An object of the present invention is to provide a flue gas purifying device that can efficiently decrease nitrogen oxides in flue gas. This object is solved by including: an exhaust pipe that guides flue gas discharged from a burning appliance; a urea-water injecting unit that injects urea water in
An object of the present invention is to provide a flue gas purifying device that can efficiently decrease nitrogen oxides in flue gas. This object is solved by including: an exhaust pipe that guides flue gas discharged from a burning appliance; a urea-water injecting unit that injects urea water into the exhaust pipe; a catalytic unit arranged on a downstream side to a position where urea water is injected in a flow direction of flue gas and having a urea SCR catalyst; a first ammonia-concentration measuring unit that measures a concentration of ammonia in flue gas at a measurement position in a region where the catalytic unit is arranged; a second ammonia-concentration measuring unit arranged on a downstream side to the catalytic unit in a flow direction of the flue gas, to measure a concentration of ammonia in the flue gas having passed through the urea SCR catalyst; and a control unit that controls injection of urea water by the urea-water injecting unit based on measurement results acquired by the first and second ammonia-concentration measuring units.
대표청구항▼
1. A flue gas purifying device that reduces nitrogen oxides contained in flue gas discharged from a burning appliance, the device comprising: a flue-gas flow path that guides flue gas discharged from the burning appliance;a urea-water injecting unit that injects urea water into the flue-gas flow pat
1. A flue gas purifying device that reduces nitrogen oxides contained in flue gas discharged from a burning appliance, the device comprising: a flue-gas flow path that guides flue gas discharged from the burning appliance;a urea-water injecting unit that injects urea water into the flue-gas flow path;a catalytic unit that includes a urea SCR catalyst that promotes a reaction between ammonia produced from injected urea water and the nitrogen oxides, and a support mechanism arranged inside of the flue-gas flow path to support the urea SCR catalyst in the flue-gas flow path, and that is arranged on a downstream side to a position where the urea water is injected in a flow direction of the flue gas;a first ammonia-concentration measuring unit that measures a concentration of ammonia in flue gas at a measurement position in a region where the catalytic unit is arranged;a second ammonia-concentration measuring unit arranged downstream of the first ammonia-concentration measuring unit in a flow direction of the flue gas, to measure a concentration of ammonia in the flue gas; anda control unit that controls injection of urea water by the urea-water injecting unit based on measurement results acquired by the first and second ammonia-concentration measuring units,wherein the control unit is configured to:set a target concentration of the second ammonia-concentration measuring unit, which is not updated;update a target concentration of the first ammonia-concentration measuring unit based on the measurement result acquired by the second ammonia-concentration measuring unit after comparing the measurement result acquired by the second ammonia-concentration measuring unit to the target concentration of the second ammonia-concentration measuring unit; andcontrol the injection of urea water by the urea-water injecting unit so that a measurement result acquired by the first ammonia-concentration measuring unit becomes the target concentration of the first ammonia-concentration measuring unit. 2. The flue gas purifying device according to claim 1, wherein each of the first ammonia-concentration measuring unit and the second ammonia-concentration measuring unit comprises: a measuring unit body that outputs a laser beam;an optical fiber that is connected to the measuring unit body, and through which the laser beam output from the measuring unit body is passed;a measuring unit that is connected to the optical fiber, and includes a route through which the laser beam output from the optical fiber passes and an output unit that outputs the laser beam passed through the route; anda receive unit that receives the laser beam output from the output unit, converts the laser beam received to a light receiving signal and output the light receiving signal to the measuring unit body,wherein the measuring unit body receives the light receiving signal output from the receive unit and calculates an ammonia concentration by comparing an intensity of the laser beam output from the measuring unit body with an intensity calculated from the light receiving signal received. 3. The flue gas purifying device according to claim 1, wherein the target concentration of the first ammonia-concentration measuring unit is calculated using a value by dividing the measurement result acquired by the second ammonia-concentration measuring unit by the target concentration of the second ammonia-concentration measuring unit. 4. The flue gas purifying device according to claim 1, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)/(C2(t, NH3)/C20(NH3)+0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, where C1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit; andC20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit,whereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1(NH3), andfrom next C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3). 5. The flue gas purifying device according to claim 1, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)-n×(C2(t, NH3)—C20(NH3)×0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, where C1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit;C20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit, andn is an arbitrary constant,whereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1(NH3), andfrom next, C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3). 6. The flue gas purifying device according to claim 1, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)×sin(t/T)/(C2(t, NH3)/C20(NH3)+0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, where C1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit;C20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit,T is an arbitrary cycle, andt is timewhereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1(NH3), andfrom next, C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3). 7. The flue gas purifying device according to claim 1, further comprising a pretreatment nitrogen-oxide-concentration measuring unit arranged upstream of the catalytic unit in the flow direction of the flue gas to measure a concentration of nitrogen oxide in flue gas flowing into the catalytic unit, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)×(C0(t, NOx)/C00(NOx))/C2(t, NH3)/C20(NH3)+0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, whereC1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit,C20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit,C0(t, NOx) is a measurement result acquired by the pretreatment nitrogen-oxide-concentration measuring unit, andC00(NOx) is a reference concentration at a measurement position of the pretreatment nitrogen-oxide-concentration measuring unit,whereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1(NH3),from next C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3) andC00(NOx) is preset as an initial value. 8. The flue gas purifying device according to claim 1, further comprising a post-treatment nitrogen-oxide-concentration measuring unit arranged on a downstream side to the catalytic unit in a flow direction of the flue gas to measure a concentration of nitrogen oxide in flue gas having passed through the urea SCR catalyst, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)×(C2(t, NOx)/C20(NOx))/C2(t, NH3)/C20(NH3)+0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, whereC1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit;C20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit,C2(t, NOx) is a measurement result acquired by the post-treatment nitrogen-oxide-concentration measuring unit, andC20(NOx) is a reference concentration at a measurement position of the post-treatment nitrogen-oxide-concentration measuring unit,whereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1 (NH3), andfrom next, C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3). 9. The flue gas purifying device according to claim 1, further comprising a pretreatment nitrogen-oxide-concentration measuring unit arranged on an upstream side to the catalytic unit in a flow direction of the flue gas to measure a concentration of nitrogen oxide in flue gas flowing into the catalytic unit, and a post-treatment nitrogen-oxide-concentration measuring unit arranged on a downstream side to the catalytic unit in the flow direction of the flue gas to measure a concentration of nitrogen oxides in flue gas having passed through the urea SCR catalyst, wherein the control unit controls injection of urea water by the urea-water injecting unit, such that C1(NH3)′ is C1(NH3)′═C1(NH3)×(1/η)/(C2(t, NH3)/C20(NH3)+0.5) and the measurement result acquired by the first ammonia-concentration measuring unit becomes C1(NH3)′, whereC1(NH3) is a calculation basis of the target concentration at a measurement position of the first ammonia-concentration unit,C1(NH3)′ is the target concentration at the measurement position of the first ammonia-concentration measuring unit,C2(t, NH3) is the measurement result acquired by the second ammonia-concentration measuring unit,C20(NH3) is the target concentration at a measurement position of the second ammonia-concentration measuring unit,C0(t, NOx) is a measurement result acquired by the pretreatment nitrogen-oxide-concentration measuring unit,C2(t, NOx) is a measurement result acquired by the post-treatment nitrogen-oxide-concentration measuring unit, andη is (C0(t, NOx)-C2(t, NOx))/C0(t, NOx),whereinat startup, an initial target concentration C10(NH3), which is a preset value, is assigned as C1(NH3), andfrom next, C1(NH3)′ calculated by a calculation immediately before, is assigned as C1(NH3). 10. The flue gas purifying device according to claim 1, wherein the second ammonia-concentration measuring unit is provided in the catalytic unit so as to measure an ammonia concentration in a region where the catalytic unit is arranged. 11. The flue gas purifying device according to claim 1, wherein the second ammonia-concentration measuring unit is provided downstream of the catalytic unit in the flow direction of the flue gas so as to measure an ammonia concentration of the flue gas passing through the urea SCR catalyst.
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이 특허에 인용된 특허 (2)
Gladden, John R., Enhanced ammonia feed control for selective catalytic reduction.
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