Wastewater processing systems for power plants and other industrial sources
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C02F-001/16
B01D-001/06
C02F-001/04
C02F-001/10
C02F-009/00
C02F-001/38
C02F-001/74
C02F-101/10
C02F-103/02
출원번호
US-0762020
(2013-02-07)
등록번호
US-9199861
(2015-12-01)
발명자
/ 주소
Duesel, Jr., Bernard F.
Clerkin, Craig
출원인 / 주소
HEARTLAND TECHNOLOGY PARTNERS LLC
대리인 / 주소
Marshall, Gerstein & Borun LLP
인용정보
피인용 횟수 :
6인용 특허 :
196
초록▼
Methods, systems, and/or apparatuses for treating wastewater produced at a thermoelectric power plant, other industrial plants, and/or other industrial sources are disclosed. The wastewater is directed through a wastewater concentrator including a direct contact adiabatic concentration system. A str
Methods, systems, and/or apparatuses for treating wastewater produced at a thermoelectric power plant, other industrial plants, and/or other industrial sources are disclosed. The wastewater is directed through a wastewater concentrator including a direct contact adiabatic concentration system. A stream of hot feed gases is directed through the wastewater concentrator. The wastewater concentrator mixes the hot feed gases directly with the wastewater and evaporates water vapor from the wastewater. The wastewater concentrator separates the water vapor from remaining concentrated wastewater. A contained air-water interface liquid evaporator may be arranged to pre-process the wastewater before being treated by the wastewater concentrator.
대표청구항▼
1. A wastewater treatment system for a thermoelectric power plant, the system comprising: a first wastewater concentrator operatively connected to a wastewater holding reservoir, the first wastewater concentrator implementing a contained air-water interface liquid evaporator, the air-water interface
1. A wastewater treatment system for a thermoelectric power plant, the system comprising: a first wastewater concentrator operatively connected to a wastewater holding reservoir, the first wastewater concentrator implementing a contained air-water interface liquid evaporator, the air-water interface liquid evaporator including a body defining a partially enclosed vessel that is disposed at least partially within the wastewater holding reservoir, a top surface of the wastewater in the wastewater holding reservoir being located between a top portion of the vessel and a bottom portion of the vessel, the vessel defining an interior space that is confined by the walls of the vessel, the interior space including an upper chamber, a middle chamber, and a lower chamber that are in fluid communication with one another, and an opening through a submerged portion of the vessel, the opening allowing wastewater to enter into the bottom portion of the interior space of the vessel;a second wastewater concentrator operatively connected to the wastewater holding reservoir, the second wastewater concentrator implementing a direct contact adiabatic wastewater concentrator system, the second wastewater concentrator comprising a direct contact evaporative section and a gas-liquid separator, the direct contact evaporative section including a venturi section;a stream of wastewater generated in a thermoelectric power plant operatively connected to the wastewater holding reservoir; anda stream of hot feed gases operatively connected to the second wastewater concentrator to supply feed gases to the direct contact evaporative section simultaneously as the stream of wastewater;wherein an open bottom of the lower chamber defines the opening and in the operative position the top surface of the wastewater extends through the middle chamber, the lower chamber and a lower portion of the middle chamber being disposed beneath the top surface of the wastewater and the upper chamber and an upper portion of the middle chamber being disposed above the top surface of the wastewater,wherein the direct contact evaporative section mixes the hot feed gases directly with the wastewater and evaporates water from the wastewater to form water vapor and concentrated wastewater, andwherein the gas-liquid separator separates the water vapor from the concentrated wastewater and exhausts discharge gases from the gas-liquid separator, including the water vapor and some or all of the feed gases. 2. The wastewater treatment system of claim 1, wherein the stream of wastewater comprises at least one of flue gas desulfurization purge water, cooling tower purge water, service water, power plant leachate, and power plant holding reservoir water. 3. The wastewater treatment system of claim 2, wherein the stream of hot feed gases is heated with waste heat from within the thermoelectric power plant. 4. The wastewater treatment system of claim 3, wherein the hot feed gases comprise hot flue gases from a hydrocarbon-fired combustion heater. 5. The wastewater treatment system of claim 1 wherein the gas-liquid separator comprises at least one of a cross flow gas-liquid separator and a cyclonic gas-liquid separator operatively connected to the direct contact evaporative section. 6. A method of processing wastewater from a thermoelectric power plant with a first wastewater concentrator and a second wastewater concentrator, wherein the first wastewater concentrator includes a contained air-water interface liquid evaporator including a body defining a partially enclosed vessel that is disposed at least partially within a wastewater holding reservoir, a top surface of wastewater in the wastewater holding reservoir being located between a top portion of the vessel and a bottom portion of the vessel, the vessel defining an interior space that is confined by walls of the vessel, the interior space including an upper chamber, a middle chamber, and a lower chamber that are in fluid communication with one another, and an opening through a submerged portion of the vessel, the opening allowing wastewater to enter into the bottom portion of the interior space of the vessel; the second wastewater concentrator includes a direct contact adiabatic wastewater concentrator system having a venturi section; the power plant includes a source of wastewater and a source hot feed gases, the method comprising: receiving wastewater though the opening into the bottom portion of the first wastewater concentrator;evaporating a portion of the wastewater in the first wastewater concentrator, thereby separating the wastewater into a vapor portion and an unevaporated liquid portion;receiving a stream of the hot feed gases into the second wastewater concentrator;receiving feed wastewater including the unevaporated liquid portion into the second wastewater concentrator;mixing the hot feed gases directly with the unevaporated liquid portion in the venturi section of the second wastewater concentrator to evaporate water vapor from the unevaporated liquid portion to form a concentrated wastewater;separating the water vapor from the concentrated wastewater in the second wastewater concentrator to form a concentrated discharge brine and discharge gases; andexhausting the discharge gases from the second wastewater concentrator,wherein an open bottom of the lower chamber defines the opening and in the operative position the top surface of the wastewater extends through the middle chamber, the lower chamber and a lower portion of the middle chamber being disposed beneath the top surface of the wastewater and the upper chamber and an upper portion of the middle chamber being disposed above the top surface of the wastewater. 7. The method of claim 6, wherein the wastewater comprises at least one of flue gas desulfurization purge water, cooling tower purge water, and service water. 8. The method of claim 6, wherein the hot feed gases comprise hot flue gases discharged from a hydrocarbon-fired combustion heater. 9. The method of claim 6, further comprising the step of post-processing the discharge brine. 10. The method of claim 9, wherein the step of post-processing includes the steps of removing solids from liquids in the discharge brine in a solid-liquid separator and/or further concentration of the discharge brine. 11. The method of claim 6, further comprising the step of pre-processing the stream of hot feed gases to separate particulates from the hot feed gases prior to receiving the hot feed gases into the wastewater concentrator. 12. The method of claim 6, further comprising the steps: reheating the discharge gases above the acid-gas condensation temperature of the discharge gases; andreturning the discharge gases to an exhaust system of the thermoelectric power plant. 13. A thermoelectric power plant comprising: a thermoelectric generator for producing electricity;a first wastewater concentrator operatively connected to a wastewater holding reservoir, the first wastewater concentrator comprising a contained air-water interface liquid evaporator, the air-water interface liquid evaporator including a body defining a partially enclosed vessel that is disposed at least partially within the wastewater holding reservoir, a top surface of the wastewater in the wastewater holding reservoir being located between a top portion of the vessel and a bottom portion of the vessel, the vessel defining an interior space that is confined by the walls of the vessel, the interior space including an upper chamber, a middle chamber, and a lower chamber that are in fluid communication with one another, and an opening through a submerged portion of the vessel, the opening allowing wastewater to enter into the bottom portion of the interior space of the vessel;a second wastewater concentrator operatively connected to the wastewater holding reservoir, the second wastewater concentrator comprising a direct contact adiabatic wastewater concentrator system including a venturi section;a source of wastewater operatively connected to the wastewater holding reservoir to supply feed wastewater to the wastewater holding reservoir; anda source of hot feed gases operatively connected to the second wastewater concentrator to supply the hot feed gases to the second wastewater concentrator;wherein an open bottom of the lower chamber defines the opening and in the operative position the top surface of the wastewater extends through the middle chamber, the lower chamber and a lower portion of the middle chamber being disposed beneath the top surface of the wastewater and the upper chamber and an upper portion of the middle chamber being disposed above the top surface of the wastewater, andwherein the second wastewater concentrator mixes the hot feed gases directly with the feed wastewater, evaporates water vapor from the feed wastewater, separates the water vapor from the feed wastewater thereby forming discharge brine and discharge gases, exhausts the discharge gases to atmosphere and/or another process component, and provides the discharge brine in a form suitable for further processing and/or disposal separate from the discharge gases. 14. The thermoelectric power plant of claim 13, wherein the thermoelectric generator comprises a boiler for generating steam to turn a turbine operatively connected to an electric generator, and wherein the source of wastewater comprises a flue gas desulfurization system operatively connected to the boiler to receive flue gas from the boiler, wherein the flue gas desulfurization system removes sulfur from the flue gas and generates flue gas desulfurization purge water containing contaminants, and wherein the wastewater concentrator is operatively connected to the flue gas desulfurization system to receive feed wastewater containing at least some of the desulfurization purge water. 15. The thermoelectric power plant of claim 14, wherein the boiler comprises a hydrocarbon-fired combustion heater. 16. The thermoelectric power plant of claim 14, wherein the source of hot feed gases comprises hot flue gases from the boiler. 17. The thermoelectric power plant of claim 13, wherein the source of wastewater comprises at least one of cooling tower purge water and service water. 18. The thermoelectric power plant of claim 13, wherein the thermoelectric generator comprises a gas turbine and the source of hot feed gases comprises waste heat generated by the gas turbine. 19. The wastewater treatment system of claim 1, wherein the upper chamber forms a tortuous exhaust path from the middle chamber to at least one exhaust port, the at last one exhaust port directing exhaust gases downward, toward the top surface of the wastewater.
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