EP3347656A1 - Method for manufacturing a single-piece magnetocaloric element, magnetocaloric element obtained and thermal apparatus including at least one such magnetocaloric element - Google Patents

Abstract

The present invention relates to a method for manufacturing a single-piece magnetocaloric element, wherein at least one supporting part (SI) is manufactured from at least one mechanically strong material and said supporting part (SI) is at least partially covered with at least one material having a magnetocaloric effect. The covering step consists in mechanically joining, or even intimately bonding, the magnetocaloric material to the supporting part, so as to manufacture a magnetocaloric element that takes the form of a single-piece part. The magnetocaloric element obtained thus includes a mechanical core that ensures the mechanical strength thereof and a thermal surface providing it with the ability to exert a magnetocaloric effect.

Description

 METHOD FOR MANUFACTURING A MONOBLOC MAGNETOCALORIC ELEMENT, MAGNETOCALORIC ELEMENT OBTAINED AND

THERMAL APPARATUS COMPRISING AT LEAST ONE MAGNETOCALORIC ELEMENT

Technical area :

The present invention relates to a method for manufacturing a monobloc magnetocaloric element. It also relates to a magnetocaloric element thus obtained. The invention further relates to the use of at least one magnetocaloric element in a thermal apparatus and said thermal apparatus comprising at least one magnetocaloric element.

Prior art:

Magnetic cold technology is based on the magnetocaloric effect (EMC) of some materials, which is a change in temperature when subjected to a magnetic field. It suffices to subject these materials to a succession of magnetization and demagnetization cycles and to perform a heat exchange with a coolant to achieve the widest possible temperature variation. By way of example, the efficiency of such a magnetic refrigeration cycle is about 30% greater than that of a conventional refrigeration cycle, which makes this technology particularly attractive for air conditioning or domestic refrigeration applications. However, this technology is applicable in many thermal domains such as heating, tempering, freezing, cryogenics, etc.

The magnetocaloric effect (EMC) is maximum when the temperature of the material is close to its Curie temperature, the Curie temperature (Te) being the temperature at which the material loses its spontaneous magnetization. Above this temperature, the material is in a disordered state called paramagnetic.

Certain magnetic materials such as gadolinium, lanthanum or some manganese-iron alloys (MnFe) have magnetocaloric properties particularly well suited to the aforementioned applications. Among the alloys, and in particular those based on silicon (Si), it is known, according to the desired Curie temperatures, to use alloys based on lanthanum-iron-silicon-cobalt LaFeSiCo or based on lanthanum-iron. silicon-cobalt with hydrogen LafeSi (H), in which the insertion of light atoms, such as hydrogen or cobalt in LaFeSi compounds, is an effective way to increase and / or adjust the temperature of Curie while maintaining the EMC effect of the material at a high level. These materials are particularly interesting because of their magnetocaloric properties combined with reduced manufacturing costs, allowing more favorable mass applications in terms of material cost and ecological impact than those obtained with materials known for their natural EMC effect such as than gadolinium.

In general, to exploit the thermal properties of magnetocaloric materials, magnetic cold technology relies on the interaction of these materials with a coolant, often consisting of a preferably aqueous liquid. Thus, in a thermal apparatus exploiting the magnetocaloric effect, a magnetic system is used capable of varying the intensity of the magnetic field that is applied to the magnetocaloric material. Under the effect of changes in magnetic field strength, the magnetocaloric material heats up almost instantaneously when it is placed in the magnetic field or when it undergoes increasing field strength and cools according to the same thermal dynamics when it is removed from the magnetic field or when it undergoes a decreasing magnetic field strength. During these magnetic phases, the magnetocaloric material is traversed by a fluid called coolant that will be moved in one direction when the material is magnetized and in the opposite direction when the material is demagnetized, to recover the heat of the material (for heating applications) or to provide heat to it (for refrigeration applications) from the heat transfer fluid of a heat exchange by establishing a temperature gradient in said magnetocaloric material.

Thus, a magnetic cycle comprises:

 a magnetization phase (magnetic state = 1);

 a phase of demagnetization (magnetic state = 0)

which results in a thermal energy available at each phase.

This magnetic cycle is repeated up to frequencies of several hertz. As the frequency increases, the thermal power (for example: cooling) delivered by the magnetocaloric heat device also increases. In order for this thermal power to increase in proportion to the increase in the frequency, it is necessary to create thermal exchange characteristics between the magnetocaloric material and the heat transfer fluid which make it possible to increase this thermal flux. The geometry of a part made in one or more magnetocaloric materials is therefore essential to ensure optimal heat exchange between said part and the coolant circulating in contact therewith. However, this geometry is dictated and limited by the magnetocaloric material. Indeed, the raw magnetocaloric material or the alloy of magnetocaloric materials, according to its composition, has characteristics of ductility, mechanical strength, etc. which are peculiar to it and which limit its capacity to be put in a particular form to render it fit to be exploited in a magnetocaloric thermal apparatus. These constraints explain that currently, there is mainly on the market plates made from an alloy of magnetocaloric material capable of being laminated or sintered. These plates are then positioned so as to be spaced parallel to the to one another by means of spacers, for example, in a thermal apparatus to form rectilinear channels for circulating a coolant. There are also blocks of porous magnetocaloric material made from powder, beads or spheres of magnetocaloric material, by an agglomeration or sintering process.

The publications EP 2 541 167 A2 and WO 2014/019941 A1 disclose processes for the manufacture by extrusion of magnetocaloric material, which do not make it possible to manufacture a magnetocaloric part according to various or complex geometric shapes adapted to the intended application.

The publications EP 2 762 801 A1, US 2005/0241134, WO 2008/099235 A1 disclose other methods of manufacture which provide for enclosing the magnetocaloric material in the form of powder or beads in a metal envelope. This envelope necessarily has a very high thermal conductivity to allow heat exchange between the magnetocaloric material and the coolant flowing outside the envelope. However, the presence of the metal envelope generates eddy currents under the effect of the magnetic field, creating heat that will interfere with the thermal performance of the generator. It also creates a thermal flux that will increase the thermal conductivity in the longitudinal direction of the magnetocaloric piece between its hot and cold ends, having the technical effect of dropping the temperature gradient. The magnetocaloric materials have the advantage of having a low thermal conductivity and the presence of a metal casing thus goes against the desired result, namely to create a temperature gradient between the opposite ends of the magnetocaloric piece.

There is thus a need to be able to have magnetic elements having a magnetocaloric effect and whose shape can be freely chosen and easily adapted to the thermal apparatus in which they are intended to be arranged, while enabling a manufacturing process that is simple to implement and economical, and that guarantees mechanical strength and durability throughout the life cycle of use of the magnetocaloric elements. Presentation of the invention

In this context, the present invention aims to meet the aforementioned constraints and to provide a manufacturing method of a magnetocaloric thermal element to give it easily and inexpensively a form adapted to the needs, without this form being dictated nor limited by the physical and mechanical constraints of the magnetocaloric effect material which it comprises.

For this purpose, the invention relates to a method of manufacture of the kind indicated in the preamble, characterized in that it comprises at least the steps of:

 i) fabricating at least one support member in a mechanically resistant material to form a mechanical core providing said magnetocaloric element with mechanical strength, and

 ii) at least partially covering said support member with at least one magnetocaloric effect material, to form a thermal surface providing said magnetocaloric element with its ability to achieve the magnetocaloric effect,

in that the covering step ii) comprises intimately bonding said at least one magnetocaloric effect material to said support member to form a one-piece magnetocaloric member in which said at least one support member and said at least one magnetocaloric material are indissociable, and in that said at least one mechanically resistant material has a thermal conductivity lower than that of said at least one magnetocaloric effect material.

The covering step consists in mechanically connecting, or even intimately bonding the magnetocaloric material to the support piece, so as to produce a magnetocaloric element in the form of a single piece. Advantageously, this monobloc magnetocaloric element thus comprises a mechanical core ensuring its mechanical strength and a thermal surface assuring its ability to achieve the EMC. In the present disclosure, the term magnetocaloric material refers to magnetocaloric effect materials in general, these materials may be identical or different, and have identical or different Curie temperatures. It is in particular possible to create adjacent regions of magnetocaloric materials having different Curie temperatures to create a temperature gradient increasing or decreasing in the direction of circulation of the heat transfer fluid on the magnetocaloric element.

The method may consist in manufacturing the support piece in one of the following configurations: wired, two-dimensional, three-dimensional, and in one of the following forms: a solid plate, a lattice, a grid, a perforated plate, a weave, a fabric , an entanglement of threads, a web of material, a network, a cylinder. The support piece may comprise a plane face or two parallel and opposite planar faces. In this case, the covering step may consist in covering part or all of one of the flat faces or the two flat faces of said support piece by a layer of said at least magnetocaloric material.

The method may further comprise a step of manufacturing several support pieces covered with magnetocaloric material by providing at least one passage for a heat transfer fluid between them, and thus forming a thermal element ready to be mounted in a thermal device.

Alternatively, the method may further comprise a step of folding said support piece covered with magnetocaloric material so as to form in each bend at least one passage for a coolant. The process according to the invention may consist in carrying out step ii) by one of the processes chosen from electrolysis, catalysis, firing, electrostatism, screen printing, two-dimensional or three-dimensional printing. This allows for an intimate connection between the support piece and the magnetocaloric material which is applied to said support piece to form a monobloc magnetocaloric element.

Alternatively, it may be to perform step ii) by spraying a powder of magnetocaloric material on said support piece or by immersing said support piece in a powder bath of magnetocaloric material.

The method may comprise a step carried out before the spraying or immersion and consisting of depositing at least partially on the support part a layer of a binder selected from an adhesive, a resin, an adhesive. Step ii) may consist in depositing a mixture of binder and powder of magnetocaloric effect material.

The support part can be made from one of the following processes: sintering, rolling, stamping, extrusion, molding, injection, blowing, thermoforming, calendering, profiling, machining, cutting, punching, bi or three-dimensional printing.

According to the invention, the support piece may be made of a material selected from: a synthetic material, a composite material, a ceramic, fiberglass, a natural material, an artificial material, a combination of said materials.

The invention also relates to a monobloc magnetocaloric element for a thermal apparatus, characterized in that it is produced according to the manufacturing method as defined above and in that it comprises at least one support piece having mechanical strength properties partially or completely covered by at least one magnetocaloric effect material.

The invention relates to the use of at least one monobloc magnetocaloric element as defined above in a thermal apparatus.

The present invention finally proposes a thermal apparatus comprising at least one monobloc magnetocaloric element as defined above, intended to be traversed by a heat transfer fluid circulating, said apparatus comprising a magnetic arrangement arranged to subject said magnetocaloric element to a variation of magnetic field and alternatively create in said magnetocaloric element a heating cycle and a cooling cycle.

Brief description of the drawings:

The present invention and its advantages will appear better in the following description of several embodiments given as non-limiting examples, with reference to the appended drawings, in which:

 FIG. 1 represents a plate-shaped support piece on which a powdered magnetocaloric material is sprayed,

 FIG. 2 is a view of a magnetocaloric element consisting of several plates made according to the method illustrated in FIG. 1,

 FIG. 3 represents a magnetocaloric element made by folding a plate already covered with a magnetocaloric material,

FIG. 4 represents a magnetocaloric element made according to another variant,

FIG. 5 represents two magnetocaloric elements of FIG. 4 recessed head to tail, and FIG. 6 shows a magnetocaloric element in the form of a lattice or an entanglement of support pieces in the form of wires covered with a magnetocaloric material. Illustrations of the invention and different ways of making it:

The invention relates to a manufacturing method for producing a magnetocaloric element El, E2, E3, E4. This process essentially consists in manufacturing a support piece and covering it partially or entirely with a magnetocaloric material, thus making it possible to separate the magnetocaloric thermal function from the structural mechanical function of a magnetocaloric element. The function of the support piece is thus to ensure the mechanical strength in time of the magnetocaloric element El, E2, E3, E4, and in other words, to form its mechanical core. The material in which this support piece is made is capable of ensuring mechanical retention over time and does not need to have a magnetocaloric function or effect. This material preferably has a thermal conductivity lower than that of the magnetocaloric material, such as for example less than 10 watts per meter-Kelvin, so as not to induce a parasitic thermal flux detrimental to the establishment of the temperature gradient. It may in particular be a thermal insulator, such as for example a synthetic material, a composite material reinforced or not by fillers, fiberglass, a ceramic, a natural material, an artificial material, a mixture of said materials. It may for example be a woven or nonwoven product. It can also have a magnetocaloric effect if it is made of a composite material comprising particles of magnetocaloric material. These examples of materials are of course not limiting, the essential lies in the mechanical properties of the manufactured support part, which must have a certain rigidity to carry the magnetocaloric material, serve as a guide for a heat transfer fluid circulated from from said magnetocaloric element obtained, without harming the temperature gradient. Advantageously, since the choice of the material constituting the support piece is essentially determined by its mechanical strength, the possibilities in terms of shape are much greater than in the present case where it is the magnetocaloric material itself which is worked. , machined, shaped, etc. to form the magnetocaloric element. Indeed, in the state of the art, this magnetocaloric material currently provides both the mechanical function of resistance to mechanical stresses and the magnetocaloric thermal function, that is to say the ability to produce a magnetocaloric effect under a magnetocaloric effect. magnetic solicitation.

FIG. 1 represents for this purpose a plate-shaped support piece S 1 made for example of synthetic material, such as a thermoplastic, which has no magnetocaloric effect. This support piece SI can be obtained for example by a process of extrusion, molding, injection, blowing, thermoforming, rolling, calendering, profiling, sintering, machining, bi-printing. or three-dimensional, or the like. Of course, this support piece SI can be made of any other material compatible for its mechanical functions, with or without a magnetocaloric effect. In the example of FIG. 1, a mixture of a binder with powder of magnetocaloric material 1 is vaporized on the surface of said support piece S 1. This mixture can be vaporized, depending on the desired result, or on a only one of its faces to form a single layer of magnetocaloric material, or on its two parallel faces and opposite to form two layers of magnetocaloric material disposed on either side of the support piece SI. Thus, a magnetocaloric element E1 formed by the combination of the support piece S1 and the powder of magnetocaloric material 1 is very easily obtained. Advantageously, the magnetocaloric element E1 simultaneously exhibits a stability and a mechanical rigidity and a magnetocaloric effect. As a variant, the support piece SI can be immersed in a bath of powder of magnetocaloric material, this powder being able to be made fluid by via a gas, such as air, for example. The binder associated with the magnetocaloric material powder may be a glue, an adhesive, a resin, or the like.

The objective is to intimately bond the magnetocaloric material 1 with the material constituting the support piece S1 in order to form a single-piece magnetocaloric element El in which the support piece and the magnetocaloric material are indissociable. A cooking step may be necessary to achieve this goal. In other examples not shown, the intimate connection between the magnetocaloric material and the material constituting the support part can also be obtained by other processes such as electrolysis, catalysis, firing, electrostatism, silkscreen, bi or three-dimensional printing.

The magnetocaloric material is not necessary in a powder form, but may be in the form of beads, particles, flakes, pellets, wafers, sheets, etc. according to both the material constituting the support part and the manufacturing process.

A thermal element 10 may then comprise a plurality of such magnetocaloric elements E1 in the form of plates which are, for example, arranged parallel to each other and spaced apart by means of spacers 2, so as to produce rectilinear channels allowing the passage of a heat transfer fluid. Such a thermal element 10 is shown in FIG. 2. This thermal element 10 can be obtained from a three-dimensional magnetocaloric element E1 or from several magnetocaloric elements E1 planes assembled by spacers. The spacers 2 may be inserts or parts integrated in the magnetocaloric elements El. They may for example be printed on the surface of the magnetocaloric elements E1 by any known and compatible 3D printing process. This support piece SI in plate form can also be folded in different places along folds parallel to each other, in order to delimit between the different folds passages for a heat transfer fluid. The magnetocaloric element E2 monoblock thus obtained is represented in FIG.

The three-dimensional magnetocaloric element E3 can also be produced from a support part comprising a base 3 from which plates 4 parallel to each other extend and defining passages for a heat transfer fluid. For such a support piece, the covering is ideally made by immersing said support piece in a powder bath of magnetocaloric material. We then obtain a mono-bloc magnetocaloric element E3 such as that represented in FIG. 4. When two magnetocaloric elements E3 according to FIG. 4 are assembled by a head-to-tail installation, a new thermal element 20 is obtained. according to Figure 5. In this particular configuration, the free space between the blades 4 can be reduced to 0.1 mm, while this is currently unachievable with known manufacturing techniques.

Finally, FIG. 6 represents a single-piece magnetocaloric element E4 made from several semi-rigid wires forming a support piece, covered with a magnetocaloric material and entangled in each other through which a heat transfer fluid can circulate.

The attached figures show the variety of forms made possible to achieve to manufacture a magnetocaloric element El, E2, E3, E4 according to the method of the invention. Of course, the rectangular plate shape illustrated in the figures is only an example and is not limiting. This shape may be formed of another geometric shape, or of any shape by virtue of the dissociation of the mechanical part of the magnetocaloric part in the magnetocaloric element. In this way, the shape of the support piece can be obtained by stamping, punching, cutting by any means such as laser, water jet, etc., It can in particular be wireframe, two-dimensional or three-dimensional, such as a cylinder, for example. These examples are not meant to be limiting.

The invention also makes it possible to very simply manufacture magnetocaloric elements El, E2, E3, E4 whose temperature gradient is increased by the deposition on the support part of different magnetocaloric materials having different Curie temperatures in order to create adjacent regions in which the different Curie temperatures are arranged increasing or decreasing in the direction of circulation of the coolant on said magnetocaloric element. This deposit may consist of deposits of these different magnetocaloric materials either in layers partially or totally superimposed and offset in the direction of circulation of the coolant, each layer being made of one of the magnetocaloric materials, or side by side in the same layer, or in a combination of these two deposition techniques.

Possibilities of industrial application:

It is clear from this description that the invention makes it possible to achieve the goals set, namely to separate the magnetocaloric thermal function from the mechanical strength and structure function of a magnetocaloric element El, E2, E3, E4 intended to generate a magnetocaloric effect when subjected to a magnetic induction of variable intensity. With the manufacturing method according to the invention, it is possible to produce a magnetocaloric element whose shape is independent of the mechanical characteristics of the magnetocaloric material that it comprises or of which it is constituted, thus offering new possibilities for improving the thermal efficiency. of a magnetocaloric thermal apparatus.

The present invention is not limited to the embodiments described but extends to any modification and variation obvious to a person skilled in the art.

Claims

claims

1. A method for manufacturing a monobloc magnetocaloric element (E1, E2, E3, E4), characterized in that it comprises at least the steps consisting of:

 i) fabricating at least one support member (SI) in at least one mechanically resistant material, to form a mechanical core providing said magnetocaloric element with its mechanical strength, and

 ii) at least partially covering said at least one support member (S1) with at least one magnetocaloric effect material, to form a thermal surface providing said magnetocaloric element with its ability to achieve the magnetocaloric effect,

in that the covering step ii) comprises intimately bonding said at least one magnetocaloric effect material to said support member to form a one-piece magnetocaloric member in which said at least one support member and said at least one magnetocaloric material are inseparable

and in that said at least one mechanically resistant material has a lower thermal conductivity than said at least one magnetocaloric effect material.

2. Method according to claim 1, characterized in that it consists in manufacturing said at least one support piece (SI) in one of the following configurations: wired, two-dimensional, three-dimensional.

3. Method according to claim 2, characterized in that it consists in manufacturing said at least one support piece (SI) according to one of the following forms: a solid plate, a lattice, a grid, a perforated plate, a weaving, a web, an entanglement of threads, a web of material, a network, a cylinder.

4. Method according to any one of claims 1 to 3, characterized in that said at least one support piece (SI) comprises a flat face and in that said recovery step ii) consists in covering all or part of said planar face with a layer of said at least one magnetocaloric material.

5. Method according to any one of claims 1 to 3, characterized in that said at least one support piece (SI) comprises two parallel and opposite flat faces, and in that said recovery step ii) consists in covering in part or all of each planar face of a layer of said at least one magnetocaloric material.

6. Method according to any one of claims 1 to 3, characterized in that it consists in manufacturing several support pieces (SI) covered with magnetocaloric material by providing between them at least one passage for a heat transfer fluid.

7. Method according to any one of claims 1 to 3, characterized in that it further comprises a step of folding said support part covered with magnetocaloric material so as to form in each fold at least one passage for a fluid coolant.

8. Method according to any one of claims 1 to 7, characterized in that it consists in carrying out the recovery step ii) by one of the methods selected from electrolysis, catalysis, cooking, the electrostatism, screen printing, bi or three-dimensional printing.

9. Method according to any one of claims 1 to 7, characterized in that it consists in performing the recovery step ii) by spraying a powder of magnetocaloric material (1) on said support piece (SI). .

10. Method according to any one of claims 1 to 7, characterized in that it consists in performing the recovery step ii) by immersing said support member (SI) in a powder bath of magnetocaloric material.

11. The method of claim 9 or 10, characterized in that it comprises a step carried out before the spraying or immersion and of depositing at least partially on said support part a layer of a binder selected from an adhesive, a resin, an adhesive.

12. Method according to any one of claims 1 to 7, characterized in that the recovery step ii) comprises depositing a mixture of binder and magnetocaloric material powder.

13. A method according to any one of claims 1 to 12, characterized in that the recovery step ii) comprises depositing at least two different magnetocaloric materials, having different Curie temperatures, to create on said support piece at minus two adjacent regions in which the different Curie temperatures are increasing or decreasing.

14. Process according to any one of the preceding claims, characterized in that said support piece (SI) is produced from one of the following processes: sintering, rolling, stamping, extrusion, molding, injection, blowing, thermoforming, calendering, profiling, machining, cutting, punching, bi- or three-dimensional printing.

15. Method according to any one of the preceding claims, characterized in that said support piece (SI) is made of a material selected from: a synthetic material, a composite material, a ceramic, fiberglass, a material natural, an artificial material, a combination of said materials.

16. A magnetocaloric element (E1, E2, E3, E4) in one piece for a thermal apparatus, characterized in that it is produced according to the manufacturing method of any one of claims 1 to 15, and in that it comprises at least one support piece (SI) made in at least one mechanically resistant material to form a mechanical core providing said magnetocaloric element with mechanical strength, and in that said at least one support piece (SI) is covered in part or in by at least one magnetocaloric effect material to form a thermal surface providing said magnetocaloric element with its ability to achieve the magnetocaloric effect, said at least one magnetocaloric effect material being intimately bonded to said support member to form a magnetocaloric element (El , E2, E3, E4) in which said at least one support piece and said at least one magnetocaloric material are inseparable and said at least one mechanically resistant material having a lower thermal conductivity than said at least one magnetocaloric effect material.

17. A magnetocaloric element according to claim 16, characterized in that it has one of the following configurations: wired, two-dimensional, three-dimensional.

18. A magnetocaloric element according to claim 17, characterized in that it has a shape chosen from: a solid plate, a lattice, a grid, a perforated plate, a weave, a fabric, an entanglement of threads, a strip of material , a network, a cylinder.

19. magnetocaloric element according to any one of claims 16 to 18, characterized in that said at least one support piece (SI) comprises a flat face covered in part or in full by a layer of said at least one magnetocaloric material.

20. magnetocaloric element according to any one of claims 16 to 18, characterized in that said at least one support piece (SI) comprises two parallel and opposite planar faces, each flat face being covered in part or in whole by a layer said at least one magnetocaloric material.

21. Magnetocaloric element according to any one of claims 16 to 20, characterized in that it comprises a plurality of support pieces (SI) covered with magnetocaloric material delimiting between them at least one passage for a heat transfer fluid.

22. Magnetocaloric element according to any one of claims 16 to 20, characterized in that it comprises a support part covered with magnetocaloric material and folded in parallel folds between them delimiting in each fold at least one passage for a heat transfer fluid .

23. magnetocaloric element according to any one of claims 16 to 22, characterized in that it comprises at least two different magnetocaloric materials, having different Curie temperatures, deposited to create on said support member at least two adjacent regions in which different Curie temperatures are increasing or decreasing.

24. magnetocaloric element according to any one of claims 16 to 23, characterized in that said support piece is made of a material selected from: a synthetic material, a composite material, a ceramic, fiberglass, a material natural, an artificial material, a combination of said materials.

25. Use of at least one monobloc magnetocaloric element (E1, E2, E3, E4) according to any one of claims 16 to 24 in a thermal apparatus.

26. Thermal apparatus comprising at least one magnetocaloric element (E1, E2, E3, E4) monoblock according to any one of claims 16 to 24, arranged to be traversed by a heat transfer fluid circulating, said apparatus comprising an arranged magnetic arrangement for subjecting said magnetocaloric element to a magnetic field variation and alternately creating in said magnetocaloric element (E1, E2, E3, E4) a heating cycle and a cooling cycle.