An energy storage system for a direct current transmission system and a method for exchanging energy with a direct current transmission system

1 . An energy storage system for a direct current (DC) transmission system, the energy storage system being configured to be connected to a DC link of the DC transmission system, the energy storage system comprising: a first system terminal and a second system terminal, a first converter connected to the first system terminal, a second converter connected to the first converter and the second system terminal, an alternating current (AC) loop device connected to the first system terminal and to the second system terminal and in parallel with the first and second converters, the AC loop device providing an alternating current (AC) path, and a plurality of energy storage devices connected in parallel with the second converter and in series with the first converter, wherein each energy storage device comprises a cell having power electronic switches, and an energy storage element connected to the cell, wherein the cells are individually switchable. 2 . The energy storage system according to claim 1 , comprising an energy storage device controller, wherein the first and second converters are configured to control a first direct current (DC) voltage between the first and second system terminals and a second DC voltage between their interconnection point and the second system terminal, and to control first and second alternating current (AC) voltages across the first and second converters, respectively, and wherein the energy storage device controller is configured to control each cell to insert or bypass the energy storage element such that a power exchange with the plurality of energy storage devices is controlled and such that an energy storage voltage, being a total output voltage of the plurality of energy storage devices, is adapted to the second DC voltage and the second AC voltage. 3 . The energy storage system according to claim 1 , wherein at least one of the first and second converters generate an AC current that is allowed to circulate through the first and second converters, and through the AC loop device. 4 . The energy storage system according to claim 1 , wherein each of the first and second converters is a modular multilevel converter. 5 . The energy storage system according to claim 1 , wherein the AC loop device comprises at least one of an arrangement of passive elements, and an arrangement of active elements. 6 . The energy storage system according to claim 1 , wherein each energy storage element is a super capacitor and/or a battery. 7 . The energy storage system according to claim 1 , further comprising a braking device comprising a braking resistor arranged in parallel to the plurality of energy storage devices, and a switching structure comprising a first switch connected in series with the plurality of energy storage devices, and a second switch connected in parallel to the braking resistor, wherein the braking device is configured to disconnect the plurality of energy storage devices and to redirect a current to flow through the braking resistor. 8 . The energy storage system according to claim 1 , further comprising a braking device comprising a braking resistor arranged in parallel to the plurality of energy storage devices and a switching structure comprising the first switch, connected in series with the plurality of energy storage devices, and power electronic switches, wherein the power electronic switches are connected in series with the braking resistor. 9 . The energy storage system according to claim 1 , wherein the plurality of energy storage devices comprises a branch of several energy storage devices connected in series. 10 . The energy storage system according to claim 1 , further comprising an alternating current (AC) rejecting circuit connected in series with the plurality of energy storage devices between the energy storage devices and the first and second converters. 11 . The energy storage system according to claim 1 , wherein the DC link has a first pole and a second pole, the energy storage system further comprising a third converter, a fourth converter and a further plurality of energy storage devices, which are interconnected similar to the first converter, the second converter and the plurality of energy storage devices, and comprise a third system terminal and a fourth system terminal, similar to the first and second system terminals, respectively, wherein the first system terminal is connected to the first pole, the second system terminal to ground, the third system terminal is connected to the second pole, and the fourth system terminal is connected to ground. 12 . A method for exchanging energy with a direct current (DC) transmission system, by means of an energy storage system configured to be connected to a DC link of the DC transmission system, wherein the energy storage system comprises: a first system terminal and a second system terminal, a first converter connected to the first system terminal, a second converter connected to the first converter and the second system terminal, an AC loop device connected to the first system terminal and to the second system terminal and in parallel with the first and second converter, the AC loop device providing an alternating current (AC) path, and a plurality of energy storage devices connected in parallel with the second converter and in series with the first converter, wherein each energy storage device comprises a cell having power electronic switches, and an energy storage element connected to the cell, wherein the cells are individually switchable, the method comprising: absorbing energy from the DC transmission system by controlling at least one of the plurality of energy storage devices to absorb energy in the energy storage element, and releasing energy to the DC transmission system from the energy storage system by controlling at least one of the energy storage devices to release energy from the energy storage element. 13 . The method according to claim 12 , comprising: controlling a first DC voltage between the first and second system terminals and a second DC voltage between an interconnection point of the first and second converters and the second system terminal by means of the first and second converters, controlling a first AC voltage across the first converter and a second AC voltage across the second converter, and controlling each cell to insert or bypass the energy storage element such that a power exchange with the plurality of energy storage devices is controlled and such that a total output voltage of the plurality of energy storage devices is adapted to the second DC voltage and the second AC voltage. 14 . The method according to claim 12 , comprising: generating an AC current; and circulating the AC current through the first and second converters and the AC loop device. 15 . The method according to claim 14 , comprising controlling a total voltage across the energy storage devices to follow the variations of an amplitude of a modulated AC voltage across the second converter.