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Professional Development Fluid Catalytic Cracker (FCC) cat cracker By Kerry Pritchard
Fluid Catalytic Cracker A chemical reactor for converting oils with high boiling points into fuels with lower boiling points in the presence of a catalyst
Fluid Catalytic Cracker
Fluid Catalytic Cracker • In petroleum geology and chemistry , cracking is the process whereby complex organic molecules (e.g. kerogens or heavy hydrocarbons ) are converted to simpler molecules (e.g. light hydrocarbons) by the breaking of carbon - carbon bonds in the precursors. The rate of cracking and the end products are strongly dependent on the temperature and presence of any catalysts
Fluid Catalytic Cracker Crude oil is separated into fractions by fractional distillation. The heavier fractions that emerge from the bottom of the fractionating column are often broken up (cracked) to make more useful products.
Fluid Catalytic Cracker •Applications •In an oil refinery cracking processes allow the production of "light" products (such as LPG and gasoline ) from heavier crude oil distillation fractions (such as gas oils ) and residues. Fluid Catalytic Cracking (FCC for short) produces a high yield of gasoline and LPG while hydrocracking is a major source of jet fuel, gasoline components and LPG. Thermal cracking is currently used to "upgrade" very heavy fractions ("upgrading", "visbreaking"), or to produce light fractions or distillates, burner fuel and/or petroleum coke. Two extremes of the thermal cracking in terms of product range are represented by the high-temperature process called steam cracking or pyrolysis (ca. 750 to 900 °C or more) which produces valuable ethylene and other feeds for the petrochemical industry, and the milder-temperature delayed coking (ca. 500 °C) which can produce, under the right conditions, valuable needle coke, a highly crystalline petroleum coke used in the production of electrodes for the steel and aluminum industries.
Fluid Catalytic Cracker The branched molecules help to give petrol with higher octane number, less inclined to knocking.
Fluid Catalytic Cracker Fluid catalytic cracking is a commonly used process and a modern oil refinery will typically include a cat cracker, particularly refineries in the USA due to the high demand for gasoline. The process was first used in around 1942, and employs a powdered catalyst. Initial process implementations were based on a low activity alumina catalyst and a reactor where the catalyst particles were suspended in a rising flow of feed hydrocarbons in a fluidized bed. In newer designs, cracking takes place using a very active zeolite-based catalyst in a short- contact time vertical or upward sloped pipe called the "riser". Pre-heated feed is sprayed into the base of the riser via feed nozzles where it contacts extremely hot fluidized catalyst at 665 to 760 °C . The hot catalyst vaporizes the feed and catalyzes the cracking reactions that break down the high molecular weight oil into lighter components including LPG, gasoline, and diesel. The catalyst-hydrocarbon mixture flows upward through the riser for just a few seconds and then the mixture is separated via cyclones. The catalyst-free hydrocarbons are routed to a main fractionator for separation into fuel gas, LPG, gasoline, light cycle oils used in diesel and jet fuel, and heavy fuel oil.
Fluid Catalytic Cracker During the trip up the riser, the cracking catalyst is "spent" by reactions which deposit coke on the catalyst and greatly reduce activity and selectivity. The "spent" catalyst is disengaged from the cracked hydrocarbon vapors and sent to a stripper where it is contacted with steam to remove hydrocarbons remaining in the catalyst pores. The "spent" catalyst then flows into a fluidized-bed regenerator where air (or in some cases air plus oxygen) is used to burn off the coke to restore catalyst activity and also provide the necessary heat for the next reaction cycle, cracking being an endothermic reaction. The "regenerated" catalyst then flows to the base of the riser, repeating the cycle. The gasoline produced in the FCC unit has an elevated octane rating but is less chemically stable compared to other gasoline components due to its olefinic profile. Olefins in gasoline are responsible for the formation of polymeric deposits in storage tanks, fuel ducts and injectors. The FCC LPG is an important source of C3-C4 olefins and isobutane that are essential feeds for the alkylation process.
Fluid Catalytic Cracker • Hydrocracking is a catalytic cracking process assisted by the presence of an elevated partial pressure of hydrogen. The products resulted are saturated hydrocarbons; depending on the process severity (temperature, pressure, catalyst activity) these products range from ethane, LPG to heavier hydrocarbons comprising mostly of isoparaffins. Hydrocracking is normally facilitated by a bifunctional catalyst that is capable of rearranging and breaking hydrocarbon chains as well as adding hydrogen to aromatics and olefins to produce naphthenes and alkanes. • Major products from hydrocracking are jet fuel, relatively high octane rating gasoline fractions and LPG. All these products have a very low content of sulfur and contaminants.
Fluid Catalytic Cracker Steam cracking is a petrochemical process in which saturated hydrocarbons are broken down into smaller, often unsaturated, hydrocarbons. It is the principal industrial method for producing the lighter alkenes (or commonly olefins), including ethene (or ethylene) and propene (or propylene). • In steam cracking, a gaseous or liquid hydrocarbon feed is diluted with steam and then briefly heated in a furnace. Typically, the reaction temperature is very hot—over 900°C—but the reaction is only allowed to proceed for a few tenths of a second before being quenched by contact with a colder fluid. • The products produced in the reaction depend on the composition of the feed, the hydrocarbon to steam ratio and on the cracking temperature & furnace residence time. Light hydrocarbon feeds (such as ethane, LPGs or light naphtha's) give product streams rich in the lighter alkenes, including ethylene, propylene, and butadiene. Heavier hydrocarbon (full range & heavy naphtha's as well as other refinery products) feeds give some of these, but also give products rich in aromatic hydrocarbons and hydrocarbons suitable for inclusion in gasoline or fuel oil. The higher cracking temperature (also referred to as severity) favors the production of ethene and benzene, whereas lower severity produces relatively higher amounts of propene, C4- hydrocarbons and liquid products. • The process also results in the slow deposition of coke, a form of carbon, on the reactor walls. This degrades the effectiveness of the reactor, so reaction conditions are designed to minimize this. Nonetheless, a steam cracking furnace can usually only run for a few months at a time between de-cokings.
Fluid Catalytic Cracker • Chemistry • "Cracking" breaks larger molecules into smaller ones. This can be done with a thermic or catalytic method. The thermal cracking process follows a homolytic mechanism, that is, bonds break symmetrically and thus pairs of free radicals are formed. The catalytic cracking process involves the presence of acid catalysts (usually solid acids such as silica-alumina and zeolites) which promote a heterolytic (asymmetric) breakage of bonds yielding pairs of ions of opposite charges, usually a carbocation and the very unstable hydride anion. Carbon-localized free radicals and cations are both highly unstable and undergo processes of chain rearrangement, C-C scission in position beta (i.e., cracking) and intra- and intermolecular hydrogen transfer or hydride transfer. In both types of processes, the corresponding reactive intermediates (radicals, ions) are permanently regenerated, and thus they proceed by a self-propagating chain mechanism. The chain of reactions is eventually terminated by radical or ion recombination
Fluid Catalytic Cracker • Catalytic cracking uses a catalyst (often a zeolite catalyst) to aid the process of breaking down large hydrocarbon molecules into smaller ones, as well as using high temperatures and slight pressure. During this process, less reactive and therefore more stable and longer lived intermediate cations accumulate on the catalysts' active sites generating deposits of carbonaceous products generally (and in many cases inappropriately) known as coke. Such deposits need to be removed (usually by controlled burning) in order to restore catalyst activity.
Fluid Catalytic Cracker • Thermal Cracking • In thermal cracking elevated temperatures and pressures are used. An overall process of disproportionation can be observed, where "light", hydrogen-rich products are formed at the expense of heavier molecules which condense and are depleted of hydrogen. • A large number of chemical reactions take place during steam cracking, most of them based on free radicals. Computer simulations aimed at modeling what takes place during steam cracking have included hundreds or even thousands of reactions in their models. The major sorts of reactions that take place, with examples, include: • Initiation reactions, where a single molecule breaks apart into two free radicals. Only a small fraction of the feed molecules actually undergo initiation, but these reactions are necessary to produce the free radicals that drive the rest of the reactions. In steam cracking, initiation usually involves breaking a chemical bond between two carbon atoms, rather than the bond between a carbon and a hydrogen atom. • CH3CH3 → 2 CH3•
Fluid Catalytic Cracker • Hydrogen abstraction, where a free radical removes a hydrogen atom from another molecule, turning the second molecule into a free radical. • CH3• + CH3CH3 → CH4 + CH3CH2• • Radical decomposition, where a free radical breaks apart into two molecules, one an alkene, the other a free radical. This is the process that results in the alkene products of steam cracking. • CH3CH2• → CH2=CH2 + H• • Radical addition, the reverse of radical decomposition, in which a radical reacts with an alkene to form a single, larger free radical. These processes are involved in forming the aromatic products that result when heavier feedstocks are used. • CH3CH2• + CH2=CH2 → CH3CH2CH2CH2• • Termination reactions, which happen when two free radicals react with each other to produce products that are not free radicals. Two common forms of termination are recombination, where the two radicals combine to form one larger molecule, and disproportionation, where one radical transfers a hydrogen atom to the other, giving an alkene and an alkane. • CH3• + CH3CH2• → CH3CH2CH3 • CH3CH2• + CH3CH2• → CH2=CH2 + CH3CH3
Fluid Catalytic Cracker • History • In 1855, petroleum cracking methods were pioneered by Chemistry Professor Benjamin Silliman, Jr., of Yale University (then Sheffield Scientific School at Yale University). Silliman, like his father, were Skull and Bones members and both Chemistry Professors at SSS. • The first thermal cracking method, the Burton process, was invented by William M. Burton; the oil industry first using it to produce gasoline in 1913. • Catalytic cracking, based upon a process developed by Dr. Alex Golden Oblad at Standard Oil of Indiana has been used from around 1936. Typical catalysts include alumina, silica, zeolites, and various types of clay • The world's first oil refinery opened at Ploieşti, Romania in 1856 [1]. Several other refineries were built at that location with investment from United States companies before being taken over by Nazi Germany during World War II. Most of these refineries were bombarded by the US Air Force in Operation Tidal Wave, August 1, 1943. • Another early example is Oljeön preserved as a museum at the UNESCO world heritage site Engelsberg. It started operation in 1875 and is part of the Ecomuseum Bergslagen. • The largest oil refinery in the world is in Ras Tanura, Saudi Arabia, owned by Saudi Aramco. The city was originally built as a sea port, but actually developed because of the huge refinery area. For most of the 20th century the largest refinery of the world was that of Abadan in Iran.
Fluid Catalytic Cracker An oil refinery. The tapering vertical elements are smokestacks to create draft for heating units. Most of the complex vertical units are fractionating towers. Others are flares, at this refinery (Shell at Martinez, California) designed and permitted for emergency use only in case of process upset. (Flares are alleged by some to be used to dispose of unwanted waste materials by incomplete burning with the actual pollution figures grossly underreported.)
Fluid Catalytic Cracker
Fluid Catalytic Cracker
Fluid Catalytic Cracker
Fluid Catalytic Cracker
Fluid Catalytic Cracker
Fluid Catalytic Cracker • http://www.uop.com/refining/1080.html • http://catcracking.com/ • http://www.tceq.state.tx.us/assets/public/permitting/air/Guidance/NewSource Review/fccu.pdf • http://catalysis.che.wsu.edu/~aplaton/interests/1_intro_to_oil_refining/ • http://www.schoolscience.co.uk/content/index.asp • http://www.ekomuseum.se/english/besoksmal/oljeon.html
Fluid Catalytic Cracker • Item Definition Activation energy The amount by which the energy of reactants must be raised for reaction to take place Analgesic A substance with pain-relieving properties Aromatic Compounds based on the “benzene ring” Atom economy The proportion of reactant atoms that appear in the desired product Autoclave Apparatus used for small-scale reactions in a contained environment, usually at high pressure Biocatalysis Catalysed reactions where the catalyst is an enzyme Biotransformation Chemical reaction carried out using biological catalysts Candida rugosa A fungus used in biocatalysis Carbocation (“Carbo – cation”, not “carbocashun”!) A positive ion formed from an organic molecule Cat cracker “Catalytic cracker” – industrial scale equipment used to break large alkane molecules from fractional distillation of oil into smaller molecules Chemical promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst by chemical means Chiral Term used to describe molecules that contain a carbon atom that is surrounded by four different groups, allowing for isomers that are mirror-images (leading to optical isomerism) Co-catalyst A second catalyst used in conjunction with another Co-monomer Monomer molecules used in addition to main monomer when making a polymer (introduces controlled branching) Cracking Breaking large alkane molecules from heavier oil fractions into smaller ones Creep Polymer chains sliding over one another in a plastic, leading to a change in dimensions Diffraction An interference effect that leads to the scattering of beams of electromagnetic radiation and small particles (like electrons) in specific directions - used to help determine structure Enantiomers Two mirror-image molecules Envirocats A group of catalysts using clay supports Enzyme A catalyst of biological origin Ferrocene The first of the metallocenes, transition metal complexes consisting of a metal atom “sandwiched” between two 5-membered rings
Fluid Catalytic Cracker Fuel Cell Electrochemical cell used to generate electricity from fuels Hdpe High Density Poly(ethene) Heterogeneous catalysis Catalysed reactions in which the catalyst and reactants are in different phases (solid, liquid or gas) Homogeneous catalysis Catalysed reactions in which the catalyst and reactants are in the same phase (solid, liquid or gas) IR Spectrum Infra-red radiation can cause a molecule to vibrate, absorbing energy, and the frequencies at which this happens is different for each substance. A spectrum can be produced showing the frequencies at which absorption occurs, effectively a fingerprint for the material. Isomerism The characteristic of substances that have the same formula, but different structures Kaminsky Walter Kaminsky developed catalysts based on metallocenes Kevlar A nylon-based fibre with exceptional strength – used to make bullet-proof vests, tyres, heat resistant fabrics Ldpe Low density poly(ethene) Lewis acid A substance that is an electron-pair acceptor Lldpe Linear low density poly(ethene) MAO Methylalumoxane – formed during activation of a metallocene catalyst for the production of poly(ethene) Metallocene Transition metal complexes consisting of metal atoms “sandwiched” between 5-membered rings Montmorillonite A type of clay used as catalyst support in Friedel-Crafts alkylation Nanotechnology Technology that is on a molecular (or strictly nanometre) scale Natta Developer of organo-metallic catalysts for production of plastics – shared Nobel Prize with Ziegler Optical isomerism Isomerism as a result of a molecule existing in two mirror-image forms (which affect polarised light differently). The two isomers are referred to as the L- and D- isomers, or alternatively as the (R) and (S) forms Organometallic Organic compounds that also include one or more metal atoms PET “Polyethylene terephthalate” (polyethene benzene – 1,4- dicarboxylate) – used to make lightweight plastic bottles Polyethylene Poly(ethene) Note that Polythene is an ICI trade name Item Definition
Fluid Catalytic Cracker Promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst – promoters may act chemically or physically Protecting groups Groups of atoms that are placed temporarily on parts of a molecule which need to be protected from a reagent to be used in one of the synthetic steps needed to make the final product . These protecting groups are removed afterwards. Racemic mixture An equal mixture of the two optical isomers of a compound, being therefore optically inactive Racemisation The process of producing an equal mixture of the two optical isomers of a compound Recombinant DNA techniques These are a variety of techniques used to analyse and manipulate DNA. They include methods to modify genes and construct new genes. The techniques also include ways to express new and modified genes to yield protein products. Reforming The process of synthesising a suitable material from another less suitable one Rhodococcus rhodochrous A bacterium used to provide the enzymes used in the biocatalytic manufacture of Propeneamide. This bacterium is able to use organic substances as its sole source of carbon for growth Sintering The fusing of individual solid particles caused by heating. Spectroscopy Methods for analysing materials based on how the reflection or transmission of radiation (eg light, IR etc) is affected by the material Stereo selective Reacting mainly with only one optical isomer Stoichiometric In the proportions indicated by the chemical equation Structural promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst by providing a suitable structure Item Definition
Fluid Catalytic Cracker Supercritical CO2 Carbon dioxide at a temperature and pressure such that distinct liquid and gas phases do not occur TAED Tetraacetyl ethylenediamine is used in some washing powder detergents to enable peroxide-based bleaches to work at lower temperatures Titanocene A metallocene compound containing the metal titanium Uhmwpe Ultra High Molecular Weight Poly(ethene) Zeolite A group of aluminosilicate materials, some of which occur in nature. They are widely used as catalysts and as catalyst supports. Ziegler Developer of organo-metallic catalysts (known as Ziegler Catalysts) for production of plastics –shared Nobel Prize with Natta Zirconocene A metallocene compound containing the metal zirconium Item Definition

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FCC

  • 1. Professional Development Fluid Catalytic Cracker (FCC) cat cracker By Kerry Pritchard
  • 2. Fluid Catalytic Cracker A chemical reactor for converting oils with high boiling points into fuels with lower boiling points in the presence of a catalyst
  • 4. Fluid Catalytic Cracker • In petroleum geology and chemistry , cracking is the process whereby complex organic molecules (e.g. kerogens or heavy hydrocarbons ) are converted to simpler molecules (e.g. light hydrocarbons) by the breaking of carbon - carbon bonds in the precursors. The rate of cracking and the end products are strongly dependent on the temperature and presence of any catalysts
  • 5. Fluid Catalytic Cracker Crude oil is separated into fractions by fractional distillation. The heavier fractions that emerge from the bottom of the fractionating column are often broken up (cracked) to make more useful products.
  • 6. Fluid Catalytic Cracker •Applications •In an oil refinery cracking processes allow the production of "light" products (such as LPG and gasoline ) from heavier crude oil distillation fractions (such as gas oils ) and residues. Fluid Catalytic Cracking (FCC for short) produces a high yield of gasoline and LPG while hydrocracking is a major source of jet fuel, gasoline components and LPG. Thermal cracking is currently used to "upgrade" very heavy fractions ("upgrading", "visbreaking"), or to produce light fractions or distillates, burner fuel and/or petroleum coke. Two extremes of the thermal cracking in terms of product range are represented by the high-temperature process called steam cracking or pyrolysis (ca. 750 to 900 °C or more) which produces valuable ethylene and other feeds for the petrochemical industry, and the milder-temperature delayed coking (ca. 500 °C) which can produce, under the right conditions, valuable needle coke, a highly crystalline petroleum coke used in the production of electrodes for the steel and aluminum industries.
  • 7. Fluid Catalytic Cracker The branched molecules help to give petrol with higher octane number, less inclined to knocking.
  • 8. Fluid Catalytic Cracker Fluid catalytic cracking is a commonly used process and a modern oil refinery will typically include a cat cracker, particularly refineries in the USA due to the high demand for gasoline. The process was first used in around 1942, and employs a powdered catalyst. Initial process implementations were based on a low activity alumina catalyst and a reactor where the catalyst particles were suspended in a rising flow of feed hydrocarbons in a fluidized bed. In newer designs, cracking takes place using a very active zeolite-based catalyst in a short- contact time vertical or upward sloped pipe called the "riser". Pre-heated feed is sprayed into the base of the riser via feed nozzles where it contacts extremely hot fluidized catalyst at 665 to 760 °C . The hot catalyst vaporizes the feed and catalyzes the cracking reactions that break down the high molecular weight oil into lighter components including LPG, gasoline, and diesel. The catalyst-hydrocarbon mixture flows upward through the riser for just a few seconds and then the mixture is separated via cyclones. The catalyst-free hydrocarbons are routed to a main fractionator for separation into fuel gas, LPG, gasoline, light cycle oils used in diesel and jet fuel, and heavy fuel oil.
  • 9. Fluid Catalytic Cracker During the trip up the riser, the cracking catalyst is "spent" by reactions which deposit coke on the catalyst and greatly reduce activity and selectivity. The "spent" catalyst is disengaged from the cracked hydrocarbon vapors and sent to a stripper where it is contacted with steam to remove hydrocarbons remaining in the catalyst pores. The "spent" catalyst then flows into a fluidized-bed regenerator where air (or in some cases air plus oxygen) is used to burn off the coke to restore catalyst activity and also provide the necessary heat for the next reaction cycle, cracking being an endothermic reaction. The "regenerated" catalyst then flows to the base of the riser, repeating the cycle. The gasoline produced in the FCC unit has an elevated octane rating but is less chemically stable compared to other gasoline components due to its olefinic profile. Olefins in gasoline are responsible for the formation of polymeric deposits in storage tanks, fuel ducts and injectors. The FCC LPG is an important source of C3-C4 olefins and isobutane that are essential feeds for the alkylation process.
  • 10. Fluid Catalytic Cracker • Hydrocracking is a catalytic cracking process assisted by the presence of an elevated partial pressure of hydrogen. The products resulted are saturated hydrocarbons; depending on the process severity (temperature, pressure, catalyst activity) these products range from ethane, LPG to heavier hydrocarbons comprising mostly of isoparaffins. Hydrocracking is normally facilitated by a bifunctional catalyst that is capable of rearranging and breaking hydrocarbon chains as well as adding hydrogen to aromatics and olefins to produce naphthenes and alkanes. • Major products from hydrocracking are jet fuel, relatively high octane rating gasoline fractions and LPG. All these products have a very low content of sulfur and contaminants.
  • 11. Fluid Catalytic Cracker Steam cracking is a petrochemical process in which saturated hydrocarbons are broken down into smaller, often unsaturated, hydrocarbons. It is the principal industrial method for producing the lighter alkenes (or commonly olefins), including ethene (or ethylene) and propene (or propylene). • In steam cracking, a gaseous or liquid hydrocarbon feed is diluted with steam and then briefly heated in a furnace. Typically, the reaction temperature is very hot—over 900°C—but the reaction is only allowed to proceed for a few tenths of a second before being quenched by contact with a colder fluid. • The products produced in the reaction depend on the composition of the feed, the hydrocarbon to steam ratio and on the cracking temperature & furnace residence time. Light hydrocarbon feeds (such as ethane, LPGs or light naphtha's) give product streams rich in the lighter alkenes, including ethylene, propylene, and butadiene. Heavier hydrocarbon (full range & heavy naphtha's as well as other refinery products) feeds give some of these, but also give products rich in aromatic hydrocarbons and hydrocarbons suitable for inclusion in gasoline or fuel oil. The higher cracking temperature (also referred to as severity) favors the production of ethene and benzene, whereas lower severity produces relatively higher amounts of propene, C4- hydrocarbons and liquid products. • The process also results in the slow deposition of coke, a form of carbon, on the reactor walls. This degrades the effectiveness of the reactor, so reaction conditions are designed to minimize this. Nonetheless, a steam cracking furnace can usually only run for a few months at a time between de-cokings.
  • 12. Fluid Catalytic Cracker • Chemistry • "Cracking" breaks larger molecules into smaller ones. This can be done with a thermic or catalytic method. The thermal cracking process follows a homolytic mechanism, that is, bonds break symmetrically and thus pairs of free radicals are formed. The catalytic cracking process involves the presence of acid catalysts (usually solid acids such as silica-alumina and zeolites) which promote a heterolytic (asymmetric) breakage of bonds yielding pairs of ions of opposite charges, usually a carbocation and the very unstable hydride anion. Carbon-localized free radicals and cations are both highly unstable and undergo processes of chain rearrangement, C-C scission in position beta (i.e., cracking) and intra- and intermolecular hydrogen transfer or hydride transfer. In both types of processes, the corresponding reactive intermediates (radicals, ions) are permanently regenerated, and thus they proceed by a self-propagating chain mechanism. The chain of reactions is eventually terminated by radical or ion recombination
  • 13. Fluid Catalytic Cracker • Catalytic cracking uses a catalyst (often a zeolite catalyst) to aid the process of breaking down large hydrocarbon molecules into smaller ones, as well as using high temperatures and slight pressure. During this process, less reactive and therefore more stable and longer lived intermediate cations accumulate on the catalysts' active sites generating deposits of carbonaceous products generally (and in many cases inappropriately) known as coke. Such deposits need to be removed (usually by controlled burning) in order to restore catalyst activity.
  • 14. Fluid Catalytic Cracker • Thermal Cracking • In thermal cracking elevated temperatures and pressures are used. An overall process of disproportionation can be observed, where "light", hydrogen-rich products are formed at the expense of heavier molecules which condense and are depleted of hydrogen. • A large number of chemical reactions take place during steam cracking, most of them based on free radicals. Computer simulations aimed at modeling what takes place during steam cracking have included hundreds or even thousands of reactions in their models. The major sorts of reactions that take place, with examples, include: • Initiation reactions, where a single molecule breaks apart into two free radicals. Only a small fraction of the feed molecules actually undergo initiation, but these reactions are necessary to produce the free radicals that drive the rest of the reactions. In steam cracking, initiation usually involves breaking a chemical bond between two carbon atoms, rather than the bond between a carbon and a hydrogen atom. • CH3CH3 → 2 CH3•
  • 15. Fluid Catalytic Cracker • Hydrogen abstraction, where a free radical removes a hydrogen atom from another molecule, turning the second molecule into a free radical. • CH3• + CH3CH3 → CH4 + CH3CH2• • Radical decomposition, where a free radical breaks apart into two molecules, one an alkene, the other a free radical. This is the process that results in the alkene products of steam cracking. • CH3CH2• → CH2=CH2 + H• • Radical addition, the reverse of radical decomposition, in which a radical reacts with an alkene to form a single, larger free radical. These processes are involved in forming the aromatic products that result when heavier feedstocks are used. • CH3CH2• + CH2=CH2 → CH3CH2CH2CH2• • Termination reactions, which happen when two free radicals react with each other to produce products that are not free radicals. Two common forms of termination are recombination, where the two radicals combine to form one larger molecule, and disproportionation, where one radical transfers a hydrogen atom to the other, giving an alkene and an alkane. • CH3• + CH3CH2• → CH3CH2CH3 • CH3CH2• + CH3CH2• → CH2=CH2 + CH3CH3
  • 16. Fluid Catalytic Cracker • History • In 1855, petroleum cracking methods were pioneered by Chemistry Professor Benjamin Silliman, Jr., of Yale University (then Sheffield Scientific School at Yale University). Silliman, like his father, were Skull and Bones members and both Chemistry Professors at SSS. • The first thermal cracking method, the Burton process, was invented by William M. Burton; the oil industry first using it to produce gasoline in 1913. • Catalytic cracking, based upon a process developed by Dr. Alex Golden Oblad at Standard Oil of Indiana has been used from around 1936. Typical catalysts include alumina, silica, zeolites, and various types of clay • The world's first oil refinery opened at Ploieşti, Romania in 1856 [1]. Several other refineries were built at that location with investment from United States companies before being taken over by Nazi Germany during World War II. Most of these refineries were bombarded by the US Air Force in Operation Tidal Wave, August 1, 1943. • Another early example is Oljeön preserved as a museum at the UNESCO world heritage site Engelsberg. It started operation in 1875 and is part of the Ecomuseum Bergslagen. • The largest oil refinery in the world is in Ras Tanura, Saudi Arabia, owned by Saudi Aramco. The city was originally built as a sea port, but actually developed because of the huge refinery area. For most of the 20th century the largest refinery of the world was that of Abadan in Iran.
  • 17. Fluid Catalytic Cracker An oil refinery. The tapering vertical elements are smokestacks to create draft for heating units. Most of the complex vertical units are fractionating towers. Others are flares, at this refinery (Shell at Martinez, California) designed and permitted for emergency use only in case of process upset. (Flares are alleged by some to be used to dispose of unwanted waste materials by incomplete burning with the actual pollution figures grossly underreported.)
  • 23. Fluid Catalytic Cracker • http://www.uop.com/refining/1080.html • http://catcracking.com/ • http://www.tceq.state.tx.us/assets/public/permitting/air/Guidance/NewSource Review/fccu.pdf • http://catalysis.che.wsu.edu/~aplaton/interests/1_intro_to_oil_refining/ • http://www.schoolscience.co.uk/content/index.asp • http://www.ekomuseum.se/english/besoksmal/oljeon.html
  • 24. Fluid Catalytic Cracker • Item Definition Activation energy The amount by which the energy of reactants must be raised for reaction to take place Analgesic A substance with pain-relieving properties Aromatic Compounds based on the “benzene ring” Atom economy The proportion of reactant atoms that appear in the desired product Autoclave Apparatus used for small-scale reactions in a contained environment, usually at high pressure Biocatalysis Catalysed reactions where the catalyst is an enzyme Biotransformation Chemical reaction carried out using biological catalysts Candida rugosa A fungus used in biocatalysis Carbocation (“Carbo – cation”, not “carbocashun”!) A positive ion formed from an organic molecule Cat cracker “Catalytic cracker” – industrial scale equipment used to break large alkane molecules from fractional distillation of oil into smaller molecules Chemical promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst by chemical means Chiral Term used to describe molecules that contain a carbon atom that is surrounded by four different groups, allowing for isomers that are mirror-images (leading to optical isomerism) Co-catalyst A second catalyst used in conjunction with another Co-monomer Monomer molecules used in addition to main monomer when making a polymer (introduces controlled branching) Cracking Breaking large alkane molecules from heavier oil fractions into smaller ones Creep Polymer chains sliding over one another in a plastic, leading to a change in dimensions Diffraction An interference effect that leads to the scattering of beams of electromagnetic radiation and small particles (like electrons) in specific directions - used to help determine structure Enantiomers Two mirror-image molecules Envirocats A group of catalysts using clay supports Enzyme A catalyst of biological origin Ferrocene The first of the metallocenes, transition metal complexes consisting of a metal atom “sandwiched” between two 5-membered rings
  • 25. Fluid Catalytic Cracker Fuel Cell Electrochemical cell used to generate electricity from fuels Hdpe High Density Poly(ethene) Heterogeneous catalysis Catalysed reactions in which the catalyst and reactants are in different phases (solid, liquid or gas) Homogeneous catalysis Catalysed reactions in which the catalyst and reactants are in the same phase (solid, liquid or gas) IR Spectrum Infra-red radiation can cause a molecule to vibrate, absorbing energy, and the frequencies at which this happens is different for each substance. A spectrum can be produced showing the frequencies at which absorption occurs, effectively a fingerprint for the material. Isomerism The characteristic of substances that have the same formula, but different structures Kaminsky Walter Kaminsky developed catalysts based on metallocenes Kevlar A nylon-based fibre with exceptional strength – used to make bullet-proof vests, tyres, heat resistant fabrics Ldpe Low density poly(ethene) Lewis acid A substance that is an electron-pair acceptor Lldpe Linear low density poly(ethene) MAO Methylalumoxane – formed during activation of a metallocene catalyst for the production of poly(ethene) Metallocene Transition metal complexes consisting of metal atoms “sandwiched” between 5-membered rings Montmorillonite A type of clay used as catalyst support in Friedel-Crafts alkylation Nanotechnology Technology that is on a molecular (or strictly nanometre) scale Natta Developer of organo-metallic catalysts for production of plastics – shared Nobel Prize with Ziegler Optical isomerism Isomerism as a result of a molecule existing in two mirror-image forms (which affect polarised light differently). The two isomers are referred to as the L- and D- isomers, or alternatively as the (R) and (S) forms Organometallic Organic compounds that also include one or more metal atoms PET “Polyethylene terephthalate” (polyethene benzene – 1,4- dicarboxylate) – used to make lightweight plastic bottles Polyethylene Poly(ethene) Note that Polythene is an ICI trade name Item Definition
  • 26. Fluid Catalytic Cracker Promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst – promoters may act chemically or physically Protecting groups Groups of atoms that are placed temporarily on parts of a molecule which need to be protected from a reagent to be used in one of the synthetic steps needed to make the final product . These protecting groups are removed afterwards. Racemic mixture An equal mixture of the two optical isomers of a compound, being therefore optically inactive Racemisation The process of producing an equal mixture of the two optical isomers of a compound Recombinant DNA techniques These are a variety of techniques used to analyse and manipulate DNA. They include methods to modify genes and construct new genes. The techniques also include ways to express new and modified genes to yield protein products. Reforming The process of synthesising a suitable material from another less suitable one Rhodococcus rhodochrous A bacterium used to provide the enzymes used in the biocatalytic manufacture of Propeneamide. This bacterium is able to use organic substances as its sole source of carbon for growth Sintering The fusing of individual solid particles caused by heating. Spectroscopy Methods for analysing materials based on how the reflection or transmission of radiation (eg light, IR etc) is affected by the material Stereo selective Reacting mainly with only one optical isomer Stoichiometric In the proportions indicated by the chemical equation Structural promoter A substance which, though not itself a catalyst, improves the effectiveness of the catalyst by providing a suitable structure Item Definition
  • 27. Fluid Catalytic Cracker Supercritical CO2 Carbon dioxide at a temperature and pressure such that distinct liquid and gas phases do not occur TAED Tetraacetyl ethylenediamine is used in some washing powder detergents to enable peroxide-based bleaches to work at lower temperatures Titanocene A metallocene compound containing the metal titanium Uhmwpe Ultra High Molecular Weight Poly(ethene) Zeolite A group of aluminosilicate materials, some of which occur in nature. They are widely used as catalysts and as catalyst supports. Ziegler Developer of organo-metallic catalysts (known as Ziegler Catalysts) for production of plastics –shared Nobel Prize with Natta Zirconocene A metallocene compound containing the metal zirconium Item Definition

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