Thermoelectric energy storage system with an intermediate storage tank and method for storing thermoelectric energy

What is claimed is: 1. An energy storage system having a charging cycle for providing thermal energy to a thermal storage, and a discharging cycle for generating electricity by retrieving the thermal energy from the thermal storage, the energy storage system comprising: a heat exchanger; a working fluid circuit for circulating a working fluid through said heat exchanger; a thermal storage medium circuit for circulating a thermal storage medium, the thermal storage medium circuit having at least one hot storage tank, one intermediate temperature storage tank and one cold storage tank connected together via the heat exchanger; means for joining or dividing a stream of thermal storage medium; and wherein the means for joining or dividing a stream of thermal storage medium comprise an internal stream splitter comprised in the heat exchanger. 2. The energy storage system according to claim 1 , wherein at least one further intermediate storage tank is connected in the thermal storage medium circuit, and the heat exchanger has a further internal stream splitter for each further intermediate storage tank. 3. The energy storage system according to claim 1 , wherein the charging and/or discharging cycle run transcritically. 4. An energy storage system having a charging cycle for providing thermal energy to a thermal storage, and a discharging cycle for generating electricity by retrieving the thermal energy from the thermal storage, the energy storage system comprising: a heat exchanger; a working fluid circuit for circulating a working fluid through said heat exchanger; a thermal storage medium circuit for circulating a thermal storage medium, the thermal storage medium circuit having at least one hot storage tank, one intermediate temperature storage tank and one cold storage tank connected together via the heat exchanger; means for joining or dividing a stream of thermal storage medium; and wherein the heat exchanger is divided into a first section and a second section and the thermal storage medium flows through both the first section and the second section, and wherein the means for joining or dividing a stream of thermal storage medium comprise a stream splitter located between the first section and second section of the heat exchanger. 5. An energy storage system having a charging cycle for providing thermal energy to a thermal storage, and a discharging cycle for generating electricity by retrieving the thermal energy from the thermal storage, the energy storage system comprising: a heat exchanger; a working fluid circuit for circulating a working fluid through said heat exchanger; a thermal storage medium circuit for circulating a thermal storage medium, the thermal storage medium circuit having at least one hot storage tank, one intermediate temperature storage tank and one cold storage tank connected together via the heat exchanger; means for joining or dividing a stream of thermal storage medium; and wherein the energy storage system converts electricity into heat and stores said heat in the charging cycle. 6. A method for storing and retrieving energy in an energy storage system, comprising: charging the system by heating a thermal storage medium, wherein the charging comprises: the thermal storage medium circulates between a hot storage tank, an intermediate storage tank and a cold storage tank connected together via a heat exchanger, wherein some proportion of thermal storage medium from the cold storage tank is split off and directed to the intermediate storage tank after passing through some part of the heat exchanger, or a portion of thermal storage medium from the intermediate storage tank is combined with thermal storage medium from the cold storage tank before passing through some other part of the heat exchanger; and discharging the system by heating a working fluid in a working fluid circuit with heat from the thermal storage medium, and expanding the working fluid through a thermodynamic machine. 7. The method according to claim 6 , wherein during discharging, thermal storage medium from the intermediate storage tank is combined with thermal storage medium from the hot storage tank before passing through some part of the heat exchanger, or some proportion of thermal storage medium from the hot storage tank is split off and directed to the intermediate storage tank after passing through some other part of the heat exchanger. 8. The method according to claim 6 , wherein thermal storage medium from the cold storage tank is pumped through the heat exchanger into the hot storage tank, and partially into the intermediate storage tank. 9. The method according to claim 6 , wherein thermal storage medium from the hot storage tank and the intermediate storage tank are pumped through the heat exchanger into the cold storage tank. 10. The method according to claim 6 , wherein a rate of flow of the thermal storage medium through the heat exchanger is modified by varying the input rate of flow of thermal storage medium to the intermediate storage tank, and by varying the output rate of flow of thermal storage medium from the intermediate storage tank. 11. The method according to claim 10 , wherein the step of modifying the rate of flow comprises minimizing the temperature difference between the working fluid and the thermal storage medium during charging and discharging cycles. 12. The method according to claim 6 , further comprising: connecting at least one further intermediate storage tank via the heat exchanger, and further dividing or joining the stream of the thermal storage medium for each further intermediate storage tank. 13. The method according to claim 6 , wherein the charging and/or the discharging cycle are performed transcritically. 14. The method according to claim 6 , wherein the energy storage system is a thermoelectric energy storage system, and wherein electricity is converted into heat and stored in the charging cycle. 15. A method for storing and retrieving energy in an energy storage system, comprising: charging the system in a charging cycle, wherein the charging comprises: the thermal storage medium circulates between a hot storage tank, an intermediate storage tank and a cold storage tank connected together via a heat exchanger, wherein all the thermal storage medium from the cold storage tank is routed to the intermediate storage tank after a first heat exchanger section of the heat exchanger, and then a portion of the thermal storage medium is piped out of the intermediate storage tank and fed into a second heat exchanger section of the heat exchanger and subsequently to the hot storage tank; and discharging the system by heating a working fluid in a working fluid circuit with heat from the thermal storage medium, and expanding the working fluid through a thermodynamic machine.