Title of Invention	METHOD OF OPERATING A FLUIDIZED BED REACTOR SYSTEM, AND SYSTEM ,
Abstract	The present invention relates to a circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator. PRICE: THIRTY RUPEES

Title of Invention

METHOD OF OPERATING A FLUIDIZED BED REACTOR SYSTEM, AND SYSTEM ,

Abstract

The present invention relates to a circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator. PRICE: THIRTY RUPEES

Full Text	The present invention relates to a circulating fluidized bed reactor system Fluidized bed reactors, particularly circulating fluidized bed reactors, are extremely useful in practicing a wide variety of 10 reactions, such as combustion and gasification of fuel material. Gasification is an attractive way to convert energy of fuel material into a more useful form, producing combustible gas; or combustion of the fuel in the reactor may produce steam to drive a steam turbine. However under many circumstances, the gas is discharged from the 15 reactor (e.g. fuel product gas) may contain undesirable substances such as tar-like condensable compounds. These substances tend to turn sticky below certain temperatures, and therefore deposit or accumulate on surrounding surfaces, particular surfaces of gas cooling devices. 20 Gasification of solid fuel material in fluidized bed has been discussed in U.S. patents 4,017,272 and 4,057,402. The gasification process is generally stated to be characterized by following reactions: r The product gas usually contains substances which cause difficulties when the gas is cooled, i.e. compounds (e.g. tars) which turn sticky when cooled. The existence of these cause problems in cooling the product gas by depositing or accumulating on heat transfer surfaces of gas cooler. The problem of fouling of gas cooling surfaces has been addressed by using a direct heat transfer system, such as in U.S. patents 4,412,848 and 4,936,872. In these patents the product gas is led into fluidized bed gas cooler, and the fouling components are captured by particles of the fluidized bed. The use of a separate fluidized bed -- as described above -- is hardly an ideal solution to the problem, however, since the additional bed consumes space and requires construction and maintenance of different components, which can make costs prohibitive. Using indirect recuperator heat exchangers has also been fomid vmacceptable, however, due to exhaust fouling difficulties. The fouling problem described above is particularly acute under pressurized conditions, e.g. superatmospheric pressure of about 2-50 bars. Under such pressurized conditions conventional steam soot blowers do not work properly. The problems as indicated above do not exist solely during gasification, but also during combustion of a number of different types of fuel in a fluidized bed. For example when brown coal is burned the flue gases contain alkali species which condense on cooling surfaces, accumulating on the surfaces, fouling them, and causing corrosion of surrounding surfaces. Diffculties also occur particularly in the combustion of municipal waste or sludge. According to the present invention a method and system are provided which overcome the problem of gas particles depositing on (and thereby fouling and perhaps corroding) gas cooling surfaces. The invention solves this problem in a simple yet effective manner. The basic concept behind the invention is to utilize the very same solids which are used as bed material (e.g. inert bed material such as sand and/or reactive bed material such as limestxone) to mechanically scrub the gas cooler cooling surfaces so as to prevent accumlation of deposits, and/or remove deposits, therefrom. The invention is applicable to all types of fluidized bed reactors and reactor systems, but is particularly applicable to circulating fluidized bed reactors, and to pressurized systems (that is operating at a pressure of about 2-50 bar, preferably, 2-30 bar). According to one aspect of the present invention, a method of operating a fluidized bed reactor system comprising a fluidized bed reactor containing solid material particles and for reacting fuel, and a reactor outlet for gas produced during fuel reaction (combustion, gasification, etc.), and a gas cooler having cooling surfaces and connected to the reactor outlet. The method comprises the steps of; (a) Introducing solid material particles, fluidization medium, and fuel into the reactor to provide a fluidized bed therewithin. (b) Reacting the fuel material within the bed to produce exhaust gas and discharging the gas from the reactor outlet, (c) Cooling the gas from the reactor outlet in the gas cooler, (d) Cleaning the cooling surfaces of the gas cooler by introducing a sufficient concentration and size of bed particles into the gas during, or before, step (c), so that the particles mechanically dislodge deposits from, and thereby clean, the cooling surfaces. And, (e) removing the particles from the gas after step (d). Step (d) is preferably practiced only at spaced time intervals (e.g. intermittently or periodically, or in response to sensing of a decrease in cooling efficiency), but may be practiced continuously. Step (d) is typically practiced by introducing particles separated in step (e) into the gas just before the gas cooler, and/or by introducing particles from a bed particle supply into the gas just before the gas cooler. Altrnatively or additionally,whrerin the reactor is a CFB reactor having a particle separator between the reactor gas outl and the cooler which . nonnally operates at a first efficiency (which does not allow passage of a sufficient number or size of bed particles. therethrough to effect gas cooler cleaning) step (d) practiced by interrupting operation of the particle separator so that operates at significantly less than the first efticiency, so that a sufficient number and size of bed particles pass therethrough to effect cleaning of the gas cooler surfaces. This may be done - where the particle separator 1/ is a cyclone separator which produces a vortex -- by introducing a fluid stream into the vortex to disrupt the vortex flow and thereby reduce separation efficiency, or by introducing a solid object into the vortex, having the same affect. The stream may be steam, air, inert gas, or a liquid. Typically step (b) is practiced to produce gas at a temperature above 600 degrees C, and step (c) is practiced to cool the gas to about 400 degrees C. According to another aspect of the present invention a circulating fluidized bed reactor system is provided, comprising the following elements: A fluidized bed rector having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet. A cyclone separator normally operating at a first efficiency and connected to the reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to the reactor. A gas cooler connected to the separator gas outlet and having cooling surfaces. And, means for affecting the operating efficiency of the separator so that it is significantly less than the first efficiency so that sufficient bed particles pass through the separator to effect mechanical dislodgement of deposits which form on the cooling surfaces. The system preferably further comprises pressure vessels surrounding the reactor, separator, and cooler for maintaining them at superatmospheric pressure (e.g. 2-50 bar), and a second separator is preferably provided downstream of the gas cooler for separating bed particles from gas discharged from the cooler, and at spaced time intervals introducing at least some of the separated bed particles into the gas at or just before the cooler. The means for affecting operating efficiency of the cyclone separator may be means for introducing a fluid stream into the cyclone separator vortex, or for introducing and removing a solid object. According to yet another aspect of the present invention a circulating fluidized bed reactor system is provided comprising the following elements: A fluidized bed rector having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet. A cyclone separator connected to the reactor gas outlet, having a gas outlet, and a particle outlet for returning separated bed material to the reactor. A gas cooler connected to the separator gas outlet and having cooling surfaces. A second cyclone separator downstream of the gas cooler for separating bed particles from gas discharged from the cooler, and including a particle discharge. And, a conduit ' extending from the second cyclone particle discharge to the gas cooler or to between the first separator and the gas cooler. It is the primary object of the present invention to avoid the problem of gas cooler surface fouling in fluidized bed reactors in a simple yet effective manner. This and other objects of the invention 5 will become clear from an inspection of the detailed description of the invention, and from the appended claims. Accordingly the present invention provides a circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator. The invention will now be described in more detail with reference to the accompanying drawings, in which; BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is a schematic view of a first exemplary embodiment of a circulating fluidized bed reactor system according to the present invention; FIGURE 2 is a detail side cross-sectional view of the first cyclone separator of the apparatus of FIGURE 1, illustrating means for affecting the operating efficiency of the separator; FIGURE 3 is a view like that of FIGURE 2 only illustrating a different embodiment of the efficiency-affecting means; FIGURE 4 is a view like that of FIGURE 1 only illustrating a different embodiment of a system according to the invention; and FIGURE 5 is a view like that of FIGURE 1 only showing an exemplary pressurized reactor system according to present invention. DETAILED DESCRIPTION OF THE DRAWINGS FIGURE 1 illustrates a circulating fluidized bed (CFB) gasification reactor system 11 according to the present invention, including a circulating fluidized bed reactor 12 and a gas cooler 13. Gasification is practiced in the reactor 12 by introducing fluidized gas through a plenum 14 at the bottom of the reactor 12. Solid fuel material is introduced into the reactor 12 via an inlet 15, and solid bed material particles are introduced from a storage vessel 16 via inlet 17. The solid bed material may be an inert material such as sand, and may also comprise active material (that is active in the gasification process, such as limestone or other sulfur oxide reducing agents). The fuel material introduced at 15 is reacted (gasification in the case of FIGURE 1, but combustion or other reactions are also within the scope of the invention) to produce an exhaust gas which is discharged from an outlet (unnumbered) adjacent the top of the reactor 12 and connected to a first cyclone separator 18. The gas produced during the reaction in reactor 12 exhausts from the reactor 12, and includes in it entrained particulates such as inert solid bed particles, and unreacted fuel material. The vast majority of the particles -- particularly the large particles -- are separated from the exhaust gas by the separator 18, and are returned by conduit 19 to the bottom of the reactor 12, as is conventional per se. The product gas which exhausts the separator is passes to the gas cooler 20. Typically the exhaust gas from the reactor 12 and separator 18 has a temperature above 600 degrees C, and the cooler 13 is typically designed to cool the gases to about 400 degrees C. In the FIGURE 1 embodiment the gas cooler 13 is a fire-tube cooler in which the gas flows inside a plurality of spaced tubes. The space between the tubes is used as a conduit for heat transfer medium to extract heat from the gases. The heat transfer medium is introduced into the cooler 13 via inlet 20, and passes out via outlet 21. Water Tube heat transfers surfaces may be utilized too, in which case the gas flows outside the heat transfer surfaces. As the gas in the gas cooler 13 is cooled, tar-like substances condense or turn sticky and therefore tend to accumulate on the surfaces of the cooler 13. According to the present invention the surfaces are kept clean, or cleaned after accumulation of deposits, by introducing solid particles into the gas flow in, or just before, the cooler 13. For example this may be acconiplished by injecting clean particles using injection device 22, the clean bed particles being provided from the source 16 (e.g. comprising sand). A flow controller 28 may be provided for controlling the flow of particles to the injecting device 22 and into the line 17. While injection can take place continuously, it is preferred that it be at spaced time intervals, for example either intermittently or periodically, when it is expected that the layer of condensed and/or sticky material has deposited on the clean surfaces. Alternatively, control may be automatic, e.g. in response to sensing of a decrease in cooling efficiency as a result of depositing of condensing or sticky substances. Downstream of the gas cooler 13 is a second cyclone separator 23. The second separator 23 may operate continuously, but is particularly necessarty when particles are introduced (e.g. through injector 22) to effect cleaning. Particles separated by the second separator 23 may either be returned to the reactor 12 as indicated by line 24, may pass to the injector 22, and/or may be disposed of as indicated by line 26. The product gas in line 27, discharged from the second separator 23, may be filtered, and then acted upon, or may be used directly, depending upon the desired use and the gas's composition. FIGURE 1 also illustrates exemplary- conventional control valves 30, 31 which are operatively connected to the source of clean bed particles 16 and particles discharged from separator 23, respectively. A means 32 for lowering the particle separation 36 efficiency of the first separator 18 is also shown schematically in FIGURE 1. All of the elements 28, 30, 31, and 32 may be controlled by suitable automatic means, such as a conventional computer controller 33, so as to time, and control the volume of, the particles used for cleaning. The device 32 of FIGURE 1 is illustrated schematically, but, ia more detail, in FIGURE 2 in association with the first separator 18. An inlet 36 off-center with respect to the axis of the main hody 37 ot the separator 18, is connected to the gas outlet from the reactor 12, and introduces the gas and particle mixtures in a vortex flow, going around the vortex fmder 38. The tapered bottom of the structure 37 is indicated by reference numeral 39, and is connected to the particle recirculation line 19. In the FIGURE 2 embodiment, the means 32 for affecting the operating efficiency of the separator 18 comprises a fluid conduit 40 with a valve 41 controlled by the controller 33 therein, and connected up to a source of fluid 42 under pressure. The fluid in the source 42 may comprise steam, air, an inert gas such as nitrogen, or a liquid. The conduit or injector 40 is positioned so as to introduce fluid from the source 42 — when the valve 41 is opened by the controller 33 ~ so that it disrupts the vortex flow within the separator 18, and thereby reduces the separator efficiency, causing a significant number of relatively large particles to pass with the gas flowing through the vortex finder 38 to the gas cooler 13. During normal operation of the separator 18 its particle removal efficiency is such that insufficient number and size of particles pass to the cooler 13 to effect cleaning of the cooler surfaces by mechanically dislodging deposits therefrom. However when the particle removal efficiency of the separator 18 is adversely affected by introducing fluid through conduit/nozzle 40, sufficient particles do pass through the separator 18 so that -- either alone, or supplemented by particles from the source 16 and/or from the line 25 -- can effect cleaning. FIGURE 3 illustrates another exemplary embodiment of the means for adversely affecting separator efficiency. In this case the means are indicated by reference numeral 32', and comprise a solid object -- such as a metal bar -- 44 which is operated by a pneumatic of hydraulic cylinder 45, or other linear actuator, to move in the dimension of arrow 46. The bar 44 may be moved out of contact with the vortex flow in the separator 18 -- as indicated at solid hne in FIGURE 3 -- or, when it is desired to adversely affect separator efficiency, may be moved to the dotted line position illustrated in FIGURE 3. FIGURE 4 illustrates a system substantially the same as that in FIGURE 1 except for the details of the cooler 13', and the elimination of a bed particle feed from the source 16 to the injector 22. In the FIGURE 4 embodiment the reactor 12 also is a combustor rather than a gasifier, the exhaust gas passing through the first separator 18 and then to the cooler 13'. The cooler 13' includes a heat exchanger 50 having connections 51 which extend externally of the cooler 13', for example typically for producing steam to drive a steam turbine. A second heat exchanger 52 also may be provided, connected to a turbine, other heat exchangers, and the hke via connections 53. Utilizing the system 11 of FIGURE 4, brown coal, municipal waste, sludge, or the like may be combusted. Alkaline deposits in the gas which form on the surfaces of the heat exchangers 50, 52 are removed by injecting particles by injector 22, and/or by controlling the means 32 for affecting particle efficiency removal of the first separator 18, as described with respect to the FIGURE 1 embodiment. The FIGURE 5 embodiment is substantially the same as the FIGURE 1 embodiment except that it comprises a PCFB (pressurized circulating fluidized bed) gasification system. In this case the entire system is operated at superatmospheric pressure, typically 2-50 bar and preferably 2-30 bar. Pressure vessels 59, 60, 61, 62, and 63 are provided surrounding the bed particles sources 16, reactor 12 and separator 18, cooler 13, the duct between the separator is and cooler 13, and second separator 23, respectively. In this embodiment the controller 33 is not shown for clarity of illustration. While the primary action of the particles introduced in or just before the cooler 13, 13' in the practice of the present invention is to effect mechanical removal of deposits, it should also be understood that the solid bed material that comprises the introduced particles may combine with harmful condensable or sticky compounds thereto (e.g. which stick to or condense on the particles), therefore minimizing the deposits that form on the cooling surfaces. Even when pressurized (e.g. particularly in the FIGURE 5 embodiment) the solid bed material is at a low enough temperature that at least some condensable compomids, such as tar, condense thereon. y^ While the invention has been described above with respect to the use of a conventional generally circular configuration cyclone separator for each of the separators 18, 23, it is understood that other cyclone separators can also be utilized, such as the type shown in U.S. patent 5,281,398. Also, other types of separators besides cyclone separators may be utilized in which case the particle removal efficiency can be changed in any way that is effective for that particular type of separator. Also for cyclone separators while the means for affecting particle separation efficiency are preferred to be some sort of a fluid or mechanical mechanism for affecting the vortex flows that is extremely simple, other mechanisms can also be provided, such as a deflector in the inlet 36, a restriction in particle discharge 39, etc. Also while the invention has been described particularly with respect to circulating fluidized beds - which are the preferred embodiment - under some circumstances bubbling beds may be utilized instead. In a bubbling bed less inert material, other particle bed material, is utilized so that the separator 18 may not be necessary. Under these circumstances clearly the introduction of particles can then only come from the separator 23, and/or from the 5 source 16. Even in the circulating fluidized bed embodiment any selected one, or combination, of the particle introduction mechanisms described above may be utilized. While the invention has been described in connection with what is presently considered to be the most practical and preferred 10 embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. We claim: 1. A circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator. 2. The system as claimed in claim 1 comprising pressure vessels surrounding said reactor, separator, and cooler for maintaining them at superatmospheric pressure. 3. The system as claimed in claim 1 comprising a second separator downstream of said gas cooler for separating bed particles fi-om gas discharged from said cooler, and means for introducing at spaced time intervals at least some separated bed particles to said gas cooler or to said passage. 4. The system as claimed in claim 1 wherein said cyclone separator produces a vortex, and wherein said means for affecting the operating efficiency of said separator comprises means for introducing a fluid stream into the vortex to disrupt the vortex flow and thereby reduce separation efficiency. 5. The system as claimed in claim 1, wherein said cyclone separator produces a vortex, and wherein said means for affecting the operating efficiency of said separator comprises a solid object, and means for introducing or removing the solid object into or from the vortex, the solid object disrupting the vortex flow and thereby reducing separation efficiency when introduced into the vortex. 6. A circulating fludizied bed reactor system, substantially as herein above described with reference to the accompanying drawings.

Full Text

The present invention relates to a circulating fluidized bed reactor system
Fluidized bed reactors, particularly circulating fluidized bed reactors, are extremely useful in practicing a wide variety of
10 reactions, such as combustion and gasification of fuel material. Gasification is an attractive way to convert energy of fuel material into a more useful form, producing combustible gas; or combustion of the fuel in the reactor may produce steam to drive a steam turbine. However under many circumstances, the gas is discharged from the
15 reactor (e.g. fuel product gas) may contain undesirable substances such as tar-like condensable compounds. These substances tend to turn sticky below certain temperatures, and therefore deposit or accumulate on surrounding surfaces, particular surfaces of gas cooling devices.
20 Gasification of solid fuel material in fluidized bed has been
discussed in U.S. patents 4,017,272 and 4,057,402. The gasification process is generally stated to be characterized by following reactions:
r

The product gas usually contains substances which cause difficulties when the gas is cooled, i.e. compounds (e.g. tars) which turn sticky when cooled. The existence of these cause problems in cooling the product gas by depositing or accumulating on heat transfer surfaces of gas cooler. The problem of fouling of gas cooling surfaces has been addressed by using a direct heat transfer system, such as in U.S. patents 4,412,848 and 4,936,872. In these patents the product gas is led into fluidized bed gas cooler, and the fouling components are captured by particles of the fluidized bed.
The use of a separate fluidized bed -- as described above -- is
hardly an ideal solution to the problem, however, since the additional bed consumes space and requires construction and maintenance of different components, which can make costs prohibitive. Using indirect recuperator heat exchangers has also been fomid
vmacceptable, however, due to exhaust fouling difficulties. The fouling problem described above is particularly acute under pressurized conditions, e.g. superatmospheric pressure of about 2-50 bars. Under such pressurized conditions conventional steam soot blowers do not work properly. The problems as indicated above do
not exist solely during gasification, but also during combustion of a number of different types of fuel in a fluidized bed. For example when brown coal is burned the flue gases contain alkali species which condense on cooling surfaces, accumulating on the surfaces, fouling them, and causing corrosion of surrounding surfaces. Diffculties also
occur particularly in the combustion of municipal waste or sludge. According to the present invention a method and system are provided which overcome the problem of gas particles depositing on (and thereby fouling and perhaps corroding) gas cooling surfaces. The invention solves this problem in a simple yet effective manner.
The basic concept behind the invention is to utilize the very same

solids which are used as bed material (e.g. inert bed material such as sand and/or reactive bed material such as limestxone) to mechanically scrub the gas cooler cooling surfaces so as to prevent accumlation of deposits, and/or remove deposits, therefrom. The invention is
applicable to all types of fluidized bed reactors and reactor systems, but is particularly applicable to circulating fluidized bed reactors, and to pressurized systems (that is operating at a pressure of about 2-50 bar, preferably, 2-30 bar).
According to one aspect of the present invention, a method of
operating a fluidized bed reactor system comprising a fluidized bed reactor containing solid material particles and for reacting fuel, and a reactor outlet for gas produced during fuel reaction (combustion, gasification, etc.), and a gas cooler having cooling surfaces and connected to the reactor outlet. The method comprises the steps of;
(a) Introducing solid material particles, fluidization medium, and fuel into the reactor to provide a fluidized bed therewithin. (b) Reacting the fuel material within the bed to produce exhaust gas and discharging the gas from the reactor outlet, (c) Cooling the gas from the reactor outlet in the gas cooler, (d) Cleaning the cooling surfaces
of the gas cooler by introducing a sufficient concentration and size of bed particles into the gas during, or before, step (c), so that the particles mechanically dislodge deposits from, and thereby clean, the cooling surfaces. And, (e) removing the particles from the gas after step (d).
Step (d) is preferably practiced only at spaced time intervals
(e.g. intermittently or periodically, or in response to sensing of a decrease in cooling efficiency), but may be practiced continuously. Step (d) is typically practiced by introducing particles separated in step (e) into the gas just before the gas cooler, and/or by introducing
particles from a bed particle supply into the gas just before the gas

cooler. Altrnatively or additionally,whrerin the reactor is a CFB reactor having a particle separator between the reactor gas outl
and the cooler which . nonnally operates at a first efficiency (which does not allow passage of a sufficient number or size of bed particles. therethrough to effect gas cooler cleaning) step (d) practiced by interrupting operation of the particle separator so that operates at significantly less than the first efticiency, so that a sufficient number and size of bed particles pass therethrough to effect cleaning of the gas cooler surfaces. This may be done - where the particle separator 1/ is a cyclone separator which produces a vortex -- by introducing a fluid stream into the vortex to disrupt the vortex flow and thereby reduce separation efficiency, or by introducing a solid object into the vortex, having the same affect. The stream may be steam, air, inert gas, or a liquid. Typically step (b) is practiced to produce gas at a temperature above 600 degrees C, and step (c) is practiced to cool the gas to about 400 degrees C.
According to another aspect of the present invention a circulating fluidized bed reactor system is provided, comprising the following elements: A fluidized bed rector having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet. A cyclone separator normally operating at a first efficiency and connected to the reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to the reactor. A gas cooler connected to the separator gas outlet and having cooling surfaces. And, means for affecting the operating efficiency of the separator so that it is significantly less than the first efficiency so that sufficient bed particles pass through the separator to effect mechanical dislodgement of deposits which form on the cooling surfaces.
The system preferably further comprises pressure vessels surrounding the reactor, separator, and cooler for maintaining them

at superatmospheric pressure (e.g. 2-50 bar), and a second separator is preferably provided downstream of the gas cooler for separating bed particles from gas discharged from the cooler, and at spaced time intervals introducing at least some of the separated bed particles into the gas at or just before the cooler.
The means for affecting operating efficiency of the cyclone separator may be means for introducing a fluid stream into the cyclone separator vortex, or for introducing and removing a solid object.
According to yet another aspect of the present invention a circulating fluidized bed reactor system is provided comprising the following elements: A fluidized bed rector having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet. A cyclone separator connected to the reactor gas outlet, having a gas outlet, and a particle outlet for returning separated bed material to the reactor. A gas cooler connected to the separator gas outlet and having cooling surfaces. A second cyclone separator downstream of the gas cooler for separating bed particles from gas discharged from the cooler, and including a particle discharge. And, a conduit ' extending from the second cyclone particle discharge to the gas cooler or to between the first separator and the gas cooler.
It is the primary object of the present invention to avoid the problem of gas cooler surface fouling in fluidized bed reactors in a simple yet effective manner. This and other objects of the invention 5 will become clear from an inspection of the detailed description of the invention, and from the appended claims.

Accordingly the present invention provides a circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator.
The invention will now be described in more detail with reference to the accompanying drawings, in which;

BRIEF DESCRIPTION OF THE DRAWINGS
FIGURE 1 is a schematic view of a first exemplary embodiment of a circulating fluidized bed reactor system according to the present invention;
FIGURE 2 is a detail side cross-sectional view of the first cyclone separator of the apparatus of FIGURE 1, illustrating means for affecting the operating efficiency of the separator;

FIGURE 3 is a view like that of FIGURE 2 only illustrating a
different embodiment of the efficiency-affecting means;
FIGURE 4 is a view like that of FIGURE 1 only illustrating a different embodiment of a system according to the invention; and
FIGURE 5 is a view like that of FIGURE 1 only showing an exemplary pressurized reactor system according to present invention.
DETAILED DESCRIPTION OF THE DRAWINGS
FIGURE 1 illustrates a circulating fluidized bed (CFB) gasification reactor system 11 according to the present invention, including a circulating fluidized bed reactor 12 and a gas cooler 13.
Gasification is practiced in the reactor 12 by introducing fluidized gas through a plenum 14 at the bottom of the reactor 12. Solid fuel material is introduced into the reactor 12 via an inlet 15, and solid bed material particles are introduced from a storage vessel 16 via inlet 17. The solid bed material may be an inert material such as
sand, and may also comprise active material (that is active in the

gasification process, such as limestone or other sulfur oxide reducing agents).
The fuel material introduced at 15 is reacted (gasification in the case of FIGURE 1, but combustion or other reactions are also
within the scope of the invention) to produce an exhaust gas which is discharged from an outlet (unnumbered) adjacent the top of the reactor 12 and connected to a first cyclone separator 18. The gas produced during the reaction in reactor 12 exhausts from the reactor 12, and includes in it entrained particulates such as inert solid bed
particles, and unreacted fuel material. The vast majority of the particles -- particularly the large particles -- are separated from the exhaust gas by the separator 18, and are returned by conduit 19 to the bottom of the reactor 12, as is conventional per se.
The product gas which exhausts the separator is passes to the
gas cooler 20. Typically the exhaust gas from the reactor 12 and separator 18 has a temperature above 600 degrees C, and the cooler 13 is typically designed to cool the gases to about 400 degrees C. In the FIGURE 1 embodiment the gas cooler 13 is a fire-tube cooler in which the gas flows inside a plurality of spaced tubes. The space
between the tubes is used as a conduit for heat transfer medium to extract heat from the gases. The heat transfer medium is introduced into the cooler 13 via inlet 20, and passes out via outlet 21. Water Tube heat transfers surfaces may be utilized too, in which case the gas flows outside the heat transfer surfaces.
As the gas in the gas cooler 13 is cooled, tar-like substances
condense or turn sticky and therefore tend to accumulate on the surfaces of the cooler 13. According to the present invention the surfaces are kept clean, or cleaned after accumulation of deposits, by introducing solid particles into the gas flow in, or just before, the
cooler 13. For example this may be acconiplished by injecting clean

particles using injection device 22, the clean bed particles being provided from the source 16 (e.g. comprising sand). A flow controller 28 may be provided for controlling the flow of particles to the injecting device 22 and into the line 17. While injection can take
place continuously, it is preferred that it be at spaced time intervals, for example either intermittently or periodically, when it is expected that the layer of condensed and/or sticky material has deposited on the clean surfaces. Alternatively, control may be automatic, e.g. in response to sensing of a decrease in cooling efficiency as a result of
depositing of condensing or sticky substances.
Downstream of the gas cooler 13 is a second cyclone separator 23. The second separator 23 may operate continuously, but is particularly necessarty when particles are introduced (e.g. through injector 22) to effect cleaning. Particles separated by the second
separator 23 may either be returned to the reactor 12 as indicated by line 24, may pass to the injector 22, and/or may be disposed of as indicated by line 26. The product gas in line 27, discharged from the second separator 23, may be filtered, and then acted upon, or may be used directly, depending upon the desired use and the gas's
composition.
FIGURE 1 also illustrates exemplary- conventional control valves 30, 31 which are operatively connected to the source of clean bed particles 16 and particles discharged from separator 23, respectively. A means 32 for lowering the particle separation
36 efficiency of the first separator 18 is also shown schematically in FIGURE 1. All of the elements 28, 30, 31, and 32 may be controlled by suitable automatic means, such as a conventional computer controller 33, so as to time, and control the volume of, the particles used for cleaning.

The device 32 of FIGURE 1 is illustrated schematically, but, ia more detail, in FIGURE 2 in association with the first separator 18. An inlet 36 off-center with respect to the axis of the main hody 37 ot the separator 18, is connected to the gas outlet from the reactor 12,
and introduces the gas and particle mixtures in a vortex flow, going around the vortex fmder 38. The tapered bottom of the structure 37 is indicated by reference numeral 39, and is connected to the particle recirculation line 19. In the FIGURE 2 embodiment, the means 32 for affecting the operating efficiency of the separator 18 comprises a
fluid conduit 40 with a valve 41 controlled by the controller 33
therein, and connected up to a source of fluid 42 under pressure. The fluid in the source 42 may comprise steam, air, an inert gas such as nitrogen, or a liquid. The conduit or injector 40 is positioned so as to introduce fluid from the source 42 — when the valve 41 is opened by
the controller 33 ~ so that it disrupts the vortex flow within the
separator 18, and thereby reduces the separator efficiency, causing a significant number of relatively large particles to pass with the gas flowing through the vortex finder 38 to the gas cooler 13.
During normal operation of the separator 18 its particle
removal efficiency is such that insufficient number and size of
particles pass to the cooler 13 to effect cleaning of the cooler surfaces by mechanically dislodging deposits therefrom. However when the particle removal efficiency of the separator 18 is adversely affected by introducing fluid through conduit/nozzle 40, sufficient particles do
pass through the separator 18 so that -- either alone, or
supplemented by particles from the source 16 and/or from the line 25 -- can effect cleaning.
FIGURE 3 illustrates another exemplary embodiment of the means for adversely affecting separator efficiency. In this case the
means are indicated by reference numeral 32', and comprise a solid

object -- such as a metal bar -- 44 which is operated by a pneumatic of hydraulic cylinder 45, or other linear actuator, to move in the dimension of arrow 46. The bar 44 may be moved out of contact with the vortex flow in the separator 18 -- as indicated at solid hne in
FIGURE 3 -- or, when it is desired to adversely affect separator efficiency, may be moved to the dotted line position illustrated in FIGURE 3.
FIGURE 4 illustrates a system substantially the same as that in FIGURE 1 except for the details of the cooler 13', and the
elimination of a bed particle feed from the source 16 to the injector 22. In the FIGURE 4 embodiment the reactor 12 also is a combustor rather than a gasifier, the exhaust gas passing through the first separator 18 and then to the cooler 13'. The cooler 13' includes a heat exchanger 50 having connections 51 which extend externally of
the cooler 13', for example typically for producing steam to drive a steam turbine. A second heat exchanger 52 also may be provided, connected to a turbine, other heat exchangers, and the hke via connections 53.
Utilizing the system 11 of FIGURE 4, brown coal, municipal
waste, sludge, or the like may be combusted. Alkaline deposits in the gas which form on the surfaces of the heat exchangers 50, 52 are removed by injecting particles by injector 22, and/or by controlling the means 32 for affecting particle efficiency removal of the first separator 18, as described with respect to the FIGURE 1
embodiment.
The FIGURE 5 embodiment is substantially the same as the FIGURE 1 embodiment except that it comprises a PCFB (pressurized circulating fluidized bed) gasification system. In this case the entire system is operated at superatmospheric pressure, typically 2-50 bar
and preferably 2-30 bar. Pressure vessels 59, 60, 61, 62, and 63 are

provided surrounding the bed particles sources 16, reactor 12 and separator 18, cooler 13, the duct between the separator is and cooler 13, and second separator 23, respectively. In this embodiment the controller 33 is not shown for clarity of illustration.
While the primary action of the particles introduced in or just
before the cooler 13, 13' in the practice of the present invention is to effect mechanical removal of deposits, it should also be understood that the solid bed material that comprises the introduced particles may combine with harmful condensable or sticky compounds thereto
(e.g. which stick to or condense on the particles), therefore
minimizing the deposits that form on the cooling surfaces. Even when pressurized (e.g. particularly in the FIGURE 5 embodiment) the solid bed material is at a low enough temperature that at least some condensable compomids, such as tar, condense thereon.
y^ While the invention has been described above with respect to
the use of a conventional generally circular configuration cyclone separator for each of the separators 18, 23, it is understood that other cyclone separators can also be utilized, such as the type shown in U.S. patent 5,281,398. Also, other types of separators besides cyclone
separators may be utilized in which case the particle removal efficiency can be changed in any way that is effective for that particular type of separator. Also for cyclone separators while the means for affecting particle separation efficiency are preferred to be some sort of a fluid or mechanical mechanism for affecting the vortex
flows that is extremely simple, other mechanisms can also be
provided, such as a deflector in the inlet 36, a restriction in particle discharge 39, etc.
Also while the invention has been described particularly with respect to circulating fluidized beds - which are the preferred
embodiment - under some circumstances bubbling beds may be

utilized instead. In a bubbling bed less inert material, other particle bed material, is utilized so that the separator 18 may not be necessary. Under these circumstances clearly the introduction of particles can then only come from the separator 23, and/or from the
5 source 16. Even in the circulating fluidized bed embodiment any selected one, or combination, of the particle introduction mechanisms described above may be utilized.
While the invention has been described in connection with what is presently considered to be the most practical and preferred
10 embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

We claim:
1. A circulating fludizied bed reactor system comprising a fludizied bed reactor having a bed material inlet, an exhaust gas outlet, and a fluidizing gas inlet; a cyclone separator normally operating at a first efficiency and connected to said reactor gas outlet, and having a gas outlet, and a particle outlet for returning separated bed material to said reactor; and a gas cooler connected by a passage to said separator gas outlet and having cooling surfaces, wherein the system comprises means for introducing solid particles to said gas cooler or to said passage, having means for affecting the operating efficiency of said separator.
2. The system as claimed in claim 1 comprising pressure vessels surrounding said reactor, separator, and cooler for maintaining them at superatmospheric pressure.
3. The system as claimed in claim 1 comprising a second separator downstream of said gas cooler for separating bed particles fi-om gas discharged from said cooler, and means for introducing at spaced time intervals at least some separated bed particles to said gas cooler or to said passage.
4. The system as claimed in claim 1 wherein said cyclone separator produces a vortex, and wherein said means for affecting the operating efficiency of said separator comprises means for introducing a fluid stream into the vortex to disrupt the vortex flow and thereby reduce separation efficiency.

5. The system as claimed in claim 1, wherein said cyclone
separator produces a vortex, and wherein said means for affecting the
operating efficiency of said separator comprises a solid object, and means
for introducing or removing the solid object into or from the vortex, the solid
object disrupting the vortex flow and thereby reducing separation efficiency
when introduced into the vortex.
6. A circulating fludizied bed reactor system, substantially as
herein above described with reference to the accompanying drawings.

Documents:

1060-mas-1995 abstract.jpg

1060-mas-1995 abstract.pdf

1060-mas-1995 assignment.pdf

1060-mas-1995 claims.pdf

1060-mas-1995 correspondence-others.pdf

1060-mas-1995 correspondence-po.pdf

1060-mas-1995 description(complete).pdf

1060-mas-1995 drawings.pdf

1060-mas-1995 form-1.pdf

1060-mas-1995 form-10.pdf

1060-mas-1995 form-26.pdf

1060-mas-1995 form-4.pdf

1060-mas-1995 form-9.pdf

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Patent Number

192611

Indian Patent Application Number

1060/MAS/1995

PG Journal Number

30/2009

Publication Date

24-Jul-2009

Grant Date

06-Dec-2004

Date of Filing

21-Aug-1995

Name of Patentee

A. ALSTROM CORPORATION,

Applicant Address

FIN- 29600 NOORMARKKU,

Inventors:

#	Inventor's Name	Inventor's Address
1	BERG, EERO,	RIITTULANMAENTIE 7AS. 1 FIN-78300 VARKAUS,
2	DAVIS , CHARLES M.	1349 MARLYN DRIVE, COLOMBUS, OH 43220 ,
3	NIEMINEN JORMA	SOLVENKATU 2, FIN-78300 VARKAUS,
4	PALONEN JUHA	MALLINKATU 14 C023 , FIN-48600 KARHULA

PCT International Classification Number

F23C10/18

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA