Cyclone type liquid-vapor separator and forced circulation type evaporator using the same

What is claimed is: 1. A cyclone type liquid-vapor separator for separating vapors from treatment liquid introduced thereinto, discharging the separated vapors to the upper portion thereof, and discharging concentrated treatment liquid to the lower portion thereof, the liquid-vapor separator comprising: a chamber comprising: an internal space wherein the treatment liquid introduced into the internal space is depressurized and evaporated; a vapor outlet formed on a top of the chamber and through which vapors generated through the evaporation is discharged; and a concentrated liquid outlet formed on a bottom of the chamber and through which the concentrated treatment liquid is discharged; an inlet part coupled to a side surface of the chamber in a direction of a tangent line of an inner peripheral surface of the chamber between the vapor outlet and the concentrated liquid outlet, the treatment liquid introduced into the chamber being turned in the form of vortexes along the inner peripheral surface of the chamber, the inlet part comprising a guide part configured to guide a rotation of the treatment liquid introduced through the inlet part, the guide part comprising a pipe passing through the inlet part; and at least one partition wall that is disposed above the tangent line of the inlet part and below the vapor outlet of the internal space of the chamber and protrudes from the inner peripheral wall of the chamber to block large mist droplets contained in the vapors from moving upward toward the vapor outlet while allowing small mist droplets to move upward together with the vapors through an opening in the at least one partition wall, wherein the pipe of the inlet part is passed through the chamber to be extendedly inserted into the chamber and includes a top portion that is open such that evaporation of the treatment liquid occurs in an extendedly inserted area of the inlet part. 2. The liquid-vapor separator according to claim 1 , wherein the at least one partition wall inclinedly protrudes upwardly from the inner peripheral surface of the chamber at an angle of 90 to 180°. 3. The liquid-vapor separator according to claim 1 , wherein the guide part is disposed extendedly by a section along the inner peripheral surface of the chamber from a connected portion to the side surface of the chamber. 4. The liquid-vapor separator according to claim 3 , wherein the guide part is separate from the inlet part and protrudes from the inner peripheral surface of the chamber. 5. The liquid-vapor separator according to claim 1 , wherein the pipe extendedly inserted into the chamber is fastened to the inner peripheral surface of the chamber along the inner peripheral surface of the chamber. 6. The liquid-vapor separator according to claim 1 , further comprising an interior demister disposed above or under the at least one partition wall in the chamber and having a mesh type plate member configured to face the opening in the at least one partition wall in order to block the mist that is contained in the vapors discharged upwardly and is not removed by the at least one partition wall. 7. The liquid-vapor separator according to claim 1 , further comprising an exterior demister disposed separately to an exterior of the chamber in such a manner as to be connected to an end of the vapor outlet to introduce the discharged vapors from the vapor outlet thereinto and having a chevron type member disposed in a moving path of the introduced vapors to block the mist contained in the vapors. 8. The liquid-vapor separator according to claim 1 , wherein the inner peripheral wall of the chamber is tapered toward the concentrated liquid outlet formed on the bottom of the chamber to reduce a turning radius of the treatment liquid. 9. The liquid-vapor separator according to claim 8 , further comprising a vortex breaking member disposed on an area wherein the concentrated liquid outlet is formed on the bottom of the chamber so as to break the vortexes generated from the treatment liquid. 10. The liquid-vapor separator according to claim 9 , wherein the vortex breaking member comprises at least two plate members crossing each other in such a manner as to be parallel to a discharge direction of the concentrated treatment liquid. 11. A forced circulation type evaporator for evaporating and concentrating treatment liquid, comprising: a heat exchanger configured to heat the treatment liquid introduced into the heat exchanger by a heat medium introduced from an exterior of the heat exchanger; and a liquid-vapor separator configured to separate vapors from the heated treatment liquid from the heat exchanger, configured to discharge the separated vapors to an upper portion of the liquid-vapor separator, and configured to discharge concentrated treatment liquid to a lower portion of the liquid-vapor separator, wherein the liquid-vapor separator comprises: a chamber comprising: an internal space wherein the treatment liquid introduced into the internal space is depressurized and evaporated; a vapor outlet formed on a top of the chamber and through which vapors generated through the evaporation is discharged; and a concentrated liquid outlet formed on a bottom of the chamber and through which the concentrated treatment liquid is discharged; an inlet part coupled to a side surface of the chamber in a direction of a tangent line of an inner peripheral surface of the chamber between the vapor outlet and the concentrated liquid outlet, the treatment liquid introduced into the chamber being turned in the form of vortexes along the inner peripheral surface of the chamber, the inlet part comprising a guide part configured to guide a rotation of the treatment liquid introduced through the inlet part, the guide part comprising a pipe passing through the inlet part; and at least one partition wall that is disposed above the tangent line of the inlet part and below the vapor outlet of the internal space of the chamber and protrudes from the inner peripheral wall of the chamber to block large mist droplets contained in the vapors from moving upward toward the vapor outlet while allowing small mist droplets to move upward together with the vapors through an opening in the at least one partition wall, wherein the pipe of the inlet part is passed through the chamber to be extendedly inserted into the chamber and includes a top portion that is open such that evaporation of the treatment liquid occurs in an extendedly inserted area of the inlet part. 12. The forced circulation type evaporator according to claim 11 , further comprising a suction pump connected to a rear end of the liquid-vapor separator and configured to provide power for discharging the concentrated treatment liquid from the liquid-vapor separator. 13. The forced circulation type evaporator according to claim 11 , wherein the at least one partition wall inclinedly protrudes upwardly from the inner peripheral surface of the chamber at an angle of 90 to 180°. 14. The forced circulation type evaporator according to claim 11 , wherein the guide part is disposed extendedly by a section along the inner peripheral surface of the chamber from a connected portion to the side surface of the chamber. 15. The forced circulation type evaporator according to claim 14 , wherein the guide part is separate from the inlet part and protrudes from the inner peripheral surface of the chamber. 16. The forced circulation type evaporator according to claim 11 , wherein the pipe extendedly inserted into the chamber is fastened to the inner peripheral surface of the chamber along the inner peripheral surface of