FR3083994A1 - LOAD DISTRIBUTOR FOR AXIAL FLOW REACTOR - Google Patents

Abstract

The invention relates to the field of charge distribution means within a catalytic reactor such as hydrotreatment reactors with axial flow. In particular, the present invention describes a distributor for the introduction of liquid or gaseous hydrocarbon feedstock within a catalytic reactor with axial flow of the incoming fluid or fluids. This distributor comprises an external wall (2) having a frustoconical lower section and a cylindrical upper section, a central wall (5) frustoconical, N internal walls (3, 4) coaxial frustoconical of increasing diameters.

Description

TECHNICAL AREA

The invention relates to the field of charge distribution means within a catalytic reactor such as hydrotreatment reactors with axial flow. In particular, the present invention describes a distributor for the introduction of liquid or gaseous hydrocarbon feedstock within a catalytic reactor with axial flow of the incoming fluid or fluids.

PRIOR ART

One of the problems posed by catalytic hydrotreatment in an axial fixed bed is the homogeneous distribution of the charge at the head of each reactor. In the case of a single-phase load, local overspeeds cause the particle bed to rise, which can lead to the formation of fine particles, fouling of the bed and therefore an increase in the pressure drop of the bed and distribution problems and then the premature shutdown of the reactor.

Similarly, if the load is two-phase, a distributor plate is placed above the catalyst bed. The pre-distribution is important insofar as the disturbance of the liquid level on the plate leads to an imbalance of the distribution at the level of the catalyst bed.

Distribution problems are mentioned in the literature (ind. Eng. Chem. Res. 2WH, 46, 6164-6182).

Several distributor or input distributor systems have been proposed (for example US3007779, US4938422, US2017113199, US2017157584, US2017157588). All these systems lead to high lateral fluid velocities and are accompanied by lifting of the particles on the surface of the catalytic bed and lead to distribution problems.

To overcome these limits, the present invention describes a distributor for an axial flow catalytic reactor composed of several walls with a frustoconical section.

Another object of the invention relates to an upward or downward axial flow reactor comprising said distributor at the inlet pipe of a liquid and / or gaseous hydrocarbon feedstock.

An advantage of the present invention is to allow a homogeneous charge distribution on the surface of the catalytic bed.

Advantageously, the distributor according to the invention can be implemented in new reactors as in existing reactors with a few modifications (lines, valves, reactor internals, distributors, etc.).

SUMMARY OF THE INVENTION

An object of the present invention is to provide a gas or liquid distributor for an axial flow reactor comprising:

- An outer wall comprising a frustoconical lower section extending by a cylindrical upper section;

- a central wall positioned inside the external wall and comprising a frustoconical section;

- N internal walls (3, 4) positioned around the central wall, and between the external wall and said central wall, said internal walls each comprising a frustoconical lower section of increasing diameter relative to the diameter of the frustoconical section of the central wall , in which

- For each external, central and internal wall, the diameter of the base of the frustoconical section is greater than the diameter of the top of said frustoconical section;

- The base of the frustoconical section of each external, central and internal wall is positioned on the same plane;

- N is between 1 and 40.

PRESENTATION OF THE FIGURES

To facilitate understanding of the invention, the figures use the same nomenclature for the elements common between the various embodiments of the distributor according to the invention.

Figures 1 to 5 show particular embodiments, the figures are subdivided into 5 parts denoted A, B, C, D, E. Part A) corresponds to the distributor. Part B) corresponds to the outer wall. Parts C) and D) correspond to the internal walls and part E corresponds to the central wall.

Figure 1 illustrates a particular embodiment of a distributor, and the different walls constituting it. FIG. 1A illustrates a distributor 1 according to the invention comprising an external wall 2 with two internal walls 3 and 4, a central wall 5 and means 6 for securing the walls such as crosspieces. In FIG. 1A, the internal walls 3, 4 and the central wall 5 are represented by dotted lines because they are located inside the external wall 2. FIG. 1B represents the external wall 2, in particular the frustoconical section 2a and the cylindrical section 2b, in which the frustoconical section has an angle a, denoted 2c, with the axis parallel to the cylindrical section. Figures IC, and 1D show, respectively, the internal walls 3 and 4 made up of a frustoconical section 3a and 4a. Each of the frustoconical sections 3a and 4a has an angle an angle a, denoted 3c and 4c respectively, with the axis parallel to the cylindrical section 2b represented by a dotted line. Similarly, Figure 1E shows the central wall 5 consisting of a frustoconical section 5a having an angle a, denoted 5c, with the axis parallel to the cylindrical section 2b represented by a dotted line. In this embodiment, the frustoconical sections all have the same height.

FIG. 2 illustrates another embodiment of a distributor according to the invention, in which each of the frustoconical sections 2a, 3a, 4a and 5a have a height, denoted h-2a, h-3a, h-4a and h-5a respectively , different. In this embodiment, the heights of the frustoconical sections are increasing in the direction from the central wall towards the external wall (h-5a <h-4a <h-3a <h-2a).

FIG. 3 illustrates an embodiment in which the heights of the frustoconical sections are decreasing in the direction from the central wall towards the external wall (h-5a> h-4a> h-3a> h-2a).

Figure 4 illustrates an embodiment which differs from that of Figure 1 in that the internal frustoconical walls 3a and 4a and central 5a each extend by a cylindrical wall 3b, 4b and 5b. The heights of the frustoconical sections are identical and the heights of the cylindrical sections are identical. In this embodiment, the distributor further comprises securing elements 6 of the cylindrical sections.

FIG. 5 illustrates a distributor according to the invention, in which the heights of the frustoconical sections are decreasing in the direction of the external wall towards the central wall and all the frustoconical sections are extended by a cylindrical section denoted 2b, 2b, 4b and 5b respectively. In addition, the central wall, at the junction 5d of the frustoconical section and the cylindrical section, is partially obstructed in order to reduce the diameter of said junction 5d relative to the diameter of the cylinder. In addition, in this embodiment, the internal and central walls comprise, at the ends of the frustoconical and cylindrical sections, elements 6 allowing the assembly and the joining of the various walls in a distributor. The external wall 2 has at its cylindrical end two elements 7 allowing the positioning and the assembly of the distributor within a reactor.

FIG. 6 illustrates a fixed-flow axial flow reactor equipped with a distributor 1. The casing 11 of the reactor of diameter d-11 is similar to a conventional shell of a hydrotreatment reactor with downdraft gas and liquid. The bottoms can be elliptical or hemispherical. The upper bottom has an opening 12 of diameter d-12 which can either be directly connected to an inlet tube 15 of diameter d-15 equal to d-12 (variant not shown), or has a reduction 14 of diameter d -14 so as to connect the inlet pipe 15 of diameter d-15 to the reduction 14, in the latter case d-15 is equal to d-14 and less than d-12. The inlet pipe 15 allows the entry of gaseous and liquid fluids into the reactor via the distributor 1 which is mounted on the reduction 14 or mounted directly on the opening 12 (variant not shown). The lower bottom comprises an outlet pipe 13 of diameter d-13, allowing the outlet of the fluids, and is generally equipped with an outlet collector (“outlet collector” according to English terminology) not shown. The casing 11 can be fitted with internals not shown, it comprises at least one bed of catalysts 16.

DETAILED DESCRIPTION OF THE INVENTION

It is specified that, throughout this description, the expression "comprised between ... and ..." must be understood as including the limits cited.

In the following description, the terms "lower" and "upper" are considered for the distributor positioned vertically in a reactor.

Furthermore, the term "external" defines the outermost element, the term "central" denotes the innermost element, and the term "internal" denotes an element situated between an external element and a central element.

In the sense of the present invention, the various embodiments presented can be used alone or in combination with each other, without limitation of combination.

The characteristics of the invention are presented on reading the description through non-limiting embodiments of embodiments, with reference to the figures.

Distributor

The present invention therefore relates to a gas and / or liquid distributor 1 for an axial flow reactor comprising:

- An outer wall 2 comprising a frustoconical lower section 2a extending by a cylindrical upper section 2b;

- A central wall 5 positioned inside the external wall 2 and comprising a frustoconical section 5a, preferably coaxial with the frustoconical section 2a of said external wall;

- N internal walls (3, 4) positioned around the central wall, and between the external wall and said central wall, said internal walls each comprising a frustoconical lower section (3a, 4a) of increasing diameter relative to the diameter of the section frustoconical of the central wall.

in which

- For each external, central and internal wall, the diameter of the base of the frustoconical section is greater than the diameter of the apex of said frustoconical section, that is to say that the apex of said frustoconical section is directed towards the upper part of the dispatcher.

- The base of the frustoconical section of each of the external, central and internal walls is positioned on the same plane;

- N is between 1 and 40, preferably between 1 and 30, preferably between 1 and 20, preferably between 1 and 10, preferably between 8 and 8, preferably between 1 and 6, and preferably between 2 and 4 .

In other words, the distributor according to the invention advantageously comprises:

- In its upper part at least one cylindrical wall 2b, capable of receiving the fluid to be distributed,

- In its lower part, connected to the upper part, a plurality of frustoconical walls (2a, 3a, 4a, 5a) arranged one inside the other, and spaced apart from each other, these frustoconical walls allowing the distribution of the fluid.

The distributor 1 according to the invention advantageously makes it possible to obtain a homogeneous distribution of a liquid or gaseous charge on the surface of a catalytic bed, for example within an axial flow reactor. In fact, the distributor according to the invention comprises between each wall a flow zone allowing the charge to pass through said distributor, said charge being introduced by the cylindrical part of the distributor and dispersed by the frustoconical part.

Each of the frustoconical sections have a height denoted h. In a particular embodiment, the frustoconical sections have a substantially identical height. Preferably the heights are identical.

In a second embodiment, the heights of the frustoconical sections are increasing from the central wall towards the external wall such that h-5a <h-4a <h-3a <h-2a (Figure 2).

In a third embodiment, the heights of the frustoconical sections are decreasing from the central wall towards the external wall such as h-5a> h-4a> h-3a> h-2a (FIG. 3).

Each of the frustoconical sections forms an angle a with the axis formed by the wall of the cylindrical section 2b of the external wall, in other words the angle a corresponds to the half angle at the top of the frustoconical section. Preferably, from the central wall to the external wall of the distributor, the angle a of a wall is greater than or equal to the angle a of the adjacent wall. Advantageously, the angle a of any of the walls is between 1 and 80 °, preferably between 10 and 70 °, preferably between 20 and 65 °, preferably between 25 and 60 °, very preferably between 30 and 50 °.

In a particular embodiment, all of the frustoconical sections have the same angle a. This embodiment advantageously makes it possible to facilitate the mounting of the distributor.

Advantageously, the frustoconical section 5a of the central wall 5 is extended by a cylindrical section 5b.

Advantageously, at least one of the frustoconical sections of the internal walls is extended by a cylindrical section.

Preferably, when the distributor comprises at least two cylindrical sections

the apex of said sections are at the same level, that is to say that on the same plane, and

- the at least two cylindrical sections are coaxial.

In a particular embodiment, all the frustoconical sections of the distributor are extended by a cylindrical section.

Advantageously, when the distributor comprises at least two cylindrical sections, the flow entering the distributor is distributed upstream of the frustoconical sections which facilitates distribution.

For any of the walls, when a wall comprises a cylindrical section and a frustoconical section, said sections can be made of one and the same wall (to facilitate mounting) or obtained by assembly, for example by welding two separate sections (to facilitate the manufacture of the elements).

Preferably, for the same wall, the diameter of the apex of the frustoconical section is equal to the diameter of the cylindrical section, so as to simplify the assembly and manufacture of the elements.

In a particular embodiment, when the frustoconical section of the central wall is extended by a cylindrical section, said wall may, at the junction between the frustoconical section and the cylindrical section, be partially obstructed, for example by means of a plate, a grid, a narrowing of the opening diameter.

Advantageously, the walls of the distributor can be made of material compatible with the constraints of the reaction medium during the use of said distributor, for example in an axial flow reactor for the catalytic treatment of a hydrocarbon feedstock. In particular, the distributor can be made of one or more materials chosen from carbon steels containing less than 2.0% carbon, so-called special steels containing at least 5.0% chromium, nickel or molybdenum, and stainless steels containing at least 10.5% Molybdenum.

The distributor further comprises assembly means enabling the walls to be assembled and joined together. Said means can be positioned at the plane formed by the frustoconical ends of the distributor between at least 2 walls. For example, said assembly means may be a cross member or any part allowing the joining and positioned transversely between the external wall and the central wall and joined to each of the walls, for example by welding, gluing, rivet or even interlocking.

When the distributor has several cylindrical sections, said means can also be positioned at the plane formed by the cylindrical ends. For example, said assembly means can be a cross member or any part allowing the joining and positioned transversely between the external wall and the central wall and joined to each of the walls for example by welding, gluing, rivet or even interlocking.

In one embodiment, the distributor can comprise, at the level of the plane formed by the frustoconical sections, a means of controlling the flow surface between each zone delimited by two adjacent walls. For example, said control means can be a plate perforated with holes of identical or different diameters, or even a grid. Preferably, the area of the flow surface of the different zones is identical.

In another assembly mode, the fixing means 6, such as crosspieces, join at least two adjacent sections. The distributor includes a sufficient number of fixing means to allow assembly of the distributor. In this embodiment, the securing means can also make it possible to define and control the flow surface between each zone delimited by two adjacent walls.

The distributor may further comprise on the surface of the external wall for fixing the distributor at the end of an inlet pipe in a reactor, for example with axial flow, or even at the top of said reactor at the opening allowing the 'introduction of said tubing. Said fixing means can be chosen from any suitable means such as for example by means of fittings, by screwing, by interlocking, by welding or even gluing.

Preferably, the height of the cylindrical section 2b of the external wall 2 is between 20 and 1000 mm, preferably between 50 and 900 mm, preferably between 100 and 800 mm, preferably between 200 and 700 mm, so preferred between 300 and 600 mm.

Preferably, the height of the frustoconical section 2a of the external wall 2 is between 50 and 1000 mm, preferably between 50 and 900 mm, preferably between 100 and 800 mm, preferably between 200 and 700 mm, so preferred between 300 and 600 mm.

Advantageously, the height of the cylindrical part of the external wall allows the distributor according to the invention to be fixed within the axial flow reactor. In particular, said height is between 0.5 and 2 times the height of the frustoconical section of the outer wall.

The external diameter corresponds to the diameter of the base of the frustoconical section of the external wall.

The ratio of the external diameter to the height of the external frustoconical section h-2a is between 0.2 and 4.0, preferably between 0.4 and 3.0, preferably between 0.6 and 2.5, of preferably between 0.8 and 2.0.

Preferably, the dimensions of the distributor are determined in particular as a function of the dimensions of the reactor and the flow rates of the fluids.

Reactor

Another subject of the invention relates to an axial flow reactor, in particular for the catalytic treatment of a hydrocarbon feedstock in liquid or gaseous form comprising a distributor according to the invention.

Said reactor, of the ferrule type, with axial flow for the catalytic treatment of a hydrocarbon feed (liquid and / or gaseous) comprises:

- a cylindrical casing 11 of elongated shape along the vertical axis, of diameter d-11

an opening 12 allowing the introduction of said load located at the top of said enclosure,

- an inlet pipe 15 positioned at the opening 11

- a catalytic bed 16

- A means 13 for discharging the effluent from the catalytic reaction located at the bottom of said envelope;

a distributor positioned at the end of said tube 15, said distributor comprising:

o an external wall comprising a frustoconical lower section extending by a cylindrical upper section;

o a central wall positioned inside the external wall and comprising a frustoconical section;

ο N internal walls positioned around the central wall, and between the external wall and said central wall, said internal walls each comprising a frustoconical lower section of increasing diameter.

in which o for each external, central and internal wall, the diameter of the base of the frustoconical section is greater than the diameter of the top of said frustoconical section;

o the base of the frustoconical section of each of the external, central and internal walls is positioned on the same plane;

ο N is between 1 and 40, preferably between 1 and 30, preferably between 1 and 20, preferably between 1 and 10, preferably between 8 and 8, preferably between 1 and 6, and preferably between 2 and 4 .

In particular, the reactor, possibly with upward or downward flow, and can be in a fixed bed or in a bubbling bed, preferably the reactor is in a fixed bed, very preferably the reactor is in a fixed downflow bed.

The reactor may comprise, at the opening 12 at the top of the envelope, a means 14 for reducing the diameter d-12 of said opening, in order to facilitate the connection, by any means known to those skilled in the art, of the tubing. inlet 15 at the top of the reactor shell.

Another object according to the invention relates to the use of a distributor according to the invention for the distribution of a hydrocarbon feedstock in liquid or gaseous form within a reactor with upward or downward axial flow.

Manufacturing process

The present invention also relates to a method of manufacturing a distributor, in which the following steps are carried out:

a) the different constituent walls of the distributor are manufactured independently, for example by machining, by molding, by plastic deformation of a flat plate or by additive manufacturing;

b) said distributor is constructed by means of the following steps:

i) positioning at least two adjacent walls;

ii) said walls are fixed;

iii) repeating steps i) and ii) to obtain the desired distributor.

Thus assembled, the walls of the distributor allow a better distribution of the charge to be contacted with the catalyst (in particular for a gas with spent catalyst particles).

Preferably, the fixing step is carried out by welding, gluing, screwing, bolting or any similar means. Preferably, the joining is implemented by welding.

EXAMPLE

We consider a catalytic reactor 11 in a fixed bed 4 m in diameter, comprising a catalytic height 16 of 9 m.

The ferrule is hemispherical and the distance between the fluid inlet pipe 15 and the catalytic bed 16 is 2 m.

The cylindrical section 2b of the outer wall 2 of the distributor 1 has a diameter of 500 mm and a height of 500 mm. The tapered section 2a has a vertical height of 500 mm.

All the frustoconical sections have an angle a of 49 °.

The distributor is such as that shown in Figure 1. The diameter of the cylindrical section 2b and the upper diameter of the frustoconical section 2a of the outer wall 2 are 500 mm. The upper diameter of the frustoconical section 3a of the internal wall 2 is 433 mm. The upper diameter of the frustoconical section 4a of the internal wall 4 is 354 mm. The upper diameter of the frustoconical section 5a of the external wall 5 is 250 mm.

The frustoconical sections 2a, 3a, 4a and 5a all have a height of 500 mm.

The lower diameters of the frustoconical sections 2a, 3a, 4a and 5a are respectively (from outside to inside): 833 mm, 800 mm, 760 mm and 708 mm.

Thus in a fixed bed reactor comprising a distributor according to the invention has a geometric area for bringing the charge into contact with the catalytic bed equal to 3.1 m ² .

While without a distributor according to the invention, the geometric area for bringing the charge into contact with the catalytic bed is dependent on the diameter of the charge introduction pipe of 500 mm 5 in this example, which corresponds to an area of 0.2 m ^{2 contact area} .

It clearly appears that the distributor according to the present invention makes it possible to significantly increase the contact surface between the charge and the catalytic bed.

Claims (14)

1. Gas and / or liquid distributor (1) for an axial flow reactor comprising: - an external wall (2) comprising a frustoconical lower section (2a) extending by a cylindrical upper section (2b); - a central wall positioned (5) inside the external wall and comprising a frustoconical section (5a); - N internal walls (3, 4) positioned around the central wall, and between the external wall and said central wall, said internal walls each comprising a frustoconical lower section (3a, 4a) coaxial with the frustoconical section of said external wall and in diameter increasing with respect to the diameter of the frustoconical section of the central wall in which - For each external (2), central (5) and internal (3, 4) wall, the diameter of the base of the frustoconical section is greater than the diameter of the top of said frustoconical section; - The base of the frustoconical section of each of the external, central and internal walls is positioned on the same plane; - N is between 1 and 40. 2. Distributor according to claim 1 wherein the lower frustoconical sections of the central wall (5a) and internal walls (3a, 4a) are extended by a cylindrical upper section (3b, 4b, 5b), said cylindrical upper sections being coaxial . 3. Distributor according to any one of the preceding claims, in which the heights of each of the frustoconical sections are identical. 4. Distributor according to any one of claims 1 to 3, in which the heights of the frustoconical sections are increasing from the central wall (5) towards the external wall (2). 5. Distributor according to any one of claims 1 to 3, wherein the heights of the frustoconical sections are decreasing from the central wall (5) towards the outer wall (2). 6. Distributor according to any one of the preceding claims comprising at the base of the frustoconical sections a perforated plate. 7. Distributor according to any one of claims 2 to 6, wherein the central cylindrical section (5b) is partially obstructed. 8. Distributor according to claim 7 wherein the cylindrical section (5b) of the central wall (5) is partially obstructed at the junction with the frustoconical section (5a). 9. Distributor according to any one of the preceding claims, in which each frustoconical section forms an angle a with the axis formed by the wall of the cylindrical section 2b of the external wall, said angle being between 1 and 80 °, and wherein from the central wall to the outer wall, the angle a of a wall is greater than or equal to the angle of alpha of the adjacent wall. 10. Distributor according to claim 9 wherein all the walls have the same angle a. 11. Distributor according to any one of the preceding claims, in which the height of the cylindrical part of the external wall is between 0.5 and 2 times the height of the frustoconical section of the external wall. 12. Distributor according to any one of the preceding claims, in which the ratio of the external diameter to the height of the external frustoconical section h-2a is between 0.2 and 4.0. 13. Reactor with upward or downward axial flow for the catalytic treatment of a hydrocarbon feed in liquid or gaseous form comprising a distributor according to any one of claims 1 to 12. 14. Use of a distributor according to one of claims 1 to 12 for the distribution of a hydrocarbon feedstock in liquid or gaseous form within an axial flow reactor.