CN1158136C

CN1158136C - Method and equipment for making reaction agent and discontinuous moving catalyst bed contact

Info

Publication number: CN1158136C
Application number: CNB991108981A
Authority: CN
Inventors: R・C・穆尔瓦尼; R·C·穆尔瓦尼; 布兰德尼; K·J·布兰德尼; 阿拉卡瓦; S·T·阿拉卡瓦; 卵; P·安德逊
Original assignee: Universal Oil Products Co
Current assignee: Honeywell UOP LLC; Universal Oil Products Co
Priority date: 1999-06-10
Filing date: 1999-06-10
Publication date: 2004-07-21
Anticipated expiration: 2019-06-10
Also published as: CN1277073A

Abstract

The present invention relates to a method and a device which are used for contacting reactant and granular catalysts; meanwhile, the reactant and the granular catalysts indirectly contact a heat exchange medium; through programming operation for limiting the flow rate of the reactant, the granular catalysts are discontinuously discharged and supplemented; meanwhile, the catalysts pass through a reaction cell in which the flow rate of the reactant is limited. In the process of operation, the method allows the exchange of the catalysts in a channel type reactor device; during operation, the method always limits the flow rate of the catalysts and allows that the catalysts move to pass through a heat exchange type reactor provided with a reactant channel and a heat exchange channel, and thus, the method can control the activity and the reaction temperature of the catalysts.

Description

Make reactant and the discontinuous moving catalyst bed method and apparatus that contacts

Invention field

Thereby the present invention relates to be used for reacting fluid catalyzed conversion make-up catalyst and carry out the chemical reactor that reaction temperature and catalyst activity are controlled in heat exchange simultaneously indirectly meanwhile with a kind of heat-exchange fluid.

Background technology

In petro chemical industry, many methods are used reactor, and in reactor, under given temperature and pressure condition, each component of one or more reacting fluid contacts with catalyst, finishes chemical reaction.Many reactions in these reactions produce to some extent or absorb heat, thus heat release or heat absorption.The heating or the cooling effect that interrelate with the heat release or the endothermic reaction can produce favourable or adverse influence to the operation of reaction zone.Adverse influence may include: the generation of product inferior, and the inactivation of catalyst, unwanted production of by-products and under opposite extreme situations is damaged reactor and relevant pipe fitting.More typically be that the undesirable influence relevant with variation of temperature will reduce reaction zone product selectivity or productive rate.

A solution of these problems is, in reaction zone, with a kind of heat or cold medium indirect reactant and/or catalyst.Well-known such catalytic reactor is the tubular device with fixing or moving catalyst bed.The geometry of tubular reactor causes the design limitations of big reactor of needs or limit production ability.

Indirect heat exchange also can be utilized thin plate to constitute channels interleaved and realize, it can remain on catalyst and reactant in the one cover passage, and a kind of heat-transfer fluid that is used for indirect or cooling reactant and catalyst is retained in channels interleaved.Heat exchanger plates in these indirect heat exchange reactors can be dull and stereotyped or crooked plate, and its surface can be different shapes, and corrugated for example is to increase the heat transfer between heat-transfer fluid and reactant and the catalyst.Though thin heat transfer plate can compensate to a certain extent because the caused variation of temperature of reaction heat, but not every indirect heat transfer device can both provide the temperature completely that is beneficial to many technical process control by safeguarding that in the entire reaction district temperature desired distributes.Many hydrocarbon conversion process processes are by keeping will more helping operation with the thermogenetic different Temperature Distribution of reaction.In many reactions, the isothermy by substantially obtains best Temperature Distribution.In some cases, relevant with the reaction heat just in time opposite Temperature Distribution of variations in temperature will provide best condition.An example of this situation is in dehydrogenation reaction, by Temperature Distribution in the raising reaction zone or by setting up reverse thermograde, can improve endothermic reaction process selectivity and conversion ratio.Provide the concrete device that is used for conducting heat of control more fully to be disclosed in US-A-5525311 with reactant channels.

The many catalyst that are used for hydrocarbon reaction are easy to inactivation after use a period of time.Usually owing to cause the sedimental accumulation of inactivation, the active hole site on blocking catalyst surface or catalytic activity position take place inactivation.If the sedimental accumulation of coking causes inactivation, then regenerated catalyst can recover activity of such catalysts to remove the coking deposit.In regenerative process, at high temperature, contact with oxygen-containing gas by making the catalyst that contains coking, burn or remove coking and generally can remove coking from catalyst.Regenerative process can be carried out at the scene, or takes out catalyst from carry out reactor that hydrocarbon transforms, transfers to independent being used for then and removes the renewing zone of coking and carry out.From the bed of reaction zone continuously or semi-continuously to discharge catalyst granules so that remove out the device of coking in the renewing zone be well-known.US-A-3652231 discloses a kind of continuous Catalyst-regenerating process that uses with the catalytic reforming of hydro carbons.In reaction zone, this catalyst is under the gravity effect, by discharging catalyst and catalyst is added to the transfer process that catalyst is finished at the top from the reaction zone bottom.

The phenomenon that is called as " obstruction " has suppressed the conveying of catalyst in many reactor assemblies." obstruction " phenomenon is the phenomenon that stops catalyst to move down with the reacting gas that enough big speed flows." obstruction " phenomenon is the gas velocity and the function of the physical characteristic of flowing gas reactant and the contacted flow channel of catalyst wherein.When gas flow through the passage that catalyst is housed, gas collided catalyst granules and has increased intergranular friction.When the vertical stress component of the frictional force of intergranular during greater than the weight of particle, these particles will be blocked.Along with the length of gas by the flow path of catalyst granules becomes longer, the power that acts on the particle little by little increases from the inlet that exports to of flow channel.In addition, along with the flow channel of catalyst becomes narrower, the gravity flow of catalyst granules is subjected to more obstruction.Correspondingly, because the size of flow channel becomes littler, the resistance that wall puts on the vertical direction of catalyst granules increases gradually.Therefore, easier causing of narrow flow channel stops up, and generally can not provide continuous catalyst circulation.

For the reactor with indirect heat exchange, the arrangement of reactor can make the catalyst blockage problem even more serious.Increase the number of flow channel by the size that reduces flow channel, owing to increase the surface area between heat-exchange fluid and the catalyst, and help conducting heat.Moreover, but can further promote heat transfer by the plate face irregularity that improves turbulization and can reduce the film factor of interference heat exchange.But the irregularity that constitutes the plate of passage has further been disturbed moving of catalyst, and makes the easier obstruction of catalyst.So people seek to adopt a kind of method and reactor manner of formulation that can promote the channel-type reactor of heat exchange and catalyst circulation under the reactor continued operation.

Summary of the invention

Therefore, the purpose of this invention is to provide a kind of in reaction zone reactant contact with catalyst bed, simultaneously can carry out indirect heat exchange, and can realize the method that catalyst circulates aborning in reaction zone with a kind of heat-exchange fluid.

Another object of the present invention provides and a kind ofly is used for the indirect heat exchange of reactant logistics and the reactant logistics contacts with beds and the reactor apparatus that simultaneously catalyst circulated.

The present invention uses continuous air-flow to reduce or terminating method, periodically discharge and/or make-up catalyst from the selected reactant channels that is arranged in a reaction zone, therefore, in reaction zone, realized the continuous circulation of catalyst, kept reactant to pass through catalyst bed simultaneously and keep indirect heat exchange between reactant and the heat exchange medium simultaneously.During catalyst transport, reaction zone is divided into many reactions sub-district, to the minimizing of selecting flow or the combination that termination provides many reactant channels.The reaction sub-district is made of many channels interleaveds.These channel vertical and extension flatly.Catalyst enters reactant channels, and from the continuous or semi-continuous discharge in the bottom of passage, to realize the circulation of catalyst.Reactant radially flows through reactant channels, contacts with catalyst.The plate that constitutes passage provides heating surface for the heat-transfer fluid by heat transfer path.The reactant of reaction sub-district is discharged and/or is added in control selectively, and like this, the reactant that flows to one or several reaction sub-district is stopped or limited, and being flowing in the remaining reaction sub-district of reactant proceeded.Limit or stop this flowing, can allow catalyst under the gravity effect, to settle out in the reaction zone by this selection.

The order of reactant flow restriction and the discharge of catalyst can adopt any way that is suitable for the particle technical process to finish.The circulation that the reactant flow reduces and the discharge of catalyst granules can be carried out continuously, discharge catalyst from each reaction sub-district successively termly.In addition, the operation of this technical process can proceed to the inactivation result continuously and reaches till the expectation degree.At this moment, can use the operation of series reaction agent flow restriction, the circulation of setting up make-up catalyst successively in each reaction zone is till regaining desired activity.

Catalyst replenish and with a kind of reaction advantage that also can obtain to use the inventive method that combines of heat-transfer fluid indirect heat exchange.This combination can provide isokinetic reaction condition in the reaction sub-district.Along with the catalyst stage increment ground of reaction in the sub-district is replaced, the catalyst of most of inactivation is discharged from the bottom, and many active catalysts enter the top of reacting the sub-district simultaneously.Therefore, this periodically the displacement provides a continuous top-down active gradient on the length direction of each reaction sub-district internal catalyst bed.Active this reduction can be compensated by improving reaction temperature.For the endothermic reaction, hot fluid enters heat transfer path, and this fluid can enter the reaction sub-district along the flow direction of compensate for catalyst loss of activity.By heat-transfer fluid is transported to reaction top, sub-district from bottom, reaction sub-district, can keep higher temperature in the bottom of reaction sub-district, more decaying catalyst contacts with reactant in the bottom.Upwards advance by the reaction sub-district, therefore the reactant of heating cooling heat medium, has produced the reactant of lower temperature on the top of the reaction sub-district that tool active catalyst is housed.The temperature of catalyst make-up, heat medium, by the heat exchange of reactant and the setting of hot switching path, its purpose such as is to provide at power operation in reaction zone.This power operation such as grade can produce more uniform product effluent and can react the sub-district at each and more effectively utilize reaction compartment.Deng dynamic condition can be the exothermic reaction and the endothermic reaction.In exothermic reaction, cooling medium should enter the heat exchanger channels top, keeps and stream with catalyst, consequently has most the cooling effect that active catalyst area has maximum.

Therefore, in one embodiment, the invention provides in the channel-type reactor, reactant contacts with catalyst, and reactant and heat-transfer fluid mediate contact, and allows by the intermittently mobile method of the catalyst of catalyst bed.In this method, catalyst granules is packed in many reactions sub-district.There are many vertical and horizontally extending reaction channels and heat exchanger channels in each reaction sub-district.At least one reactant sub-district is led in the reactant logistics, contacts with catalyst.Reclaim the product logistics from reactant channels.Heat exchanging fluid passes through heat transfer path, by from the reaction sub-district the bottom discharge catalyst granules and it added the top of reaction sub-district, realize off and on to the flowing of the reactant logistics of a choice reaction sub-district of small part restriction, so that carry catalyst granules in this choice reaction sub-district.After catalyst added the reaction sub-district, the reaction sub-district was recovered flowing of reactant logistics again.

In another embodiment, the invention provides and be used for reactant and contact, reactant and heat-transfer fluid mediate contact and the channel-type reaction unit of make-up catalyst particle aborning with beaded catalyst.Thereby this device comprises vertical and horizontal-extending and constitute many reactions sub-district of the parallel-plate formation of heat transfer path and reactant channels in each reaction sub-district.This device provides reactant channels for the reactant logistics, and the reactant logistics of optionally restricted passage choice reaction agent passage is mobile.This device also provide catalyst granules by and join each reaction top, sub-district, and discharge catalyst granules from its bottom.Reactant channels also with the device collaborative work of heat-transfer fluid that is used for by the heat transfer path of each reaction sub-district.

In another embodiment, the present invention is that reactant contacts with catalyst granules, and reactant and heat exchanging fluid indirect heat exchange and the reactor of make-up catalyst particle simultaneously aborning, this device comprise the reactor vessel of settling many reactions sub-district.Each reaction sub-district comprise many vertical and horizontal-extendings in case in each reaction sub-district the parallel-plate of formation heat transfer path and reactant channels.This reactor vessel is configured for the reactant logistics is fed the reactant inlet of reaction channel.At least two manifolds receive the fluid from reactant channels.Each manifold communicates with the valve of regulating from the fluid flow of reactant channels, and each manifold communicates with reactant channels less than the reactant channels sum.Selectively control to each reaction sub-district at the catalyst distributor at each reaction top, sub-district with at catalyst gatherer and being used for of the bottom of each reaction sub-district and to add catalyst granules and be connected from device of each reaction sub-district discharge catalyst granules.This device also is used to make this heat exchanger channels by each reaction sub-district of heat exchange stream.

In the following detailed of the present invention, other embodiment of the present invention is disclosed, device and detailed content.

Description of drawings

Fig. 1 is the front section view by the reactor of the present invention's layout.

Fig. 2 is the cutaway view that reactor shown in Figure 1 intercepts along the 2-2 line.

Fig. 3 is the schematic diagram that reaction sub-district and catalyst, reactant and heat transferring medium flow by the reaction sub-district.

Fig. 4 is a reactor shown in Figure 3 profile along the reaction sub-district of 4-4 line intercepting.

Fig. 5 is a schematic diagram of discharging antigravity system.

Fig. 6 is the horizontal cross that comprises the reactor that react sub-district similar to reactor shown in Fig. 1-4.

The specific embodiment

This method can be used in the various catalytic reactions of using heterogeneous catalyst.Opposite with the fluid bed of catalyst, the reaction zone that is fit to is arranged the moving bed that will adopt catalyst.

The present invention is the catalytic conversion process process that is applied to have high reaction heat the most valuably.Such representative reactions is a hydrocarbon conversion reactions, comprises the aromatisation of hydro carbons, the reformation of hydro carbons, the dehydrogenation of hydro carbons and the alkylation of hydro carbons.Be fit to specific hydro carbons conversion process process of the present invention and comprise the reformation of the catalytic dehydrogenation raw gasoline feed stream of paraffin hydrocarbon, the aromatisation of light hydrocarbon and the alkylation of aromatic hydrocarbons.

The reaction zone that is used for the inventive method is in any relevant direction, and reactant and heat exchanging fluid are mediate contacts.Therefore, the flow channel of reaction zone, entrance and exit be designed to that reactant becomes also with heat exchanging fluid, adverse current or cross-current.Implement selection process of the present invention and arrange it is to make reactant pass through heat exchanging fluid in the mode of cross-current.Be the pressure drop minimum of the reactant that guarantees to flow through reactor, the cross-current of reactant generally is preferred.For this reason, shorter in order to make reactant pass through the path of reaction zone, can use cross-current to arrange.

When reactant during by the catalyst granules in the reactor, short path has reduced the overall presure drop of reactant.Lower pressure drop has dual benefit in the processing of many reaction logistics.Flow resistance is the increase of pressure drop, can improve total operating pressure of technical process.In many cases, help improving the yield or the selectivity of product than low operating pressure.Therefore reducing pressure drop to greatest extent also will provide the productive rate of higher desired product.In addition, higher pressure drop will improve the overall utilization and the operating cost of technical process.

Enforcement of the present invention is not necessary to ask each reactant channels all to be staggered with heat exchanger channels.The possible configuration of reaction zone is can two or more heat exchanger channels be set between each reactant channels, falls with the pressure that is reduced in the heat transferring medium side.When being used for this purpose, the plate of separating adjacent heat exchanger channels can have many apertures.

Be designed to the type and the detailed structure of the reactor of the invention process process, by being more readily understood with reference to the accompanying drawings.Fig. 1 is the schematic diagram in catalytic reactor zone 10, and it is the catalytic reaction that design is used for carrying out reactant fluid, and the indirect heat exchange of use and heat-transfer fluid when reactant fluid flows through this reaction zone, can keep favourable reaction temperature simultaneously.This reactor area includes the flow that limits continuously to come out from several zones of reactor area, to allow the device of reactor area make-up catalyst.This reactor comprises many reactions sub-district.The mediate contact of the reactant fluid of this reactor by bottom horizontal flow sheet and the heat-transfer fluid of perpendicular flow is carried out catalytic reaction under the temperature conditions of control, allow catalyst to move by reacting the sub-district simultaneously.

Reactor area 10 includes the reactor vessel 12 of circular cross-section.Reactor vessel 12 has the conical butt head 14 of support catalyst container 16.The bottom of snaphead 18 closed reactor containers 12 also forms reactant logistics inlet 20.Reactant flows into manifold 22 by inlet 20, and manifold 22 distributes reactant to enter reactant inlet tube 24.As shown in Figure 2, reactant inlet tube 24 adds allocation space 26 to the reactant logistics.The vertically extending reactant flow passage of reactant by forming in allocation space flatly flows through reaction sub-district 28.The collect product of autoreaction agent passage of collection space 30.Collecting pipe 32 is discharged product from each collection space 30, and by control valve 36 regulations speeds, through managing 34 product discharge reactor vessel.In the device shown in Fig. 1 and 2, each reactant inlet tube 24 is transported to two reactant sub-districts 28 to reactant.Each outlet 32 of while is 28 discharge product from two reactant sub-districts.Reactant inlet tube 24 can make each outlet 32 discharge the reactant of being carried by two different reactant inlet tubes 24 to the displacement of outlet 32.So, when control valve 36 restriction or when stopping the flow of outlet 32, from the residual flow of reactant inlet tube by remaining open outlet 32.In this manner, discharging in the All Time of catalyst from the reaction sub-district, inlet tube is all remained valid.

In each reaction sub-district, the reactant logistics contacts with granular catalyst.This catalyst is the discrete particles that diameter is 2-15mm usually.This catalyst granules can be Any shape, and still, this catalyst granules is generally spherical or cylindrical.Catalyst container 16 is equipped with the catalyst of the reactant channels that can flow into reactant sub-district 28.Catalyst enters the top of catalyst container 16 by catalyst feed introduction 38.The gas distributor pipe 40 that can Gong select for use can enter the distribution of air flow from nozzle 42 catalyst container 16.The gas that adds catalyst container 16, can be a kind of reducing gases that is used for further handling catalyst, or a kind of purge gas of not wishing gas that is used for the catalyst void space (when not wishing that air-flow enters catalyst container 16) that emptying can enter catalyst container 16.Gatherer baffle plate 44 is made of an annular space 46, discharges through nozzle 48 from purge gas or other gas of catalyst container 16.

The catalyst that comes out from catalyst container 16 flows into diffuser 52 by catalyst transfer pipeline 50, and the top of catalyst being striden the reaction channel of each reaction sub-district through diffuser 52 distributes.Bottom catalyst gatherer 54 in each reaction sub-district 28 is discharged catalyst by the mode of describing hereinafter through catalyst discharge nozzle 55.

Heat exchanging fluid enters technical process by the nozzle 56 that heat exchanging fluid is transported to into oral 58.Distributing pipe 60 is transported to heat exchanging fluid in the heat exchange manifold 62 that reacts the bottom of sub-district 28 at each.Heat exchanging fluid flows into the collecting manifold 64 at the place, top of each heat transfer zone 28 vertically upward in the heat exchanger channels of each reaction sub-district.Collecting pipe 66 adds heat exchanging fluid collects house steward 68, discharges heat exchanging fluid by nozzle 70 from reactor vessel 16.

Fig. 3 and 4 clearly show that the setting and the operation of reaction sub-district.Each reaction sub-district 28 comprises many parallel-plates 72 as shown in Figure 4.The plate that the present invention suits comprises any plate that allows high heat transfer rate.Preferred thin plate, thickness is 1-2mm usually.This plate usually by irony or non iron alloy for example stainless steel make.Every block of plate 72 can be smooth, still, preferably tends to the corrugated plating that reactant and heat exchanging fluid flow.This plate can be made into bending and other configuration, still, and for ease of heaping general preferred flat board.Corrugated plating can directly be piled up each other, and the space between the ripple forms staggered reactant channels 73 and heat exchanger channels 74.Plate 72 has the ripple of inclination.The zone that this plate can be deposited between the ripple mutually forms heat exchanger channels and reactant flow passage.Preferred wave pattern is opposite between adjacent panels, will extend in the opposite direction at the lip-deep herringbone pattern of corrugated plating relatively like this, and relative plate face is in contact with one another setting, forms flow channel, provides structural support to the zone of plate.

The catalyst granules 75 reactant flow passage 73 of packing into.The end plate 76 of reactant flow passage 73 stops flowing of catalyst by still allowing reactant along the mobile permeable baffle plate of direction shown in the arrow " A ".The end plate 77 of heat exchanger channels 74 has the baffle plate of the fluid impermeable on the length that heat exchanging fluid can be fixed on passage 74.The top of sealing zone of heat liberation stops catalyst to enter the heat exchanging fluid passage.Shown in the reaction sub-district of Fig. 3, heat exchanging fluid is mobile by being directed downwards shown in the arrow " B ", therefore react the sub-district and form " A " and " B " mobile special circulatory system, in this system, reactant logistics " A " and heat exchanging fluid " B " flows by cross-current direction, and the channels interleaved by being formed by adjacent plate 72.

As mentioned above, catalyst granules 75 flows into the top of reactant channels 73 through diffuser 52.Diffuser 52 can comprise the interior panelling or the corrugated plating 78 of the catalyst that is used for distributing equably along the top of reactant channels.Equally, the gatherer 54 collection catalyst particles 75 in reactant channels 73 bottoms, and baffle plate or corrugated plating 80 can be arranged.Baffle plate in diffuser and gatherer or corrugated plating can promote evenly replenishing along the catalyst in the whole horizontal length of each reactant channels 73.

Each reaction sub-district comprises, is used to receive the inlet that heat exchanging fluid enters the circulatory system " B " on reaction top, sub-district.This inlet can be a hole.Fig. 3 and 4 shows respectively from the bottom of reaction sub-district 28 and the manifold 64 and 62 of top distribution and collection heat exchanging fluid.Manifold 64 with 62 by being arranged in reaction sub-district relative end plate the top and the hole of the end plate 77 of bottom communicate with heat exchanging fluid passage 74.These two manifolds provide distributed areas on the end plate of reaction sub-district.In by manifold 64 and 62 distributed areas that surround, end plate 76 sealings of reactant channels stop heat exchanging fluid to enter reactant channels.

Discharge the system of catalyst from each reaction sub-district, be shown in to diagram Fig. 5.Illustrated as Fig. 1-4, every reactant management and control system is discharged product stream from adjacent a pair of reactant sub-district.Come autoreaction sub-district 28 ' the control of reaction logistics, by valve 36 ' adjusting from reactor product pipe 32 ' inflow outlet 34 ' and schematically illustrate.Catalyst by control valve 80 ' the hole from the reaction sub-district 28 ' discharge, be transported to catalyst pans 85 through managing 82.Pans 85 preferably are separated into several districts, and each district receives catalyst from a reaction sub-district.The volume in each district of pans 85 can be scheduled to make it and discharge catalytic amount that cycle period discharges from each reaction sub-district at each and be consistent.Catalyst gatherer 54 ' can be as the region of acceptance of the catalyst volume that remains in each discharge circulation, to be discharged.When being when remaining on gatherer 54 ' interior from pipe 84 continuous blow-down gas, can add this gas so that from the void space discharging reactant of catalyst.The catalyst granules that separation is discharged from each reaction sub-district helps monitoring to be discharged from catalyst all provides catalyst so that whether check discharging cycle period to each reaction sub-district.Enter the charging that to monitor each separated region by measuring charge level in the separated region or the temperature by the monitored area so that determine whether existing thermocatalyst.The pipe 83 from other the reaction sub-district catalyst transport to pans 85 (not illustrating).

Catalyst from pans 85 flows into sealing hopper 86.Catalyst enters the sealing hopper through managing 88.Pipe 88 comprises a series of valve 90,92 and 94.Valve 90 and 92 provides jointly along the air-tightness of pipe 88.Valve 90 stops the flowing and be used for stopping catalyst flowing and do not influence valve seal or valve seat of catalyst of these pipes, and still, valve 90 does not have gas tightness.In case the mobile of catalyst stops, catalyst is reduced under the plane of hermetic seal valve 92, if but there is sensitive for damages in catalyst.Valve 94 also has hermetic seal, and can be from managing 88 remainder parting seal hopper, so as the residues in the pipe 88 by going into pans 85 with the speed purge of regulating by control valve 98 through managing 96 nitrogen that add.

The catalyst that comes self sealss hopper 86 is by comprising 3 valves of series connection again: 102,104 and 106 pipe 100.In the valve sets of pipe in 100, operate by the mode identical with valve on the pipe 88, valve 104 and 106 catalyst are removed in case valve 102 provides catalyst seal just provides hermetic seal.Pipe 108 provides purging with nitrogen gas, and the atmosphere below the valve 106 is kept apart with the sealing hopper.The sealing hopper also can receive the continuous inert purge gas from pipe 109, so that during catalyst does not have charging, discharges the oxygen in the sealing hopper.The gas of purge gas and discharge is by pipeline 110 ' discharged by the sealing hopper.

Determine sealing hopper 86 volume in case storage catalyst until it is discharged from technical process with till regenerating.Sealing hopper 86 can be stored the catalyst that is transported to the continuous catalyst regenerating system of reactor joint operation, perhaps seals hopper and can keep in order to barrelling and non-at-scene regeneration or additional catalyst.If the catalyst of sealing hopper is discharged in the bucket, then the sealing hopper preferably should have sufficient space, to hold the volume of catalyst in the reaction sub-district.This just allowed before needs are with the sealing hopper discharge, from the disposable fully more catalyst changeout in reaction sub-district.Because the sealing hopper will be passed back into the sealing hopper by discharging from the oxygen of atmosphere.This purge and wash system provides the device of discharging this oxygen, and in most of reaction systems, oxygen is to enter reaction zone.

This method can be operated in a different manner.For the discharging or charging process of the catalyst that comes freely react the narrow passage that the sub-district forms, its key factor is to limit to enter or discharge the flow that reacts the sub-district.Setting enter the reaction sub-district or from the flow that comes out of reaction sub-district to control a plurality of reactions sub-district simultaneously, shown in the embodiment of Fig. 1-5.Another kind method is, enters reactant of each reaction sub-district or flow of the product that comes out from each reaction sub-district can be controlled respectively.The flow arrangement of the reactant that enters each reaction cell flow or come out from each reaction sub-district, as shown in Figure 6.Fig. 6 shows the horizontal cross-section of the reactor that comprises many and the similar reaction sub-district shown in Fig. 1-4.The difference of Fig. 6 and Fig. 1-4 is to react sub-district 110 around being arranged in around it by polygonal layout as distributor or as the central space 112 of gatherer.Baffle plate 116 is around the outside 114 of each reaction sub-district 110.Baffle plate 116 also forms a space in the outside of each reaction sub-district 110 that can be used as gatherer or distributor.Each pore 118 is connected with the space outerpace 117 that is surrounded by each baffle plate 116.Suitable valve on outlet 118 pipe can selectively limit or stop by each reaction sub-district flow.The total overall reaction sub-district again can by 120 of reactor vessels around, for reaction provides wiper seal.

In a kind of method of operating, the reaction zone shown in Fig. 1-5 will only carry out periodically catalyst make-up operation.In most operation, this catalyst will remain in the reaction sub-district, and when carrying out the replenishment cycles of catalyst in the reaction sub-district, the program of reactant or product effluent flow took place during moment.Therefore, reactant will enter reactor vessel by manifold 22, and discharge till preset time or discovery catalysqt deactivation by outlet 32.

In case when catalyst will replenish, the program of discharging catalyst from a pair of reaction sub-district will.This program flows through two reaction sub-districts by valve-off 36 with the stopped reaction agent and begins.In case the mobile of reactant stops, just from selecting to stop two catalyst that react sub-districts discharge scheduled volumes of reactant flow.For the regular replenishment catalyst, normally discharge a large amount of catalyst from each reaction sub-district.Preferred about 25% the catalyst that equals to react catalyst total amount in the sub-district of discharging.Flow into the make-up catalyst that equals to discharge catalytic amount at the catalyst that when catalyst is discharged in the bottom of reaction sub-district, replenishes from catalyst container 16.After make-up catalyst, open the control valve 36 on outlet 32, the reaction sub-district that reactant is flow through just received fresh catalyst.Program is proceeded, and closes down the outlet pipe valve of a pair of reaction sub-district, ends the logistics from flowing through here.In case when exchanging the equal-volume catalyst once more in following a pair of reaction sub-district, program is proceeded, up to all exchange the equal-volume catalyst in all reaction sub-districts till.

Make-up catalyst does not have substantive the interference to technical process in such a way.Can keep complete flow of reactant in reactor, simultaneously can be in the reaction sub-district of selecting whole catalyst changeouts more, and the increase of having only appropriateness falls in its pressure.In whole this catalyst exchange process, can keep fully flowing of reactant.In most of technical process, though for the exchange of carrying out catalyst will limit or stop to flow of reactant, but, also needn't stop the flowing of heat exchanging fluid by the reaction sub-district, concerning many technical process, when heat medium flowed by heat tunnel, the temperature of heat medium only changed a little.The change of this temperature is usually less than 12 ℃ (20 °F).Therefore,, in the exchange process of catalyst, although restriction or discharge reactant,, superheating phenomenon can not take place in the reaction sub-district.In many cases, in the exchange process of catalyst, flowing of reactant will stop basically.But, still wish the minimum discharge of maintenance, to avoid taking place the situation of stagnation at reaction compartment by reaction zone.Between the commutation period of catalyst, according to specific embodiment of the invention process, the flow that needs to keep the reactant flow or reduce heat medium.

Catalytic reforming is known hydroconversion process, and it is used for petroleum refinement industry, improves the octane number of hydrocarbon raw material, and refining primary product is a motor benzine.The technology of catalytic refining is well-known, does not describe in detail herein.Briefly, in catalytic reforming, raw material mixes with the recycle stream that comprises hydrogen, and contacts with catalyst in the reaction zone.The raw material commonly used of catalytic reforming is that initial boiling point is that 80 ℃ (180) and final boiling point are the petroleum cuts that is called as naphtha of 205 ℃ (400).The catalytic reforming process process is specially adapted to handle by the cycloalkane of higher concentration and mainly is the direct steaming gasoline that the linear paraffin hydrocarbon is formed, and carries out aromatisation by dehydrogenation and/or cyclization.Reformation can be defined as by the dehydrogenation of cyclohexane and alkyl cyclopentane dehydroisomerization produce aromatic hydrocarbons, paraffin hydrocarbon dehydrogenation produce alkene, paraffin hydrocarbon and alkene dehydrocyclization produce aromatic hydrocarbons, just-isomerization of paraffin hydrocarbon, the isomerization of alkyl ring paraffin hydrocarbon generation cyclohexane, the isomerization of substituted arene and total effect that hydrocracking produced of paraffin hydrocarbon.About other data of reforming process is disclosed among US-A-4119526, US-A-4409095 and the US-A-4440626.

Catalytic reforming reaction generally by one or more VIII family noble metal (for example platinum, iridium, rhodium and palladium) and and porous carrier, for example the catalyst formed of the halogen atom of high-temperature inorganic oxide combination carries out under existing.Halogen generally is a chlorine.Usually use alumina support.Preferred alumina material be γ-, η-and θ-aluminium oxide, use gama-alumina and η-aluminium oxide to obtain best result.Surface area that critical nature be carrier relevant with the character of catalyst.The preferred surface area of carrier is a 100-500 rice ²/ gram.Though catalyst granules can resemble 6.35 millimeters (1/4 inches) so big, be generally sphere, its diameter is 1.5-3.1 millimeter (1/16 inch-1/8 inch).Preferred catalyst granules diameter is 3.1 millimeters (1/16 inches).In the reforming reaction process, catalyst granules is owing to the mechanism of deposition of coking on particle and so on causes inactivation; In use for some time promptly, catalyst granules promotes the degree that the ability drop of reforming reaction no longer plays a role to catalyst.Before it re-used in the reforming process process, this catalyst must activate or regenerate again.

In preferred mode, resurfacing operation adopts a moving bed reaction district and a renewing zone.The present invention can be applied to this moving bed reaction district.In the moving bed operation, the fresh catalyst particle adds reaction zone by gravity.Catalyst is discharged from the bottom of reaction zone, and is transported to the renewing zone, in the renewing zone, uses the multistep regenerative process to activate this catalyst again, makes it recover to promote the ability of reacting fully.Flow through the different regeneration stages by the gravity catalyst, discharge from the renewing zone then, and the supply response district.The catalytic reforming process process is generally repeatedly carried more a spot of catalyst in the immediate time interval.So when catalyst mobile is commonly referred to when continuous, it is actually semi-continuous.

Catalytic dehydrogenation is another the heat absorption method example that advantageously uses the inventive method and equipment.Briefly, in catalytic dehydrogenation processes, raw material mixes with the recycle stream that comprises hydrogen, and contacts with catalyst in reaction zone.The raw material of catalytic dehydrogenation generally is the petroleum distillate that comprises the paraffin hydrocarbon of 3-18 carbon atom.Concrete raw material will comprise light or heavy paraffin hydrocarbon usually.For example, the common raw material that is used to produce the heavy dehydrogenation product will comprise the paraffin hydrocarbon of 10 or 10 above carbon atoms.The catalytic dehydrogenation process process is specially adapted to handle the hydrocarbon raw material that consists predominantly of the paraffin hydrocarbon for the treatment of process dehydrogenation reaction and then generation olefin(e) compound.

Catalytic dehydrogenating reaction carries out in the presence of catalyst usually, and this catalyst is made up of with porous carrier such as high-temperature inorganic oxide one or more VIII family noble metal (for example platinum, iridium, rhodium and palladium).Aluminium oxide also is normally used carrier, and preferred alumina material is identical with the aluminium oxide that is used for catalytic reforming.Usually, muriatic concentration is the heavy % of 0.5-3 in the catalyst granules.In dehydrogenation reaction process, catalyst granules also can be along with coke laydown inactivation, and requirement and the described similar renovation process of reforming process process; So the dehydrogenating technology process also will adopt moving bed reaction of the present invention district.

Dehydrogenation condition comprises that temperature is that 400-900 ℃ of (752-1652), pressure are that 10-1013KPa (0.01-10 atmospheric pressure) and liquid phase space-time speed (LHSV) are 0.1-100hr ^-1To general paraffin hydrocarbon, in general, molecular weight is low more, and it is just high more to transform desired temperature similarly.Pressure in dehydrogenation reaction zone should be low as much as possible according to the qualification of the equipment of employing, and chemical reaction equilibrium is moved to the product direction.The preferred process conditions of method of the present invention comprise that temperature is that about 400-700 ℃ of (752-1652) pressure is that 10-507KPa (0.1-5 atmospheric pressure) and liquid hourly space velocity (LHSV) are 0.1-100hr ^-1

But hydrocarbon, hydrogen and the products of dehydrogenation reactions that generally will comprise unconverted dehydrogenation from the discharge logistics of dehydrogenation reaction zone.After the normal cooling of this effluent circulation, lead to the Hydrogen Separation district, from the rich hydrogen steam of rich hydrocarbon liquid phase separation.Usually, rich hydrocarbon liquid phase can adopt a kind of suitable selected adsorbent, a kind of selective solvent, a kind of choice reaction or several reaction to separate further, perhaps further separates by suitable fractionation flow process.But reclaim the hydrocarbon of unconverted dehydrogenation, and be recycled to dehydrogenation reaction zone.The product of dehydrogenation reaction reclaims as final products, or reclaims as the intermediate product of other compound of preparation.

But the hydro carbons of dehydrogenation before being passed into dehydrogenation reaction zone, therebetween or afterwards, can mix with carrier gas.This carrier gas can be hydrogen, steam, methane, carbon dioxide, nitrogen, argon gas etc., or their mixture.Hydrogen is preferred carrier gas.Usually, when a kind of carrier gas is when being used as diluent, its consumption guarantees that enough the mol ratio of carrier gas and hydrocarbon is 0.1-20.When this mol ratio is 0.5-10, obtained best result.The dilute hydrogen entraining air stream that leads to dehydrogenation reaction zone generally is an isolated circulating hydrogen in the discharge logistics of dehydrogenation reaction zone from the Hydrogen Separation district.

Water or under dehydrogenation condition, decompose to generate the material of water for example alcohol, aldehyde, ether or ketone can add dehydrogenation zone.The precursor of water or water or adding continuously, or add discontinuously, by being benchmark when water gaging, its addition is 1-20000 (weight) ppm hydrocarbon feed stream.When the paraffin hydrocarbon dehydrogenation of 6-30 or more a plurality of carbon atoms, the water that adds 1-10000 (weight) ppm has obtained best result.Other data relevant with the operation of dehydrogenation, the layout of operating condition and technological process can be with reference to US-A-4677237, US-A-4880764 and US-A-5087792.

Embodiment

Utilize the effect of method of the present invention and dynamic conditions such as reactor exchange catalysts and maintenance once in the hydrocarbon conversion process process of paraffin hydrocarbon dehydrogenation, to study.This simulation is periodically replaced catalyst by the increment by 10%, produces the semi-continuously result of exchange catalysts of dehydrogenation reaction zone.This catalyst is typically to comprise platinum to load on dehydrogenation on the alumina support.Activity of such catalysts changes linearly gradually, is 100% at the top of bed, to bed the bottom be 55%.This method is that the ratio at hydrogen and hydrocarbon is 2.9, and LHSV is 31.5hr ^-1Operate under the condition.The average pressure of reaction zone is 194KPa (13.5psig).The speed that enters the raw material of reaction zone is 58060kg/hr (128000lbs/hr), and the mole composition is shown in table 1.The inlet temperature that enters the raw material of reactor is 432 ℃ (810 °F), and the average outlet temperature of discharge is 479 ℃ (895 °F).Raw material and 794mg/hr (1.75 * 10 ⁶Ibs/hr) density is 83.3kg/m ³(5.198lbs/ft ³) and thermal capacity be the heat medium counter current contacting of 0.705kj/kg (0.303BTUs/lb/).The temperature that enters the heat medium of technical process is 560 ℃ (932 °F), and the outlet mean temperature of discharge is 481 ℃ (898 °F).The weight conversion ratio of raw material is 20.15 weight %.The selectivity monoolefine of representing with weight % is 85.7%, and alkadienes is 4.7%, aromatic hydrocarbons be 4% and light hydrocarbon be 4.2%.

Table

Logistics MOL%	Charging
Logistics MOL%	Charging	Water	1.78
Hydrogen	71.67	Water	1.78
Hydrogen	71.67	Methane	0.47
Ethane	0.92	Methane	0.47
Ethane	0.92	Propane	0.20
Just-butane	0.06	Propane	0.20
Just-butane	0.06	Just-pentane	0.02
Just-decane	2.72	Just-pentane	0.02
Just-decane	2.72	n-C ₁₁	10.85
n-C ₁₂	7.94	n-C ₁₁	10.85
n-C ₁₂	7.94	n-C ₁₃	3.22
n-C ₁₄	0.160	n-C ₁₃	3.22
n-C ₁₄	0.160	Nonylene-1	0.000
Decylene-1	0.000	Nonylene-1	0.000
Decylene-1	0.000	Undecene-1	0.000
Dodecylene-1	0.000	Undecene-1	0.000
Dodecylene-1	0.000	Tridecylene-1	0.000
Add up to	100.01	Tridecylene-1	0.000

Claims

1. one kind makes reactant contact, make simultaneously reactant and heat-transfer fluid mediate contact with beaded catalyst in the channel-type reactor and makes catalyst discontinuously by the method for the catalyst bed that formed by reactant channels, and described method comprises:

In many reactions sub-district catalyst granules is housed, there are many vertical and horizontally extending reaction channels and heat exchanger channels in each reaction sub-district;

Make the reactant logistics feed at least one above-mentioned reaction sub-district, and described catalyst and described reactant gas are in contact with one another;

Make heat exchanging fluid feed above-mentioned heat exchanger channels;

Limit the flow that described reactant logistics enters the choice reaction sub-district to small part discontinuously, and in the choice reaction sub-district by discharging catalyst granules from the bottom and catalyst granules being carried at the top that catalyst granules adds selected reaction sub-district;

After catalyst granules adds above-mentioned selected reaction sub-district, in above-mentioned selected reaction sub-district, recover the flow of above-mentioned reactant logistics again; With

Reclaim product stream from above-mentioned reaction channel.

2. the process of claim 1 wherein that described heat-transfer fluid vertically flows through above-mentioned heat exchanger channels, described reactant flatly flows through reactant channels.

3. claim 1 or 2 method, wherein reactant contacts with catalyst the endothermic reaction takes place, and heat exchanging fluid is a kind ofly to add hot fluid from the heat exchanger channels bottom to what flowed in the top.

4. claim 1 or 2 method, wherein only a part of catalyst shifts out from the reaction sub-district in the reaction sub-district of selecting, simultaneously the flow of limited reactions agent.

5. the method for claim 3, but wherein above-mentioned reactant comprises the hydrocarbon of dehydrogenation, and above-mentioned product comprises alkene.

6. claim 1 or 2 method wherein when stopping the flow of above-mentioned reactant, keep the flow of above-mentioned heat exchanging fluid.

7. one kind is used for reactant and contacts with catalyst granules, and reactant and heat-transfer fluid indirect heat exchange are also replaced the channel-type reactor assembly of catalyst granules aborning, and described device comprises:

A plurality of reactions sub-district, it comprises many vertical and horizontal-extendings and the parallel-plate of formation heat transfer path and reactant channels in each reaction sub-district;

Be used to make the reactant logistics by above-mentioned reactant channels and the selectional restriction device by the above-mentioned reactant logistics of choice reaction sub-district, the said apparatus that wherein limits above-mentioned reactant flow comprises collects from the manifold of the fluid of the reactant channels of each reaction sub-district, by the formed outlet of each manifold be used for regulating the valve of each rate of discharge;

Be used for that catalyst granules added top of each reaction sub-district and discharge the device of catalyst granules from its bottom; With

Be used to make heat exchanging fluid to pass through the device of the heat exchanger channels of each reaction sub-district.