FR2775552A1 - DEVICE FOR HEATING A MATERIAL BY MICROWAVE - Google Patents

Abstract

The invention concerns a microwave source (1), of magnetron type, a waveguide (2), a set of magnetically coupled cylindrical dielectric resonators (3), and a conveyor (4) for displacing a material (MT) to be heated beneath the coupled resonators (3). The coupled dielectric resonators (3) are excited by the microwave source (1) via the waveguide (2) according to a transverse electric mode TE01. The material is placed opposite the cylindrical surfaces of the resonators. Said device is particularly adapted, in particular, for elastomer vulcanisation and polymer cross-linking.

Description

The present invention relates generally to the heating of a material, for example for the treatment of this material. More specificly,
The invention relates to a device for heating an absorbent material using a microwave field. According to a particular application of the invention, the material is an elastomer (rubber) to be vulcanized.

 Several devices for microwave heating of a dielectric / magnetic absorbent material for the treatment of this material are known. These devices apply a microwave electromagnetic field to the material to be heated. The electric / magnetic field of this microwave field then interacts with the material, so that dielectric / magnetic losses occur in the latter.

 A first type of microwave heating device essentially consists of a waveguide associated with a microwave source. The microwave electromagnetic field produced by the microwave source is directed towards the material to be heated by the waveguide. The heating efficiency obtained with this type of device is relatively low, because the microwave field applied through the material is in the form of traveling waves, the power of which cannot exceed that delivered by the microwave source. wave.

 According to a second type of microwave heating device, a metal resonator is provided to produce an electromagnetic resonance field which is applied to the material to be heated. The metal resonator is excited by a microwave source. This resonator consists of a metallic resonant cavity inside which is placed the material to be heated. This type of device allows efficient heating of the material, since the microwave field used for heating is a resonant field, the intensity of which is higher than that of the excitation field provided by the microwave source. However, it is necessary to ensure precise guidance of the material to be heated so as to position the latter in the center of the cavity, that is to say at the place where the microwave field is most intense. The metallic resonant cavities are moreover relatively bulky. Also, it is difficult, with resonant cavities, to achieve selective heating of certain parts of the material.

 The present invention aims to provide a device for heating a material by microwave capable of remedying the aforementioned drawbacks.

 To this end, a device for heating, by microwave, an absorbent material with a view, for example, to a treatment of this material, is characterized in that it comprises at least one dielectric resonator, excited by an excitation means. microwave, to produce a microwave electromagnetic field for heating at least part of the material.

 The aforementioned microwave electromagnetic field is therefore a resonant field, which makes it possible to heat the material with a higher efficiency than that obtained with heating devices not using a resonator.

 In addition, compared to microwave heating devices comprising a metal resonator, the device according to the invention offers greater flexibility of use. In particular, according to the invention, the material to be heated can be placed outside said at least one dielectric resonator since the latter, unlike metallic resonators, produces an external electromagnetic field. In this way, it is possible to carry out a selective heating of the material, that is to say to select with great precision particular areas to be heated in the material. The device according to the invention does not require complicated guide means for positioning the material to be heated inside a cavity.

 The dimensions of a dielectric resonator can be significantly reduced compared to the dimensions of a metal resonator, so that the size of the device according to the invention can be made less important than that of the metal resonator devices of the prior art.

 Advantageously, a conveyor is provided for bringing the material near said at least one dielectric resonator, and in particular in the region of the external electromagnetic field produced by said at least one dielectric resonator. The heating device can thus be integrated into an online production line>>. For example, the material to be heated is in the form of an extrudate, partly composed of an elastomer. Heating the material then makes it possible to vulcanize the latter, which can then be used, for example, for the manufacture of seals.

 Preferably, the device according to the invention comprises several dielectric resonators magnetically coupled together, at least one of the dielectric resonators being excited by the microwave excitation means. Greater power can thus be recovered from the microwave excitation means. Indeed, the power which can be transmitted from the microwave excitation means to a given dielectric resonator without risk of deterioration of the latter is limited by the breakdown threshold of the resonator. Thanks to the presence of several coupled dielectric resonators, the power supplied by the microwave excitation means is distributed between these resonators, and can therefore be increased.

 Means may be provided for adjusting the distance between two adjacent resonators given among said magnetically coupled dielectric resonators.

This typically mechanical adjustment means makes it possible to adjust the resonant frequency of the resonator assembly formed by the coupled dielectric resonators. In particular in order to obtain an optimal heating efficiency, the adjustment means can be used to precisely match the resonance frequency of the resonator assembly to the emission frequency of the microwave excitation means. According to an alternative application of the adjustment means, it is possible, by substantially varying the resonance frequency of the resonator assembly, to modify the heating power supplied to the material.

 The microwave excitation means typically comprises a microwave source for producing an electromagnetic excitation field, and a transmission means for transmitting the electromagnetic excitation field from the microwave source to said at least one dielectric resonator. . The transmission means is for example a waveguide into which metal plungers are partially introduced in order to adapt the impedance between the microwave source and said at least one dielectric resonator.

 Furthermore, in practice, the dielectric resonator (s) which is excited by the microwave excitation means is arranged opposite a window formed on an exit face of the transmission means.

Other characteristics and advantages of the present invention will emerge from the following description of particular embodiments given by way of example with reference to the accompanying drawings in which
- Figure 1 is a schematic sectional front view of a microwave heating device of a material according to the invention;
- Figure 2 is a schematic bottom view of part of the device of Figure i and
- Figures 3 and 4 respectively illustrate a bottom view and front of the magnetically coupled dielectric resonators included in the device of Figure 1;
With reference to FIG. 1, the microwave heating device according to the present invention mainly comprises a microwave source 1, of the magnetron type, a rectangular waveguide 2, a set of coupled dielectric resonators 3, and a conveyor 4. Elements 1 to 3 constitute a microwave applicator. The conveyor 4 makes it possible to scroll a material, or product, to be heated MT in a predetermined direction DR, for example horizontal. opposite the microwave applicator 1-3 and more particularly of the set of resonators 3. The heating device according to the invention also comprises support means (not shown) for holding the microwave applicator 1 -3.

 The MT material is an absorbent material, that is to say a material capable of absorbing electrical and / or magnetic energy. According to a particularly suitable application of the present invention, the MT material is an elastomer to be vulcanized, which is in the form of an extrudate.

To heat the MT material, the microwave applicator 1-3 produces a microwave electromagnetic field 5 (represented in FIG. 1 by the field lines of the corresponding electric field), through which the MT material is transported by the conveyor 4. The electromagnetic field 5 is produced by the set of resonators 3 in response to an excitation field transmitted from an antenna 10 of the magnetron I to the set of resonators 3 via the waveguide
3
The set of coupled dielectric resonators 3 is composed, according to the embodiment shown in FIG. 1, of a central resonator 30, centered relative to an output face 20 of the waveguide 2, and of two peripheral resonators 31 and 32 adjacent to the central resonator 30. Each resonator 30 to 32 has a cylindrical shape, as shown in FIGS. 1 and 4. The lines of the microwave electric field produced by the resonator 30 to 32 are thus circular around the resonator (cf. FIG. 1), while the lines of the corresponding microwave magnetic field each form a loop around a peripheral part of the resonator (see FIG. 3).

 The resonators 30 to 32 are aligned in a direction which is preferably parallel to the direction DR of travel of the material MT under the applicator 1-3, and are each separated from an adjacent resonator by a non-zero distance. The flat faces of the resonators 30-32 are perpendicular to the exit face 20 of the waveguide 2 and to the plane defined by the conveyor 4. The respective distances dl and d2 (see FIG. 2) between the adjacent resonators 30, 31 and the adjacent resonators 30, 32 parallel to the direction of alignment of the resonators are adjustable, but remain small enough for magnetic coupling to take place between the resonators. FIGS. 3 and 4 illustrate the magnetic coupling between the resonators 30-32, and in particular the coupling between the respective microwave magnetic fields (designated by 300-320) produced by them.

The dielectric resonators 30 to 32 are excited by the microwave source 1 via the waveguide 2. More precisely, the excitation microwave field produced by the source 1 and emitted by its antenna 10 is transmitted by the guide wave 2 to the central dielectric resonator 30 through a window 21, formed on the outlet face 20 of the waveguide 2 and facing the central resonator 30. The dimensions of the window 21 are preferably determined so that the excitation microwave field arrives on the central resonator 30 with an angle of
Brewster, in order to avoid any reflection of this field at the level of the window 21. The excitation microwave field excites the central resonator 30, which in turn excites, by magnetic coupling, its two adjacent resonators 31 and 32. The resonant frequency of the dielectric resonators 30 to 32 depends on the one hand on the intrinsic characteristics of each of these resonators, and on the other hand on the distances d1 and d2. Said intrinsic characteristics of the resonators 30 to 32 and the range of variation of the distances dl and d2 are chosen so that the resonant frequency of the resonators remains at all times substantially equal to the emission frequency of the magnetron l.

 By way of illustration, the dimensions of the cross section (parallel to the outlet face 20) of the waveguide 2 and of the window 21 are respectively 86 mm x 43 mm and 20 mm x 40 mm. The diameter and height of a given resonator 30 to 32 are 21 mm and 11 mm respectively.

 An impedance matching means associated with the waveguide 2 is also provided for adapting the impedance between the magnetron 1 and the set of coupled resonators 3. The impedance matching means is for example constituted by metal plungers 22, playing the role of a capacitor, partially introduced through a lateral face 23 of the waveguide 2 in a substantially central part of it, as shown in FIG. 1.

 According to the invention, the distances dl and d2 between adjacent resonators are adjustable respectively by two identical mechanical mechanisms 61 and 62, shown diagrammatically in FIG. 2, associated with the peripheral resonators 31 and 32. Each mechanism 61, 62, when is actuated, brings closer or apart the peripheral resonator 31, 32 of the central resonator 30. The peripheral resonators 31 and 32 are for this purpose slidably mounted parallel to their direction of alignment. A variation of at least one of the distances d1 and d2 results in a corresponding variation in the resonance frequency of the set of coupled resonators 3.

 The heater according to the present invention can be used to selectively heat certain parts of the MT material. The positioning of the MT material on the conveyor 4 can in fact be adjusted relative to the resonators 30 to 32, depending on the zones of the material that it is more particularly desired to heat. Also, the conveyor 4 can be replaced by a movable plate in at least two directions, in order to increase the precision of the guidance of the material with respect to the resonators.

 The heating device according to the present invention has been described with three dielectric resonators coupled by way of example only. it will be clear to those skilled in the art that a different number of resonators can be used. In particular, the heating device can comprise only the central resonator 30, the peripheral resonators 31 and 32 being omitted.

 Although the present invention is particularly suitable for the vulcanization of elastomers, the device according to the invention can be used to heat other absorbent materials, such as heat-transformable materials, for example of the polyester type, etc.

 The material to be heated MT is preferably in solid or liquid form.

When the MT material is liquid, it is brought before the microwave applicator by the conveyor 4 in a suitable receptacle, transparent to microwaves.

Claims (9)

 CLAIMS 1. Device for heating an absorbent material (MT) by microwave for example for the treatment of this material, characterized in that it comprises at least one dielectric resonator (3), excited by means microwave excitation (1, 2), to produce a microwave electromagnetic field (5) intended to heat at least part of the material (MT).  2. Device according to claim 1, in which the material (MT) is placed outside said at least one dielectric resonator (3). 3. Device according to claim 1 or 2, further comprising a conveyor (4) for bringing the material (MT) near said at least one dielectric resonator (3). 4. Device according to any one of claims 1 to 3, wherein said at least one dielectric resonator (3) consists of several dielectric resonators (30-32) magnetically coupled together, at least one (30) of said dielectric resonators being excited by the microwave excitation means 2). 5. Device according to claim 4, further comprising means (6 "62) for adjusting the distance (dl, d2) between two adjacent resonators given among said magnetically coupled dielectric resonators (30-32). 6. Device according to any one of claims 1 to 5, wherein said microwave excitation means comprises a microwave source (1) for producing an electromagnetic excitation field, and a transmission means (2 ) for transmitting the electromagnetic excitation field from the microwave source (1) to said at least one dielectric resonator (30). 7. Device according to claim 6, wherein said transmission means is a waveguide (2), in which metal plungers (22) are partially introduced to adapt the impedance between the microwave source (1) and said at least one dielectric resonator (30). 8. Device according to claim 6 or 7 when it depends at least on claim 4, wherein the (or) dielectric resonator (s) (30) which is excited by the micro-excitation means wave is arranged opposite a window (21) formed on an outlet face (20) of the transmission means (2). 9. Device according to any one of claims 1 to 8, wherein said material (MT) comprises an elastomer, and said treatment comprises vulcanization of the elastomer.