Thermoelectric energy storage system and an associated method thereof

The invention claimed is: 1. A thermoelectric energy storage system comprising: a first refrigeration system comprising a first heat exchanger, a first compressor, a second heat exchanger, and a first expander, wherein the first heat exchanger is disposed upstream relative to the first compressor and downstream relative to the first expander, and wherein the second heat exchanger is disposed downstream relative to the first compressor and upstream relative to the first expander; a power system comprising a third heat exchanger, a second compressor, a fourth heat exchanger, a fifth heat exchanger, and a second expander, wherein the third heat exchanger is disposed downstream relative to the second compressor and upstream relative to the fourth heat exchanger, wherein the fourth heat exchanger is disposed upstream relative to the second expander and coupled to a heat source, and wherein the fifth heat exchanger is disposed downstream relative to the second expander and upstream relative to the second compressor; a first thermal storage tank coupled to the first heat exchanger and the fifth heat exchanger; and a second thermal storage unit coupled to the first refrigeration system and the power system, wherein the second thermal storage unit comprises at least one of a hot storage tank, an intermediate tank, and a cold storage tank. 2. The thermoelectric energy storage system of claim 1 , wherein the first thermal storage tank and the first heat exchanger are integrated to each other. 3. The thermoelectric energy storage system of claim 1 , wherein the first thermal storage tank and the fifth heat exchanger are integrated to each other. 4. The thermoelectric energy storage system of claim 1 , wherein the second thermal storage unit comprises the hot storage tank, the intermediate storage tank, and the cold storage tank, wherein the hot storage tank and the intermediate storage tank are coupled to one another via a first circulation path extending through the first refrigeration system, and wherein the hot storage tank, the intermediate storage tank, and the cold storage tank are further coupled to one another via a second circulation path extending through the power system. 5. The thermoelectric energy storage system of claim 1 , further comprising a second refrigeration system coupled to the first refrigeration system and the second thermal storage unit. 6. The thermoelectric energy storage system of claim 5 , wherein the second thermal storage unit comprises the hot storage tank, the intermediate storage tank, and the cold storage tank, coupled to each other via a first circulation path extending through the first refrigeration system and second refrigeration system, and wherein the hot storage tank, the intermediate storage tank, and the cold storage tank are further coupled to each other via a second circulation path extending through the power system. 7. The thermoelectric energy storage system of claim 1 , wherein the power system further comprises a split channel extending from the second compressor to the fourth heat exchanger bypassing the third heat exchanger. 8. The thermoelectric energy storage system of claim 7 , wherein the fourth heat exchanger comprises a first heater and a second heater disposed downstream relative to the first heater, wherein the split channel is coupled to the second heater bypassing the first heater. 9. The thermoelectric energy storage system of claim 8 , wherein the power system further comprises: a third heater disposed downstream relative to the second expander; and a third expander disposed downstream relative to the third heater and upstream relative to the fifth heat exchanger. 10. A thermoelectric energy storage system comprising: a first refrigeration system; a second refrigeration system; a thermal storage comprising a cold storage tank, an intermediate storage tank, and a hot storage tank, wherein the cold storage tank, the intermediate storage tank, and the hot storage tank are coupled to each other via first circulation paths extending through the first refrigeration system and the second refrigeration system; and a power system, wherein the hot storage tank, the intermediate storage tank, and the cold storage tank are coupled to each other via a second circulation path extending through the power system. 11. A method comprising: circulating a first fluid in a first refrigeration system to generate first thermal energy; circulating a second fluid from a first thermal storage tank in heat exchange relationship with the first fluid to store a first quantity of the first thermal energy in the second fluid; circulating a third fluid from a second thermal storage unit in heat exchange relationship with the first fluid to store a second quantity of the first thermal energy in the third fluid, the second thermal storage unit including at least one of a hot storage tank, an intermediate tank, and a cold storage tank; circulating a fourth fluid in a power system; circulating the second fluid from the first thermal storage tank in heat exchange relationship with the fourth fluid circulated in the power system, to retrieve the first quantity of the first thermal energy stored in the second fluid; circulating the third fluid from the second thermal storage unit in heat exchange relationship with the fourth fluid circulated in the power system, to retrieve the second quantity of the first thermal energy stored in the third fluid; providing second thermal energy to the fourth fluid circulated in the power system, using a heat source, to increase temperature of the fourth fluid; and expanding the fourth fluid in the power system for generating electric power. 12. The method of claim 11 , wherein circulating the third fluid from the second thermal storage unit in heat exchange relationship with the first fluid comprises circulating the third fluid from the intermediate storage tank of the second thermal storage unit in heat exchange relationship with the first fluid to store the second quantity of the first thermal energy in the third fluid in the hot storage tank of the second thermal storage unit. 13. The method of claim 12 , further comprising circulating a fifth fluid in a second refrigeration system in heat exchange relationship with the first fluid circulated in the first refrigeration system to transfer a third quantity of the first thermal energy of the fifth fluid. 14. The method of claim 13 , wherein circulating the fifth fluid in the second refrigeration system further comprises circulating the third fluid from the cold storage tank of the second thermal storage unit in heat exchange relationship with the fifth fluid to store the third quantity of the first thermal energy of the third fluid in the intermediate storage tank. 15. The method of claim 14 , wherein circulating the third fluid from the second thermal storage unit in heat exchange relationship with the fourth fluid comprises circulating the third fluid from the hot storage tank in heat exchange relationship with the fourth fluid to retrieve the second quantity of the first thermal energy stored in the third fluid, in the intermediate storage tank. 16. The method of claim 15 , wherein circulating the third fluid from the second thermal storage unit in heat exchange relationship with the fourth fluid further comprises circulating the third fluid from the intermediate storage tank in heat exchange relationship with the fourth fluid to retrieve the third quantity of the first thermal energy stored in the third fluid, in the cold storage tank. 17. The method of claim 11 ,