Patent Application
20140102342
The present invention relates generally to the field of circulating fluidized bed (CFB) reactors and boilers such as those used in electric power generation facilities and industrial facilities. It particularly relates to CFB reactor arrangements containing both a CFB and one or more bubbling fluidized bed(s) (BFB's) feeding materials into a lower portion of the CFB reactor enclosure, and to non-mechanical valves for controlling solids flowing between slow bubbling bed region(s) and highly-fluidized CFB regions.
Reactors and boilers can use CFB's and BFB's together in various arrangements. For example, U.S. Pat. No. 5,533,471 teaches placing the slow BFB below and to the side of the bottom of the faster moving CFB chamber. In U.S. Pat. No. 5,526,775, the slow BFB is above and to the side of the fast CFB. U.S. Pat. No. 5,190,451, to Goldbach, illustrates a CFB chamber having a heat exchanger immersed within a fluidized bed at the lower end of the chamber. U.S. Pat. No. 5,184,671 to Alliston et al. teaches a heat exchanger having multiple fluidized bed regions. The present invention can be adapted for use with these or other arrangements.
The present invention also relates to valves for regulating the movement of solids, including solid fuel, between BFB's and CFB's. It relates, in particular, to non-mechanical valves to control the flow of granular solids between fluidized beds by regulating local fluidization at an opening in a wall between enclosures. As a general principal, such valves “open” by sufficiently aerating the area immediately around an opening between the enclosures so that the particles are “fluidized” and flow through the opening in a manner similar to a liquid. The valves “close” by stopping or slowing fluidization around the same openings so that the particles no longer behave and flow similarly to a liquid.
For example, U.S. Pat. No. 6,532,905 to Belin et al. describes a CFB boiler with a controllable in-bed heat exchanger (IBHX). The boiler comprises both a CFB furnace and a separately-controllable BFB heat exchanger located inside of the CFB furnace. Heat transfer in the BFB's heat exchanger is controlled by controlling the rate of solids discharged from the lower part of the BFB into the larger CFB furnace. The discharge control may be accomplished using at least one non-mechanical valve between the CFB and the BFB. The non-mechanical valve may be operated by controlling flow rate of fluidizing gas in the vicinity of the valve. Reducing or completely shutting off fluidizing gas flow to the controlling fluidizing means (typically, bubble caps) hampers local fluidization and, as a result, slows or stops solids movement through the non-mechanical valve, thus allowing the control of the solids discharged from the BFB to the CFB (see, for example, Published Patent Application US 2011/0073049 A1).
One problem with the prior art non-mechanical valve of Belin et al. is that solid bed material may fall into the fluidizing means (e.g., bubble caps), particularly when the fluidizing gas flow is shut off to limit the flow of solids through the valve. The problem can be particularly severe for idle fluidizing means that are adjacent to active fluidizing means. This can block the fluidizing gas flow once it is turned back on, and can hinder further use of the non-mechanical valve.
Another problem of reducing the flow rate of the fluidizing gas in the vicinity of the non-mechanical valve is bed material agglomeration. Turning off the fluidizing gas reduces local bed mixing. As bed solids combustion continues, there may be an increase in the local bed temperature that can lead to solid material agglomeration. Agglomeration may also happen elsewhere in the boiler, with the agglomerates eventually moving towards the non-mechanical valve along with the flow of other solids in the system. Such agglomerates, whether forming or accumulating in the vicinity of the valves, can eventually plug the valve and hinder its operation.
Yet another problem with operating a CFB boiler including a BFB is that the vigorous fluidization of the CFB furnace can interfere with local fluidization in the vicinity of the non-mechanical valve. This can interfere with control of solids flow from the BFB into the CFB through the valve which relies, at least in part, on controlling fluidization.
The present invention provides an improved non-mechanical valve assembly which can be used with prior art fluidized bed boilers including, but not limited to, the CFB boiler taught by U.S. Pat. No. 6,532,905 to Belin et al. comprising a BFB linked to a CFB. As mentioned, non-mechanical valves can be used to control the flow of granular solids between enclosures by regulating local fluidization at an opening in a wall between the enclosures. Typically, such valves “open” by injecting fluidizing gas into the area immediately around an opening between the two enclosures so that the solid particles there are “fluidized”, i.e., behaving in a manner similar to a liquid. The solid particles flow through the opening in the wall when they are fluidized. The valves “close” by stopping or slowing gas injection, thereby ending fluidization around the openings. Absent fluidization, the solid particles no longer behave or flow like a liquid, and thus no longer flow through the opening in the wall, or else move through at a much lower rate.
The present invention eliminates problems associated with temporarily closing non-mechanical valves by reducing or stopping the flow of fluidizing medium. The problem of solid material backsifting into the fluidization means when fluidizing gas flow is turned off, and thereby causing their blockage, is solved by providing collectors. These collectors are typically placed below the fluidization means, so that solids backsifting into the fluidization means will fall into the collectors and be stored below a level where they can impede the flow of the fluidizing gas. The solids are periodically or continuously removed from the collectors to keep their level sufficiently low. In a preferred embodiment, the collectors can be emptied during boiler operation without interrupting the flow of fluidizing medium, ideally without breaking any seal that would allow escape of fluidizing medium.
Removal means are also provided in the valve arrangement for removing agglomerates from the solids flow based, for example, on their larger size and greater weight. As a result, the probability of large agglomerates sticking in and blocking valves is reduced. In a preferred embodiment, the removal means are sealed against furnace pressure, the rate of solids removal out of the system is controlled, and the removed material is cooled.
The present invention also alleviates interference between the intense fluidization of the CFB furnace and the fluidization-controlled non-mechanical valve between the CFB and the BFB. Walls projecting into the BFB and/or CFB from the BFB enclosure wall form channels or tunnels, which block lateral solids movement near the valve openings. These walls shield the opening between the CFB and the BFB from the most extreme effects of the CFB solids churning, and thus improve control over local fluidization and the function of the non-mechanical valves.
In a preferred embodiment, there is little or no solids flow through the non-mechanical valve, i.e. the valve is “closed,” when local fluidization by independently controlled fluidizing means is turned off. The invention teaches how to design passages between BFB's and CFB's that substantially block particle flow in the manner of an L-valve. All of the improvements of the invention can be applied to a range of non-mechanical valves regulating granular material flow between different compartments using local fluidization, particularly where at least one of the compartments contains a fluidized bed.
Accordingly, one aspect of the present invention is drawn to a circulating fluidized bed boiler comprising: a circulating fluidized bed boiler reaction chamber comprising side walls and a distribution grid defining a floor at a lower end of the circulating fluidized bed boiler reaction chamber, the distribution grid being adapted for providing fluidizing gas into the circulating fluidized bed boiler reaction chamber; a bubbling fluidized bed located within a lower portion of the circulating fluidized bed boiler reaction chamber and being bound by enclosure walls and by the floor of the circulating fluidized bed boiler reaction chamber; at least one controllable in-bed heat exchanger, the in-bed heat exchanger occupying part of the circulating fluidized bed boiler reaction chamber floor and being within the enclosure walls of the bubbling fluidized bed; at least one non-mechanical valve designed to permit the control of solids discharge from the bubbling fluidized bed into the circulating fluidized bed boiler reaction chamber, the valve comprising at least one opening in the enclosure wall of the bubbling fluidized bed, and including at least one independently controlled fluidizing means located at least at one of upstream and downstream of the opening; the at least one independently controlled fluidizing means each being connected to corresponding fluidizing medium supply means, the independently controlled fluidizing means being adapted for controlling a flow rate of solids from the bubbling fluidized bed to the circulating fluidized bed boiler reaction chamber, the independently controlled fluidizing means being controlled separately from the distribution grid; the independently controlled fluidizing means and the fluidizing medium supply means being at least one of connected to and comprising collectors, the collectors being adapted for collecting solids in the event of backsifting of solids into the fluidizing means such that the collected solids do not obstruct the supply of fluidizing medium; valves for sealing at least one of the collectors, the fluidizing means, and the fluidizing medium supply means, to allow removal of backsifted solids from the collectors during operation of the circulating fluidized bed furnace; the non-mechanical valve further comprising at least one solids removal means, being adapted for removal of agglomerates, located at least one of upstream and downstream of said at least one opening in the bubbling fluidized bed enclosure wall; the removal means each being connected to at least one screw cooler adapted for sealing against furnace pressure, for controlling solids discharge rate through the removal means, and for cooling discharged solids and agglomerates; the bubbling fluidized bed enclosure wall comprising a plurality of channel walls adjacent to one or more openings in the bubbling fluidized bed enclosure wall, the walls projecting generally away from the enclosure wall into at least one of the circulating fluidized bed and the bubbling fluidized bed, the channel walls being adapted to reduce lateral movement of solids in one or more directions perpendicular to the direction of solids discharge from the bubbling fluidized bed to the circulating fluidized bed.
Yet another aspect of the present invention is drawn to a circulating fluidized bed boiler comprising: a circulating fluidized bed boiler reaction chamber comprising side walls and a distribution grid for providing fluidizing gas into the circulating fluidized bed boiler reaction chamber; a bubbling fluidized bed in a compartment including at least one enclosure wall; at least one controllable in-bed heat exchanger, the in-bed heat exchanger being located within the compartment comprising the bubbling fluidized bed; at least one non-mechanical valve adapted to control solids discharge from the bubbling fluidized bed into the circulating fluidized bed boiler reaction chamber, the valve comprising at least one opening in the enclosure wall, and including at least one independently controlled fluidizing means located at least at one of upstream and downstream of the opening; the independently controlled fluidizing means each being connected to fluidizing medium supply means, the independently controlled fluidizing means being adapted for controlling a flow rate of solids from the bubbling fluidized bed to the circulating fluidized bed boiler reaction chamber, the independently controlled fluidizing means being controlled separately from the distribution grid; and collectors linked to the one or more independently controlled fluidizing means, the collectors being adapted for collecting solids in the event of backsifting of solids into the fluidizing means such that the collected solids do not obstruct a supply of fluidizing medium.
Yet another aspect of the present invention drawn to a non-mechanical valve arrangement for selectively controlling a flow of particulate solids between two compartments wherein at least one of said compartments comprises a fluidized bed, the non-mechanical valve arrangement comprising: an enclosure wall separating the two compartments; an opening in the enclosure wall linking the two compartments; independently controlled fluidizing means located at least one of upstream and downstream of the opening, the independently controlled fluidizing means being connected to fluidizing medium supply means and being adapted for selectively controlling the flow of particulate solids through the opening; one or more collectors connected to the independently controlled fluidizing means, the collectors being adapted for collecting any solids entering the fluidizing means such that the collected solids do not obstruct the supply of fluidizing medium to the fluidizing means; and one or more independently controlled solids removal means located at least one of upstream and downstream of the opening, the removal means being adapted for removal of solids and agglomerates.
These and other non-limiting aspects and/or objects of the disclosure are more particularly described below.
The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages, and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which a preferred embodiment of the invention is illustrated.
In the drawings:
A more complete understanding of the processes and apparatuses disclosed herein can be obtained by reference to the accompanying drawings. These figures are merely schematic representations based on convenience and the ease of demonstrating the existing art and/or the present development, and are, therefore, not intended to indicate relative size and dimensions of the assemblies or components thereof.
Although specific terms are used in the following description for the sake of clarity, these terms are intended to refer only to the particular structure of the embodiments selected for illustration in the drawings, and are not intended to define or limit the scope of the disclosure. In the drawings and the following description below, it is to be understood that like numeric designations refer to components of like function.
The modifier “about” used in connection with a quantity is inclusive of the stated value and has the meaning dictated by the context (for example, it includes at least the degree of error associated with the measurement of the particular quantity). When used with a specific value, it should also be considered as disclosing that value. For example, the term “about 2” also discloses the value “2” and the range “from about 2 to about 4” also discloses the range “from 2 to 4.”
As is known to those skilled in the art, heat transfer surfaces which convey steam-water mixtures are commonly referred to as evaporative boiler surfaces; heat transfer surfaces which convey steam therethrough are commonly referred to as superheating (or reheating, depending upon the associated steam turbine configuration) surfaces. Regardless of the type of heating surface, the sizes of the tubes, their material, diameter, wall thickness, number, and arrangement are based upon temperature and pressure for service, according to applicable boiler design codes, such as the American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code, Section I, or equivalent other codes as required by law.
To the extent that explanations of certain terminology or principles of the heat exchanger, boiler, and/or steam generator arts may be necessary to understand the present disclosure, and for a more complete discussion of CFB boilers, or of the design of modern utility and industrial boilers, the reader is referred to the reader is referred to Steam/its generation and use, 41st Edition, Kitto and Stultz, Eds., Copyright © 2005, The Babcock & Wilcox Company, Barberton, Ohio, U.S.A., Lib. of Congress No. 92-74123, the text of which is hereby incorporated by reference as though fully set forth herein.
The present invention solves several problems encountered with non-mechanical, fluidizing-medium controlled valves of the prior art. In a particularly preferred embodiment described herein to demonstrate the invention, an improved non-mechanical valve is used with a CFB boiler comprising both a CFB reaction chamber and a BFB with IBHX located within the reaction chamber.
Referring now to the drawings, where like reference numerals designate the same or similar elements throughout the drawings,
The CFB may be comprised of solids made up of fuel 5, the ash of the fuel 5, sorbent 6 and, in some cases, external inert material 7 fed through at least one of the walls 2 of the furnace. Many other possible solid components are known to those of skill in the art. The CFB is fluidized by injection of the primary air 8 and/or by other gases. The fluidizing air is preferably supplied through a distribution grid 9 which may comprise a part of the furnace floor, and which typically comprises bubble caps.
Some solids 15 are entrained upward by gases resulting from the fuel combustion and eventually reach a particle separator 16 near the furnace exit. While some of the solids 17 pass the separator, the bulk of the solids 18 are captured and recycled back to the furnace. Part of the captured solids 18, along with other solids 19 falling out of the upflow solids stream 15 driven by gravity will enter the BFB 4.
The BFB 4 is fluidized by fluidizing medium 25 fed through a distribution grid 26, which may comprise part of the furnace floor. This will generally be a separate grid from the distribution grid 9, which fluidizes the CFB. As is well known to those skilled in the art, the most common design of a distribution grid would be an array of bubble caps fed from a corresponding source of fluidizing medium. A bubble cap is comprised of a bubble cap proper and a supply pipe, typically referred to as the stem, which interconnects the fluidizing medium with the fluidized bed. Fluidizing gas is conveyed upwardly along the stem into the bubble cap, from which it is distributed to the fluidized bed via a plurality of outlet holes. Jets of fluidizing gas exiting from the outlet holes penetrate into the CFB or BFB fluidizing particulate solids in the area around each bubble cap.
Means for removing solids from the CFB and BFB (27 and 28, correspondingly) are preferably provided in the pertinent areas of the floor.
The BFB 4 is separated from the CFB by an enclosure wall 30 comprising one or more non-mechanical valves 40. The rate of solid recycle 35 back to the CFB through one or more non-mechanical valves 40 is controlled by controlling one or more streams of the fluidizing medium 45 and 46. The streams of fluidizing medium are preferably provided through one or more independently controlled fluidizing means 86, 87, 94, 95, which are located upstream (towards the BFB) and/or downstream (towards the CFB) of the opening(s) 85 in the enclosure wall 30 (
Gas flow to the vicinity of the non-mechanical valve promotes solids discharge from the lower part of the BFB 4 into the CFB 1. Independent control of these flow rates, e.g., turning them on and off in alternate cycles, allows for smoothing the solids discharge rate. Particular fluidizing medium control patterns (frequency of cycling, length of a cycle, etc.) depend on properties of the bed material and boiler operation requirements and should be established during boiler commissioning.
The fluidizing gas streams 45, 46 are preferably controlled independently of the CFB distribution grid 9 and the BFB distribution grid 26, and may be controllable independently of each other, but are most preferably regulated in accordance with each other in operation. As used in the claims, the term “independently controlled fluidizing means” always refers to fluidizing means which are capable of being controlled independently of the distribution grids 9, 26, and preferably, but not necessarily, independent of other independently controlled fluidizing means in the same row or in different rows. In one preferred embodiment, independently controlled fluidizing means are provided in from one to six rows on each of one or both sides of a enclosure wall 30, each row comprising a plurality of bubble caps. In a most preferred embodiment the fluidizing means in each row are controlled together as a row, but each row can be controlled separately from any other rows and separately from the distribution grids 9, 26. Typically, each row will be parallel to a enclosure wall 30, the wall having one or several openings 85. Thus, controlling the fluidization of each row may affect more than one valve 40 if the row is near more than one opening 85. Embodiments where each valve is controlled separately, and where fluidizing means are not controlled as a row, are also possible, however.
Persons of skill in the art will appreciate that the non-mechanical valves 40 can include wall openings 85, independently controlled fluidizing means 86, 87, 94, 95, solids removal means 60, and other components in a wide variety of configurations.
The independently controlled fluidizing means 86, 87, 94, 95 are typically bubble caps, but other embodiments are possible. The independently controlled fluidizing means may comprise the same type of bubble caps as found in the distribution grids 9, 26, or they may take different forms.
The enclosure wall 30 is preferably made of tubes or pipes 50 that are cooled by water or steam. The tubes are usually protected from erosion and corrosion by a protective layer, commonly formed by a refractory held by studs welded to the tubes. The tubes may be horizontal as shown in
In a preferred embodiment, secondary air 70 or another gas is supplied through nozzles 75. The nozzles 75 are typically located on the opposite walls 2 of the CFB furnace somewhat above the floor of the furnace.
As is well known to those skilled in the art, the most common embodiment of a distribution grid, such as 9 for CFB or 26 for BFB, would be an array of bubble caps fed from a corresponding source of the fluidizing medium, i.e. 8 for CFB and 25 for BFB. To prevent erosion of the bubble caps (or other fluidizing means) in the vicinity of the opening 85 by the solids flow through the opening, the tops of the bubble caps should not be higher than the bottom of the opening.
The non-mechanical valve 40 is preferably equipped with solids removal means 60 and 61. The removal means 60 and 61 are adapted to allow passage for removal of agglomerates that can be formed at, or transported to, the vicinity of the opening, and selectively remove agglomerates from the other solids based, for example, on their greater size and weight. Solids removal means 60 and 61 are preferably located both upstream and downstream of the opening 85, but their positions and quantity can vary. For example, solids removal means might only be provided on one side of each wall opening, and there may or may not be fluidizing means between the removal means and the nearest wall opening. Preferably, the solids removal means 60 and 61 are separately controlled. Preferably, the removal means 60 and 61 are sealed against furnace pressure, and to control solids discharge. This can be accomplished using screw coolers 88 and 89 that are also adapted to cool discharged solids, or by other means known to those skilled in the art.
Independently controlled fluidizing means 86, 87,94, 95 are preferably connected to corresponding collectors 92 and 93. Fluidizing medium 45 and 46 is preferably supplied to the upper parts of the collectors 92 and 93, respectively, from where it is distributed to corresponding fluidizing means. If backsifting takes place, such as when the fluidizing medium is turned off, any solids falling into the fluidizing means 86 and 87 should end up in the collectors 92 and 93. The level of accumulated solids in the collectors 92 and 93 should be maintained below the elevation of the supply of the fluidizing medium 45 and 46 so that backsifted solids do not affect operation of the fluidizing means 86 and 87.
Alternatively, the means 92 and 93 for collecting backsifted solids may be further separated from the path of the fluidizing medium 45, 46 to the corresponding fluidizing means. For example, the
In preferred embodiments the collectors 92, 93 can be emptied while the furnace is operating, and without turning off the fluidizing medium 45, 46 pressure to any fluidizing means. Sealing off the collectors 92 and 93 while removing the backsifted solids can be accomplished by rotary valves 96 and 97 or by other means known to those skilled in the art. For example, a rotary valve could be used to remove backsifted solids from the bottom of a collector, while the collector remains pressurized, without opening a direct path for the escape of fluidizing medium. Alternatively, the collectors themselves could be temporarily sealed off from the fluidizing medium pressure during emptying. It is preferable if the fluidizing medium streams 45 and 46 can be maintained while the collectors 92 and 93 are emptied to prevent backsifting of additional solids during emptying, and to allow uninterrupted operation of the boiler system.
The independently controlled fluidizing means 86, 87, 94, 95 can be located on either one or both sides of the solids removal means 60 and 61. The latter arrangement is exemplified in
Each fluidizing means 86 and 87, or each part of each fluidizing means (such as when a fluidizing means comprises multiple bubble caps), may be supplied with fluidizing medium 45 and 46 either individually or via shared sources of fluidizing medium 47 and 48 shared with other units. Similarly, solids collection means 92 and 93 may or may not be shared.
Arrangements where different fluidizing media may be selectively supplied to each fluidizing means—such as regular air or reduced oxygen air—may be used.
The applicants have found that the considerable turbulence of CFB's can interfere with fluidization in the vicinity of adjacent non-mechanical valves. This can affect the ability of such non-mechanical valves to regulate solids discharge rate, for example, from a BFB into a CFB furnace.
The applicants have discovered that controllability of solids discharge rate can be improved by creating channels parallel to the direction of the solids discharge. Such channels allow unobstructed solids movement through the opening, but suppress bed movement in other directions. These channels can be formed, for example, by walls 100 on the sides of opening 85. Each wall protrudes away from the enclosure wall 30 into at least one of the CFB and/or the BFB, preferably by a distance of at least one half of the width of the opening. The channel walls suppress lateral bed material movement in directions perpendicular to that of the solids discharge from the BFB to the CFB. See
Similar to other parts of the enclosure wall 30, the walls 100 and bridge surfaces 105 may comprise tubes 50 cooled by water or steam, and are preferably covered with refractory, firebrick or a similar substance.
The size, shape and length of the opening 85 can play a role in controlling the flow of granular solids from the BFB side of the enclosure wall 30 to the CFB furnace 1 side. In a preferred embodiment, solids will not flow substantially from the BFB side though the opening 85 to the CFB side of the enclosure wall 30 unless the solids are at least somewhat fluidized. Preferably, steady flow through the opening 85 can be restored using fluidization means 86, 87, 94, 95.
The area inside the enclosure wall 30 which may be a BFB under fluidization conditions, in combination with a properly dimensioned opening 85, can together function as an L-valve for regulating the flow of granular solids through the opening. As is known to those skilled in the art, L-valves allow reliable control of the rate of solids flow, including complete flow shutdown.
The L-valve geometry required for flow rate control depends on the properties of the solids, in particular, the solids' angle of repose. While most common bed material produced in CFB combustion has an angle of repose in the 35-40° range, in atypical cases the angle of repose may fall in the range of 30-45°. Given an angle of repose in the 35-40° range, the minimal depth-to-height ratio (horizontal:vertical ratio) of the channel 85 required for solids flow shutdown is about 1.4-1.2 for most common cases. The ratio may be as high as 1.7 or as low as 1.0 in unusual cases. See
The walls 100 and bridging surfaces 105 discussed above may, optionally, be designed to function as part of an L-valve in addition to regulating lateral fluidization movement.
In addition to the embodiments using walls 100, 105 described above, channels can be formed in other ways, e.g., by using the thickness of the enclosure wall 30, by forming opening 85 with pipe 110, and other means which will be apparent to one of skill in the art. Two examples are illustrated in
Solids discharge through one or more non-mechanical valves 40 can be stopped by stopping fluidization by the pertinent independently controlled fluidizing means 86, 87, 94, 95. This, however, may cause agglomeration of solids in the temporarily-stagnated bed in the vicinity of the shut down valve. This is particularly true when continued combustion causes localized temperature increase. Since formation of agglomerates is usually a slow process, it can be prevented by periodic fluidization of the stagnated bed. Such a fluidization can be brief relative to the duration of the idle period to minimize its effect on overall discharge rate, but of sufficient duration to break-up and prevent incipient agglomerates. For example, the areas adjacent to the wall openings or other regions might be fluidized for short periods spaced by longer periods of non-fluidization.
As discussed, local reductions in fluidization can result in local heat buildup due to continued combustion, leading to the formation of agglomerates. Thus, it is sometimes desirable to reduce the local heat release rate in areas of the bed where mixing may (at least temporarily) be reduced, such as the vicinity of the opening 85, to decrease the chances of forming agglomerates there. A reduction of the heat release rate around an opening 85 may be accomplished by using a fluidizing medium 45 and 46 with reduced content of oxygen, e.g. flue gas. Depending on the makeup of the fuel, the ash, and other solids, reducing oxygen content in the fluidizing medium down to 15% may be sufficient for preventing agglomeration. In other cases, its oxygen content should be reduced to 12%, or even as low as 9% or 6% to achieve adequate cooling. Low oxygen medium may be used in combination with the intermittent fluidization technique to prevent agglomerates.
It will be understood by persons of skill in the art that the improved non-mechanical valves of the present invention—comprising agglomerate removal means 60 and 61, backsifted solids collection means 92 and 93 connected to the fluidizing means 86, 87, 94, 95, perpendicular channel walls 100 and 105, valve openings having specific depth to height ratios, and/or other disclosed improvements—can be used in a variety of boilers and other devices comprising fluidized beds known in the art. Non-limiting examples are described in the patents identified in the Background section above, as well as in texts such as Steam/its generation and use, 41st Edition, Kitto and Stultz, Eds., Copyright © 2005, The Babcock & Wilcox Company, Barberton, Ohio, U.S.A., pp. 17-1-17-15. Lib. of Congress No. 92-74123.
The present disclosure has been described with reference to exemplary embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the present disclosure be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
While specific embodiments of the present invention have been shown and described in detail to illustrate the application and principles of the invention, it will be understood that it is not intended that the present invention be limited thereto and that the invention may be embodied otherwise without departing from such principles. In some embodiments of the invention, certain features of the invention may sometimes be used to advantage without a corresponding use of the other features. Accordingly, all such changes and embodiments properly fall within the scope of the following claims.
