COMBUSTION OF FUEL CONTAINING ALKALINES
BACKGROUND AND SUMMARY OF THE INVENTION
There are abundant fossil fuels which contain low melting point alkaline compositions (usually alkali metal salts) , particularly lignite and salty brown coals. However only .a small portion of such fossil fuels are utilized com¬ mercially because of the difficulties in producing energy from burning the lignite or the like. Typically, lignite is burned on a grate in a boiler furnace. However this requires high combustion temperatures, in the range of 1200-1500°C, which causes sintering of the fuel. At these temperatures, the sulfates and chlorides evaporate causing condensate on the walls of the furnace and other surfaces, and enhancing the formation of deposits on the boiler heat transfer tubes causing corrosion of the tubes and poor heat transfer. In order to deal with this prob¬ lem, typically the furnaces must be frequently shut down and the deposits removed from the heat transfer tubes, something that is difficult to do.
Although fluidized bed reactors are known to have many advantages over conventional boiler furnaces, in the past it has not been considered practical to burn many types of lignite and salty brown coal in fluidized bed reactors. This is because the alkalines in the lignite cause agglo¬ meration of the bed material. The higher the alkali metal salt content of the fuel, the lower the agglomeration temperature is.
Conventional fluidized bed combustors are typically oper¬ ated in the relatively narrow temperature range of about 750-950 C, having a dense bed in the lower part of the reactor and a lean region in the upper part of the reactor. At the lower end of the temperature range the
combustion of the fuel deteriorates, and at the upper end of the range the risk that the bed material will sinter or agglomerate increases. It is very hard to keep an even temperature in a conventional fluidized bed reactor when burning fuels of high calorific values. High local tem¬ perature variations will occur, leading to sintering or agglomeration of particles. Especially the temperature above the fluidized bed tends to rise too high as cooling in the lean upper region, due to low heat transfer rates, is difficult to accomplish.
It has been suggested in US 3,907,674 to burn waste streams, low calorific alkali metal chloride containing sludges, in conventional fluidized bed reactors. By en¬ suring the presence of sufficient additives such as re¬ active silica and alkali metal oxides, sticky compounds are prevented from accumulating in the bed. Relatively high amounts of additives have to be' used as the very fine particles which would have the best reactivity cannot be used as they would immediately flow through the bed and out of the reactor almost inreacted with the off gases. Coarse particles big enough to stay in the fluid¬ ized bed are less effective and must be added in over¬ doses. During combustion in a conventional fluidized bed the reactor load must be held relatively constant for avoiding local temperature variations, as low temperatures have negative effects on the combustion process and high temperatures cause agglomeration of particles. Especially, if high calorific fuels containing alkalines were to be combusted in conventional fluidized bed reactors, very high amounts of additives should be used for preventing agglomeration at local high temperature locations.
According to the present invention a method is provided which solves the long felt need of being able of effect¬ ively burn fuel containing alkaline compositions, such as
lignite, and recover energy therefrom in a relatively simple and straight-forward manner. According to the present invention, this is accomplished utilizing a cir¬ culating fluidized bed reactor also called a fast fluid¬ ized bed reactor.
According to the invention it is possible to burn solid fuel having low melting point alkaline compositions in a fluidized bed reactor by: using the fast fluidized bed reactor, which has a relatively uniform temperature throughout the reaction chamber and particle circulation system; and by the addition to the reaction chamber of a reactant material capable of reacting with the low melting point alkaline compositions of the fuel to pro¬ duce high melting point alkali metal compounds during combustion. The alkali metal compounds produced during combustion have a high enough melting point so that the reactor may be operated at a desirable temperature (within the range of about 750-950 C) without melting. In this way agglomeration of the bed material, sintering of the fuel, and enhanced formation of deposits on operable components of th.e reactor 'are prevented.
Fast fluidized bed reactors utilized in the combustion processes comprise an upright combustion chamber, having substantially vertical peripheral walls. The walls in the lower region of the combustion chamber may be inwards inclined and they are often made as refractory walls. The upper walls in the reactor are made as tube walls. The combustion chamber has one or more inlets for the particulate fossil fuel which is to be combusted. Inlets for reactant material are provided preferably in the lower part of the reactor. Inlets for secondary air can be disposed at different levels in the peripheral walls. Primary air is normally supplied to the combustion chamber through a windbox or air chamber beneath the combustion chamber. The air is supplied through nozzles or holes in
a grid plate which is disposed between the combustion chamber and the windbox. In the fast fluidized bed reactor the air is supplied through the nozzles at a velocity high enough, to fluidize the particles in the combustion chamber to a stage where a substantial portion of the particles is transported out of the combustion chamber with the ex¬ haust gases. A bed can be maintained in the combustion chamber only by recirculation of particles entrained with the gases and separated from the off gas by a high effi¬ ciency separator e.g. a cyclone-. The particles are re¬ turned to the combustion chamber through a return pipe. The solids concentration in the combustion chamber de¬ creases continuously up the chamber and does not show a definite border between a dense bed and a freeboard region.
Notwithstanding the high gas velocity the solids velocity in the combustion chamber is relatively low. The fast bed condition is marked by relatively high solids concen¬ trations and good mixing and heat transfer between gases and solids. Due to the large particle amounts circulating in the system and good mixing throughout the whole cir¬ culating path, combustion chamber, separator and return pipe, a uniform temperature throughout the system ' is achieved. The temperature can easily be controlled and held throughout the system at an optimal range by changing the particle density or flow rates. The danger of overheating and consequent agglomeration or sintering of particles is minimized. The fuel is completely com¬ busted due to optimal temperature conditions. Due to more efficient and long contact between particles and gases high reaction rates for reactions taking place in the system are achieved. The alkalines in the fuel will have time to react completely with the additives. The need for additives is decreased as even very fine 10-300 μm
additive particles can be used in this system as the par¬ ticles entrained with the off gases are recycled to the combustion chamber.
The reactant material utilized according to the invention comprises an oxide, or a hydroxide which is converted to an oxide during combustion, of the group consisting of aluminum, calcium, magnesium, silica, iron, titanium, and mixtures of two or more of aluminum, calcium, magnesium, silica, iron, and titanium. If silica oxide is used, it desirably is used with a metal oxide. Typically sufficient metal oxide is added so that the molar ratio of metal of the metal oxide to metal of the alkali metal salts in the fuel is at least about 1.0. Preferably, the reactant material comprises kaolin (clay) which includes oxides of all of silica, aluminum, iron, titanium, calcium, and mag¬ nesium, and which reacts with the fuel and the circulating bed material to form high melting temperature sodium com¬ pounds. Typically the molar ratio of aluminum in the kaolin to sodium plus potassium in the fuel is at least 1.0.
It is desirable to also add limestone with the reactant material in order to absorb sulfur. Further, since the combustion of the fuel is for the purpose of producing useful heat energy (which may be transformed into steam energy, electricity, or the like) , it is desirable to recover heat energy directly from the reaction chamber utilizing heat recovery apparatus disposed on the surface of, or in, the reaction chamber. Such heat recovery appar¬ atus, which is conventional per se, has had minimal utility in the past when lignite was the fuel due to the build up deposits on the heat recovery surfaces. How¬ ever in view of the fact that the formation of deposits on the heat recovery tubes is minimized according to the invention, such apparatus can be effectively utilized in the reaction chamber itself.
After start-up, fast fluidized bed operated according to the invention has little sand or other bed-forming consti¬ tuents in the fluidized bed. While some sand, or other accessory bed material is added during start-up, once a steady state condition is achieved the circulating bed material comprises mainly the lignite fuel, kaolin, and ash; still agglomeration of the bed material does not occur. The reactor is operated, including by withdrawing and recovering heat directly from the reaction chamber, so that the temperature in all parts of the reaction chamber is between about 750-950 C, and specifically is lower than the melting temperature of the alkali metal compounds formed by the reaction of the kaolin (or the like) with the alkali metal salts in the fuel, during combustion.
It is the primary object of the present invention to provide a simple yet effective method for burning fuel con¬ taining low melting point alkaline compositions, to produce and recover heat energy. This and other objects of the invention will become clear from an inspection of the detailed description of the invention, and from the- appended claims.
BRIEF DESCRIPTION OF THE DRAWING
The drawing figure is a schematic illustration of an exemplary circulating fluidized bed reactor with which the method according to the invention may be carried out.
DETAILED DESCRIPTION OF THE DRAWING
The circulating fluidized bed reactor illustrated in the drawing is a basically typical circulating reactor, having heretofore been used for the successful combustion of a diversity of fuels to recover heat from the fuels, in¬ cluding coal, oil, wastes, and the like. While such
reactors have been utilized to burn lignite and salty brown coals, or like fuels containing low melting point alkaline compositions such as alkali metal salts, the results of combustion of such fuels have been much less satisfactory than for other fuels. In particular problems of agglomeration of the bed material, sintering of the fuel, and enhanced formation of deposits on the heat recovery tubes, have been exprienced, and made such fue^-s impractical.
The reactor in the drawing includes a hopper 1 in which a solid alkaline-containing fuel, such as lignite or salty brown coal having a high sodium content, is pro¬ vided. The fuel is fed from the hopper 1 at a controlled rate by a feed screw 2 to a mixing chamber 3. A reactant material according to the invention, which reacts with the low melting point alkaline compositions of the fuel to produce high melting point alkali metal compounds, is supplied from hopper 4 at a controlled rate by the feed screw 5 to the mixing chamber 3. Limestone may also be added to the mixing chamber 3, as indicated schemati¬ cally by reference numeral 5' in the drawing, to absorb sulfur in the reaction chamber.
The reactant material preferably is added in the form of particulate solids, and is desirably at least one metal oxide (or a hydroxide which is converted to an oxide during combustion) of the group aluminum, calcium, mag¬ nesium, iron, or titanium, or silica oxide. Preferably the reactant material is a mixture of several of such metal oxides and/or silica oxide, one particularly pre¬ ferred material being kaolin (clay) , which includes sig¬ nificant proportions of silica oxide and aluminum oxide, and also contains some calcium oxide, magnesium oxide, iron oxide, and titanium oxide.
Also added to the mixing chamber 3 are solid particulates separated in the cyclone separator 6 of the conventional ciculating fluidized bed reactor 7. Combustion of the fuel takes place in the reaction chamber 71 of the reactor 7, and exhaust gases are procuded, which exit the reaction chamber 7' through the exhaust duct 8.
The mixture of solid particulate fuel, reactant material, limestone, and particles passes through duct 9, the return pipe for recycled particles, to the lower end of the reaction chamber 7'. A blower 10, or a like device, is utilized to generate a flow of air so that primary and secondary air is added through the conduits 11, 12, respectively, to the reaction chamber 7'. At least one of the sources of gas 11, 12, includes oxygen containing gas to react with the fuel. The gas fluidizes the bed of solid material, and a large volume of material continuously cir¬ culates from the reaction chamber 7' , through cyclone separator 6, and back to conduit 9. In this way unreacted reactant material (e.g. kaolin) is recovered so that the amount of reactant material utilized is minimized.
During start-up of the reactor 7, sand, or a similar inert bed material, is introduced into the reaction chamber 7. However once a steady state condition is established (i.e. after start-up) , no further bed material is intro¬ duced, but rather the circulating bed during the steady state condition comprises mainly the solid fuel particles, kaolin, and ash.
Exhaust gases, after passing the cyclone separator 6, pass to the flue gas filter 13, in which ash is separated from the gas. The ash may be disposed of, and/or at least a portion of the ash may be recirculated, through conduit 14', to the mixing chamber 3. The blower 10 supplies air for transporting the ash to the mixing chamber 3.
Since the purpose of combustion of the lignite or brown coal is to recover heat energy (which ultimately may take the form of steam or electricity) , it is desirable to provide heat transfer surfaces 15 which are disposed in the wall 16 of the reaction chamber 7', or within the reaction chamber 7'. Preferably heat is also recovered from the flue gases utilizing conventional convective boiler 17 disposed between the cyclone separator 6 and the filter 13.
In the circulating bed reactor 7, a large flow of cir¬ culating material is maintained, which results in a substantially uniform temperature throughout the reaction chamber 7', which is useful in ensuring that the reactor 7 is operated in such a way that the maximum temperature therein is lower than the melting point of the alkali metal compounds produced by reaction of the reactant and the fuel alkaline compositions, during combustion. Typi¬ cally, the reactor would be operated at a temperature of between about 750-950 C, with an optimum temperature of about 865 C. Fuel which has not burned and which is contained in the flue gases, as well as unreacted reactant material such as kaolin, are efficiently recovered by the cyclone separator 6, and recirculated through mixing chamber 3 and chute 9.
The feed screws 2 and 3 are controlled depending upon the amount of recycled fuel and reactant mateial, and also to control the temperature in the reaction chamber 7'. Further, the proportions of reactant material in the fuel are controlled so that the ratio of metal of the metal oxide to metal of the alkali metal salts (e.g. Na and K) , is at least about 1.0. Also the amount of oxygen con¬ taining gas added to the reaction chamber 7', and the throughput of heat recovery fluid through the heat re¬ covery apparatus 15, as well as other parameters, may be controlled to maintain the temperature in the reaction chamber 7' at a desired level.
Example
Tests have been carried out on combustion of salty brown coal in the presence of kaolin in a pilot plant cir¬ culating fluidized bed reactor as illustrated in the drawing. Representative samples of the fuel and the reac¬ tant material were analyzed. The following analyses were obtained:
Coal analysis
Dry solids
content Ash in C in S in Na in K in Cl in Ca in Mg i
(d.s) d. s. d. s. d.s. d.s. d. s. d.s. d. s. d.s.
% % % % % % % % %
3.2 15.8 61.9 3.7 2.60 0.07 2.71 1.62 0.20
Kaolin analysis
sio2 48. 7 %
Al2°3 36 . 0 %
Fe2°3 0 . 8 % τio2 0 . 05 %
CaO 0 . 06 %
MgO 0 . 25 % κ2o 2. 12 % a20 0 . 10 %
Sand was introduced into the reactor as a starting material but during but during operation the circulating bed consisted mainly of brown coal, kaolin and ash. The mass flow rates of the fuel and the additive and the ratio of Al/ (Na and K) were varied. The temperature in the reactor 7 was maintained at about 8 5°C, and was substantially uniform throughout the chamber 7'. The reaction chamber was cooled by heat transfer tubes 15 disposed in the reaction chamber.
No agglomeration of the bed material and no sintering on the heat recovery surfaces occured when the Al/ (Na and K) molar ratio was 1.0 or higher.
It will thus be seen that according to the present inven¬ tion it is possible to effectively burn fuel having low melting point alkaline compositions, to produce and re¬ cover heat energy, in a fluidized bed reactor without agglomeration of the bed material, sintering of the fuel, or enhanced formation of deposits on operable components (particularly heat transfer surfaces) of the reactor. While the invention has been herein shown and described in what is presently conceived to be the most practical and preferred embodiment thereof, it will be apparent to those in the art that many modifications may be made thereof within the scope of the invention, which scope is to be accorded the broadest interpretation of the appended claims so as to encompass all equivalent methods and procedures.