ES2925569A2 - ELECTROMAGNETIC SUSPENSION MATRIX SYSTEM FOR TRANSPORT VEHICLES (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

The present invention relates to an electromagnetic suspension matrix system that can be coupled to transport vehicles, comprising a plurality of electromagnetic suspension modules, where each of the modules comprises: a frame; a coil wound on the armature; an adjustable power supply connected to the coil, configured to control the intensity of a first magnetic field; and two permanent magnets arranged in contact with the armature, by means of poles opposite each other, which generate a second magnetic field; where the plurality of modules is arranged in a matrix that satisfies that the adjacent poles of the permanent magnets of adjacent modules are of the same polarity. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

ELECTROMAGNETIC SUSPENSION MATRIX SYSTEM FOR TRANSPORT VEHICLES

OBJECT OF THE INVENTION

The present invention relates to the technical field of high-speed transport systems and more specifically to transport systems with on-board electromagnetic support systems.

BACKGROUND OF THE INVENTION

Magnetic suspension is a phenomenon that has been studied for more than 50 years and that, thanks to the development of high-speed trains, has experienced greater growth in terms of research, validation and application in recent years. The different types of magnetic suspension, or levitation, can be grouped based on their technology as: electromagnetic suspension (EMS); electrodynamic suspension (EDS) or hybrid electromagnetic suspension (HEMS).

In general terms, EMS allows static suspension with the drawback that it requires a complex control component to regulate the distance and high energy consumption for medium and high loads. In contrast, the EDS presents a lower control complexity and a reduced consumption inherent to the levitation system, but instead requires a relative speed between the system and the airfoil, in addition to requiring guidance. The third alternative, the HEMS, represents an intermediate solution in which complex control is required, but it has lower consumption thanks to the use of permanent magnets that provide an intense field at zero current.

On the other hand, within HEMS-based systems a distinction can be made between two configurations, those that integrate guidance and suspension and those that keep them separate. Integration in HEMS technology is associated with lower energy consumption but has other complications associated with interference due to increased speed, as well as greater construction difficulty and the increase in controllers required.

However, the most avant-garde means of transport, especially those related to the Hyperloop concept, are proposing low-pressure environments in a transport tube that require a review of these technologies to take advantage of their infrastructure as a levitation and guidance integration surface.

The state of the art is in a continuous development of levitation systems applicable to the aforementioned high-speed means of transport. In it some proposals for controllable systems are known that increase, as far as possible, the force/consumption ratio, compared to others that sacrifice minimizing the surface in front of the improvement of control response or that seek an improvement in efficiency by reducing the losses in the windings. Thus, in general, these proposals resort to magnet-electromagnet contact systems, which implies a thermal problem in low pressure systems such as the aforementioned Hyperloop, or are limited to a single permanent magnet, which reduces efficiency compared to volume and consumption to reach high forces.

In general, one of the great problems added to the known systems appears when it is necessary to scale them for the loads associated with a passenger or freight transport system, where the increase in force associated with the increase in the size of the magnets or the windings entails a increase in size, weight and consumption in greater proportion and, therefore, a significant reduction in the efficiency of the final system due to increased losses.

Until now, one of the few known solutions is to use a combination of permanent magnets, known as a Halbach array, which allows the magnetic field on one side of the array to be strengthened while the magnetic field on the opposite side is eliminated, or instead of permanent magnets replace or combine these with equivalent electromagnets that can use high consumption to generate even greater forces. However, these solutions pose some drawbacks, mainly in the scaling of the system, which does not maintain the relationship between size and force consumption, or assembly complexity, since the magnets are geometrically arranged in an unnatural way, therefore they exert forces significant to change its position.

For all of the above, there is a lack in the state of the art of an efficient and stable magnetic support system solution that can be easily scaled without losing efficiency and can be coupled to high-speed means of transport.

DESCRIPTION OF THE INVENTION

In order to achieve the objectives and avoid the drawbacks mentioned above, the present invention describes, in a first aspect, an electromagnetic suspension matrix system attachable to transport vehicles comprising a plurality of electromagnetic suspension modules, where each of the modules comprises: - a frame;

- a coil wound on the armature;

- an adjustable power supply connected to the coil, configured to control the intensity of a first magnetic field (which can favor or oppose the second magnetic field); Y

- two permanent magnets arranged in contact with the armature, by means of poles opposite each other, which generate a second magnetic field;

where the plurality of modules is arranged in a matrix that satisfies that the adjacent poles of the permanent magnets of adjacent modules are of the same polarity. Thus, advantageously, a scalable matrix in defined directions results that provides a total force greater than the sum of the forces of the individual and independent modules, due to the reduction of dispersion losses.

The system of the present invention , in one of its embodiments, comprises: a guide structure made of ferromagnetic material; at least one transport vehicle, arranged in coupling with the plurality of modules, configured to move under the guide structure; and where the adjustable power supply is configured to provide a value of the first magnetic field that, in combination with the second magnetic field, provides a magnetic attraction force of the vehicle towards the guide structure that compensates for the weight of the vehicle. Thus, advantageously, the magnetic forces oppose the gravitational forces to support and guide the vehicle and allow it to move at high speeds without mechanical contact with the guide structure.

In one of the embodiments of the invention, the guide structure is a tubular structure configured to allow the vehicle to move inside said structure. tube structure. In particular, it is contemplated that the tubular structure comprises inside a controlled low pressure atmosphere. Thus advantageously, the present invention can be adapted to transport infrastructures of the Hyperloop type.

Additionally, in one of the embodiments of the invention it is contemplated to add a cooling circuit, configured to reduce the temperature between the coil and the magnets of the modules. Thus, advantageously, the operating range is increased and it prevents the loss of useful life of the system due to the high heating that the currents necessary to maneuver very powerful magnets can cause.

For all of the above, the magnetic suspension system of the present invention not only improves its efficiency when climbing, but also maintains the ratio of strength, size, weight and consumption. The magnetic field it provides is adapted to the required operation thanks to the fact that the strength of the permanent magnets can be increased or reduced, with minimal consumption, by acting on the coil. However, unlike other state-of-the-art solutions, the permanent magnets are mechanically separated from the coil.

The ordered grouping of the unitary modules of the present invention allows advantageously to create a scalable matrix in defined directions, in which the total force is greater than the sum of the forces of the individual and independent modules due to the reduction of dispersion losses. .

BRIEF DESCRIPTION OF THE FIGURES

To complete the description of the invention and in order to help a better understanding of its characteristics, according to a preferred embodiment of the same, a set of drawings is attached where, by way of illustration and not limitation, represented the following figures:

- Figure 1 represents a unitary levitation module, according to one of the embodiments of the invention.

- Figure 2 represents two unitary modules and the magnetic field lines that are generated.

- Figure 3 represents the advantageous association of two unitary modules in proximity and the resulting magnetic field lines.

- Figure 4 represents an array of unitary magnetic levitation modules, according to one of the embodiments of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention discloses an electromagnetic suspension system for high-speed transport vehicles that levitate on a guide structure. It comprises an intelligent regulation system in which, by means of electromagnets, it controls the magnetic flux generated by a particular arrangement of permanent magnets embedded in a magnetic circuit, where the arrangement of permanent magnets takes advantage of the intrinsic qualities of said magnets to provide a source magnetic field as a force without energy cost to levitate a certain mass (the transport vehicle) in the vicinity of a ferromagnetic material.

It is known that the magnetic field generated by a single magnet closes around the magnet itself between the faces with different polarity, which means that part of the flux that the magnet could potentially generate is lost when it closes on itself in the so-called flux of dispersion. On the other hand, the system of the present invention minimizes this dispersion flux using a configuration based on unitary modules 11 of two permanent magnets, a coil and an armature, where the assembly of the magnets is carried out ensuring that the poles on the armature are opposite. , so that the field is channeled between them.

Figure 1 shows this configuration, where a first magnet 1 and a second magnet 2 are arranged with reverse polarity orientation on an armature 3, so that the south face 4 of the first magnet 1 and the north face 6 of the second magnet 2 are in direct contact with the surface of the armor 3 . Equivalently, in another embodiment not shown, the magnets are configured in reverse with the same result, that is, the north face of the first magnet 1 and the south face of the second magnet 2 in direct contact with the surface of the armature 3 .

The magnetic circuit is completed with the electromagnet 7 , formed by a winding 8 around the armature 3 , so that during its action (through the passage of current through the turns of the coil 8 ) a magnetic field is induced in the direction of the magnetic flux 0 naturally generated by the arrangement of the magnets ( 1, 2 ), their orientation and intensity being adjustable by controlling the amount of electric current i(t) supplied in the winding from a power supply 13 v(t ), with which it is capable of supporting or opposing said magnetic flux 0 ( 15 ) generated by the permanent magnets. The coil wound on the armature allows control of the flux that is channeled in the direction of the magnets. If the coil is excited in the direction of the magnets flux, it is favored, otherwise the magnetic flux is reduced.

The magnetic suspension system of the present invention is preferably shipped on the transport vehicle, so that its weight 12 can be compensated by the sum of the magnetic forces 9 generated by the magnets 1, 2 and the electromagnet 7 , with which the vehicle it moves suspended magnetically (without mechanical contact), in a controlled manner, at a predetermined distance 14 from a guide structure 10 made of ferromagnetic material. The guide structure is of the open rail type in one of the embodiments, but according to another embodiment of the invention, the guide structure is integrated into a transport tube with low pressure conditions of the Hyperloop type.

The configuration of the embodiment represented in Figure 1 , achieves a highly efficient system that decouples the electromagnet 7 and the permanent magnets 1, 2 , but that fully exploits the passive force of said permanent magnets by directing and regulating the magnetic flux with a consumption minimum. In addition, this distribution minimizes the problems of heat dissipation, especially present in low pressure environments, which is why it is advantageous in Hyperloop-type transport systems, developed to move transport vehicles inside a closed tube with low pressure conditions.

This arrangement of the elements described and represented in figure 1 , has several advantages, on the one hand, the open arrangement of magnets and armor facilitates assembly and allows a larger surface to be made on which to make the fastenings to the structure of the vehicle. transportation. On the other hand, it facilitates access to all the geometry of the electromagnet 7 , also allowing, in one of the embodiments of the invention, the installation of a cooling system (not shown in the figures) that reduces the increase in temperature by conduction between coil 8 and permanent magnet 1, 2 with respect to the configurations known in the state of the art in which the electromagnet is around the permanent magnet. This is especially relevant considering that some of the most powerful magnets, such as grade 52 Neodymium magnets, have a low maximum working temperature (between 60 and 150 °C) so that an excess of temperature results in a detriment of the useful life of the material due to permanent loss of strength.

Regarding the problem of scalability described above, which affects the known solutions of the state of the art by increasing the consumption and dimensions of the components in an inefficient manner, the present invention solves it by combining unitary modules such as those described in figure 1 to provide a fully scalable magnetic suspension system.

Figure 2 shows two unitary modules 11 , configured to be one the mirror image of the other, and the magnetic field lines they generate. One of the main effects of the present invention is produced by bringing the modules 11 closer together until the space between them is almost completely reduced, as can be seen in figure 3, the redirection of the magnetic flux is optimized and the dispersion flux is minimized. In this way, the magnetic suspension system thus configured achieves greater efficiency in the use of the magnetic force, which translates into lower consumption. The arrangement of the modules guarantees that the adjacent poles of the permanent magnets have the same polarity. Thus, in figure 3 the two permanent magnets that are in proximity are arranged with the north pole (N) contacting the respective armatures. If an additional module were added, both to the left and to the right of the two modules represented, the permanent magnet arranged in proximity to those already represented, would be configured with its south pole (S) in contact with its armature. In this way the array can be scaled indefinitely in any direction.

Figure 4 represents an array of unitary modules 11 like the previous ones, arranged in various directions, thus achieving that the force of the assembly is greater than the sum of the forces generated by the elements independently. When climbing, the The resulting modular electromagnetic suspension system can be compared to a Halbach permanent magnet distribution, but in this case the force potentiated by the grouping can be regulated, thanks to the electromagnets, as in the case of an isolated module. The ability to act on each unitary module makes it possible to compensate for defects associated with the manufacturing or the nature of the materials (such as different degrees of magnetization, winding resistance or inductance), making it possible, therefore, to reach operating points close to the optimum in each of the modules 11, with the sole restriction of their mechanical connection. In this way, the consumption for a levitation point close to the optimum of the system tends to 0.

The application of this configuration to a magnetic levitation vehicle allows to have scaled force distributions that can be oriented and compensated taking advantage of the structure of the vehicle and the infrastructure, allowing not only the levitation of the mass of the vehicle, but also the control of it by time that disturbances associated with the internal elements of the vehicle or infrastructure defects are absorbed.

The present invention is not to be limited to the embodiment described herein. Other configurations can be made by those skilled in the art in view of the present description. Accordingly, the scope of the invention is defined by the following claims.

Claims (4)

1. An electromagnetic suspension matrix system attachable to transport vehicles comprising a plurality of electromagnetic suspension modules (11), where each of the modules comprises: - an armor (3); - at least one coil (8) wound on the armature; - an adjustable power supply (13) connected to the coil, configured to control the intensity of a first magnetic field; Y - two permanent magnets (1, 2) arranged in contact with the armature, by means of poles opposite each other, which generate a second magnetic field; - a guide structure (10) made of ferromagnetic material; Y, - a transport vehicle, arranged in coupling with the plurality of modules, configured to move under the guide structure; where the plurality of modules is arranged in a matrix that satisfies that the adjacent poles of the permanent magnets of adjacent modules are of the same polarity; Y, where the adjustable power supply is configured to provide a value of the first magnetic field that, in combination with the second magnetic field, provides a magnetic attraction force (9) of the vehicle towards the guide structure that compensates the weight (12) of the vehicle. 2. System according to claim 1, wherein the guide structure (10) is a tubular structure configured to allow the vehicle to move inside said tubular structure. 3. System according to claim 2, wherein the tubular structure comprises inside a controlled low pressure atmosphere. 4. System according to any of the preceding claims that also comprises a cooling circuit configured to reduce the temperature between the coil and the magnets of the modules.