RU2091894C1 - Explosion-type release - Google Patents

Abstract

FIELD: electrical engineering; on-line and emergency disconnection of heavy-current electric circuits. SUBSTANCE: explosion-type release has destructible current conductor 1 with explosive material charge 2 placed inside and with side surfaces 3, 4, provided with suppressing slots 5, 6, 7, 8. Explosive material charge may be also made in the form of set of cylinders and two insulating plates may be arranged in a spaced relation to and in parallel with hollow destructible current conductor. EFFECT: improved reliability of electric circuit opening in normal and abnormal situations. 3 cl, 4 dwg

Description

 The invention relates to the field of electrical engineering and energy and can be used for operational and emergency shutdown of high-current electrical networks.

 Known explosive breaker [1] in which to disconnect the contacts and complete disconnection using an explosion of an explosive charge.

 The disadvantage of this circuit breaker is the low rated current. The rated current of such an apparatus is determined by the cross section of its destructible current lead, which is performed with a weakening groove. The cross section of this groove determines the rated current.

 Also known is our improved prototype switch [2], chosen by us for the prototype, containing a hollow destructible current lead with a transverse weakening groove, inside of which there is an explosive charge.

 The disadvantage of this switch is the low rated current, which is associated with the cross section of the weakening of the groove fields. In addition, the explosion of the explosive charge is accompanied by the release of explosion products that adversely affect the surrounding equipment, since they take out an arc of shutdown and close adjacent busbars.

 The main technical task of the proposed explosive circuit breaker is to increase the rated current by changing the cross section and the location of the attenuating grooves. Compared with the prototype, the rated current of the proposed circuit breaker is increased by 30%. In addition, the reliability of the operation is increased by supplying the circuit breaker with two insulating plates.

 This goal is achieved by the fact that in an explosive switch containing a hollow destructible current lead with a transverse attenuating groove, inside of which an explosive charge is located, according to the proposed solution, the destructible current lead is made flat with four attenuating grooves located at the side surfaces of the explosive charge and pairwise facing each other vertices to each other, and the distances from the vertices of the attenuating grooves of each pair to the lateral surface of the charge are different, and the attenuating ditches and having the smallest and largest distance, are arranged crosswise.

 It is advisable to charge the explosive in the form of a series of cylinders.

 In addition, it is advisable to make an explosive switch with two insulating plates that are parallel to the hollow destructive current lead with a gap and are fastened together.

 In FIG. 1 shows the design of the explosive switch in the initial position; figure 2 after operation; figure 3 explosive switch, in which the explosive charge is made in the form of cylinders, and it is equipped with two insulating plates; in FIG. 4 it is after triggering.

 The explosive switch (Fig. 1) consists of a destructible current lead 1, inside which a charge of explosive 2 with side surfaces 3 and 4 is placed and which is made with attenuating grooves of 5.6 and 7.8.

 Figure 2 shows the same circuit breaker after operation.

 In the explosive disconnector (figure 3), the explosive charge is made of cylinders 9, and parallel to the hollow destructible current lead with a gap of 10, 11 there are two insulating plates 12 and 13, fastened together by bolts 14 and 15.

 In FIG. 4 this circuit breaker is shown after tripping.

 Explosive breaker operates as follows (Fig. 1, 2 and 3). In the initial state, current flows through the explosive disconnector. When there is a need for shutdown, explosive 2 is undermined. The destruction of the current lead 1 occurs at the smallest distances of the grooves 6, 7, and the grooves 5, 8 do not collapse (Fig. 3) and parts of the destroyed current lead diverge to the sides, forming a gap and breaking the electric circuit.

 Explosion products and metal particles (Fig. 4), formed during the destruction of the destructible current lead, stop at the insulating plates 12, 13, which also fixes the detonated switch in the initial position after operation. The electric arc that occurs during shutdown goes out in the products of the explosion, the circuit is switched off.

Claims (3)

 1. An explosive switch containing a hollow destructible current lead with a transverse weakening groove, inside of which there is an explosive charge (EX), characterized in that the hollow destructible current lead is made flat with four weakening grooves located at the side surfaces of the explosive charge and facing each other in pairs vertices, and the distance from the vertices of the attenuating grooves of each pair to the lateral surface of the charge is made different, and the attenuating grooves having the smallest and largest distances are located enes criss-cross.  2. The disconnector according to claim 1, characterized in that the explosive charge is made in the form of a series of cylinders.  3. The disconnector according to claims 1 and 2, characterized in that it is equipped with two insulating plates that are parallel to the hollow destructible current lead with a gap and are fastened together.

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