Electrical transmission or interconnection systems – Anti-induction or coupling to other systems – Magnetic or electrostatic field control
Reexamination Certificate
2000-12-11
2002-12-10
Jackson, Stephen W. (Department: 2836)
Electrical transmission or interconnection systems
Anti-induction or coupling to other systems
Magnetic or electrostatic field control
C307S089000, C307S104000, C174S032000
Reexamination Certificate
active
06492746
ABSTRACT:
OBJECT OF THE INVENTION
The present invention relates to a device which can compensate, at origin, the magnetic field perturbations in the surroundings of the tracks of an electrically driven train caused by variations in the current of the power supply catenary.
The method relies on shielding the magnetic field with a circuit of suitable geometry to compensate or reduce the field created by power lines of an electrical train.
The method consists of reducing the magnetic field created by the variations in the power catenary current by rerouting the return currents in the tracks. This rerouting is achieved by conductors placed perpendicular to the track and is directed towards a conductor parallel to the catenary. Thus, fluctuations of the magnetic field caused y current fluctuations in the loop formed by the catenary and the return conductor may be compensated at origin regardless of the distance and orientation of the receiver of the perturbation with respect to the path of the train.
The system is applied only to segments of the underground line which are near areas requiring shielding for diverse reasons.
BACKGROUND OF TH INVENTION
Nowadays there are growing problems with electrical systems, computers, electron microscopes, nuclear magnetic resonance units, etc. due to perturbations of the Earth's magnetic field mainly caused by underground metropolitan trains which run nearby or under the sites in which these are installed. The problem is particularly serious for trains powered by a catenary line and current return on the tracks, and particularly when employing low voltage direct current (0, 6-3 KV), and therefore high currents, on the order of 1-10 KA. In these cases the variable magnetic field created by current variations in the catenary-train-track loop reaches large values, on the order of the Earth's magnetic field at distances on the order of 100 metres from the train line.
In certain cases magnetic shielding of the affected equipment has been proposed as a solution. On occasions it is simply the Earth's magnetic field that is shielded (WO9738534). This method suffers from disadvantages as it never obtains reductions above one tenth of the field which is shielded, and is expensive.
Shielding of the source of the perturbation, such as shielding the train tunnel with a magnetic metallic material causes interactions with radiotelephony, capacitance problems and is extremely costly.
The ideal method to eliminate perturbations would be to practically annul the area of the current loop by having a return current conductor near and parallel to the catenary, or equivalently a catenary power supply conductor placed between the tracks. However, as the train is moving and with it the point at which the catenary-train-track circuit is closed, the geometry or size of the loop originating the perturbation field are also variable and therefore cannot be compensated with a return conductor with a fixed geometry.
Compensation at origin using return circuits has been performed by other authors (WO9633541) for high voltage lines. The difference between these systems and the one here considered is that, firstly, the field to be compensated is geometrically invariant over time, while the object of the present Patent is to shield a magnetic field which varies in a non-uniform manner. Other latter inventions (application P9802654) deal with the problem at the source of the perturbing field and instead of shielding with ferromagnetic metallic material use a compensation current loop controlled by magnetic field sensors.
The present invention, instead of compensating at the source with active compensation loops uses the same catenary-train-track power supply current so that, through a return conductor parallel to and near the catenary, the loop causing the perturbations is eliminated. This is achieved by an electrical sectioning of the track in which perturbations must be eliminated and taking the return current to the catenary by vertical conductors placed symmetrically on the walls of the tunnel or on the catenary support columns in open air lines.
DESCRIPTION OF THE INVENTION
The system of currents for compensating the magnetic field produced by electrically driven trains, object of the present invention, is based on reducing the effect of current fluctuations produced by power absorption and release of electric traction engines which generate a strong magnetic perturbation field in catenary powered trains where the track-engine-catenary-substation form a large surface current loop- All of this is achieved by a conductor located in the top area of the tunnel parallel to its section, which we shall term the return conductor. Only at areas where this is desired, the track shall be sectioned into successive electrically insulated conductor segments mutually insulated from each other, allowing to install as many return conductors as are required to obtain the displacement of the engine along the shielded area. The length of the sectioned segments is calculated and optimised considering the size of the engine and the geometrical conditions which provide the optimum results.
Specifically, and with reference to the description of the figures, the system of currents for compensating the magnetic field produced by electrically powered trains consists in creating a current to compensate the magnetic field produced which, according to
FIG. 1
, begins at substation (
1
), passes through catenary (
4
), reaches engine (
2
) and returns along tracks (
5
). Likewise, and with reference to the figures,
FIG. 3
a
shows the first case object of study. As we are here outside the shielded area and on the side of the substation (left) current returns in the normal manner and through the track.
FIG. 3B
shows the return when still beyond the shielded area we are on the opposite side of the substation (right). In this case it is necessary to use the return conductors (
6
) as shown in the sketch. The current from the substation arrives, through the catenary, to the engine, from where it returns along the tracks until reaching the first vertical conductor, which shunts it to the horizontal return cable parallel to the catenary. In this manner it crosses the dangerous area and once it is crossed descends along a vertical conductor to the track finally reaching the substation. The dotted line shows the geometry of the current circuit. With this new geometry two objectives are obtained: reducing the are of the track-engine-catenary-substation circuit and obtaining, in the area object of the shielding, a compensation of the catenary current by the return current parallel to it.
When entering a danger area (FIG.
4
), on the side nearest the substation, the cut performed in the track allows to design a favourable return current (FIG.
4
A). The current arriving from the substation reaches the engine, returns along the track along a short segment and just before reaching the cut rises along a return conductor to the horizontal one. Along the horizontal conductor it reaches another vertical conductor beyond the cut, along which it descends to reach the substation along the track. Thus, the surface area of the circuit is also reduced and in a small area a return current parallel to the catenary is obtained. FIG.
4
A′ shows the appearance of the circuit if the engine moves away from the substation and the same return circuit is used. The lack of cuts in the tracks would force us to use the same vertical return conductor. In this case in addition to having a circuit with an enormous area there would not be a return current parallel to the catenary.
FIG. 4B
shows the situation of
4
A′ but here with cuts made in the track. This allows to install as many vertical return conductors as desired. As the engine advances, it will use the one nearest to it. This allows to minimise the circuit area and to have a return current parallel to the catenary.
It must be remarked that an circular arc-shaped current (
6
) leaves each rail (FIG.
5
). In other words, what is represented in
FIGS. 3 and 4
as
Briones Fernandez Pola Fernando
Hernando Grande Antonio
Marin Palacios Pilar
Rivero Rodriguez Guillermo
DeBeradinis Robert
Jackson Stephen W.
Katten Muchin Zavis & Rosenman
Universidad Complutense de Madrid
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