This invention relates generally to boilers, and more particularly to the optimization of combustion in fossil fuel fired boilers.
In numerous industrial environments, a hydrocarbon fuel is burned in stationary combustors (e.g., boilers or furnaces) to produce heat to raise the temperature of a fluid, e.g., water. For example, the water is heated to generate steam, and this steam is then used to drive turbine generators that output electrical power. Such industrial combustors typically employ an array of many individual burner elements to combust the fuel. In addition, various means of combustion control, such as overfire air, staging air, reburning systems, selective non-catalytic reduction systems, can be employed to enhance combustion conditions and reduce oxides of nitrogen (NOx) emission.
For a combustor to operate efficiently and to produce an acceptably complete combustion that generates byproducts falling within the limits imposed by environmental regulations and design constraints, all individual burners in the combustor must operate cleanly and efficiently and all combustion modification systems must be properly balanced and adjusted. Emissions of NOx, carbon monoxide (CO), mercury (Hg), and/or other byproducts (e.g., unburned carbon or loss-on-ignition (LOI) data) generally are monitored to ensure compliance with environmental regulations and acceptable system operation. The monitoring heretofore has been done, by necessity, on the aggregate emissions from the combustor (i.e., the entire burner array, taken as a whole).
Some emissions, such as the concentration of unburned carbon in fly ash and Hg are difficult to monitor on-line and continuously. In most cases, these emissions are measured on a periodic or occasional basis, by extracting a sample of ash and sending the sample to a laboratory for analysis. When a particular combustion byproduct is found to be produced at unacceptably high concentrations, the combustor is adjusted to restore proper operations. Measurement of the aggregate emissions, or measurement of emissions on a periodic or occasional basis, however, do not provide an indication of what combustor parameters should be changed and/or which combustor zone should be adjusted.
It is known that the air to fuel ratios between each burner in a combustor of a boiler can vary considerably because the burner air and pulverized coal distributions can vary significantly from burner to burner. The absence of effective methods to adequately monitor and control the coal and air flows can contribute to a boiler not operating under its optimal combustion conditions. The variance in burner coal and air flow rates can lead to a wide variance in individual burner operating conditions, some operating on the fuel-rich side and some on the fuel-lean side of the average boiler air to fuel ratio. The burners operating on the fuel-rich side produce significant unburned combustion by-products (CO and LOI) that may not be completely oxidized downstream by mixing with excess air from fuel-lean burners. The degree to which a fuel-rich burners unburned byproducts are oxidized depends on the proximity of fuel-lean burners, the degree of mixing and the mixed burner stream temperature. The final unburned byproduct levels restrict the boiler from operating at lower excess air levels that has the effect of driving fuel-rich burners richer, producing more unburned byproducts as well as reducing the availability of excess air from fuel-lean burners to burn-out byproducts of the fuel-rich burners. The result of these out of balance burner conditions is that boilers must operate at higher excess air levels. The levels of excess air are dictated by the amount of imbalance in the burner's air to fuel ratios. As a result of the operation under high excess air there can be an increase in NOx emissions and a reduction in the boiler's efficiency which increases operational costs for fuel and NOx credits and reduces output due to emissions caps.
In some plants, boilers are operated with high excess air in order to increase combustion gas mass flow and subsequent heat transfer in the convective pass to achieve desired steam temperatures. In these applications, burner imbalance can have an impact on gas temperature uniformity. For fossil fuel fired boilers, peak combustion temperatures are reached at slightly fuel-rich operation. These peak temperatures caused by fuel-rich burners can lead to increased metal fatigue, slagging (melted ash) deposits on convective passes, corrosive gases and high ash loadings in local convective pass regions. To remove ash and slagging, additional sootblowing is required. Sootblowing, high temperature gases and corrosive gases lead to deterioration of watertube and waterwall metals resulting in frequent forced outages with lost power generation capability. Currently to avoid catastrophic failure due to high temperature metal fatigue in convective passes, the boiler is derated. This means the boiler is operated below rated capacity which reduces the total heat input and reduces the gas temperature exiting the furnace prior to the convective passes.
In one aspect, a method of optimizing operation of a fossil fuel fired boiler is provided. The boiler includes a plurality of burners with each burner receiving fossil fuel and combustion air. The method includes providing a plurality of sensors positioned in different spatial positions within the fossil fuel fired boiler. The method also includes recording sensor outputs, identifying spatial combustion anomalies indicated by sensor outputs, identifying burners responsible for the spatial combustion anomalies, and adjusting air flow of responsible burners to alleviate the spatial combustion anomalies.
In another aspect, a method of optimizing operation of a fossil fuel fired boiler is provided. The boiler includes a plurality of burners with each burner receiving fossil fuel, primary air, and secondary air. The method includes providing a plurality of at least one of LOI sensors and CO sensors positioned in different spatial positions within the fossil fuel fired boiler, balancing burner fuel flow, recording sensor outputs, identifying spatial combustion anomalies indicated by sensor outputs, identifying burners responsible for the spatial combustion anomalies, and adjusting air flow of responsible burners to alleviate the spatial combustion anomalies.
A method of optimizing operation of a fossil fuel fired boiler is described below in detail. The method includes the use of a plurality of different sensors in different spatial locations within a particulate fossil fuel fired boiler furnace to track in-furnace combustion conditions and the relative differences between individual burners. The method also includes using the sensor information to make adjustments to individual burners to yield an optimized boiler performance. The optimized operating burner conditions can vary from one burner to another. This means that the air flow and fuel flow can vary from burner to burner and that the air to fuel ratio to individual burners are not predetermined. Rather, each burner is biased and adjusted to meet boiler performance objectives as indicated by the in-furnace sensors. Optimized performance includes, for example, reduced NOx emissions, reduced LOI emissions, increased efficiency, increased power output, improved superheat temperature profile, and/or reduced opacity. Burner adjustments include, for example, coal and air flow, fuel to air ratio, burner register settings, overfire air flows, and other furnace input settings.
Referring to the drawings,
Referring also to
To balance 54 burner fuel flow, the coal flow from mill 22 to burners 28 is balanced. Coal fineness, mill coal feeder, and mill primary air flow are variables that affect burner coal flow. Coal flow monitors and controls can be used to control coal flow. Referring to
To identify 58 spatial combustion anomalies, spatial combustion data from the plurality of CO sensors 44, LOI sensors 38, and temperature sensors 40 are examined. Also, a visual flame inspection is performed as well as examining input from any flame sensors to detect burner imbalance.
Identifying 60 burners responsible for the spatial combustion anomalies includes tracing burners 28 to corresponding sensors. Particularly, tracing the burners can be accomplished by computational flow modeling, isothermal flow modeling, and/or empirically by adjusting individual burner air settings and noting changes to sensor output data. The individual air settings can be adjusted by reducing excess air to individual burners and/or increasing fuel to individual burners to determine the burners that are causing the combustion anomalies. Also, settings to all burners can be adjusted by reducing excess air to all burners and/or increasing fuel to all burners to determine the burners that are causing the combustion anomalies. Also, settings to individual columns of burners can be adjusted by reducing excess air to individual columns of burners and/or increasing fuel to individual columns of burners to determine the burners that are causing the combustion anomalies. Further, increasing mill fuel flow at constant mill air flow and/or increasing mill fuel flow at a constant boiler air to fuel ratio can be used to determine the burners that are causing the combustion anomalies. Also, reducing windbox air flow at constant mill fuel flow, reducing windbox air flow at constant boiler fuel flow, and/or reducing windbox air flow at a constant boiler air to fuel ratio can be used to determine the burners that are causing the combustion anomalies.
Also, identifying responsible burners include recording burner settings, determining if anomalies trace to burners with most biased air settings, maximizing a feed air pressure drop at a mean damper setting, and adjusting burner air settings to alleviate combustion anomalies caused by the responsible burners.
Further, identifying responsible burners can include adjusting inner and outer spin vanes on individual burners and adjusting burner registers to determine responsible burners. Responsible burners are indicated where a small adjustment produces a large impact on burner combustion. Adjusting 62 responsible burner air flow to alleviate the spatial combustion anomalies also includes adjusting a secondary air damper and adjusting an over fire air damper.
Also, the air flow through overfire air jets and fuel flow through reburn fuel jets can cause combustion anomalies. Identifying responsible overfire jets responsible for spatial combustion anomalies can include reducing excess air to all burners and/or increasing fuel to all burners to determine overfire jets responsible for the spatial combustion anomalies. Identifying responsible reburn jets responsible for spatial combustion anomalies can include reducing excess air to all burners and/or increasing fuel to all burners to determine reburn jets responsible for the spatial combustion anomalies.
Referring again to
Method 50 also includes developing 86 a spatial combustion data model at the optimized conditions defined by readings from the plurality of sensors, establishing 88 rules for burner adjustments based on the spatial combustion data model, and adjusting 90 burner settings in accordance with the rules to maintain optimized operation of the boiler.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
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Number | Date | Country | |
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20040191914 A1 | Sep 2004 | US |