RU2381207C2 - Membrane reactor and method for synethesis of alkenes via catalytic dehydrogenation of alkanes - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used in petrochemical industry. The membrane reactor for dehydrogenation of alkanes has a tubular catalytic membrane 2 containing several end-to-end radial macropores, on the surface of which a dehydrogenation catalyst is deposited and two membranes 3, which are permeable to hydrogen only. The catalytic membrane 2 lies between the membranes 3 which are permeable to hydrogen only such that, together with transverse walls 5, they form a row of closed cavities 6 which are connected to each other only by the end-to-end pores of the catalytic membrane 2.

EFFECT: invention provides the process of obtaining alkenes without loss of hydrocarbon material.

12 cl, 4 dwg, 6 tbl

Description

The invention relates to petrochemical production, as well as to a technology for the production of organic substances from associated gases and gas condensate.

The invention relates, in particular, to the catalytic dehydrogenation of lower alkanes to produce olefins, including ethylene, propylene and other lower alkenes.

The invention also relates to the construction of catalytic dehydrogenation reactors of lower alkanes using membranes to remove hydrogen from the reaction zone.

Lower alkenes such as ethylene and propylene are critical petrochemical products. They are used for the production of polyethylene, polypropylene, acrylonitrile, cumene and other equally valuable organic substances.

In general, the catalytic dehydrogenation of alkanes is carried out in the form of a reversible reaction:

The most valuable for industry are lower alkenes, with a value of n from 2 to 6. The alkane dehydrogenation reaction is endothermic and reversible. The q value for lower alkanes is close to 30 kcal / mol. The catalytic dehydrogenation process proceeds in the temperature range 400-600 ° C under the condition of continuous removal of hydrogen from the reaction zone.

Over the past 15 years, various methods have been used in the technology for producing alkenes by the catalytic dehydrogenation of lower alkanes.

A known method for the dehydrogenation of light hydrocarbons in a three-chamber reactor (US Pat. No. 4,914,249), in which the hydrocarbon feed is subjected to dehydrogenation with intermediate selective oxidation of hydrogen in a separate chamber. The first reaction chamber containing the dehydrogenation catalyst is used to mix the hydrocarbon gas with steam and to carry out the first stage of the catalytic dehydrogenation of the hydrocarbon feed. The second reaction chamber contains a selective hydrogen oxidation catalyst. When a gas mixture consisting of primary and dehydrogenated hydrocarbons, hydrogen and water vapor, as well as an additional oxygen-containing gas is introduced from the first chamber, selective hydrogen burning occurs. Due to the exothermic effect of the reaction, the temperature of the dehydrogenated and starting hydrocarbons increases markedly. The third chamber is similar in design to the first. In it, the mixture heated in the second chamber in contact with the dehydrogenation catalyst is converted into the target product. A distinctive feature of the dehydrogenation process proposed in this invention is the use of a selective hydrogen oxidation catalyst in a second reactor chamber. The catalyst consists of a porous carrier, which is first impregnated with compounds of noble metals of group VIII and metals of group IV, then calcined and then impregnated with lithium compounds. A distinctive feature of the dehydrogenation reactor proposed in this invention is the use of a selective hydrogen oxidation catalyst in a second reactor chamber.

The main disadvantage of this reactor is that part of the primary and dehydrogenated hydrocarbons react with an oxygen-containing gas and this leads to contamination of the final product with partially oxidized hydrocarbons.

A known method for the dehydrogenation of light hydrocarbons (Japanese Patent 5-41610) in a reactor consisting of a hydrocarbon dehydrogenation chamber and a hydrogen collection chamber formed during the dehydrogenation of hydrocarbon feedstocks. The chambers are separated by a hydrogen-permeable membrane, which makes it possible to quickly remove hydrogen from the reaction zone. So that hydrogen does not accumulate in the hydrogen collection chamber and maintains a high gradient of hydrogen concentration between the dehydrogenation and hydrogen collection chambers, it is continuously oxidized in the hydrogen collection chamber with oxygen or an oxygen-containing gas and the reaction products together with the hydrogen residues are removed from this chamber. This provides a continuous outflow of hydrogen from the dehydrogenation chamber. Both chambers are surrounded by a layer of thermal insulation to stabilize the temperature regime of the reactor.

The disadvantage of this solution is the use of a bulk catalyst in the reaction chamber, which requires a large reactor capacity and is inconvenient to use, since it has to be periodically poured and subjected to high-temperature oxidation in order to remove coke forming on its surface.

The closest proposed invention corresponds to the technical solution described in US patent 5202517. This patent describes the process of producing ethylene from ethane in a flow reactor. The catalytic chamber of the reactor is separated from the hydrogen collection chamber by a nanoporous γ-alumina membrane with a thickness of less than 10 μm with pores with a diameter of less than 10 nm. A nanoporous membrane is formed on the outer side of a ceramic microporous pipe with a thickness of 1 ÷ 2 mm. A metal dehydrogenation catalyst (platinum, palladium or chromium) is applied to the surface of the nanoporous membrane by impregnating it with solutions of the corresponding salts and their subsequent decomposition. The reactor can be heated from 300 to 650 ° C. The space between the nanoporous membrane and the wall of the reactor is filled with a granular catalyst. During the movement of a gas stream containing ethane, argon and hydrogen along this space as a result of contact with the catalyst at high temperature, ethane partially decomposes into ethylene and hydrogen. Ethylene formed is removed from the reaction zone by a gas stream, and a significant part of hydrogen is washed out of the stream due to the molecular flow through the nanoporous membrane. Together with an admixture of ethane and ethylene, which also penetrate through nanopores, hydrogen is collected inside the volume of the ceramic pipe and carried out by an auxiliary stream of water vapor or inert gas. The permeability of the membrane to hydrogen, ethane and ethylene are correlated as 3.5: 0.9: 1.0

The disadvantages of the technical solution claimed in US patent 5202517 are:

1. The use of a nanoporous membrane, which due to the Knudsen nature of the flow has a low hydrogen throughput and insufficient selectivity. Together with hydrogen, dehydrogenated and primary light hydrocarbons seep through nanopores. Theoretical estimates of the authors showed that the calculated fraction of these hydrocarbons in the removed hydrogen should exceed 25% (molar).

2. In order to compensate for heat loss during dehydrogenation, the catalyst and gas in the reaction zone are heated to higher temperatures than necessary for catalytic dehydrogenation.

3. The use of a granular catalyst, in addition to the inconvenience caused by its regeneration (unloading-loading), requires a significant increase in the volume of the reactor itself.

The objective of the invention is to develop a compact, high-performance membrane reactor for catalytic dehydrogenation of alkanes, devoid of these disadvantages and ensuring the implementation of the process of producing alkenes without loss of hydrocarbon feedstocks.

The problem is solved in that the inventive membrane alkane dehydrogenation reactor and a method for producing alkenes by catalytic alkane dehydrogenation are based on the use of the developed membrane reactor. The proposed reactor contains thermocouples inside the reactor, has a dehydrogenation chamber, a hydrogen collection chamber, a system for removing hydrogen from the catalytic dehydrogenation zone to a hydrogen collection chamber, a heating system for the reactor, an alkane input device into the dehydrogenation chamber and a mixture of alkane and alkene from it, a buffer gas input device into the chamber for collecting hydrogen and withdrawing from it a buffer gas containing hydrogen. Thermocouples are located inside the reactor to control the temperature.

Distinctive features of the developed membrane reactor are that the dehydrogenation chamber is made in the form of a tubular catalytic membrane containing through radial macropores, on the surface of which a dehydrogenation catalyst is applied, the hydrogen collection chamber has two cylindrical cavities, each of which is selectively permeable from the dehydrogenated alkane stream only for hydrogen, membranes coaxially located relative to the catalytic membrane; in order to ensure the sequential passage of the alkane stream through the through pores of the catalytic membrane from the entrance to the reactor to the exit from it, cavities are formed on the flow path, consisting of sections of the catalytic membrane enclosed between transverse walls and membrane sections that are permeable only to hydrogen. The catalytic membrane is made in the form of a porous tube of aluminum oxide or zirconium oxide with a thickness of 1 to 4 mm and has through radial pores with a diameter of 1 to 100 microns.

The through radial pores of the catalytic membrane contain on their surface a dehydrogenation catalyst from platinum group metals or 3d transition metals or their alloys, or in the form of iron, chromium or mixed oxides containing transition metal oxides. A feature of this membrane is that the average pore diameter of the catalytic membrane and its thickness must satisfy the condition: d≤0.1 · δ, where d is the average pore diameter, δ is the membrane thickness.

Hydrogen-permeable membranes are made in the form of a porous tube of aluminum oxide or zirconium oxide, have a thickness of 1 to 4 mm and a diameter of through radial pores of 1 to 100 μm, which are sealed on one side with a palladium film from 1 to 0.01 thick microns.

In the membrane reactor, cavities are formed consisting of sections of the catalytic membrane and sections of membranes selectively permeable only to hydrogen, limited by transverse baffles. These partitions are arranged so that one half of any limited portion of the catalytic membrane, except the first and last, simultaneously belongs to this cavity and the previous one, and the other half belongs to both this and the subsequent cavity, while the number of cavities in the reactor cannot be less than two.

It is important that each section of catalytic membranes and membranes selectively permeable only to hydrogen, limited by transverse partitions, is equipped with a resistive heater and a temperature meter, allowing independent heating and temperature control in the range of 250-600 ° C.

A membrane reactor can be included in a system of parallel reactors of similar reactors spatially distributed both horizontally and vertically.

The method of producing alkenes by catalytic dehydrogenation of alkanes is implemented in a membrane reactor containing a dehydrogenation chamber, a hydrogen collection chamber, a system for removing hydrogen from the catalytic dehydrogenation zone to a hydrogen collection chamber, a reactor heating system, an alkane input device into the dehydrogenation chamber and a mixture of alkane and alkene from it , a device for introducing a buffer gas into a hydrogen collection chamber and withdrawing from it a buffer gas containing hydrogen.

New in the method is that the dehydrogenation process is carried out in a membrane reactor, in which the dehydrogenation chamber is made in the form of a catalytic membrane, which is a through radial macropores in a ceramic pipe, the surface of which is coated with a dehydrogenation catalyst, and the hydrogen collection chamber has two cylindrical cavities, each of which are separated from the dehydrogenated alkane stream by membranes selectively permeable only for hydrogen, cylindrical in shape and coaxially arranged relative to but a catalytic membrane. To ensure conditions for the sequential passage of the alkane stream from the entrance to the reactor through the through pores of the catalytic membrane, cavities are formed on the path of the specified stream, consisting of sections of the catalytic membrane enclosed between the transverse walls and portions of hydrogen-permeable membranes only; at the same time, a mixture of an alkane containing from 0.1 to 10% hydrogen with argon in a volume ratio of from 1: 1 to 1:15 is fed to the input device to the membrane reactor into a membrane reactor, and this gas mixture is sent to the cavity between the catalytic membrane and two hydrogen-permeable membranes limited by longitudinal baffles, the number of which cannot be less than 2. A pressure drop of 5 · 10 ⁴ to 3 · 10 ⁵ Pa forces the specified stream to move from the inlet to the reactor to the exit from it by sequential seepage from one gender awns in the adjacent through-pores of the catalytic membrane. After dehydration of the alkane in the nanopores of the catalytic membrane, the obtained target product, alkene and hydrogen, is selectively separated by means of membranes permeable only to hydrogen. These membranes, the through pores of which are covered with a thin palladium film, are made in the form of porous pipes and are located coaxially on both sides of the catalytic membrane,

Compensation of energy costs due to the endothermic dehydrogenation process and set to reduce the temperature of the catalytic membrane is carried out by heating the catalytic membrane with electric current supplied by the conductors to the resistive heater of the catalytic membrane.

The rate of removal of part of hydrogen from the stream containing alkane, alkene, hydrogen and argon into the hydrogen collection chamber after the specified stream exits from the pores of the catalytic membrane is controlled by changing the temperature from 250 to 600 ° C of the adjacent section of the hydrogen-permeable membrane only by means of a resistive heater.

The simultaneous removal of hydrogen from the hydrogen chamber is carried out by a stream of superheated steam due to the pressure drop in the specified stream from 5 · 10 ⁴ to 3 · 10 ⁵ Pa between the entrance to and exit from the hydrogen chamber.

The control of the alkane dehydrogenation process in a membrane reactor is organized using a microprocessor unit, which is continuously supplied with readings of pressure sensors, temperature, composition and velocity of gas flows at the reactor inlet and outlet, as well as data on the temperature of the catalytic membrane and sections of hydrogen-permeable membranes .

The method of producing alkenes by catalytic dehydrogenation of alkanes can be implemented in a system of membrane reactors parallelly connected by pipelines spatially distributed both horizontally and vertically; however, in each of the reactors, the dehydrogenation process is carried out independently of other reactors.

The diagrams below (Figs. 1-4) show the main features of the invention. They are also illustrative material, revealing the essence of the invention.

Figure 1 is a schematic diagram of a membrane reactor for catalytic dehydrogenation of alkanes.

Figure 2 is a schematic representation of a section of a portion of a catalytic membrane.

Figure 3 is a schematic illustration of a section of a portion of a membrane selectively permeable to hydrogen.

Figure 4 - diagram of the main gas communications, providing a catalytic process for the production of alkene in a membrane reactor.

In the proposed reactor, the section of which is schematically shown in Fig. 1 and which is indicated by the number 1, the main working element is a catalytic dehydrogenation membrane 2 and two hydrogen-permeable membranes 3 only. The membranes are placed in a steel sealed container 9 having the shape of a cylinder. The catalytic membrane 2 is a macroporous ceramic pipe having through radial pores with a dehydrogenation catalyst deposited on their surface. Thus, a plurality of through macroscopic pores containing a catalyst on its surface performs the functions of a dehydrogenation chamber. Alkane interacts with the catalyst during its movement through these pores. Next to the catalytic membrane 2, on either side of it, an additional two hydrogen-permeable membranes are disposed. Further, for brevity, these membranes are called hydrogen. Hydrogen membranes, like the catalytic membrane, have a cylindrical shape. They are located coaxially on both sides relative to the catalytic membrane with a gap of 1 to 3 mm between the hydrogen and catalytic membranes. The main purpose of these membranes is to selectively and controllably pass hydrogen generated during alkane dehydrogenation in the pores of the catalytic membrane 2 into the hydrogen collection chamber, which consists of two cavities 4.

The catalytic membrane 2 is located between the hydrogen membranes 3 in such a way that together with the transverse baffles 5 forms a series of closed cavities 6, which are connected to each other only through the pores of the catalytic membrane 2. The temperature of the catalytic membrane and the sections of the hydrogen membranes forming the cavity 6 can be independently controlled resistive heaters deposited on the surface of the catalytic 1 and each section of hydrogen membranes 3 involved in the formation of cavities 6. In principle, the heater They can be made in the form of wire coils mounted in the body membranes. Electric current is supplied to resistive heaters through current leads 7 and 8 mounted on the reactor lid.

In order to compensate for the thermal expansion of the materials used in the reactor, all longitudinal elements of the reactor, including the catalytic membrane 2 and hydrogen membranes 3, are connected to the outer shell of the reactor 9 through bellows 14.

The two-cavity thermostabilizing chamber 11 is designed to maintain a temperature from 250 ° C to 500 ° C inside the reactor. The heat-stabilizing gas 11, for example, superheated water vapor or any gas preheated to high temperatures, enters the C ₁ inputs _of both cavities of the thermostabilizing chamber 11. The outlet pipes С ₂ are intended for directing the spent heat carrier gas to the recuperator, where it gives off its thermal energy for preheating the alkane entering the reactor.

Thermal insulation shell 10 minimizes the energy consumption for maintaining high temperature in the reactor volume. Input device A ₁ serves to introduce preheated alkane into the reactor. Due to excess pressure from 0.5 · 10 ⁵ to 5 · 10 ⁵ Pa, the alkane has the ability to move along cavities 6 to the outlet of reactor A ₂ , sequentially seeping through the pores of the catalytic membrane from one cavity to another. The number of cavities in the reactor cannot be less than 2. The maximum number of cavities is determined by the throughput of the catalytic membrane and the permissible excess pressure in the cavities.

The apparatus ₁ B is intended for insertion into the cavity of the hydrogen buffer gas chamber in the form of superheated steam to remove them from the permeate hydrogen which is formed during the dehydrogenation of the alkane and diffuses from the reaction zone through two permeable only to hydrogen via the membrane 3. In ₂ O-vapor stream a mixture containing hydrogen is sent from the reactor to the hydrogen evolution system.

Figure 2 shows a schematic sectional view of a portion of a catalytic membrane 2 made in the form of a pipe of porous alumina having through radial pores with a diameter of 1 to 100 μm and a wall thickness of 1 to 4 mm. Instead of alumina ceramics, any other material resistant to high temperatures in a hydrocarbon medium, hydrogen, and oxygen-containing gas can be used to make the basis of the catalytic membrane. These may be, for example, zirconium oxide, metal carbides or nitrides.

A thermocouple 13 is mounted in the recess 20 inside the membrane body, and a resistive heater 21 is applied to the surface of the catalytic membrane, with which the temperature of the membrane is controlled within the range of 250-600 ° C. Instead of a film heater, other heater designs can be used that can provide temperature conditions for the catalytic membrane. For example, they can be made of tungsten or nichrome filaments.

Figure 2 in oval 22 schematically shows a portion of a catalytic membrane with a large increase in through radial pores, the surface of which is coated with a dehydrogenation catalyst 23. The pores are coated with a metal or oxide dehydrogenation catalyst. Catalytic coating 23 in nanopores is deposited in the form of nanoparticles ranging in size from 1 to 100 nm (the best option). Platinum group metals (rhodium, palladium, osmium, iridium, platinum) and other catalytically active metals and alloys, including transition 3-d metals with alloying additives, are used as a metal catalyst. As oxide catalysts, transition metal oxides, including chromium, iron or heteronuclear oxides containing these metals, are used.

Catalytic coatings of nanopores with platinum group metals and transition metal oxides are applied in various ways.

A catalytic layer based on platinum group metals is applied by impregnating the pores of the catalytic membrane with aqueous solutions of metal complexes containing a ligand in the coordination sphere, capable of reducing the metal complex to a metal with the formation of active metal nanoclusters on the nanopore surface at a controlled increase in temperature (after separation of the supported oxide support from the liquid phase) .

The catalytic layer of transition metal oxides is applied by impregnation of pores with aqueous solutions of formate and / or acetate oxo or hydroxo complexes of the above transition metals containing an oxygen-containing ligand, for example, water, amide in the coordination sphere. At an elevated temperature, catalytically active clusters of transition metal oxides or heteronuclear oxides capable of dehydrogenating alkanes form on the membrane pore surface.

To ensure the optimal ratio of the maximum number of collisions of alkane molecules with the surface of the catalyst to the pore throughput of the catalytic membrane, the following relationship between the average pore diameter d and the thickness of the catalytic membrane δ is maintained:

The physical meaning of this condition corresponds to the fact that when moving in the pores of the catalytic membrane, each alkane molecule should be able to collide with the catalyst more than 10 ³ times.

In order of magnitude, approximately this number of collisions is experienced by an alkane molecule when moving through a layer of bulk granular catalyst with a granule size of 2-3 mm and a layer height of about one meter.

The pore throughput of the catalytic membrane 2, which actually determines the alkane membrane reactor productivity, is very difficult to accurately calculate, but can be estimated based on the following expression [T.A. Voronchev, V.P. Sobolev. Physical fundamentals of electrovacuum technology. From VSh, M., 1967]:

Here

d is the effective pore diameter of the catalytic membrane, m;

S is the effective total cross-section of through radial pores per m ² ;

p ₂ and p ₁ - alkane pressure at the inlet to the reactor and at the exit of the reactor, Pa;

η is the viscosity of the hydrocarbon gas, N s / m ² ;

δ is the membrane thickness (i.e., approximately the pore length), m.

The calculated values of the throughput of the catalytic membrane with parameters (d = 7 · 10 ^-6 m; n = 10 ⁶ , δ = 2 · 10 ^-3 m) for a number of light hydrocarbons at various temperatures are shown in table 1.

Table 1
The throughput (U, mol / m ² · h) of the catalytic membrane for light alkanes at various temperatures for averaged values d = 7 μm; n = 10 ⁶ , δ = 2 mm. Temperature, K Bhutan, U Propane, U Ethan U 400 615 560 513 600 554 512 439 800 490 442 353

Figure 3 shows a schematic sectional view of a section of a hydrogen membrane 3 made in the form of a pipe of porous alumina having through radial pores with a diameter of 1 to 100 μm and a wall thickness of 1 to 4 mm. Instead of alumina ceramics, any other material resistant to high temperatures in a hydrocarbon medium, hydrogen, and oxygen-containing gas can be used to make the base of the hydrogen membrane. This can be, for example, zirconium oxide, metal carbides or nitrides.

Inside the body of each section of hydrogen membranes involved in the formation of cavities, there is a recess 24, where a thermocouple 12 is placed. A resistive heater 25 is applied to their surface of the hydrogen membrane, with which the temperature of the membrane is controlled within the range of 250-600 ° C. Instead of a film heater, other heater designs (tungsten or nichrome wire) can be used that can ensure the temperature regime of the catalytic membrane.

Oval 26 schematically shows a section of a hydrogen membrane with a large increase in through radial pores, which are sealed on one side by a palladium 27 film 10–1000 nm thick. Instead of palladium films, nickel films can be used.

The method of forming thin-film palladium plugs of the pores of the hydrogen membrane is based on the following. Initially, the pore volume is filled with a fusible and leachable organic composition. Then, on one side of the membrane, the composition is washed off and a palladium metal complex is deposited on the surface. It contains a compound as a ligand, which, with a controlled change in the physicochemical characteristics of the medium and temperature, can restore the metal complex to a metal coating in the form of a thin film with a thickness of 10 ÷ 1000 nm .

Thin films and foils of palladium and nickel have a unique ability: at high temperatures they pass only one gas - hydrogen and practically do not pass other gases. This is due to the fact that H ₂ molecules on the surface of Pd and Ni catalytically decompose into atoms, which then diffuse along the lattice of these metals in the form of protons. The diffusion rate of hydrogen through thin layers of palladium (or palladium alloys) is more than 10 ⁴ times higher than for such light gases as helium and nitrogen.

The diffusion permeability of hydrogen through a palladium film depends on temperature and on the thickness of the film [S. Dashman. Scientific foundations of vacuum technology. Izd. IL, 1950, ch. 9]:

Here

T is the temperature in degrees Kelvin;

p is the partial pressure of hydrogen in the stream of light hydrocarbon, Pa;

δ is the thickness of the palladium film ("plug") covering the micropores of the membrane, m;

s is the effective cross section of one micropore, m ² ;

n is the number of micropores per m ² .

Table 2 below shows the calculated hydrogen throughput (U _H2 ) of a macroporous alumina membrane with palladium plugs in pores at the same temperatures for which the catalytic membrane throughputs for light hydrocarbons are given in Table 1. This allows you to compare the bandwidth of the catalytic and hydrogen membranes.

table 2
The dependence of hydrogen permeability on the temperature of a microporous membrane with palladium "plugs" 30 nm thick and an average pore diameter d = 17 μm. (U _H2 , mol / m ² · h) Temperature, K U _H2 , mol / m ² hour 500 178 600 632 800 3079

A comparison of the data given in tables 1 and 2 shows that in order to optimize the alkane dehydrogenation process, the temperature of the hydrogen membrane should be significantly reduced relative to the temperature of the catalytic membrane.

To realize high hydrogen permeability and ensure the appropriate level of reliability and mechanical strength of the hydrogen membrane at high temperatures, various designs of hydrogen membranes have been tested. And only those that were made of porous alumina, the through pores of which are sealed with ultrathin palladium films, showed their performance. This design allowed us to solve the main problem:

to create a mechanically strong thin-film system capable of selectively transmitting only hydrogen formed after alkane dehydrogenation at relatively low temperatures.

The production version of the membrane alkane dehydrogenation reactor may have the following dimensions: outer diameter from 0.03 m to 0.3 m or more, and a length or height from 0.3 m to 3 m.

A high-performance alkane dehydrogenation unit can be made in the form of a block of separate membrane dehydrogenation reactors parallel connected by pipelines, each of which can have the maximum possible size. Such a unit may contain up to several tens of reactors. The number of reactors used in the corresponding unit is determined by the necessary productivity and economic efficiency of production using specified gas pressures and temperatures in the reactor.

The process for producing alkenes in accordance with the present invention includes the following important steps and steps. From the tank 31, the alkane through the reducer 32 and the flow rate meter 33 is sent to the pipe system 40, where it is mixed with hydrogen, which from the tank 34 through the gearbox 35 and the flow meter 36 enters the same pipeline system 40. The gas is mixed in this way so that the volume fraction of hydrogen in the alkane corresponds to a ratio in the range of 0.1% ÷ 10%. The mixture of alkane with hydrogen is diluted with argon coming from the tank 37 through a reducer 38 and a flow meter 39, in a volume ratio of from 1: 1 to 1: 5. The gas flow in the pipeline 40 is controlled by a pressure sensor 42 and a flow rate meter 41 and sent for preheating to the recuperator 43. In the recuperator, the heat energy of the gas flows leaving the reactor 1 is used to preheat the inlet stream 40, which is then heated to 250 in the high-temperature block 43 -500 ° C and sent to the device for introducing a gas stream A ₁ into the membrane reactor 1.

In the high-temperature block, the steam passing through the pipeline 45 through the metering valve 46 is also heated to a temperature of 250-500 ° C and sent to the device B ₁ to organize the steam flow through the hydrogen collection chamber 4 of the reactor 1. The pressure and speed of the steam flow are measured by pressure sensors 50 and a flow rate meter 49. The steam entering through line 47 through the metering valve 48 and entering C ₁ into both cavities of the thermostabilizing chamber 11 of the reactor is also additionally heated in the high-temperature unit 44 to 250-500 ° C. Instead of steam, any other gas chemically inert under these conditions can be used as a heat carrier gas.

The energy for the high temperature unit 44 is supplied in the form of heat generated by electric spirals, or by heating the unit with gas burners.

The stream of heated alkane entering the first cavity of the reactor, limited by the transverse baffle 5 and sections of the catalytic 2 and hydrogen membranes 3, is forced under the action of a pressure drop between the entrance to the reactor A ₁ and the exit from the reactor A ₂ (within 5 · 10 ⁴ ÷ 5 · 10 ⁵ Pa) to seep-through radial catalytic membrane pores into the next, a second lumen and acts to make the catalytic interaction of molecular collisions alkane with a catalyst 23. As a result of this interaction occurs dehydrogenation of the alkane and n output from the pores along with an appreciable proportion of alkane and alkene increased portion of the hydrogen. In addition, due to the endothermicity of the alkane dehydrogenation process, the temperature of the catalytic membrane decreases and this is recorded by the signal of the thermocouple 13 of the catalytic membrane. This signal stimulates the appearance of an instantaneous current pulse in the resistive heater 21 of the catalytic membrane to compensate for energy losses in the dehydrogenation reaction.

During the movement of the alkane stream, together with hydrogen and alkene in the second cavity, part of the hydrogen is forced to diffuse through the palladium baffle 27 of the hydrogen membrane 3 before this stream has time to re-enter the through radial pores of the catalytic membrane 2 in order to enter the third cavity through these pores. Using thermocouples 12, mounted in the body of each section of the hydrogen membrane, control the temperature, and resistive heaters 25 regulate it and thereby control the rate of hydrogen diffusion through the palladium wall 27.

The rate of hydrogen diffusion through a palladium film exponentially depends on the temperature of the film, is inversely proportional to its thickness and proportional to the difference in partial hydrogen pressures on both sides of the film. This difference in partial pressures is ensured by the fact that a large steam stream is passed through the hydrogen collection chamber 4, which continuously carries out all the hydrogen that has appeared in the chamber 4. The steam flow rate in the hydrogen collection chamber 4 is provided at a level such that it is 5-10 times higher than the alkane flow rate through the reactor.

Further, the process is repeated until the main part of the alkane stream, which is forced to move through the cavities 4 and the pores of the catalytic membrane 2 until the exit of A ₂ from the reactor 1, turns into an alkene.

At the exit A _{2, a} stream containing alkane, alkene, argon and hydrogen is subjected to continuous or periodic mass spectral control. To do this, through the metering valve 51, a test portion is taken (continuously or periodically) from the flow and sent directly to the mass spectrometer. The main part of the flow through the pipeline 54 is directed to the separation column, after utilizing the heat energy in the recuperator 43.

The hydrogen diluted with steam after the outlet device B _{2 is} monitored by pressure sensors 55 and flow rates 56 and sent to a condensation chamber 57 where it is separated from the steam and then to a gas holder for collecting hydrogen. In the condensation chamber 57, heat energy is utilized, which is removed by steam from the hydrogen chamber, to heat the water used in the steam boiler. A mass spectral analysis of impurities in hydrogen is periodically performed through a metering valve 60. The amount of hydrogen released is monitored by a hydrogen flow rate sensor 61 after passing through the dryer 58.

The procedure for preparing membrane reactor 1 for operation and its output to the optimal alkane dehydrogenation mode is carried out according to the following procedure. Initially, the reactor 1 is purged with hot argon using a pipe 40, a recuperator 43 and a heating unit 44 while washing the hydrogen chamber 4 of the reactor with superheated steam. After reaching the set temperature in the reactor and stabilizing it within 250-500 ° C, hydrogen is added to the argon stream at a level of 1-5% by volume and with the help of heaters 25 of hydrogen membranes 3, these temperatures of hydrogen membranes are set at which all hydrogen through these hydrogen membranes deleted. This is established by mass spectral analysis and comparison of the readings of the hydrogen flow sensor at the inlet to the reactor 36 and at the outlet of the reactor 61. The next step is the gradual replacement of part of the flows of argon and hydrogen with an alkane stream. This is carried out using reducers 32, 35 and 38 and is controlled according to the readings of the flow sensors 33, 36, 39 and 61. The entire operation mode of the dehydrogenation reactor is established using a microprocessor unit, in which information is collected from all temperature meters inside and outside the reactor, flow meters and results of mass spectral analyzes obtained at the output of the products. Due to this, based on the developed algorithms and using actuators, the dehydrogenation process is carried out in the optimal mode.

Any catalytic dehydrogenation process is accompanied by a gradual poisoning of the catalyst. Therefore, the process of optimizing dehydrogenation in a membrane reactor is carried out according to a certain algorithm, which takes into account that each cavity of the membrane reactor has its own optimal dehydrogenation conditions, taking into account the possibly deeper level of dehydrogenation, when the probability of coke deposition increases significantly. Using a microprocessor-controlled selection of hydrogen from each cavity of the reactor, the poisoning of the dehydrogenation catalyst in the membrane reactor is minimized.

Pore cleaning of catalytic and hydrogen membranes from coke is carried out by blowing the membrane reactor with hot air.

To this end, air is supplied from the tank 63 through the reducer 64 and the flow rate meter 65, which through the pipe 40, the recuperator 43 and the heating unit 44 enters the inlet A _{1 of the} membrane reactor 1. At the same time, the flow of hydrogen and alkane to the pipe 40 is completely stopped. The coke burning process ends when the carbon oxides CO and CO ₂ disappear to the background level in the mass spectral samples. After that, the membrane reactor is again ready for the dehydrogenation process.

The following examples of the dehydrogenation of ethane and propane in a membrane reactor demonstrate the feasibility of the practical implementation of the claimed invention on a membrane reactor and a method for producing alkenes using this reactor.

Example 1

The production of propylene by catalytic dehydrogenation of propane in a membrane reactor is carried out according to the method described above. The normalized propane throughputs (m ³ / m ² · h) for the catalytic membrane (G) and for the hydrogen membrane (H) versus the temperature of the catalytic membrane are shown in Table 1. The temperature of the hydrogen membrane is shown in parentheses when its temperature does not coincide with the temperature catalytic membrane. The number of cavity cavities in the dehydrogenation chamber 3.

Table 3
Permeability of catalytic and hydrogen membranes at various temperatures. T, ° С 250 350 530 G 110,2 93.9 76.3 H 3.6 18.1 63, 8 (490 ° C)

A platinum catalyst is deposited in the pores of the catalytic membrane, the calculated amount of which corresponds to 3.8 g per m ^{2 of the} membrane. The equivalent thickness of the palladium film sealing the pores of the hydrogen membrane, estimated from studies of hydrogen diffusion through the hydrogen membrane, corresponded to ~ 0.09 μm.

Table 4 shows the material balance of the process for producing propylene by dehydrogenation of propane in a membrane reactor at different temperatures of the catalytic membrane.

Table 4.
The material balance of the production of propylene by catalytic dehydrogenation of propane at different temperatures of the catalytic membrane (mol / m ² · h) T ° C H ₂ C ₃ H ₆ C ₃ H ₄ Ar other substance 250 four 22 ≤1 73 - 350 10 fourteen 8 68 - 530 17 5 16 62 <1 entrance 3 23 - 74 -

Example 2

Obtaining ethylene by catalytic dehydrogenation of ethane in a membrane reactor according to the method described above.

The normalized ethane throughputs in m ³ / m ² · hour for the catalytic membrane (G) and for the hydrogen membrane (H) depending on the temperature of the catalytic membrane are shown in table 3. The temperature of the hydrogen membrane is shown in parenthesis if the temperature of the hydrogen membrane does not match with the temperature of the catalytic membrane. A layer of palladium — a rhodium catalyst — is deposited in the pores of the catalytic membrane. The calculated thickness corresponds to 11 nm. The number of cavities in the dehydrogenation chamber is 3.

Table 5
Normalized ethane throughputs (m ³ / m ² · h) for the catalytic membrane (G) and for the hydrogen membrane (H) at different temperatures of the catalytic membrane. T, ° С 230 300 375 510 G 35.3 29.6 25.0 19.8 N 3 eleven 14.5 (430) 18 (470)

Table 6 shows the material balance of the process of producing ethylene by dehydrogenation of ethane in a membrane reactor at a catalytic membrane temperature of 493 ° C. The composition of the gas flows was determined at the inlet and outlet of the reactor, including the exit of “permeate” hydrogen from the hydrogen chamber. At the inlet, the flow was heated to 270 ° С

Table 6
The material balance of the process of producing ethylene by dehydrogenation of ethane in a membrane reactor. Stream composition At the entrance, mol / hour At the exit, mol / hour Permeate. H ₂ mol / hour ethane 4.20 1.41 - ethylene - 2.79 - hydrogen 0.35 0.18 2.93 argon 14.12 14.11 -

The proposed technical solutions for the design of the membrane reactor allow creating practically optimal conditions for the process of producing alkenes by catalytic dehydrogenation of alkanes.

This result was achieved due to the fact that:

a) the maximum possible contact of alkane molecules with the surface of the catalyst is ensured;

b) an effective supply of heat to the catalytic reaction zone is implemented to compensate for the endothermic effect of the chemical process;

d) conditions have been created for shifting the equilibrium of the dehydrogenation reaction towards alkene production by effectively removing hydrogen directly from the catalytic reaction zone through a membrane that is permeable only to hydrogen and without loss of raw materials.

The process can be carried out in a system of parallel membrane reactors connected by pipelines spatially distributed both horizontally and vertically, while in each of the membrane reactors this process can be carried out independently of other reactors integrated into the system.

Claims (12)

1. A membrane alkane dehydrogenation reactor, including a hydrogen collection chamber, a system for removing hydrogen from the catalytic dehydrogenation zone to a hydrogen collection chamber, a reactor heating system, an alkane input device to the dehydrogenation chamber and a mixture of alkane and alkene from it, a buffer gas input device to the collection chamber hydrogen and withdrawal from it of a buffer gas containing hydrogen, and thermocouples inside the reactor, characterized in that it is equipped with a tubular catalytic membrane containing many through radial macropores, and the surface of which the dehydrogenation catalyst is applied, the hydrogen collection chamber has two cylindrical cavities, each of which is separated from the dehydrogenated alkane stream by membranes selectively permeable only to hydrogen, coaxially located relative to the catalytic membrane, while ensuring a sequential passage of the alkane stream through the through pores of the catalytic membrane from cavities consisting of enclosed between transverse partitions are formed on the flow path catalytic sites of the membrane and portions permeable membranes for hydrogen only. 2. The membrane reactor according to claim 1, characterized in that the catalytic membrane is made in the form of a porous tube of aluminum oxide or zirconium oxide with a thickness of 1 to 4 mm, having a diameter of through radial pores from 1 to 100 microns. 3. The membrane reactor according to claim 1, characterized in that the through radial pores of the catalytic membrane contain on their surface a dehydrogenation catalyst based on platinum group metals or 3d transition metals or their alloys, or in the form of iron, chromium or mixed oxides containing transition metal oxides. 4. The membrane reactor according to claim 1, characterized in that the average pore diameter of the catalytic membrane and its thickness must satisfy the condition: d≤0.1 · δ, where d is the average pore diameter, δ is the thickness of the membrane. 5. The membrane reactor according to claim 1. characterized in that the hydrogen-permeable membranes are made in the form of a porous tube of aluminum oxide or zirconium oxide with a wall thickness of 1 to 4 mm and a diameter of through radial pores of 1 to 100 μm, which are sealed on one side with a palladium film with a thickness of 1 up to 0.01 microns. 6. The membrane reactor according to claim 1, characterized in that the cavities consisting of sections of the catalytic membrane and sections of selectively permeable only for hydrogen membranes are limited by transverse walls so that one half of any limited section of the catalytic membrane, except the first and last, simultaneously belongs both this cavity and the previous one, and the other half belong, respectively, to both this and the subsequent cavity, while the number of cavities in the reactor cannot be less than two. 7. The membrane reactor according to claim 1, characterized in that each section of the membranes selectively permeable only for hydrogen, limited by transverse partitions, is equipped with a resistive heater and a temperature meter, allowing independent heating and temperature control in the range of 250-600 ° C. 8. The membrane reactor according to claim 1, characterized in that the catalytic membrane is equipped with a resistive heater and a temperature meter, allowing independent heating and temperature control in the range of 250-600 ° C. 9. A method of producing alkenes by catalytic dehydrogenation of alkanes in a membrane reactor containing a hydrogen collection chamber, a system for removing hydrogen from the catalytic dehydrogenation zone to a hydrogen collection chamber, a heating system for the reactor, an alkane input device to the dehydrogenation chamber and a mixture of alkane and alkene from it, a device introducing a buffer gas into the hydrogen collection chamber and withdrawing from it a buffer gas containing hydrogen, characterized in that the membrane reactor also contains a tubular catalytic membrane, representing A ceramic tube containing many through radial macropores with a dehydrogenation catalyst deposited on its surface, the hydrogen collection chamber contains two cylindrical cavities, each of which is separated from the dehydrogenated alkane stream by membranes selectively permeable to hydrogen only, which are made in the form of porous tubes arranged coaxially on both sides of the catalytic membrane, and the through pores of which are covered with a thin palladium film; To ensure conditions for the sequential passage of the alkane stream from the entrance to the reactor through the through pores of the catalytic membrane, cavities are formed in the path of the specified stream, consisting of sections of the catalytic membrane enclosed between the transverse walls and portions of membranes that are permeable only to hydrogen, and to the input device into a membrane reactor is fed a mixture of alkane, hydrogen and argon preheated to 250-500 ° C; this mixture is sent to the cavity between the catalytic membrane and two ronitsaemymi only hydrogen membranes, bounded by longitudinal partitions, whose number can not be less than two, which under the influence of a differential pressure of 5 × 10 ⁴ to 5 × 10 ⁵ Pa are forced to move from the inlet to the reactor to exit therefrom serial transfer flow from one cavity adjacent to the through pores of the catalytic membrane containing a dehydrogenation catalyst, as a result of interaction with which the obtained target product - alkene and hydrogen are selectively separated by means of permeable hydrogen-only membranes en. 10. The method of producing alkenes according to claim 9, characterized in that the catalytic membrane is heated by electric current supplied by current leads to a resistive heater of the catalytic membrane. 11. The method of producing alkenes according to claim 9, characterized in that hydrogen is removed from the catalytic reaction zone into a two-cavity hydrogen collection chamber using two hydrogen-permeable membranes, the permeability of which is controlled by controlled variation of their temperature from 250 to 600 ° C by electric heating said membranes, and hydrogen is removed from said chamber by a stream of buffer gas in the form of superheated steam, after condensation of which pure hydrogen is obtained. 12. The method of producing alkenes according to claim 9, characterized in that the alkane dehydrogenation process in the membrane reactor is controlled by a microprocessor unit, which is continuously supplied with readings of pressure sensors, temperature, composition and velocity of gas flows at the reactor inlet and outlet , as well as data on the temperature of the catalytic membrane and sites permeable to hydrogen membranes.

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