Redox flow battery using electrolyte concentration gradient and operation method thereof

The invention claimed is: 1. A redox flow battery, comprising: a catholyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of a catholyte received therein, wherein the partition plate controls a flow path of catholyte in order to form the concentration gradient of the catholyte; an anolyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of an anolyte received therein, wherein the partition plate controls a flow path of anolyte in order to form the concentration gradient of the anolyte; and a stack for charging and discharging power by using the concentration gradient of the catholyte and the concentration gradient of the anolyte supplied from the catholyte tank and the anolyte tank. 2. The redox flow battery of claim 1 , wherein the partition plate of the catholyte tank is provided in a horizontal direction. 3. The redox flow battery of claim 1 , wherein the partition plate of the anolyte tank is provided in a horizontal direction. 4. The redox flow battery of claim 1 , wherein the stack includes at least one battery cell, and the battery cell comprises: an ion exchange membrane; and a cathode and an anode, with the ion exchange membrane positioned therebetween. 5. A redox flow battery, comprising: a first catholyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of a catholyte received therein; a second catholyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of a catholyte received therein, wherein the partition plate of the first catholyte tank and the partition plate of the second catholyte tank control a flow path of catholyte in order to form the concentration gradient of the catholyte of the first and second catholyte tanks respectively; a first anolyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of an anolyte received therein; a second anolyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a partition plate for forming a concentration gradient of an anolyte received therein, wherein the partition plate of the first anolyte tank and the partition plate of the second anolyte tank control a flow path of anolyte in order to form the concentration gradient of the anolyte of the first and second anolyte tanks respectively; and a stack for charging and discharging power by using the concentration gradient of the catholyte and the concentration gradient of the anolyte supplied from the first and second catholyte tanks and the first and second anolyte tanks. 6. The redox flow battery of claim 5 , wherein the partition plate of each of the first and second catholyte tanks is provided in a horizontal direction. 7. The redox flow battery of claim 5 , wherein the first catholyte tank and the second catholyte tank are connected to each other via a connection pipe through which the catholyte received therein moves. 8. The redox flow battery of claim 5 , wherein the partition plate of each of the first and second anolyte tanks is provided in a horizontal direction. 9. The redox flow battery of claim 5 , wherein the first anolyte tank and the second anolyte tank are connected to each other via a connection pipe through which the anolyte received therein moves. 10. The redox flow battery of claim 5 , wherein the stack includes at least one battery cell, and the battery cell comprises: an ion exchange membrane; and a cathode and an anode, with the ion exchange membrane positioned therebetween. 11. A redox flow battery, comprising: a first catholyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a barrier rib provided in a vertical direction to form a concentration gradient of a catholyte received therein, wherein the barrier rib controls a flow path of catholyte in order to form the concentration gradient of the catholyte; a first anolyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a barrier rib provided in a vertical direction to form a concentration gradient of an anolyte received therein, wherein the barrier rib controls a flow path of anolyte in order to form the concentration gradient of the anolyte; and a stack for charging and discharging power by using the concentration gradient of the catholyte and the concentration gradient of the anolyte supplied from the catholyte tank and the anolyte tank. 12. The redox flow battery of claim 11 , wherein a plurality of barrier ribs is provided in the catholyte tank. 13. The redox flow battery of claim 11 , wherein a plurality of barrier ribs is provided in the anolyte tank. 14. The redox flow battery of claim 11 , wherein the stack includes at least one battery cell, and the battery cell comprises: an ion exchange membrane; and a cathode and an anode, with the ion exchange membrane positioned therebetween. 15. The redox flow battery of claim 11 , wherein the redox flow battery further comprises: a second catholyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a barrier rib provided in a vertical direction to form a concentration gradient of a catholyte received therein, wherein the barrier rib of the first catholyte tank and the barrier rib of the second catholyte tank control a flow path of catholyte in order to form the concentration gradient of the catholyte of the first and second catholyte tanks respectively; a second anolyte tank having an electrolyte inlet at a top thereof and an electrolyte outlet at a bottom thereof and having a barrier rib provided in a vertical direction to form a concentration gradient of an anolyte received therein, wherein the barrier rib of the first anolyte tank and the barrier rib of the second anolyte tank control a flow path of anolyte in order to form the concentration gradient of the anolyte of the first and second anolyte tanks respectively; and the stack for charging and discharging power by using the concentration gradient of the catholyte and the concentration gradient of the anolyte supplied from the first and second catholyte tanks and the first and second anolyte tanks. 16. The redox flow battery of claim 15 , wherein a plurality of barrier ribs is provided in each of the first and second catholyte tanks. 17. The redox flow battery of claim 15 , wherein the first catholyte tank and the second catholyte tank are connected to each other via a connection pipe through which the catholyte received therein moves. 18. The redox flow battery of claim 15 , wherein a plurality of barrier ribs is provided in each of the first and second anolyte tanks. 19. The redox flow battery of claim 15 , wherein the first anolyte tank and the second anolyte tank are connected to each other via a connection pipe through which the anolyte received therein moves. 20. The redox flow battery of claim 15 , wherein the stack includes at least one battery cell, and the battery cell comprises: an ion exchange membrane; and