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1. An electrolytic cell for an FT-CDI, comprising:
an anode electrolyte receiving plate including an anode electrolyte receiving part in which an anode electrolytic solution is received, an anode electrolyte injection port injected with the anode electrolytic solution from the outside, an anode electrolyte discharge port through which the anode electrolytic solution is discharged to the outside, a concentrate injection port injected with a concentrate from the outside, and a bead injection port injected with a bead from the outside; a cathode electrolyte receiving plate including a cathode electrolyte receiving part in which a cathode electrolytic solution is received, a cathode electrolyte injection port injected with the cathode electrolytic solution, a cathode electrolyte discharge port through which the cathode electrolytic solution is discharged, a concentrate discharge port through which the concentrate is discharged to the outside, and a bead discharge port through which the bead is discharged to the outside; and at least one bead receiving plate including a bead inlet into which the bead injected from the bead injection port is injected, a bead receiving part receiving the bead injected from the bead inlet, a bead outlet through which the bead is discharged from the bead receiving part, an upper concentrate passing hole through which the concentrate injected from the concentrate injection port passes, and a lower concentrate passing hole through which the concentrate passes, wherein the bead inlet and the bead outlet of the bead receiving plate are each formed in a diagonal direction to each other; wherein the bead receiving plate further comprises:
a first bead temporary receiving part disposed at a lower portion of the bead inlet and a plurality of bead inflow channels disposed at a lower portion of the first bead temporary receiving part, anda second bead temporary receiving part disposed at an upper portion of the bead outlet and a plurality of bead outflow channels disposed at an upper portion of the second bead temporary receiving part; wherein the bead inlet is formed at one side of and at substantially the same height as the first bead temporary receiving part; wherein the bead outlet is formed at one side of and at substantially the same height as the second bead temporary receiving part; wherein the upper concentrate passing hole is formed at a location within a horizontal boundary defined by a left side and a right side of the bead receiving part and within a vertical boundary defined by an upper end of the bead receiving part and an upper end of the first bead temporary receiving part; wherein the lower concentrate passing hole is formed at a location within a horizontal boundary defined by the left side and the right side of the bead receiving part and a vertical boundary defined by a lower end of the bead receiving part and a lower end of the second bead temporary receiving part; wherein the width of the bead temporary receiving parts is smaller than that of the bead receiving part; at least one concentrate receiving plate including a concentrate inlet into which the concentrate injected from the concentrate injection port is injected, a concentrate receiving part receiving the concentrate injected from the concentrate inlet, a concentrate outlet through which the concentrate is discharged from the concentrate receiving part, an upper bead passing hole through which the bead injected from the bead injection port passes, and a lower bead passing hole through which the bead passes, wherein the concentrate inlet and the concentrate outlet of the concentrate receiving plate are each formed in a diagonal direction to each other; wherein the concentrate receiving plate comprises:
a first concentrate temporary receiving part disposed at a lower portion of the concentrate inlet and a plurality of concentrate inflow channels disposed at a lower portion of the first concentrate temporary receiving part, anda second concentrate temporary receiving part disposed at an upper portion of the concentrate outlet and a plurality of concentrate outflow channels disposed at an upper portion of the second concentrate temporary receiving part; wherein the concentrate inlet is formed at one end of and at substantially the same height as the first concentrate temporary receiving part; wherein the concentrate outlet is formed at one end of and at substantially the same height as the second concentrate temporary receiving part; wherein the upper bead passing hole is formed at a location within a horizontal boundary defined by a left side and a right side of the concentrate receiving part and within a vertical boundary defined by an upper end of the concentrate receiving part and an upper end of the first concentrate temporary receiving part; wherein the lower bead passing hole is formed at a location within a horizontal boundary defined by the left side and the right side of the concentrate receiving part and a vertical boundary defined by a lower end of the concentrate receiving part and a lower end of the second concentrate temporary receiving part; a diaphragm inserted between the bead receiving plate and the concentrate receiving plate wherein the bead inlet is penetrated so as to communicate with an upper bead passing hole that is disposed on the stacked concentrate receiving plate and the bead outlet is penetrated to communicate with the lower bead passing hole that is disposed on the stacked concentrate receiving plate; wherein the concentrate inlet is penetrated so as to communicate with the upper concentrate passing hole disposed on the stacked bead receiving plate and the concentrate outlet is penetrated so as to communicate with the lower concentrate passing hole disposed on the stacked bead receiving plate. |
