Process for improving operation of large-scale combustors

Abstract

The heat output, e.g., megawatt product or steam generation, of a combustor is increased, preferably while plume is mitigated, by targeting treatment chemicals to locations in a furnace. The process improves heat output from the fuel in the region of the combustor optimum for heat recovery and also maintains good heat transfer characteristics for the heat exchange surfaces. The effectiveness of targeted in furnace injection, in-fuel introduction and in-furnace introduction of slag and/or corrosion and/or plume control chemicals are preferably determined, as are the effectiveness of targeted in furnace injection, in fuel introduction and in furnace introduction of combustion catalysts. Then, the effectiveness of various combinations of the above treatments are determined, and a treatment regimen employing one or more of the above treatments is selected. Preferred treatment regimens will contain at least two and preferably three of the treatments. Chemical utilization and boiler maintenance can improved as LOI carbon, slagging and/or corrosion are also controlled. In one preferred embodiment, the invention enables increasing by determining the positions for effective introduction of slag controlling chemical, introducing targeted slag controlling chemical treatment in an amount effective to reduce slag and introducing a combustion catalyst into the flame in an amount effective to improve combustion.

Description

RELATED APPLICATIONS

This application is a continuation-in-part of and claims priority to prior U.S. patent application Ser. No. 10/754,072 filed Jan. 8, 2004.

BACKGROUND OF THE INVENTION

The invention relates to a process for increasing the heat output of large-scale combustors, such as the type used industrially and by utilities to provide power and incinerate waste. According to the invention, heat output is increased while, or plume opacity is mitigated, preferably both, and/or slag and/or corrosion are reduced. The invention achieves one or more of these desired results through the use of one or more chemicals, which in one embodiment is a unique combination of combustion catalyst and slag modifier. The chemicals are preferably introduced by targeted in-furnace injection, and/or in-body injection.

The combustion of carbonaceous fuels, such as heavy fuel oils, coals, refinery coke, biomass and municipal and industrial waste, is typically less efficient than would be desired; and in some cases the imposition of pollution control requirements is viewed as a cost penalty because the combustors are less able to efficiently produce electricity or steam. The heat outputs of combustors are often modified by using alternative fuels, often reduced. There is a need to improve heat output from the fuel in the region of the combustor optimum for heat recovery and also maintain good heat transfer characteristics for the heat exchange surfaces so that heat output can be improved, especially while pollution control is effected or maintained while using alternative fuels.

The combustion of carbonaceous fuels typically produces a plume arising from the smoke stack and can have opacity ranging from low to high. In addition, these fuels contain slag-forming materials, and can generate corrosive acids, and unburned carbon, that in combination have a relatively negative effect on the productivity of the boilers, and can corrode the environment and pose a health risk. Plume is a problem from an aesthetic standpoint as well as an environmental one. Plume can be objectionable in and of itself and is expensive to treat by conventional technology. The negative effects of plume are considered to be related to the opacity of emissions from power plants. Plume opacity is measured in percent. Simply, the greater the opacity, the more the background behind the plume is obscured and the less light can come through the plume. If none of the background is obscured, then the opacity is 0%. If the entire background is obscured, then the opacity is 100%.

The visibility impairment effects of power plant plumes can be grouped into three categories. The first, opacity, occurs very near the stack and is determined by EPA Reference Method 9 is found in 40 CFR Part 60, Appendix A. It was adopted as a visible emissions inspection method in an effort to standardize the training and certification of observers and to ensure that reliable and repeatable opacity observations could be conducted anywhere in the United States. The second, plume blight, occurs at distances from 2 km to 1 day's travel downwind. Blight happens before the plume has been dispersed so widely that it is indistinct from the background. Regional haze is the effect of the plume on a broader scale and is obviously of critical concern. Coal and oil fired power plants, especially, produce small particles in plumes from when sulfur dioxide (SO₂) is oxidized to sulfur trioxide (SO₃) inside a furnace and boiler, condenses with water (H₂O) at lower temperatures to become suspended sulfuric acid aerosol particles. SO₃ also reacts with alkali metals to form various sulfates. Sulfate particles can significantly contribute to the concentration of very fine particle matter (PM_2.5), which is associated with health as well as reduced visibility. Desulfurization, e.g., flue gas desulphurization (FGD), of the entire effluent can be used to decrease plume from coal-fired boilers by decreasing the overall SO₂ content of the effluent. The invention, by decreasing plume opacity, directly affects opacity and is believed to greatly reduce an individual plant contribution to the other two categories of visibility impairment.

While plume opacity is of concern from an external pollution position, slagging and some of the other problems caused by combustion can affect efficiency—therefore, economics, which are a severe threat to older power plants, especially, where efficiency is required for pollution controls to be affordable for maintaining the plants in operation. Slagging deposits are sometimes extremely difficult to remove by conventional techniques such as soot blowing. Slag buildup results in a loss of heat transfer throughout the system, increases draft loss, limits gas throughput and is a factor in tube failure due to erosion from excessive sootblowing. A variety of other procedures are known for adding treatment chemicals to the fuel or into the furnace in quantities sufficient to treat all of the ash produced, in the hope of solving the slagging problem. Typical chemicals include magnesium oxide and magnesium hydroxide for the above reasons and various combustion catalysts, such as copper, iron, calcium, barium and/or manganese to improve the burning of the fuel.

Corrosion, typically occurs to a greater degree at the cold end of the combustor, and can create maintenance costs that are desirably avoided. Acid gases and deposits can often be controlled by the addition of chemicals to the combustion chamber or the fuel. The introduction of chemicals in this manner is often very inefficient and increases the amount of ash that must be disposed. Corrosion control is too often a choice between polluting byproducts.

The art has endeavored to solve slagging and/or corrosion problems by introducing various chemicals, such as magnesium oxide or hydroxide. Magnesium hydroxide has the ability to survive the hot environment of the furnace and react with the deposit-forming compounds, raising their ash fusion temperature and thereby modifying the texture of the resulting deposits. Unfortunately, the introduction of the chemicals has been very expensive due to poor utilization of the chemicals, much simply going to waste and some reacting with hot ash that would not otherwise cause a problem. U.S. Pat. No. 5,740,745 and U.S. Pat. No. 5,894,806 deal with this problem, by introducing chemical in one or more stages to directly address predicted or observed slagging and/or corrosion.

The presence of unburned carbon in the ash is an indication that combustion is not efficient and can cause operational problems. Increasing the amount of air used for combustion can reduce carbon in the ash, often referred to as LOI carbon (for loss on ignition, denoting a weight loss of ash due to combustion of its carbon content). This can be effective in some situations, but the use of excess air always decreases boiler efficiency. Also, excess air increases SO₂ to SO₃ conversion, causing additional acid aerosol plume and may also increase NOx levels. The use of combustion catalysts can also be effective in some cases; however, combustion catalysts cannot always be used effectively or efficiently due to fuel and/or equipment limitations. Among combustion catalysts proposed in the art are the metal compounds in the form of basic metal salts, generally calcium, iron, copper, barium, manganese and/or magnesium compounds. Generally the metal compounds are delivered as metal salts. The anionic portion of the salt can be hydroxyl, oxide, carbonate, borate, nitrate, etc. Carbon in the ash can decrease commercial value of the ash, which can be used in concrete if the LOI can be reduced to less than 2%.

The art is in need of a process that can efficiently deal with plume, while preferably permitting efficient combustion with lower LOI carbon, lower excess air, lower CO, and/or lower NO_x, and/or controlling slag, and/or corrosion. It has now been observed in some cases that the same treatments effective for plume reduction can also result in increased heat production by a combustor. This is a result which goes far beyond the aesthetics and is believed to provide added incentives for combustor operators to pursue the treatments found effective and, thereby, reduce plume while gaining significant economic rewards.

BRIEF DESCRIPTION OF THE INVENTION

It is an object of the invention to improve the operation of large-scale combustors by efficiently mitigating plume.

It is another object of the invention to improve the operation of large-scale combustors by increasing heat output.

It is another object of the invention to improve the operation of large-scale combustors by efficiently mitigating plume, while preferably controlling slag and/or corrosion at the same time that LOI carbon is mitigated.

It is another object of the invention to enable the treatment of many boilers with an effectiveness that has heretofore escaped those skilled in the art.

It is a further object of the invention to mitigate plume with reduced chemical treatment costs in many boilers and synergies in others.

A yet further, but related, object is to mitigate the costs resulting from any or all of the aforementioned problems by reducing their occurrence.

A yet further object is to increase combustor output.

These and other objects are achieved by the present invention which provides an improved process for improving the operation of combustors, comprising: burning a carbonaceous fuel in the presence a combustion catalyst in the fuel or injected into the combustor apart from the fuel; determining combustion conditions within a combustor that can benefit from targeted in-furnace treatment chemical; locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished; and, based on the determinations of the previous step, introducing targeted in-furnace treatment chemical.

In another embodiment, the invention provides a process, which comprises: burning a carbonaceous fuel in the presence of a combustion catalyst in the fuel or injected into the combustor apart from the fuel and a slag and/or corrosion controlling chemical; determining combustion conditions within a combustor that can benefit from targeted in-furnace treatment chemical for control of slag and/or corrosion; locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished; and, based on the determinations of the previous step, introducing targeted in-furnace treatment chemical.

In one preferred embodiment, a process for increasing heat output of a combustor burning carbonaceous fuel in a flame, comprises: determining the positions for effective introduction of slag controlling chemical; based on the determination of the previous step, introducing targeted slag controlling chemical treatment in an amount effective to reduce slag; and introducing a combustion catalyst into the flame in an amount effective to improve combustion.

The invention also provides a process of system analysis for pollutant control. According to this aspect of the invention, the effectiveness of targeted in furnace injection, in fuel introduction and in furnace introduction of slag and/or corrosion and/or plume control chemicals are determined, as are the effectiveness of targeted in furnace injection, in fuel introduction and in furnace introduction of combustion catalysts. Then, the effectiveness of various combinations of the above treatments are determined, and a treatment regimen employing one or more of the above treatments is selected. Preferred treatment regimens will contain at least two and preferably three of the treatments.

The invention has several preferred aspects, which are described in greater detail below.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood and its advantages more apparent from the following detailed description, especially when read in connection with the accompanying drawings, wherein:

The FIGURE is a graphical presentation of the results of Example 3, wherein a combustion catalyst and a slag-controlling chemical are added with the result that the heat output of the furnace is increased.

DETAILED DESCRIPTION OF THE INVENTION

The invention relates to a process for increasing the heat output, i.e., megawatt generation in the case of boilers used for electricity generation or steam output otherwise, of a combustor is increased, preferably while plume is mitigated, by targeting treatment chemicals to locations in a furnace. The invention can accomplish this by improving heat output from the fuel in the region of the combustor optimum for heat recovery and also by maintaining good heat transfer characteristics for the heat exchange surfaces. The invention is also effective in reducing plume, preferably while improving combustion and/or reducing slag and/or corrosion in large-scale combustors, such as of the type used industrially and by utilities to provide power and incinerate waste. The following description will illustrate the invention with reference to a power plant type boiler fired with heavy, e.g., number 6, fuel oil. It will be understood however, that any other combustor fueled with any other carbonaceous fuel and susceptible to the problems treated by the invention could benefit from the invention. Without meaning to be limiting of the type of fuel, carbonaceous materials such as fuel oil, gas, coal, waste, including municipal and industrial, sludge, biomass and/or synfuels, and the like, can be employed.

In general, the combustion of carbonaceous fuels, such as heavy fuel oils, coal and municipal and industrial waste, result in effluents having significant plume opacity and can cause slag formation, corrosive acids, that individually and in combination have relatively negative effect on the productivity and social acceptability of the boilers. The invention addresses these problems in a manner that is economically attractive and surprising in effectiveness. The invention provides an improved process for improving the operation of combustors. Important to the process is the determination of combustion conditions within a combustor that can affect plume. The invention can be used to treat plume alone or with one or more of LOI carbon, slagging and corrosion in the absence of treatment.

The process will entail burning a carbonaceous fuel with or without a combustion catalyst and introducing targeted in-furnace treatment chemical directed at problem areas or to locations where the chemical can do the most good. This latter step will require locating introduction points on the furnace wall where introduction of chemicals to control plume could be accomplished. The invention, thus, can be facilitated by the use of computational fluid dynamics and modeling or observation according to the teachings of U.S. Pat. No. 5,740,745 and U.S. Pat. No. 5,894,806. In addition to the specifically identified techniques, those skilled in the art will be able to define other techniques effective for locating the problem areas and, from them, determining the best locations to introduce chemical. The teachings of these patents will not be repeated here, but are incorporated by reference in their entireties to explain suitable techniques effective for the invention.

Among the preferred targeted in-furnace injection chemicals are combustion catalysts (e.g., a member selected from the group consisting of potassium, barium, calcium, cerium, iron, copper, zinc, magnesium, manganese, and mixtures of any of these, etc.) in various forms, and the oxides and hydroxides of magnesium for example, in the form of slurries or solutions in water or other suitable vehicle. The slag-reducing agent is most desirably introduced as an aqueous treatment solution, a slurry in the case of magnesium oxide or magnesium hydroxide. The concentration of the slurry will be determined as necessary to assure proper direction of the treatment solution to the desired area in the boiler. Typical concentrations vary from 1 to 100%, e.g., and are typically within the range of from about 51 to about 80% active chemical by weight of the slurry or solution, preferably from about 5 to about 30%. Other effective metal oxides and hydroxides (e.g., copper, titanium and blends) are known and can be employed. These chemicals, or others, such as copper oxychloride, copper carbonate, iron oxide, organometallics of iron, copper, calcium, supplied in a dosage to make 1 to 1000 ppm (typical 40-50 ppm) as active metal in the fuel by weight.

Important to the invention and a departure from known prior art in the field, is the introduction of a combustion catalyst with the fuel or separately from the fuel as a targeted in-furnace chemical effective for improving the oxidation of the fuel, in combination with the targeted in-furnace treatment chemical. The combustion catalyst will be any material effective for the intended purpose and preferably comprises a metal compound wherein the metal is selected from the group consisting of copper, iron, magnesium and calcium. It can include fuel dispersible or fuel soluble compositions. Among these, are chemical compounds which affect the combustion process, such as salts of organic acids, such as naphthenates, octoates, tallates, salts of sulfonic acids, saturated or unsaturated fatty acids, such as oleic acid, and tall oil, with metals from the group of K, Ba, Mg, Ca, Ce, Fe, Mn, Zn; rare earth metals; organometallic compounds, such as carbonyl compounds, mixed cyclopentadienyl carbonyl compounds, or aromatic complexes of the transition metals Fe or Mn, and mixtures of any of these. One preferred catalyst composition is calcium nitrate which can be supplied in the form 50% to 75%, e.g., typically up to 66 or 70%, % water solution at a dosage rate of from 1 to 1000 ppm (@˜0.5 lb/ton or 40-50 ppm as active metal) as active metal in the fuel by weight. Variation in the amounts will be initially determined by calculation and adjusted following testing. Variations of up to 100% of the indicated values will be expected, and up to about 25% of the values will be more typical.

In addition to the addition of combustion catalyst to the fuel, and a targeted in-furnace addition of chemical, the process of the invention will entail, in some preferred embodiments, the use of an in-furnace treatment chemical added to the carbonaceous fuel. The chemical can be the same or different from the targeted in-furnace injection chemical. In one scenario, total magnesium use can be about 0.6 kg per 1000 kg of fuel with 30-40% going low in the furnace or in the fuel and 60-70% going targeted higher in the furnace with targeted in-furnace injection (TIFI). The combustion catalyst is typically introduced at a dosage rate of from about 0.1 to about 2.0, e.g., about 0.2 to about 0.8, kg per 1000 kg of carbonaceous fuel burned in the combustor. In some preferred configurations, the targeted treatment chemical is introduced into the furnace at a dosage rate of from about 0.2 to about 1.2, e.g., from about 0.32 to about 0.46, kg per 1000 kg of carbonaceous fuel burned in the combustor Variation in the amounts will be initially determined by calculation and adjusted following testing. Variations of up to 100% of the indicated values will be expected, and up to about 25% of the values will be more typical.

Targeted injection of the in-furnace injection chemical will require locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished. And, based on the determinations of this procedure, targeted in-furnace treatment chemical is introduced, such as in the form of a spray. The droplets are desirably in an effective range of sizes traveling at suitable velocities and directions to be effective as can be determined by those skilled in the art. These drops interact with the flue gas and evaporate at a rate dependent on their size and trajectory and the temperatures along the trajectory. Proper spray patterns result in highly efficient chemical distributions.

As described in the above-identified patents, a frequently used spray model is the PSI-Cell model for droplet evaporation and motion, which is convenient for iterative CFD solutions of steady state processes. The PSI-Cell method uses the gas properties from the fluid dynamics calculations to predict droplet trajectories and evaporation rates from mass, momentum, and energy balances. The momentum, heat, and mass changes of the droplets are then included as source terms for the next iteration of the fluid dynamics calculations, hence after enough iterations both the fluid properties and the droplet trajectories converge to a steady solution. Sprays are treated as a series of individual droplets having different initial velocities and droplet sizes emanating from a central point.

Correlations between droplet trajectory angle and the size or mass flow distribution are included, and the droplet frequency is determined from the droplet size and mass flow rate at each angle. For the purposes of this invention, the model should further predict multi component droplet behavior. The equations for the force, mass, and energy balances are supplemented with flash calculations, providing the instantaneous velocity, droplet size, temperature, and chemical composition over the lifetime of the droplet. The momentum, mass, and energy contributions of atomizing fluid are also included. The correlations for droplet size, spray angle, mass flow droplet size distributions, and droplet velocities are found from laboratory measurements using laser light scattering and the Doppler techniques. Characteristics for many types of nozzles under various operating conditions have been determined and are used to prescribe parameters for the CFD model calculations. When operated optimally, chemical efficiency is increased and the chances for impingement of droplets directly onto heat exchange and other equipment surfaces is greatly reduced. Average droplet sizes within the range of from 20 to 1000 microns are typical, and most typically fall within the range of from about 100 to 600 microns.

One preferred arrangement of injectors for introducing active chemicals for reducing slag in accordance with the invention employ multiple levels of injection to best optimize the spray pattern and assure targeting the chemical to the point that it is needed. However, the invention can be carried out with a single zone, e.g., in the upper furnace, where conditions permit or physical limitations dictate. Typically, however, it is preferred to employ multiple stages, or use an additive in the fuel and the same or different one in the upper furnace. This permits both the injection of different compositions simultaneously or the introduction of compositions at different locations or with different injectors to follow the temperature variations which follow changes in load.

The total amount of the in-furnace treatment chemical introduced into the combustion gases from all points should be sufficient to obtain a reduction in plume opacity and/or corrosion and/or the rate of slag build-up and/or the frequency of clean-up. The build-up of slag results in increased pressure drop through the furnace, e.g., through the generating bank. Dosing rates can be varied to achieve long-term control of the noted parameters or at higher rates to reduce slag deposits already in place.

It is a distinct advantage of the invention that plume can be well controlled at the same time as corrosion, slag LOI carbon, and/or SO₃. The net effect in many cases is a synergy in operation that saves money and/or increases efficiency in terms of lower stack temperatures, cleaner air heater surfaces, lower corrosion rates in the air heaters and ducts, lower excess O₂, cleaner water walls, resulting in lower furnace exit temperatures and cleaner heat transfer surfaces in the convection sections of the boiler.

The process of the invention can be looked at from the unique perspective of system analysis. According to this aspect of the invention, the effectiveness of targeted in furnace injection, in fuel introduction and in furnace introduction of slag and/or corrosion and/or plume control chemicals are determined, as are the effectiveness of targeted in furnace injection, in fuel introduction and in furnace introduction of combustion catalysts. Then, the effectiveness of various combinations of the above treatments are determined, and a treatment regimen employing one or more of the above treatments is selected. Preferred treatment regimens will contain at least two and preferably three of the treatments. In each case, a determination can be any evaluation whether or not assisted by computer or the techniques of the above-referenced patents. In addition, it may involve direct or remote observation during operation or down times. The key factor here and a departure from the prior art is that targeted injection is evaluated along with nontargeted introduction, especially of a combination of combustion catalysts and slagging and/or corrosion and/or plume control chemicals. Chemical utilization and boiler maintenance can improved as LOI carbon, slagging and/or corrosion are also controlled.

The following examples are provided to further illustrate and explain the invention, without being limiting in any regard. Unless otherwise indicated, all parts and percentages are based on the weight of the composition at the particular point of reference.

EXAMPLE 1

In this example, magnesium hydroxide was fed to the fuel oil for a residual oil fired electric power plant boiler at a rate of 0.20 kg per 1000 kg. Magnesium hydroxide was also directed into the boiler at positions determined by computational fluid dynamic modeling as described in U.S. Pat. No. 5,894,806, at a rate of 0.20 kg per 1000 kg. In addition, a calcium nitrate combustion catalyst was added to the fuel oil at a rate of 0.25 kg per 1000 kg. The magnesium hydroxide fed the fuel oil performed two roles: it protected the lower furnace against slagging and hot-side corrosion by the mechanism of tying up vanadium in the oil. The magnesium hydroxide also prevented fouling caused by the catalyst from affecting lower furnace cleanliness. Most catalysts used for fossil fuels can also cause fouling in the lower furnace. Data showed base line opacities of 25% opacity and excess O₂ levels of 1.5%-2.0%. When the invention was introduced after a CFD model was run, opacity dropped to approximately 4.0% and excess O₂ was lowered to approximately 0.5%. It was observed that such operation on the unit had never been achieved before, as the fuel analysis is typically 250 ppm vanadium, 2.0% sulfur and 12% asphaltenes, which makes it impossible to achieve these results with in-body injection alone.

EXAMPLE 2

A similar set as in Example 1 is run with similar treatment to reduce opacities from 30% to 7%. In this case, the combustion catalyst is fed at a rate of 0.25 kg per 1000 kg of fuel, and the in-furnace injection chemical is Mg, which is fed at a rate of 0.35 kg per 1000 kg of fuel.

EXAMPLE 3

In this example, an injection of Mg(OH)2 slurry containing copper combustion catalyst increased MW generation while controlling furnace exit gas temperature (FEGT) and steam temperature. The power generation of 150 MW coal fired utility boiler was limited to about 140 MW due to high FEGT and main steam temperature. To overcome this limitation, a chemical treatment mixture of Mg and Cu compositions (comprised of magnesium hydroxide and copper carbonate, with 19% magnesium and 6% copper based on the weight of the slurry) was injected through the lowest elevation Targeted In-Furnace Injection ports. These and other targeted in-furnace injection ports were previously determined through a CFD modeling study.

With the initial start of Catalyst feed, the gross MW generation increased from increased coal flow rates. The main steam temperature and FEGT stayed within the maximum allowed limit throughout the test. This test was repeated on the following day with a similar result.

The introduction of treatment chemicals was correlated with a drop in steam temperature for a given production level, allowing for a MW production increase. Further, by comparison to other periods burning the same coal without treatment, the FEGT at the higher MW with treatment is lower than would be expected based on non-treated periods, assuming a linearly extrapolated trend. The FIGURE graphically shows gross combustor output in MW versus catalyst feed.

While not wanting to be bound by any theory, we believe we understand how this combination of treatments provides the unexpected increase in heat output for the combustor. Combustion catalysts increase the combustion reaction rate. This increased rate can lower CO emissions and LOI, contain the flame to lower furnace, and increase the heat generation in the lower furnace. If the flame reaches the upper furnace and superheaters, heavy slagging, metal fatigue, and corrosion can occur.

Injection of Mg(OH)₂ has successfully reduced slagging and other deposits on water/steam tubes on many coal fired boilers. MgO prevents the slags from forming hard and uniform deposits. The treated deposits are typically friable and easily removed by sootblowing. Cleaner water walls enhance heat absorption in the lower furnace.

A combination of these two effects can explain the observed phenomenon. A combustion catalyst improves the combustion efficiency but cannot maintain the FEGT and main steam temperature if water walls are slagged. On the other hand, clean water walls cannot lower the FEGT and main steam temperatures if poor combustion causes the flame to elongate and reach the upper furnace. Therefore, the observed MW increase without FEGT and main steam temperature excursions is likely to be the result of both increased heat generation (combustion catalyst) and increased heat absorption (Mg(OH)₂) in the lower furnace. Whatever the explanation, the results are surprising and of greater commercial value than might be expected by combining the two treatments.

The above description is for the purpose of teaching the person of ordinary skill in the art how to practice the invention. It is not intended to detail all of those obvious modifications and variations, which will become apparent to the skilled worker upon reading the description. It is intended, however, that all such obvious modifications and variations be included within the scope of the invention which is defined by the following claims. The claims are meant to cover the claimed components and steps in any sequence which is effective to meet the objectives there intended, unless the context specifically indicates the contrary.

Claims

1. A process for improving the operation of combustors, comprising:

burning a carbonaceous fuel in the presence of a combustion catalyst in the fuel or injected into the combustor apart from the fuel;

determining combustion conditions within a combustor that can benefit from targeted in-furnace treatment chemical;

locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished; and,

based on the determinations of the previous step, introducing targeted in-furnace treatment chemical.

2. A process according to claim 1 wherein the combustion catalyst comprises a metal compound wherein the metal is selected from the group consisting of copper, iron, magnesium, calcium, cerium, barium, manganese, zinc and mixtures of any of these.

3. A process according to claim 1 wherein the combustion catalyst comprises calcium nitrate.

4. A process according to claim 1 wherein the concentration of the targeted treatment chemical in a slurry or solution is within the range of from about 1 to about 100%.

5. A process according to claim 1 wherein the combustion catalyst is introduced either in-fuel or in-furnace at a dosage rate of from about 0.2 to about 0.8 kg per 1000 kg of carbonaceous fuel burned in the combustor.

6. A process according to claim 1 wherein the targeted treatment chemical is introduced into the furnace at a dosage rate of from about 0.2 to about 0.5 kg per 1000 kg of carbonaceous fuel burned in the combustor.

7. A process according to claim 1 wherein the targeted treatment chemical comprises a slurry of magnesium oxide or magnesium hydroxide as a slag reducing chemical and a combustion catalyst.

8. A process according to claim 6 wherein targeted treatment chemical is introduced at more than one elevation.

9. A process for improving the operation of combustors, comprising:

burning a carbonaceous fuel containing a combustion catalyst and a slag and/or corrosion controlling chemical;

determining combustion conditions within a combustor that can benefit from targeted in-furnace treatment chemical for control of slag and/or corrosion;

locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished; and,

based on the determinations of the previous step, introducing targeted in-furnace treatment chemical.

10. A process according to claim 9 wherein the combustion catalyst is introduced at a dosage rate of from about 0.2 to about 0.8 kg per 1000 kg of carbonaceous fuel burned in the combustor.

11. A process according to claim 9 wherein targeted treatment chemical is a combustion catalyst.

12. A process for reducing the opacity of plume released to the atmosphere from large-scale combustors, comprising:

determining the effectiveness of targeted in furnace injection of slag and/or corrosion and/or plume control chemicals;

determining the effectiveness of adding slag and/or corrosion and/or plume control chemicals to the fuel;

determining the effectiveness of adding combustion catalysts to the fuel;

determining the effectiveness of adding combustion catalysts to the furnace;

determining the effectiveness of targeted in furnace injection of combustion catalysts;

determining the effectiveness of various combinations of the above treatments; and

selecting a treatment regimen employing one or more of the above treatments.

13. A process according to claim 12, wherein the combustion catalyst comprises a metal compound wherein the metal is selected from the group consisting of copper, iron, magnesium, calcium, cerium, barium, zinc and mixtures of any of these.

14. A process according to claim 12, wherein the targeted treatment chemical is magnesium oxide or magnesium hydroxide in a vehicle.

15. A process according to claim 12, wherein the selected treatment regimen comprises at least three of the above treatments.

16. A process according to claim 15, wherein the combustion catalyst comprises a metal compound wherein the metal is selected from the group consisting of copper, iron, magnesium, calcium, cerium, zinc, zinc and mixtures of any of these.

17. A process according to claim 15, wherein the targeted treatment chemical is a slurry of magnesium oxide or magnesium hydroxide.

18. A process for improving the operation of combustors, comprising:

burning a carbonaceous fuel in the presence of a combustion catalyst comprising a composition of calcium, copper, barium, manganese or a mixture of these in the fuel or injected into the combustor apart from the fuel;

determining combustion conditions within a combustor that can benefit from targeted in-furnace treatment chemical;

locating introduction points on the furnace wall where introduction of targeted in-furnace treatment chemical could be accomplished; and,

based on the determinations of the previous step, introducing targeted in-furnace treatment chemical.

19. A process for increasing heat output of a combustor burning carbonaceous fuel in a flame, comprises:

determining the positions for effective introduction of slag controlling chemical;

based on the determination of the previous step, introducing targeted slag controlling chemical treatment in an amount effective to reduce slag; and

introducing a combustion catalyst into the flame in an amount effective to improve combustion.

20. A process according to claim 19 wherein the slag controlling chemical comprises a slurry of magnesium oxide or magnesium hydroxide as a slag reducing chemical and combustion catalyst comprises a composition of calcium, copper, barium, manganese, or a mixture of any of these.