AUTONOMOUS RETARDER SYSTEM FOR A VEHICLE, AND VEHICLE INCLUDING SAME

Abstract

The invention relates to an autonomous retarder system for a vehicle including a retarder (10) having a central rotor (11) and two stators (12), one on each side of the rotor (11). The rotor (11) is rigidly coupled to an axle (1). A generator (20, 30, 50) is also included, coupled to the retarder (10), for supplying same with electrical energy. In addition, the generator (20, 30, 50) comprises a stator (22) and a rotor (21, 31, 51) coupled to the retarder.

Claims

1. An autonomous retarder system for a vehicle that comprises: a retarder that comprises a central rotor and two stators on each side of the rotor, said rotor rigidly coupled to an axle, a generator coupled to the retarder configured to supply it with electrical energy, wherein the generator in turn comprises a stator and a rotor that is coupled to the generator.

2. The autonomous retarder according to claim 1, in which the stator of the generator is located externally and rigidly coupled to the stator of the retarder through the same axle.

3. The autonomous retarder system according to claim 1, in which the generator is a self-excited generator.

4. The autonomous retarder system according to claim 1, in which the generator is a permanent-magnet generator.

5. The autonomous retarder system according to claim 4, in which the generator is an externally excited generator.

6. The autonomous retarder system according to claim 5, in which the permanent-magnet generator is configured to provide excitation to the externally excited generator.

7. The autonomous retarder system according to claim 3, in which the permanent-magnet generator and the self-excited generator cooperate such that the permanent-magnet generator supplies electrical energy to the retarder when the rotational speed of the axle is lower than a first threshold and the self-excited generator supplies electrical energy to the retarder when the rotational speed of the axle is higher than a second threshold.

8. The autonomous retarder system according to claim 1, in which the central rotor is self-ventilated.

9. The autonomous retarder system according to claim 8, in which the central rotor comprises two lateral disks and a plurality of spaced ribs connecting said disks.

10. The autonomous retarder system according to claim 1, which comprises a braking regulation module configured to control the excitation current of the generator according to a control signal.

11. The autonomous retarder system according to claim 10, in which the regulator module comprises a rectifier and a voltage stabilizer.

12. The autonomous retarder system according to claim 10, which further comprises a temperature sensor to measure the temperature of the retarder and report it to the regulator module to reduce the current from the generator if this temperature exceeds a threshold.

13. A vehicle that incorporates the retarder system according to claim 1.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0018] FIG. 1: Exterior view of a retarder system with its housing, mounted on an axle.

[0019] FIG. 2: Interior view of a retarder system with two types of generators.

[0020] FIG. 3: Detailed view of the self-excited generator.

[0021] FIG. 4: Moving parts of a system with a self-excited generator.

[0022] FIG. 5: Non-moving parts of a system with a self-excited generator.

[0023] FIG. 6: Detailed view of the permanent-magnet generator.

[0024] FIG. 7: Moving parts of a system with a permanent-magnet generator.

[0025] FIG. 8: Non-moving parts of a system with a permanent-magnet generator.

[0026] FIG. 9: Detailed view of the system with two combination generators, one auxiliary generator that excites another principal generator.

[0027] FIG. 10: Non-moving parts of FIG. 9.

[0028] FIG. 11: Moving parts of FIG. 9.

DETAILED DESCRIPTION OF THE INVENTION

[0029] The figures describe several examples of embodiments but do not limit the invention.

[0030] Note that the selected configuration is not the customary configuration with two external rotors and an intermediate stator. The axial arrangement of one rotor and two stators is proposed as an alternative in the embodiments described here. The retarder rotor is positioned centrally, with the stators positioned on either side of it. This configuration mitigates problems of rotor locking caused mainly by exposure to weather. In cold climates, blocks of ice may form on the rotors, which could damage nearby elements if they are thrown off during rotation.

[0031] There are other advantages to selecting a central rotor. One is that it provides fixed air gaps. Another is that it can function regardless of the direction of rotation. The direction of rotation is especially important for cooling. With external rotors, when they rotate in one direction, air is forced into the retarder to cool it. Cooling problems may result if the direction of rotation is reversed. On another note, compared with the case of two rotors, the axial forces are neutralized when there is only a single rotor. These forces can cause warping of the retarder rotors.

[0032] FIG. 1 shows the external appearance of one embodiment of the retarder system. The retarder system is compact despite being equipped with a generator 20, 30, because the generator is integrated into the assembly. This makes it possible to house all of the components that are protected externally by a series of housings 3 on each side of the axle 1 on which it is mounted. This axle 1 may be an axle with a direct connection to the wheels, or may be a cardan shaft. Generally, the assembly is mounted on the axle 1 by means of a bushing 2.

[0033] FIG. 2 shows the complete interior of the aforementioned retarder system. For the sake of convenience, the embodiment of the system includes two different electrical generators on each side. Nevertheless, both generators may also be the same. Depending on the application, a single generator may even suffice to provide power to the retarder system. In turn, this single generator may be a permanent-magnet generator 30, or a self-excited generator 20, depending on the needs. For example, to reduce weight, a permanent-magnet generator would be preferable. On the other hand, if high braking torque is needed, a self-excited generator would be preferred.

[0034] The following figures complement FIG. 2, showing the two types of generators separately and in greater detail. The self-excited generator 20 is illustrated in FIGS. 3, 4, and 5. The permanent-magnet generator 30 is illustrated in FIGS. 6, 7, and 8.

[0035] As shown in the figure, the retarder 10 is positioned centrally, and the generators 20, 30 are coupled to the outside of the retarder 10. The rotating elements: the retarder rotor 11 and the rotors 21 (or 31) of the generator 20 (or 30) are fixed to a bushing 2, forming a monobloc assembly. The rest of the non-rotating elements of the retarder 10 and the generators 20, 30 are mounted using bearings 4.

[0036] Preferably, the retarder 10 rotor 11 will be a cast steel assembly. The rotor 11 may be manufactured as two disks 13 connected by a series of ribs 14, which are generally cylindrical. High electrical conductivity is required in the rotor to ensure that the absorbed power is greater for the same electromotive force, thus increasing the induced current. Also, high thermal conductivity facilitates the dissipation of the heat that is generated. Another important factor that promotes heat dissipation is the optimization of the design. To do this, the geometry of the ribs 14 will preferably be such that it is able to ventilate the inside of the rotor 11 with air, regardless of the direction of rotation of the rotor 11, thus facilitating heat dissipation.

[0037] When this assembly is installed on a railroad car axle, it is rigidly affixed to it, generally as a forced joint (pressed) as is done with conventional brakes. In other applications, the retarder 10 may incorporate its own axle.

[0038] The stators of the retarder 10 and generator 20, 30 will preferably be made of a ferrous alloy. The electromagnets 15 are fixed inside the retarder 10 stator 12, while the stator 22 of the generator 20, 30, with its cores and winding 28, is attached to the outside. The stator 22 is similar for the two types of generators (self-excited 20 and permanent-magnet 30).

[0039] An exterior ring with bearings suitable to withstand the weight of the retarder, as well as the axial and radial forces that produce vibration, may be used to mount it on the axle 1. To regulate the axial clearance of the bearings 4 of the stators 12, they have been designed with a series of braces 5 and nuts that set the air gap distances.

[0040] Also, a series of supports secure the stators 12 to a frame or chassis to prevent them from turning with the axis 1.

[0041] The generator 20 is self-excited by the winding 27 of the fixed pole core 26, secured to the outside of the retarder 10 stator 12 (or stators, if two generators are needed on each side). The remanence on this pole core 26 must be large enough to make pre-excitation unnecessary (it is made of hard magnetic materials).

[0042] The rotor 21 of the generator 20 is preferably mounted securely to the bushing 2 and has an interior configuration with a solid core. The fixed pole core 26 is included inside, and is frictionless, which is to say that the preliminary air gaps are maintained.

[0043] The stator 22 of the generator 20 is properly secured to the outside of the stator 12 (or stators) of the retarder 10, on the same side as the fixed pole core 26. This stator 22 is made up of sheets that are insulated from one another, equipped with a series of slits, which are tightly compressed to form a compact core. The stator windings 28 are installed in the aforementioned slits.

[0044] The field magnetizes the disks 13 of the rotor 11, alternating N-S, when they turn, inducing an alternating current on the stator 22 winding 28 of the generator 20.

[0045] The other type of generator shown in FIG. 6 to FIG. 8 is a permanent-magnet generator 30. The source of electrical energy is achieved by means of a rotor 31 with permanent magnets that are fixed to the bushing 2, with the generator 30 stator 22 secured to the outside of the retarder 10 stator 12.

[0046] Both types of generators 20, 30 are properly sized to supply the necessary power to the retarder 10, which is responsible for braking above a certain speed threshold. At slower speeds, the conventional mechanical brake must be applied until the vehicle comes to a complete stop. These two generators 20, 30 may act individually or jointly on the retarder 10, functioning independently.

[0047] The rotors or inducers 21, 31 of the generators 20, 30 generate the magnetic field necessary for the windings of the stators 22 of the generators to generate the corresponding alternating current.

[0048] The retarder 10 functions with no wear or friction, and the bearings 4 are the only parts that are subject to wear. Alloys are preferably used in their manufacture, combining those that are magnetic and non-magnetic, in order to make better use of flows and prevent them from dispersing. Welds should preferably be avoided, bolting the elements and sub-assemblies precisely and securely, based on the thermal fatigue stresses to which they are subjected.

[0049] A braking regulator module 40 will be responsible for controlling the braking force. The braking regulator module 40 is an electronic control device that converts and controls the current from the power supply for use directly on the windings of the retarder 10, based on the parameters programmed according to the required operating conditions.

[0050] This regulator module 40 modifies the power supply of the retarder 10 linearly, allowing more or less power supply voltage to enter the retarder 10 in a linear manner, which provides precise control over braking. The braking regulator 40 generally includes a rectifier and a voltage stabilizer. The generator 20, 30 produces alternating current, transforming the mechanical energy of the rotation produced by the axle 1 into electrical energy to power the retarder 10. Since this is alternating current, it must be rectified for correct functioning and control of the retarder 10. The rectifier converts the alternating current into direct current. It also includes a voltage stabilizer to keep it approximately constant, without variations when rpm (revolutions per minute) increase or decrease.

[0051] Part of the braking regulator module 40 is located next to the retarder 10, but the control will preferably be located in another place. For example, in railway vehicles, it is generally located inside the train's cab to be manipulated by the operator and to control or monitor the braking force of all of the cars.

[0052] The control input that the regulator module 40 receives is the desired braking signal from the central computer system, which may be manual or automatic. It also receives the actual rotation speed detection signals and the digital input-output signals, to receive information or safety conditions from the vehicle's central system, and also to send these signals to the vehicle's central system.

[0053] The regulator module 40 is preferably programmable for different operating limit curves, for example, direct or inverse signal, or linear or quadratic response. A fully autonomous power supply is achieved by generating current using the integrated generator 20, 30. The regulator module 40 controls and sends the excitation current from the generator in the form of a closed servo control loop, to obtain braking current based on the control signal and within the limits of the previously programmed curves.

[0054] In addition, for greater safety, a temperature sensor installed on the brake can be used in any of the embodiments described to limit the maximum power levels that are developed.

[0055] Finally, another specific embodiment that uses a generator with higher output is described. If the hard materials in a self-excited generator are replaced with soft materials (core 56), the generator may no longer be self-excited, but in exchange generates much greater output. This type of generator will be referred to hereinafter as an “external-excitation generator 50”. FIG. 9 to FIG. 11 show a retarder system that is equipped with this generator 50 as the principal generator, along with a permanent-magnet generator 30 as an auxiliary. Preferably, the core 56 (low remanence) has the same composition as the ferrous parts of the stator 12.

[0056] The self-excitation is due to the fact that hard materials, once magnetized, behave like permanent magnets. Consequently, soft materials are easily demagnetized and their losses are lower, so they may be preferable in applications with higher output (they have lower hysteresis losses than hard materials, so they do not heat up as much and output is higher).

[0057] In this case, the excitation to create the magnetic field needed in the generator 50 must be provided externally to start up. Specifically, this can be done advantageously through a small auxiliary permanent-magnet generator 30. This allows the generator 50 that is acting as the main generator to be optimized as much as possible. In other words, once the rotor 51 reaches an adequate speed, it is no longer excited by the generator 30, which will be deactivated.

[0058] This mixed or hybrid configuration is also especially desirable in a situation in which the retarder 10 has a low number of revolutions. It is then that the braking torque, and consequently the power supply to the retarder, must be the highest. For this reason, soft materials must be used in the fixed pole core as well as in the pole masses. The use of soft materials results in high levels of magnetic saturation, and also eliminates the passive resistance to rotation when there is no excitation, reducing inertia to insignificant levels.

[0059] The control of external excitation in a mixed configuration is provided by an electronic system that can be integrated into the regulator module 40, which controls the power that is supplied by the auxiliary generator (permanent-magnet generator 30) to the induction winding of the retarder generator. This is fixed to the axle and rotates, so the electronic system is responsible for ensuring that the auxiliary generator sends an excitation supply with the highest power when the axle is rotating at lower rpm. And in the opposite case, when the axle is rotating at high rpm, the system will limit the excitation power supply of the induction winding of the retarder generator, because it requires less excitation voltage when it is rotating at high rpm.

GLOSSARY OF NUMERICAL REFERENCES

[0060] 1 Axle. [0061] 2 Bushing. [0062] 3 Housings. [0063] 4 Bearings. [0064] 5 Braces. [0065] 10 Retarder. [0066] 11 Central rotor of the retarder 10. [0067] 12 Stator of the retarder 10. [0068] 13 Disks. [0069] 14 Ribs. [0070] 15 Electromagnets. [0071] 20 Self-excited generator. [0072] 21 Rotor of the self-excited generator 20. [0073] 22 Stator of the generator (either self-excited 20, with permanent magnets 30, or external excitation 50). [0074] 26 Stationary hard core (with high remanence). [0075] 27 Core winding. [0076] 28 Windings (of stators of generators 20, 30, 50). [0077] 30 Permanent-magnet generator. [0078] 31 Rotor of the permanent-magnet generator 30. [0079] 40 Regulator module. [0080] 50 External-excitation generator. [0081] 51 Rotor of the external-excitation generator. 56 Stationary soft core (or low remanence).