PL205415B1 - Vacuum connector extinguishing chamber - Google Patents

Description

Description of the invention

The subject of the invention is an extinguishing chamber of a vacuum circuit breaker, used in current switches with the intensity of the disconnected short-circuit current exceeding 10 kA.

High values of transmission and short-circuit currents in power grids make more and more demands on switchgear, including circuit breakers in particular. In recent years, vacuum circuit-breakers have become more and more popular among users not only due to their high switching capacity, excellent insulating properties of the contact gap, high connection and mechanical durability, but also due to their environmentally friendly (ecologically safe) design.

Switching off the current with vacuum switches for currents up to 10 kA does not present any technical difficulties at present. With sufficiently large dimensions of the electrodes, the electric arc accompanying the switching processes has a dispersed form (it is the so-called diffusion arc), characterized by the existence of cathode plasma and macroparticle sources (in the form of cathode spots) and the lack of thermal and emission activity of the anode. Such working conditions of the vacuum switch correspond to the minimal and uniform heating of the electrodes during the arc period, the rapid disappearance of particles in the volume of the vacuum chamber when the current passes through the zero value, high half strength of the contact space, and the greatest durability of the contact system, limited only by the erosive action of cathode spots.

Under the influence of electrodynamic interactions, for a current with values greater than 10 kA (even for large dimensions of the electrodes), the arc compresses in a vacuum, creating a concentrated (also called narrowed) form. The arc of this form, especially when it remains stationary for a long time, causes their strong erosion as a result of local and deep melting of the electrodes. Due to the long cooling time, the deep craters filled with the liquid metal of the electrodes and the large and hot metal drops thrown into the space of the vacuum chamber contribute, through the emission of vapors, to the reduction of the voltage strength of the switch after passing the current half-wave through the zero value, which may cause the arc to re-ignite.

After the craters and metal infiltrations on the electrodes solidify, even with the application of high contact pressure, it is no longer possible to obtain their adhesion over a large surface. In the conditions of throughput of the switch, this causes an increase in contact resistance with local areas of increased current density, and thus also heating.

In order to reduce the negative effects of an arc, vacuum circuit breakers have been using for many years either methods of electrodynamic forcing the arc motion (e.g. by using contacts generating a radial magnetic field) or methods aimed at raising the limit of the current value at which the discharge concentration occurs. The second method is achieved by acting on the electric arc with a magnetic field parallel to the direction of the plasma flow (the so-called axial magnetic field), produced either by means of a suitably shaped contact, or by using external coils connected in series in the arc current flow circuit. It should be added that the use of an axial magnetic field (regardless of the method of its production), apart from stabilizing the discharge, additionally lowers the arc voltage, which contributes to the limitation of the amount of energy released in the discharge.

To increase the switching capacity of the vacuum circuit-breaker by forcing the arc to move (e.g. to reduce the melting of the contact tips and limit the erosion of the electrodes), contacts with spiral or corona electrodes are used, shown in Fig. 1 and Fig. 2 (the drawings are taken from the literature) .

The drawings show both the construction and the idea of operation of the contacts. At present, they are practically the only industrially manufactured forms of electrodes generating a transverse (radial) magnetic field Br, which, by applying the force F on the arc column, forces the arc to move around the edge of the electrodes.

The tests show that the contact systems presented above fulfill their tasks when switching off high currents I, provided that the instantaneous value of the arc current at the moment of electrode separation is not less than 7-10 kA. In real working conditions, however, there are often cases when the switch contacts are separated at the beginning of the current flow half-wave, and the current during the arc increases to a very large value. In such cases, the electric arc at the beginning of its existence has a weakly concentrated (or classical diffusion) form and initially scatters throughout the entire contact space. Further increase in current causes

Electrodynamic compression of the arc (the so-called pinch effect) in the central part of the electrodes (in the contact axis) where the radial magnetic field practically does not exist. The arc is therefore "anchored" and the contact does not fulfill its purpose. Additionally, in the case of contact with the corona electrodes (with open cavities on the discharge side, not covered by the annular contact strips), the arc penetrates into the electrode cavities, in which the molten construction material of the contact fills the gaps (cuts) between the electrode segments, causing a deterioration of the magnetic field generation efficiency. The existence of an open (from the arc side) cavity in the electrodes is generally disadvantageous.

The possibility of the occurrence of an electric arc in a concentrated or diffusive form, depending on the instantaneous (randomly occurring during switching processes) current value, suggests that the appropriate contact solution should be a design that uses both the axial magnetic field (when the arc is diffusive) and the radial field (when in phase electrode separation, the arc was concentrated).

If you want to use the axial magnetic field generated by typical electrodes (in which the circumferential component of the current flow generates the axial component of the magnetic field in the inter-contact area), one should take into account the fact that the magnetic induction has a maximum in the electrode axis and decreases as it moves away towards the edge of the contacts. Experimental studies show that the high-current vacuum arc, despite stabilizing under the action of the axial magnetic field, tends to concentrate in the area of the maximum value of the magnetic induction. This means that the distribution of the field with its maximum value in the axis of the electrode system will result in the arc concentration in this area, which will consequently cause increased local electrode melting and will reduce the switching capacity of the vacuum circuit-breaker.

In order to counteract the concentration of the arc in the central part of the contact system, many companies have developed special designs of electrodes producing multipolar (usually 2 or 4) distributions of axial magnetic field induction in the contact space. These structures are characterized by considerable complexity and functionally cause the electric arc to be separated into parallel discharges, the number of which corresponds to the number of pole pairs of the generated magnetic field. Also in these cases, an increase in the arc concentration in individual arc columns is observed in the vicinity of the maximum magnetic field induction of individual poles. This means that the inter-pole areas and consequently the electrode surfaces are not used efficiently.

Increasing the connecting capacity of the connector with the axial magnetic field is also possible by shaping the magnetic field in such a way that its radial distribution will be axially symmetrical with a minimum in the axis of the electrodes and a maximum in the vicinity of their edges.

It should be emphasized that the contact systems with axial magnetic field used so far in vacuum switches do not generate a radial magnetic field, which could force the arc to move as a result of electrodynamic interactions.

The essence of the invention, which is the extinguishing chamber of a vacuum switch, which is closed and sealed in ceramic insulators and a condensation shield, located on the current paths, electrodes with cylinder-shaped contacts with contact strips, one of which is a fixed electrode, the other one is a movable one, that one of the contacts on its peripheral surface has at least three oblique cuts, inclined in relation to the current flow surface at an angle α <90 °, preferably 30 °, and that each of the contacts in the area of the contact strip having a recess on its surface has a cylinder-contour socket wherein a ring of soft magnetic material is located.

Thanks to the solution according to the invention, the following technical and operational effects were obtained:

- creating both radial and axial magnetic fields in the interstitial space,

- preventing the arc from concentrating in the central part of the contact,

- increasing the switching capacity of the switch in relation to electrodes with cylindrical contacts that do not generate an axial magnetic field and in relation to conventional electrodes with an axial magnetic field of the same geometrical dimensions,

- independence of contact effectiveness from the form of arc discharge,

PL 205 415 B1

- forcing the movement of high-current arc during breaking the short-circuit current, when the contact is opened at a high instantaneous current value,

- generation of a high-current diffusion arc when switching off the short-circuit current, when the contact is opened at a small instantaneous current value,

- reduction of electrode erosion in relation to conventional solutions,

- can be used in extinguishing systems with contacts that automatically generate a radial magnetic field.

- the possibility of optimizing the distribution of the induction of the axial magnetic field in the contact space of the vacuum circuit breaker by selecting the geometric dimensions and distances of ring magnets, as well as by selecting the shape of the cross-section of the cores and the magnetic properties of their material,

The subject of the invention, in an exemplary embodiment, is shown in the diagram in the drawing, where Fig. 3 shows the chamber in section, in a plane passing through its longitudinal axis, and Fig. 4 shows the electrodes in section in a plane passing through their longitudinal axis.

The extinguishing chamber of the vacuum switch, which is closed and sealed in ceramic insulators 1 and a condensation shield 2, located on the current paths 3, electrodes 4 with contacts 5 with a cylindrical shape with contact strips 6, with a recess 10, one of which is a fixed electrode, the other a movable one. One of the contacts 5 has at least three oblique notches 7 on its peripheral surface, inclined with respect to the current flow surface at an angle α <90 °, preferably 30 °, and each of the contacts 5 in the area of the contact strip 6 has a socket 8 with a cylindrical profile, in which is located a ring 9 made of a soft ferromagnetic material.

The method of simultaneous generation of radial and axial magnetic field in the inter-contact space of vacuum switches and the method of shaping the mutual distribution of these fields in the extinguishing chamber is based on the fact that the components of the magnetic field, both radial and axial, are generated by a contact having cuts in its circumferential (cylindrical) ) surface. From the point of view of shaping the distribution of the axial magnetic field, the desired effect is obtained by using ferromagnetic rings with the axes directed in the direction of the required axial magnetic field affecting the arc discharge. In the presented solution, this field has an axially symmetric distribution. The use of ferromagnetic rings results in shaping the radial distribution of the magnetic field in such a way that its axial symmetry is maintained, but the maximum magnetic induction occurs between the opposite surfaces of the rings and decreases both in the direction of the contact axis and for distances greater than the radius of the outer ring. The location of the maximum and the ratio between the maximum and minimum values of the axial magnetic field induction in the contact area can be influenced by changing the diameters of ferromagnetic rings, changing the ratio between the diameter of the rings and their height, and by changing the distance between the rings. This means that in the case of composite cores with the contact solid, for given geometric dimensions, the area between the contacts will change during the separation of the electrodes. When switching off the current (extinguishing the arc), this situation also occurs in conventional solutions of electrodes with an axial magnetic field (both coreless and with ferromagnetic cores).

The cross section of the ferromagnetic ring need not be rectangular. Moreover, by modifying the shape of this cross-section, it is possible to influence both the position of the maximum and the width of the ridge in the course of the distribution of the induction of the axial magnetic field and the steepness of the decrease in the value of the magnetic induction towards the center of the electrodes and towards the edge of the contact. In order to reduce energy losses in ferromagnetic rings, they should be made of a material with the highest possible resistivity. The magnetic properties of the ring material also determine the permissible operating temperature of the contact system.

In order to create a magnetic field between the electrodes 4, directed radially in relation to the plasma axis of the arc discharge, it is necessary to obtain a circumferential (azimuth) direction of the current flow in the electrode material 4. For this purpose, in one of the contact bodies 5, in its cylindrical wall, incisions 7 directed obliquely to the working surface of the electrodes 4. The electrodes 4 are closed on the discharge plasma side by contact strips 6 made of a material with increased resistance to electric arc and are hollow inside. The current flowing along the wall of the oblique electrode 4 from the current path 3 to the contact strip 6 is

Between the segments of the contact body, and the individual current streams obtain the flow component in the circumferential direction. The performed calculations and measurements show that a single, incised electrode generates both the axial and the radial component of the magnetic field. Both components, due to the presence of ferromagnetic rings, undergo local strengthening in the active inter-contact space.

However, the effective influence of the radial field concerns only the edge part of the electrodes, i.e. the area between the faces of the sockets 8 hollowed in the electrodes 4. For this reason, the contact strips 6 have a recess 10 on a diameter smaller than the internal diameter of the socket 8 of the electrodes 4, which in the operating conditions of the contacts 5 causes them adhesion in the vicinity of the shore. The exact point of contact is not critical and depends on the degree of erosion (destruction) of the electrodes. It is important, however, that when the current is switched off, the arc is initiated in the edge part of the contacts 5. If the discharge remains concentrated (high instantaneous current value), it is affected by a radial magnetic field and the arc moves. If the discharge breaks down into a diffusion form (the cathode spots spread over the entire cathode surface), the arc will be under the action of the axial magnetic field formed by the ferromagnetic rings 9, which will prevent the formation of a concentrated arc.

The use of ring ferromagnets allows for the creation of an axial magnetic field with such a distribution of magnetic induction that its maximum value is located between the faces of the rings and not in the center of the contact, which increases the switching capacity of the contact.

Claims (1)

The extinguishing chamber of the vacuum switch, which is closed and sealed in ceramic insulators and a condensation cover, electrodes with cylinder-shaped contacts with contact strips located on the current paths, one of which is a fixed electrode and the other a movable one, characterized in that one of the contacts (5) it has at least three oblique notches (7) on its peripheral surface, inclined in relation to the current flow surface at an angle α <90 °, preferably 30 °, and each of the contacts (5) in the area of the contact strip (6) having a depression on its surface (10) has a cylinder-shaped seat (8) in which a ring (9) made of a soft magnetic material is located.