RU2647134C1 - Bullet for small arms cartridges - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to the ammunition of small arms, in particular to the designs of bullets. Bullet contains a bimetallic shell and a hard steel core. Generator of electrical impulses is installed in the cavity of the tail part of the bullet. It includes a piezoelectric cell, capacitors, diodes and a key. Piezoelectric element is connected to the capacitor connection point by one terminal. Second terminal of the piezoelement is connected through a diode to the tail part of the bimetallic shell, and also through a diode and a mechanical key to the main part of the bimetallic shell. This shell is separated by a dielectric from the tail part of the bimetallic shell.

EFFECT: increase in the effectiveness of the bullet damage due to an additional electric shock effect on the biological object.

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Description

The invention relates to ammunition, in particular to designs of small arms cartridges for various purposes. The invention relates to ammunition of small arms, in particular to the construction of bullets.

A technical solution is known for the bullet for cartridges of small arms (US Pat. No. 2584048, publ. 05/20/2016, prototype). A bullet for small arms containing a bimetallic shell, a hard alloy core, characterized in that an additional pulse generator is installed in the cavity of the tail of the bullet, including: a piezoelectric element, a capacitor, diodes and a key, a piezoelectric element connected via a diode to the tail of the bimetal shell and the second terminal - to the capacitor, the second terminal of which is connected through a diode and a mechanical key to the main part of the bimetallic shell, which is separated by a dielectric from the tail part STI bimetallic shell.

The design of this bullet creates a shock effect when it enters a biological object. This technical solution uses only half the energy of the piezoelectric element.

The task of the invention is to eliminate the noted drawbacks, namely increasing the efficiency of the electric charge of small arms for shock effects on a biological object.

The problem is solved due to the fact that in the known pool containing a bimetallic shell, the core is made of hard alloy, in the cavity of the tail of which is installed an electric pulse generator, including: a piezoelectric element, capacitor, diodes and a mechanical key, with one output the piezoelectric element is connected through the diode to the tail part of the bimetallic shell, and the second terminal to the capacitor (C1), the second terminal of which is connected through a diode and a mechanical key to the main part of the bimetallic shell, which is separated by a dielectric ohm from the tail of the bimetallic shell, a second capacitor (C2) is additionally included, one terminal of which is connected to terminal C1 and the piezoelectric element, and the second terminal of C2 is connected to the terminal of the tail of the bimetallic shell and the anode of the diode (D2), the cathode of which is connected to the point connecting the diode D1 to the piezoelectric terminal.

An additional series connection of the second capacitor can increase the energy storage in the capacitors and the efficiency of their discharge.

The second capacitor (C2) is turned on, with one output to terminal C1 and the piezoelectric element Q terminal, and the second terminal C2 is connected to terminal “b” of the tail of the bimetallic shell and the diode anode (D2), the cathode of which is connected to the junction point of the diode D1 with the piezoelectric terminal.

This technical solution allows to increase the energy storage of capacitors and their discharge voltage.

The claimed combination of distinctive features allows us to consider this technical solution satisfying the criterion of "inventive step".

In FIG. 1 shows a general view of a bullet; FIG. 2 shows an electrical diagram of an electric pulse generator located in the tail of a bullet.

In FIG. 1, the following designations are adopted: the main bimetallic shell of the bullet is 1, the dielectric is 2, which separates electrically the main part of the bimetallic shell (1) from the tail, the core is 3, the points: “a” and “b” of the terminals of the electrical pulse generator to the main and the tail parts of the bimetallic shell (1).

In FIG. 2. the following designations are accepted: a mechanical key - k, diodes - D1, D2, capacitors - C1, C2, a piezoelectric element - Q. One of the terminals of the piezoelectric element (Q) is connected to the common connection point of the capacitors C1 and C2, and the second terminal of the piezoelectric element (Q ) is connected to the anode of the diode D1 and the cathode of the diode (D2), the anode of which is connected to the second terminal of the capacitor (C2) and the terminal “b” of fastening the input of the electric pulse generator to the tail of the bimetallic shell (1), and through the diode D1 is connected to the capacitor C1 and the terminal of the mechanical key k, the output of which is connected to the main th part of the bimetallic shell (1) of the bullet (point "a").

; где приняты следующие обозначения: E - электрическое поле внутри пластины [B], h - толщина пластины [м], P_x - поляризация пластины

, d₁₁ - постоянная, называемая электрическим модулем, ε - диэлектрическая проницаемость кварца,

- механическое напряжение? действующее параллельно оси x, [Па], m - масса, действующая на пластину кварца, [кг], g - ускорение силы тяжести, [m/c²]. Конденсатор (C1) заряжается до напряжения ϕ⁺. По окончании ускорения пули механический ключ (k) соединяет вывод конденсатора (C1) с основной частью биметаллической оболочки (1), а конденсатор (C2) через диод D2 заряжается до напряжения (ϕ^-). За время полета пули до цели конденсаторы (C1 и C2) получают дополнительный заряд с поверхности биметаллической оболочки, возникающий за счет ее трения о воздух.The device operates as follows. When fired, a bullet under the influence of powder gases acquires acceleration - (g), while the core (3) exerts mechanical influence by pressure on the piezoelectric element (Q) and mechanical key (k), disconnects the capacitor output (C1) from the main part of the bimetallic shell of the bullet (1) ) The piezoelectric element undergoes deformation and generates a stress determined from the equality

; where the following notation is used: E is the electric field inside the plate [B], h is the thickness of the plate [m], P _x is the polarization of the plate

, d ₁₁ is a constant called an electric module, ε is the dielectric constant of quartz,

- mechanical stress? acting parallel to the x axis, [Pa], m is the mass acting on the quartz plate, [kg], g is the acceleration of gravity, [m / c ² ]. Capacitor (C1) is charged to a voltage of φ ^+. At the end of the acceleration of the bullet, a mechanical key (k) connects the output of the capacitor (C1) to the main part of the bimetallic shell (1), and the capacitor (C2) is charged through the diode D2 to the voltage (ϕ ^- ). During the flight of the bullet to the target, the capacitors (C1 and C2) receive an additional charge from the surface of the bimetallic shell arising from its friction against the air.

When a bullet meets an obstacle, the piezoelectric element (Q) undergoes deformation, generates tension? recharging capacitors (C1 and C2). Between the connection points “a” and “b” of the capacitor terminals (C1 and C2)? located in the main and tail parts of the bimetallic shell of the bullet, a potential difference is created higher compared to the prototype, which causes the discharge of capacitors (C1 and C2) and the shock effect that paralyzes motor functions when the bullet enters the body of the animal.

The proposed technical solution can be implemented industrially. Bullets can be used in commercial hunting, increasing hunting efficiency and reducing the number of wounded animals.

Claims (1)

A bullet for small arms containing a bimetallic shell, a core made of hard alloy, an electric pulse generator is installed in the cavity of the tail of the bullet, including a piezoelectric element, a capacitor, diodes, a key and a piezoelectric element, which is connected through a diode to the tail of the bimetallic shell with a single terminal and a second terminal - to a capacitor, the second terminal of which is connected through a diode and a mechanical key to the main part of the bimetallic shell, which is separated by a dielectric from the tail of the bimetallic shell and, characterized in that the second capacitor C2 is additionally included, one terminal of which is connected to the terminal C1 and to the piezoelectric element terminal, and the second terminal C2 is connected to the terminal of the rear part of the bimetallic shell and the anode of the diode D2, the cathode of which is connected to the connection point of the diode D1 with the terminal piezoelectric element.

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