Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers

192 Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers Masayuki Hirano Yasuyoshi Kato Okikazu Ishiguro Akira Mori ABSTRACT: In the last quarter century, air pollution has become a global environmental problem. To remove NOx in flue gas emitted from thermal power plants, many DeNOx plants (NOx removal plants) have been constructed in and are being planned for Japan, the US, the EC, and Asia. DeNOx plants for coal-fired boilers require high technology system and catalyst designs because the flue gas contains high amounts of NOx, SOx and dust. Hitachi developed a unique plate-type catalyst which has high resistance to erosion and plugging with dust. It supplied the first DeNOx plant for a coal-fired boiler in 1983 and has since then supplied many plants, including recent ones for 1,-MW coal-fired boilers. In this paper we describe the features of the DeNOx plants for coal-fired boilers, introduce the plate-type catalyst, and discuss the long-term operating performance of the plants and the latest scale-up technologies, such as an advanced control system, being incorporated in the plants for large-scale boilers. INTRODUCTION WITH the rapid progress of industrialization, air pollution has become a global environmental problem in the last quarter century. As early as 1963, Hitachi commenced studies on DeNOx catalysts and found that a titanium dioxide catalyst is a highly active catalyst which has high resistance to SOx poisoning. Hitachi developed a unique plate-type catalyst that is highly resistant to erosion and plugging with dust in flue gas. DeNOx plants apply to the NOx contained in the flue gas a selective catalytic reduction (SCR) process in which ammonia is used as a reducing agent, decomposing the NOx into harmless N2 and H2O through the action of the catalyst. Hitachi began the commercial application of DeNOx plants in Japan in 1977 and has supplied more than 2 plants in Japan, the US, the EC, and Asia. Recently, DeNOx plants have mainly been Characteristics of coalfired flue gas Catalyst requirements Design features of DeNOx plant High NO x High SO x High halogen (HCL, HF, etc.) High dust including alkaline metal (K, Na) High activity Unaffected by gas or dust components Low conversion of SO 2 to SO 3 for minimum effect on downstream equipment High plugging resistance High erosion resistance Fig. 1 Considerations on DeNOx Plant for Coal-Fired Flue Gas. Catalyst Ti-base catalyst Plate type 1) elements (with center plate) high structural strength and erosion resistance 2) units optimum element pitch 3) blocks easy handling and loading Reactor Down flow type Selection of optimized gas velociy Installation of guide vanes and screen lates uniform distribution of gas and dust Operation Keeping of catalyst in dry condition at operation and shut down Operation at low NH 3 slip

Hitachi Review Vol. 47 (1998), No. 5 193 constructed or are planned in these regions for coalfired boilers. Hitachi supplied the first DeNOx plant for The Tohoku Electric Power Co., Inc. s coal-fired boiler at its Sendai Power Station in 1983. Since then, it has supplied many plants, including recent plants for 1,-MW coal-fired boilers for the Shinchi Unit No. 1 of Soma Kyodo Power Co., Ltd., etc. FEATURES OF DeNOx PLANTS FOR COAL- FIRED BOILERS The main characteristics of coal-fired flue gas and catalyst requirements and design features of DeNOx plants are shown in Fig. 1. Since the coal-fired flue gas contains a high amount of NOx, SOx and dust, the selection of a catalyst with high resistance to erosion and plugging with dust is very important, especially for the high dust loading system in which the boiler exhaust gas flows directly into the DeNOx plant. It is also important to keep the catalyst dry during operation and shut-down because the catalyst can be deteriorated by alkaline metals in the dust when wet. In the design of the reactor, a suitable gas velocity and uniform distributions of gas and dust should be considered. Size: approx. 5 5 5 (mm) Fig. 2 Hitachi Plate-Type Catalyst. Main features are: high activity and long life, high erosion resistance to dust, high plugging resistance to dust, low pressure loss, and compact, rigid and easy to handle. Customer/Plant (MW) 82 83 84 85 86 87 88 89 9 91 92 93 94 95 96 97 Chugoku/ Mizushima No. 2 156 *1(2%) Chugoku/ Mizushima No. 1 A B C (Austria) D (Austria) E 125 25 25 45 32 45 *1(33%) *1(33%) *1(2%) *2(1%) *1(2%) F G H I J K L Soma Kyodo/ Shinchi No. 1 (Sweden) (Sweden) (Finland) 1 3 1 - - 55 7 1, Fig. 3 Operational Performance of DeNOx Plants for Coal-Fired Boilers at High Dust Loading (catalyst addition and replacement record). The chart shows typical plants only. *1: Addition of catalyst. The figure in parentheses shows percentage to the initially loaded catalyst. *2: Replacement for the catalyst with a specially low SO 2 to SO 3 conversion rate.

194 Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers 1.4 1.2 Note: The latest data were measured in 1996. Catalyst activity ratio ( ) 1.8.6.4 Sendai No. 3 Sendai No. 2 Mizushima No. 2 Mizushima No. 1 a b c d e.2 2 4 6 8 1 12 14 16 Operating time (Year) Fig. 4 Changes of Catalyst Activity with Operating Time at DeNOx Plants for Coal- Fired Boilers at High Dust Loading (measured with sample catalyst). Also noteworthy is that during pilot tests of catalysts for wet bottom boilers with 1% ash recirculation in Germany, the activity of the catalyst decreased rapidly as a result of arsenic adsorption. To resolve this problem, we developed a catalyst resistant to arsenic and began supplying it to commercial DeNOx plants in Germany in 1988. 1) HITACHI PLATE-TYPE CATALYST Hitachi s plate-type catalyst, shown in Fig. 2, is made up of plate catalyst elements approximately 1 mm thick arranged in parallel. The element consists of a center plate coated with the catalyst material. This type of catalyst has many unique advantages such as high resistance to erosion and plugging and low pressure loss. Hitachi manufactures the plate-type catalyst at its own factory. OPERATING PERFORMANCE OF DeNOx PLANTS FOR COAL-FIRED BOILERS Fig. 3 shows a record of the operation of DeNOx plants for coal-fired boilers at high dust loading. All plants use the plate-type catalyst. Catalyst additions and replacements are also shown in the chart. Although the life of the catalyst depends considerably on its operating conditions, the longest operation without catalyst addition or replacement is over 1 years. Changes in catalyst performance over time are checked by plant performance tests and sample catalyst tests. The sample catalysts are installed in the reactor and taken out for periodic analyses. Fig. 4 shows the changes in catalyst activity over time as measured by sample catalysts at DeNOx plants for coal-fired boilers at high dust loading. The longest uses of a catalyst so far are 14 years at the Sendai Nos. 2 and 3 units and 13 years at the Mizushima Nos. 1 and 2 units. (The latest data were taken in 1996.) These catalysts showed no erosion and still maintain considerable catalyst activity. Maintenance work for the DeNOx plants during their annual shut-down consisted of just cleaning the inside of the reactors. The long life and low-maintenance requirements of the plate-type catalyst contributed to the reduced operating cost of the DeNOx plants. Moreover, the power plants have never had to be shut down as a result of a DeNOx plant failure. Thus, the DeNOx plants are considered to be highly reliable. LATEST TECHNOLOGIES FOR DeNOx PLANTS FOR COAL-FIRED BOILERS Although many DeNOx plants for coal-fired boilers have shown to operate reliably, continuing efforts are being made for better DeNOx performance, higher reliability and lower operating costs of the plant. The latest technologies being incorporated in the DeNOx plants for coal fired boilers are as follows.

Hitachi Review Vol. 47 (1998), No. 5 195 Inlet 1.2 V: gas velocity V : average of gas velocity 1.8 Upstream of catalyst layer V/V [ ].6.4.2 By computer analysis By flow model test Reactor front Center Flow pattern upsteam of catalyst layer Rear Outlet Fig. 5 Analytical Model and Comparison of Flow Pattern by Computer Analysis and Flow Model Test (at DeNOx plant for Matsuura Unit No. 1 of Electric Power Development Co., Ltd., 1,-MW coal-fired boiler). (1) Scale-up technology for DeNOx plants for largescale boilers Recently, large-scale boilers with a capacity of 1, MW have been constructed in Japan. The DeNOx plants for these boilers are so large that scale-up technology must be studied carefully and applied to these plants. a) Uniform gas flow in large DeNOx reactors: It is important to obtain uniform gas flow to improve DeNOx performance and prevent erosion and plugging of the catalyst with dust. The optimal shape of the reactor and arrangement of the guide vanes for obtaining a uniform gas flow were usually determined Initially loaded catalysts Inlet Outlet NH 3 injection grid Screen plated (guide vanes) Space for future additional catalyst Fig. 6 Reactor Structure for Large-Scale DeNOx Plant. by a flow model test. Recently, however, flow patterns in the duct and reactor have been analyzed by computer. Fig. 5 shows the analytical model and a comparison of the flow patterns upstream of the catalyst layers by computer analysis and by flow model test. The results coincide well and the gas flow is almost uniform. Fig. 6 shows the optimal shape of the reactor and arrangement of the guide vanes. These guide vanes, called screen plates, are different from the conventional guide vanes. They work as if a large number of small guide vanes were installed. (The structure is our patent.) b) Uniform distribution of injected ammonia: It is also important to obtain uniform distribution of injected NH 3 to improve DeNOx performance. A lattice-type NH 3 injection grid has been applied and the quantity of injected NH 3 to each section of the duct has been adjusted by flow adjustment valves. c) Long-term economical operation: Long-term economical operation of the DeNOx plant is achieved by the catalyst addition method and the long life of the applied catalyst. The plate-type catalyst is particularly advantageous when the addition method is used because additional catalysts can be stacked directly on the existing catalyst in the vertical gas flow arrangement. Space for additional catalysts is available on the existing catalyst layer. The long life of the catalyst results from minimizing the deterioration of the catalyst and ensuring the mechanical strength of the catalyst over long-term operation. Fig. 6 shows the reactor structure which incorporates these scale-up technologies.

196 Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers Fig. 7 Exterior View of the DeNOx Plant for the Shinchi Power Station Unit No. 1 of Soma Kyodo Power Co., Ltd., 1,-MW Coal-Fired Boiler. Two DeNOx reactors (front) and boiler house (back) are shown. Fig. 7 shows the exterior view of the DeNOx plant for the 1,-MW coal-fired boiler for the Shinchi Power Station Unit No. 1 of Soma Kyodo Power Co., TABLE 1. Design Specifications and Performance Test Results of DeNOx Plant for a 1,-MW Coal-Fired Boiler (Shinchi Unit No.1 in Japan) Flue gas flow rate (m 3 N/h) Flue gas temp. ( C) Dust conc. (g/m 3 N) Inlet NO x conc. DeNOx efficiency (%) NH 3 slip Item Design Performance test result* 3,14, 37 2 3 8 3. 3,14, 37 3 8 Less than.1 *: Test result was converted to the values at the design condition for evaluation. Ltd. Table 1 shows the design specifications and performance test results. DeNOx efficiency is 8%. The design NH 3 slip is 3 ppm, which was lowered from the conventional 5 ppm to counteract the influence on the downstream equipment (such as plugging of the air preheater). The DeNOx plant is located between the boiler and air preheater and the dust concentration in the flue gas is 2 g/m 3 N. The performance test results show that the NH 3 slip is less than.1 ppm at the initial stage of operation and the performance of the DeNOx plant fully meets the specifications. (2) Application of advanced control system The DeNOx plant is controlled to maintain the required DeNOx performance (DeNOx efficiency and NH 3 slip) at all times following operation of a boiler. This is done by controlling the quantity of injected NH 3. In DeNOx plants for coal-fired boilers, the inlet NO x often varies depending on the type of coal and the combustion conditions of the boiler. To deal with this variation, a feedback signal for the outlet NO x was added to the control circuit. However, the time-constant of the change in the outlet NO x corresponding to a change in the quantity of injected NH 3 is as large as

TABLE 2. Comparison of by Fuzzy Control and NH 3 Preceding Injection Control at Load Changes (at DeNOx Plant for Matsuura Unit No. 2 of Electric Power Development Co., Ltd.) Hitachi Review Vol. 47 (1998), No. 5 197 Load change Load change rate set. value A-train (by NH 3 preceeding inj. control) B-train (by fuzzy control) (MW) (% min.) deviation max./min. deviation at one hour average value deviation max./min. deviation at one hour average value 5 1, 4 4 +./-29.5-13.3 +./-18.4-7.8 1, 5 4 4 +3./-38.4-1.9 +4.8/-31.4-6.4 1 minutes. Since the outlet NO x does not change simultaneously with the NH 3 injection, the feedback control is not sufficient for controlling at load changes. Therefore, we tried adding an NH 3 preceding injection circuit. The quantitiy of NH 3 injected is increased or decreased quickly by using signals such as the boiler load signal (MWD) and the mill start-stop signal at load changes. Even with the addition of the NH 3 preceding injection circuit, however, the NH 3 injection is not always controlled properly for handling the required DeNOx reaction for various load changes, various load change rates, and on-off of burners. Therefore, the NH 3 preceding injection circuit was replaced with fuzzy control. The fuzzy controller added to the control system generates a signal for correcting the mole ratio (that is, a signal for increasing or decreasing the quantity of NH 3 injected) to compensate for the delayed response in the DeNOx reaction from the NH 3 injection. The signals are generated based on the fuzzy control rule using feed-forward signals such as load change rate, outlet NO x concentration change rate, deviation of outlet NO x concentration from the setting value, and timing of start-up and shut-down of the mills. The effectiveness and controllability of fuzzy control were studied and confirmed by computer simulation prior Fig. 8 Comparison of NH 3 Injection and Outlet NOx at a Load Change by Fuzzy Control and NH 3 Preceding Injection Control at DeNOx Plant for Matsuura Unit No. 2 of Electric Power Development Co. 1 Inelt NO x by fuzzy control (corrected), 2 Inlet NO x by NH3 preceding inj. control (corrected), 3 by fuzzy control (corrected), 4 by NH3 preceding inj. control (corrected), 5 NH 3 injection by fuzzy control (m 3 N/h) 6 NH 3 injection by NH3 preceding inj. control (m 3 N/h) 15 1 5 1 6 7 1 2 5 3 4 2 3 4 5 Operating time (min) 5 7 Load (MW)

198 Operating Performance and Latest Technology of DeNOx Plants for Coal-Fired Boilers to their application. Fuzzy control was applied to the Matsuura Unit No. 2 of Electric Power Development Co. Table 2 shows a comparison of the outlet NO x with fuzzy control and that with NH 3 preceding injection control. Fuzzy control reduced the deviations (max. to min. value) from the setting value of the outlet NO x (4 ppm) considerably and reduced the deviation by approximately 4% at one hour average value. Fig. 8 compares the NH 3 injection and the outlet NO x at a load change by fuzzy control and by NH 3 preceding injection control. Fuzzy control considerably reduced the excessive NH 3 injection and the deviation of the outlet NO x. The application of fuzzy control is not only economical but also effective for counteracting the influence on the downstream equipment resulting from the reduction of NH 3 slip. CONCLUSIONS The longest use of a Hitachi plate-type catalyst at a DeNOx plant for a coal-fired boiler at high dust loading has already reached 14 years. The plant has never experienced a shut-down as a result of any failure of the DeNOx plant. Thus, the DeNOx plant has been shown to be highly reliable. The scale-up technology for obtaining uniform gas flow and uniform ammonia injection for the DeNOx plant was applied to the DeNOx plants for 1-MW coal-fired boilers. Its effectiveness was demonstrated by the excellent performance of the DeNOx plant for the Shinchi Unit No. 1 of Soma Kyodo Power Co., Ltd. Fuzzy control was applied to the Matsuura Unit No. 2 of Electric Power Development Co. and its effectiveness was demonstrated by the consdiderable reduction in the excessive NH 3 injection and deviation of the outlet NO x. REFERENCES (1) H. Kuroda et al., Recent Developments in the SCR System and its Operational Experiences, EPRI/EPA(1989) Joint Symposium on Stationary Combustion NOx Control. (2) A. Mori, S. Nozawa, and M. Hirano, Operational Result of the Advanced FGD and SCR System, 11th Conference of the Electricity Supply Industry (1996), Business Papers Vol. 5, pp.28-36. (3) T. Ishikawa and M. Nishimura, Latest Technologies in SOx and NOx Removal System for Flue Gas from Thermal Power Plants, Hitachi Review 39, No. 6 (199), pp. 347 354. (4) H. Kuroda et al., Recent Technological Developments in SOx and NOx Removal Systems for Flue Gases from Thermal Power Plants, Hitachi Review 36, No. 6 (1987). (5) H. Kuroda and T. Masai, Babcock Hitachi NOx Abatement Technology, NOx Symposium Karlsruhe, West Germany, Feb., 1986. ABOUT THE AUTHORS Masayuki Hirano Joined Babcock-Hitachi K.K. in 1974. Belongs to Environmental Control Plant Design Dept. Currently working to design DeNOx plants in Japan and overseas. Member of the Japan Society of Mechanical Engineers. E-mail: hirano@kure.bhk.co.jp Yasuyoshi Kato Joined Babcock-Hitachi K.K. in 1973. Belongs to Environmental Research Dept. of Kure Research Lab. Curently working to develop catalysts. Member of the Catalyst Society of Japan. E-mail: katoo-y@arl. bhk.co.jp Okikazu Ishiguro Joined Babcock-Hitachi K.K. in 1965. Belongs to Kure Research Laboratory. Currently working to develop a simulation model for dynamic characteristic analysis on heat-recovery steam generator. Member of the Japan Society of Mechanical Engineers. E-mail: ishiguro-o@krl. bhk.co.jp Akira Mori Joined Hitachi, Ltd. in 1962. Belongs to Overseas Thermal Power Plant Dept, Thermal Power Division. Currently working to promote the sales of environmental control system. E-mail: a-mori@powerhp2.power.hitachi.co.jp