UA78178C2 - Explosion-absorbing coating - Google Patents

Abstract

Explosion-absorbing coating relates to methods for neutralization of charges of explosive substances. Increase of reliability of coating is provided due to direct contact of piroelectric and detonation wave through sectioning coating and placement of electrodes on sections normally to sublayer.

Description

Description of the invention

The useful model refers to means of disposal of charges of explosive substances and can be used in 2 destruction of ammunition.

Known devices for localization of explosion products (1, 2). Such devices contain a damping material, such as fiberglass, placed between the shells.

In these devices, part of the explosion energy is absorbed by the damping material, but it is not diverted to a significant distance from the protective shell. Therefore, the reliability of known devices is low. 70 The closest to the proposed one is a protective device for localization of an explosion, which contains a cylindrical fiberglass shell and a coaxially placed metal shell inside it with direct contact, as well as a metal shell placed outside the fiberglass shell with direct contact with it, and the fiberglass shell is made of pyroelectric material , and a varistor |Z) is connected between the metal shells with a high-voltage wire.

This device is more reliable, because it allows reducing the load on the protective shell by diverting a certain part of the destructive energy of the explosion to a safe distance from the protective shell. Here, part of the thermal and elastic energy of the explosion is converted into electrical energy by the pyroelectric material of the protective shell, with the subsequent direction of this energy along the high-voltage wire into the varistor, where the electrical energy is utilized as heat.

The reliability of this protective device is insufficient, because there is no direct contact of the pyroelectric with the detonation wave. This contact is prevented by an internal electrode in the form of a metal shell placed inside a fiberglass shell. In addition, the internal electrode is not protected from the effects of explosion products, which further reduces the reliability of the device.

The basis of a useful model is the task of creating an explosion-absorbing coating, in which direct contact of the pyroelectric with the detonation wave and protection of the electrodes from the products of the explosion is ensured by sectioning the coating and placing the electrodes on the sections parallel to the direction of action of the products of the explosion.

The technical result of the introduction of a useful model is to increase the reliability of the explosion-absorbing coating due to the increase in the share of the explosion energy that is converted by the pyroelectric, as well as due to greater protection of the electrodes. co

The task is solved due to the fact that the coating is made in the form of sections, and the electrodes are located on the sections perpendicular to the substrate.

The introduced features make it possible to eliminate the obstacle (electrode) in the path of the detonation wave to the pyroelectric material and, thanks to this, to increase the effect of the explosion on the pyroelectric converter (and therefore to increase the proportion of the energy of the explosion that is utilized). At the same time, the isolation of the electrodes from external influences has also been improved.

The general appearance of the proposed explosion-absorbing coating is shown in Fig. -

The coating contains a pyroelectric material applied to the substrate 1 in the form of elements 2 with rigidly fixed electrodes 3, between which a varistor 5 is connected by a high-voltage wire 4. The main direction of action of the explosion 6 is indicated by an arrow in the figure. Electrodes C are applied to each element 2 from two opposite sides; "FC they are made of nickel and are located perpendicular to the substrate 71. Elements 2 are made of ferroceramics based on barium titanate and are glued together with conductive glue so that they are electrically connected in series. The sections fastened together (pyroelements 2) are glued to the substrate 1 with a dielectric

And" glue; as a result, the C electrodes are isolated from each other. Thus, the coating consists of sections in the form of pyroelectric elements 2, on which electrodes C are placed parallel to the main direction of action of the explosion 6.

The blast-absorbing coating functions as follows. The detonation wave that occurs during the explosion acts in the direction 6 49 and pyroelectric elements 2. Electric charges and electromotive force arise on the electrodes C, the magnitude of which is proportional to the rate of increase in pressure and temperature. Since electrodes C do not interfere with the action of the detonation

Ge | waves on the pyroelectric material of sections 2 (the pulse of pressure and temperature does not stretch in time), a significant part of the energy of the explosion is converted into electrical energy. This energy is sent along the high-voltage wire 4 to the varistor 5, where it is used as heat. -and 20 Thus, the placement of the electrodes of the pyroelements perpendicular to the substrate 1 compared to the placement of the electrodes parallel to the substrate (as in the prototype) leads to an increase. (according to the data of the experiments - not less than twice) the share of the energy of the explosion, which is transformed by pyroelements into electrical energy and then disposed of. Accordingly, the reliability of the blast-absorbing coating increases.

At the same time, electrodes made of pyroelements are more protected from explosion products (than in the prototype), which additionally increases the reliability of the explosion-absorbing coating.

GF) Sources of information: 1. KO 2130563, cl. Е17С1/00, г4205/00, 1999. by 2. VI 2168107, cl. Е17С1/00, г4205/00, 2001. 3. ША 2004031533, cl. E4205/05, 2005. - Prototype

Claims (1)

The formula of the invention An explosive-absorbing coating containing a pyroelectric material applied to the substrate with rigidly fixed electrodes, between which a varistor is connected by a high-voltage wire, which differs in that that the coating is made in the form of sections, and the electrodes are located on the sections perpendicular to the substrate. c (Fo) (ee) - "- (ee) - With c 1" -I (ee) shk -0.750 (Che) (F) ko 60 65