A fluidized bed reactor (FBR) is a type of reactor device that can be used to carry out a variety of multiphase chemical reactions. In this type of reactor, a fluid (gas or liquid) is passed through a solid granular material (usually a catalyst) at high enough speeds to suspend the solid and cause it to behave as though it were a fluid. This process, known as fluidization, imparts many important advantages to an FBR. As a result, FBRs are used for many industrial applications.
The solid substrate material (the catalytic material upon which chemical species react) in the fluidized bed reactor is typically supported by a porous plate, known as a distributor.[1] The fluid is then forced through the distributor up through the solid material. At lower fluid velocities, the solids remain in place as the fluid passes through the voids in the material. This is known as a packed bed reactor. As the fluid velocity is increased, the reactor will reach a stage where the force of the fluid on the solids is enough to balance the weight of the solid material. This stage is known as incipient fluidization and occurs at this minimum fluidization velocity. Once this minimum velocity is surpassed, the contents of the reactor bed begin to expand and swirl around much like an agitated tank or boiling pot of water. The reactor is now a fluidized bed. Depending on the operating conditions and properties of solid phase various flow regimes can be observed in this reactor.
History and current usesedit
Fluidized bed reactors are a relatively new tool in the chemical engineering field. The first fluidized bed gas generator was developed by Fritz Winkler in Germany in the 1920s.[2] One of the first United States fluidized bed reactors used in the petroleum industry was the Catalytic Cracking Unit, created in Baton Rouge, LA in 1942 by the Standard Oil Company of New Jersey (now ExxonMobil).[3] This FBR and the many to follow were developed for the oil and petrochemical industries. Here catalysts were used to reduce petroleum to simpler compounds through a process known as cracking. The invention of this technology made it possible to significantly increase the production of various fuels in the United States.[4]
Today, fluidized bed reactors are still used to produce gasoline and other fuels, along with many other chemicals. Many industrially produced polymers are made using FBR technology, such as rubber, vinyl chloride, polyethylene, styrenes, and polypropylene.[5][page needed] Various utilities also use FBRs for coal gasification, nuclear power plants, and water and waste treatment settings. Used in these applications, fluidized bed reactors allow for a cleaner, more efficient process than previous standard reactor technologies.[4]
Advantagesedit
The increase in fluidized bed reactor use in today's industrial world is largely due to the inherent advantages of the technology.[6]
Uniform particle mixing: Due to the intrinsic fluid-like behavior of the solid material, fluidized beds do not experience poor mixing as in packed beds. This complete mixing allows for a uniform product that can often be hard to achieve in other reactor designs. The elimination of radial and axial concentration gradients also allows for better fluid-solid contact, which is essential for reaction efficiency and quality.
Uniform temperature gradients: Many chemical reactions require the addition or removal of heat. Local hot or cold spots within the reaction bed, often a problem in packed beds, are avoided in a fluidized situation such as an FBR. In other reactor types, these local temperature differences, especially hotspots, can result in product degradation. Thus FBRs are well suited to exothermic reactions. Researchers have also learned that the bed-to-surface heat transfer coefficients for FBRs are high.
Ability to operate reactor in continuous state: The fluidized bed nature of these reactors allows for the ability to continuously withdraw product and introduce new reactants into the reaction vessel. Operating at a continuous process state allows manufacturers to produce their various products more efficiently due to the removal of startup conditions in batch processes.
Disadvantagesedit
As in any design, the fluidized bed reactor does have its draw-backs, which any reactor designer must take into consideration.[6]
Increased reactor vessel size: Because of the expansion of the bed materials in the reactor, a larger vessel is often required than that for a packed bed reactor. This larger vessel means that more must be spent on initial capital costs.
Pumping requirements and pressure drop: The requirement for the fluid to suspend the solid material necessitates that a higher fluid velocity is attained in the reactor. In order to achieve this, more pumping power and thus higher energy costs are needed. In addition, the pressure drop associated with deep beds also requires additional pumping power.
Particle entrainment: The high gas velocities present in this style of reactor often result in fine particles becoming entrained in the fluid. These captured particles are then carried out of the reactor with the fluid, where they must be separated. This can be a very difficult and expensive problem to address depending on the design and function of the reactor. This may often continue to be a problem even with other entrainment reducing technologies.
Lack of current understanding: Current understanding of the actual behavior of the materials in a fluidized bed is rather limited. It is very difficult to predict and calculate the complex mass and heat flows within the bed. Due to this lack of understanding, a pilot plant for new processes is required. Even with pilot plants, the scale-up can be very difficult and may not reflect what was experienced in the pilot trial.
Erosion of internal components: The fluid-like behavior of the fine solid particles within the bed eventually results in the wear of the reactor vessel. This can require expensive maintenance and upkeep for the reaction vessel and pipes.
Pressure loss scenarios: If fluidization pressure is suddenly lost, the surface area of the bed may be suddenly reduced. This can either be an inconvenience (e.g. making bed restart difficult), or may have more serious implications, such as runaway reactions (e.g. for exothermic reactions in which heat transfer is suddenly restricted).
Current research and trendsedit
Due to the advantages of fluidized bed reactors, a large amount of research is devoted to this technology. Most current research aims to quantify and explain the behavior of the phase interactions in the bed. Specific research topics include particle size distributions, various transfer coefficients, phase interactions, velocity and pressure effects, and computer modeling.[7] The aim of this research is to produce more accurate models of the inner movements and phenomena of the bed.[8] This will enable chemical engineers to design better, more efficient reactors that may effectively deal with the current disadvantages of the technology and expand the range of FBR use.
^"First Commercial Fluid Bed Reactor". National Historic Chemical Landmarks. American Chemical Society. Retrieved 2014-02-21.
^ abThornhill, D. "The Fluidized Bed Reactor Page". Retrieved February 13, 2007.
^Polypropylene Production via Gas Phase Process, Technology Economics Program. Intratec Solutions. 2012. ISBN978-0-615-66694-5.
^ abTrambouze, P., & Euzen, J. (2004). Chemical Reactors: From Design to Operation. (R. Bononno, Trans.). Paris: Editions Technip.
^Arastoopour, H. (Ed.). (1998). Fluidization and Fluid Particle Systems: Recent Research and Development. New York, NY: American Institute of Chemical Engineers.
^Abbasi, Mohammad Reza; Shamiri, Ahmad; Hussain, M.A. (2016). "Dynamic modeling and Molecular Weight Distribution of ethylene copolymerization in an industrial gas-phase Fluidized-Bed Reactor". Advanced Powder Technology. 27 (4): 1526–1538. doi:10.1016/j.apt.2016.05.014.
January 01, 1970
fluidized, reactor, other, topics, fluidization, fluidized, fluidized, combustion, fluidization, fluidized, reactor, type, reactor, device, that, used, carry, variety, multiphase, chemical, reactions, this, type, reactor, fluid, liquid, passed, through, solid,. For other topics on fluidization see Fluidized bed Fluidized bed combustion and Fluidization A fluidized bed reactor FBR is a type of reactor device that can be used to carry out a variety of multiphase chemical reactions In this type of reactor a fluid gas or liquid is passed through a solid granular material usually a catalyst at high enough speeds to suspend the solid and cause it to behave as though it were a fluid This process known as fluidization imparts many important advantages to an FBR As a result FBRs are used for many industrial applications Basic diagram of a fluidized bed reactor Contents 1 Basic principles 2 History and current uses 3 Advantages 4 Disadvantages 5 Current research and trends 6 See also 7 ReferencesBasic principles editThe solid substrate material the catalytic material upon which chemical species react in the fluidized bed reactor is typically supported by a porous plate known as a distributor 1 The fluid is then forced through the distributor up through the solid material At lower fluid velocities the solids remain in place as the fluid passes through the voids in the material This is known as a packed bed reactor As the fluid velocity is increased the reactor will reach a stage where the force of the fluid on the solids is enough to balance the weight of the solid material This stage is known as incipient fluidization and occurs at this minimum fluidization velocity Once this minimum velocity is surpassed the contents of the reactor bed begin to expand and swirl around much like an agitated tank or boiling pot of water The reactor is now a fluidized bed Depending on the operating conditions and properties of solid phase various flow regimes can be observed in this reactor History and current uses editFluidized bed reactors are a relatively new tool in the chemical engineering field The first fluidized bed gas generator was developed by Fritz Winkler in Germany in the 1920s 2 One of the first United States fluidized bed reactors used in the petroleum industry was the Catalytic Cracking Unit created in Baton Rouge LA in 1942 by the Standard Oil Company of New Jersey now ExxonMobil 3 This FBR and the many to follow were developed for the oil and petrochemical industries Here catalysts were used to reduce petroleum to simpler compounds through a process known as cracking The invention of this technology made it possible to significantly increase the production of various fuels in the United States 4 Today fluidized bed reactors are still used to produce gasoline and other fuels along with many other chemicals Many industrially produced polymers are made using FBR technology such as rubber vinyl chloride polyethylene styrenes and polypropylene 5 page needed Various utilities also use FBRs for coal gasification nuclear power plants and water and waste treatment settings Used in these applications fluidized bed reactors allow for a cleaner more efficient process than previous standard reactor technologies 4 Advantages editThe increase in fluidized bed reactor use in today s industrial world is largely due to the inherent advantages of the technology 6 Uniform particle mixing Due to the intrinsic fluid like behavior of the solid material fluidized beds do not experience poor mixing as in packed beds This complete mixing allows for a uniform product that can often be hard to achieve in other reactor designs The elimination of radial and axial concentration gradients also allows for better fluid solid contact which is essential for reaction efficiency and quality Uniform temperature gradients Many chemical reactions require the addition or removal of heat Local hot or cold spots within the reaction bed often a problem in packed beds are avoided in a fluidized situation such as an FBR In other reactor types these local temperature differences especially hotspots can result in product degradation Thus FBRs are well suited to exothermic reactions Researchers have also learned that the bed to surface heat transfer coefficients for FBRs are high Ability to operate reactor in continuous state The fluidized bed nature of these reactors allows for the ability to continuously withdraw product and introduce new reactants into the reaction vessel Operating at a continuous process state allows manufacturers to produce their various products more efficiently due to the removal of startup conditions in batch processes Disadvantages editAs in any design the fluidized bed reactor does have its draw backs which any reactor designer must take into consideration 6 Increased reactor vessel size Because of the expansion of the bed materials in the reactor a larger vessel is often required than that for a packed bed reactor This larger vessel means that more must be spent on initial capital costs Pumping requirements and pressure drop The requirement for the fluid to suspend the solid material necessitates that a higher fluid velocity is attained in the reactor In order to achieve this more pumping power and thus higher energy costs are needed In addition the pressure drop associated with deep beds also requires additional pumping power Particle entrainment The high gas velocities present in this style of reactor often result in fine particles becoming entrained in the fluid These captured particles are then carried out of the reactor with the fluid where they must be separated This can be a very difficult and expensive problem to address depending on the design and function of the reactor This may often continue to be a problem even with other entrainment reducing technologies Lack of current understanding Current understanding of the actual behavior of the materials in a fluidized bed is rather limited It is very difficult to predict and calculate the complex mass and heat flows within the bed Due to this lack of understanding a pilot plant for new processes is required Even with pilot plants the scale up can be very difficult and may not reflect what was experienced in the pilot trial Erosion of internal components The fluid like behavior of the fine solid particles within the bed eventually results in the wear of the reactor vessel This can require expensive maintenance and upkeep for the reaction vessel and pipes Pressure loss scenarios If fluidization pressure is suddenly lost the surface area of the bed may be suddenly reduced This can either be an inconvenience e g making bed restart difficult or may have more serious implications such as runaway reactions e g for exothermic reactions in which heat transfer is suddenly restricted Current research and trends editDue to the advantages of fluidized bed reactors a large amount of research is devoted to this technology Most current research aims to quantify and explain the behavior of the phase interactions in the bed Specific research topics include particle size distributions various transfer coefficients phase interactions velocity and pressure effects and computer modeling 7 The aim of this research is to produce more accurate models of the inner movements and phenomena of the bed 8 This will enable chemical engineers to design better more efficient reactors that may effectively deal with the current disadvantages of the technology and expand the range of FBR use See also editChemical engineering Chemical looping combustion Chemical reactor Fluidized bed combustion Siemens processReferences edit Howard J R 1989 Fluidized Bed Technology Principles and Applications New York NY Adam Higler Tavoulareas S 1991 Fluidized Bed Combustion Technology Annual Reviews Inc 16 25 27 First Commercial Fluid Bed Reactor National Historic Chemical Landmarks American Chemical Society Retrieved 2014 02 21 a b Thornhill D The Fluidized Bed Reactor Page Retrieved February 13 2007 Polypropylene Production via Gas Phase Process Technology Economics Program Intratec Solutions 2012 ISBN 978 0 615 66694 5 a b Trambouze P amp Euzen J 2004 Chemical Reactors From Design to Operation R Bononno Trans Paris Editions Technip Arastoopour H Ed 1998 Fluidization and Fluid Particle Systems Recent Research and Development New York NY American Institute of Chemical Engineers Abbasi Mohammad Reza Shamiri Ahmad Hussain M A 2016 Dynamic modeling and Molecular Weight Distribution of ethylene copolymerization in an industrial gas phase Fluidized Bed Reactor Advanced Powder Technology 27 4 1526 1538 doi 10 1016 j apt 2016 05 014 Retrieved from https en wikipedia org w index php title Fluidized bed reactor amp oldid 1176896367, wikipedia, wiki, book, books, library,
