WO2012045923A1 - Continuous heat treatment device, in particular for dividing materials, using microwave radiation - Google Patents

Abstract

The present invention relates to a continuous heat treatment device, in particular for divided materials, using microwave radiation, which comprises: a microwave-impermeable enclosure (1) having at least one inlet (1a) and at least one outlet (1b); at least one means (2) for introducing the product (P) to be treated into said enclosure; at least one means (3) for discharging said product (P) from the enclosure; at least one microwave generator (4); at least one waveguide (5) placed between the microwave generator (4) and the enclosure (1); and means (6) for conveying and stirring the product (P), which consist of a feed screw (12), characterized in that said conveying and stirring means (6, 12) are provided with mixing blades (19) that are distributed over at least a portion of their length.

Description

 Continuous thermal treatment device, in particular of divided materials, by microwave radiation.

The present invention relates to a device for continuous heat treatment, in particular of divided materials, such as grains, aggregates, powders, pastes, liquids, by microwave radiation.

Particularly well known in the processing industries are various heat treatment devices and processes applied to the aforementioned divided materials. For example, WO-01/34533 discloses a method for obtaining high temperature results (1200 ° C), on an industrial scale, for the treatment of clay aggregates in order to obtain their expansion.

The documents WO-2004 / 068,906 and WO-2004 / 068,907 describe, respectively, a complete line of manufacture of expanded clay beads, from the granulation of the dough, to the cooling of the granules, and the technical features of the oven of baking, especially in the application to clay expansion.

These documents which describe devices using a microwave heating technique, disclose an oven technology operating discontinuously, by "batch" (or introduction of successive batches). A rotating internal cavity ensures the expansion of the clay granules for a determined volume. Draining and filling steps are necessary for the operation of the processes.

A major disadvantage of these devices is that the processing is performed batchwise, batch, continuity of production being made possible by a combination of battery ovens.

One of the known solutions for the continuous treatment of various materials in a heating process is the use of a worm. Many applications use this technology, particularly for efficiently performing thermal treatments of divided materials.

It is known, for example, a device comprising a mixing system consisting of a worm device heated by an internal heat transfer fluid circuit, or Joule effect, such as that described in FR-2.775.621. Said screw is then made of a conductive metal material traversed by a current.

The material to be treated being driven by this screw, it is heated, in contact with this screw, by conduction and radiation, which generates a significant temperature gradient and therefore limits the efficiency and homogeneity of the heater. .

It has been planned to improve the processes using microwave radiation as a means of heating the products to be treated, by combining this heating means with a worm, ensuring the movement of said products through the treatment chamber.

For example, a device such as that described in document FR-2.660 is known. 47, which discloses a heat treatment system for granular or powdery products using a worm drive system, and a heating system by a microwave field. According to this device, the worm, made of metal or other conductive material, is disposed in a dielectric sheath through which the microwave field passes, and in which the product driven by the worm, constituted by a wound wire, moves. helical, extending away from the axis of the sheath, and near the inner surface thereof. This type of device has the disadvantage of limiting the flow of the product, and poses the problem of evacuation of steam and gases, and the leak tightness of microwaves by the dielectric sheath. In addition, the presence of this dielectric sheath makes delicate industrial use at high temperature due to the material used (plastic or quartz). Document EP-036.362 proposes a device for the thermal treatment of divided materials (for example grains or powders) by micro-radiation. wave, using an Archimedean screw made of metal or other conductive material housed in a metal sheath or other conductive material, for transporting and mixing the product to be treated. The material to be treated is arranged in the thread of the screw whose dimensions allow it to act as a waveguide. This design strongly limits the heating zone and does not allow a good mixing of the product.

According to the document FR-2.614.490, there is described another type of heat treatment device consisting of an applicator for the continuous heating of grains, powders, pastes or liquids by microwaves. This applicator consists of a coaxial conductive (metal) shaft and cylinder between which the product to be treated and the waves pass. To improve the feed of the product, the shaft can serve as a worm. As for the previous document, the disadvantage of this device is that the material is confined in the cylinder, which limits the homogeneity of heating, flow and stirring. There is still known (GB-2.110.803) a device for drying granular materials by microwaves. This device comprises a closed and elongated cylindrical enclosure disposed horizontally and comprising, from upstream to downstream, a first introduction section of the granular material, a second microwave drying section and a third section of the draining said dried granular material. These three sections are separated by perforated sealing plates at the bottom for the circulation of the material from one end to the other of the enclosure, and having, in the upper part, tubes for evacuation towards one end. and the other extreme sections of the enclosure, steam produced by drying the product in the microwave section. The enclosure is traversed end-to-end by a conveyor screw which serves to advance the granular material through the sections constituting the enclosure.

Each pair of turns disposed near the inlet and / or outlet ports in the second and third sections are connected by lifting plates serving, during rotation of the screw, to disengage the inlet passage orifices. or outputting said second and third sections to prevent clogging by said granular material. These plates do not fill no function capable of effectively completing the stirring action exerted by the conveyor screw, granular material circulating in the drying chamber.

No known device allows continuous homogeneous heating for industrial applications of divided material processing (granules, powders, ...), due to poor mixing efficiency of the proposed devices. Indeed, microwave heating has the particularity of being very heterogeneous and discontinuous if we do not bring special care to the mixing of the treated material. An object of the present invention is to overcome all the disadvantages of systems and processes representative of the prior art, and to propose a technical solution for industrial application for continuous heat treatment and efficient and adjustable mixing, in particular. particular of divided materials, in the form of grains or powder whose particle size is between one micron and a few centimeters, or in the form of paste or liquid, of mineral or organic origin, such as clay, silica, asbestos, glass, Refioms, slag, sludge, crushed stone, ...

Industrial applications are multiple, such as drying, firing, expansion, inerting, decontamination, chemical conversion, the technology resulting from the implementation of the invention being particularly suitable for heat treatments requiring the l application of temperatures, for example, between 200 ° C and 2000 ° C.

According to the invention, the above-mentioned object is achieved by means of a continuous heat treatment device, in particular of divided materials, by microwave radiation, comprising:

an enclosure, which is microwaveable and has at least one inlet and at least one outlet,

 at least one means for admitting the product to be treated in said enclosure, at least one means for unloading said product out of it,

at least one microwave generator, at least one waveguide placed between the microwave generator and the enclosure, and

 - Means for routing and mixing the product disposed between said inlet and outlet of the enclosure, constituted by a worm housed in said enclosure,

this device being characterized in that said conveying and mixing means are provided with mixing paddles spread over at least a portion of their length.

According to another characteristic arrangement, the mixing paddles are distributed over the entire length of said conveying and stirring means.

Advantageously, the worm consists of helical turns, and said conveying and stirring means comprising said screw, also comprises an axial shaft passing through the helical turns of the worm, and separated from them by an annular space. .

According to one embodiment, spacers connect the axial central shaft to the turns of the worm.

According to one embodiment, the mixing paddles are arranged on at least one of the rotating components of the worm. According to an advantageous embodiment, the mixing paddles are arranged on the turns of the worm.

According to an advantageous embodiment, the device according to the invention comprises a system for adjusting the inclination of the entire heat treatment device, thus making it possible to adjust the stirring and the flow rate of the product.

According to a preferred embodiment, a secondary inclination adjustment system is arranged on the guides of the wave generators, so as to compensate for the inclination of the entire device. According to an advantageous embodiment, the enclosure comprises an upper part and a lower part, and the routing and stirring means are located in the lower part of said enclosure, close to the bottom of the latter. According to an interesting embodiment, microwaveable metal walls are spaced apart inside the upper part of the enclosure, between the inlet and the outlet thereof.

According to another embodiment, the device according to the invention consists of modular elements arranged in alignment, one after the other.

According to an advantageous embodiment, each module comprises:

- a portion of the enclosure,

 - a portion of worm,

 an axial shaft portion,

 at least one microwave generator,

 at least one waveguide,

several modules thus defined that can be assembled, rigidly, one after the other, to form a variable size installation.

According to another mode of implementation, additional inputs are arranged to allow the introduction of additional energies in addition to microwaves, to increase the efficiency (cold or hot air, infrared, ...).

According to another mode of implementation, a secondary air flow is provided by openings disposed on the lower portion of the enclosure. The device according to the invention provides several advantageous advantages, in particular to allow: a continuous treatment of the products, an excellent mixing of the products resulting in a very homogeneous heating thereof, an efficient thermal treatment of materials of small particle size, a modularity allowing a sizing of industrial scale furnaces compared to conventional heat treatment furnaces, good thermal insulation, - a great ease of implementation and simplicity of maintenance, a yield important compared to conventional ovens, precise control capability, reduced cycle time compared to conventional processes, and exceptional product quality. The above and other objects, features and advantages will become more apparent from the following detailed description and accompanying drawings in which:

Figure 1 is a schematic view in longitudinal section of an embodiment of the heat treatment device according to the invention.

FIG. 2 is a cross-sectional view, on an enlarged scale, along the line 2-2 of FIG. 1.

Figure 3 is a detail view showing a turn of the worm conveyor and stirring, equipped with mixing paddles. Figure 4 is a view similar to Figure 1 and showing an alternative embodiment of the device according to the invention.

FIG. 5 is a schematic view in longitudinal section illustrating a modular microwave heat treatment device consisting of several modules assembled one after the other. Figure 6 is a front view of the auger showing the inclination of the mixing paddles.

Figure 7a is a side view of an adjustable tilt mixing paddle. Figure 7b is a front view of an adjustable tilt mixing paddle.

Referring to said drawings to describe an interesting example although not limiting, embodiment of the continuous heat treatment device, in particular of divided materials, by microwave radiation, according to the invention.

In the present specification and in the claims, the words "upper", "lower", "high", "low", and "horizontal" are used with reference to the functional positioning of the constituent elements of the claimed device. The terms "upstream end" and "downstream end" are chosen in relation to the direction of movement of the processed product.

The device according to the invention comprises:

an enclosure 1, sealed to microwaves and comprising at least one inlet 1a and at least one outlet 1b, disposed at the upstream and downstream ends, respectively, of said enclosure,

at least one intake means 2 for the product P to be treated in said enclosure, in relation with the inlet 1 a,

at least one unloading means 3 of said product P, out of it, in relation to the output b, at least one microwave generator 4, and, preferably, several microwave generators 4 (three microwave generators according to the example shown), at least one waveguide 5 connecting each microwave generator 4 inside the enclosure 1, and

- Means for routing and stirring 6 of the product P to be treated, arranged between the inlet 1a and the outlet 1b of the enclosure 1. The enclosure is preferably made of stainless steel or any other metal or material suitable for its function. Its walls 7 may be formed of a double skin 7a-7b and a thermal insulation 8, for example consisting of rockwool, disposed between the elements 7a-7b of this double skin, in order to minimize the losses. thermal of the enclosure. Its dimensions may be a function of the nature and volume of the product to be treated, and the desired flow rate. They are, for example, between 100 mm and 3000 mm for height and width.

Advantageously, the inner surface 9 of the enclosure 1 is covered with a thermally insulating material, dielectric and infrared reflector, thereby increasing the degree of thermal insulation and a return of the infrared radiation to the inside of the enclosure 1, especially during high temperature treatments.

According to the illustrated embodiment (FIG. 2), the enclosure 1 comprises an upper part 1c of polygonal section and a lower part 1d of half-circular section. The routing and mixing means 6 are installed in the lower part 1d of said enclosure 1, close to the bottom 10 of the latter.

The upstream end of the chamber 1 is provided with at least one input 1a or several inputs 1a while the downstream end of said enclosure is provided with at least one output 1b, or several outputs 1b. The inlet 1a or each inlet 1a and the outlet 1b or each outlet 1b are, for example, circular in shape and arranged in such a way that they are microwave-tight. They may have diameters of the order of 10 mm. These inputs 1a and these outputs 1b thus make it possible to obtain a treated material flow rate of between 00 g / h and 10 T / h.

The inlet 1a or each inlet 1a is connected to an intake means 2, as shown in FIG. 1. This intake means 2 is, for example, constituted by a hopper and a tube of the order of 10 mm in diameter and 150 mm in length.

The output 1b or each output 1b is connected to an unloading means 3 of the treated product, also consisting of a tube of diameter of the order of 10 mm and length of the order of 150 mm. These intake means 2 and discharge 3 are arranged to prevent microwave leakage to the outside; they include, for example, a wave trap system known per se.

Microwave generators 4 consist of generators associated with known magnetrons. These generator sets can have unit powers of between 100 W and 100 KW (or more, depending on the state of the magnetron technology). These values may vary depending on the evolution of magnetron technology.

The microwave field thus emitted has a frequency of between 300 MHz and 6000 MHz. The microwave generators 4 are connected to the cavity C delimited by the chamber 1 by means of waveguides 5 and wave inputs 1 which may advantageously be made of quartz.

These wave inputs 11 are configured so as to pass the electromagnetic field while isolating the chamber 1 of dust and temperature.

Preferably, the waveguides 5 are connected to the upper portion 1e of the enclosure 1.

The conveying and mixing means 6 are advantageously constituted by an endless screw or Archimedean screw 12. This endless screw is installed in the lower part 1d of the enclosure 1 and it occupies all or almost all of the length of the latter.

The diameter of the worm 12 may, for example, be between 2 cm and 50 cm. The helicoidal turns 13 of the worm 12 may have different sections (flat, rectangular, cylindrical, parallelepiped or other), and participate, among other things, to homogenize the microwave field in the treatment chamber.

A space, for example of height h, between 100 mm and 300 mm, is provided between the outer diameter of the worm 12 and the upper internal surface 9 of the enclosure 1. This characteristic arrangement allows a multimode propagation of the micro in the enclosure 1.

A clearance or space e is also provided between the outer diameter of the worm 12, and the inner surface 9 in the lower semi-circular portion 1d of the enclosure 1. This clearance e is included, for example, between 1 mm and 50 mm. Preferably, it is of the order of 3 mm.

The worm 12 may be made of a conductive material, for example stainless steel, or other metal or material, to allow the creation of eddy current loops produced by the electric component of the microwave field. This phenomenon then leads to the heating of the auger 12 by Joule effect, which contributes to the warming of the product P during treatment.

The worm 12 may also be made of dielectric material, for example quartz. Indeed, although this material is less suitable for industrial use, it makes it easier to expose the product to be treated in the microwave field.

More particularly interestingly, the worm 12 is made of a metal whose resistivity allows its heating by the action of microwaves, so to very substantially improve the overall performance of the device. The helical turns 13 of the worm 12 can be directly attached to the axial core of said screw, according to a common embodiment of such worm used for the routing of products.

According to the embodiment shown in FIG. 4, the helical turns 13 of the worm 12 are attached to an axial drive shaft 14 by means of spacers 15, so that an annular space E is arranged. between the inside of said turns 13 and said axial shaft 14. This space E is intended to minimize the influence of the conveying means and stirring on the microwave field. This particular arrangement makes it possible at the same time to stiffen the turns 3 of the worm 12, in particular during high temperature heating applications, and constitutes an additional element for mixing the product P during its passage through the enclosure.

The ends of the axial core of the worm 12 or of the axial drive shaft 14 can pass through the upstream and downstream ends of the enclosure 1 via a wave trap 16, thus avoiding any leakage of microwave to the outside.

In order to allow the routing and stirring means to function properly, the ends of the axial core of the worm screw 12 or of the axial drive shaft 14 are guided in rotation, for example by means of bearings 17.

One of the ends (end 12a according to the accompanying drawings) of the worm 12 is rotated by a geared motor 18. This geared motor 18 further allows the adjustment of the feed rate of the product. P in the chamber 1, as well as the optimization of the mixing of the latter.

According to an important characteristic arrangement of the invention, the routing and mixing means 6 of the product P comprise mixing paddles 19 distributed over at least a portion of the length of said means 6. Preferably, these mixing paddles 19 are distributed over the entire length of said conveying and brewing means 6.

The mixing paddles 19 are arranged on at least one of the rotary components (turns or threads 13 or axial shaft 14) of the worm screw 12. Preferably and advantageously, the mixing paddles 19 are arranged on the turns or threads 13 of the worm 12, to optimize the mixing of the product P.

The mixing paddles 19 are preferably arranged on the downstream face (face facing the outlet of the enclosure) of the turns 13 of the worm 12 so as to attack the product by stirring.

Depending on the nature of the product to be treated, the mixing paddles 19 could also be placed on the upstream face (face facing the inlet of the chamber) of the turns 13 of the worm 12 so as to improve the stirring of said product. , or simultaneously on both sides of the turns 13, as shown in FIG.

The position, the inclination, the number, the shape and the dimensions of these mixing palettes 19 may vary, in particular as a function of the product to be treated and the dimensions and conformations of the worm 12.

For example, these pallets may be flat and rectangular (for example more or less 20 mm side). They could, depending on the product, have a beveled, concave shape ...

Advantageously, each turn 13 of the worm 12 is provided with three mixing paddles 19, spaced 120 °.

According to another example of implementation, the number of vanes 19 fitted to each turn 13 is defined by the angle β (FIG. 6).

According to one embodiment, to allow homogeneous mixing, and thus obtain a homogeneous heating of the product to be treated, mixing paddles 9 may also or alternatively be arranged on at least a portion of the length of the axial drive shaft 14, or the entire length of the latter.

The mixing paddles 19 serve to stir and hold all grains of the flow of granular material in motion relative to one another.

According to the example shown in FIG. 6, the mixing paddles 19 have an angle of inclination α with respect to the radius of the worm 12.

According to one embodiment, the mixing paddles 19 have a fixed inclination. The angle a is determined according to the characteristics of the product to be treated (granulometry, compaction, brittleness, disintegration, grain geometry, entanglement, ...) and the positioning of the pallets is made in a fixed manner, for example by welding.

According to another advantageous characteristic of the invention, the mixing paddles 19 have an adjustable inclination. For example, as illustrated in FIGS. 7a and 7b, the vanes 19 are provided with slots 26 of oblong shape and adapted to cooperate with screws 27 fixed to the turns 13 of the worm 12, so as to allow the inclination of the mixing paddles 19.

Interestingly, the heating of the material to be treated can be optimized by the provision of one or more complementary different heating sources.

For this purpose, and according to the embodiment shown, the chamber 1 may be provided with additional inputs 20 arranged to allow the introduction of additional energies (such as hot air, infrared heating, ...) in addition to the action of the microwave radiation, to increase its efficiency, and thus optimize the heat treatment of the product P considered.

The enclosure 1 is also provided with additional outlets 21 for the evacuation of these complementary energies. Advantageously, a secondary air flow can be provided by openings 22 arranged on the lower portion 1f of the enclosure 1.

Sighting tubes (not shown) may be arranged on a portion of the outer surface of the enclosure 1, or on all of the latter. These tubes are dimensioned so as to be microwaveable, and allow the adaptation of all kinds of sensors, such as temperature readers, for example, pyrometers.

According to another characteristic arrangement of the invention, the device further comprises an inclination adjustment system 23 of the previously described heat treatment assembly. The device can thus be inclined at an angle α between 0 ° and 30 °, which makes it possible to regulate the routing and stirring of the product P during its passage through the enclosure 1.

This tilt adjustment system 23 can be advantageously motorized. This tilt adjustment system 23 has the particular advantage of making it possible to make the adjustment of the feed of the product and that of the stirring independent.

In the case of low inclinations or low powers, the microwave generator sets 4, which can be fixed directly on the chamber 1, also tilt during the inclination of the device via the system 23.

For larger angles or power, it is essential to provide a tilt adjustment system on the waveguides 5, so as to keep the generator sets 4 in a perfectly horizontal position for their proper operation.

For example, a secondary tilt adjustment system 24 is disposed on the waveguides 5 of the microwave generators 4, so as to compensate for the inclination of the entire device. This system may advantageously consist of an adjustable twisted guide consisting of two parts angularly offset by half the angle according to know-how known in the art to cancel the reflected part of the wave in this twisted guide. The geared motor 18 and the drive devices of the tilt adjustment systems 23 and 24 can be regulated on the flow rate or the temperature of the product P.

According to another characteristic arrangement of the invention and considering an embodiment comprising several microwave generators, microwaves sealed walls are arranged between each wave input 11 in the enclosure 1, perpendicular to the core or to the axis of the worm 12, to define M heating modules.

This arrangement makes it possible to confine the microwave field in the module M concerned. The walls 25 are preferably made of stainless steel, or other metal or material and, according to the embodiment shown, they are arranged, spaced apart, in the upper part 1c of the chamber 1, between the inlet 1a and the output 1b thereof.

Preferably and advantageously, the intermediate walls 25 are perforated in order to let the flow of air or gas but not the microwaves.

According to another embodiment of the invention, the heat treatment device consists of two or more M modules rigidly assembled, one after the other, in alignment, to form an enclosure of variable size. In this case, each module M may comprise:

a portion of enclosure 1,

a portion of worm 12 provided with one or more mixing paddles 19, an axial drive shaft portion 14, optionally provided with one or more mixing paddles 19,

 at least one microwave generator 4,

 at least one waveguide 5.

Claims

Continuous thermal treatment device, in particular of divided materials, by microwave radiation, comprising:

 - a chamber (1), sealed to microwaves and having at least one inlet (1a) and at least one outlet (1b),

 at least one admission means (2) for the product (P) to be treated in said enclosure,

 at least one unloading means (3) for discharging said product (P) therefrom,

 at least one microwave generator (4),

 at least one waveguide (5) placed between the generator (4) of microwaves and the enclosure (1), and

 - Means for routing and mixing (6) of the product (P) constituted by a worm (12) housed in said enclosure,

characterized in that said conveying and mixing means (6, 12) are provided with mixing paddles (19) distributed over at least a portion of their length.

Device according to claim 1, characterized in that the worm (12) is made of a metal whose resistivity allows its heating by the action of microwaves, so to very substantially improve the overall performance of the device.

Device according to one of claims 1 or 2, characterized in that the mixing paddles (19) are distributed over the entire length of said conveying and mixing means (6, 12).

Device according to any one of claims 1 to 3, characterized in that the enclosure (1) comprises an upper part (1c) and a lower part (1d), and the conveying and mixing means (6, 12 ) are located in the lower part (1d) of said enclosure (1), close to the bottom (10) of the latter.

5. Device according to one of claims 1 to 4, wherein said conveying means and stirring (6, 12) comprise an endless screw (12) consisting of helical turns (13), characterized in that said screw endlessly (12) also comprises an axial shaft (14) passing through the helicoidal turns (13) of the worm (12), and separated therefrom by an annular space (E).

6. Device according to claim 5, characterized in that the mixing paddles (19) are arranged on at least one of the rotary components (13 or 14) of the worm (12).

7. Device according to claim 6, characterized in that the mixing paddles (19) are arranged on the downstream face of the turns (13) of the worm (12).

8. Device according to claim 6, characterized in that the mixing paddles (19) are arranged on the upstream face of the turns (13) of the worm (12). 9. Device according to claim 6, characterized in that the mixing paddles (19) are arranged on both sides, downstream and upstream, turns (13) of the worm (12).

10. Device according to any one of claims 7 to 9, characterized in that each turn (13) of the worm (12) is provided with three mixing paddle (19) spaced 120 °.

11. Device according to any one of claims 1 to 10, characterized in that the mixing paddles (19) are fixed with an inclination angle (a) relative to the radius of the worm (12).

12. Device according to any one of claims 1 to 10, characterized in that the inclination of the mixing paddles (19) is adjustable.

13. Device according to one of claims 5 to 12, characterized in that mixing paddles (19) are arranged on at least a portion of the drive shaft (14).

14. Device according to any one of claims 1 to 13, characterized in that it comprises a tilt adjustment system (23) of the entire heat treatment device, thus allowing the adjustment of the stirring and flow of the product (P). 5. Device according to one of claims 1 to 14, characterized in that a secondary inclination adjustment system (24) is arranged on the guides (5) of the wave generators (4), so as to compensate the inclination of the entire device. 16. Device according to one of claims 1 to 15, characterized in that it is provided with walls (25) sealed to microwaves, arranged between each wave input (11) in the chamber (1), to define heating modules.

17. Device according to any one of claims 1 to 16, characterized in that it consists of several modules (M) rigidly assembled in alignment one after the other, each module comprising:

an enclosure portion (1),

 - a portion of worm (12), provided with one or more mixing paddles (19),

 an axial drive shaft portion (14),

 at least one microwave generator (4),

 at least one waveguide (5),

 several modules thus defined that can be assembled to form an enclosure of variable size.

18. Device according to any one of claims 1 to 17, characterized in that the inner surface (9) of the enclosure (1) is covered with a thermally insulating material, dielectric and infrared reflector.

19. Device according to one of claims 1 to 18, characterized in that it comprises additional inputs (20) for the introduction of additional energies (cold or hot air, infrared, ...) in addition to micro -ondes, to increase its effectiveness.

20. Device according to any one of claims 1 to 19, characterized in that openings (22) for supplying a secondary air flow are arranged on the lower portion (1f) of the enclosure (1). ).

21. Device according to claim 20, characterized in that the intermediate walls (25) are perforated to allow the flow of air or gas but not microwaves.

22. Device according to any one of claims 1 to 21, characterized in that the worm (12) consists of a material for heating under the effect of the microwave field (eddy currents) so to increase the efficiency of the heating.