RU2411284C2 - Device and method for catalyst regeneration - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to a device (50) for realising a method of burning carbonaceous deposits on a catalyst which has a bottom chamber (54), having a base (63) and lateral walls (55), where the bottom chamber has a first gas distributing device for combustion (66) in the bottom chamber and a second gas distributing device for combustion (74); projecting from the side across the bottom chamber, higher than the first distribution device for combustion, a catalyst input (62) into the bottom chamber between the first gas distributing device for combustion and the second gad distributing device for combustion; where the point of intersection (B) of the base and side walls defines the first cross sectional area; a top chamber (100) having separators (98, 99) for separating the catalyst from flue gases, connected to the said bottom chamber, an outlet (12) for the regenerated catalyst and an output for flue gases (110), a gas distributing device (108) and a recirculating pipe (82) which connects the top chamber with the bottom chamber; a catalyst input tray (86) for the said recirculation pipe between the first distribution device for combustion (66) and a second distribution device for combustion (74); a transition section (90) in form of a flattened cone, where the second gas distributing gas for combustion (74) lies nearer the catalyst input tray (62) of the bottom chamber than the said transition section and a riser section (94) elongated upwards from the bottom chamber, where the riser has a second cross sectional area which is less than the first cross sectional area. The invention also relates to a method for combustion of carbonaceous deposits on a catalyst.

EFFECT: complete catalyst regeneration, high output of gas for combustion.

9 cl, 2 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a method for regenerating a spent hydrocarbon conversion catalyst by burning coke on a catalyst in a fluidized combustion zone. Specifically, this invention relates to a method for converting heavy hydrocarbons into lighter hydrocarbons using a fluidized stream of catalyst particles and regenerating the catalyst particles to remove coke, which has a deactivating effect on the catalyst.

Fluidized catalytic cracking (FCC) is a hydrocarbon conversion process carried out by contacting hydrocarbons in a fluidized reaction zone with a catalyst consisting of finely dispersed granular material. Unlike hydrocracking, the catalytic cracking process is carried out without adding hydrogen or without consuming hydrogen. During the cracking process, significant amounts of a high-carbon material called coke are deposited on the catalyst. During the operation of high-temperature regeneration in the regeneration zone, coke is burned from the catalyst. The coke-containing catalyst, which is called spent catalyst in this invention, is continuously removed from the reaction zone and replaced by the catalyst from the regeneration zone, which is substantially free of coke. Fluidization of the catalyst particles by means of various gaseous streams allows the transport of catalyst between the reaction zone and the regeneration zone. Methods for cracking hydrocarbons in a fluidized catalyst stream, transporting a catalyst between a reaction zone and a regeneration zone, and burning coke in a regenerator are well known to those skilled in the art of PCC processes. To this end, the prior art is saturated with descriptions of the configuration of apparatuses for contacting the catalyst particles with the feed and the corresponding regeneration gas.

The common goal of these configurations is to obtain maximum product yield in the reactor, while minimizing operating costs and equipment costs. Usually, almost complete removal of coke from the catalyst is required to optimize the degree of conversion of the feed. This near-complete removal of coke from the catalyst is often called complete regeneration. With complete regeneration, a catalyst is obtained containing less than 0.1% and preferably less than 0.05 wt.% Coke. In order to achieve complete regeneration, the catalyst must be in contact with oxygen for a sufficient time to ensure exhaustive combustion of coke.

State of the art

Typically, traditional regenerators are apparatuses that include an inlet for spent catalyst, an outlet for regenerated catalyst, and a distribution device for supplying air to a dense catalyst bed located in the apparatus. Cyclone separators remove the catalyst entrained with the exhaust flue gas until the gas exits the regenerator apparatus. US Pat. No. 4,610,851 describes a regenerator apparatus with two air distribution devices at different levels, in order to provide an appropriate distribution of combustion gas throughout the apparatus. US Pat. No. 5,282,793 recommends at least two switchgears at various levels in the lower half of the dense catalyst bed to maintain reconditioning conditions in the dense layer. In US patent No. 4843051 shows two air distribution grilles at different levels of the regeneration apparatus in order to ensure appropriate combustion. US Pat. No. 5,773,378 recommends a regenerator apparatus with a lower air distribution device, with air flowing above the lower air distribution device with spent catalyst.

In a dense catalyst bed, which is also known as a fluidized bed, flue gases form bubbles that rise through the distinguishable upper surface of the dense catalyst bed. A relatively small portion of the catalyst is carried away by flue gases leaving the dense layer. The surface flue gas velocity is usually less than 0.3 m / s (1.0 ft / s), and the density of the dense layer is usually greater than 640 kg / m ³ (40 lb / ft ³ ), depending on the characteristics of the catalyst . The mixture of catalyst and flue gas is heterogeneous with penetrating gas flowing around the catalyst particles.

One way to obtain a fully regenerated catalyst is the phased implementation of regeneration. US Pat. No. 3,958,953 describes a phased flow system comprising concentric catalyst layers separated by baffles that open into a joint space for collecting exhaust gas from regeneration and separating catalyst particles. US Pat. No. 4,299,687 recommends the use of a stepwise regeneration system having combined catalyst beds in which spent catalyst particles first enter the upper dense fluidized catalyst bed and are contacted with a regeneration gas from the lower catalyst layer and with fresh regeneration gas. After partial regeneration in the first regeneration zone, the stream of catalyst particles is transferred under the action of gravity to the lower catalyst layer, into which the stream of fresh regeneration gas enters. US Pat. Nos. 4,695,370 and 4,664,778 describe two phased regenerators in which each stage is carried out in a separate apparatus.

The use of relatively dilute phases in the regeneration zone for complete catalyst regeneration is shown in US Pat. Nos. 4,430,201, 3,844,973 and 3,923,686. These patents recommend a lower dense layer in which combustion gas is distributed and an upper transport zone. Additional air is distributed in the riser, providing a transport zone. US Pat. Nos. 5,158,919 and 4,272,402 show a two-stage system in which a transport zone with respect to a dilute phase is combined without a lower zone of a dense layer for catalyst regeneration. In all these patents, an upper dense layer is proposed in which at least partially regenerated catalyst exiting the transport zone is collected.

Diluted or transport flow regimes are typically used in FCC reactors with an ascending catalyst bed. In the transport stream, the difference in gas and catalyst velocities is relatively small, with a small amount of catalyst being returned or retained in the apparatus. For the catalyst, flow conditions with a low density and a very dilute phase are maintained in the reaction zone. In traffic, the surface gas velocity is usually greater than 2.1 m / s (7.0 ft / s), and the density of the catalyst is usually not greater than 48 kg / m ³ (3 lb / ft ³ ). The density in the transport zone of the regenerator can reach up to 80 kg / m ³ (5 lb / ft ³ ). In the transport mode, the mixture of the catalyst with flue gases is homogeneous, without gas voids or bubbles formed in the catalyst phase.

The intermediate between the dense, fluidized bed and the regime of the diluted transport stream are the turbulent layers and the fast fluidization mode. In the turbulent layer, the mixture of catalyst and flue gas is not uniform. The turbulent layer is a dense catalyst layer with elongated flue gas voids formed inside the catalyst phase, with a less distinguishable surface. The entrained particles of the catalyst leave the bed with the flue gases, and the density of the catalyst is not entirely proportional to the lift height inside the reactor. In a turbulent layer, the surface flue gas velocity is between 0.3 and 1.1 m / s (1.0 and 3.5 ft / s), and a typical catalyst density is between 320 and 640 kg / m ³ (20 and 40 lb / ft ³ ).

Rapid fluidization means the state of fluidized solid particles between the turbulent layer of particles and the regime of complete particle transport. The fast fluidization mode is characterized by an increased velocity of the fluidizing gas in comparison with the velocity of the turbulent layer of the dense phase, which leads to a reduced density of the catalyst and intensive contact of solid particles with the gas. In the fast fluidization zone, there is a total catalyst transport caused by an upward flow of fluidizing gas. Under conditions of rapid fluidization, the density of the catalyst is much more sensitive to particle loading than in the full particle transport mode. Therefore, it is possible to adjust the residence time of the catalyst particles in such a way as to achieve the desired degree of combustion (coke) under conditions of highly efficient mixing of gas and solid particles. In the fast fluidization mode, an additional increase in the velocity of the fluidizing gas will increase the transport velocity of the ascending particles, and the average density of the catalyst will decrease sharply, while, at the corresponding gas velocity, the particles move mainly in the mode of complete transport of the catalyst. Thus, there is a continuous transition from the state of a layer of fluidized particles, through rapid fluidization, to a purely transport mode. The surface flue gas velocity in the fast fluidized flow mode is usually between 1.1 and 2.1 m / s (3.5 and 7 ft / s), and the density is usually between 48 and 320 kg / m ³ (3 and 20 lb / ft ³ ).

U.S. Patent Nos. 4,849,091, 4,197,189, and 4,336,160 propose an upstream combustion zone in which rapid fluidization conditions are maintained. The last of these patents describes a regeneration apparatus with a furnace, in which complete combustion occurs in the zone of rapid fluidization of the riser, without the need to add combustion gas to the layer collected on top of the riser.

The combustion chamber is a type of regenerator in which the catalyst is completely regenerated in the lower combustion chamber under conditions of rapid fluidization of the flow with a relatively small amount of excess oxygen. The regenerated catalyst and exhaust flue gases are transferred in a riser to the separation chamber, in which significant combustion takes place. The regenerated catalyst from the separation chamber is recycled to the lower phase of combustion in order to heat the spent catalyst before starting the combustion process. Recirculation of the regenerated catalyst provides heat for accelerated combustion of the lower phase of the catalyst. The combustion chambers are advantageous due to their high oxygen consumption efficiency.

Since the FCC installations are in high demand, combustion devices are required that can process the catalyst with a higher throughput. Large amounts of combustion gas are added to the combustion apparatuses to burn large amounts of catalyst. When the flow rate of the combustion gas increases, the flow rate of the catalyst between the combustion chamber and the separation chamber also increases. Therefore, if the combustion chamber of the apparatus for combustion is not increased, the residence time of the catalyst in the lower zone will decrease, and thus, the degree of combustion, which must be achieved before the catalyst enters the separation chamber, will decrease.

SUMMARY OF THE INVENTION

The present invention relates to a device for removing carbon deposits, called coke, from the surface and pores of a catalyst used in hydrocarbon conversion processes. The combination of turbulent bed conditions and rapid fluidization in the regeneration apparatus provides an appropriate residence time for the regeneration of the spent hydrocarbon cracking catalyst. Hybrid conditions are used in the combustion chamber to completely regenerate the catalyst. A dense layer of fully regenerated catalyst is collected in a separation chamber. The present invention can be used to increase the productivity of the combustion gas in order to provide a correspondingly increased productivity of the catalyst, while maintaining contact of the combustion gas with the catalyst for a sufficient residence time.

Brief Description of the Drawings

The figure 1 shows a schematic view in vertical section of the installation of the FCC, including the present invention.

2 is a schematic vertical sectional view of an alternative embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The method and device of the present invention can be implemented in the installation of the FCC. The figure 1 shows the installation of the FCC, which includes the apparatus of the reactor 10 and the apparatus for combustion 50. The pressure pipe 12 transfers the catalyst from the apparatus for combustion 50 with a speed that is controlled by a valve 14, into the apparatus of the reactor 10. Fluidizing medium, such as water vapor from the nozzle 16 transports the catalyst upstream of the riser 18 at a relatively high density while a plurality of feed nozzles 20 (only one is shown) inject the feed across the stream of catalyst particles. The resulting mixture continues to move up the riser 18, while a pair of disconnecting brackets 22 tangentially releases a mixture of gas and catalyst on top of the riser 18 through passages 24 into the separation zone 26, in which the separation of gases from the catalyst. Transport line 28 transfers hydrocarbon vapors, including stripped hydrocarbons, stripping medium and entrained catalyst, to one or more cyclones 30 in a separator tank 32, in which spent catalyst is separated from the hydrocarbon vapor stream. The collection chamber 34 in the reservoir of the separator 32 collects a stream of separated hydrocarbon vapors from the cyclones 30 for passage to the exhaust nozzle 36 and finally to the extraction zone by fractionation (not shown). In the immersion struts 38, the catalyst from the cyclones 30 is discharged into the lower part of the separator tank 32, from which the catalyst and adsorbed or entrained hydrocarbons finally pass to the stripping section 40 through the passages 42 made in the wall of the separation tank 26, The catalyst separated in the separation tank 26 passes directly to stripping section 40. This stripping section 40 includes baffles 43, 44 to facilitate mixing of the stripping gas and catalyst. The stripping gas enters the lower part of the stripping section 40 through at least one inlet 46 into one or more distribution devices (not shown). The spent catalyst leaves the stripping section 40 through the reactor pipe 48 and passes into the combustion apparatus 50 at a speed controlled by a valve 52.

The combustion apparatus 50 utilizes a hybrid mode of turbulent bed and rapid fluidization in a highly efficient combustion chamber 54 to completely regenerate spent catalyst. The combustion chamber 54 of the combustion apparatus 50 includes three combustion zones: a turbulent zone 56, a quick fluidization zone 58 and a transport zone 60. The reactor pipe 48 feeds the spent catalyst into the combustion chamber 54 through the spent catalyst inlet 62 at the entry point “A” . The elliptical base 63 of the combustion chamber 54 defines a cross-sectional area in the line of intersection "B" with the side wall 55 of the combustion chamber 54 below the inlet tray 62 of the spent catalyst. Typically, spent catalyst from the reactor tank 10 contains carbon in an amount of 0.2 to 2 wt.%, Which is present in the form of coke. Although coke mainly consists of carbon, it can contain from 3 to 12 wt.% Hydrogen, as well as sulfur and other materials. Oxygen-containing combustion gas, usually air, enters the combustion chamber 54 of the combustion apparatus 50 at two levels. The first flow of combustion gas enters the combustion chamber 54 at a low level through the lower conduit 64 and is distributed across the turbulent zone 56 using the lower distribution device 66. The openings 68 in the lower distribution device 66 discharge the combustion gas in a vertical projection that is lower than the entry point “A” of the spent catalyst into the combustion chamber 54. When the combustion gas enters the combustion zone, it contacts the spent catalyst, which accumulates in the turbulent catalysis layer 70 ora in the turbulent zone 56. Combustion gas is distributed from the lower switchgear 66, providing a surface gas velocity of less than 1.1 m / s (3.5 ft / s), which is insufficient to destroy the turbulent catalyst layer 70 in the turbulent zone 56. In other words, the gas velocity from the lower switchgear 66 will not be sufficient to entrain the catalyst and remove the catalyst from the bed, thus maintaining the catalyst bed 70. In the turbulent zone 56, the density of the catalyst is from 320 to 640 kg / m ³ (20-40 lb / ft ³ ).

The second flow of combustion gas enters the quick fluidization zone 58 of the combustion chamber 54 through the upper conduit 72 and is distributed throughout the combustion chamber 54 by the upper distribution device 74. The openings 76 in the upper distribution device 74 discharge the combustion gas in a vertical projection, which is higher, than the point "A" of the input of the spent catalyst into the combustion apparatus 50, through the input tray 62 for the spent catalyst, and higher than the point of entry of the first flow of combustion gas through the lower distribution construction 66. Therefore, in this embodiment, the entry point “A” is vertically between the upper distribution device 74 and the lower distribution device 66. In another embodiment, less combustion gas is distributed through the upper distribution device 74 in the quick fluidization zone 58 of the combustion chamber 54 than through the lower distribution device 66. However, when the flow rate of the combustion gas from the lower distribution device 66 is added to the flow rate of the combustion gas from the top of switchgear 74, the total surface velocity of the combustion gas in the combustion chamber 54 reaches at least 1.1 m / s (3.5 ft / s), entering the fast fluidization zone 58 in the fast fluidization flow mode. In one embodiment, in the rapid fluidization zone 58, the density of the catalyst may be from 48 to 320 kg / m ³ (from 3 to 20 lb / ft ³ ), and the surface velocity of the gases from 1.1 to 2.2 m / s (from 3.5 to 7 ft / s). Above the openings 76, a gradual transition from the turbulence zone 56 to the fast fluidization zone 58 is provided. In the fast fluidization zone 58, the density of the catalyst will decrease in proportion to the height.

The transition from the turbulent layer to the fluidized flow mode is not displayed by a distinguishable surface layer. Therefore, the set of decreasing values of the density of the catalyst can extend from the turbulent layer 70 upwards of the combustion chamber 54. The rate of decrease in the density of the catalyst along the height of the combustion chamber 54 will decrease in proportion to the speed at which the catalyst enters the combustion chamber 54.

In an embodiment, in order to accelerate coke combustion in the combustion chamber 54, the hot regenerated catalyst from the dense catalyst bed 78 in the upper chamber 80 can be recycled to the combustion chamber 54 via an expanded recycle discharge pipe 82 controlled by a control valve 84. The hot regenerated catalyst enters the combustion chamber 54 through the input tray 86. Recirculation of the regenerated catalyst by mixing the catalyst from the dense catalyst layer 78 with a relatively cold spent to catalyst was of the reactor conduit 48 entering the combustion chamber 54, raises the overall temperature of the catalyst and gas mixture in a turbulent zone 56. Except for the use of a pressure pipe 82 extended recycle some other ways of recycling catalyst can be used. For example, the catalyst may be moved inside the apparatus using an internal pressure pipe (not shown). The loading height of the catalyst particles in the combustion chamber 54 can be adjusted by increasing the rate of the recirculated catalyst stream through the control valve 84, without affecting the flow rate of the spent catalyst through the valve 52. The regenerated catalyst can enter through the input tray 86 at the same level as the entry point " A "spent catalyst through the input tray 62 of spent catalyst. However, in an embodiment, the regenerated catalyst enters the combustion chamber 54 between the lower distribution device 66 and the upper distribution device 74 in order to be able to more intensively heat exchange in the turbulent layer 70.

By distributing the combustion gas at two levels, above and below the catalyst entry point “A”, more combustion gas can be added to the catalyst in the combustion chamber 54, without immediately fulfilling the conditions for rapid fluidization of the flow in the combustion chamber 54 and disruption of the turbulent layer 70. Therefore, the transition between the turbulent zone 56 and the rapid fluidization zone 58 can extend almost to the upper switchgear 74 or above this device 74. The spent catalyst is in contact with the combustion gas for a longer residence time in the combustion chamber 54. Moreover, if all of the gas introduced into the combustion proceeds beyond the point "A" of spent catalyst, most of the spent catalyst in the turbulent layer 70 will be subjected to fluidization only after a long delay and congestion.

The mixture of catalyst and gas in the quick fluidization zone 58 rises through the transition section 90 in the form of a truncated cone into the transport zone 60 in the riser section 94 of the combustion chamber 54, which is operated at a higher surface gas velocity than in the quick fluidization zone 58 or in the turbulent zone 56, below the transition section 90. The increased gas velocity is due to a decrease in the cross-sectional area of the riser section 94 compared with the cross-sectional area of the combustion chamber 54, below the transition section 90. Cross-sectional area Nia riser section 94 is smaller than the cross sectional area of the combustion chamber 54 below the input tray 62 to the spent catalyst at the intersection point "B" in order to provide increased surface velocity. Therefore, the surface gas velocity will typically exceed 2.2 m / s (7 ft / s). In transport zone 60, the catalyst will have a density of less than 80 kg / m ³ (5 lb / ft ³ ).

In addition, the combustion apparatus 50 includes an upstream separation chamber 100. A mixture of catalyst particles and combustion gas, which is exhausted due to oxygen consumption, is ejected from the top of the riser section 94 in the separation chamber 100. A substantially completely regenerated catalyst exits at the top of the transport zone 60. The release is through a disconnecting device 96, in which most of the regenerated catalyst is separated from the regeneration exhaust gas. The initial separation of the catalyst at the outlet of the riser section 94 minimizes the load of the catalyst on the cyclone separators 98, 99 or other subsequent devices used to almost completely remove catalyst particles from the regeneration exhaust gas, and thus reduce the total cost of equipment. Various flow-through devices known to those skilled in the art can pre-separate the catalyst and gas, which can be conveniently used as a disconnecting device 96. In an embodiment, the catalyst and gas flowing to the top of the riser section 94 acts on the upper elliptical cover 61 sections of the riser 94, and the flow is drawn. The catalyst and gas then exit through obliquely directed openings in the side brackets 97 of the disconnecting device 96. A sudden loss of momentum and a return flow down cause at least 70% and preferably 80% by weight of the heavier catalyst to fall into the denser catalyst layer 78. and a lighter gas for combustion and a smaller part of the catalyst, still carried away with the flow, rises up into the freed space 102 of the separation chamber 100.

Particles of the released catalyst falling downward are collected in the dense catalyst bed 78. The density of the catalyst in the dense catalyst layer 78 is usually maintained in the range of 640 to 960 kg / m ³ (40-60 lb / ft ³ ). The fluidizing conduit 106 delivers fluidizing gas, typically air, to the dense catalyst bed 78 through the fluidizing distributor 108. Approximately no more than 2% of the total amount of gas needed for the process enters the dense catalyst bed 78 through the fluidizing distributor 108. Here, gas is added not for the purpose of combustion, but only for the purpose of fluidization so that the catalyst can smoothly exit through the pressure pipes 82 and 12. The fluidizing gas added through the fluidizing fluid predelitelnoe device 108 may be a flue gas.

The combination of combustion gas, fluidizing gas and entrained catalyst particles enters one or more separation devices, such as cyclone separators 98, 99, in which the catalyst dust is separated from the gas. Exhaust flue gases, relatively free of catalyst, are discharged from the combustion apparatus 50 through the exhaust pipe 110, while the recovered catalyst is returned to the dense catalyst bed 78 through the respective immersion struts 112, 113 or other similar means. In gases above the exit from transport zone 60, from 10 to 30 wt.% Of the catalyst exiting the combustion chamber 54 is present, and the gas enters the cyclone separators 98, 99. The catalyst is transferred from the dense catalyst bed 78 to the pressure pipe 12 of the combustion apparatus back to the reservoir of the reactor 10, where it again comes into contact with the feed when the FCC process continues.

In the combustion chamber 54, regions of reduced catalyst density and long periods of intensive mixing are provided, which are considered to be the most effective for coke combustion and characterize high regeneration efficiency. Therefore, the addition of combustion gas under conditions conducive to high regeneration efficiency is sufficient to remove all coke from the spent catalyst entering the combustion chamber 54. The combustion gas can be supplied to the pipes 64, 72 and 106 along the same line, however, in In an embodiment, the feed rate to the lower conduit 64 should be higher than to the upper conduit 72.

Thus, the FCC reaction zone, in connection with the present invention, can be used in a process with a conventional FCC feedstock or with a high boiling hydrocarbon feedstock. This most common traditional feed is vacuum gas oil (VGO), which is usually a hydrocarbon material having a boiling range of 343 ° to 552 ° C (650 ° -1025 ° F) and obtained by vacuum fractionation of the residue of atmospheric distillation. Typically, such a fraction contains few coke precursors and heavy metal impurities that can contaminate the catalyst. Heavy hydrocarbon feeds that can be used in the present invention include heavy crude oil residues, heavy bituminous crude oil, shale oil, tar sand extract, deasphalted residue, coal liquefied products, stripped atmospheric and vacuum distillation oils. In addition, the types of heavy feedstocks for the present invention include mixtures of the above hydrocarbons. However, the above list is not intended to exclude other suitable types of raw materials for use in this method. In addition, fractions of heavy hydrocarbons are characterized by the presence of a significant amount of polluting metals. These metals accumulate on the catalyst and poison the catalyst by blocking the active sites and contribute to excessively deep cracking, and thus interfere with the reaction process. Therefore, when processing heavy raw materials using the present invention, the use of passivation or other methods of passivation of metals in the reaction zone itself or before it is allowed.

Therefore, one advantage of the present invention is that it provides for the regeneration of increased amounts of spent catalyst by treating it with a proportionally large amount of combustion gas without blowing the catalyst out of the regeneration zone until regeneration is completed. Regarding the need for oxygen or air, typically the combustion apparatus of the present invention requires 14 kg of air per 1 kg of coke to be removed in order to obtain complete regeneration. When a larger amount of catalyst is regenerated, a larger amount of raw material can be processed in a conventional process apparatus.

Another embodiment of the invention is shown in figure 2, which shows a slightly modified apparatus for combustion 50 '. The position numbers of similar elements in FIG. 2 are denoted in the same manner as in FIG. 1, but differ by a dash symbol ('). Similar elements in both figures 1 and 2 will be indicated by the same positions. The combustion apparatus 50 'has a lower mixing riser 120 for combining spent catalyst, regenerated catalyst and regeneration gas. The hot regenerated catalyst transported down the elongated pressure pipe 82 'meets the spent catalyst entering the lower mixing riser 120 through the reactor conduit 48'. The spent and regenerated catalysts are in contact with at least part of the first stream of oxygen-containing gas for combustion from the lower pipe 64 'in the lower part of the lower mixing riser 120. The base 63' of the combustion chamber 54 ', having the shape of a truncated cone, determines the cross-sectional area at the point the intersection "B" 'with the side wall 55' of the combustion chamber 54 ', below the holes 68', where the catalyst enters the combustion chamber 54 'at the entry point "A"'. The cross-sectional area of the riser section 94 'is smaller than the cross-sectional area of the combustion chamber 54', below the openings 68 ', to provide an increased surface velocity through the riser section 94'. In addition, the lower mixing riser 120 has a cross-sectional area smaller than the cross-sectional area of the combustion chamber 54 'below the openings 68' in order to facilitate good mixing of the catalyst particles and the gas stream. In addition, the lower mixing riser 120 has a cross-sectional area that is less than the cross-sectional area of the riser section 94 '. After mixing, the catalyst and the gas mixture enter the turbulence zone 56 ′ of the combustion chamber 54 ′ through the openings 68 ′ in the lower switchgear 66 ′. The gas flow rate for combustion from the lower conduit 64 'is insufficient to create a surface velocity in the combustion chamber 54', which could provide a fast fluidization mode. Therefore, in the turbulent zone 56 ′ of the combustion chamber 54 ′, a turbulent layer 70 ′ is provided. Additional combustion gas from the upper conduit 72 'is added using the upper distribution device 74', which, in combination with the combustion gas from the lower distribution device 66 ', creates conditions for rapid fluidization of the flow in the quick fluidization zone 58'. The catalyst and combustion gas rising into the transport zone 60 'exit through a disconnecting device 96' into the separation chamber 100 'in order to separate the catalyst falling into the dense catalyst layer 78' from the upstream flue gas stream. Exhaust flue gases rise into cyclone separators 98 ', 99', which separate the additional entrained catalyst, and exit through conduit 110 '. The fluidizing conduit 106 'delivers gas, which may be flue gas, to the dense catalyst bed 78' through a fluidizing dispenser 108 'to fluidize the catalyst in the dense catalyst bed 78'. A portion of the regenerated catalyst can be returned to the combustion chamber 54 ′ through an elongated pressure head pipe 82 ′ for recirculation and a lower mixing riser 120 to heat spent catalyst in the turbulent bed 70 ′, and the remaining part of the regenerated catalyst is returned to the reactor apparatus 10 in FIG. 1 through the pressure pipe 12 'incinerator to contact with fresh raw materials. All other aspects of the combustion apparatus 50 'with the lower mixing riser 120 are similar to the combustion apparatus 50 of FIG. 1. The operation of the mixing riser is described in more detail in US patent No. 4340566, which is incorporated into this invention by reference.

In figures 1 and 2 shows the regeneration zone of a symmetrical configuration with separation chambers 100, 100 'located above in the combustion chambers 54, 54'. However, the turbulence zones 56, 56 ′, the quick fluidization zones 58, 58 ′ and the transport zones 60, 60 ′ may be located in a separate combustion apparatus or located near a reservoir containing separation chambers 100, 100 ′. In this embodiment, the catalyst is transferred from the combustion apparatus to the separator reservoir using a pipeline. Thus, the application of the present invention is not limited to the symmetric configuration of the regenerator, but may be a modified dense-layer regenerator apparatus.

Claims (9)

1. The device (50) for implementing the method of burning carbon deposits on the catalyst, which includes:
a lower chamber (54) having a base (63) and side walls (55), the lower chamber including a first combustion gas distribution device (66) in the lower chamber and a second combustion gas distribution device (74) protruding laterally across the lower chamber above the first combustion switchgear, introducing a catalyst (62) into said lower chamber between the first combustion gas distributor and the second combustion gas distributor, wherein the intersection point (B) of the base and side walls of the edelyaet first cross-sectional area;
an upper chamber (100) connected to said lower chamber, said upper chamber including separators (98, 99) for separating the catalyst from the flue gases, a regenerated catalyst outlet (12) and a flue gas outlet (110), a gas distribution device (108) ) and a recirculation pipe (82) connecting the upper chamber to the lower chamber, an inlet tray (86) of the catalyst of said recirculation pipe between the first combustion switchgear (66) and the second combustion switchgear (74);
transition section (90) in the form of a truncated cone, and the second gas distribution device for combustion (74) is located closer to the input tray (62) of the catalyst of the lower chamber than to the specified transition section, and
a section of the riser (94), elongated upward from the lower chamber, and the riser has a second cross-sectional area that is less than the first cross-sectional area. 2. The device according to claim 1, in which at the top of the riser there is a device (96) for the initial separation of the catalyst from flue gases. 3. The device according to claim 1 or 2, in which the catalyst and the combustion gas are mixed together and distributed in the lower chamber using the distribution device (66 ') of the first combustion gas. 4. The device according to claim 1 or 2, in which the gas distribution device (108) is located in the upper chamber. 5. The method of burning carbon deposits on the catalyst, carried out in the device according to claim 1, which includes:
introducing spent catalyst into the lower chamber (54) through the input (62) of spent catalyst;
distribution of the combustion gas in the lower chamber below the input of the spent catalyst at a rate at which the catalyst bed is maintained;
the distribution of the combustion gas in the lower chamber is higher than the input of the spent catalyst with a speed to such an extent that when the combustion gas is distributed below the input of the spent catalyst, it will entrain the catalyst with the combustion gas, more gas being distributed below the input of the spent catalyst catalyst, the higher the input of spent catalyst;
raising the catalyst entrained with the combustion gas to the exit (96) from said lower chamber to the upper chamber (100);
the allocation of the catalyst from these flue gases;
collecting the catalyst in the layer (78) in the upper chamber (100);
removal of catalyst from the upper chamber and extraction of flue gases from the upper chamber. 6. The method according to claim 5, in which the combustion gas is distributed in the first chamber below the input of the spent catalyst in order to provide a surface velocity of less than 1.1 m / s; and combustion gas is distributed in the first chamber above the input of the spent catalyst in order to provide a surface velocity of at least 1.1 m / s when combined with the combustion gas distributed below the input of the spent catalyst. 7. The method according to claim 5 or 6, in which the catalyst recycles from the upper chamber to the lower chamber. 8. The method according to claim 5 or 6, in which the entrained catalyst and combustion gas exit the lower chamber through the riser (94). 9. The method according to claim 5 or 6, in which the catalyst accumulates in the second layer (78) in the upper chamber.

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