RU2481676C1 - Thermal battery with device of protection against electromagnetic radiation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: thermal battery may be used in an unmanned aerial vehicle (UAV) with a long guarantee period and temperature of storage and operation of ±60°C. The proposed device comprises a thermal battery with an RC-filter installed in its body.

EFFECT: increased reliability of battery operation, since possibility of its unauthorised actuation because of high-frequency noise pickup is eliminated.

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Description

The invention relates to primary chemical current sources of one-time action, in particular to thermal batteries, which can be used to autonomously power on-board equipment of aircraft.

Known thermal battery, consisting of anode and cathode in contact with each other, during the combustion of which the chemical energy of the compositions is converted into electrical energy (application RU No. 94013374, publ. 05.15.1997, IPC F42C 11/00, H01M 6/20). The disadvantage of this invention is the insufficiently high reliability of the battery due to the possible unauthorized operation from exposure to a high-frequency electromagnetic field.

A device for igniting a gas generator is known, consisting of a housing, a powder igniter mixture housed in the housing, an igniter, an external electronic module located outside the gas generator housing, and an electromagnetic radiation protection device in the form of a capacitor connected to the ignitor located outside the gas generator housing and connected in parallel with an electronic module (application JP No. 2008284115, IPC F42B 3/12, dated 05.11.2008). The disadvantage of this device is the insufficiently high reliability of the device due to poor protection from exposure to high-frequency electromagnetic fields.

Closest to the proposed invention is a thermal battery, consisting of a metal housing hermetically connected to each other and a metal cover, with pyrotechnic and electrochemical mixtures placed inside the metal housing, as well as a thread of a pyrotechnic fuse in contact with the pyrotechnic mixture (I.A. Kedrinsky, V. E. Dmitrienko, I. I. Grudyanov. Lithium current sources. Moscow, Energoatomizdat, 1992, ISSN 5-283-00820-7, pp. 171-173). On the lid of the heat battery are the first and second terminals of the ignition circuit, as well as positive and negative down conductors. The disadvantage of this thermal battery is the insufficiently high reliability due to unauthorized operation from exposure to high-frequency electromagnetic fields.

The objective of the invention is to eliminate the above drawback and create a reliable thermal battery with a device for protection against electromagnetic radiation, which provides protection against unauthorized operation in a wide range of frequencies of electromagnetic interference.

The problem is solved due to the fact that a thermal battery with a device for protection against electromagnetic radiation consists of a metal case and a metal cover hermetically interconnected, while inside the metal case pyrotechnic and electrochemical mixtures are in contact and a pyrotechnic fuse, besides a pyrotechnic thread the igniter is in contact with the pyrotechnic mixture, while the first and second conclusions of the ignition circuit are installed on the metal cover, at least , one positive down conductor and one negative down conductor, the outer ends of the first and second terminals of the ignition circuit are connected to the battery charging command unit, a limiting resistor and capacitor are installed inside the metal case, while the inner end of the first terminal of the ignition circuit is connected to the first terminal of the capacitor and the first end pyrotechnic igniter filaments, the second end of the pyrotechnic igniter filament connected to the second terminal of the capacitor and to the first terminal of the limiting resistor, the second terminal ivayuschego resistor is connected to the inner end of the second seed output circuit.

The invention is illustrated by drawings, on which:

figure 1 is a top view of a thermal battery with a device for protection against electromagnetic radiation; figure 2 is a side view in section of a thermal battery with a device for protection against electromagnetic radiation.

In figure 1, 2 are indicated:

1 - the outer end of the first output of the ignition circuit;

2 - the outer end of the second output of the ignition circuit;

3 - cover;

4 - the first output of the limiting resistor;

5 - the second output of the limiting resistor;

6 - the first end of the thread pyrotechnic fuse;

7 - the second end of the thread pyrotechnic fuse;

8 - the inner end of the first output of the ignition circuit;

9 - the inner end of the second terminal of the ignition circuit;

10 - the first output of the capacitor;

11 - the second output of the capacitor;

12 - battery case;

13 - pyrotechnic mixture;

14 - negative current collector;

15 - positive down conductor;

16 - electrochemical mixture.

The proposed thermal battery with a device for protection against electromagnetic radiation, which is shown in FIGS. 1, 2, consists of a metal housing 12, in which a capacitor, a limiting resistor, a pyrotechnic igniter thread and a pyrotechnic 13 and electrochemical 16 mixture in contact with each other are placed. The metal housing 12 is closed by a metal cover 3, on which the first and second leads of the ignition circuit are installed, at least one positive collector and one negative collector, while the inner end of the first output of the ignition circuit 8 is connected to the first output of the capacitor 10 and to the first end of the pyrotechnic filament fuse 6, and the second terminal of the capacitor 11 is connected to the second end of the thread of the pyrotechnic fuse 7 and to the first terminal of the limiting resistor 4, the second terminal of the limiting resistor 5 is connected to the inner con the second terminal of the ignition circuit 9. The pyrotechnic igniter thread is in contact with the pyrotechnic mixture 13. The outer end of the first 1 and the outer end of the second 2 terminals of the ignition circuit are connected to the battery charging cock unit. The negative collector 14 and the positive collector 15 are connected to consumers, for example, with an automation unit, an inertial control system, and a homing head.

The thermal battery is designed for short-term autonomous power supply of UAV on-board equipment and should be able to provide a shelf life of up to 15 years under rather severe operating conditions without deterioration in performance: temperature: ± 60 ° C, vibration, overload. When placing a UAV on a carrier, for example, on an aircraft, sea or land, the electromagnetic radiation of various radio electronic devices of the carrier can create interference in the circuits connected to the terminals of the ignition circuit of the UAV thermal battery. During the flight of the aircraft carrier (or the movement of land or sea carrier), there are pickups on the UAV electric circuits from the influence of the carrier’s electromagnetic fields and from the influence of the radar station, thus, during operation (before charging), thermal batteries are subjected to great mechanical stresses (shock, vibration) as well as exposure to electromagnetic radiation.

In the proposed device, the electrochemical and pyrotechnic mixtures are solid non-conductive materials. The electrochemical mixture may consist of LiCl-KCl, and the anode of the thermal battery may be made of a Li-Si alloy, which remains solid at the battery discharge temperature. The anode, cathode and electrochemical mixture (electrolyte) can be made in the form of tablets pressed to each other or connected in some other way (using a coupler, spring, etc.). The UAV cocking command unit can be located on the carrier or inside the UAV in the automation unit.

A pyrotechnic fuse driven by an electric pulse is used to charge the heat battery. Pyrotechnic fuse can be made in the form of a thread (wire with high resistivity), which is located inside the pyrotechnic mixture. When passing current, the thread heats up and sets the mixture on fire.

When using a thermal battery as a source of electric power for an unmanned aerial vehicle (UAV), it is necessary to ensure the safety (not charging) of its fuse under the influence of high-frequency electromagnetic fields during storage and operation. With large pickups, a current of sufficiently large magnitude close to the value of the tripping current can occur in the ignition circuit, and this can lead to unauthorized starting of the thermal battery.

To exclude unauthorized operation when using a thermal battery, under the influence of electromagnetic fields, as a rule, its ignition circuit is shielded, and an RC filter located in a separate shielded housing is introduced into this circuit.

In the proposed device, the filter, which does not allow high-frequency interference to the fuse, is placed in a sealed metal case of the thermal battery itself, this also reduces the dimensions and weight of the UAV due to the fact that there is no need to use an additional shielded case for the filter. At the same time, a limiting resistor of the thermal battery itself and a frameless capacitor can be used in the filter of the proposed device, which allows to increase the filter efficiency while reducing its dimensions. Placing the filter inside the shielding metal case of the battery eliminates interference not only on the external circuit of the igniter, but also on the circuit from the thread of the pyrotechnic igniter to the RC filter.

Consider the operation of a thermal battery with a device for protection against electromagnetic radiation on the example of the device shown in figures 1, 2.

During the flight of an aircraft carrier (or the movement of land or sea carrier), there are pickups on the UAV electric circuits, in particular on the ignition circuit of the heat battery, from the influence of the carrier’s electromagnetic fields and from the effects of the radar station. The low-pass filter filters out high-frequency interference, this eliminates the false signal to the thread of the pyrotechnic fuse and avoids unauthorized operation of the thermal battery.

The battery charging command unit supplies a voltage pulse to the outer ends of the first and second terminals of the ignition circuit, the pyrotechnic igniter thread is heated and ignites the pyrotechnic mixture, which melts the electrochemical mixture (or solid electrolyte). An electric voltage is generated at the anode and cathode, which is supplied to consumers (automation unit, homing head and others). The limiting resistor, in addition to the filter element, acts as a fuse, since when a long pulse is received and the terminals of the ignition circuit are shorted, it burns out and the circuit breaks, which reduces power consumption.

Thus, the proposed device eliminates unauthorized operation from high-frequency electromagnetic radiation and reduces the weight of the UAV. The proposed device can be used in UAVs with a long warranty period and storage and operating temperatures of ± 60 ° C, as well as with vibrations and linear accelerations.

The technical result is to increase the reliability of the thermal battery by introducing a filter into the ignition circuit and placing this filter in the battery case.

The presented drawings and description of the device allow, using the existing element base, to manufacture the device in an industrial way, which characterizes the invention as industrially applicable.

Claims (1)

A thermal battery with a device for protection against electromagnetic radiation, consisting of a metal case and a metal cover hermetically connected to each other, while pyrotechnic and electrochemical mixtures are in contact with each other and a pyrotechnic igniter thread, while the pyrotechnic igniter thread is in contact with the pyrotechnic mixture this on the metal cover installed the first and second conclusions of the ignition circuit, at least one positive down conductor and one negative a solid down conductor, characterized in that the outer ends of the first and second terminals of the ignition circuit are connected to the battery charging command unit, a limiting resistor and capacitor are installed inside the metal case, while the inner end of the first terminal of the ignition circuit is connected to the first terminal of the capacitor and to the first end of the pyrotechnic thread fuse, the second end of the pyrotechnic fuse is connected to the second terminal of the capacitor and to the first terminal of the limiting resistor, the second terminal of the limiting resistor with one with the inner end of the second terminal of the ignition circuit.

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