Controlled spectrum ultraviolet radiation pollution control process
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01D-053/56
B01D-053/62
B01D-053/68
B01D-053/70
B01D-053/72
B01D-053/46
B01D-053/74
B01J-019/12
출원번호
US-0566831
(2005-08-11)
등록번호
US-7498009
(2009-03-03)
국제출원번호
PCT/US05/028637
(2005-08-11)
§371/§102 date
20060201
(20060201)
국제공개번호
WO07/061401
(2007-05-31)
발명자
/ 주소
Leach,James T.
Fraim,Michael Lee
출원인 / 주소
Dana UV, Inc.
대리인 / 주소
Haefliger,William W.
인용정보
피인용 횟수 :
76인용 특허 :
58
초록▼
A method for reducing or substantially eliminating oxides of nitrogen from an effluent gas stream, that includes providing a source of ultraviolet radiation with a precise wavelength, adding ammonia or an ammonia based reagent to the effluent stream, upstream of the ultraviolet radiation source, con
A method for reducing or substantially eliminating oxides of nitrogen from an effluent gas stream, that includes providing a source of ultraviolet radiation with a precise wavelength, adding ammonia or an ammonia based reagent to the effluent stream, upstream of the ultraviolet radiation source, controllably operating the ultraviolet radiation source to irradiate the effluent stream flowing in the duct and substantially reducing or eliminating oxides of nitrogen by promotion a reaction of ammonia with the oxides of nitrogen to produce N2 and H2O, and also thereby destroying any surplus ammonia. This process can also be modified to oxidize carbon monoxide and VOC's to CO2 and H2O.
대표청구항▼
We claim: 1. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method
We claim: 1. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and controlling the rate of ammonia or ammonia based reagent added to said stream including measuring upstream NOx and downstream NOx and/or NH3 slip. 2. The method of claim 1 including providing an excimer or ion laser with rasterization of effluent gas with beam or beams in the UV spectrum between 172 nm and 220 nm, and optionally using an ArF laser at 193 nm output as an optimal excimer laser for the SUVR process, with optional laser output in visible or near infrared spectrum, frequency doublers or quadruples being used to reduce the wavelength to the useful UV spectrum. 3. The method of claim 1 including employing electrostatic force to reduce or prevent particle buildup on tubular or planer emitter surfaces and to encourage particle collection on an impact shield, the electrostatic force being created by a high frequency, voltage source connected to the emitter surface while an impact shield is used as the ground plane. 4. The method of claim 1 wherein an amidogen generator is provided using as an ultraviolet source, a laser with spectrum out put between 172 nm and 220 nm, or a corona discharge using a metal electrode and a dielectric surface or two dielectric surfaces, or a packed dielectric bed discharge, or an electron beam. 5. The method of claim 1 including providing low pressure mercury vapor lamps operating as said source of ultraviolet radiation. 6. The method of claim 1 wherein the source is provided in the form of elongated, spaced apart irradiation means extending in the duct, and transversely thereof whereby the effluent stream passes over said spaced apart means. 7. The method of claim 6 wherein the irradiation means include multiple tubes located generally centrally in the duct. 8. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and including effecting dissociation of virtually all of the ammonia and producing a purified effluent stream that contains an insignificant amount of residual ammonia. 9. The method of claim 8 including controlling the rate of ammonia or ammonia based reagent added to said stream including measuring upstream NOx and downstream NOx and/or NH3 slip. 10. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and including controlling the volumetric flux of UV radiation in response to measuring/sampling upstream NOx and downstream NOx and NH3 slip and in response to measuring actual UV flux in the reaction zone. 11. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and including employing a two stage retrofit or technology transition system for reducing NOx levels, where the first stage is a conventional NSCR, SCR or SHR system and the second stage is a SUVR system with ultraviolet elements acting to polish the ammonia and NOx slip to below 1 ppm. 12. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and wherein the radiation source is provided in the form of elongated tubular emitters spaced apart and located in an orientation with respect to the velocity vector of the effluent stream, whereby the pollutant gases flowing around the emitters are treated uniformly and completely. 13. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and wherein a radiation source is provided in the form of one or more LED arrays producing the effective wavelength and intensity of radiation. 14. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and wherein the tubular emitters are located around the perimeter of a duct passing said flow stream. 15. The method of controlling the wavelength and the volumetric flux intensity of an SUVR process to reduce or substantially eliminate unburned hydrocarbons or volatile organic compounds, VOC's, (CxHyOz) including carbon monoxide (CO) and halogenated VOC's (CxHy(F,Cl,Br,I)z) from effluent gas streams that contain oxygen gas (O2) and water vapor (H2O) by reacting these species with oxygen based radicals (O*, O2-, HO2*, OH*) to form to carbon dioxide (CO2) and water vapor (H2O), the method including: a) providing a source of ultraviolet radiation with output between 172 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) providing a source of electrons with energies of 4 eV or greater, derived from a corona discharge or electron beam, c) causing said ultraviolet radiation, or electron source, to achieve intensity flux sufficient to dissociate the water molecule (H2O) and the oxygen molecule (O2) to oxygen based radicals (O*, O2-, HO2*, OH*) and to excite VOC molecules (CxHyOz) to expedite the oxidation reaction and dissociate halogenated VOC's (F,Cl,Br,I) to form halogen acids, d) and including removing halogen acids (HF, HCl, HBr, or HI) and sulfuric acid (H2SO4) generated in the oxidation process down stream by converting them to an ammonium salt or salts, the method using wet or dry electrostatic precipitation, or by absorbing the halogen acid in an aqueous solution containing a base metal (Na, Ca, Mg, K, etc.) or by absorption on a filter impregnated with activated carbon and/or calcium or magnesium oxide. 16. The method of claim 15 including operating a two stage system for reducing high levels of VOC's by factor greater than 100, wherein the first stage includes injection of ozone, or ozonated air, or oxygen based radicals (O*, O2-, HO2*, OH*) from a generator using water vapor and an oxygen source, and the second stage uses ultraviolet radiation or electron source to achieve intensity flux to dissociate the water molecules (H2O) and the residual oxygen molecules (O2) to oxygen based radicals (O*, O2-, HO2*, OH*) and to excite remaining VOC molecules (CxHyOz) to expedite the oxidation reaction and dissociate halogenated VOC's (F,Cl,Br,I) to form halogen acids. 17. The method of claim 16 including controlling the volumetric concentration of injected oxygen based radicals by measuring/sampling upstream VOC's and downstream oxidation products with mid-infrared spectroscopy or full range UV-B to near infrared spectroscopy and by measuring second stage UV flux in the reaction zone and oxygen and/or water vapor content. 18. The method of claim 15 including controlling the volumetric flux of UV radiation or electron bombardment by measuring/sampling upstream VOC's and downstream oxidation products with mid-infrared spectroscopy or full range UV-B to near infrared spectroscopy and by measuring actual UV flux in the reaction zone and oxygen and/or water vapor content. 19. The method of claim 15 wherein the CO or VOC's are controlled in an initial process stage followed by a NOx reduction stage that includes the injection of ammonia-based reagent, mixing of the reagent in the effluent gas stream and photo-chemical reduction of NOx. 20. The method of claim 19 of a two stage SUVR process whereby the NOx is controlled and residual ammonia effectively destroyed in an initial process stage followed by a VOC destruction stage to effectively purify the effluent gas stream. 21. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and including embodying the UV source in a mobile device that is self contained and includes a circulation fan and particulate matter filter, for use in areas where people are present and where the VOC's may present a potential health or safety hazard, and wherein the ultraviolet source optionally has two zones; the first zone for making oxygen based free radicals and ozone, and the second stage for ozone and chlorine gas destruction. 22. The method of claim 21 including employing a downstream particle filter impregnated with activated carbon and/or calcium oxide to absorb halogen or sulfuric acids. 23. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) including providing an electrostatic precipitator and operating said source of ultraviolet radiation in series with said precipitator. 24. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and wherein said source of ultraviolet radiation comprises multiple UV bulbs, which are spaced apart in the path of said effluent stream, and providing chevron shaped elements in said path directly upstream of said bulbs to protect the bulbs from erosion from effluent particles impact. 25. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) and wherein said source of ultraviolet radiation comprises one or more UV bulbs, and including the step of flowing particle free gas adjacent the bulb or bulbs as a protection from erosion due to effluent particle impact. 26. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 am associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) including converting ammonia to amidogen radical or radically for injection into the effluent stream. 27. The method of claim 26 wherein said converting step is one of the following: i) operation of an ultraviolet lamp, ii) operation of LEDs, iii) dielectric barrier discharge between electrodes, iv) provision and operation of a dielectric pack bed electrode to provide surface area for absorbed ammonia reactions, v) provision and operation of an electron beam generator to subject ammonia and water to electron beam processing to create amidogen radical and hydrogen gas. 28. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) including providing a combustion process stack, wherein said effluent stream flows, during stream irradiation. 29. The SUVR method for reducing or substantially eliminating oxides of nitrogen (NOx) from an effluent gas stream between 300-800�� K and that contains oxygen gas (O2) by reacting NOx with the amidogen radical (NH2*) to form to harmless nitrogen gas (N2) and water vapor (H2O), the method including the steps: a) providing a source of ultraviolet radiation with output between 180 nm and 220 nm associated with a duct containing the effluent stream, or streams, b) mixing ammonia or an ammonia-based reagent with said stream, upstream of said ultraviolet radiation source so that the variance is within +15%/-5% of stoichiometric concentration, c) causing said ultraviolet radiation source to irradiate the stream with effective wavelength band and intensity flux sufficient to dissociate the ammonia molecules (NH3) to the amidogen radicals (NH2*) and to excite and dissociate NOx molecules to promote the (NO+NH2*) to (N2+H2O) reduction reaction, d) including removing one of the following from the effluent stream prior to said irradiation: x1) particulate x2) aerosols x3) VOCs. 30. Apparatus for reducing or substantially eliminating oxides of nitrogen from a hot effluent gas stream, that comprises: a) a duct and a source of ultraviolet radiation associated with said duct passing said effluent stream, b) means for adding ammonia or amidogen radicals to said stream, upstream of said ultraviolet radiation source, and c) means for controllably operating said ultraviolet radiation source to irradiate said stream flowing in the duct, to effect reduction or substantial elimination of said oxides of nitrogen by promoting, reaction of ammonia with said oxides of nitrogen, to produce N2 and H2O flowing in the stream, d) and wherein said source of ultraviolet radiation comprises UV emitting means extending in generally clustered relation. 31. The apparatus of claim 30 wherein said source of ultraviolet radiation comprises UV emitting tubes extending in generally clustered relation. 32. The apparatus of claim 31 wherein said tubes extend in parallel relation to an X-direction; the tubes being spaced apart in a Y-direction; and the duct extending in a Z-direction, where said directions are the X, Y and Z directions in a rectangular co-ordinate system. 33. The apparatus of claim 31 wherein said tubes are arrayed in staggered relation presented toward the oncoming stream. 34. The apparatus of claim 31 wherein the duct is locally enlarged to receive said tubes, for enhanced radiation transmission to the stream. 35. The apparatus of claim 30 wherein said a), b) and c) comprise a first stage apparatus, and also including a second stage apparatus having a'), b') and c'), corresponding to said a), b) and c). 36. The apparatus of claim 30 wherein said source of amidogen radicals includes steam reforming means. 37. The apparatus of claim 30 wherein UV generator means is located in the duct to provide about 254 nanometers and about 185 nanometers transverse radiation path lengths relative to the duct wall. 38. The apparatus of claim 37 wherein the duct wall provides a reflective inner surface for said about 254 nanometer radiation. 39. The apparatus of claim 30 wherein said radiation source is one of the following types: i) UV generator, ii) LED generator, iii) dielectric barrier between two electrodes, iv) dielectric pack electrode means, v) electron beam. 40. A method for reducing or substantially eliminating oxides of nitrogen from a hot effluent gas stream, that includes a) providing a clustered source of ultraviolet radiation less than about 220 nanometers and associated with a duct passing said effluent stream, b) adding ammonia to said stream, upstream of said ultraviolet radiation source, c) controlling the rate of ammonia addition to said stream and controllably operating said ultraviolet radiation source to irradiate said stream flowing in the duct, to effect reduction or substantial elimination of said oxides of nitrogen by promoting reaction of ammonia with said oxides of nitrogen, to produce N2 and H2O flowing in the stream.
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Borchert, Bradford David; Trout, Jesse Edwin; Simmons, Scott Robert; Valeev, Almaz; Slobodyanskiy, Ilya Aleksandrovich; Sidko, Igor Petrovich; Ginesin, Leonid Yul'evich, Systems and methods for high volumetric oxidant flow in gas turbine engine with exhaust gas recirculation.
Vorel, Aaron Lavene; Thatcher, Jonathan Carl, Systems and methods of estimating a combustion equivalence ratio in a gas turbine with exhaust gas recirculation.
Thatcher, Jonathan Carl; Slobodyanskiy, Ilya Aleksandrovich; Vorel, Aaron Lavene, Systems and methods to respond to grid overfrequency events for a stoichiometric exhaust recirculation gas turbine.
Allen, Jonathan Kay; Borchert, Bradford David; Trout, Jesse Edwin; Slobodyanskiy, Ilya Aleksandrovich; Valeev, Almaz; Sidko, Igor Petrovich; Subbota, Andrey Pavlovich, Turbine system with exhaust gas recirculation, separation and extraction.
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