ES1251530U - ATTRACTION MAGNETIC LEVITATION SYSTEM (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

A magnetic levitation system by attraction characterized in that it comprises: - a guiding structure (20) configured to guide a magnetic levitation vehicle by attraction, wherein at least a part of said structure comprises a ferromagnetic laminate material (30); and - a magnetic levitation vehicle (21) by attraction configured to move under said guiding structure, where the vehicle comprises magnetic means configured to provide a variable magnetic field, where the variable magnetic field provided by the magnetic means of the vehicle causes a constant magnetic attraction force of the vehicle towards the ferromagnetic laminate of the guiding structure that compensates for the weight of the vehicle. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

ATTRACTION MAGNETIC LEVITATION SYSTEM

OBJECT OF THE INVENTION

The present invention relates to the technical field of transportation systems and more specifically to magnetic levitation transportation systems for high-speed vehicles, such as trains.

BACKGROUND OF THE INVENTION

Today magnetic levitation transport systems are a reality. Technologies based on magnetic levitation have been studied for many years and the possibilities they offer compared to traditional transport methods make them of great interest to the industry.

The means of transport based on magnetic levitation mainly benefit from the fact that, since there is no physical contact between the guide rail and the vehicle, but the only friction is produced with the air, very high speeds can be reached that can rival even air transport. . Magnetic levitation techniques can be classified into two categories: electrodynamic suspension (SED), based on repulsive forces, and electromagnetic suspension (SEM), based on attractive forces.

The usual configuration of this type of transport is usually of the SED type and can be observed for example in a maglev train, where electromagnets are arranged on the track rails to produce a magnetic field. Train wagons with an arrangement of superconducting materials in their lower part are placed on this track. When penetrating the magnetic field generated by the electromagnets in said superconductors, a Meissner effect is produced and the rejection of the superconductors to said magnetic field results in the suspension of the vehicle. However, these systems also have some drawbacks that derive from the high energy consumption that implies maintaining and controlling the polarity of the magnets, the high cost of the infrastructure necessary for the tracks and electrical control system and the impossibility of achieving levitation for low speeds.

On the other hand, the magnetic levitation force of SEM systems is inherently unstable, so the control problem of this type of system is complex and often discourages its use in transportation systems. Because an SEM system has non-linear and unstable dynamic behavior, it is difficult to design an accurate control model, as it requires the use of control actions to adequately compensate for system imbalances. Additionally, the lift of a vehicle moving at high speeds in an SEM type system hypothetically presents negative effects on performance that translate into significant losses. Specifically, when a ferromagnetic material moves so close to a magnetic field, induced currents are generated that produce, on the one hand, a braking force that opposes the movement and, on the other hand, a repulsive force opposite to that of magnets. .

For all the above, a solution is lacking in the state of the art that allows the implementation of efficient and stable magnetic levitation systems by attraction, which minimize losses and allow the transport of vehicles at high speeds with a relatively low power consumption. .

DESCRIPTION OF THE INVENTION

In order to achieve the objectives and avoid the drawbacks mentioned above, the present invention describes, in a first aspect, a magnetic levitation system by attraction comprising:

- a guiding structure configured to guide a magnetic levitation vehicle by attraction, where at least a part of said structure comprises a ferromagnetic laminated material; and

- a vehicle for magnetic levitation by attraction configured to move under said guiding structure, where the vehicle comprises magnetic means configured to provide a variable magnetic field,

where the variable magnetic field provided by the magnetic means of the vehicle causes a constant attractive force of the vehicle towards the ferromagnetic laminate material of the guiding structure that compensates for the weight of the vehicle.

In one of the embodiments, the magnetic means are arranged on an upper face of the vehicle, the ferromagnetic laminate material is arranged on a lower face of the guiding structure and the upper face of the vehicle and the lower face of the structure of guided face. Thus, the interaction between the magnetic means and the ferromagnetic material arranged in sheets is advantageously achieved, whereby when the gravitational force is compensated with the attractive force caused by the magnetic forces generated by the magnetic means, the vehicle is suspended from the structure without there being any type of contact between them.

Optionally, it is contemplated that the arrangement of the ferromagnetic laminate is continuous along the entire underside of the guide structure. Alternatively, in other embodiments a discontinuous arrangement of the material is contemplated.

In one embodiment of the invention, the underside of the guiding structure comprising the ferromagnetic laminate material is contemplated to be parallel to the direction of travel of the vehicle. Alternatively, one embodiment of the invention contemplates that the ferromagnetic sheet material is arranged perpendicular to the direction of travel of the vehicle.

The ferromagnetic laminate material, according to one of the embodiments of the invention, is arranged perpendicular to the longitudinal direction of the guiding structure. Thus, the path of the current is advantageously limited and losses are reduced.

The magnetic means, according to one of the embodiments of the invention, comprise: a permanent magnet configured to exert a first determined magnetic attraction force; a sensor configured to detect at least one characteristic parameter; and an electro-magnet, in communication with the sensor, configured to exert a second variable magnetic attraction force, as a function of the variation of a characteristic parameter with respect to a balance point. The feedback of the sensor output signal and the electromagnet input allow the electromagnet to be maintained between preset values associated with a balance point. Thus, advantageously, the vehicle is kept in an equilibrium point thanks to the correction actions of the electromagnet, which compensate for small variations and ensure a constant attractive force by means of a feedback loop, arranged between the sensor and the electromagnet, configured to adjust the second variable attraction force of the electromagnet based on the characteristic parameter detected by the sensor.

The guiding structure is contemplated, in one of the embodiments of the invention, to be a tubular structure configured to allow movement of the vehicle inside said tubular structure. Alternatively, the structure can be of the open type.

In one of the embodiments of the invention it is contemplated that the vehicle is a passenger transport vehicle, for example of the capsule type.

In one embodiment of the invention it is contemplated that the vehicle is a cargo transport vehicle.

A second aspect of the invention refers to a method of magnetic levitation by attraction of a vehicle under a guiding structure comprising the steps of:

a) providing a first magnetic force, by means of a permanent magnet arranged on the vehicle, which compensates for a first part of the gravitational force to which the vehicle is subjected under the guiding structure;

b) providing a second magnetic force, by means of an electromagnet arranged in the vehicle, that compensates for a second part of the gravitational force to which the vehicle is subjected under the guiding structure, where said second magnetic force is variable;

c) detecting at least one characteristic parameter, by means of a sensor arranged in the vehicle; and

d) depending on the variation of the characteristic parameter with respect to an equilibrium point of the vehicle, sending a signal to the electromagnet to vary the second magnetic force and return the vehicle to the equilibrium point.

Additionally, in one embodiment of the invention it is contemplated to provide a displacement force to the vehicle that causes movement of the vehicle along the guiding structure.

In one of the embodiments of the invention, detecting at least one characteristic parameter comprises obtaining a measure of the distance between the vehicle and the guidance structure. Thus, advantageously, a relevant signal is used to feed back the control actions of the electromagnet and modify the magnetic force produced by it to keep the vehicle at a distance from the guiding structure within safety margins.

In one of the embodiments of the invention, detecting at least one characteristic parameter comprises obtaining a measurement of the electric field generated by the electromagnet.

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 example of its embodiment, a set of drawings is attached in which, with an illustrative and non-limiting nature, they have been represented the following figures:

- Figure 1 represents a combination of magnetic means used in an embodiment of the invention, specifically a permanent magnet and an electromagnet.

- Figure 2 schematically represents an embodiment of the invention, where the magnetic levitation vehicle by attraction, equipped with the corresponding magnetic means, moves under the guiding structure.

- Figure 3 represents in detail the configuration of the material used in the guiding structure, specifically a laminated ferromagnetic material.

DETAILED DESCRIPTION OF THE INVENTION

The present invention discloses a method and a magnetic levitation system for high speed vehicles traveling according to a guidance structure.

The vehicles are moved by conventional propulsion systems and are kept in suspension thanks to the compensation of the weight of the vehicles with an attractive force generated by a combination of magnets capable of producing a variable magnetic force. The combination of magnets is provided with control means, to maintain the necessary balance point between the vehicle and the guidance structure, which monitor at least one characteristic parameter, such as the distance between the vehicle and the structure, with a closed loop system.

Figure 1 shows a combination of magnetic means consisting of a permanent magnet (1) and an electromagnet (2).

The permanent magnet (1) produces a magnetic attraction force (3) with respect to a ferromagnetic material (4) that follows a law of the type 1 / r2, so that for a given mass, there is a distance in which the force of gravity is equal to the magnetic force:

mg = K / r2

At this point of equilibrium, a magnet simply levitates magnetically, but in practice, the slightest disturbance modifies this distance and, as it is an unstable equilibrium, this point is not recovered.

To compensate for these possible disturbances, it is necessary to apply some control technique that allows the system to return to its equilibrium point. To do this, the present invention uses a closed loop system that consists of making constant readings of a relevant signal, such as the generated magnetic field or the distance between the vehicle and the structure, and establishing a compensatory control action based on of the signal read with the actuation of the electromagnet (2).

An electromagnet is a type of magnet in which the magnetic field is produced by the flow of an electric current that circulates, for example, through the turns of a wire wound (5) around the magnetic core (6). The main difference compared to a permanent magnet is that the magnetic field can be changed quickly by controlling the intensity of the electric current provided by the power supply (7), so that the magnetic force (8) it produces is variable. Thus, advantageously, the present invention compensates for the small disturbances that can occur during the movement of the vehicle under the guide structure and can take the system out of the balance point necessary to maintain the levitation controlled. Even in the case of a very heavy system, most of the force comes from the permanent magnet, so the power required to stabilize the system and the control actions of the electromagnet is manageable.

Figure 2 represents a particular embodiment of the present invention, where a guiding structure (20), which comprises a ferromagnetic material on its underside, is arranged at a certain height from the ground, in such a way as to allow a vehicle (21) move under said structure. In the upper part of the vehicle there is one or more magnetic means as explained above, for example a combination of a permanent magnet (1) and an electromagnet (2), which allow the vehicle to magnetically levitate by effect of the attraction that occurs between the combination of magnet and electromagnet and the ferromagnetic material arranged on the lower face of the guide structure.

During the movement of the vehicle under the guidance structure, in a state of magnetic levitation, the equilibrium point is maintained as a result of the compensatory actions of the electromagnet against any disturbance. To control the electromagnet, there is a sensor that detects a relevant reference characteristic with respect to which to establish the control actions. For example, the relevant characteristic may be the magnetic field or it may be the distance between the vehicle and the guidance structure. In the latter case, the sensor makes continuous readings of said distance and depending on the feedback of the characteristic parameter, to keep it at a preset value associated with a vehicle balance point, it sends a signal to the electromagnet to vary the second magnetic force and return the vehicle to balance point.

Specifically, this action regulates the intensity of the electric current, which generates the electromagnet's magnetic field, acting on its power source.

The sum of the magnetic forces produced by the permanent magnet and the electromagnet is what compensates the weight of the vehicle and supports it in the air under the guidance structure, but it must be ensured that the vehicle remains in a balance point by adjusting the threshold value of the chosen relevant characteristic and providing a sufficiently high frequency of readings at the sensor to allow correcting the magnetic force of the electromagnet in real time. In this way, the electromagnet's real-time corrective actions ensure that the vehicle never strays from its balance point so far that it loses lift and the state of magnetic levitation.

A tubular-shaped guide structure is also contemplated, but in both an open configuration and a closed tube configuration, the operation is the same.

The magnetic field generated by the combination of permanent magnet and electromagnet is therefore what keeps the vehicle in suspension. However, the vehicle suspended in the air travels at high speeds through the structure and this implies that induced currents are created as a result of the relative movement of the ferromagnetic material with respect to the magnetic field. The problem with induced currents is that they generate losses caused by two negative effects:

• A braking force is generated opposite to the movement.

• A repulsive force is generated opposite to that of the magnet.

In figure 3, the special configuration of the ferromagnetic material, arranged in the guide structure, used by the present invention to minimize the two effects described above can be seen in detail. Thus, the ferromagnetic material is advantageously arranged in sheets (30), which, in a similar way to the effect produced in laminated transformers, limit the path of current (31).

In this way, the present invention provides a system and method of magnetic levitation by attraction that keeps the force of attraction constant and reduces the losses caused by the material in the movements at high speeds.

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

Claims (9)

1. A magnetic levitation system by attraction characterized in that it comprises: - a guiding structure (20) configured to guide a magnetic levitation vehicle by attraction, wherein at least a part of said structure comprises a ferromagnetic laminate material (30); and - a magnetic levitation vehicle (21) by attraction configured to move under said guiding structure, where the vehicle comprises magnetic means configured to provide a variable magnetic field, where the variable magnetic field provided by the magnetic means of the vehicle causes a constant magnetic attraction force of the vehicle towards the ferromagnetic laminate material of the guiding structure that compensates for the weight of the vehicle. 2. System according to the preceding claim, where the magnetic means are arranged on an upper face of the vehicle; the ferromagnetic laminate material is arranged on a lower face of the guide structure; and where the upper face of the vehicle and the lower face of the guide structure face each other. 3. System according to claim 2, wherein the ferromagnetic laminated material is arranged parallel to a direction of travel of the vehicle. 4. System according to claim 2, wherein the ferromagnetic laminated material is arranged perpendicular to a direction of travel of the vehicle. 5. System according to any of the preceding claims where the magnetic means comprise: - a permanent magnet (1) configured to exert a first determined magnetic attraction force (3); - a sensor configured to detect at least one characteristic parameter; and - an electro-magnet (2), in communication with the sensor, configured to exert a second force (8) of variable magnetic attraction, depending on the variation of the characteristic parameter with respect to a point of equilibrium. System according to claim 5, further comprising a feedback loop, arranged between the sensor and the electromagnet, configured to adjust the second variable attraction force of the electromagnet as a function of the characteristic parameter detected by the sensor. System according to any of the preceding claims, wherein the guiding structure is a tubular structure configured to allow the vehicle to move inside said tubular structure. 8. System according to any of the preceding claims, wherein the vehicle is a vehicle configured to transport passengers inside. 9. System according to any of the preceding claims, where the vehicle is a vehicle configured to transport cargo inside.