FR2963824A1 - Magnetic field generator for magnetocaloric thermal apparatus utilized in e.g. heating field, has magnetizing structure creating constant magnetic field in air gap, and ferromagnetic elements placed face to face with spacing forming air gap - Google Patents

Abstract

The generator (1) has a magnetizing structure (2) creating constant magnetic field in an air gap (3) in which a magnetocaloric element is arranged. The structure has magnetic poles (5, 6) arranged opposite to each other on both sides of a plane of symmetry. Each pole is formed by an assembly of permanent magnets (7, 8) and a ferromagnetic element (9). The ferromagnetic element has a face (F1) projecting with respect to an assembly forming the magnetic poles. The ferromagnetic elements are placed face to face with a spacing forming the air gap of the structure. An independent claim is also included for a method for mounting a magnetic field generator for a magnetocaloric thermal apparatus.

Description

MAGNETIC FIELD GENERATOR FOR MAGNETOCALORIC THERMAL APPARATUS AND METHOD OF MOUNTING SUCH A GENERATOR Technical Field:

The present invention relates to a magnetic field generator for a magnetocaloric thermal apparatus, said magnetic field generator comprising at least one magnetizing structure creating a constant magnetic field in at least one gap in which at least one magnetocaloric element is disposed, said magnetizing structure comprising first and second magnetic poles arranged facing each other on each side of a plane of symmetry and each constituted by an assembly of permanent magnets and a ferromagnetic element.

The invention also relates to a method of mounting such a magnetic field generator.

PRIOR ART In order economically to obtain a large magnetic field in a defined space, it is known to produce an assembly of permanent magnets. The literature describes such assemblies in particular for an application in the field of medical magnetic resonance imaging. In this field, one makes permanent magnet crowns that are arranged side by side. The permanent magnets used, however, have a complex geometric structure difficult to achieve, which increases the cost of the assembly of magnets. The transposition of such magnet structures is therefore not possible in the context of smaller volume applications, and in particular in the field of magnetocaloric thermal generators. Indeed, in these devices, it is essential to generate a uniform and intense magnetic field in an air gap substantially corresponding to the volume of a magnetocaloric material or element so that the magnetic field created can successively activate and deactivate magnetically one or more magnetocaloric materials alternately introduced and removed from the gap. The larger the magnetic field, the greater the magnetocaloric effect of a magnetocaloric element or material, which will have the effect of increasing the thermal power and therefore the efficiency of such a magnetocaloric thermal device.

Moreover, in these devices, it is further desirable that no magnetic field remains outside the gap. This makes it possible to increase the magnetocaloric effect, which is directly dependent on the magnetic field difference undergone by the magnetocaloric material between its position in the gap and its position outside the gap. If there is a magnetic field outside the air gap, the magnetocaloric elements do not go from a zero magnetic field to a strong magnetic field between these two positions. The efficiency of the apparatus is therefore not optimal because the efficiency of the magnetocaloric cycles and the magnetocaloric effect are limited.

Presentation of the invention

The present invention aims at overcoming these disadvantages by proposing a magnetic field generator intended to be integrated in a magnetocaloric thermal apparatus and having an intense, uniform and concentrated field in its gap. This magnetic field generator is also easy to produce, has an easy assembly and components of simple geometric shapes and therefore low cost.

For this purpose, the invention relates to a magnetic field generator as defined in the preamble, characterized in that said ferromagnetic element has a face F1 projecting from the assembly forming said magnetic pole and in that the two ferromagnetic elements of said magnetizing structure are arranged face to face with a spacing forming said at least one gap of said magnetizing structure.

The magnetocaloric elements are intended to be in thermal contact with a coolant circulating from their cold end towards their hot end during a first phase of the magnetic cycle which corresponds to a phase in which the materials or magnetocaloric elements are subjected to an increase. their temperature and their hot end towards their cold end during a second phase of the magnetic cycle in which the materials or magnetocaloric elements are subjected to a decrease in their temperature. The thermal contact between the heat transfer fluid and the magnetocaloric elements can be achieved by a heat transfer fluid passing along or through magnetocaloric materials. For this purpose, the magnetocaloric elements may be constituted by one or more magnetocaloric materials and may be permeable to the coolant. They may also include fluid flow passages extending between the two ends of the magnetocaloric materials. These passages may be made by the porosity of the magnetocaloric materials, or by machined channels or obtained by a set of magnetocaloric material plates.

Preferably, the coolant is a liquid. For this purpose, it is for example possible to use pure water or added antifreeze, a glycol product or brine.

In each magnetic pole, the ferromagnetic element may comprise a quadrangular cross section, each of its three faces F2, F3, F4 located outside said gap being in contact with a face of a corresponding permanent magnet.

The faces F2, F4 of the ferromagnetic element may be substantially perpendicular to the face F1 located in the gap and are in contact with a face of a permanent magnet said lateral magnet whose direction of magnetization is substantially perpendicular to said perpendicular faces F2, F4.

The face F3 of the ferromagnetic element, opposite to the face F1 located in the gap and said opposite face F3, is advantageously in contact with a permanent magnet said opposite magnet whose magnetization direction is substantially perpendicular to said opposite face F3 .

The faces of the permanent magnets and the ferromagnetic element in contact are preferably of identical shape and size.

In the first magnetic pole, the magnetization direction of the side magnets and the opposite magnet can be oriented opposite to the ferromagnetic element and, in the second magnetic pole, the magnetization direction of the side magnets can be oriented towards the ferromagnetic element, in a direction opposite to that of the side magnets of the first magnetic pole, and the magnetization direction in the opposite magnet being the same as that of the opposite magnet of the first magnetic pole.

In each magnetic pole, the side magnets may have a parallelepipedal cross-section and the opposing magnets may have two faces in contact with corresponding faces of the side magnets of identical shape and size.

The first and second magnetic poles may respectively comprise first and second magnetic field conductive fasteners made of a ferromagnetic material and having a contact surface with a corresponding face of the opposite magnet of said first and second magnetic poles.

A magnet or a ferromagnetic piece may be disposed in the plane of symmetry between said first and second magnetic poles and may form an air gap with each of the two corresponding faces F 1 of the ferromagnetic elements of said first and second magnetic poles.

Said generator may comprise two mounting frames laterally closing said generator and arranged in a plane substantially perpendicular to the plane of symmetry.

Said generator may comprise a single magnetizing structure, the mounting armatures being able to be made of a ferromagnetic material and laterally connecting said first and second magnetic poles.

It may also include at least two magnetizing structures arranged side by side, said mounting frames being made of a non-magnetic material.

The mounting frames may be in contact with an opposing magnet and a side magnet of said first and second magnetic pole and the fasteners may have a boss in the two areas adjacent to the contact surfaces between each mounting frame and the magnet. opposite opposite.

The mounting frames may consist of two parts connected together in an adjustable spacing. Each mounting armature may comprise a permanent magnet on its side wall facing the magnetizing structure and whose direction and the magnetization direction of said permanent magnet are identical to those of the opposite magnets of said magnetizing structure.

For this purpose also, the invention relates to a method of mounting such a magnetic field generator, characterized in that it consists in: a) producing a first assembly comprising a first magnetic pole and a first part of two armatures of assembly, b) forming a second assembly comprising a second magnetic pole and the other part of said two mounting frames, c) arranging said two assemblies opposite one another so as to form an air gap by a translational movement of one with respect to the other parallel to a plane of symmetry.

Steps a) and b) may consist of: i) connecting a ferromagnetic element of quadrangular section to a magnetic field conducting fastening device by interposing a permanent magnet said opposite magnet, for example by screwing, ii) connect each of the two permanent magnets with parallelepipedal section called side magnets with a part of two mounting frames, for example by gluing, iii) then connect together the subsets from a) and b) so that each side magnet has a surface in contact with the ferromagnetic element and a surface in contact with the opposite magnet and that each part of the two mounting plates has a surface in contact with a fixing device, for example by screwing the fixing device to the part of said mounting frames.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention and its advantages will appear better in the following description of three embodiments given as non-limiting examples, with reference to the appended drawings, in which: FIG. 1 is a perspective view of a first embodiment of a magnetic field generator according to the invention,

FIG. 2 is a cross-sectional view of the magnetic field generator of FIG. 1 representing the lines of the magnetic field,

FIG. 3 is a front view of a variant of the generator of FIG. 1,

FIG. 4 is a front view illustrating another variant of the generator of FIG. 1; FIG. 5 is a cross-sectional view of the generator of FIG. 4 representing the lines of the magnetic field; FIG. in cross-section of another embodiment of the generator of FIG. 1 representing the lines of the magnetic field; FIG. 7 is a cross-sectional view of a second embodiment of the magnetic field generator comprising two airgaps and illustrating the lines of the magnetic field; FIG. 8 is a cross-sectional view of a third embodiment of the magnetic field generator having two magnetizing structures and illustrating the magnetic field lines, and FIGS. 9A, 9B , 10A, 10B, 11A, 11B and 12 show the various steps of mounting the magnetic field generator shown in FIG.

Illustrations of the Invention: FIG. 1 represents an elementary embodiment of a magnetic field generator 1 according to the invention. In this case, this magnetic field generator 1 is composed of a single magnetizing structure 2 comprising two magnetic poles 5 and 6 arranged facing one another by delimiting an airgap 3. The first magnetic pole 5 is constituted by a assembly of permanent magnets 7 and 8 and a ferromagnetic element 9. With the exception of the magnetization direction of the permanent magnets 7 and 8, the two magnetic poles 5 and 6 are identical.

In each magnetic pole 5, 6, the ferromagnetic element 9 forms a magnetic field concentrator and protrudes from the permanent magnets 7 and 8. It has a rectangle-shaped cross-section and four lateral faces F1, F2, F3 and F4. A side face F1 is located in the gap 3. The faces F2 and F4 which are perpendicular to the face F1 located in the air gap 3 and called perpendicular faces F2, F4 are fixed or intimately each connected to a permanent magnet said lateral magnet 7. Each lateral magnet 7 has a parallelepipedal section and the faces F2 and F4 of the ferromagnetic element 9 have the same dimension as the corresponding faces of the lateral magnets 7. The face F3 of the ferromagnetic element 9 said opposite face F3 and opposite the face F1 located in the gap is fixed or intimately connected to a magnet said opposite magnet 8. This opposite magnet 8 also has a face whose dimension corresponds to that of the corresponding face F3 of the ferromagnetic element 9. It presents in addition, a hexagonal cross-section of which two faces are of the same dimension as one face of each lateral magnet 7 to which they are attached or intimately related.

The two sets each consisting of two lateral magnets 7 and an opposite magnet 8 fixed to a ferromagnetic element 9 and forming the two magnetic poles 5, 6 are connected to one another laterally by two mounting armatures 15 made of a ferromagnetic material and forming a return of the magnetic field. In the variant shown, each mounting arm 15 is in contact with a side of a lateral magnet 7 and a face of the opposite magnet 8 of each magnetic pole 5, 6.

Preferably, and as is apparent from Figures 1 and 2, the mounting armatures 15 have a shape comprising a recess in which one or more magnetocaloric elements 4 can be arranged. Indeed, the magnetic field generator 1, 10, 20, 30, 40, 50 according to the invention is intended to subject at least one magnetocaloric element 4 to a variable magnetic field by a relative movement of said magnetocaloric element 4 with respect to the gap 3, 13, 23 of said magnetic field generator. Thus, it is necessary, on the one hand, to provide an air gap 3, 13, 23 whose volume makes it possible to position at least one magnetocaloric element 4 so that it undergoes an intense and constant magnetic field and secondly , to provide a volume outside this air gap 3 and in which the magnetic field is zero or very low and may include said magnetocaloric element 4. This volume outside the gap 3 may be the internal volume of the generator magnetic field out of its air gap 3, 13, 23 or the volume located outside the magnetic field generator.

For this purpose, in the magnetic field generator 1 configuration shown in FIG. 1, the volume outside the gap 3 is delimited by the two mounting plates 15 which have a substantially C-shaped section. 15 can be made in one piece or by assembling several parts 18, 19 as shown in Figure 3 illustrating a magnetic field generator 10 according to a first variant. In the magnetic field generators 1 and 10 of FIGS. 1 to 3, said magnetocaloric material or element 4 moves on either side of the air gap 3 laterally, in the direction of a mounting frame 15 and then of the other (see arrow F) to undergo successive heating and cooling according to its position in or out of the gap 3.

Advantageously, the magnetic field generators 1 and 10 also comprise two fixing devices 11, 12 made of a ferromagnetic material which form a magnetic bridge and a mounting plate. Each fixing device 11, 12 is in contact with an opposite magnet 8 of a magnetic pole 5, 6 and with the two mounting plates 15.

With regard to the magnetization of the magnets 7, 8, the magnetization direction of the lateral magnet 7 is perpendicular to the perpendicular faces F2, F4 and the magnetization direction of the opposite magnet 8 is perpendicular to said opposite face F3. In the first magnetic pole 5, the magnetization direction of the side magnets 7 and the opposite magnet 8 is oriented opposite the ferromagnetic element 9 and in the second magnetic pole 6, the magnetization direction of the magnets 7 is oriented towards the ferromagnetic element 9, namely in a direction opposite to that of the side magnets 7 of the first magnetic pole 5 and the magnetization direction in the opposite magnet 8 is the same as that of the opposite magnet 8 of the first magnetic pole 6.

Such a configuration makes it possible to obtain an intense field in the gap 3 with few magnets and magnets of easy configuration, presenting a low cost price. By way of example, in the magnetic field generator 1 according to the invention, a magnetic field of 1.22 Tesla is obtained in the gap 3 of thickness e equal to 16 millimeters and permanent magnets 7 and 8 of 1.41 Tesla. The lines of the magnetic field flowing in this magnetic field generator 1 are illustrated in FIG. 2. It can be seen that these lines are numerous and predominant in the gap 3 in which a magnetocaloric element 4 is arranged.

In the magnetic field generator 10 shown in FIG. 3, the two magnetic poles 5 and 6 may be arranged according to a variable variation making it possible to adjust the thickness e of the gap 3 as a function of that of the magnetocaloric element 4 and also the intensity of the magnetic field. This adjustment is achieved through the two mounting frames 15 which each consist of two parts 18 and 19 whose spacing is adjustable by a screw system or other suitable means.

FIGS. 9A, 9B, 10A, 10B, 11A, 11B and 12 show the various steps of mounting of the magnetic field generator 10 described with reference to FIG.

A first mounting step (step i) shown in FIGS. 9A and 9B consists in fixing by bonding or any equivalent means the face of a lateral magnet 7 to a part 18, 19 of a mounting frame 15. This step is performed for the four lateral magnets 7 of the magnetic field generator 10. A second step (step ii) shown in FIGS. 10A and 10B consists of interconnecting by clamping, screwing or any equivalent means, a ferromagnetic element 9 of quadrangular section to a fastening device 11, 12 of ferromagnetic material by interposing an opposing magnet 8, this opposite magnet 8 being able to be in simple abutment or partially embedded in said fixing device 11, 12. These two steps i) and ii) can be realized independently in any order.

The next step (step iii) shown in FIGS. 11A and 11B consists in connecting the subsets derived from steps i) and ii) so that each lateral magnet 7 comprises a surface in contact with the ferromagnetic element 9 and a surface in contact with the opposite magnet 8 and that each portion 18, 19 of a mounting frame 15 has a surface in contact with a fixing device 11, 12. Here also a screw fixing is performed between each fixing device 11, 12 and the corresponding part 18, 19 of the mounting frames 15. Thus two sets 24, 25 are obtained.

The last step shown diagrammatically in FIG. 12 consists in positioning said assemblies 24, 25 facing each other, aligned in their axis of symmetry, and moving them by a translation movement of the one relative to the other parallel to the plane of symmetry P so that the parts 18 and 19 of the two mounting plates 15 accost simultaneously and self-position, to bring the two ferromagnetic elements 9 face to face and form the gap 3.

The fixing of the two assemblies 24, 25 relative to one another can be carried out with variable adjustment of the distance separating them by providing a shim 13 (see FIG 4) or a screw adjustment system or the like.

Figures 4 and 5 show a magnetic field generator 20 according to another embodiment. This magnetic field generator 20 has the same advantages and the same magnetic field strength in the gap 3 as those relating to the magnetic field generators 1, 10 shown in FIGS. 1 to 3.

It differs from the magnetic field generator 10 of FIG. 3 by the presence of a shim 13 disposed between the parts 18 and 19 of the mounting armature 15, the thickness of which is chosen as a function of the air gap 3. is also distinguished by the presence of a boss 17 made in each fixing device 11, 12 at the areas adjacent to the contact surfaces between each mounting frame 15 and an opposite magnet 8. These bosses 17 can avoid a possible saturation of the magnetic field in said fixing devices 11, 12 and thus make it possible to guarantee a maximum magnetic field in the gap 3. FIG. 5 illustrates the magnetic field in said magnetic field generator 20 in which the spacing between the two parts 18 and 19 of each mounting frame 15 is zero. Figure 6 shows a magnetic field generator 30 according to yet another alternative embodiment. This magnetic field generator 30 further increases the magnetic field in the gap 3 to 1.36 Tesla. It differs from the magnetic field generator 20 shown in Figures 4 and 5 in that the inner wall of each mounting frame 15 comprises a permanent magnet 21 whose direction and direction of magnetization are identical to those of the opposite magnets 8.

In the magnetic field generator 30 illustrated in FIG. 6, the magnetocaloric element or elements 4 are intended to move in the direction perpendicular to that of their displacement in the magnetic field generator 1, 10 represented in FIGS. 1 to 3. However, it is also possible to arrange a volume for positioning said magnetocaloric elements 4 in the enclosure of this magnetic field generator 30. Such an arrangement can be easily obtained by modifying the shape of the two mounting plates 15, for example by their affecting a more arcuate shape than that shown in Figure 6.

The magnetic field generator 40 shown in FIG. 7 differs from that of FIG. 6 in that it comprises two gaps 13 and 23. A magnet 14 whose direction and direction of magnetization is identical to those of the magnets. opposed 8 is positioned between the two ferromagnetic elements 9 of the magnetizing structure 2. This magnet 14 can be replaced by a ferromagnetic part. The holding in position of this magnet or of this part 14 can be achieved by means of a thermoplastic material or by any other equivalent device, magnetic or nonmagnetic. This magnet or this part 14 thus forms with each ferromagnetic element 9 a gap 13, 23.

The advantage of this configuration lies in the fact that for a space and a weight substantially equivalent to those of the magnetic field generators 1, 10, 20 and 30 already described it is possible to obtain two air gaps 13, 23 may solicit more of magnetocaloric elements 4 and thus to increase the efficiency of a thermal apparatus comprising said magnetic field generator 40.

The generator 50 of magnetic field shown in Figure 8 comprises, meanwhile, two magnetizing structures 2 identical and arranged side by side. To obtain a maximum magnetic field in the air gap 3 of each magnetizing structure 2, it is necessary for the first magnetic pole 5 of a magnetizing structure 2 to be arranged next to the second magnetic pole 6 of the other magnetizing structure 2. allows for a magnetic loop between the two magnetizing structures 2. In this configuration, the mounting frames 16 are made of a non-magnetic material.

This configuration also makes it possible to magnetically solicit more magnetocaloric elements 4 and thus to increase the efficiency of a thermal apparatus comprising said magnetic field generator 50.

The configuration of the magnetic field generator 1, 10, 20, 30, 40, 50 according to the invention makes it possible to use permanent magnets 7, 8, 14 whose shape is easy to produce and whose magnetization is anisotropic.

The magnetic field generators 1, 10, 20, 30, 40 and 50 illustrated by all the figures are intended to be integrated in a thermal apparatus comprising at least one magnetocaloric element 4. This magnetocaloric element 4 may be constituted by one or a plurality of magnetocaloric materials 4 and is traversed or in contact by a heat transfer fluid circulating alternately towards a first end of said magnetocaloric element 4 and then towards its second end, in a manner synchronized with the change of position of said magnetocaloric element 4, in and out of the gap 3.

Preferably, the magnetocaloric element 4 is slidably mounted in the air gap 3, 13, 23 of the magnetic field generator and driven in a reciprocating translation movement or continuous rotation. Possibilities of industrial application:

It is clear from this description that the invention makes it possible to achieve the goals set, namely to propose a magnetic field generator whose construction is structurally simple and economical and which makes it possible to obtain a large magnetic field with relatively little material. magnetized. Such a generator can in particular find an industrial as well as a domestic application when it is integrated in a magnetocaloric heat device intended to be used in the field of heating, air conditioning, tempering, cooling or others, at competitive costs. and with a small footprint.

The present invention is not limited to the embodiments described but extends to any modification and variant obvious to a person skilled in the art while remaining within the scope of protection defined in the appended claims.

Claims (19)

REVENDICATIONS1. Magnetic field generator (1, 10, 20, 30, 40, 50) for a magnetocaloric thermal apparatus, said magnetic field generator (1, 10, 20, 30, 40, 50) comprising at least one magnetising structure (2) creating a constant magnetic field in at least one air gap (3) in which at least one magnetocaloric element (4) is arranged, said magnetising structure (2) having a first (5) and a second (6) magnetic poles arranged facing each other each other on each side of a plane of symmetry (P) and each constituted by an assembly of permanent magnets (7, 8) and a ferromagnetic element (9), a magnetic field generator characterized in that said ferromagnetic element (9) has a surface (Fl) protruding from the assembly forming said magnetic pole (5, 6) and in that the two ferromagnetic elements (9) of said magnetizing structure (2) are arranged face to face with a spacing forming minus one gap (3, 13, 23) of said magnetizing structure (2). 2. Generator according to claim 1, characterized in that, in each magnetic pole (5, 6), said ferromagnetic element (9) has a quadrangular cross section and in that each of its three faces (F2, F3, F4 ) outside said gap (3, 13, 23) is in contact with a face of a corresponding permanent magnet (7, 8). 3. Generator according to claim 2, characterized in that the faces (F2, F4) of the ferromagnetic element (9) are substantially perpendicular to the face (F1) located in said gap (3, 13, 23) and are in contact with a face of a permanent magnet said lateral magnet (7) whose magnetization direction is substantially perpendicular to said perpendicular faces (F2, F4). 16 4. Generator according to claim 2, characterized in that the face (F3) of the ferromagnetic element (9), opposite to the face (F1) located in said gap (3, 13, 23) and said opposite face (F3 ), is in contact with a permanent magnet said opposite magnet (8) whose magnetization direction is substantially perpendicular to said opposite face (F3). 5. Generator according to any one of claims 2 to 4, characterized in that the faces of the permanent magnets (7, 8) and the ferromagnetic element (9) which are in contact are of identical shape and size. 10 Generator according to claims 3 and 4, characterized in that in the first magnetic pole (5) the direction of magnetisation of the side magnets (7) and the opposite magnet (8) is oriented at the opposite to the ferromagnetic element (9) and in that, in the second magnetic pole (6), the magnetization direction of the lateral magnets (7) is oriented towards the ferromagnetic element (9) in a direction opposite to that lateral magnets (7) of the first magnetic pole (5) and the magnetization direction in the opposite magnet (8) being the same as that of the opposite magnet (8) of the first magnetic pole (5). 7. Generator according to any one of claims 2 to 6, characterized in that in each magnetic pole (5, 6) the lateral magnets (7) have a parallelepipedal cross-section and the opposing magnets (8) have two faces in contact with corresponding faces of the side magnets (7) and are of identical shape and size. 25 8. Generator according to any one of claims 2 to 7, characterized in that said first (5) and second (6) magnetic poles respectively comprise a first (11) and second (12) field-conducting attachment devices magnetic material made of a ferromagnetic material and having a contact surface with a corresponding face of the opposite magnet (8) of said first (5) and second (6) magnetic poles. 9. Generator according to any one of the preceding claims, characterized in that a magnet or a ferromagnetic part (14) is arranged in the plane (P) between said first (5) and second (6) magnetic poles and forms an air gap (13, 23) with each of the two corresponding faces (F 1) of the ferromagnetic elements (9) of said first (5) and second (6) magnetic poles. 10. Generator according to any one of the preceding claims, characterized in that it comprises two mounting frames (15, 16) laterally closing said magnetic field generator (1, 10, 20, 30, 40, 50) and disposed in a plane substantially perpendicular to the plane of symmetry (P). 11. Generator according to claim 10, characterized in that it comprises a single magnetizing structure (2) and in that said mounting plates (15) are made of a ferromagnetic material and laterally connect said first (5) and second ( 6) magnetic poles. 12. Generator according to claim 10, characterized in that it comprises at least two magnetizing structures (2) arranged side by side and in that said mounting frames (16) are made of a non-magnetic material. 13. Generator according to claim 11, characterized in that said mounting plates (15) are in contact with an opposite magnet (8) and a lateral magnet (7) of said first and second magnetic poles (5, 6) and said fixing devices (11, 12) have a boss (17) in the two areas adjacent to the contact surfaces between each mounting frame (15) and the corresponding opposing magnet (8). 18 14. Generator according to claim 11, characterized in that said mounting frames (15) consist of two parts (18 and 19) interconnected in an adjustable spacing. 15. Generator according to claim 11, characterized in that each mounting armature (15) comprises a permanent magnet (21) on its side wall facing said magnetizing structure (2) and whose direction and direction of rotation. magnetization of said permanent magnet (21) are identical to those of the opposite magnets (7) of said magnetizing structure (2). 16. A method of mounting a magnetic field generator (1) for a magnetocaloric thermal apparatus, characterized in that it consists in: a) producing a first assembly (24) comprising a first magnetic pole (5) and a first portion (18) of two mounting frames (15), b) providing a second assembly (25) having a second magnetic pole (6) and the other portion (19) of said two mounting frames (15), c) having said two assemblies (24, 25) facing each other so as to form an air gap (3) by translational movement of one with respect to the other parallel to a plane of symmetry (P) . 17. Method according to claim 16, characterized in that the steps a) and b) consist in: i) connecting a ferromagnetic element (9) of quadrangular section to a fixing device (11, 12) conducting magnetic field in interposing a permanent magnet (8) said opposing magnet, ii) connecting each of the two permanent magnets (7) of parallelepipedal section called side magnets to a portion (18, 19) of two mounting frames (15), iii) and then connect together the subsets from a) and b) so that each side magnet (7) has a surface in contact with the ferromagnetic element (9) and a surface in contact with the opposite magnet (8) and that each part (18, 19) of the two mounting plates (15) has a surface in contact with a fixing device (11, 12). 18. A method according to claim 17, characterized in that step i) is carried out by screwing, in that step ii) is carried out by gluing and in that step iii) is performed by screwing said device Fixing (11, 12) to said portion (18, 19) of said mounting frames (15).