GB1569467A - Fluidized catalytic cracking regeneration process - Google Patents
Fluidized catalytic cracking regeneration process Download PDFInfo
- Publication number
- GB1569467A GB1569467A GB4656777A GB4656777A GB1569467A GB 1569467 A GB1569467 A GB 1569467A GB 4656777 A GB4656777 A GB 4656777A GB 4656777 A GB4656777 A GB 4656777A GB 1569467 A GB1569467 A GB 1569467A
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- GB
- United Kingdom
- Prior art keywords
- catalyst
- regeneration
- zone
- spent
- regeneration gas
- Prior art date
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Classifications
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- C—CHEMISTRY; METALLURGY
- C10—PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
- C10G—CRACKING HYDROCARBON OILS; PRODUCTION OF LIQUID HYDROCARBON MIXTURES, e.g. BY DESTRUCTIVE HYDROGENATION, OLIGOMERISATION, POLYMERISATION; RECOVERY OF HYDROCARBON OILS FROM OIL-SHALE, OIL-SAND, OR GASES; REFINING MIXTURES MAINLY CONSISTING OF HYDROCARBONS; REFORMING OF NAPHTHA; MINERAL WAXES
- C10G11/00—Catalytic cracking, in the absence of hydrogen, of hydrocarbon oils
- C10G11/14—Catalytic cracking, in the absence of hydrogen, of hydrocarbon oils with preheated moving solid catalysts
- C10G11/18—Catalytic cracking, in the absence of hydrogen, of hydrocarbon oils with preheated moving solid catalysts according to the "fluidised-bed" technique
- C10G11/182—Regeneration
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J8/00—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes
- B01J8/18—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes with fluidised particles
- B01J8/24—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes with fluidised particles according to "fluidised-bed" technique
- B01J8/26—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes with fluidised particles according to "fluidised-bed" technique with two or more fluidised beds, e.g. reactor and regeneration installations
- B01J8/28—Chemical or physical processes in general, conducted in the presence of fluids and solid particles; Apparatus for such processes with fluidised particles according to "fluidised-bed" technique with two or more fluidised beds, e.g. reactor and regeneration installations the one above the other
Description
(54) FLUIDIZED CATALYTIC CRACKING
REGENERATION PROCESS
(71) We, TEXACO DEVELOPMENT
CORPORATION, a Corporation organized and existing under the laws of the State of Delaware, United States of America, of 135 East 42nd Street, New York, New
York 10017, United States of America, do hereby declare the invention, for which we pray that a patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following statement: The present invention relates to fluidized catalytic cracking of hydrocarbons. In particular, the present invention relates to a method for regeneration of zeolitic molecular sieve containing fluidizable catalytic cracking catalyst.
Fluidized catalytic cracking processes are well known and widely practiced in petroleum refineries. Such processes comprise contacting a hydrocarbon charge with hot regenerated fluidized cracking catalyst in a reaction zone under cracking conditions for conversion of the hydrocarbon charge into cracked hydrocarbon products with the concomitant deposition of carbonaceous materials (coke) upon the catalyst; separating cracked hydrocarbon vapors from the coke-contaminated catalyst (spent catalyst) within the reaction zone; recovering as product the cracked hydrocarbon vapors essentially free of entrained catalyst; stripping, in a stripping zone, volatile hydrocarbons from the spent catalyst by contact with stripping vapors; regenerating, in a regeneration zone, the coke-contaminated stripped catalyst by burning coke therefrom with a molecular oxygen-containing regeneration gas at an elevated temperature for restoring activity to the regenerated catalyst; and contacting hot regenerated catalyst with additional hydrocarbon charge in the reaction zone, as described above.
In fluidized catalytic cracking processes for conversion of normally liquid hydrocarbons, such as petroleum fractions, into lower boiling hydrocarbons, it is well known to employ catalysts comprising zeolitic aluminosilicate molecular sieves to obtain increased conversion of hydrocarbon charge into useful, lower boiling hydrocarbons, particularly into naphtha fractions useful as motor fuels. Such catalysts comprise an amorphous matrix such as silica-alumina, silica-magnesia, etc. containing a minor portion of a crystalline zeolytic aluminosilicate molecular sieve having uniform crystalline port openings which has been ion exchanged with rare earth ions, magnesium ions, hydrogen ions, ammonium ions and/or other divalent and polyvalent ions for reduction of the sodium content of the molecular sieves to not more than one weight percent, and preferably less. These cracking catalysts (hereinafter referred to as "zeolite catalysts") are well-known and commercially available.
The activity and selectivity of such zeolite catalysts for conversion of hydrocarbon charge stocks into useful cracked hydrocarbon products, particularly naphtha, are particularly affected by residual carbon remaining on regenerated catalyst. For obtaining the full utility and benefit the activity and selectivity of such zeolite catalysts, carbon on regenerated catalyst is maintained below 0.2 weight percent, and preferably 0.07 weight percent or less.
Now, according to the present invention, an improved process is disclosed for regeneration of spent, coke-contaminated zeolite cracking catalyst by burning coke therefrom with a molecular oxygen-containing regeneration gas to produce flue gas comprising oxides of carbon and regenerated catalyst containing 0.1 weight percent or less residual carbon.
According to the present invention there is provided a method of regenerating a cata lyst from a fluidized catalytic cracking process wherein a hydrocarbon charge is cracked, in a reaction zone, in the presence of hot, regenerated cracking catalyst, for conversion of the hydrocarbon charge into lower boiling hydrocarbon product, wherein catalyst, spent by the accumulation of coke thereon is separated from the hydrocarbon product at a temperature in the range of 750-1100 F, and wherein the spent catalyst is regenerated, in a regeneration zone, by burning coke therefrom; which comprises:
a) charging spent catalyst substantially vertically downward into a vertical, cylindrical lower regeneration zone;
b) charging an oxygen-containing primary regeneration gas to the lower regeneration zone, under turbulent flow conditions, at a flow rate sufficient to provide 25 to 40 percent of the stoichiometric amount of oxygen required for combusting the coke on spent catalyst to carbon dioxide and water, for forming an intimate mixture of spent catalyst and primary regeneration gas;
c) flowing the catalyst-primary regeneration gas mixture upward through said lower regeneration zone at a superficial vapor velocity in the range of 4.5-8 ft/sec, and a catalyst residence time in the range of 10 seconds to 1 minute into the bottom of a vertical, cylindrical upper regeneration zone for initiation of catalyst regeneration;
d) radially distributing an oxygen-containing secondary regeneration gas into the bottom of the upper regeneration zone at a flow rate sufficient to provide 60 to 85 percent of the stoichiometric amount of oxygen required for combustion of the coke to carbon dioxide and water such that 100 to 110 percent of the stoichiometric amount of oxygen required for combustion of coke to carbon dioxide and water is supplied to the upper and lower regeneration zone;
e) burning coke from the catalyst undergoing regeneration at a specific coke burning rate in the range of 0.05 to 1.0 pounds of coke per hour per pound of catalyst in said upper regeneration zone;
f) withdrawing hot regenerated catalyst from the upper portion of the fluidized dense phase catalyst bed for contact with additional hydrocarbon charge in the reaction zone;
g) disengaging regeneration gas, comprising carbon dioxide and carbon monoxide, substantially spent in oxygen, and containing entrained catalyst from the upper surface of the fluidized dense phase catalyst bed;
h) flowing the spent regeneration gas and entrained catalyst from the top of the upper regeneration zone into a frusto
conic transition zone wherein a major por
tion of the entrained catalyst disengages
the spent regeneration gas and returns to
the fluidized dense phase bed under the
influence of gravity, and wherein a dilute
phase of catalyst suspended in spent re
generation gas is formed;
i) flowing the dilute phase from the top
of the transition zone into the bottom of
a cylindrical dilute phase regeneration
zone;
j) separating, in a separation zone, the
dilute phase into a catalyst phase and spent
regeneration gas phase essentially free of
entrained catalyst;
k) transferring the separated catalyst
from the separation zone to the lower re
generation zone for contact with additional
spent catalyst and primary regeneration
gas; and
1) venting the spent regeneration gas
essentially free of entrained catalyst from
the separation zone as a flue gas.
According to a preferred embodiment of
the present invention spent, coke-con
taminated cracking catalyst, from a
fluidized catalytic cracking zone wherein
a hydrocarbon charge is cracked in the
presence of hot, regenerated catalyst,
having 0.5-2.0 weight percent coke de
posited thereon, at a temperature in the
range of 750-1100"F., is transferred sub
stantially vertically into the axial center
of a vertical, cylindrical lower regenera
tion zone for intimate mixture with an
oxygen-containing primary regeneration
gas, under turbulent flow conditions. The
primary regeneration gas is charged into
the lower regeneration zone radially at an
angle downward from horizontal of 30 to 60 at a nozzle exit velocity in the range
of 65-175 ft/sec, at a flow rate sufficient to
provide 25 to 40 percent of the stoichio
metric amount of oxygen required for
combustion of the coke on spent catalyst
to carbon dioxide and water. The spent
catalyst-primary regeneration gas mixture
flows upward in said lower regeneration
zone, at a superficial vapor velocity in the
range of 4.5-8.0 ft/sec, for a catalyst resid
ence time of 1.0 second to 1 minute, for
initiation of catalyst regeneration and for
distribution of the spent catalyst-primary
regeneration gas mixture across the cross
sectional area of the lower regeneration
zone.
From the open top of the lower re
generation zone, the spent catalyst-primary
regeneration gas mixture flows upward into
the bottom of a vertical, cylindrical upper
regeneration zone. In the upper regenera
tion zone, an oxygen-containing secondary
regeneration gas is injected at a flow rate
sufficient to provide 60 to 85 percent of the stoichiometric amount of oxygen re quired for combustion of coke on spent catalyst to carbon dioxide and water, such that 100 to 110 percent of the oxygen required for combustion of coke is supplied by primary and secondary regeneration gas to the regeneration process. The secondary regeneration gas flows radially into the bottom of the upper regeneration zone, such that regeneration gas, flowing upward at a superficial vapor velocity in the range of 2.5-6 ft/sec, and catalyst undergoing regeneration form a fluidized dense phase bed of catalyst having an upper surface above which is superimposed a dilute phase of catalyst suspended in spent regeneration gas. Within the upper regeneration zone, operating conditions including catalyst residence time in the dense phase bed in the range of 3 to 20 minutes, regeneration temperature in the range of 1150-13500F and pressure at the top of the dense phase bed in the range of 6-50 psig are maintained to provide a specific coke burning rate of 0.05 to 1 pounds of coke per hour per pound of catalyst in the dense phase bed such that residual carbon on regenerated catalyst is reduced to 0.1 wt. percent or less. Regeneration operating conditions and the amount of oxygen supplied to the regeneration process may be adjusted within their respective ranges to obtain carbon on regenerated catalyst of 0.1 wt. percent or less, and preferably 0.05 wt. percent or less, and to combust essentially all carbon monoxide, formed from burning coke, to carbon dioxide.
From the upper portion of the fluidized dense phase catalyst bed in the upper regeneration zone, hot, regenerated catalyst is withdrawn into a deaeration zone wherein regeneration gas is separated from the regenerated catalyst. The deaerated catalyst is transferred from the deaeration zone to the reaction zone for conversion of additional hydrocarbon charge stock.
Regeneration gas separated from the deaerated catalyst is transferred to a dilute phase zone for admixture with the dilute phase of catalyst suspended in spent regeneration gas which is above the upper surface of the fluidized dense phase catalyst bed.
From the upper surface of the fluidized dense phase catalyst bed, spent regeneration gas, comprising carbon dioxide and carbon monoxide, substantially depleted in oxygen content, and having catalyst entrained therein, flows upward into a frustoconic transition zone wherein spent regeneration gas superficial vapor velocity is reduced from 2.5-6.0 ft/sec to 1.0-2.2 ft/ sec. such that a major portion of the entrained catalyst returns, under the influence of gravity to the fluidized dense phase catalyst bed. The spent regeneration gas
with the minor portion of catalyst en
trained therein as a dilute phase flow from the top of the transition zone into a dilute
phase regeneration zone. The ratio of carbon dioxide to carbon monoxide in the spent regeneration gas is in the range of
1:1 to 500: 1 or greater. Additional carbon
monoxide may be combusted in the regeneration process, thus aleviating a pollution hazard by increasing the amount of
oxygen supplied to the fluidized dense phase catalyst bed. Such additional oxygen
may result in carbon monoxide combustion
within the transition zone. A substantial portion of the heat of such carbon monoxide combustion is absorbed by the entrained catalyst, and is returned to the fluidized dense phase bed such that the dilute phase temperature does not exceed a temperature (1500"F and preferably 1450"F) at which the catalyst is seriously deactivated.
The dilute phase, having a superficial vapor velocity of 1.0-2.2 ft/sec, flows from the dilute phase regeneration zone into a catalyst-gas separation zone wherein entrained catalyst is essentially completely separated from the spent regeneration gas.
The spent regeneration gas is transferred from the catalyst-gas separation zone and the regeneration process as flue gas. The carbon monoxide content of the flue gas may be 500 ppm or less. The hot, separated catalyst from the catalyst-gas separation zone is transferred to the lower regeneration zone for contact with additional spent catalyst and primary regeneration gas for transfer of heat thereto, thus enhancing the initiation of catalyst regeneration.
Advantages of the improved regeneration process of the present invention include regeneration of spent zeolitic cracking catalyst to provide a regenerated catalyst having less than 0.1 weight percent residual carbon thereon, and to produce a flue gas substantially free of carbon monoxide.
The Drawing is a schematic representation of fluidized catalyst regeneration process equipment embodying improvements of the present invention.
In order to demonstrate and provide a better understanding of the invention, reference is now made to the Drawing.
The Drawing is a schematic representation of fluidized catalytic cracking regeneration apparatus embodying improvements of the present invention. It is to be understood that the Drawing is only in such detail as required for a clear understanding of the present invention, and that various
elements commonly employed in commercial apparatus, such as valves, pumps, in
strumentations, etc. which are unneces
sary for a description of the present inven tion have been omitted for the sake of clarity.
In the Drawing, fluidized cracking catalyst regeneration apparatus is shown, including a vertical regeneration vessel 100 comprising a lower regeneration section 101 which comprises a hollow cylinder having a closed bottom and an open top; an upper regeneration section 102 comprising a hollow cylinder having an axial centered opening in the bottom of an open top, wherein the open top of said lower regeneration section 101 is in open communication with the bottom opening of said upper regeneration section 102; an open ended frusto-conic transition section 103, the bottom of which is in axial alignment and in communication with, the open top of upper regeneration section 102; and a dilute phase regeneration section 104, comprising a hollow cylinder having a closed top and an open bottom in axial alignment and in communication with the open top of said transition section 103. The internal cross-section area of lower regenerator section 101 is sufficient to provide a regeneration gas superficial vapor velocity in the range of 4.5-8.0 ft/ sec., and the volume of lower regenerator section 101 is sufficient to provide a catalyst residence time of from 10 seconds to one minute at flow rates and operating conditions contemplated herein. The internal cross-section area of upper regeneration section 102 is sufficient to provide a regeneration gas superficial vapor velocity in the range of 2.5-6.0 ft/sec, and the volume of upper regeneration section 102 is sufficient to provide a dense phase fluidized catalyst residence time of from 3 minutes to 20 minutes at flow rates and operating conditions contemplated herein.
The walls of transition section 103 have a conic angle of 20"40" from the vertical and have sufficient height such that the increased cross-sectional area of the top of transition section 103 is sufficient for reducing the superficial vapor velocity of regeneration gas flowing therethrough from the range of 2.5-6.0 ft/sec. to the range of 1.0-2.2 ft/sec. Dilute phase regeneration section 104 is of the same diameter and cross-section area as the top of transition section 103.
In the Drawing, a spent catalyst conduit means 105 for introducing spent, cokecontaminated catalyst from a reaction section (not shown) substantially vertically downward into regenerator vessel 100 comprises a spent catalyst conduit directed downward at an angle of 30 to 450 from the vertical, having a discharge end directed substantially vertically downward.
Said spent catalyst conduit 105 passes through the side wall of upper regenerator section 102 and the lower, discharge end of said spent catalyst conduit 105 is directed substantially vertically downward into the axial center of lower regenerator section 101. The open discharge of spent catalyst conduit 105 terminates above a spent catalyst distribution means 109 which comprises a conical member having an upward facing apex, and having a base diameter equivalent to 1/2 to 1-1/2 spent catalyst conduit 105 diameters. Spent catalyst distribution means 109 is axially centered within lower regenerator section 101. Spent catalyst from the reaction section (not shown) flows downwardly through spent catalyst conduit 105 and discharges vertically downward, striking spent catalyst
distribution means 109 for radial distribution into lower regenerator section 101.
In the Drawing, a primary regeneration gas conduit 106 passes into lower regenerator section 101 as means for introducing a molecular oxygen-containing primary regeneration gas, e.g. air, into regenerator vessel 100. The discharge end of primary
regeneration gas conduit 106 is in com
munication with a primary regeneration
gas distribution means 107 which comprises
a pipe forming a ring having a plurality of
openings directed downward at an angle within the range of 30 to 600 from the
horizontal for radially distributing primary
regeneration gas within the bottom of
lower regenerator section 101. The total
cross-sectional area of the plurality of openings in primary regeneration gas dis
tribution means 107 is sufficient to provide
a primary regeneration gas discharge
velocity in the range of 65-175 ft/sec. when
said primary regeneration gas flow rate is
sufficient to provide 25 to 40 percent of
the molecular oxygen required for con
version of coke on spent catalyst to carbon
dioxide and water, such that spent catalyst
from spent catalyst conduit means 105, and primary regeneration gas from primary
regeneration gas distribution means 107 are
intimately mixed and radially distributed within the bottom of lower regenerator section 101.
In the Drawing, a secondary regeneration gas conduit 110 passes into the lower portion of upper regenerator section 101 as means for supplying a secondary regeneration gas comprising molecular oxygen, e.g., air, to a secondary gas distributor 108. Secondary gas distributor 108 comprises a pipe forming a ring having a - plurality of openings directed downward
at an angle within the range of 30 to 60 from the horizontal for radially distribut
ing secondary regeneration gas within the bottom of upper regenerator section 102.
The total cross-sectional area of said openings in secondary gas distributor 108 is sufficient to provide a secondary regeneration gas discharge velocity in the range of 65-175 ft. per sec.
The flow rate of said secondary regeneration gas is sufficient to provide 60 to 85 percent of the molecular oxygen required for conversion of the coke on spent catalyst to carbon dioxide and water.
In the drawing, upper regenerator section 102 has a cross-sectional area sufficient to provide for a superficial vapor velocity of regeneration gas flowing therethrough in the range of 2.5 to 6.0 ft/sec., such that spent catalyst undergoing regeneration and regeneration gas form a fluidized dense phase bed of catalyst. The volume of upper regenerator section 102 is sufficient to provide an average residence time of 3 to 20
minutes for spent catalyst in the fluidized
dense phase bed, such that substantially all the coke may be burned therefrom at a
specific coke burning rate within the range of 0.05 to 1 pounds of coke per hour per pound of catalyst in the fluidized dense
phase catalyst bed, at regeneration temperatures within the range of 1150 to 1 3500F.- In the Drawing, a regenerated catalyst ductway 113 communicates between the
upper portion of upper regenerator section
102 and an external regenerated catalyst standpipe 114. Regenerated catalyst ductway 113 is inclined at an angle in the range of 30 to 60 from the vertical such that regenerated catalyst from the upper portion of the fluidized dense phase catalyst bed maintained in upper regenerator section 102 will flow downwardly through regenerated catalyst ductway 113 into the
upper portion of external regenerated catalyst standpipe 114. Regenerated catalyst standpipe 114 comprises an upper vertical cylindrical section 115 having a cylinder wall, an open top and an open bottom and a lower frustoconic section 116 having an open top and open bottom. Communication of regenerated catalyst ductway 113 with upper standpipe section 115 is through said vertical cylinder wall. The open top of lower standpipe section 116 is in communication with the open bottom of upper standpipe section 115, and the walls of lower standpipe section 116 preferably have a conical angle of about 7 1/2" from the vertical. Within said lower standpipe section 116 hot regenerated catalyst from regenerator vessel 100 is deaerated. A slide valve 117, in communication with the bottom of lower standpipe section 116 allows withdrawal of hot, deaerated, regenerated catalyst at a controlled rate for contact with a hydrocarbon charge stock in a fluidized catalytic cracking reaction section (not shown).
In the Drawing, gas entering regenerated catalyst standpipe 114 with regenerated -catalyist from reactor vessel 100, accumu -lates in upper standpipe section 115. A reaeration gas conduit 69 is in communication with the open top of upper standpipe section 115 and dilute phase regenerator section 104 for removing such accumulated deaeration gas from regenerated catalyst standpipe 114 to the upper portion of reactor vessel 100.
In the Drawing, as previously stated, the open top of upper regenerator section 102 is in communication with the open bottom of transition section 103, for allowing flow of regeneration gas and entrained catalyst from the upper surface of the fluidized
dense phase catalyst bed maintained in upper regenerator section 101 into dilute phase regenerator section 104 wherein a
dilute phase of catalyst suspended in regeneration gas is maintained.
In the Drawing, the open top of re
generator transition section 103 is in com
munication with the open bottom of dilute phase regenerator section 104 for flow of
regeneration gas and entrained catalyst
into the dilute catalyst phase maintained in
dilute phase regenerator section 104. The
cross-sectional area of dilute phase re
generator section 104 is such that the
superficial vapor velocity of gas flowing
therethrough is in the range of 1.0 to 2.2 ft. per second. Within dilute phase re
generator section 104, catalyst-gas separation means 118, preferably cyclone separators, are provided for separating entrained
catalyst from spent regeneration gas.
Within the present invention, it is contemplated that catalyst-gas separation
means 118 may comprise one or more
cyclone separators in series and/or parallel
arrangement for substantially completely separating the entrained catalyst from the spent regeneration gas. For the purposes of clarity, only one separator 118 is shown.
Line 119, in communication with the bottom of separator 118 extends downward into the lower regenerator section 101, terminating at about the point spent catalyst discharges from spent catalyst distributor 109. Entrained catalyst, separated from spent regeneration gas in separator 118 flows downward at regeneration temperature through line 119 and discharges into the bottom of lower regenerator section 101 wherein the hot separated catalyst mixes with spent catalyst and primary regeneration gas, increasing the temperature thereof and improving the initiation of coke burning on the spent catalyst.
In the Drawing, Line 120 communicates with the top of separator 118 and a plenum chamber 121. Plenum chamber 121 is attached to the top of regenerator vessel
100. Spent regeneration gas, essentially completely separated from entrained catalyst in catalyst-gas separator 118 flows through line 120 into plenum chamber 121.
A vent line 122 communicating with plenum chamber 121 provides means for removing spent regeneration gas from regenerator vessel 100 as a flue gas.
Fluidized catalytic cracking units employing the improved regeneration apparatus of the present invention are operated for the conversion of hydrocarbon charge stock into lower boiling cracked hydrocarbons and coke. Such conversion of hydrocarbon charge is accomplished by contacting hydrocarbon charge with hot regenerated catalyst under cracking conditions in a fluidized catalytic cracking reaction zone. Hydrocarbon charge and regenerated catalyst may be contacted in a riser transport reactor, in a reactor vessel containing a dense phase fluidized bed of catalyst fluidized by the up-flowing hydrocarbon charge vapors, or in a reactor zone comprising both a riser transport zone and a dense phase catalyst bed. Reaction conditions for conversion of hydrocarbon charge include reaction temperatures in the range of 850-1100"F, reaction pressures in the range of 5-50 psig or higher, regenerated catalyst to hydrocarbon charge weight ratios (catalyst/oil ratios) of from 2:1 to 20:1, catalyst and hydrocarbon contact times of from 10 seconds to 5 minutes, and reactor superficial vapor velocities in the range of 0.8 to 3.0 ft/sec. In such a fluidized catalytic cracking process, hydrocarbon charge and hot regenerated catalyst are contacted at such reaction conditions for conversion of the hydrocarbon charge into lower molecular weight hydrocarbons.
A substantial portion of the hydrocarbons in contact with the catalyst are in vapor phase with a minor portion being present as liquid or solid phase. Such solid and liquid hydrocarbons collect upon the catalyst particles, resulting in a decrease of catalyst activity. Catalyst containing such hydrocarbons is referred to as spent catalyst. In such a fluidized catalytic cracking process, spent catalyst is treated for removal of such accumulated hydrocarbons and for regeneration of cracking activity.
From the reaction zone of a fluidized catalytic process, spent catalyst containing accumulated hydrocarbons is commonly transferred to a stripping zone wherein the spent catalyst is contacted with a stripping vapor (e.g. steam) at a temperature in the range of 750-1100 F for vaporization of at least a portion of the volatile hydrocarbons accumulated upon the catalyst. Volatilized hydrocarbons and stripping vapors are transferred from the stripping zone to the
reaction zone. Stripped catalyst containing nonvolatile hydrocarbon residues (commonly referred to as coke), is transferred to a regeneration zone wherein catalytic activity is restored to said catalyst by burning such coke from the catalyst with a molecular oxygen-containing regeneration gas at an elevated temperature. Upon regeneration, hot regenerated catalyst, having restored activity, is transferred from the regeneration zone for contact with additional hydrocarbons charge in the reaction zone, as described above.
Catalysts, the regeneration of which the regeneration apparatus of the present invention is well suited include those catalyst commonly referred to as "zeolite" or "molecular sieve" cracking catalysts.
Such catalyst will be referred to herein as zeolite catalyst for convenience in the discussion which follows.
Such zeolite catalyst comprise 95-85 wt. %) crystalline aluminosilicate zeolitic molecular sieves, having uniform crystalline pore openings, dispersed within said matrix. Said matrix generally has substantial cracking activity and is selected from naturally occuring clays, and synthetic oxide mixtures such as silica-alumina, silica-magnesia, and silica-zirconia. The zeolite portion of such zeolitic cracking catalyst comprises small particles of either natural or synthetic crystalline, aluminosilicate zeolitic molecular sieves, such as faujasite, chabazite and X-type or Y-type aluminosilicate materials, having a major portion of their sodium content replaced by ion exchange with magnesium ions, rare earth ions, ammonium ions, hydrogen ions, and/or other divalent and polyvalent ions which enhance the catalyst activity.
The apparatus of the present invention is particularly well suited for use in regenerating those zeolite cracking catalysts promoted for increasing the rate of burning carbon monoxide to carbon dioxide within the regeneration zone. Such promoted zeolite catalyst may have controlled pore size, and contain small amounts of material such as plantin and/or composition of the catalyst is affected in such a way that the catalyst irreversably losses at least a portion of its catalytic activity.
Regeneration of catalyst in a fluidized catalytic cracking process comprises burning coke therefrom at an elevated temperature with a molecular oxygen containing regeneration gas. Generally, the regeneration gas is air, although other regeneration gases containing molecular oxygen, such as oxygen enriched air and steam and air mixtures, may also be employed. The degree of regeneration of catalytic activity of a spent cracking catalyst is proportional to the degree of removal of coke from said catalyst. Lower residual carbon content of regenerated catalyst results in higher regenerated catalyst activity. The regenerated catalytic activity of zeolite cracking catalyst appears to be somewhat more sensitive to residual carbon that the regenerated activity of an amorphous cracking catalyst.
Preferably, residual carbon content of regenerated catalyst is reduced to 0.1 weight percent or less.
Hydrocarbon charge stocks within contemplation of the present invention are those which may be cracked to yield useful lower molecular weight hydrocarbon products. Examples of hydrocarbon charge stocks include virgin gas-oils, vacuum gas oils, atmospheric residua, topped crudes, shale oils, tar sand oils, virgin naphthas, and cycle oil and cracked naphtha recycle streams from cracking processes. A portion of all such hydrocarbon charge stocks when subjected to fluidized catalytic cracking is converted into coke. The portion of hydrocarbon charge stock which is converted into coke is proportional to the boiling range of the particular charge stock, and will vary from 1 weight percent for some naphthas to 15 weight percent or more for some residua.
In a process employing the improvements of the present invention, spent cracking catalyst containing about 0.5 to 2.0 weight percent coke is transferred vertically downward through spent catalyst conduit 105 into the axial center of a first regeneration zone maintained in lower regenerator section 101. Such downward flowing spent catalyst is contacted with a primary regeneration gas flowing radially into said first regeneration zone, under turbulent flow conditions, for intimately mixing said spent catalyst and regeneration gas, and even distributing the resulting mixture across the cross-sectional area of said first regeneration zone. Primary regeneration gas is supplied to the first regeneration zone via primary gas distributing means 107 in an amount sufficient to
provide 25 to 40% of the stoichiometric molecular oxygen required for complete combustion of coke on spent catalyst to carbon dioxide and water. Spent catalyst entering said first regeneration zone is at a temperature in the range of 750-1100"F, and primary regeneration gas entering the first regeneration zone is at a temperature in the range of 100-600"F, such that combustion of coke upon spent catalyst is initiated. Residence time of spent catalyst in said first regeneration zone is sufficient for obtaining even distribution of spent catalyst and primary regeneration gas across the cross-sectional area of the lower regenerator section 101, and is in the range of 10 seconds to 1 minute. From said first regeneration zone spent catalyst and regeneration gas flow upwardly into a second regeneration zone maintained in the upper regeneration section 102. Secondary regeneration gas, containing molecular oxygen, is radially distributed into the lower portion of said second regeneration zone, via secondary regeneration gas distribution means 110. The rate of secondary regeneration gas flow is sufficient such that the total oxygen in regeneration gas is equivalent to 100 to 110 per cent of the stoichometric oxygen required for combustion of coke to carbon monoxide and water. In said secondary regeneration zone, operating conditions are maintained such that a dense phase bed of catalyst undergoing regeneration is fluidized by the upward flow of regeneration gas, and wherein substantially all the coke is burned from the catalyst undergoing regeneration.
In the second regeneration zone the dense phase fluidized bed of catalyst has a density in the range of 20-30 pounds per cubic foot and has an upper surface above which is superimposed a dilute phase of catalyst suspended in regeneration gas. Operating conditions within the second regeneration zone for maintaining the fluidized dense catalyst phase bed and for obtaining the degree of regeneration desired, include regeneration temperatures in the range of 1050-1350"F, regeneration pressures at the top of the dense phase catalyst bed in the range of 6-50 psig, regeneration gas superficial vapor velocity upward through the dense phase bed in the range of 2.5 to 6.0 ftlsec catalyst residence time in the dense phase bed in the range of 3-20 minutes, and a specific coke burning rate, based upon the inventory of catalyst in the dense phase bed, in the range of 0.05 to 1.0 pounds of coke per hour per pound of catalyst. Under these regeneration conditions, residual carbon on regenerated catalyst may be reduced to 0.1 weight percent or preferably 0.05 weight percent or less.
In the present invention, distribution of primary regeneration gas and catalyst into the first regeneration zone is such as to produce an intimate mixture of spent catalyst and a primary regeneration gas which flows upward into the bottom of the second regeneration zone. Regenerated catalyst is withdrawn from the upper portion of the second regeneration zone near the upper surface of the fluidized catalyst bed via regenerated catalyst ductway 113 which does not have projections which may impede the smooth flow of catalyst and vapors within the fluidized dense phase catalyst bed. Regenerated catalyst from said regenerated catalyst ductway 113 flows into a regener
ated catalyst standpipe 114, located external
to the second regeneration zone, wherein re
generated catalyst disengages regeneration
gas entrained therein to form a deaerated
bed of regenerated catalyst in the lower
standpipe section 116. Hot regenerated
catalyst is transferred from the lower standpipe section 116 for contact with additional
hydrocarbon charge stock in the reaction
zone of the fluidized catalyst cracking pro
cess. Regeneration gas separated from the
regenerated catalyst flows from the upper
standpipe section 115 into the dilute cata
lyst phase which superimposes the dense
phase fluidized catalyst bed, via line 69.
In the present invention, regeneration gas
comprising nitrogen, carbon dioxide, carbon
monoxide, and substantially spent in mole
cular oxygen, with a small amount of catalyst entrained therein, disengages the upper
surface of the fluidized dense phase catalyst
bed and enters a transition zone wherein
the cross-sectional area is increased such
that the superficial vapor velocity of the
spent regeneration gas decreases to a value
in the range of 1.0 to 2.2 ft./sec. Upon
decreasing the superficial vapor velocity of
spent regeneration gas within the transition zone, substantial amounts of entrained
catalyst return, under the influence of
gravity, to the top of the dense phase fluidized catalyst bed. Spent regeneration gas from the top of said transition zone forms
a dilute phase having a small amount of catalyst suspended therein. This dilute
phase having a density of 0.1 to 1.0 lbicu. ft enters the bottom of a dilute phase regeneration zone. The ratio of carbon dioxide to carbon monoxide with spent regeneration gas of the dilute phase may vary from 1:1 to 500 to 1 or greater depending upon operating conditions within said fluidized dense phase catalyst bed. As carbon monoxide is a serious air pollutant, it is desirable that as much as possible be burned to carbon dioxide within regeneration vessel 100. With unpromoted zeolite cracking catalyst, increased temperatures in the regeneration zone dense phase result in increased combustion of carbon monoxide to carbon dioxide such that at about 13500F the carbon monoxide content of spent regeneration gas will be less than 1 percent by weight and preferably is less than about 200 parts per million weight (ppmw) under regeneration conditions employed herein. When catalyst promoted for combustion of carbon monoxide to carbon dioxide is employed, essentially complete combustion of carbon monoxide to carbon dioxide may be obtained at substantially lower temperatures of 12500F. In the event that combustion of carbon monoxide in the dense phase fluidized bed is incomplete and substantial amounts of carbon monoxide are present in spent regeneration gas entering the transition zone, additional secondary regeneration gas, sufficient to provide from 1 to 10 mole percent excess oxygen over the stoichiometric amount of oxygen required for complete combustion of the coke on spent catalyst, is introduced into the second
regeneration zone via secondary regeneration gas distribution means 110. This additional oxygen injected into the fluidized dense phase enables substantially com
bustion of carbon monoxide to carbon dioxide in said fluidized dense phase. Additionally, excess oxygen in the spent regeneration gas of the transition zone and the dilute phase regeneration zone results in additional combustion of carbon monoxide to carbon dioxide. The portion of catalyst
entrained in the spent regeneration gas
which falls back to the upper surface of the dense phase fluidized catalyst bed from the transition zone under the influence of gravity, carries a substantial amount of the heat generated from the combustion of car
bon monoxide to carbon dioxide in the
transition zone back to the dense phase fluidized catalyst bed, such that the temperature of the dilute phase does not increase above the temperature at which entrained catalyst will be deactivated (e.g. to about 1450cm).
In the present invention, the dilute phase comprising spent regeneration gas and catalyst, having carbon monoxide essentially completely burned to carbon dioxide, exits said dilute phase regeneration zone into a catalyst-gas separation zone wherein spent regeneration gas is essentially completely separated from said entrained catalyst. From said separation zone spent regeneration gas is removed from the regeneration zone as a flue gas. Separated catalyst, at regenera tion temperature in the range of 1150 1450cm, from the bottom of said separation zone is returned to said first regeneration zone. In said first regeneration zone said hot regenerated catalyst is intimately mixed with spent catalyst and primary regeneration gas for increasing the temperature thereof such that combustion of coke on spent catalyst is enhanced.
Claims (10)
1. A method of regenerating a catalyst from a fluidized catalytic cracking process wherein a hydrocarbon charge is cracked, in a reaction zone, in the presence of hot, regenerated cracking catalyst, for conversion of the hydrocarbon charge into lower boilinging hydrocarbon product, wherein catalyst, spent by the accumulation of coke
thereon is separated from the hydrocarbon product at a temperature in the range of 750-1100 F, and wherein the spent catalyst is regenerated, in a regeneration zone, by burning coke therefrom; which comprises:
a) charging spent catalyst substantially
vertically downward into a vertical, cylindrical lower regeneration zone;
b) charging an oxygen-containing primary
regeneration gas to the lower regeneration zone, under turbulent flow conditions, at a flow rate sufficient to provide 25 to 40 percent of the stoichiometric amount of oxygen required for combusting the coke on spent catalyst to carbon dioxide and water, for forming an intimate mixture of spent catalyst and primary regeneration gas;
c) flowing the catalyst-primary regeneration gas mixture upward through said lower regeneration zone at a superficial vapor velocity in the range of 4.5-8 ft/sec, and a catalyst residence time in the range of 10 seconds to 1 minute into the bottom of a vertical, cylindrical upper regeneration zone for initiation of catalyst regeneration;
d) radially distributing an oxygencontaining secondary regeneration gas into the bottom of the upper regeneration zone at a flow rate sufficient to provide 60 to 85 percent of the stoichiometric amount of oxygen required for combustion of the coke to carbon dioxide and water such that 100 to 110 percent of the stoichiometric amount of oxygen required for combustion of coke to carbon dioxide and water is supplied to the upper and lower regeneration zone;
e) burning coke from the catalyst undergoing regeneration at a specific coke burning rate in the range of 0.05 to 1.0 pounds of coke per hour per pound of catalyst in said upper regeneration zone; f) withdrawing hot regenerated catalyst from the upper portion of the fluidized dense phase catalyst bed for contact with additional hydrocarbon charge in the reaction zone;
g) disengaging regeneration gas, comprising carbon dioxide and carbon monoxide, substantially spent in oxygen, and containing entrained catalyst from the upper surface of the fluidized dense phase catalyst bed;
h) flowing the spent regeneration gas and entrained catalyst from the top of the upper regeneration zone into a frusto-conic transition zone wherein a major portion of the entrained catalyst disengages the spent
regeneration gas and returns to the fluidized dense phase bed under the influence of
gravity, and wherein a dilute phase of catalyst suspended in spent regeneration gas is
formed;
i) flowing the dilute phase from the top
of the transition zone into the bottom of a cylindrical dilute phase regeneration zone;
j) separating, in a separation zone, the dilute phase into a catalyst phase and spent regeneration gas phase essentially free of
entrained catalyst;
k) transferring the separated catalyst from the separation zone to the lower regeneration zone for contact with additional spent catalyst and primary regeneration gas: and
1) venting the spent regeneration gas essentially free of entrained catalyst from the separation zone as a flue gas.
2. A method as claimed in Claim 1, wherein primary regeneration gas is charged
radially into the lower regeneration zone from a plurality of openings in a primary regeneration gas distributor in a downward direction at an angle in the range of 30 to 60 from horizontal at an exit velocity from the primary regeneration gas distributor in the range of 65-175 ftlsec for intimately mixing primary regeneration gas and spent catalyst under turbulent flow conditions.
3. A method as claimed in Claim 1 or 2, wherein secondary regeneration gas is charged radially into the upper regeneration zone from a plurality of openings in a secondary regeneration gas distributor in a downward direction at an angle in the range of 30 to 60 from horizontal at an exit velocity from the secondary regeneration gas distributor in the range of 65-175 ftlsec for dispersing secondary regeneration gas into the bottom of the fluidized dense phase bed.
4. A method as claimed in any preceding claim, wherein the amount of oxygen supplied with the primary and secondary regeneration gas, the regeneration pressure, the fluidized dense phase temperature, and the catalyst residence time in the fluidized dense phase bed are adjusted within their respective ranges for reducing residual carbon on regenerated catalyst to 0.1 weight percent or less.
5. A method as claimed in any preceding claim, wherein regenerated catalyst is withdrawn from the fluidized dense phase bed into a catalyst standpipe deaeration zone external of the upper regeneration zone wherein the regenerated catalyst is deaerated forming a bed of hot, aerated, regenerated catalyst superimposed by deaerated gas and wherein the deaerated gas is transferred from the standpipe deaeration zone to the dilute phase regeneration zone.
6. A method as claimed in any preceding claim, wherein the spent regeneration gas disengaging the fluidized dense phase catalyst bed contains a substantial amount of carbon monoxide, wherein combustion of carbon monoxide occurs in the transition zone wherein a substantial amount of the heat of carbon monoxide combustion is absorbed by entrained catalyst in the transition zone, and wherein a major portion of such absorbed heat is transferred to the fluidized dense phase catalyst bed with disengage dcatalyst returning thereto under the influence of gravity.
7. A method as claimed in any preceding claim, wherein primary and secondary regeneration gas flow rates are adjusted within their respective ranges for providing sufficient oxygen for substantially complete combustion of carbon monoxide.
8. A method as claimed in any preceding claim, wherein carbon monoxide content of the flue gas is 500 ppm or less.
9. A method as claimed in any preceding claim, wherein residual carbon on regenerated catalyst is 0.05 weight percent or less.
10. A fluidized catalytic cracking process as claimed in Claim 1 and substantially as hereinbefore described with reference to the accompanying drawings.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB4656777A GB1569467A (en) | 1977-11-09 | 1977-11-09 | Fluidized catalytic cracking regeneration process |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB4656777A GB1569467A (en) | 1977-11-09 | 1977-11-09 | Fluidized catalytic cracking regeneration process |
Publications (1)
Publication Number | Publication Date |
---|---|
GB1569467A true GB1569467A (en) | 1980-06-18 |
Family
ID=10441757
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
GB4656777A Expired GB1569467A (en) | 1977-11-09 | 1977-11-09 | Fluidized catalytic cracking regeneration process |
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Country | Link |
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GB (1) | GB1569467A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0092065A1 (en) * | 1982-04-19 | 1983-10-26 | Ashland Oil, Inc. | Regeneration of catalyst used in the conversion of carbo-metallic containing residual oils |
EP0092059A1 (en) * | 1982-04-19 | 1983-10-26 | Ashland Oil, Inc. | Regeneration of catalyst used in the conversion of carbo-metallic containing residual oils |
-
1977
- 1977-11-09 GB GB4656777A patent/GB1569467A/en not_active Expired
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP0092065A1 (en) * | 1982-04-19 | 1983-10-26 | Ashland Oil, Inc. | Regeneration of catalyst used in the conversion of carbo-metallic containing residual oils |
EP0092059A1 (en) * | 1982-04-19 | 1983-10-26 | Ashland Oil, Inc. | Regeneration of catalyst used in the conversion of carbo-metallic containing residual oils |
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Legal Events
Date | Code | Title | Description |
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PS | Patent sealed | ||
PCNP | Patent ceased through non-payment of renewal fee |
Effective date: 19961109 |