FR3127625A1 - Device for transporting and processing at least one magnet - Google Patents

Abstract

Device (100) for transporting and treating at least one magnet (D), the device (100) comprising at least one neutralization container (8) and at least one outer shell (101), the walls (9, 10 ) of the neutralization container (8) being made at least in part of non-magnetic metallic material, the outer shell (101) forming electromagnetic shielding, the device (100) being characterized in that it comprises a removable assembly system of the outer shell (101) with the neutralization container (8). Figure for abstract: figure 5

Description

Device for transporting and processing at least one magnet

FIELD OF THE INVENTION

The present invention relates to the field of recycling magnets. More specifically, the invention relates to the recycling of so-called high-power magnets, such as those found in industrial machines.

TECHNOLOGICAL BACKGROUND

Generally called a "high power magnet" a permanent magnet, based on rare earths, whose remanent magnetic field, that is to say in the absence of any magnetic excitation, is of the order of less than 1 T (Tesla).

This type of magnet is found in particular in rotating electrical machines, such as motors or generators of wind turbines, in measuring devices and instruments equipped with permanent magnets, for example an MRI device in the medical field, or more generally in any system and equipment requiring a strong magnetic field.

The magnetism of permanent magnets can degrade over time, for example under the effect of heat: their intrinsic power is reduced and/or they break up and/or they detach from their support. In order to maintain optimum efficiency of the electric machine, it is then necessary to partially or totally remagnetize the magnets, or to replace them. Remagnetization can be done inside or outside the machine. For remagnetization outside the machine or to replace the magnets, they must be extracted from the machine, either using machine-specific tools, or by partially or totally dismantling the machine.

The magnet extracted from the machine is then assembled to a support, or sole, forming a magnetic pole. Other elements can also be assembled to the pole. We then speak of a magnetic block.

The supply of rare earths for the manufacture of magnets is problematic. Recycling used magnets therefore provides an answer to this problem.

A problem frequently encountered, and in particular concerning high-power magnets, concerns interactions, potentially dangerous or even fatal, with their environment. Indeed, the remanent and/or coercive magnetic field of the magnets can interact with metallic and/or electronic objects in their environment, which is particularly problematic when the interactions take place with equipment of a transport vehicle, in particular in an airplane. , but also with medical devices such as pacemakers or any type of metal prosthesis. These dangerous interactions can occur as soon as the magnet is extracted from the machine.

Precautions are then implemented to minimize the remanent and/or coercive magnetic field of the magnet.

For example, the magnets are placed in a box, for example made of cardboard, to transport them and are arranged relative to each other in such a way as to obtain electromagnetic looping: the magnetic fields neutralize each other, so that the magnetic field around the box is attenuated so that it no longer presents a danger. In addition, the box may have sufficient dimensions to prevent any equipment or person from getting too close to the magnet and thus avoid any interaction.

However, this solution has limitations. Indeed, for example in the case where a single magnet must be transported, a magnetic loop is not possible. In addition, each box must be sized according to the magnetic field it emits and the extent to which it must be attenuated.

Finally, to recycle the magnet, it must be removed from the box, which risks bringing impurities during recycling operations.

Another known solution consists in placing the magnets, possibly already placed in a cardboard box, in a box made of material which forms a magnetic shield, and which is particularly recommended for transport by air. Such a box is made of materials with magnetic properties that can attenuate the magnetic field of a lover placed inside;

However, here again, to recycle the magnet, it must be removed from the box forming the shielding, which risks also being recycled and therefore no longer being reusable. In addition, recycling may involve a demagnetization step, which will also be applied to the box forming the shield, which will then lose its magnetic properties and can no longer be used to transport magnets.

In addition, when removing the magnet from its box, cardboard and/or magnetic shielding, the environment is again subjected to the dangerous magnetic field of the magnet. Special precautions must then be taken to handle the magnet and subject it to recycling operations, which generates costs.

There is therefore a need for a new device making it possible to transport magnets to be recycled, in particular overcoming the aforementioned drawbacks.

A first object of the invention is to propose a device for transporting and processing at least one magnet making it possible to reduce the interactions between the magnet and its environment from its collection to its recycling.

A second object of the invention is to provide a device for transporting and processing at least one magnet that reduces the costs of recycling magnets.

A third object of the invention is to propose a device for transporting and processing at least one magnet which limits manipulation of the magnet.

A fourth object of the invention is to provide a device for transporting and processing at least one magnet which does not add impurities to the magnet during recycling.

A fifth object of the invention is to provide a reusable device for transporting and processing at least one magnet.

• Un état de transport, dans lequel la coque externe est solidaire du récipient de neutralisation et contient au moins en partie le récipient de neutralisation ;
• Un état de traitement, dans lequel la coque externe est séparée physiquement du récipient de neutralisation.

Thus, the invention relates to a device for transporting and processing at least one magnet. The device includes at least one neutralization vessel and at least one outer shell. The neutralization container notably comprises walls forming a closed receptacle intended to contain the at least one magnet, the walls of the neutralization container being made at least in part of a non-magnetic metallic material. The outer shell forms electromagnetic shielding. The device is characterized in that it comprises a removable assembly system of the outer shell with the neutralization container, so that the transport and treatment device can take two states:

• A state of transport, in which the outer shell is integral with the neutralization container and at least partially contains the neutralization container;
• A processing state, in which the outer shell is physically separated from the neutralization vessel.

Thus, the transport and treatment device makes it possible to minimize the handling of the magnet: the latter is placed in the device in the transport state as soon as it is collected, then it is transported to a treatment installation, such as than a recycling facility for example. The device is then put in the processing state, and the magnet can be processed in the installation, and for example be demagnetized. The magnet is thus not handled directly from its collection until it is demagnetized. The outer shell, which does not pass through the processing line, can be reused

• Une couche paramagnétique orientée vers le récipient de neutralisation,
• Une couche diamagnétique,
• Une couche antiferromagnétique orientée vers l’extérieur du dispositif de transport et de traitement.

According to one embodiment, the outer shell is formed by a superposition of at least three layers:

• A paramagnetic layer oriented towards the neutralization container,
• A diamagnetic layer,
• An antiferromagnetic layer facing outward from the transport and processing device.

This superimposition of layers ensures effective electromagnetic shielding, and makes it possible to transport and process high-power magnets. As the outer shell does not undergo any treatment, the shielding properties of the layers are not altered and allow the outer shell to be reused for several transport operations.

According to one embodiment, the outer shell comprises at least one one-piece panel formed by the superposition of said at least three layers, the three layers being held rigidly together. Thus, the manipulation of the outer shell, and in particular for the passage of the transport and processing device from one state to the other, is thereby facilitated.

According to one embodiment, the non-magnetic material of the walls of the neutralization vessel comprises at least in part austenitic stainless steel, which is easy to obtain and inexpensive.

According to one embodiment, the receptacle comprises a raised reinforced bottom, separate from the walls of the neutralization container. The raised reinforced bottom is particularly capable of supporting the weight of a plurality of magnets dumped in bulk into the device. Thus, several magnets can be placed in the device by a simple pouring operation, and without any particular organization of the magnets. The number of manipulations of the magnets is again reduced.

According to one embodiment, the reinforced bottom may comprise perforations and is placed at a distance from a bottom wall of the neutralization container so as to form, between the raised reinforced bottom and the bottom wall, a waste recovery space . Thus, when the neutralization container is used to pass the magnets through an oven and the magnets are part of a magnetic block, under the effect of the heat the glues, binders, resins or varnishes can melt or even burn out, and parts of the magnetic block can detach, forming waste. This waste is then easily separated from the magnets, and recovered in the recovery space. The magnets are therefore at least partly cleaned and separated from the other elements of the magnetic block by passing through the oven. The recovery of magnets is facilitated.

According to one embodiment, the neutralization container may comprise at least two openings located opposite each other and giving access to the receptacle inside the neutralization container, at least one traction system of at least one magnet in the receptacle of the neutralization container and a removable closure system for each of said two openings. The magnet can thus be inserted into the neutralization container by pulling it through an opening, the traction system crossing the receptacle through the two openings facing each other. The placement of the magnet, possibly part of a magnetic block, is facilitated, which is particularly appreciable in the case where the magnet or the magnetic block is heavy.

According to one embodiment, the device may comprise at least one member for cooperating with a handling tool, in order to facilitate its handling throughout its use.

According to one embodiment, the device may comprise a system for inserting at least one magnet inside the receptacle of the neutralization container. The insertion system then comprises, for example, at least one reclosable entrance for the magnet inside the receptacle of the neutralization container and a device for guiding the magnet by slide, for example on a wheeled trolley. Placing heavy magnets in the neutralization container receptacle is made easier by eliminating the need to lift the magnets.

According to one embodiment, a gap can be maintained between the walls of the neutralization vessel and the outer shell, so as to form an empty space. This empty space makes it possible to increase the shielding effect, and to offer an adjustable characteristic according to the power of the magnet(s) placed in the device in order to attenuate as much as possible the outgoing magnetic field, outside the device.

According to one embodiment, the device may comprise a framework made of non-magnetic material. The neutralization container and the outer shell can then be fixed to the framework when the device is in the transport state, and the device can be easily handled as a single piece.

For this purpose, for example, the assembly system is of the sliding type on the frame, the frame being rigidly fixed to the neutralization container. Thus, the device enters the processing state simply by sliding off the outer shell.

According to one embodiment, the outer shell comprises panels and fixed connections between at least some of the panels. By fixed connection is meant here connections of any kind, allowing or not allowing degrees of freedom between the panels, and which are not intended to be easily removable during use of the device. Thus, the outer shell can form an element in one piece, easily put in place on the neutralization container to put the device in the transport state and easily removed to put the device in the treatment state.

Embodiments of the invention will be described below with reference to the drawings, briefly described below:

is a schematic presentation of part of a recycling line according to one embodiment;

is a schematic presentation of part of a recycling line according to another embodiment;

is a schematic presentation of another part of a recycling line;

shows a side view of the transport and treatment device according to a first embodiment, in a so-called treatment state, with the side doors closed;

shows a sectional view along a wall of the device of the , in a so-called transport state;

shows a top view of the device from the , in the processing state;

represents a diagram illustrating in transparency the magnet spill in the device of FIGS. 4 to 6;

represents the device of the with one of the side doors open;

represents an outer shell of a transport and treatment device according to a second embodiment

In the drawings, identical references designate identical or similar objects.

Claims (13)

Device (100) for transporting and processing at least one magnet (D), the device (100) comprising at least one neutralization container (8) and at least one outer shell (101), the container (8) for neutralization device comprising walls (9, 10) forming a closed receptacle intended to contain the at least one magnet, the walls (9, 10) of the neutralization container (8) being made at least in part of non-magnetic metallic material, the shell (101) forming electromagnetic shielding, the device (100) being characterized in that it comprises a system for removable assembly of the outer shell (101) with the container (8) for neutralization, so that the device ( 100) transport and processing can take two states:

• A state of transport, in which the outer shell (101) is integral with the neutralization container (8) and at least partially contains the neutralization container (8);
• A processing state, in which the outer shell (101) is physically separated from the neutralization vessel (8).

Device according to claim 1, in which the outer shell (101) is formed by a superposition of at least three layers:

• A paramagnetic layer (107) oriented towards the neutralization container (8),
• A diamagnetic layer (108),
• An antiferromagnetic layer (109) facing the exterior of the transport and processing device (100).

Device according to the preceding claim, in which the outer shell (101) comprises at least one panel (106) in one piece formed by the superposition of the said at least three layers (107, 108, 109), the three layers (107, 108, 109) being rigidly held together. . Device (100) according to any one of the preceding claims, in which the non-magnetic metallic material of the walls (9, 10) of the neutralization vessel (8) comprises at least in part austenitic stainless steel. Device (100) according to any one of the preceding claims, in which the receptacle comprises a raised reinforced bottom (114), distinct from the walls (9, 10) of the neutralization container (8), the raised reinforced bottom (114) being able to support the weight of a plurality of magnets poured in bulk into the device (100). Device (100) according to the preceding claim, in which the raised reinforced bottom (114) comprises perforations and is arranged at a distance from a bottom wall (9) of the neutralization container (8) so as to form, between the bottom (114) reinforced raised and the wall (9) bottom, a waste recovery space. Device (100) according to any one of the preceding claims, in which the neutralization container (8) comprises at least two openings located opposite each other and giving access to the receptacle inside of the container (8) for neutralization, at least one traction system for the at least one magnet in the receptacle of the container (8) for neutralization and a removable closure system for each of said two openings. Device (100) according to any one of the preceding claims, comprising at least one member (117, 118, 124) for cooperating with a handling tool. Device (100) according to any one of the preceding claims, comprising a system for inserting the at least one magnet inside the receptacle of the neutralization container (8), the insertion system comprising at least one inlet resealable for the magnet inside the receptacle of the container (8) of neutralization and a guide device by slide of the magnet. Device (100) according to any one of the preceding claims, in which a gap (E) is maintained between the walls (9, 10) of the neutralization container (8) and the outer shell (101), so as to form a empty space. Device (100) according to any one of the preceding claims, comprising a framework (103) made of non-magnetic material, the neutralization container (8) and the outer shell (101) being fixed to the framework (103) when the device ( 100) is in the transport state. Device (100) according to the preceding claim, in which the assembly system (102) is of the sliding type on the frame (103), the frame (103) being rigidly fixed to the neutralization container (8). Device according to any one of claims 1 to 10, in which the outer shell (101) comprises panels (106) and fixed connections (120) between at least part of the panels (106).