of the transformer, and wherein the output circuit is further configured to generate the DC output voltage using a second current induced in a secondary coil of the transformer. 8. The apparatus of claim 7 , wherein to generate the DC output voltage using the second current, the output circuit is further configured to: rectify the second current to generate an internal supply voltage; and generate the DC output voltage using the internal supply voltage. 9. The apparatus of claim 6 , wherein the renewable energy source includes a plurality of photovoltaic cells configured to generate the DC input voltage based on an illumination of the photovoltaic cells. 10. A method, comprising: receiving, by an input circuit ( 3401 ) of a given converter circuit of a plurality of converter circuits ( 3203 A-C), a direct current (DC) input voltage from a renewable energy source ( 3202 A-C); generating, by an output circuit ( 3419 ) of the given circuit that is galvanically isolated from the input circuit, a DC output voltage derived from the DC input voltage; combining respective DC output voltages by coupling the output circuits of a first plurality of converter circuits in series to produce a transmit voltage ( 3108 ); and heating a thermal storage medium ( 3104 ) by a heating element ( 3112 ) using the transmit voltage. 11. The method of claim 10 , further comprising adding a second plurality of DC voltages to generate the transmit voltage. 12. The method of claim 10 , wherein generating the DC output voltage includes: inducing, by the input circuit using the DC input voltage, a first current in a primary coil of a transformer included in the given converter circuit; and generating, by the output circuit using a second current in a secondary coil of the transformer, the DC output voltage, wherein the second current in the secondary coil is based on the first current in the primary coil of the transformer. 13. The method of claim 12 , further comprising: rectifying, by the output circuit, the second current to generate an internal supply voltage; and generating, by the output circuit, the DC output voltage using the internal supply voltage. 14. An apparatus, comprising: a plurality of first converter circuits ( 3203 A-C), each first converter circuit including: a first input circuit ( 3401 ) configured to receive a direct current (DC) input voltage from a renewable energy source; and a first output circuit ( 3419 ) galvanically isolated from the first input circuit and configured to generate a DC output voltage derived from the DC input voltage, wherein the output circuits of the first plurality of converter circuits are coupled in series to combine respective DC output voltages to produce a transmit voltage; a plurality of second converter circuits ( 3302 A-C) coupled in series across the transmit voltage to generate a plurality of voltage portions, wherein each second converter circuit includes: a second input circuit ( 3401 ) configured to receive a corresponding portion of the plurality of voltage portions; and a second output circuit ( 3419 ) galvanically isolated from the second input circuit and configured to generate, using the corresponding portion, a DC load voltage; and a thermal storage unit ( 3104 ) configured to heat a thermal storage medium ( 3111 ) using respective DC load voltages from the second plurality of converter circuits. 15. The apparatus of claim 14 , wherein each first converter circuit further includes a transformer, wherein the first input circuit is further configured to induce, using the DC input voltage, a first current in a primary coil of the transformer, and wherein the first output circuit is further configured to generate the DC output voltage using a second current induced in a secondary coil of the transformer. 16. The apparatus of claim 15 , wherein to generate the DC output voltage, the first output circuit is further configured to: rectify the second current to generate an internal supply vol