HU187905B - Arc extinguishing construction for electric switches - Google Patents

Abstract

Arc extinction device for heavy current switch uses de-ion arc extinction chamber with plates of different length on opposite sides

Description

The present invention relates to an arcuate for the electrical switching device with a standing contact and a movable contact, a metal diverting arcuate for a metal arcuate with a deionic sheet arcu assembly.

The purpose of the arc extinguisher used in electrical switching devices is to extinguish the electric arc generated by contact separation when the circuit is switched off.

Many arc extinguishing mechanisms consist of a stationary and movable contact formed in a manner known per se, an air gap or a metal diverting arc deflector assembly, and a so-called deionic sheet arc chamber. The working principle of such arc extinguishers is the following: when switched off, an electric arc is created between the contacts. The magnetic field of the expediently designed power leads - the so-called. magnetic blowing - and the current flowing through the arc - is the so-called. arc current - through its interaction electromagnetic force acts on the electric arc. As a result, the base of the arc moves away from the contacts and reaches the arc deflector assembly, which guides the continuous arc to the flange of the deionic sheeting chamber. Meanwhile, the force exerted on the arc continues to increase, the elements of the arch first folding in between the deionic sheets, and then breaking into pieces to form arcuate sections. The metal plates in the deionic sheet arc chamber contact the individual sheet members and the base points of the sheet sections over a large surface area, thereby effectively cooling them. The arc voltage on the series-connected arc portions is significantly higher than that of a continuous arc column of the same length due to the multiplication of cathode and anode falls. An increase in arc voltage increases the impedance of the circuit, resulting in a further decrease in arc current and thus in the arc column temperature. Due to the significant decrease in temperature, recombination of charge carriers in the arch portions begins and at the same time the thermal emission of the arched points decreases. The diameter of the arc parts decreases rapidly and more and more neutral gases and molecules are formed. During the electrode the electrical insulating capacity increases, the electric arc goes out and the circuit is broken.

Because of the extremely high destructive effect of the electric arc generated during shutdown and the surrounding hot gas mass, the most important requirement for the arc extinguisher is to provide the fastest and most efficient arc extinguishing possible.

In order to allow time between the formation of the arc and its extinction, the so-called "arc" is used. the arc time should be as short as possible, with proper construction to ensure rapid arc movement at the contacts and arc deflectors, as soon as possible the splitting of the originally connected arc column and the formation of serial arc portions between the deionic plates and finally the effective cooling of the arc portions.

The above objects are achieved by the known arc extinguishing mechanisms by providing magnetic blasting of the contact conductors and arc deflection fittings to the extent necessary for rapid arc movement, and by a sufficient selection of the shape and number of cut-outs of the deionic plates. A common feature of these solutions is that, in a given arrangement, the increase in the interruption capacity of the arc extinguisher is accomplished solely by increasing the number and size of the deionic sheets and by rapid movement of the sheets between the deionic sheets. Increasing the breaking capacity in this way sometimes results in a significant increase in volume and weight, thus ultimately leading to an increase in production costs. In addition, technical problems may arise due to the rapid rate of sexual movement between the deionic plates. Rapid arc movement is advantageous in that the thermal stress of the deionic sheets is reduced. However, the disadvantage is that the deion plates cannot cool the arc efficiently because the fast moving arc portions are very short between the plates. Due to the reduced cooling effect, the recombination of the charge carriers slows down and the insulating capacity of the electrode gap is more difficult! location. Arc parts that move too fast can get out of the deionic plates more easily and form a coherent column of arches, which also reduces the likelihood of arcing. The arc extinguisher shall be capable of interrupting any high current up to the maximum breaking capacity. It is a common disadvantage of known extinguishers that the extinction of the lower currents takes considerably longer, which causes rapid extinction of the extinguisher. This current range, which is smaller than the maximum interruption capacity, for which a significantly longer arc time can be measured, is called the critical current range.

It is an object of the present invention to provide an arc extinguishing chamber which is capable of interrupting substantially larger currents with unchanged dimensions but which also provides a short arcing time when interrupting smaller intermediate currents. It thus has no critical current range. The object is achieved by the arcuate chamber described in the introduction, according to the invention, that half of the arcuate chamber formed from the short and long deionic plates is stepped away from the stationary and movable contacts, such that the arcuate the re Ad deion plates are fitted with a choke made of insulating material farther away from the moving contacts. The ratio between long and short deionic sheets is between 1.25 ... 2 and the ratio between long and short deionic sheets is 0.5 ... 2. The throttle insert is also stepped and spaced according to the arc chamber.

The use of the extinguishing device according to the invention allows to increase the interruption of the extinguishing device within a given volume by 20 ... 70% compared to the known solutions. power in such a way that it provides an equally short arcing time even when intermediate intermediate currents are switched off.

Detailed description of the invention is based on the drawings.

Figure 1 is an axonometric view of a deionized sheet fire chamber used in an embodiment of the arch extinguisher of the present invention. Figure 2 is a side view of an embodiment of the arch extinguisher according to the invention.

The deionic sheet arch chamber shown in Figure 1 is made up of short and long deionic sheets 1 and 2 arranged at identical distances from one another.

One side of short and long deionic sheets 1 and 2

It is arranged along a straight contour line 187 905. On this side, the deionic plates 1 and 2 may also have a cutout in order to exert a more attractive force on the electric arc and to provide a better flow condition for the heated gas mass *; remtsenek. The deion plates 1 and 2 are secured by the insulating spacer 3 in the specified position. Since the deion plates 1 and 2 have different lengths, the starting chamber will have a stepped configuration on the opposite side.

Figure 2 illustrates the arch extinguisher of the present invention in the open position of the switch. The movable contact 6 facing the stationary contact 4 abuts the metal deflector assembly 7. In the closed position of the switch, the metallic contact of the movable contact 6 and the deflector assembly 7 is terminated and the movable contact 6, with the stationary contact 4, becomes metallic. The deionic sheet arc chamber of Fig. 1 is located in a plane perpendicular to the plane of the stationary and movable contacts 6 such that the ends of the plate located along the straight contour are on the side of the stationary and movable contacts 6. The contact plane of the stationary contact 4 and the movable contact 6 is perpendicular to the plane of the plates of the deionic sheet arc chamber. The distal short deion plate 1 of the deionic sheet extinguishing chamber is adjacent to and parallel to the arch deflector assembly 7, and the outermost long deion sheet 2 is adjacent to, and parallel to, the deflector assembly 5 made of metal contact 2.

The arcuate fittings 5, 7 surround the deionic sheet extinguishing chamber parallel to the length of the short deionic sheets 1. In the arching device according to the invention, FIG

1, a longitudinal choke member 8 is formed of a longitudinally extending insulating material 2 adjacent to the short deion board 1. Up to half of the 6 moving contacts. Figure 2 also shows the instantaneous position of movement of the electric arc in positions 1, II, III, IV / 1 and IV / 2 in chronological order of its formation. The latter two positions represent 4 portions of the arc that exist at the same time but are in different locations. The wavy lines indicate the arc column and the arrows show the direction of gas flow. When the switch is disengaged, the electric arc I at the separation of the stationary contact 4 and the movable contact 6 is moved by the loop force 4 towards the deion plate arc chamber, such that one foot of the arc at the contact 4 and the arc at the other moving on a moving contact. The speed of movement of the parts of the electric arc in position II is not the same. The arcuate point 5 mounted on the arcuate guide 5 moves faster, while the arcuate point moving on the movable contact 6 moves more slowly as the arcuate 5 moves along the continuous metal surface of the arcuate and from the vertex of and the gap between the arch deflector assembly 7 is difficult. The velocity of movement of some of the elements of the broken-down electric arc entering the deion plate arc chamber is not the same, namely, the movement of the arcs moving between the long deion plate 2 is faster, what-? between them, the gas mass heated by the electric arc can flow freely, while the movement of the arc parts between the short deionic plates 1 is slowed down by the throttle 8. The different flow and arc movement conditions divide the electric arc in position III into two distinct parts, namely the IV sections running between short deionic sheets 1, IV and 2 running between long deionic sheets. Furthermore, the choke 8 of insulating material is braked to such an extent that the bending point cooling of the individual parts is optimal. At the same time, the IV / 2 arch sections run faster between the revenge 2 deionic sheets and severely reduce the thermal stress caused by the arc current without the risk of arc re-ignition, thus using the deionic sheet arch structure according to the invention. In the case of IV / 2 shown in FIG. 2, we take advantage of the rapid arc cutting, while in the other group 5 of the IV portions in FIG. 2, the insulating material 8 is provided with optimum base point cooling.

Such a discontinuously varying throttle arrangement 1 and 2 provides a number of advantages over known arrangements of de3 sheet sheet extinguishers. On the one hand, the suppressed inoculum chamber section made with shorter deionic plates 1 eliminates the aforementioned disadvantage of the known solutions, namely that too fast arcing delays the partitioning, i.e. the arc extinction. On the other hand, the combined use of the quenched short tube 5 with open long sections of open deion plates 1 and 2 reduces the risk of critical currents. In fact, even at relatively low currents, the 0 arc is easily penetrated into the open extinguishing chamber portion containing the long leion plates. As the current to be interrupted increases, the force moving the arc becomes greater and the damped arc chamber part made with short deionic plates 1 becomes increasingly active. To interrupt smaller currents, less deion plate is sufficient while larger currents are interrupted. more and more efficiently-cooled deion plates are in operation, thereby providing the arc with a consistently short arcing time over a wide current range.

By adjusting the number, size, and throttle of the deionic sheet used in the inventive extinguishing device 2, it is ensured that the specific interrupting capacity of the extinguishing device, by volume or unit of weight, is much greater than that of known extinguishing devices.

Comparative interruption tests were carried out, on the one hand, with an arc extinguisher constructed according to the invention and, on the other, with switches equipped with an equal volume of known lengths of identical length deionic plates in arc circuits of 1-15 kA.

Your exam! The results showed that with the same volume of grafting chamber, the stepped deionic laryngeal grafting chamber used in the arching apparatus of the present invention increases the breaker capacity of the switch by 20-70% when using the funnel insert between long and short deionics 2 and 1. the length to length ratio is between 1.25 ... 2 and the ratio of long to short and 1 to deion plates is 0.5 ... 2.

In the tested current range, no critical current was encountered in the arc extinguishing device according to the invention, whereas in the parallel tested arc relay devices, the arc extinguishing time increased by 20-40% in the current range of 1-3 kA.

Claims (3)

1. Extinguishing device with electrical contacting means for opening a leading edge of a metal arcing member having a contact opening for a switch and a movable contact for the electrical switching device with a standing contact and a movable contact characterized in that one half of the arch of the short and long deion plate (1 and 2) extending away from the stationary and movable contacts (4 and 6) is stepped in such a way that the arc deflector (5) facing the stationary contact (4) long deionic plates (2) are disposed, furthermore, half of the short deionic plates (1), further away from the movable contact (6), are fitted with an insulating material choke (8). An arc extinguishing device according to claim 1, characterized in that the length ratio between the long deionic plates (2) and the short deionic plates (1) is between 1.25 ... 2, the long deionic plates (2) and the short deionic plates (1). and its ratio is between 0.5 ... 2. An arc extinguishing device according to claim 1 or 2, characterized in that the throttle insert (8) also has a stepped configuration and is spaced relative to the arc chamber.