WO2023247641A1

WO2023247641A1 - Liquid-phase fixed-bed catalytic reactor

Info

Publication number: WO2023247641A1
Application number: PCT/EP2023/066842
Authority: WO
Inventors: Isabelle CHAMPON; Alban CHAPPAZ; Albin Chaise
Original assignee: Commissariat A L'energie Atomique Et Aux Energies Alternatives
Priority date: 2022-06-21
Filing date: 2023-06-21
Publication date: 2023-12-28
Also published as: FR3136684A1

Abstract

The invention relates to a liquid-phase horizontal fixed-bed catalytic reactor comprising a reactor tube (1) extending along a horizontally oriented longitudinal axis (8), which liquid-phase horizontal fixed-bed catalytic reactor comprises a reaction zone (5) extending along the longitudinal axis (8) of the reactor tube (1) configured to receive a fixed catalyst bed and a flow of the liquid reactant and of the liquid product, and a flow zone (6) through which the gaseous product flows extending along the longitudinal axis (8) of the reactor tube (1), and a porous material (7) arranged at least at the interface of the flow zone (6) and the reaction zone (5), the flow zone (6) and the reaction zone (5) being arranged parallel to one another, the flow zone (6) being stacked on top of the reaction zone (5).

Description

“Fixed bed catalytic reactor in liquid phase”

TECHNICAL FIELD OF THE INVENTION

The present invention relates to the technical field of catalytic reactors in particular using solid catalysts. The invention will find its application more particularly for the implementation of reactions in the liquid phase resulting in the formation of a gas phase, for example processes for the dehydrogenation of a liquid resulting in the formation of a gas from a ( or more) liquid reagent(s). The invention can be applied for example to dehydrogenation reactions of liquid organic hydrogen carrier type molecules (or LOHC for “Liquid Organic Hydrogen Carriers” in English) such as the dehydrogenation reaction of butanediol (BDO) to y-butyrolactone (GBL). The invention can also be applied to decarbonylation (formation of CO) and decarboxylation (formation of CO2) reactions of carboxylic acid.

STATE OF THE ART

LOHC hydrogen carriers were developed to enable the storage and transport of hydrogen within a liquid. To recover the dihydrogen, it is necessary to pass the charged carrier medium through a reactor to allow the release of gaseous dihydrogen.

We know in particular from document US 2018/0290117 a reactor allowing the dehydrogenation of a liquid vector. This tube-and-shell type reactor has a plurality of tubes arranged in an enclosure and oriented horizontally. The tubes, where the chemical reaction takes place, are semi-filled with a solid catalyst. The gas produced will be separated from the liquid vector since it will, by gravity, occupy the free space above the catalytic bed.

This reactor however has the disadvantage of being able to have a catalyst poorly distributed along each tube for example following manipulations of the reactor, but also if the catalyst is entrained by the gas during the reaction for example by a local fluidization phenomenon, this which would also have the effect of having a degradation of the catalyst. This leads to a loss of contact between the catalyst and the reagent and therefore to a drop in yield.

The aim of the present invention is to propose a solution which makes it possible to propose a reactor which makes it possible to optimize the energy and chemical yield of the process.

The other objects, characteristics and advantages of the present invention will appear on examination of the following description and the accompanying drawings. It is understood that other benefits may be incorporated.

SUMMARY OF THE INVENTION

To achieve this objective, according to one embodiment, a horizontal fixed bed catalytic reactor in the liquid phase is provided comprising a reactor tube extending along a longitudinal axis oriented horizontally comprising an inlet intended to allow the entry of a liquid reagent , an outlet intended to allow the exit of a liquid product, an evacuation intended to allow the exit of a gaseous product discharged from the liquid reagent, a reaction zone extending along the longitudinal axis of the reactor tube and configured to receive a fixed bed of catalyst and a circulation of the liquid reagent and the liquid product, a circulation zone of the discharged gaseous product extending along the longitudinal axis of the reactor tube, and a porous material arranged so as to form an interface of the circulation zone and the reaction zone, the circulation zone and the reaction zone being arranged parallel to each other, the circulation zone being stacked above the reaction zone.

Thus, the reactor according to the invention makes it possible to keep the catalyst separate from the circulation zone which is free and therefore reserved for the circulation of the gas formed by the reaction. The porous material confines the catalyst in the reaction zone. The porous material ensures physical separation of the reaction zone and the circulation zone. The catalyst is correctly distributed in the reaction zone without risk of displacement by the gas, by manipulation of the tube or by the liquid reagent or the liquid product.

The reactor according to the invention also makes it possible to resolve the problem of loss of contact between the liquid reagent and the solid catalyst since the volume of gas produced is separated by gravity.

Another aspect relates to a reactor system comprising an enclosure extending along a longitudinal axis receiving several catalytic reactors as described above, the catalytic reactors are arranged parallel to each other, their longitudinal axis arranged parallel to the longitudinal axis of the enclosure, advantageously horizontally.

BRIEF DESCRIPTION OF THE FIGURES

The aims, objects, as well as the characteristics and advantages of the invention will emerge better from the detailed description of an embodiment of the latter which is illustrated by the following accompanying drawings in which:

Figure 1 represents a longitudinal sectional view of a catalytic reactor according to a first embodiment of the invention.

Figure 2 represents a developed view of the surface of a catalytic reactor according to Figure 1.

Figure 3 represents a sectional view A-A of a catalytic reactor according to Figure 1.

Figure 4 represents a longitudinal sectional view of a catalytic reactor according to a variant of the first embodiment illustrated in Figure 1.

Figure 5 represents a longitudinal sectional view of a catalytic reactor according to a second embodiment of the invention.

Figure 6 represents a sectional view B-B of a catalytic reactor according to Figure 5.

Figure 7 represents a longitudinal sectional view of a reactor system according to the invention of tube/calender type in a reactive liquid and thermal fluid co-current configuration.

Figure 8A represents a C-C sectional view of the reactor system according to Figure 7 illustrating a cover plate at the inlet of the liquid reagent.

Figure 8B represents a sectional view D-D of the reactor system according to Figure 7 illustrating a cover plate at the outlet of the liquid product.

Figure 9 shows a developed view of the surface of a reactor system according to Figure 7. The drawings are given as examples and do not limit the invention. They constitute schematic representations of principle intended to facilitate the understanding of the invention and are not necessarily on the scale of practical applications.

DETAILED DESCRIPTION OF THE INVENTION

Before beginning a detailed review of embodiments of the invention, the following are set out as optional characteristics which may possibly be used in combination or alternatively:

In one example, the cross-sectional area of a reactor tube includes the cross-sectional area of the circulation zone and the cross-sectional area of the reaction zone.

According to one example, the cross-sectional area of the reaction zone represents a maximum of 95% of the cross-sectional area of a reactor tube, preferably 90%.

According to one example, the cross-sectional area of the reaction zone represents at least 10% of the cross-sectional area of a reactor tube, preferably 20%, preferably 50%.

According to one example, the catalyst of the fixed bed is in the solid form of granules or powder with a particle size less than one centimeter, preferably between 200pm and 5mm.

According to one example, the porous material has a pore size smaller than the particle size of the catalyst.

According to one example, the porous material has a pore size configured to allow the circulation of the gaseous product. By this we mean the circulation of the gaseous product from the reaction zone to the circulation zone.

According to one example, the inlet and the outlet are arranged respectively at a longitudinal end of the tube. Advantageously, the inlet and outlet are arranged along the longitudinal axis of the tube.

According to one example, the evacuation is arranged in the upper part of the tube, advantageously in a direction radial to the tube. Advantageously, the evacuation is arranged along an axis transverse to the longitudinal axis of the tube.

According to one example, the catalytic reactor comprises an inlet plate arranged at the inlet of the tube comprising a first opening arranged opposite the reaction zone so that the liquid reagent enters the tube through the reaction zone.

According to one example, the cross-sectional area of the first opening represents 100% of the cross-sectional area of the reaction zone.

According to one example, the catalytic reactor comprises an outlet plate arranged at the outlet of the tube comprising a second opening arranged facing the reaction zone so that the liquid product and possibly the unreacted liquid reagent exit the tube through the reaction zone.

According to one example, the cross-sectional area of the second opening represents 100% of the cross-sectional area of the reaction zone.

According to one example, the catalytic reactor comprises a porous plug, advantageously non-reactive, that is to say not containing catalyst, arranged in the reactor tube at the outlet intended to maintain the fixed bed of catalyst in the reaction zone and to allow the exit of the liquid product and possibly the unreacted liquid reagent.

According to one example, the catalytic reactor comprises retention elements arranged in contact with the porous material in the circulation zone and having an inclination with the porous material so as to capture the liquid reagent or the liquid product passing through the porous material to redirect it towards the reaction zone.

Advantageously, the retention elements 14 form an angle greater than 0° and less than 180° with the porous material 7.

Advantageously, the retention elements 14 are oriented towards the entrance 2.

Advantageously, the catalytic reactor comprises a thermal energy source configured to provide heat to the reaction zone 5.

In one example, the system includes a thermal energy source configured to provide heat to the reaction zone.

For the remainder of the description, the term 'top' and 'bottom', or their derivatives, means a quality of relative positioning of an element of the reactor or the reactor system when it is installed functionally, the 'top' being oriented away from the ground and the 'bottom ¹ being oriented towards the ground. The upper end is at the top and the lower end is at the bottom.

By vertical we mean that which is parallel to the direction of gravity given in particular by the plumb line and horizontal that which is perpendicular to the vertical. The top and bottom being vertically opposed.

By horizontal we mean that which is perpendicular to the vertical.

By transverse is meant a direction perpendicular to a longitudinal direction. A cross section is a section perpendicular to the longitudinal axis.

Upstream and downstream, entry, exit, at a given point are taken with reference to the meaning circulation of the fluid.

By a parameter "substantially equal/greater/less than" or "of the order of" a given value is meant that this parameter is equal/greater/less than the given value, to within plus or minus 10%, or even to plus or minus 5% of this value.

Fluidically connected or in fluidic connection means when a line provides a connection through or in which a fluid circulates.

By hot, cold, cooled, we mean a relative temperature compared to another point in the system.

By porosity of a material, we mean the volume not occupied by the solid matter of the material, relative to the apparent volume of the material. This volume proportion can be occupied by vacuum, gas or a liquid. This proportion is delimited by a plurality of cavities.

By “cavity” we mean a volume not occupied by the material and formed in the material. According to one example, the porosity of the material is homogeneous, that is to say that the porosity per unit of volume is substantially identical in any portion of the same determined size of the material. In the case of the invention, the porous material is not necessarily homogeneous.

By “open” porosity, we designate a complex cavity which communicates with the outside, the environment of the material. In open porosity, the cavities can have dimensions of the order of a millimeter to a few hundred nanometers.

In the context of the present invention, a porous material with so-called “open” porosity designates a material having a porosity at least partly in communication with the environment of the material. Thus a gas can pass through the open material. The porosity of the material may in particular be greater than 30%, or even 40%, or even 60%, or even 70% of the apparent volume of the material.

The porous material is understood as a material comprising pores and allowing the separation of a gas and a liquid advantageously depending on their size and possibly on the size distribution of the pores. Preferably, the porous material does not transport the gas by diffusion nor by a difference in pressure, concentration or electric potential. Porous material is not dense.

Advantageously, the catalytic reactor does not include a gas-selective membrane or a gas-permselective membrane. By selective membrane is meant a membrane having a permeability which is exercised selectively, particularly with respect to gases. More precisely, the interface formed between the circulation zone and the reaction zone does not include a gas-selective membrane or a gas-permselective membrane, the interface is formed only of porous material as described below.

The invention relates to a liquid phase horizontal fixed bed catalytic reactor. The catalytic reactor according to the invention allows the formation of a gas phase.

The catalytic reactor according to the invention is configured to receive a solid catalyst forming a catalytic bed arranged horizontally. By this we mean at least that the circulation of the liquid reagent in the reactor is intended to be oriented in a horizontal direction. The catalytic reactor according to the invention is configured to ensure the chemical reaction of a liquid reagent in contact with a catalyst to produce a gaseous product and a liquid product.

More specifically, the liquid reagent is for example a charged liquid vector intended to be discharged or also called a charged liquid carrier medium. For example, in the context of a dehydrogenation reaction, the liquid reagent is an organic hydrogen storage liquid, for example in the form of a cyclic hydrocarbon or a linear diol. The carrier medium is a hydrogen-carrying medium which is chemically bonded to it. Such a carrier medium is for example known as a liquid organic hydrogen carrier (LOHC).

The gaseous product is for example hydrogen or carbon monoxide or even carbon dioxide.

The liquid reagent also produces a liquid product. The liquid product is for example the discharged liquid vector or also called discharged liquid carrier medium.

The catalyst is for example chosen from a co-precipitated catalyst of CuO-ZnO-Al2O3 or supported metal (Cu, Co, Pt, Rh, Pd, Ru, Ni). The support can be an oxide (Al2O3, SiC>2, CeC>2, TiC>2), carbon or a composite support (AhCh-TiC^ for example).

The catalyst is advantageously in a solid form such as for example granules or powder with a particle size less than a few centimeters, preferably less than a few millimeters, and preferably between 1 pm and 5 mm, more precisely between 200 pm and 5mm. For example, the catalyst has a spherical shape, or granule, ring or compressed type and alternatively in the form of a catalyst deposited on a ceramic or aluminum monolith type structure or metal foam type (steel, aluminum).

The reactor according to the invention comprises a reactor tube 1 extending along a longitudinal axis 8. In operation, the tube 1 is arranged horizontally, that is to say that the longitudinal axis 8 of the tube 1 is oriented horizontally.

The tube 1 has a hollow profile preferably of circular section to form a cylindrical tube. However, other hollow profile shapes, for example presenting a Square, rectangular, triangular, pentagonal, hexagonal or other polygonal outline are also possible. Tube 1 can also have an oval contour.

Tube 1 includes an inlet 2 intended to allow entry of the liquid reagent, also called charged liquid vector.

The tube 1 also includes an outlet 3 intended to allow the exit of the liquid product, also called the discharged liquid vector.

The tube 1 also includes an evacuation 4 intended to allow the exit of the gaseous product, in particular discharged from the charged liquid carrier, preferably from the circulation zone 6.

Preferably, the inlet 2 and the outlet 3 are arranged at each of the ends of the tube 1. The tube 1 comprises two opposite opening ends advantageously forming respectively the inlet 2 and the outlet 3 of the reagent and/or the liquid product.

According to one embodiment, the evacuation 4 of the gaseous product is advantageously formed in the upper part of the tube 1 and preferably at one end of the tube 1 in particular at the emerging end forming the outlet 3. The tube 1 is formed of a envelope 38 which is advantageously partially open on its upper part to form the evacuation 4. The evacuation 4 is for example formed by perforations of the envelope 38 of the tube 1 or by a grid arranged in an opening formed in the envelope 38 of tube 1. The evacuation of the gaseous product is carried out by the evacuation 4 at the upper periphery 41 of one end of the tube 1. Preferably, the evacuation 4 is formed on a sector of the envelope 38 called upper 41, because it does not extend not below a median plane intersecting the section of tube 1 in the middle. The evacuation of the gaseous product is advantageously done in a radial direction 9 to the tube 1, more precisely the radial direction 9 is perpendicular to the longitudinal axis 8 of the tube 1.

According to the invention, the tube 1 comprises a reaction zone 5 intended to receive the catalytic bed. The reaction zone 5 extends into the tube 1. Preferably, the tube 1 comprises an envelope 38 defining an interior volume 39 in which the reaction zone 5 is arranged. Advantageously, the reaction zone 5 extends in one direction parallel to the longitudinal axis 8 of the tube 1. The reaction zone 5 extends between the inlet 2 of the liquid reagent and the outlet 3 of the liquid product. The reaction zone 5 is advantageously also configured to allow the circulation of the liquid reagent and the liquid product. This arrangement ensures optimal contact between the catalyst and the liquid reagent. The reaction zone 5 is configured to prevent the liquid reagent then the liquid product from passing into the circulation zone 6 of the tube 1. Advantageously, the size of the pores of the porous material 7 described below is smaller than the particle size of the catalyst, the Passing the liquid reagent then the liquid product from the reaction zone 5 to the circulation zone 6 would result in a pressure loss which does not favor said passage.

The reaction zone 5 advantageously rests on the lower part 40 of the tube 1. The catalyst being solid, it is placed at the bottom of the interior volume 39 of the tube 1 and rests on the lower part 40 of the envelope 38 of the tube 1.

The tube 1 also includes a circulation zone 6 of the gaseous product. The circulation zone 6 extends in the tube 1, that is to say in the interior volume 39 defined by the envelope 38 of the tube 1. Advantageously, the circulation zone 6 extends in a direction parallel to the longitudinal axis 8 of the tube 1.

Preferably, the circulation zone 6 is advantageously formed in the upper part 41 of the tube 1. Thus, the gas produced or discharged from the liquid reagent rises by gravity in the upper part 41 of the tube 1. The circulation zone 6 is advantageously empty, that is to say, it does not include a catalyst or solid material ensuring free circulation of the gas produced. The circulation zone 6 is advantageously free of catalyst or porous material 7.

The circulation zone 6 advantageously extends to the evacuation 4 and preferably from the end of the tube 1 forming the inlet 2 of the liquid reagent.

The circulation zone 6 and the reaction zone 5 are advantageously arranged parallel to each other. Advantageously, the circulation zone 6 is stacked above the reaction zone 5.

According to the invention, the tube 1 comprises a porous material 7 arranged in the interior volume 39 to at least form an interface between the reaction zone 5 and the circulation zone 6.

The porous material 7 makes it possible to physically separate the reaction zone 5 comprising the catalyst from the circulation zone 6 of the gas.

The catalyst is confined in the reaction zone 5 without risk of being displaced during the movement of the reactor or during the circulation of fluids (liquid and gas) in tube 1.

Advantageously, the porous material 7 is configured to be impermeable to the catalyst. The porous material 7 has a pore size smaller than the particle size of the catalyst.

Preferably, the porous material 7 has open porosity allowing the circulation of the gaseous product. The porous material 7 is advantageously permeable to the gaseous product, more specifically, to dihydrogen, and/or to carbon monoxide and/or to carbon dioxide. According to a preferred possibility, the porous material 7 is configured to also contain in the reaction zone 5, the liquid reagent and the liquid product. Advantageously, the size of the pores of the porous material 7 being smaller than the particle size of the catalyst, the passage of the liquid reagent then of the liquid product from the reaction zone 5 to the circulation zone 6 is not favored in that this passage would cause a loss of charge. This arrangement advantageously allows the liquid reagent circulating in the reaction zone 5 not to be diverted towards the circulation zone 6, that is to say does not “by-pass” the reaction zone 5 in favor of the circulation zone. 6. This configuration thus ensures optimal contact between the catalyst and the liquid reagent.

For example, the porous material has a pore size of a dimension greater than a few tens of nanometers and less than 1 millimeter, preferably less than 200 micrometers, more precisely less than 100 micrometers, more precisely less than 50 micrometers.

For example, the porous material has a pore size one dimension larger than the equivalent diameter of most gas molecules. The equivalent diameter of most gases being of the order of a few Angstrom (10' ¹ ° m), the pore size is greater than 10 nm and for example greater than a micrometer.

The gaseous product, for example dihydrogen H2, is separated from the liquid phase, that is to say from the liquid reactant and the liquid product by gravity and passes physically through the porous material 7 since the diffusion of the gaseous product and in particular of hydrogen is quick and easy due to the size of the molecule. It is not necessary to impose a pressure difference on either side of the porous material 7 so that the gas is separated from the reaction zone 5.

According to a first embodiment, the porous material 7 only forms the interface between the reaction zone 5 and the circulation zone 6. The interior volume 39 of the tube 1 comprises from bottom to top, the reaction zone 5 advantageously comprising the catalytic bed, then the porous material 7, then the circulation zone 6.

According to one possibility, the catalytic bed is formed by the catalyst in solid form as described above filling the volume of the reaction zone 5. According to this possibility, the porous material 7 is configured to have a pore size less than the particle size of the catalyst so as to maintain the catalyst in the reaction zone 5.

According to another possibility, the catalytic bed is formed by the catalyst deposited on a solid structure 43 filling the volume of the reaction zone 5.

The solid structure 43 is for example of the monolith type in ceramic or aluminum or metal foam in steel or aluminum. According to this possibility, the porous material 7 is configured to have a pore size smaller than the open porosity of the solid structure 43 receiving the catalyst.

The porous material 7 forms an upper interface 42 with the circulation zone 6 and advantageously a lower interface 44 with the reaction zone 5.

For example, the porous material 7 can be a structured packing such as blocks adjusted to the interior volume 39 of the tube 1, plates, sheets or meshes, or an unstructured packing of the Raschig ring type made of ceramic material in stoneware or porcelain, or steel, or Berl or Intalox® saddle type in ceramic. The porous material 7 can also be a metal foam made of steel, titanium or aluminum or a PORAL® type sintered metal made of steel, nickel or bronze. According to one possibility, the porous material 7 and the solid structure 43 are of the same nature, but preferably have different pore sizes so that the size of the pores of the porous material 7 is less than the size of the pores of the solid structure 43.

The upper interface 42 of the porous material 7 with the circulation zone 6 is for example flat and extending advantageously along the longitudinal axis 8 of the tube 1. According to variants, the upper interface 42 and/or the lower interface 434 may have various shapes, for example sinusoidal, square, triangular or sawtooth. This arrangement makes it possible to modulate the thickness of catalyst in reaction zone 5.

The porous material 7 is held in the interior volume 39 of the tube 1 by fixing means such as for example cleats, which can be welded or screwed in particular at the inlet 2 and outlet 3 of tube 1. Typically, at least two cleats hold the porous material 7 on either side of its width at the inlet 2 and at least two cleats hold the porous material 7 on either side of its width at the tube outlet 3. Ideally the porous material 7 is held between four cleats on either side of its width and its height at inlet 2 and four cleats on either side of its width and its height at outlet 3.

The mass of catalyst loaded into tube 1 is a function of the desired productivity at the reactor outlet.

Preferably, tube 1 is partially filled with catalyst. More precisely, the reaction zone 5 does not fill the entire interior volume 39 of the tube 1. Preferably, the cross-sectional surface of the tube 1 is composed of the surface 19 in cross-section of the circulation zone 6, of the surface in cross section of the porous material 7 and possibly of the surface 18 in cross section of the reaction zone 5 if the porous material 7 is limited to the interface 42 between the circulation zone 6 and the reaction zone 5, as in Figure 3 . Advantageously, the cross-sectional area 18 of the reaction zone 5 represents a maximum of 95% of the cross-sectional area of the tube 1, preferably 90%, preferably 80%, preferably 70%, preferably 60%, preferably 50%.

Advantageously, the cross-sectional area 18 of the reaction zone 5 represents a minimum of 10% of the cross-sectional area of the tube 1, preferably 20%, preferably 30%, preferably 40%, preferably 5%, preferably 50%.

Depending on the embodiment, the cross-sectional area of the porous material 7 represents of the order of 2% to 35% of the cross-sectional area of the tube 1 as illustrated in Figure 3.

Advantageously, the cross-sectional area 19 of the circulation zone 6 represents a maximum of 40% of the cross-sectional area of the tube 1, preferably 30%, preferably 20%, preferably 10%, preferably 5%.

Advantageously, the cross-sectional area 19 of the circulation zone 6 represents a minimum of 5% of the cross-sectional area of the tube 1, preferably 10%, preferably 20%, preferably 30%, preferably 35%, preferably 40%.

The tube 1 comprises, according to one embodiment, retention elements 14. The retention elements 14 are advantageously arranged in the circulation zone 6. Preferably, the retention elements 14 extend from the porous material 7 into the circulation zone 6. More precisely, the retention elements 14 are peaks or plates in contact with the porous material 7, more precisely at the upper interface 42 of the porous material 7. The retention elements 14 advantageously form an angle with the upper interface 42 between 0° and 180° and preferably different from 0° and 180° and preferably 90°, that is to say greater than 0° and less than 90° or greater than 90° and less than 180°. The retention element 14 extends in a direction comprising a direction perpendicular to the longitudinal axis 8 of the tube 1 and a direction parallel to the longitudinal axis 8 of the tube 1. Preferably, the perpendicular direction is oriented in the zone of circulation 6. As an example illustrated in Figures 1, 4, 5, 7, the retention elements 14 are oriented towards the entrance 2.

The retention elements 14 are configured so as not to obstruct the porosity of the porous material 7 and to allow the circulation of the gaseous product by gravity and the circulation of the gaseous product in the circulation zone 6. The retention elements 14 are for example placed along the longitudinal axis 8 of the tube 1, above the porous material 7 and make it possible to prevent the entrainment of the liquid phase, the liquid reagent and/or the product. liquid by the gaseous product. The liquid phase possibly carried away with the gaseous product is blocked by the retention elements 14 and returns to the reaction zone 5 by flow along the retention means 14.

The reactor according to the invention advantageously comprises an inlet plate 10 arranged at one end of the tube 1 forming the inlet 2 of the liquid reagent. The entrance plate

10 comprises a first opening 11 arranged facing the reaction zone 5. Preferably, the first opening 11 has a cross-sectional surface of the order of the cross-sectional surface of the reaction zone 5. The first opening 11 corresponds in shape and surface in cross section to the shape and surface of the reaction zone 5 in cross section. The first opening section

11 in cross section corresponds to the section of the reaction zone 5 in cross section. This inlet plate 10 and its first opening 11 make it possible to direct the liquid reagent into the reaction zone 5.

This configuration makes it possible to limit the risks that the liquid reagent passes above the reaction zone 5 into the circulation zone 6 which presents fewer constraints, and therefore that a quantity of the liquid reagent is heated, but does not react, because it is not in contact with the catalyst. This arrangement therefore optimizes the energy and chemical efficiency of the process and the device.

In this embodiment, the porous plug 15 arranged at the end of the tube 1 forming the inlet 2 cooperates for example with the first opening 11.

The reactor according to the invention advantageously comprises an outlet plate 12 arranged at one end of the tube 1 forming the outlet 3 of the liquid reagent. The exit plate

12 comprises a second opening 13 arranged facing the reaction zone 5. Preferably, the second opening 13 has a cross-sectional surface of the order of the cross-sectional surface of the reaction zone 5. The second opening 13 corresponds in shape and surface in cross section to the shape and surface of the reaction zone 5 in cross section. The section of the second opening 13 in cross section corresponds to the section of the reaction zone 5 in cross section. This outlet plate 12 and its second opening 13 make it possible to evacuate the liquid product and possibly the unreacted liquid reagent from the reaction zone 5.

According to one possibility, the first opening 11 and the second opening 13 are identical. Preferably, the input plate 10 and the output plate 12 are identical as for example illustrated in Figures 7, 8a and 8b.

The tube 1 advantageously comprises a porous plug 15. The porous plug 15 is arranged in the tube 1 at the end forming the outlet 3 of the liquid product and possibly the unreacted liquid reagent. The porous plug 15 is arranged in the reaction zone 5. Preferably, the porous plug 15 is not reactive, that is to say that the porous plug 15 does not include a catalyst. Advantageously, the porous plug 15 is arranged in the reaction zone 5 facing the outlet 4 formed in the upper part of the tube 1. The porous plug 15 has the function of maintaining the catalytic bed in the reaction zone 5. The plug porous 15 is impermeable to the catalyst. The porous plug is configured to allow the liquid phase comprising the liquid product and possibly the unreacted liquid reagent to pass. The porous plug is for example made of sintered porous material (i.e. steel, nickel or bronze of the PORAL® type, etc.). The porous plug 15 has a pore size smaller than the particle size of the catalyst which it must maintain in the reaction zone 5. Following the example of sintered metals such as PORAL®, this pore size can be between 3 pm and 50 p.m. According to one possibility, the porous plug 15 is made of the same material as the porous material 7.

According to one embodiment, the tube 1 comprises a porous plug 15 arranged in the tube 1 or partially or completely outside the tube 1 at the end forming the inlet 2 of the liquid reagent. The porous plug 15 is advantageously identical to what is described for the porous plug 15 arranged at outlet 3.

According to a preferred embodiment, the liquid reagent and the gaseous product circulate in the tube 1 in co-current, that is to say in the same direction. According to this embodiment, the evacuation 4 and the outlet 3 are advantageously arranged at the same end of the tube 1, opposite the end receiving the inlet 2.

The reactor according to the invention is intended in particular to enable endothermic reactions. For this purpose, the tube 1 can be placed in an oven ensuring the supply of thermal energy necessary for the endothermic reaction to take place. According to another possibility, the reactor comprises a heat source intended to provide the thermal energy necessary for the reaction to take place. For example, the reactor comprises heating elements 17 which may be electrical, arranged for example in contact with the tube 1, in particular outside the envelope 38 of the tube 1, as illustrated in Figure 4. The heating elements 17 can also be arranged in conduction of the porous material 7 and/or the solid structure maintaining the catalyst in the reaction zone 5, especially if it is a metal foam or a thermally conductive material.

According to an alternative, the reactor comprises an annular tube receiving the tube 1 configured to ensure circulation of a thermal fluid in the annular space formed between the annular tube and the tube 1. Coupling with an exothermic reaction can also be envisaged.

According to one aspect, the invention relates to a reactor system comprising an enclosure 20 extending along a longitudinal axis 32. The enclosure 20 is configured to receive a plurality of catalytic reactors as described above. The catalytic reactors are arranged parallel to each other, the longitudinal axis 8 of each reactor tube 1 being parallel to the longitudinal axis 32 of the enclosure 20. Advantageously, the reactor system is configured so that in operation the The longitudinal axis 32 of the enclosure 20 is horizontal.

The reactor system is advantageously of the tube/calender type.

According to one possibility, all the tubes 1 have an identical configuration. The tubes 1 are for example shaped into cylindrical tubes. It is also conceivable that the tubes 1 are configured differently, in particular with a different contour and/or with different cross sections.

Advantageously, in the reactor system according to the invention the inlet plate 10 is advantageously shared for all the tubes 1. Thus, the reactor system comprises an inlet plate 10 provided with several first openings 11 arranged facing each reaction zone 5 of each tube 1. The inlet plate 10 advantageously has a cross-sectional area substantially equal to the cross-sectional area of the enclosure 20.

Advantageously, in the reactor system according to the invention the outlet plate 12 is advantageously shared for all the tubes 1. Thus, the reactor system comprises an outlet plate 12 provided with several second openings 13 arranged facing each zone of reaction 5 of each tube 1. The outlet plate 12 advantageously has a cross-sectional area substantially equal to the cross-sectional area of the enclosure 20.

The enclosure 20 advantageously comprises a supply of the liquid reagent 29, a withdrawal of a gaseous product 30 and a withdrawal 31 of a liquid product and possibly the unreacted liquid reagent. For example, the power supply 29 is done through the upper part of the enclosure 20 as illustrated in Figure 7 or it is done through the lower part of the enclosure.

According to one embodiment, the enclosure 20 comprises a distribution rod 33 arranged in fluid connection between the supply 29 and the inlet 2 of each tube 1 to supply each tube 1 with liquid reagent.

According to one embodiment, the enclosure 20 comprises a rod 36 for recovering the liquid product, and possibly the unreacted liquid reagent, arranged in fluid connection between the outlet 3 of each tube 1 and the withdrawal 31.

According to one embodiment, the enclosure 20 comprises a rod for withdrawing the gaseous product arranged in fluid connection between the evacuation 4 of each tube 1 and the withdrawal 30, as illustrated in Figure 7.

According to one possibility, the reactor system comprises a thermal energy source configured to provide heat to the reaction zones 5. Preferably, the thermal energy source is a thermal fluid or heat transfer fluid. The reactor system is configured so that the thermal fluid circulates in the enclosure 20 around the tubes 1. The thermal fluid circulates in a space intermediate to the tubes 1. The enclosure 20 includes a supply 27 of the thermal fluid in the enclosure 20 and an evacuation 28 of the thermal fluid outside the enclosure 20. The thermal fluid makes it possible to transfer heat to the liquid reagent. For example, the supply 27 and evacuation 28 of the thermal fluid are done through the upper part of the enclosure 20 as illustrated in Figures 7, 9.

The heat transfer fluid can circulate in co-current or counter-current to the direction of circulation of the liquid reagent. We mean co-current if the thermal fluid and the liquid reagent circulate in the same direction and we mean counter-current if the thermal fluid and the liquid reagent circulate in an opposite direction.

Advantageously, the system includes baffles 34 allowing the thermal fluid to snake along the tubes 1.

According to one possibility, the reactor system comprises a plenum 22 and/or a plenum 23. The plenum22 and the plenum23 are arranged at the longitudinal ends of the enclosure 20.

The reactor system comprises a plurality of flanges 24, 25, 26 making it possible to assemble the different parts of the system.

The length of the tube 1 is greater than the length of the circulation zone of the thermal fluid, that is to say the length between the supply 27 and the evacuation 28 of the thermal fluid in the enclosure 20. In fact , the evacuation 4 of the gas produced is formed over a length I of the tube 1. Advantageously, the reaction zone 5 comprises the porous plug 15 extending over a length I arranged opposite the evacuation zone 4. This arrangement makes it possible to maintain the catalyst in the reaction zone 5 heated by the circulation of the thermal fluid.

During operation, the liquid reagent is injected into the tube 1 through the inlet 2 at the reaction zone 5. Preferably, the pressure in the reaction zone 5 is between 0 and 20 absolute bars, preferably between 1 and 5 bars absolute, preferably the pressure of the reaction zone 5 is identical to the pressure of the circulation zone. Preferably, the temperature in the reaction zone 5 is lower than the vaporization temperature of the liquid reagents and products and preferably higher than 80°C.

Advantageously, the flow rate of the liquid reagent at inlet 2 of tube 1 is non-zero and less than 500l/min, preferably between 0.5 and 20l/min. The liquid product and possibly the unreacted liquid reagent exit tube 1 through outlet 3 at the reaction zone 5. The gaseous product is physically separated from the liquid all along the tube 1 and is evacuated through the evacuation 4.

Example

A reactor system according to the invention can be implemented in the context of the dehydrogenation of a LOHC. For example, 1,4-butanediol (BDO) can be dehydrogenated into gamma-butyrolactone (GBL) in order to release 2 moles of H2 between 150 and 220 °C and 1 and 5 bars.

In the case of a catalytic reactor comprising a single reactor tube 1 comprising a reaction zone 5 corresponding to a half-tube and a circulation zone 6 corresponding to a half-tube separated lengthwise by a porous material 7 of metal foam type adjusted to the section of tube 1 and of pore size smaller than the particle size of the catalyst. This porous material 7 is held in the tube 1 by four tabs at the inlet 2 of the tube 1 and four tabs at the outlet 3 of the tube 1.

The reaction zone 5 is filled with a solid catalyst suitable for carrying out the BDO dehydrogenation reaction, for example a co-precipitated CuO-ZnO-Al2O3 catalyst. The catalyst is in the form of granules. These granules are confined in the reaction zone 5 thanks to the porous material 7 of the metal foam type.

A circulation of a thermal fluid in an annular tube to tube 1 makes it possible to provide the heat of reaction.

Preferably, after reduction of the catalyst, under typical H ₂ /Ar conditions at 300°C for several hours, the temperature of the catalytic reactor is lowered to 180°C under an inert flow in order to purge the hydrogen used during the reduction. of the catalyst.

Preferably, the reaction is carried out at atmospheric pressure.

The liquid BDO charged with hydrogen is supplied by a power supply 29 which serves the reaction zone 5 of the tube 1 thanks to an inlet plate 10 in which a first opening 11 in the form of a half-tube which can advantageously be provided with a porous inlet plug of sintered porous type makes it possible to preferentially supply the reaction zone 5 of tube 1.

On contact with the solid catalyst, BDO (liquid) is converted into GBL (liquid) and H2 (gas). The hydrogen formed during the dehydrogenation reaction is physically separated from the liquid by gravity over the entire length of tube 1. Thus, it migrates by gravity, into the circulation zone 6, without catalyst, where it can circulate freely. In this way, the formation of the gas phase does not result in a loss of contact between the liquid reagent and the solid catalyst.

The hydrogen formed is recovered in a collection chamber via an evacuation 4 formed at the upper periphery of the tube. A withdrawal 30 preferably located in the upper part of the enclosure makes it possible to recover the gas formed. An outlet plate 12 identical to the inlet plate 10, with a second opening 13 in the form of a half-tube provided with a porous plug 15, for example a sintered porous one, makes it possible to recover the liquid coming from the tube 1. A liquid withdrawal rod 36 makes it possible to convey the liquid to the withdrawal 31.

The invention is not limited to the embodiments previously described and extends to all the embodiments covered by the invention.

LIST OF REFERENCES charged carrier discharged carrier azous carrier liquid medium sversale of the reaction zoneversale of the circulation zone hermic ermic charged carrier liquid uit discharged carrier fluid reactor tem u charged carrier liquid medium 34. Chicane

35. Thermal fluid circulation zone

36. Rod for recovering the discharged carrier liquid medium

38. Envelope 39. Interior volume

40. Lower part

41. Upper part

42. Superior interface

43. Solid structure 44. Bottom interface

Claims

1. Liquid phase horizontal fixed bed catalytic reactor comprising a reactor tube (1) extending along a longitudinal axis (8) oriented horizontally comprising: i. An inlet (2) intended to allow entry of a liquid reagent, ii. An outlet (3) intended to allow the exit of a liquid product and possibly unreacted liquid reagent, iii. An evacuation (4) intended to allow the exit of a gaseous product, iv. A reaction zone (5) extending along the longitudinal axis (8) of the reactor tube (1) and configured to receive a fixed bed of catalyst and a circulation of the liquid reactant and a liquid product, v. A circulation zone (6) of the gaseous product extending along the longitudinal axis (8) of the reactor tube (1), the circulation zone and the reaction zone being arranged parallel to each other , the circulation zone being stacked above the reaction zone; characterized in that the reactor comprises a porous material (7) extending along the longitudinal axis (8) of the tube 1 and arranged in the tube (1) to form an interface between the circulation zone (6) and the zone reaction (5).

2. Catalytic reactor according to the preceding claim wherein the cross-sectional surface of a reactor tube (1) comprises a surface (19) in cross-section of the circulation zone (6) and a surface (18) in cross-section of the reaction zone (5).

3. Catalytic reactor according to any one of the preceding claims wherein the cross-sectional area (18) of the reaction zone (5) represents a maximum of 95% of the cross-sectional area of a reactor tube (1). , preferably 90%.

4. Catalytic reactor according to any one of the preceding claims wherein the cross-sectional area (18) of the reaction zone (5) represents at least 10% of the cross-sectional area of a reactor tube (1). , preferably 20%, preferably 50%.

5. Catalytic reactor according to any one of the preceding claims in which the catalyst of the fixed bed is in solid form of granules or powder with a particle size less than one centimeter, preferably between 200pm and 5mm.

6. Catalytic reactor according to the preceding claim in which the porous material (7) has a pore size smaller than the particle size of the catalyst.

7. Catalytic reactor according to any one of the preceding claims in which the porous material (7) has a pore size configured to allow the circulation of the gaseous product.

8. Catalytic reactor according to any one of the preceding claims not comprising a gas-selective membrane.

9. Catalytic reactor according to any one of the preceding claims in which the inlet (2) and the outlet (3) are arranged respectively at a longitudinal end of the tube (1).

10. Catalytic reactor according to any one of the preceding claims in which the discharge (4) is arranged in the upper part of the tube (1), in a radial direction (9) to the tube.

11. Catalytic reactor according to any one of the preceding claims comprising an inlet plate (10) arranged at the inlet (2) of the tube comprising a first opening (11) arranged facing the reaction zone (5) so that the reagent Liquid enters tube (1) through the reaction zone (5).

12. Catalytic reactor according to the preceding claim wherein the cross-sectional area of the first opening (11) represents 100% of the cross-sectional area (18) of the reaction zone (5).

13. Catalytic reactor according to any one of the preceding claims comprising an outlet plate (12) arranged at the outlet (3) of the tube comprising a second opening (13) arranged facing the reaction zone (5) so that the liquid product and possibly the unreacted liquid reagent leaves the tube (1) through the reaction zone (5).

14. Catalytic reactor according to the preceding claim wherein the cross-sectional area of the second opening (13) represents 100% of the cross-sectional area (18) of the reaction zone (5).

15. Catalytic reactor according to any one of the preceding claims comprising a porous plug (15) arranged in the reactor tube (1) at the outlet (3) intended to maintain the fixed bed of catalyst in the reaction zone (5) and to allow the exit of the liquid product and possibly the unreacted liquid reagent.

16. Catalytic reactor according to any one of the preceding claims comprising retention elements (14) arranged in contact with the porous material (7) in the circulation zone (6) and having an inclination with the porous material (7) of so as to capture the liquid reagent or the liquid product passing through the porous material (7) to redirect it towards the reaction zone (5).

17. Reactor system comprising an enclosure (20) extending along a longitudinal axis (32) receiving several catalytic reactors according to any one of the preceding claims, the catalytic reactors are arranged parallel to each other, their longitudinal axis (8 ) arranged parallel to the longitudinal axis (32) of the enclosure (20), advantageously horizontally.

18. System according to the preceding claim comprising a thermal energy source configured to provide heat to the reaction zone (5).