The present invention generally relates to electrical switches and/or disconnectors, particularly suitable for quenching an electrical arc occurring between contacts in the opening and closing operations.
More specifically, the invention relates to a method and a device for cutting off electric current, using magnetic blow-out for quenching the electrical arc, the purpose of which is to increase the arc quenching capacity, and at the same time reduce manufacturing costs.
The method and device of the invention can be applied to any type of breaker, switch or disconnector, either with moving contacts with linear, rotational or helicoidal movement, with a one-pole or multi-pole configuration.
The mechanical switches are devices used to connect and disconnect a load from an electric power source and are based on applying an external force moving several moving contacts with respect to other fixed contacts, such that when the circuit is going to close, the moving contacts come into contact with the fixed contacts, electrically connecting a load and an energy source, and thereby allowing current circulation.
The opposite process corresponds to the movement of the moving contacts with respect to the fixed contacts, such that these moving contacts move away from the fixed contacts, making the circuit open and therefore interrupting current circulation.
Switches with a different type of movement of its moving parts, either with linear, rotational or helicoidal movement, are known. European patent application EP2,667,394A1 describes an example of a switch with linear movement of the moving contacts. Spanish utility model ES1116655U describes a rotating switch, and European patent application EP2,866,244A1 describes a helicoidal switch.
During transitory opening and closing operations, electrical arcs or voltaic arcs are formed in the contact areas between the moving and fixed contacts. Electrical arcs are known to cause many problems because the heat generated during the occurrence of an electrical arc is highly destructive. Some of these problems are: deterioration of the materials of the switch, malfunctions and/or complete or partial destruction of electrical installations, including injuries to people caused by burns or injuries of another type.
The problems in quenching electrical arcs are particularly notable in direct current interruption, because unlike alternating current, there is no zero-crossing, such that electrical arcs must be eliminated as quickly as possible by means of deionizing the medium and increasing dielectric resistance.
One of the techniques known for increasing efficacy in quenching an electrical arc specifically in the case of DC switches, is the use of a blow-out with a magnetic field generated by permanent magnets.
The technique currently used to produce the magnetic blow-out is to place several permanent magnets in a fixed position such that they drive the electrical arc as quickly as possible to a quenching area, such as deionizing chambers, elongation partitions, etc.
Since the permanent magnets are placed in a fixed position, the generated magnetic field always remains stationary, so in order for the magnetic field to reach the entire area in which the arc extends, several magnets must be used or polar expansions must be added to increase the surface of the magnetic field depending on the length of the path between fixed and moving contacts.
Spanish utility model ES1116655U shows an example of these magnetic blow-out techniques using several permanent magnets installed in a fixed position of the switch.
Since several magnets and polar expanders are required, these conventional techniques involve an increase in the material used, as well as an increase in the volume of the switch for housing the magnets near the area where the electrical arc occurs.
Generally, in the known techniques, the magnets are placed in an intermediate position of the maximum path between the fixed contact and the moving contact, so the magnetic field interferes with the electrical arc once the arc has already been generated, which limits the arc quenching capacity.
The invention is defined in the attached independent method and device claims.
One aspect of the invention relates to a breaker, switching and/or disconnector device for cutting off an electric current, conventionally comprising at least one fixed contact and at least one moving contact that can move reciprocally between a closed position in which it establishes electrical continuity and comes into contact with the fixed contact, and an open position in which it is separated from the fixed contact and prevents current circulation. The device also comprises one or more permanent magnets, placed so that their magnetic field passes through (or interferes with) an area of the device in which the occurrence of an electrical arc between the fixed contact and the moving contact in opening and closing operations is expected, such that the magnetic field causes the elongation of the arc and thereby helps to quench it.
The device of the invention is characterized in that the permanent magnet or magnets are mounted together with the moving contact, such that the moving contact and the permanent magnet or magnets move at the same time. The permanent magnet or magnets are mounted in the moving contact by means of a part made of an isolating material, such that the magnets are not in contact with the fixed contacts. That part made of an isolating material can consist of a support specifically designed for mounting the magnets with the fixed contact, or can alternatively consist of the actuator of the breaker, for example the slide or rotor of the breaker.
One technical effect that is obtained with this arrangement of elements is that it achieves, in a very simple manner, the magnetic field generated by a magnet being dynamic, i.e., the magnetic field moves at the same time as the moving contact in which they are installed. It can therefore be said that the magnetic field chases the electrical arc, so with a single magnet, instead of several as occurs in the state of the art, a magnetic field is applied in the very instant the arc occurs, and throughout the entire space in which the arc extends.
One of the main advantages of the invention is that the number of magnets required in each cut-off area is reduced, and therefore the material required for applying the field to the entire area where the arc occurs is reduced.
Furthermore, since the permanent magnet is mounted with the moving contact as proposed by the invention, it is possible to place the magnet very close to the space between the fixed contact and the moving contact in the electrically closed position. An additional technical effect and advantage associated with said arrangement of the permanent magnet is that the magnetic field is applied in the area where the arc occurs even before the arc is generated, so in the very instant in which the arc starts to occur in an opening operation, the arc runs into the magnetic field which complicates the flow thereof. The arc quenching capacity is thereby enormously increased, and the quenching time with respect to the techniques known today, in which the magnetic field only interferes with the arc in an instant after it is generated, is reduced.
The invention can be applied to any type of breakers or switches having one or several poles, whether they are breakers with moving contacts having linear, radial or helicoidal movement.
Another aspect of the invention relates to a method for cutting off an electric current, preferably by means of the breaker described above. The method comprises moving a moving contact with respect to a fixed contact to interrupt electric current circulation, and to apply a magnetic field by means of a permanent magnet such that it interferes, i.e., passes through an area where an electrical arc occurs between the fixed contact and the moving contact when the fixed contact and the moving contact move relative to one another, and such that the magnetic field complicates the creation of an arc and helps quench it.
The method is characterized in that it comprises moving the permanent magnet in the transitory opening and closing phases of the breaker, such that the generated magnetic field runs throughout the area where the arc occurs from its point of origin.
In a preferred embodiment of the invention, the permanent magnet and the moving contact move linearly with respect to a longitudinal axis. In another preferred embodiment, the permanent magnet and the moving contact move rotationally on one and the same plane with respect to an axial axis, and in another preferred embodiment they move in a helicoidal manner with respect to an axial axis.
The same technical effects and advantages discussed above with respect to the switching device are also obtained with the method of the invention.
Said area where the arc occurs can be defined as the space that is formed between the fixed contact and the moving contact in which electrical arcs are expected to be formed, including the electrically closed position and subsequently the space between both as these two contacts move relative to one another, whether in the opening or closing operation of the breaker device.
Several preferred embodiments of the invention are described below in reference to the attached drawings, where:
The breaker (1) has two cylindrical permanent magnets (4a, 4b), which are mounted together with the moving contact (6) on one of its faces by means of a support (5) made of an isolating material. This support (5) is clamp-shaped at the ends thereof, such that the magnets (4a, 4b) are retained by elastic pressure at said ends, as depicted with more detail in
The permanent magnets (4a, 4b) have diametric polarization, i.e., a semi-cylinder of the magnet has one polarity, and the other semi-cylinder has the opposite polarity, as shown in
The support (5) is fixed on the moving contact (6), such that the magnetic field generated by each of the magnets (4a, 4b) interferes respectively with each area where an electrical arc occurs (7a, 7b) between each of the fixed contacts and the moving contact. Both the moving contact (6) and the fixed contacts (2a, 2b) are metal flats with a generally rectangular shape with upper and lower faces. As seen in the drawing, the permanent magnets (4a, 4b) are arranged on the upper face of the moving contact (6) which is also the face intended for coming into contact with the lower face of the fixed contacts (2a, 2b).
In the embodiment of
As shown in
The embodiment of
The embodiment of
The blow-out process of the embodiments of
As an alternative to the use of a support (5) for mounting the magnets (4a, 4b) with the moving contact (6), the magnets can be fixed to the actuator, i.e., to the slide (8) in the embodiment of
The method of the invention is depicted, for example, in
It is also seen in
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20170358402 A1 | Dec 2017 | US |