WO2009080978A2 - Device for conveying particles, installation and method for loading a container using the device - Google Patents

Abstract

The invention relates to a conveying device (10) allowing particles to be transported from a hopper situated at ground level as far as the container, while at the same time protecting the particles from the weather and limiting the attrition thereof. To this end, it comprises a conveyor belt (11) and a protective jacket (13), open at its ends and able to accommodate the conveyor belt. The conveyor belt is equipped with at least one containment skirt (14) able to isolate from the interior wall of the jacket the particles that are being transported by one or more compartments of the conveyor belt. The invention also relates to a container loading installation using a conveying device according to the invention, and to a corresponding loading method.

Description

 DEVICE FOR TRANSPORTING PARTICLES, INSTALLATION AND METHOD FOR LOADING AN ENCLOSURE WITH THE DEVICE

The invention relates to a device for the transport of solid particles, as well as an installation and a method for loading said particles into an enclosure by means of the device.

The invention more particularly relates to a device for the transport of solid particles, a charging installation incorporating this device and an associated method, used for the loading of reactors with fixed bed (s) of chemical, electrochemical type. , petroleum or petrochemical, with solid particles in the divided state. These particles may be in the form of beads, grains, cylinders, pellets, rods, or other forms, and are generally small in size. The particles may, in particular, be molecular sieves, solid catalyst grains, which are generally in the form of single or multi-lobed extrudates, the dimensions of which may vary from a few tenths of a millimeter to a few centimeters. More specifically, the present invention relates to a method for charging in the field of the petroleum industry, one or more fixed beds of catalyst grains in a chemical reactor, the catalyst grains being transported by a transport device included in a specific installation, also objects of the present invention.

It is to this application that reference will be made more particularly in the remainder of this description, but the device, the installation integrating this device and the method for the corresponding loading operation, objects of the present invention, apply to the loading of any other type of solid particles in any type of enclosure, especially large.

The feed of the solid-particle reactors, in particular for feeding a catalyst-grain distribution device, for example a rain-effect device, is generally carried out by an opening whose diameter is initially defined in order to let an operator through, still called in the profession "manhole", located at the top of the reactor. The same goes for so-called "baggage" loads, that is to say loads with a feed sleeve, lowered and suspended in charge of solid particles inside the reactor to fill it. this. More particularly, this supply of solid particles is carried out via a hopper installed on the upper part of the reactor, above the manhole. The hopper is maintained in charge of catalyst grains by successive and manual opening of various containers generally made of flexible rigid canvas, in English "big-bag", which can contain up to one ton of catalyst. The containers are positioned successively above the hopper, by means of a crane which is active during the entire loading phase of the reactor. This operation is time-consuming, directly proportional to the height of the reactor to be loaded, that is to say the cumulative rise and fall times of the hook of the crane, especially when it must perform the necessary maneuvers to pick up the container at ground level and then bring it to the top of the hopper. The risks of rupture of the feed of the hopper, therefore ultimately the device for distributing the catalyst grains or the sleeve, therefore increase with the height of the reactor to be loaded.

It is particularly common that this diet is disturbed by weather conditions. Indeed, the suspension of the containers above the hopper and the chemical nature of some charged catalysts require favorable meteorological conditions, such as a weak wind and a lack of rain or snow. These meteorological events, more sensitive in some parts of the world, de facto stop the loading, unnecessarily inducing an increase in the immobilization time of the reactor, therefore of the manufacturing unit concerned, resulting in additional capital costs. which can be very detrimental to the operator, particularly in terms of lost profits.

The fact of using a sleeve, whether for a type of loading of the same name as explained above, or for feeding a distribution device disposed inside the enclosure, for example to charge the lower bed of a reactor with several catalytic beds, may have several disadvantages.

One can for example observe an attrition of the catalyst grains by friction on the wall of the feed sleeve located inside the reactor, especially when it is large, for example more than ten meters. This disadvantage takes another dimension when it is inert balls that are loaded into the reactor, for example in support of the catalyst bed. Indeed, if the falling speed of these balls is not controlled, it can happen that the accumulated energy causes the breakage of said balls when they hit a hard surface, for example the lower level of the reactor or simply already loaded logs.

Such a loading operation with a handle can also cause difficulties for the safety of the men who operate the loading of the catalyst grains or inert balls, from the feed hopper positioned on the upper part of the reactor, to the device distribution within this same reactor. Indeed, this sleeve, for example in charge of catalyst particles, intended for direct filling of the reactor or feeding the distribution device, can occupy up to 10% or even 20% of the free space of the hole of man or passages on trays, spaces intended for the circulation of the operators inside the reactor. These spaces generally have diameters or dimensions between 500 and 1500 mm.

The presence of this sleeve which reduces the free space of the manholes and tray passages can therefore be a serious handicap during an emergency evacuation operation of an operator, for example made unconscious, since the bottom of the reactor. Moreover, a rupture of this feed sleeve in charge of catalyst grains or inert balls, inside the reactor, can cause a drop of the particles on the operators present in the reactor, exposing these people to a serious danger to their physical integrity. Solutions have been proposed in the art to ensure the horizontal, vertical or oblique transport of solid particles as described in the patent applications or patents WO93 / 10027, WO83 / 00979, JP8002689, EP0070149, EP0053592, US3756375, or alternatively FR2082078. If these devices and / or processes respond well to the problem of particle transport, on the other hand the integrity of fragile solid particles, such as catalyst grains, whether by manipulation or friction, or simply by contact with the oxygen from the air, is not assured. Indeed, transport devices using for example buckets filling by immersion in a volume of particles to be loaded, or a worm to ensure the transport of these particles, are conducive to attrition phenomena of catalyst grains, notably more sensitive when these grains or solid particles are of fragile and friable nature. On the other hand, the design of the devices, the shapes and sizes of these devices proposed in the art, that they are not easily and immediately adaptable for controlled atmosphere operation.

There is therefore a need to improve the particle supply of an enclosure, in particular to enable a loading of particles whatever the weather conditions, reducing or even eliminating all the causes of attrition of the particles, and in particular to allow loading in more favorable safety conditions for the persons operating the load and more particularly for those inside the enclosure to be loaded. The invention aims to overcome these drawbacks by proposing a device for the transport of solid particles from a hopper on the ground to an opening of the enclosure, while protecting the particles from the weather and limiting their attrition. that is to say their friction on walls, for example belonging to the device. In particular, by using the transport device according to the invention, it is no longer necessary to suspend the containers to a crane above the enclosure, which may have a height of several tens of meters. As a result, the load is no longer wind dependent. The transport device further ensuring the particles, an atmosphere that can be controlled over the entire length of their movement, the loading can also be carried out in rainy or snowy weather. For this purpose, a first subject of the invention relates to a device for the transport of solid particles comprising an endless conveyor belt equipped with at least one compartment intended for the transport of said particles, the band comprising an upper strand which supports and drives the particles, and a lower return strand, characterized in that the device comprises

a protective envelope adapted to receive the upper and lower circulating strands of the conveyor belt,

openings arranged at the ends of the protective envelope to enable the loading and unloading of the particles, and in that

the conveyor belt is equipped with at least one confinement skirt capable of isolating from the inner wall of the protective envelope the particles transported by one or more compartment (s) of the conveyor belt.

The protective envelope, which thus completely surrounds the conveyor belt, makes it possible to seal the loading device by preventing the introduction of external elements (rain, snow, pollution, etc.) inside the conveyor. said envelope. The confinement skirt makes it possible to isolate the particles from the inner wall of the protective envelope, which makes it possible not to create attrition of the solid particles during their transport, in particular by avoiding attrition by friction against the inner wall of the protective casing. The device according to the invention also makes it possible to maintain a controlled atmosphere, for example an inert atmosphere inside the device using a gas with a slight overpressure, which makes it possible to preserve the particles transported from the ambiant air. This gas, which may be nitrogen or any other type of inert gas, will additionally minimize the friction between the upper and lower strands, as well as those possibly existing between the confinement skirt and the inner wall of the envelope. protection.

Such a device can be used in a horizontal, inclined or vertical position, so that it is possible to feed the enclosure through its top or through an opening on its side wall, while keeping the feed hopper level from the ground outside the enclosure. Advantageously, each confinement skirt is secured to the conveyor belt, for example by gluing, stitching or any other suitable type of attachment, and extends above the compartment (s) of the conveyor belt, substantially parallel to the wall internal protection envelope, away from the latter.

This configuration makes it possible to optimize the dimensions of the free space provided between the conveyor belt and the confinement skirt in order to transport the solid particles while protecting them from attrition, and / or from any frictional breaks against the wall of the container. the protective envelope.

Advantageously, each containment skirt is made in two parts whose free edges overlap, these parts being able to be spaced apart from one another in order to allow access to the particles transported in the compartment (s). of the conveyor belt, especially when it is positioned at an opening disposed at one end of the protective envelope.

Such a configuration allows easy access to the conveyor belt while the closure of the confinement skirt ensures the confinement of the particles transported. In a variant, the transport device is formed of a plurality of assemblable modules, for example by interlocking. It can thus be easily and quickly assembled and its dimensions can be adapted according to the needs.

In another variant, the transport device comprises bent portions. This makes it possible to adapt the device to each use by allowing a different inclination angle, for example between the central part of the transport device and its ends.

Preferably, each containment skirt may then have a corrugated section. Such a corrugated shape allows a deformation of the confinement skirt when the conveyor belt follows a bent part of the transport device. In particular, when the confinement skirt is in two parts, the corrugated shape makes it possible to avoid opening of the confinement skirt and contact of the particles with the protective envelope. Each containment skirt may, for example, be made in a shape memory material. In addition, to prevent compression of the solid particles by the containment skirt in the bent portions of the protective casing, expansion volumes may be provided in the outer portion of said protective casing at the bent portions.

In a particular embodiment, the conveyor belt is equipped with a plurality of compartments and containment skirts, and the ends of each compartment, delimited by a confinement skirt and a portion of the conveyor belt, are closed by partitions. extending substantially perpendicular to the surface of the conveyor belt. It is thus possible to obtain in a simple manner sealed zones delimited by the partitions of the compartments, the skirts of confinement and the conveyor belt. In addition, the partitions of the compartments participate in maintaining the confinement skirts in the closed position, keeping the skirts of confinement at a distance from the conveyor belt.

Advantageously, the outer diameter of the protective envelope is between 15 and 100 cm, preferably between 20 and 30 cm.

Such dimensions allow the introduction of the transport device according to the invention into a reactor drain pipe.

Advantageously, the device according to the invention is equipped with a pneumatic or hydraulic motor for moving the conveyor belt.

Another object of the invention relates to a use of a transport device according to the invention for the transport of solid particles from a particle feed to a petroleum, chemical or petrochemical reactor.

The invention also relates to an installation for charging an enclosure made of solid particles, comprising a device for transporting solid particles according to the invention, a hopper external to the enclosure, placed on the ground and intended to supply said device particulate transport, and an internal device for loading and / or dispersing particles, for example with a rain effect, intended to be arranged inside the enclosure and able to receive the particles discharged by the transport device inside the enclosure. The feed hopper of such an installation being placed on the ground, generally unsprung and sheltered from the weather by any means known to those skilled in the art, these bad weather do not disturb the transfer of particles from the hopper to the device. according to the invention.

Advantageously, the internal loading and / or dispersion device comprises a dismountable upper hopper, able to receive the discharged particles, thus facilitating its placement in the enclosure. Preferably, the dismountable hopper is provided with a fine suction system.

Another subject of the invention relates to a method for loading solid particles into an enclosure, in which a transport device according to the invention is used to transport particles from a particle feed hopper placed on the ground at a distance of the enclosure until an opening thereof.

Preferably, the central portion of the transport device extends substantially vertically, its ends being bent in order to connect the transport device on the one hand to the feed hopper and on the other hand to the opening of the enclosure . Such a configuration saves space and a close position of the feed hopper relative to the enclosure.

When the enclosure is equipped with an aperture at its top, the end of the protective envelope of the transport device, provided with its fitted opening, is advantageously placed above said opening, so as to pour the particles into the feed hopper of an internal charging and / or dispersion device located in the chamber for charging and / or dispersing the particles in the chamber.

When the enclosure is equipped with at least one opening on its side wall, one end of the protective envelope of the transport device, provided with its arranged opening, can be advantageously introduced into said lateral opening, so as to discharge the particles in the feed hopper of an internal charging and / or dispersion device located in the chamber for charging and / or dispersing the particles in said enclosure. This has the advantage of allowing the particle supply of the enclosure to a lower height than the traditional feed from the top. This results in a lower risk of attrition of the particles during their loading, as well as improved safety conditions, the upper inner part of the enclosure being indeed free so that access to the interior or the outside the enclosure is facilitated.

When the enclosure is equipped with a plurality of lateral openings located at different heights, the enclosure will advantageously be loaded by successively introducing one end of the protective envelope, provided with its arranged opening, into the various lateral openings, starting with the lowest opening, thus loading the lower catalytic bed, and ending with the highest opening.

In particular, for the loading of a loudspeaker provided with internal horizontal plates, each plate having a through opening for the passage and installation of an internal device for loading and / or dispersion, during loading according to the invention. the invention, the upper through openings, as well as the upper opening of the enclosure, will be completely released from the presence of a feed sleeve.

This arrangement makes it possible to increase the dimensions of the free space remaining at these through openings and upper, which makes it easier to evacuate an unconscious person to the bottom of the reactor. The charged particles may be inert beads or catalyst particles.

Advantageously, the particles are transported from the feed hopper to the enclosure in a controlled atmosphere, in particular to prevent any contact of the particles with oxygen or the humidity of the air. It may be for example an inert atmosphere, such as nitrogen.

The invention is now described with reference to the accompanying non-limiting drawings, in which: FIG. 1 is a perspective view of a transport device according to the invention; - Figure 2 is a schematic representation of a loading installation according to the invention using a transport device;

FIG. 3 is a diagrammatic representation in section of an enclosure loaded by one of its lateral openings by means of a loading installation according to the invention;

- Figure 4 is a schematic sectional representation of an enclosure charged by its upper opening by means of a loading installation according to the invention. FIG. 1 represents a portion of a device 10 for transporting solid particles according to the invention.

This device 10 comprises a conveyor belt 1 1 endless equipped with at least one compartment 12 (two compartments are shown on the upper strand and 1 compartment on the lower strand in Figure 1) for the transport of particles, the strip having a upper strand 11a which supports and drives the particles, and a lower strand 1 Ib back. In the figures, for the sake of clarity, only the partitions 12a, 12b, 12c, 12d, 12e of the compartments 12 are shown. According to the invention, the device comprises a protective envelope 13 adapted to receive the upper and lower circulating strands of the conveyor belt 11. A sheet metal separating plate (not shown) may be provided between the two strands of the conveyor belt. The protective envelope 13, which may be tubular but not exclusively, is made of a rigid type material such as metal, and preferably a composite type material, or a material of plastic type.

The ends of the protective envelope 13 are equipped with openings 13a, 13b, to allow the loading and unloading of the particles.

The conveyor belt is also equipped with at least one containment skirt 14 capable of isolating from the inner wall of the protective envelope the particles transported by one or more compartments of the conveyor belt. Each containment skirt 14, made of a flexible material and preferably of impregnated fabric, of elastomer or else of a thin plastic material, is integral with the conveyor belt 1 1 and extends, above the compartment (s) of the conveyor belt, substantially parallel to the inner wall of the protective envelope, at a distance from the latter. In the example shown, the confinement skirt 14 is arranged concentrically with respect to the protective envelope.

In the example shown, each containment skirt 14 is made in two parts 14a, 14b whose free edges overlap, these parts being able to be spaced apart from one another in order to allow access to the particles transported in the compartment (s) of the conveyor belt. This spacing can be obtained by means of a specific part.

The transport device will preferably be formed of a plurality of assemblable modules, in particular by interlocking. For example, the protective envelope is then made of several reversibly assemblable sections, as well as the conveyor belt. Such a design makes it easy to adapt the length of the transport device to the length required for each application.

In particular, the transport device may have bent portions, as shown in FIGS. 3 and 4.

In order to allow the deformation of the confinement skirts during the crossing of bent parts, each containment skirt may then have a corrugated section. The direction of the axis of the corrugations will be chosen so as to avoid crushing of the solid particles during the crossing of the bent portion. In a configuration such as that shown in Figures 3 and 4, the axis of the corrugations will preferably be perpendicular to the direction of travel of the conveyor belt.

In the example, the conveyor belt 11 is provided with a plurality of compartments 12 and containment skirts 14, each confinement skirt confining two adjacent compartments. Of course, a containment skirt may confine more than two compartments or one.

Thus, each containment skirt 14 delimits with a portion of the conveyor belt a particle loading zone, which can be closed by the partitions of the compartments 12, these partitions extending substantially perpendicular to the surface of the conveyor belt

The outer diameter of the protective envelope will for example be chosen between 15 and 100 cm, preferably between 20 and 30 cm. The transport device will also be preferably equipped with a pneumatic or hydraulic motor for moving the conveyor belt, complying with the safety requirements of a refinery.

FIG. 2 schematically represents a loading installation 20 for loading a chamber made of solid particles, only the wall 1 of the chamber being represented to scale.

This installation comprises a transport device 10 according to the invention, a hopper 21 external to the enclosure, filled with particles 22, placed on the ground and intended to supply said transport device 10 in particles 22, and an internal device 23 of loading and / or dispersion of the particles intended to be disposed inside the chamber and adapted to receive the particles discharged by the transport device into the chamber.

For this purpose, the internal device 23 for loading and / or dispersion (in FIG. 2, a rain-effect distribution device, such as the Densicat® device, for example described in document FR

2 872 497) comprises a dismountable hopper 24 adapted to receive the discharged particles.

This removable hopper 24 will preferably be provided with a fine suction system.

A recovery tank 25 may be placed under the outdoor feed hopper 21 to recover the particles.

For the sake of clarity, the protective envelope 13 and the containment skirts 14 of the transport device are not shown in FIG. 2.

The internal loading and / or dispersion device will be chosen according to the nature of the solid particles to be loaded into the chamber in order to obtain gravity filling by means of a flexible sleeve, for example for inert balls or rain-dispersion filling for catalyst grains in a chemical reactor.

Such devices are known to those skilled in the art. Figure 3 shows an enclosure 30 to be charged with solid particles. The chamber shown is a reactor provided with a plurality of internal trays 321, 322, 323, 324, 32s, 32δ. Each of these plates has a through opening 33i-6, located in the axis of a loading opening 31 at the top of the reactor. These openings 33i-6, and 31 are sufficient to allow the passage of a man and are generally called manholes. The enclosure 30 is further provided on its side wall with openings 341-4, which are for example pipes for emptying the reactor. These lateral openings 341-4 are arranged at different heights of the reactor.

The loading of the reactor 30 shown in FIG. 3 is now described using a transport device 10 according to the invention.

A hopper 21 outside the enclosure, is installed, placed on the ground. This hopper, intended to feed the particle transport device 10, is itself fed by a specific device 26, usually carried by a forklift or any suitable handling device, and called container or "big bag".

The transport device 10 according to the invention is itself placed between the hopper 21 and the reactor 30, so as to transport particles from the feed hopper 21 placed on the ground, at a distance from the enclosure, up to at an opening of the reactor.

In the example shown in FIG. 3, the central part of the transport device extends substantially vertically, its ends being bent in order to connect the transport device on the one hand to the feed hopper and on the other hand to the opening of the enclosure. In particular, the lower end of the transport device 10 extends substantially horizontally under the hopper 21, while its upper end is introduced through the emptying pipe 343 into the reactor, so that the particles are discharged into a container. internal hopper 24 disposed above a loading device and / or dispersion.

Such positioning of the transport device 10 makes it possible to consider supporting it against the support structure of the reactor (not shown), and allows the introduction of the transport device in a reduced environment. When more space is available around the reactor, one can consider tilting the transport device, which can then be substantially straight, in order to connect in a straight line oblique the external feed hopper to the selected opening of the reactor.

The charging of the reactor shown in FIG. 3 will preferably be carried out by first charging the lower part of the reactor. For this purpose, the transport device according to the invention is introduced into the emptying pipe 342, and then opens above the first plate 321 of the reactor. The internal loading device is then placed in the corresponding opening 331 of the plate. The conveyor belt is then driven to transport the particles. When the containment skirts are in two parts, spacers for example wedge-shaped, located at the ends of the transport device allow to separate the two parts of each containment skirt, to allow the loading / unloading of the particles. During this first loading phase, a man may be present on this first tray to supervise the loading. The openings of the upper trays being free, it can easily exit or be evacuated by these upper openings in case of danger. When the lower part of the reactor is filled, the transport device is removed from the reactor and then introduced into the emptying pipe 343 located just above for further loading. It then proceeds as previously described, the internal loading device being placed in the opening 343 as shown in Figure 3. The openings of the upper plates remain free, for safety.

The loading can then be continued in a similar manner by introducing the transport device into the emptying pipe 34 ₄ .

If the reactor needs to be more filled and there are no longer enough high drain pipes, then the loading end of the transport device is brought over the top opening 31 of the reactor.

Thanks to the confinement provided by the skirts, the loading can be carried out under a controlled atmosphere, for example under an inert atmosphere. FIG. 4 represents, as in FIG. 3, a chamber 30 to be charged with particles. The loading is identical to that described above with the exception of the particle feed, which is not done by a lateral opening of the reactor, but by its upper opening 31 with the aid of the device and method, objects of the present invention.

The upper feed hopper 24 of the internal loading and / or dispersion device will be in this latter configuration insulated from the elements and may be placed in a specific environment to allow its inerting by a neutral gas.

Claims

Device for the transport (10) of solid particles comprising an endless conveyor belt (11) equipped with at least one compartment (12) for transporting said particles, the band comprising an upper strand (11a) which supports and entrains the particles, and a lower return strand (1 lb), characterized in that the device comprises

- a protective envelope (13) adapted to receive the upper (l ia) and lower (1 Ib) circulating strands of the conveyor belt, - openings (13a, 13b) disposed at the ends of the protective envelope (13) to allow the loading and unloading of particles, and in that

- The conveyor belt (11) is equipped with at least one containment skirt (14) adapted to isolate from the inner wall of the protective envelope particles carried by one or more compartment (s) of the conveyor belt.

2. Transport device (10) according to claim 1, characterized in that each containment skirt (14) is integral with the conveyor belt and extends, above the compartment (s) of the conveyor belt, substantially parallel to the inner wall of the protective envelope (13), at a distance from the latter.

3. Transport device (10) according to claim 1 or 2, characterized in that each containment skirt (14) is made in two parts (14a, 14b) whose free edges overlap, these parts being adapted to be spaced apart from each other to allow access to the particles transported in the compartment (s) (12) of the conveyor belt.

4. Transport device (10) according to one of claims 1 to 3, characterized in that it is formed of a plurality of assemblable modules.

5. Transport device (10) according to one of claims 1 to 4, characterized in that it comprises bent portions.

6. Transport device (10) according to claim 5, characterized in that each containment skirt (14) has a corrugated section.

7. Transport device (10) according to one of claims 1 to 6, characterized in that the conveyor belt (11) is equipped with a plurality of compartments (12) and containment skirts (14), and in that the ends of each compartment, delimited by a containment skirt (14) and a portion of the conveyor belt, are closed by the partitions (12a). e) compartments extending substantially perpendicular to the surface of the conveyor belt.

8. Transport device (10) according to one of claims 1 to 7, characterized in that the outer diameter of the protective envelope is between 15 and 100 cm, preferably between 20 and 30 cm.

9. Transport device (10) according to one of claims 1 to 8, characterized in that it is equipped with a pneumatic or hydraulic motor for moving the conveyor belt.

10. Use of a transport device (10) according to one of claims 1 to 9 for the transport of solid particles from a particle feed to a petroleum, chemical or petrochemical reactor.

1 1. Installation for charging a chamber (30) solid particles, characterized in that it comprises a device (10) for transporting particles (10) according to one of claims 1 to 9, an external hopper (21). to the enclosure, placed on the ground and intended to supply said particulate transport device, and an internal device (23) for loading and / or dispersing the particles intended to be disposed inside the enclosure and suitable for receiving particles discharged by the transport device into the enclosure.

12. Loading plant according to claim 11, characterized in that the internal device (23) for loading and / or dispersion comprises a removable hopper (24) adapted to receive the discharged particles.

Loading device according to claim 12, characterized in that the dismountable hopper (24) is provided with a fine suction system.

A method for loading solid particles into an enclosure (30), wherein a transport device (10) according to one of claims 1 to 9 is used to transport particles from a feed hopper (21) in particles placed on the ground away from the enclosure to an opening (34i-4, 31) thereof.

The loading method according to claim 14, wherein the central portion of the transport device extends substantially vertically, its ends being bent to connect the transport device on the one hand to the feed hopper (21) and on the other hand to the opening (34- ₄ , 31) of the enclosure.

16. A method of charging according to one of claims 14 or 15 of an enclosure equipped with an opening (31) at its top, wherein is placed the end of the protective envelope of the transport device, provided with its arranged opening (13a), above said opening, so as to pour the particles into the feed hopper (24) of an internal loading and / or dispersion device located in the enclosure to load and / or or disperse the particles in the enclosure.

17. A method of charging according to one of claims 14 to 16 of an enclosure equipped with at least one opening (34i_ ₄ ) on its side wall, wherein one end of the protective envelope of the transport device, provided its fitted opening (13a), is introduced into said lateral opening, so as to pour the particles into the feed hopper (24) of an internal device for loading and / or dispersion located in the enclosure to load and / or dispersing the particles in the enclosure.

18. A method of charging according to claim 17 an enclosure equipped with a plurality of lateral openings (34- ₄ ) at different heights, wherein the enclosure is loaded by successively introducing one end of the envelope of protection, provided with its arranged opening (13a), in the different lateral openings, starting with the lowest opening and thus loading the lower catalytic bed and ending with the highest opening.

19. Loading method according to one of claims 14 to

18, wherein the charged particles are inert beads or catalyst particles.

20. Loading method according to one of claims 14 to

19, wherein the particles are transported from the feed hopper (21) to the chamber under a controlled atmosphere.