Stacked type falling film evaporator, zero liquid discharge system comprising the same, and zero liquid discharging method using the same

What is claimed is: 1. A stacked type falling film evaporator, comprising: a first falling film evaporator and the second falling film evaporator stacked in such a manner that wastewater passes through the first falling film evaporator and the second falling film evaporator in order; a first pipe, connected between a liquid storage tank of the first falling film evaporator and a vapor inlet of the second falling film evaporator, that collects vapor generated from the wastewater in the first falling film evaporator and supplies the collected vapor to the second falling film evaporator; a second pipe, connected between a liquid storage tank of the second falling film evaporator and a vapor inlet of the first falling film evaporator, that collects vapor generated from the wastewater in the second falling film evaporator and supplies the collected vapor to the first falling film evaporator; a vapor recompressor that compresses the vapor collected in the second pipe before the vapor is supplied to the first falling film evaporator; and a circulation pump that supplies concentrated wastewater exiting the second falling film evaporator to an upstream space of the first falling film evaporator. 2. The stacked type falling film evaporator according to claim 1 , wherein the vapor recompressor is a thermal vapor recompressor. 3. The stacked type falling film evaporator according to claim 1 , further comprising a second vapor recompressor that compresses the vapor collected in the first pipe before the vapor is supplied to the second falling film evaporator. 4. The stacked type falling film evaporator according to claim 1 , wherein each of the first and second falling film evaporators includes: a housing having a wastewater inlet disposed at a top portion thereof and the liquid storage tank that stores concentrated wastewater disposed at bottom portion thereof; a flow uniformity device that separates an upstream space from a heat exchange space comprising a plurality of evaporation tubes; the plurality of evaporation tubes of a length of about 5 m to 10 m passing through the flow uniformity device such that opening portions of ends of the tubes are disposed in the upstream space; the vapor inlet that introduces vapor into the heat exchange space in order to heat the outer walls of the evaporation tubes; and a condensate water recovery aperture that recovers condensate water which is introduced into the heat exchange space and concentrated through heat exchange with the evaporation tubes, such that the wastewater introduced through the wastewater inlet flows into the upstream space and is evaporated while flowing in the form of a falling film along inner walls of the evaporation tubes. 5. A zero liquid discharge system, comprising: a stacked type falling film evaporator; a wastewater pretreatment device in which introduced wastewater passes pretreatment devices in consecutive order and is passed to the stacked type falling film evaporator; a crystallization device to concentrate, by high-temperature evaporation, wastewater which was evaporated and concentrated while passing through the stacked type falling film evaporator; a condenser adapted to condense vapor, generated from the wastewater and separated by the crystallization device, and recover condensate water; and a sludge treatment device for treating sludge, generated from the wastewater and separated by the crystallization device, into a discardable form through centrifugation; wherein the stacked type falling film evaporator includes: a first falling film evaporator and the second falling film evaporator stacked in such a manner that wastewater passes through the first falling film evaporator and the second falling film evaporator in order; a first pipe, connected between a liquid storage tank of the first falling film evaporator and a vapor inlet of the second falling film evaporator, that collects vapor generated from the wastewater in the first falling film evaporator and supplies the collected vapor to the second falling film evaporator; a second pipe, connected between a liquid storage tank of the second falling film evaporator and a vapor inlet of the first falling film evaporator, that collects vapor generated from the wastewater in the second falling film evaporator and supplies the collected vapor to the first falling film evaporator; and a vapor recompressor that compresses the vapor collected in the second pipe before the vapor is supplied to the first falling film evaporator. 6. The zero liquid discharge system according to claim 5 , wherein the vapor recompressor is a thermal vapor recompressor. 7. The zero liquid discharge system according to claim 5 , further comprising a second vapor recompressor that compresses the vapor collected in the first pipe before the vapor is supplied to the second falling film evaporator. 8. The zero liquid discharge system according to claim 5 , further comprising a circulation pump that supplies concentrated wastewater exiting the second falling film evaporator to an upstream space of the first falling film evaporator. 9. The zero liquid discharge system according to claim 5 , wherein the wastewater pretreatment device is at least one selected from the group consisting of a caustic soda treatment tank, an alum treatment tank, a polymer treatment tank, and a settling separation tank. 10. The zero liquid discharge system according to claim 5 , wherein the crystallizing device is a forced circulation evaporator. 11. The zero liquid discharge system according to claim 5 , further comprising a reverse osmosis separator disposed at an upstream side of the stacked type falling film evaporator. 12. The zero liquid discharge system according to claim 5 , wherein the stacked type falling film evaporator is adapted to evaporate wastewater introduced through a wastewater inlet, flowing into an upstream space, and flowing in the form of a falling film along inner walls of evaporation tubes. 13. The stacked type falling film evaporator according to claim 5 , wherein each of the first and second falling film evaporators includes: a housing having a wastewater inlet disposed at a top portion thereof and the liquid storage tank that stores concentrated wastewater disposed at a bottom portion thereof; a flow uniformity device that separates an upstream space from a heat exchange space comprising a plurality of evaporation tubes; the plurality of evaporation tubes of a length of about 5 m to 10 m passing through the flow uniformity device such that opening portions of ends of the tubes are disposed in the upstream space; the vapor inlet that introduces vapor into the heat exchange space in order to heat the outer walls of the evaporation tubes; a vapor outlet that extracts vapor having undergone heat exchange in the heat exchange space and provides the extracted vapor to the crystallization device; and a condensate water recovery aperture that recovers condensate water which is introduced into the heat exchange space and concentrated through heat exchange with the evaporation tubes, such that the wastewater introduced through the wastewater inlet flows into the upstream space and is evaporated while flowing in the form of a falling film along inner walls of the evaporation tubes.