JP4673146B2 - Denitration device to prevent clogging of urea water injection nozzle - Google Patents

Description

  The present invention relates to a denitration apparatus that removes nitrogen oxides by injecting urea water into combustion exhaust gas, and relates to a denitration apparatus that performs control to prevent clogging of a urea water injection nozzle.

  As described in Japanese Patent Application Laid-Open No. 2003-62427, a prime mover such as a gas turbine or an engine and a waste heat boiler that recovers heat from combustion exhaust gas generated by the prime mover are installed, and heat is used together with power. In order to improve the efficiency of the entire apparatus, it is performed. In order to remove nitrogen oxides contained in the combustion exhaust gas, urea water is injected into the combustion exhaust gas to reduce and remove the nitrogen oxides.

  The urea water injection nozzle that injects urea water toward the combustion exhaust gas is installed in an exhaust gas passage that connects between the prime mover and the exhaust heat boiler. The urea water injection nozzle is installed at a place that receives the heat of the combustion exhaust gas. Since the combustion exhaust gas in the exhaust gas passage is at a high temperature, the urea water injection nozzle is heated by the combustion exhaust gas. When the urea water injection nozzle is injecting urea water, the urea water injection nozzle can be cooled by the urea water that is continuously supplied, so that the urea water injection nozzle can be prevented from becoming high temperature. However, when the urea water injection is stopped, the urea water injection nozzle cannot be cooled by the urea water, so the nozzle portion may become hot. When the temperature of the urea water injection nozzle rises, moisture may evaporate from the urea water remaining in the urea water injection nozzle, and urea may precipitate to clog the urea water injection nozzle.

Therefore, when the denitration operation is stopped, the urea water injection nozzle is cleaned and then the cleaning liquid (water) is supplied to the urea water injection nozzle to clean the inside of the urea water injection nozzle. In addition, after the cleaning with the cleaning liquid, purge air is supplied into the urea water injection nozzle, and the cleaning liquid remaining in the urea water injection nozzle is blown off. However, even if it did in this way, urea precipitated in the urea water injection nozzle, and sometimes the urea water injection nozzle was clogged.
JP 2003-62427 A

  The problem to be solved by the present invention is that in a denitration device that reduces and removes nitrogen oxides in combustion exhaust gas by injecting urea water from a urea water injection nozzle, urea is precipitated in the urea water injection nozzle. This is to prevent the water injection nozzle from clogging.

  According to the first aspect of the present invention, a urea water injection nozzle is installed in an exhaust gas passage through which combustion exhaust gas passes, urea water is injected from the urea water injection nozzle toward the combustion exhaust gas, and nitrogen oxides in the combustion exhaust gas are reduced. A denitration apparatus that performs reduction and removal, and in addition to urea water, a cleaning liquid can be supplied to the urea water injection nozzle, and when the denitration operation is stopped, the cleaning liquid is supplied to the urea water injection nozzle. In the denitration device that cleans the inside of the urea water injection nozzle, the cleaning liquid supply to the urea water injection nozzle is started at the stage where the urea water supply is continued during the denitration operation stop operation. Control is performed to stop the supply of urea water with a delay.

  In the invention according to claim 2, a urea water injection nozzle is installed in the exhaust gas passage through which the combustion exhaust gas passes, the urea water is injected from the urea water injection nozzle toward the combustion exhaust gas, and nitrogen oxides in the combustion exhaust gas are reduced. In the denitration apparatus that performs reduction and removal, air can be supplied into the urea water injection nozzle, and the liquid in the urea water injection nozzle can be supplied by supplying air to the urea water injection nozzle when the denitration operation is stopped. The air supply to the urea water injection nozzle is stopped when the urea water injection nozzle is replaced with air, but after that, while the denitration operation is stopped, the air supply to the urea water injection nozzle is periodically controlled. It is characterized by performing.

  In the invention according to claim 3, a urea water injection nozzle is installed in the exhaust gas passage through which the combustion exhaust gas passes, the urea water is injected from the urea water injection nozzle toward the combustion exhaust gas, and nitrogen oxides in the combustion exhaust gas are reduced. A denitration device that performs reduction and removal, and in addition to urea water, cleaning liquid can be supplied to the urea water injection nozzle, and when the denitration operation is stopped, the cleaning liquid is supplied to the urea water injection nozzle. In the denitration device that cleans the urea water injection nozzle at the same time, it is also possible to supply air into the urea water injection nozzle, and when the denitration operation is stopped, the cleaning of the urea water injection nozzle with the cleaning liquid is terminated and the cleaning liquid supply is stopped After that, the air supply to the urea water injection nozzle is not performed immediately, and the control to start the air supply to the urea water injection nozzle after the pressure in the urea water supply path for supplying the urea water and the cleaning liquid is released. And performing.

  In the invention according to claim 4, a urea water injection nozzle is installed in the exhaust gas passage for passing the combustion exhaust gas, the urea water is injected from the urea water injection nozzle toward the combustion exhaust gas, and nitrogen oxides in the combustion exhaust gas are reduced. In a denitration apparatus that performs reduction and removal, a discharge amount checker is attached to a urea water supply path for supplying urea water and cleaning liquid, and the urea water supply state is detected by the discharge amount checker at the time of urea water injection. When it is detected that there is an abnormality in the supply state, the denitration operation stop operation is immediately started.

  As the first effect of the present invention, at the time of denitration operation stop operation, the supply of the urea water is started at a stage where the supply of the urea water is continued and delayed from the start of the supply of the cleaning liquid. By performing the control to stop the operation, the amount of urea water in the urea water injection nozzle is not temporarily reduced when the denitration operation is stopped. Therefore, the urea water injection nozzle is not heated during the denitration operation stop operation and the urea water injection nozzle does not become high temperature, and the water evaporates from the urea water in the urea water injection nozzle during the denitration operation stop operation, so that the urea water injection nozzle It is possible to prevent clogging from occurring.

  As a second effect, even when the prime mover is stopped, control is performed to periodically supply air to the urea water injection nozzle while the denitration operation is stopped, and the urea water injection nozzle is cooled, so that the residual heat of the prime mover The urea water injection nozzle is not heated to become high temperature. Therefore, even if urea remains in the urea water injection nozzle after the denitration operation is stopped, urea does not precipitate in the urea water injection nozzle, and the urea water injection nozzle is clogged while the denitration operation is stopped. Can be prevented.

  As a third effect, at the time of denitrification operation stop operation, the cleaning of the urea water injection nozzle with the cleaning liquid is finished, and after the supply of the cleaning liquid is stopped, the urea water injection nozzle is not supplied immediately but the urea water or the cleaning liquid is supplied. After the pressure in the urea water supply path is released, control is performed to start air supply to the urea water injection nozzle, and the pressure in the urea water supply path is released before replacing the inside of the urea water injection nozzle with air. Thus, after the supply of air to the urea water injection nozzle is stopped, water that may contain urea from the urea water supply path does not overflow to the urea water injection nozzle. For this reason, it is possible to prevent clogging of the urea water injection nozzle due to evaporation of water from the urea water in the urea water injection nozzle while the denitration operation is stopped.

  As a fourth effect, when an abnormality occurs in the urea water supply, the denitration operation stop operation is immediately started and the urea water supply to the urea water injection nozzle is stopped, so that the urea water to the urea water injection nozzle is stopped. By reducing the supply amount, the amount of urea water in the urea water injection nozzle is reduced, and it is possible to prevent the urea water injection nozzle from being clogged due to evaporation of water from the urea water in the urea water injection nozzle.

  In addition, the above effects may be combined to prevent clogging of the urea water injection nozzle in all cases. If the denitration device can identify the cause of clogging of the urea water injection nozzle, the cause and response Only the necessary effect may be obtained.

  An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a flow chart showing an example of the flow of the entire denitration apparatus for carrying out the present invention, and FIG. 2 is a time chart showing the cleaning state of the urea water injection nozzle at the time of denitration operation stop operation in one embodiment of the present invention. FIG. 3 is a time chart showing a case where a urea water supply abnormality occurs during the denitration operation in another embodiment of the present invention, FIG. 4 is a time chart at the time of denitration operation stop operation in the conventional example, and FIG. It is the time chart which showed the case where the urea water supply abnormality occurred during the denitration operation in the conventional example.

  Since a high-temperature combustion exhaust gas is generated from a prime mover (not shown) such as a gas turbine that is a source of combustion exhaust gas, an exhaust heat boiler (not shown) that recovers heat from the combustion exhaust gas generated by the prime mover is installed. . The prime mover and the exhaust heat boiler are connected by the exhaust gas passage 3 so that the combustion exhaust gas flows through the exhaust gas passage 3, and the urea water injection nozzle 4 is installed in the exhaust gas passage 3. Since combustion exhaust gas contains harmful nitrogen oxides, urea water is injected into the combustion exhaust gas and detoxified by decomposing nitrogen oxides into nitrogen and water using the reducing action of ammonia.

  The urea water is likely to be crystallized and deposited, and if the crystals are precipitated in the urea water injection nozzle 4, the urea water injection nozzle 4 is clogged. Therefore, it is necessary to prevent the urea water injection nozzle 4 from clogging. Therefore, not only the urea water but also the cleaning liquid and the purge air can be supplied to the urea water injection nozzle 4. A urea water supply path 1 and an air supply path 2 are connected to the urea water injection nozzle 4, urea water and water (cleaning liquid) are supplied from the urea water supply path 1, and purge air is supplied from the air supply path 2. Like to do. On the upstream side of the urea water supply path 1, a urea water supply pump 5 and a water supply pump 6 are installed in parallel, and a discharge amount checker 9 is provided in the middle.

  Further, an atomizing air line 12 is installed outside the urea water injection nozzle 4 to increase the diffusion effect of urea water by injecting atomized air at the time of urea water injection. An air supply pump 7 is provided on the upstream side of the air supply path 2, and the air supply path 2 is branched in the middle. The air supply path 2 includes the urea water injection nozzle 4 and the atomized air line 12 around the urea water injection nozzle 4. Connect to. A purge air control valve 11 is provided in the air supply path 2 connected to the urea water injection nozzle 4, and an atomizing air control valve 10 is provided in the air supply path 2 connected to the atomizing air line 12. The urea water supply pump 5, the water supply pump 6, the air supply pump 7, the atomizing air control valve 10, the purge air control valve 11, and the discharge amount checker 9 are connected to the control device 8 that controls the operation of the denitration device. The control device 8 controls the operation of each device.

  Operation control of the urea water supply pump 5, the water supply pump 6, and the air supply pump 7 in the case of performing an operation for stopping the denitration operation will be described with reference to FIG. In the time chart of FIG. 2, the prime mover is in operation and starts from a state of performing denitration operation. When performing the denitration operation, the control device 8 supplies urea water to the urea water injection nozzle 4 by operating the urea water supply pump 5. The urea water injection nozzle 4 atomizes urea water and injects it into the exhaust gas, and decomposes nitrogen oxides in the exhaust gas into nitrogen and water. At this time, since a predetermined amount of urea water is continuously supplied to the urea water injection nozzle 4, the amount of liquid in the urea water injection nozzle 4 is constant. The urea water injection nozzle 4 receives the heat of the combustion exhaust gas. However, since the urea water injection nozzle 4 is cooled by the urea water sent one after another, the urea water temperature in the urea water injection nozzle 4 is significantly increased. In other words, the water does not evaporate from the urea water in the urea water injection nozzle 4 to precipitate crystals.

  At this time, the air supply pump 7 is operated, the atomizing air control valve 10 is opened, and the purge air control valve 11 is closed. The air from the air supply pump 7 enters the atomizing air line 12 through the air supply path 2 and diffuses the urea water injected from the urea water injection nozzle 4.

  When the prime mover is to be stopped at the point A, the control device 8 performs control to stop the denitration operation in response to information on the prime mover stop. First, the control device 8 starts the operation of the water supply pump 6 while the urea water supply pump 5 is operating. When the water supply pump 6 is operated, the supply of the cleaning liquid to the urea water injection nozzle 4 in addition to the urea water is started. At this time, since the water supplied from the water supply pump 6 is added to the urea water injection nozzle 4 in addition to the urea water supplied from the urea water supply pump 5, the amount of liquid supplied to the urea water injection nozzle Will increase.

  When the control device 8 reaches point B after a predetermined time (for example, about 30 seconds) has elapsed since the start of the operation of the water supply pump 6, the control device 8 stops the operation of the urea water supply pump 5. When the operation of the urea water supply pump 5 stops, the urea water supply to the urea water injection nozzle 4 is lost, so the amount of liquid supplied to the urea water injection nozzle 4 decreases. However, at this time, since the water supply pump 6 is operated to supply the cleaning liquid to the urea water injection nozzle 4, the amount of liquid in the urea water injection nozzle 4 does not decrease too much, and the temperature of the urea water injection nozzle 4 rises. Does not occur. Cleaning of the urea water injection nozzle 4 is continued until the point C is reached, and after sufficient cleaning, the water supply pump 6 is stopped and the cleaning with the cleaning liquid is completed.

  Thereafter, the control device 8 opens a predetermined time to wait for the pressure in the urea water supply path 1 to decrease, and when the point D is reached, opens the purge air control valve 11. By opening the purge air control valve 11, the air from the air supply pump 7 enters the urea water injection nozzle 4, and by supplying air to the urea water injection nozzle 4, Blow off any remaining liquid. At point E, the control device 8 closes the purge air control valve 11 to stop the supply of purge air and stop the denitration operation. However, the control device 8 detects the elapsed time from the purge air supply stop and supplies the purge air every time the elapsed time reaches a predetermined time even if the prime mover is stopped. If the predetermined time is reached at the point F, the purge air control valve 11 is opened from the point F, and air is supplied to the urea water injection nozzle 4 for a predetermined time.

  Even when the prime mover is stopped, the air supply to the urea water injection nozzle 4 is performed even if the prime mover is stopped, the prime mover has heat, and the urea water injection nozzle is radiated by heat radiation from the stopped prime mover. Since 4 may be heated, the urea water injection nozzle 4 is cooled. Therefore, air supply is only necessary for cooling. For example, every 15 minutes, the air supply pump 7 is operated for 1 minute. In addition, the cooling of the urea water injection nozzle 4 performed every predetermined time may be stopped if the urea water injection nozzle 4 is not heated, and is stopped when the time enough for the prime mover to sufficiently cool is elapsed. Further, the regular cooling while the prime mover is stopped may be performed based on the temperature of the urea water injection nozzle 4 portion.

  FIG. 4 is a time chart in a conventional example for comparison. In FIG. 4, the operation of the prime mover is stopped at the point a, and the control device 8 stops the urea water supply pump 5 and operates the water supply pump 6 immediately after detecting the stop of the prime mover. In this case, when the urea water supply pump 5 is stopped, the urea water supply amount to the urea water injection nozzle 4 rapidly decreases, whereas the cleaning liquid supply amount to the urea water injection nozzle 4 by the start of operation of the water supply pump 6 is Since it increases only slowly, the amount of liquid at the urea water injection nozzle 4 temporarily decreases. When the amount of liquid in the urea water injection nozzle 4 decreases, it is necessary to take in heat transmitted to the urea water injection nozzle 4 with a small amount of liquid in the urea water injection nozzle 4. For this reason, the urea water is heated to a high temperature, and crystals may be precipitated by evaporation of the water. Since the precipitated crystal is fixed in the urea water injection nozzle 4, the urea water injection nozzle 4 is clogged by repeating the precipitation and fixation every time the denitration operation is stopped.

  In FIG. 4, the water supply pump 6 is stopped at the point c and the atomizing air control valve 10 is opened to supply the purge air to the urea water injection nozzle 4. When the purge air control valve 11 is opened simultaneously with the stop of the water supply pump 6, the urea water supply path portion is covered with the purge air. Immediately after the water supply pump 6 is stopped, the pressure of the washing water is high in the urea water supply path 1, and when the lid is covered with the purge air, the pressure is kept high in the urea water supply path. Is done. In this case, when the purge air supply is subsequently stopped and the pressure due to air disappears, the wash water overflows from the high-pressure urea water supply path to the urea water injection nozzle, and a small amount of the wash water flows into the urea water injection nozzle. Accumulate in 4. If urea remains in the cleaning water in the urea water injection nozzle 4, the water evaporates from the urea water injection nozzle 4 to precipitate urea, and the urea water injection nozzle 4 may be clogged with the precipitated urea. .

  Therefore, in the present invention, the purge air control valve 11 is opened after a predetermined time for releasing the pressure in the urea water supply path 1 from the stop of the water supply pump 6. By allowing time from the stop of the water supply pump 6 to the supply of purge air, overflow from the urea water supply path due to the pressure in the urea water supply path is performed first, and then purge air is supplied. Therefore, in the present invention, it is possible to prevent the washing water from overflowing into the urea water injection nozzle 4 after the supply of the purge air is stopped.

  In FIG. 4, the urea water injection nozzle 4 is not cooled after the denitration operation is stopped. Even if the prime mover is stopped, if the temperature of the prime mover is high, the urea water injection nozzle 4 may be heated by residual heat. In the case of FIG. 4 in which the urea water injection nozzle 4 is not cooled while the prime mover is stopped, there is nothing to cool the urea water injection nozzle 4 after the air supply pump 7 is stopped at the point e. The temperature of the urea water injection nozzle 4 may rise. If the temperature of the urea water injection nozzle 4 rises with the urea water remaining in the urea water injection nozzle 4, the water evaporates from the urea water and crystallizes to clog the inside of the urea water injection nozzle 4. There was a problem. However, by implementing the present invention in which the urea water injection nozzle 4 is periodically cooled, the problem of urea precipitation during the denitration operation stop can be solved.

  FIG. 3 relates to the present invention, and shows a time chart when the urea water supply pump 5 becomes abnormal during operation of the prime mover and the urea water cannot be supplied. When the urea water supply pump 5 cannot supply urea water to the urea water injection nozzle 4 due to air leakage, abnormalities in the urea water supply pump, or clogging of the urea water injection nozzle, it is not dealt with immediately. Then, moisture evaporates from the urea water remaining in the urea water injection nozzle 4 and the urea water injection nozzle 4 is blocked by the deposited urea.

  Abnormal supply of urea water to the urea water injection nozzle 4 is detected based on a signal from the discharge amount checker 9 provided in the urea water supply path 1. When the control device 8 detects that the urea water supply signal is not output from the discharge amount checker 9 even though the operation command is output to the urea water supply pump 5, the urea water supply is performed. It is determined that the pump is abnormal (urea water discharge abnormality). When the control device 8 determines that an abnormality has occurred in the urea water supply, the prime mover performs a denitration operation stop operation even during operation. The operation for stopping the denitration operation itself is the same as the operation for stopping the motor operation. When the controller 8 detects the occurrence of an abnormality at the point H, it operates the water supply pump 6 to discharge the urea water in the urea water injection nozzle 4 with the wash water. Thereafter, the operation of the water supply pump 6 is stopped at the point I, the purge air control valve 11 is opened at the point J, and air is supplied to the urea water injection nozzle 4 to discharge the wash water in the urea water injection nozzle 4. . When urea water injection is stopped due to abnormal urea water discharge, the prime mover continues to operate, and high-temperature combustion exhaust gas continues to flow in the exhaust gas passage 3, so that air supply to the urea water injection nozzle 4 is not performed. The urea water injection nozzle 4 is cooled by continuing. Thereafter, if the operation of the prime mover is stopped at the point K, there is no reason to continue cooling the urea water injection nozzle 4. In this case, only air is periodically supplied to the urea water injection nozzle 4 as described above. Then, cooling is performed to prevent heating of the urea water injection nozzle 4 due to residual heat.

  FIG. 5 is a time chart in a conventional example for comparison. Also in FIG. 4, the urea water supply is stopped due to the abnormality of the urea water supply pump 5. However, in this case, the abnormality in the urea water supply cannot be detected, and the water supply pump 6 is not operated until the point k at which the operation of the prime mover is stopped. Therefore, the temperature of the urea water injection nozzle 4 rises. . Therefore, the urea water in the urea water injection nozzle 4 evaporates and urea is deposited in the urea water injection nozzle 4, so that the urea water injection nozzle 4 is clogged.

The explanatory view showing the outline of the whole apparatus which carries out the present invention, Time chart showing an example of the cleaning situation of the urea water injection nozzle when the denitration operation is stopped in the present invention Time chart showing an example of the cleaning situation of the urea water injection nozzle when the urea water supply abnormality occurs in the present invention Time chart when denitration operation is stopped in the conventional example Time chart when urea water supply abnormality occurs in the conventional example

Explanation of symbols

1 Urea water supply route
2 Air supply path
3 Exhaust gas passage
4 Urea water injection nozzle
5 Urea water supply pump 6 Water supply pump
7 Air supply pump
8 Control device 9 Discharge amount checker 10 Atomized air control valve 11 Purge air control valve 12 Atomized air line

Claims (4)

A denitration device in which a urea water injection nozzle is installed in the exhaust gas passage for passing the combustion exhaust gas, urea water is injected from the urea water injection nozzle toward the combustion exhaust gas, and nitrogen oxides in the combustion exhaust gas are reduced and removed. When a dehydration operation is stopped by providing a water supply pump for supplying cleaning water to the urea water injection nozzle so that the urea water injection nozzle can be supplied with cleaning water in addition to urea water, In a denitration apparatus that cleans the inside of the urea water injection nozzle by supplying a cleaning liquid to the urea water injection nozzle, the water supply pump is operated at the stage where the supply of urea water is continued during the denitration operation stop operation. start the cleaning liquid supply to the water jet nozzle, the clogging of the urea water injection nozzle, characterized in that it comprises a control device that performs control to stop the supply of aqueous urea is delayed than the supply start of the cleaning liquid proof Denitration device that. 2. The denitration apparatus according to claim 1, wherein air can be supplied into the urea water injection nozzle, and the liquid component in the urea water injection nozzle is supplied by supplying air to the urea water injection nozzle at the time of denitration operation stop operation. When the air is discharged and the inside of the urea water injection nozzle is replaced with air, the air supply to the urea water injection nozzle is stopped, but after that, while the denitration operation is stopped, the air is periodically supplied to the urea water injection nozzle. denitration device for preventing clogging of the urea water injection nozzle, characterized in that it comprises a control device. In the denitration apparatus according to claim 1 or 2, air can be supplied into the urea water injection nozzle, and when the denitration operation is stopped, the cleaning of the urea water injection nozzle with the cleaning liquid is terminated, and after the cleaning liquid supply is stopped, Control device that does not immediately supply air to the urea water injection nozzle, but performs control to start air supply to the urea water injection nozzle after the pressure in the urea water supply path for supplying urea water or cleaning liquid is released denitration device for preventing clogging of the urea water injection nozzle, characterized in that it comprises a. The denitration apparatus according to any one of claims 1 to 3, wherein a discharge amount checker is attached to a urea water supply path for supplying urea water and cleaning liquid, and the urea water supply state is detected by the discharge amount checker at the time of urea water injection. A denitration device for preventing clogging of a urea water injection nozzle, characterized by having a control device that immediately starts a denitration operation stop operation when it is detected that the urea water supply state is abnormal.

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