FR3016469A1 - PROCESS FOR PREPARING A PERMANENT MAGNET - Google Patents

Abstract

This method for preparing a magnet comprises the following steps: a) forming a layer of ferromagnetic material, by depositing an ink comprising at least one carrier solvent and particles of at least one ferromagnetic material; b) orientation of the ferromagnetic particles; c) drying the ink by removing the carrier solvent; d) repeating steps a) to c) to form an additional layer of ferromagnetic particles; e) heat treatment of the ferromagnetic particle layers.

Description

FIELD OF THE INVENTION The invention relates to a method for manufacturing a permanent magnet that can comprise a plurality of ferromagnetic particle layers. The orientation of the ferromagnetic particles may differ from one layer to another, it is achieved during the formation of the magnet.

The field of use of the present invention particularly relates to applications for rotating electrical machines, such as motors or alternators found for example in the automotive field. STATE OF THE ART Permanent magnets are necessary for the operation of many devices, for example in electric motors, rotors, loudspeakers, or recording media.

The manufacture of these magnets, however, remains relatively complex and includes many steps, making it difficult to achieve permanent magnets with excellent performance, including strong magnetization, as well as a high coercive field and a high remanent induction. The coercive field (HC) corresponds to the magnetic induction that must be applied to a magnet to cancel its magnetization.

The remanent induction (Hr) corresponds to the value of the magnetic induction in the magnet immediately after having brought its magnetization to saturation. Specific energy (BHmax) represents the maximum energy that can be stored in the magnet.

A high performance permanent magnet is defined as exhibiting in particular high values of remanent induction (Hr) and / or specific energy (BHmax). When this is made from powders, the alignment of the constituent grains of the powder contributes to the improvement of the performance. Among the most widely used manufacturing processes, injection molding of PIM powders (from acronym for "Powder Injection Molding") makes it possible to produce plasto-magnets or sintered solid magnets. Plastomagnets are magnets composed of a mixture of ferromagnetic powders and organic molecules (plastics or polymers). Sintered solid magnets denote magnets obtained by the assembly of ferromagnetic metal or ceramic powders, which do not contain polymers or whose polymer has completely disappeared during the debinding step of the PIM process.

The PIM process consists of mixing a ferromagnetic powder with a binder, advantageously a polymer, to inject this mixture into a mold, and possibly to remove the binder during the debinding phase. This type of process has certain disadvantages, and in particular: solidification of organic molecules is very rapid, which requires the use of specific organic molecules; - The orientation tool of the particles is similar to a magnetization coil, which may pose additional difficulties in the case where the forming tool is metallic. The magnetic fields to orient the particles can thus be modified or disturbed. Consequently, the methods of the prior art do not make it possible to optimize the shaping of the magnet as well as the orientation of the ferromagnetic particles constituting it. In order to answer this problem, the Applicant has developed a method of depositing successive layers from a ferromagnetic ink. This process does not use the PIM technology, nor organic molecules which, when they harden, make it possible to freeze the orientation of the ferromagnetic particles. SUMMARY OF THE INVENTION The method - object of the present invention makes it possible to manufacture a permanent magnet three-dimensional, by successive deposition of a plurality of elementary layers of ferromagnetic particles. These deposits are spaced apart from a step of orientation of the ferromagnetic particles. In contrast to the processes of the prior art, the orientation of the particles is carried out in the presence of the carrier solvent, that is to say after the deposition of the ink but before drying.

More specifically, the subject of the present invention relates to a method for preparing a magnet, comprising the following steps: a) forming a layer of ferromagnetic material, by depositing an ink comprising at least one carrier solvent and particles of at least one ferromagnetic material; b) orientation of the ferromagnetic particles; c) drying the ink by removing the carrier solvent; d) repeating steps a) to c) to form an additional layer of ferromagnetic particles; e) heat treatment of the ferromagnetic particle layers.

This method thus makes it possible to form a layer, to orient this layer, to dry this layer, to form a new layer ... and finally to subject all the formed layers to a heat treatment (sintering).

By "carrier solvent" is meant an organic or aqueous liquid for suspending ferromagnetic particles. Advantageously, the ink is deposited in step a) on a support or a substrate, by inkjet printing, and more particularly by three-dimensional ink jet printing. As already stated, the ink contains at least ferromagnetic particles and a carrier solvent. In general, the ink may be deposited at a temperature advantageously between room temperature (of the order of 20 ° C. in particular) and 60 ° C. The technology used to deposit the ink makes it possible to form layers so as to form a section of the three-dimensional magnet. Among the commercially available equipment, mention may be made of the 35 printers manufactured by CERADROP.

The deposition of the ink is followed by step b) of orienting the ferromagnetic particles. Advantageously, the application of a magnetic field makes it possible to orient the ferromagnetic particles, and thus to align them with the magnetic field. Typically, the intensity of the magnetic field may be between 3 and 9 Tesla, more preferably between 5 and 7 Tesla. The duration of exposure to the magnetic field may especially be of the order of a few seconds. This step can be carried out at room temperature in particular. After orientation of the ferromagnetic particles, the ink is dried during step c), advantageously by evaporation of the carrier solvent.

Advantageously, this step consists in heating the deposition of ferromagnetic particles (deposited ink) at a temperature of between 30 and 150 ° C., more advantageously still between 40 and 100 ° C.

Those skilled in the art will be able to adjust the drying time according to the temperature and the ink. The drying of the ink makes it possible to freeze the orientation of the ferromagnetic particles. Indeed, this step consists in eliminating the carrier solvent which allowed the mobility of the ferromagnetic particles. Step d) consists in repeating steps a) to c) in order to form a new layer of ferromagnetic particles. A plurality (at least 3) of layers can thus be formed.

Once the layers have been formed and the ink has dried, the deposition of ferromagnetic particles is subjected to a heat treatment which makes it possible to consolidate the structure of the magnet. This is step e) of the process.

This heat treatment also makes it possible to densify the layers, without modifying the preferred orientation directions of the ferromagnetic particles. It is only after step e) that the magnet can be manipulated.

Advantageously, the heat treatment is carried out at a temperature between 800 and 1600 ° C, more preferably between 1000 and 1100 ° C. In fact, this heat treatment step is a sintering step.

The duration of the heat treatment is advantageously between 10 and 500 minutes, and more advantageously between 60 and 240 minutes, and even more advantageously between 60 and 180 minutes. At the end of the heat treatment step, the layer of ferromagnetic particles has a thickness advantageously less than 15 millimeters. The thickness of each layer may be in particular between 1 and 10 micrometers. Advantageously, the layer thus formed is devoid of a carrier solvent.

As already indicated, the method - object of the invention - makes it possible to form a magnet containing a plurality of layers. These layers can be stacked and / or side by side.

Thus, since the layers of ferromagnetic material are formed independently of each other, the orientation of the ferromagnetic particles of two adjacent or stacked layers may be identical or distinct. The magnet formed by the method - object of the invention may therefore comprise, for example, a plurality of layers of ferromagnetic material, the orientation of ferromagnetic particles of two adjacent or stacked layers can be alternated. According to this particular embodiment, the method - object of the invention makes it possible to form a magnet that may have different preferred magnetization orientations within it. Indeed, the orientation being adjustable layer by layer, the realization of a multifunctional magnet is thus made possible. A first layer of ferromagnetic particles can thus be in contact with a second adjacent layer whose ferromagnetic particles have a distinct orientation. and with an adjacent third layer whose ferromagnetic particles have an identical orientation.

As already indicated, the ink used in the process - object of the invention comprises at least one carrier solvent and at least one type of ferromagnetic particles.

The ink used may be based on organic solvent or aqueous based. The organic solvent may especially be an alcohol of the ethanol, ethylene glycol, butanol or acetone type. Those skilled in the art will be able to adapt the organic or aqueous nature of the ink as a function of the reactivity of the inorganic materials to be dispersed.

In general, the ink used in step a) comprises between 10 and 500 g / l of ferromagnetic particles. Typically, the viscosity of the ink may be between 2 and 50 cps at its use temperature, and more preferably between 10 and 13 cps.

On the other hand, the ferromagnetic particles are advantageously in the form of powder. Advantageously, these are particles of a ferromagnetic material such as for example a ferromagnetic metal, or a ferromagnetic alloy. The material or materials used are chosen according to their Curie temperature (temperature at which the magnetic susceptibility of a ferromagnetic becomes zero), as well as the level of magnetization, the coercive field and the persistent induction sought for final magnet. By way of example, the materials used in the context of the present invention can be chosen from the following group: iron, nickel, ferrite, AlNiCo (AluminumNickel-Cobalt), material based on rare earths such as NdFeB (neodymium -Fer-Bore) or cobalt samarium (SmCo).

In addition, the ferromagnetic particles may be of different sizes and of variable shape. Advantageously, the particles have a size of between 1 and 200 nanometers in length, more advantageously between 10 and 100 nanometers, the length being the largest dimension of the particles.

At the end of the drying or heat treatment step, the layer formed advantageously consists solely of ferromagnetic particles. The present invention also relates to the magnet obtained or obtainable by the method described above. The invention and the advantages thereof will appear better from the following figures given to illustrate the invention and not in a limiting manner.

DESCRIPTION OF THE FIGURES FIG. 1 illustrates a view from above of a magnet having an isotropic particle organization. Figure 2 illustrates a top view of a magnet having a particle organization in the direction of the length (x) of the magnet. Figure 3 illustrates a top view of a magnet having a particle organization in the direction of the width (y) of the magnet. Figure 4 illustrates a top view of a magnet having a particle organization in the direction of the height (z) of the magnet.

Figure 5 illustrates a magnet having a stack of alternating layers having a direction of magnetization in the direction of the length (x) or width (y) of the magnet. FIG. 6 illustrates a magnet having a stack of layers all having a direction of magnetization in the direction of the depth (z) of the magnet.

FIG. 7 illustrates a magnet having a stack of layers each having two directions (x) and (y) of magnetization. DETAILED DESCRIPTION OF THE INVENTION FIGS. 1 to 4 respectively represent a layer of particles without preferred orientation (FIG. 1), or having an orientation along the x axis (FIG. 2), along the y axis (FIG. 3), and along the z axis (Figure 4).

FIG. 5 represents a magnet obtained according to the method - object of the invention, and comprising a stack of six elementary layers, the orientation of which is, alternately, either along the x axis, or along the y axis.

FIG. 6 represents a magnet obtained according to the method - object of the invention, and comprising a stack of 6 elementary layers all having an orientation along the z axis. FIG. 7 represents a magnet obtained according to the method - object of the invention, and comprising a stack of four elementary layers. More precisely, this magnet comprises three adjacent stacks, each of these stacks consisting of four stacked elementary layers. The process used to prepare this magnet may include the following steps: - formation of the stack (4) of elementary layers (1); - Formation of the stack (5) of elementary layers (3); - Formation of the stack (6) of elementary layers (2).

The stacks (4) (5) and (6) are then formed independently of each other. However, and according to another embodiment, the stacks (4), (5) and (6) can be constructed simultaneously.

Claims (6)

REVENDICATIONS1. A method of preparing a magnet, comprising the steps of: a) forming a layer of ferromagnetic material by depositing an ink comprising at least one carrier solvent and particles of at least one ferromagnetic material; b) orientation of the ferromagnetic particles; c) drying the ink by removing the carrier solvent; d) repeating steps a) to c) to form an additional layer of ferromagnetic particles; e) heat treatment of the ferromagnetic particle layers. A method of preparing a magnet according to claim 1, characterized in that the ink is deposited by inkjet printing. A method of preparing a magnet according to claim 1 or 2, characterized in that the method comprises forming a plurality of layers of ferromagnetic material. Process for the preparation of a magnet according to one of Claims 1 to 3, characterized in that the method comprises the formation of a plurality of layers of ferromagnetic material, and in that the orientation of the ferromagnetic particles of two adjacent layers is identical. Process for the preparation of a magnet according to one of Claims 1 to 3, characterized in that the method comprises the formation of a plurality of layers of ferromagnetic material, and in that the orientation of the ferromagnetic particles of two adjacent layers is distinct. Process for the preparation of a magnet according to one of Claims 1 to 5, characterized in that the heat treatment is carried out at a temperature of between 800 and 1600 ° C for a period of between 10 and 500 minutes. Process for the preparation of a magnet according to one of Claims 1 to 6, characterized in that each layer of ferromagnetic particles has a thickness of between 1 and 101.1 μm. 10 2. 15 3. 20 4. 25 5. 30 6. 357.8. A method of preparing a magnet according to one of claims 1 to 7, characterized in that the orientation of the ferromagnetic particles is achieved by applying a magnetic field whose intensity is between 3 and 9 Tesla. 9. A method of preparing a magnet according to one of claims 1 to 8, characterized in that the step of drying the ink is carried out at a temperature between 30 and 150 ° C. 10. Magnet obtained by the method according to one of claims 1 to 8.