RU2200931C2 - Electric ammunition fuze - Google Patents

Abstract

FIELD: ammunition, manufacture of electric ammunition fuzes. SUBSTANCE: electric ammunition fuze has body, primary ignition substance, electric igniter to ignite primary ignition substance, source of electric energy for initiation of electric igniter, pyrotechnic heater of source of electric energy. Heat-activated chemical source of electric energy with solid electrolyte based on aluminosilicate or aluminophosphate glass displaying high ionic conductivity and low coefficient of linear thermal expansion is used as source of electric energy. Technical result of invention lies in increased safety of storage and employment of electric ammunition fuzes, in prolonged time of their guaranteed storage and operational reliability, in expanded temperature range of their use, widened functional capabilities and application field, in expanded arsenal of electric ammunition fuzes. EFFECT: increased safety of storage and prolonged time of operational reliability. 4 cl, 2 dwg

Description

 The invention relates to the field of ammunition, namely to electric fuses of ammunition, and can be used in the manufacture of electric fuses of ammunition.

 Autonomous electric fuses of ammunition are widely known, containing a housing, a primary igniter, an electric igniter, usually in the form of an incandescent bridge, to ignite a primary igniter, and an electric current source for initiating an electric igniter, in which explosive (explosive) machines serve as a source of electric current [1]. The disadvantages of these known fuses-analogues are cumbersome, limited functionality and scope, lack of reliability and safety of use.

Autonomous electric ammunition fuses are known, comprising a housing, a primary igniter, an electric igniter, usually in the form of an incandescent bridge, to ignite a primary igniter, and an electric current source to initiate an electric igniter, which uses chemical sources of electric current (galvanic cells and batteries with insufficiently long duration guarantee storage). Of these, the closest in technical essence to the claimed invention is an electric munition fuse with a direct current source [2, 3]. However, this well-known prototype fuse has insufficient storage and use safety, shelf life, reliability, temperature range of use (in the best cases - up to plus 50-70 ^o C or inability to use at low temperatures, below minus 20 ^o C), functionality and scope.

 To transfer the initiating impulse from the primary igniter to the main explosive of the ammunition, if they are separated by a sufficiently large distance, use fire-conducting and detonating cords [1 p. 51]. The connection of the fire-conducting and detonating cords to the primary igniter is carried out through electric incendiary tubes (for single cords) or electric ignition cartridges (for bundles of cords). If it is necessary to conduct an explosion after a predetermined time interval, a fire-conducting or detonating cord is connected to the main explosive of the ammunition through a detonation relay. Numerous versions of electric igniters are known (with an incandescent bridge - they are used most often, with an exploding incandescent bridge, with a conductive ignition composition, spark), detonation relays, as well as fire-conducting and detonating cords, electric tubes and cartridges.

Known [4 p. 284] are high-temperature reserve thermally activated chemical sources of electric current (thermal chemical sources of electric current, that is, equipped with a thermo-activated pyrotechnic heater) containing a metal anode (calcium, magnesium, lithium), a cathode made of a strong oxidizing agent (for example, calcium chromate CaCrO ₄ ), which separates their thermally activated electrolyte based on salt melt (for example, a mixture of LiCl and KCl with a binder - kaolin or finely divided silica) and is equipped with thermally activated pyrotechnic heater (for example, based on a mixture of zirconium and barium chromate, which upon combustion forms an insulating ceramic mass). The current collector is made of a relatively inert metal (usually iron or nickel). For example, a redox system is often used: Ca / LiCl, KCl - CaСrO ₄ / Fe, or Ca - CaCO _{4 for} short. Before melting (i.e., before thermal activation), the electrolyte is a solid. It conducts current only in the molten state, which requires its heating to several hundred degrees (more than 400 ^o C). The pyrotechnic heater for thermally activating (melting) the electrolyte is activated by means of a flame, electric or mechanical fuse (shock capsule). Thermal batteries are used to provide emergency start-up of engines of military aircraft and ground vehicles in cold weather (4 p. 298), but they are not technologically advanced to manufacture, have a high reject rate, and do not have sufficient reliability and shock resistance for use in munition fuses.

 A variety of thermal standby sources of electric current are miniature sources [5, 6], in which cathode and anode compositions contain pyrotechnic components in addition to electrolyte salts. From the ignition pulse, the anode and cathode compositions ignite, as a result of which the electrolyte salts melt, fill the pores of the separator plate separating them (from asbestos), and the potential difference increases on the current leads. Miniature thermal chemical sources of electric current have smaller dimensions (10-15 times) and weight (using cardboard instead of metal), compared with conventional thermal chemical sources of electric current, and therefore have a higher specific power (3-6 times ) However, they have much lower strength, impact resistance, reliability and scope.

Known high-temperature thermally activated chemical current sources containing a metal anode (calcium, magnesium, lithium), a cathode of a strong oxidizing agent (sulfur, selenium or tellurium mixed with graphite or coal) and a thermally activated electrolyte separating them (solid glass-based electrolyte) [7 ]. At ordinary temperatures, a solid electrolyte based on glass practically does not conduct electric current. But when such a current source is moved to a heated medium and heated to several hundred degrees (300-600 ^° C), a glass solid electrolyte becomes able to pass an electric current (cationic conductivity), as a result of which an operating voltage is applied to the down conductors. Such sources are high-tech in production, have standard technical parameters, and have high specific characteristics. However, they can only be used at a sufficiently high ambient temperature (300-600 ^o C), and after their slow heating and, probably, therefore, there is no information about their use complete with heaters-activators or use in electric fuses.

 Recently, we proposed [8] a thermal chemical source of electric current containing anodic and cathodic masses, separating them with a thermally activated electrolyte and equipped with a pyrotechnic heater for thermal activation, characterized in that it contains a solid electrolyte as a thermally activated electrolyte (for example, based on aluminosilicate glass or aluminophosphate glass ), which has a high ionic conductivity and a low coefficient of linear thermal expansion. Such a current source is characterized by high mechanical strength, resistance to shock and temperature loads. We suggest using it in the claimed invention.

 The technical result of the invention is to increase the safety of storage and use of electric fuses of ammunition, increase the period of their guaranteed storage and reliability, expand the temperature range of their use, expand the functionality and scope in comparison with the prototype. In addition, the technical result is also the expansion of the arsenal of electric ammunition fuses.

 The technical result is achieved in that the electric munition fuse, comprising a housing, a primary igniter, an electric igniter for igniting the primary igniter and an electric current source for initiating an electric igniter, according to the invention further comprises a pyrotechnic heater of an electric current source, and contains a thermally activated chemical source of electric current solid electrolyte current source (e.g. aluminum based Mosilicate or aluminophosphate glass), which has high ionic conductivity and a low coefficient of linear thermal expansion.

 In addition, the technical result is achieved by the fact that according to the invention, if necessary, the electric circuit of the electric igniter for igniting the primary igniter contains a shock or electrically controlled type switch, the primary igniter is connected to the main explosive charge of the munition with an ignition or detonating cord for transmitting the initiating pulse to the main explosive ammunition charge, ignition or detonating cord connected to the main explosive munition charge through the detonation relay to delay a predetermined time interval for the transfer of the initiating pulse from the primary igniter to the main explosive charge of the ammunition, the pyrotechnic heater of the electric current source is equipped with an igniter-switch, driven by a coded radio signal or electric signal, and / or connected to the igniter a cord through which an initiating pulse is triggered to ignite the heater of the electric current source.

 Providing an electric fuse with a heater of an electric current source and a thermally activated chemical current source with a solid electrolyte, for example, based on aluminosilicate or aluminophosphate glass, improves the storage and use of ammunition, increases their shelf life and reliability, extends the temperature range of their use compared to an electric fuse prototype. Such solid electrolytes are highly resistant to mechanical and thermal shock.

 Providing an electric fuse with a shock or electrically controlled type switch in the electric circuit of an electric igniter to ignite the primary igniter makes it possible to increase the timeliness of an ammunition explosion when it reaches the target object or the area of the target object.

 The supply of an electric fuse with an igniter or detonating cord for transmitting an initiating pulse from the primary igniter to the main explosive charge of the ammunition allows to increase safety and expand the scope of use of ammunition.

 The supply of an electric fuse with a detonation relay for delaying a predetermined time interval for the transfer of the initiating pulse from the primary igniter to the main explosive charge of the munition allows to increase efficiency and expand the scope of its use.

 The supply, in an electric fuse of ammunition, of a heater of an electric current source with an igniter-switch driven by an encoded radio signal or an electric signal, and / or the connection of this heater with an igniter cord, through which an initiating pulse is started to ignite this heater, allows to expand the scope of use of an electric fuse ammunition.

Comparison of the claimed electric munition fuse with the prototype allows us to establish that the claimed device is distinguished by the implementation of an electric current source, the presence of a pyrotechnic heater of an electric current source, and to conclude that the invention meets the criterion of "novelty",
In the study of other known solutions in the field of explosive engineering, signs identical to those distinguishing the claimed electric munition fuse from the prototype were not identified, and therefore the claimed device meets the criterion of "inventive step".

 The possibility of using the claimed invention in the manufacture of electric fuses of ammunition provides him with the criterion of "industrial applicability".

 The essence of the proposed technical solution is illustrated in figures 1 and 2.

The device (Fig. 1) comprises a housing 1, a primary igniter 2, an electric igniter 3 for igniting a primary igniter 2, an electric current source 4 and, according to the invention, contains a pyrotechnic heater 5 of an electric current source, and as a source of electric current 4 contains a thermally activated chemical current source with solid electrolyte (TEL) 6 based on aluminosilicate glass having a composition of 0.15Li ₂ O • 0.15Al ₂ O ₃ • 0.7SiO ₂ . A solid electrolyte (TEL) separates the anode mass (for example, lithium) from the cathode mass (for example, based on sulfur). The electrical conductivity of this TEL for lithium at 300 ^o C is 8.3 • 10 ^-5 Ohm ^-1 cm ^-1 ; the electronic component of electrical conductivity is about 10 ^-3 %, which is an indicator of a very small self-discharge of the current source and a long shelf life (more than 15 years); the average value of the coefficient of linear thermal expansion (KLTR) is 48 • 10 ⁷ K ^-1 . The range of operating temperatures of the proposed TEL is from 300 ^o C to 600 ^o C, which distinguishes it from the well-known thermal chemical current sources, where a higher temperature is required for the melting of electrolyte salts. The operating voltage of a single chemical current source (galvanic cell) with a glass TEL is at least 3 V.

 The device operates as follows. After the fuse is installed and brought into combat condition, the igniter composition of the heater 5 is ignited. Due to the heat generated during the combustion of the igniter composition 5, the temperature of the chemical current source 4 increases and it is thermally activated with a working electric voltage supplied to the electric igniter 3, which ignites the primary igniter 2 The combustion of the primary igniter 2 passes into an initial impulse transmitted to the main explosive charge of the ammunition, which is leads to an explosion of a munition.

 In those cases where the electric fuse and the main explosive charge of the ammunition are intended to hit the target or the target area (by a shell, missile warhead, bomb, torpedo, etc.), the electric circuit of an electric igniter 3 for igniting a primary igniter 2 contains a shock or electrically controlled switch 7 type (figure 2). In this case, the usual way to use an electric munition fuse is to pre-initiate a heater 5 (for example, 1-2 minutes before the explosion) to increase the potential difference between the cathode and anode of the electric current source 4 with the subsequent closure of the electrical contacts of the switch 7 at the moment the munition is reached with an electric fuse for the target object (impact type switch) or target area (electrically controlled type switch). The switch 7 shock or electrically controlled type can be made in its own case, and it can be separated from the body of an electric fuse for separate storage.

 The well-known [8] introduction to the composition of the pyrotechnic heater 5 "chemical heating pad" - an additional slow-acting chemical heater (not shown) can increase the preservation of the required operating temperature of the current source from several minutes to several hours.

 In those cases when the main explosive charge of the ammunition must be located at a distance from the primary igniter, an ignition or detonating cord (not shown) is used to connect them, through which the initiating pulse is transmitted from the primary igniter 2 to the main explosive charge of the ammunition.

 If several main blasting charges are used, then each of them is connected with an ignition or detonation cord to the primary igniter 2. If necessary, carry out the blasting of these main blasting charges not simultaneously, but in a certain sequence, the ignition or detonation cord is connected to the main explosive charge of the munition through a detonation relay (not shown) for delaying a predetermined time interval for the transmission of the initiating pulse from the primary igniter agent 2 to the main explosive charge of the warhead. This kind of device can be used, in particular, in diversionary work, in cases where it is necessary to achieve the greatest effect when undermining an enemy’s object, for example, first by undermining the charge of the first ammunition to bring down the entrance to the tunnel and only then in the plugged tunnel to carry out subsequent detonation of charges of other ammunition .

 In cases where the electric munition fuse should fire upon the command of the operator (person or device) and at a distance from the operator, the pyrotechnic heater of the electric current source is equipped with an igniter-switch (not shown) driven by a coded radio signal or electric signal, and / or connected to the ignition cord (primary ignition cord, not shown) through which the initiating pulse is started to ignite the heater 5 of the electric current source 4. Pr This kind of device with an igniter, a switch may be used, in particular in aircraft projectiles with prolonged presence in flight to initiate electric igniter 4, for example, 1-2 minutes before the approach to the goal. Moreover, the electrical signal to turn on the igniter-switch can be obtained from the on-board computing device, for example, from a cruise missile - an ammunition carrier that calculates the distance and time of movement to the target. The inclusion of an igniter-switch with a coded radio signal for space communication can be used to eliminate their own dangerous or secret space objects (having exhausted a working resource, failed, descended from a given trajectory, captured by an enemy spaceship, etc.). When storing an electric fuse in a warehouse, such an igniter-switch (with a device for receiving an encoded radio signal or an electric signal) can be separated from the body of an electric fuse to ensure storage safety. A type of device with a primary ignition cord can be used in diversionary work, for example, to mine the main charge of ammunition with an electric fuse of special objects when the troops retreat, followed by undermining the main charge of the ammunition (at the right time after the enemy troops capture a mined special object) from a remote distance by supplying an initiating pulse through a masked primary igniter cord to the igniter, the jelly 5 (to activate the electric current source 4 with the subsequent initiation of the electric igniter 3 of the electric fuse) and then from the electric igniter 3 to the main explosive charge of the ammunition.

Compared with the fuse prototype of the claimed device is characterized by a much greater safety of storage and use. At ambient temperatures less than 150 ^o With spontaneous initiation of an electric igniter with the subsequent operation of an electric fuse is practically excluded. The same applies to unexploded ordnance. Even used unexploded ordnance, and without separating them from the fuse, can be transported without unnecessary precautions. This is because the claimed device does not use substances that are easily detonating from impacts, such as explosive mercury, dynamite, etc. And even an unauthorized shorting of the electric circuit of an electric igniter 3 by a switch 7 (for example, from an accidental strike) cannot lead to an explosion of ammunition, until until a pyrotechnic heater 5 ignites from a high temperature followed by a supply of working electric voltage from a chemical current source to an electric igniter 3. Compared with the prototype The claimed electric munition fuse is characterized by a much longer shelf life (more than 15 years, and in the prototype up to 5-7 years in the best cases). To increase the reliability and safety of storage in warehouses, the switch 7, the igniter-switch and the pyrotechnic heater 5 of the chemical current source can be separated from the case of an electric munition fuse. In addition, compared with the fuse of the prototype of the claimed device can be used in a wider temperature range of the environment (from minus 60 ^o C to plus 120-150 ^o C depending on the nature of the structural materials of the radio, and in the prototype from minus 20 ^o C and only up to plus 70 ^o C at best, due to failure of a chemical source of electric current due to overheating), which expands its functionality and scope.

Sources of information
1. Lurie A. I. Electric explosion of charges. // M .: Nedra, 1973, p. 59.

 2. Copyright certificate of the Russian Federation 1820182, F 42 C 19/08, 1993, BI 21. - Prototype.

 3. Copyright certificate of the Russian Federation 1820184, F 42 C 19/12, 1993, BI 21.

 4. Crompton T. Primary current sources. // M .: World. 1986, p. 284.

 5. RF patent 2018782, F 42 C 11/00, H 01 M 6/20, 1994, BI 16.

6. RF patent 2018783, F 42 С 11/00, Н 01 М 6/20, 1994, BI 16
7. UK patent 1344069, CL H 1 B, 1973.

Claims (5)

 1. An electric fuse of ammunition, comprising a housing, a primary igniter, an electric igniter for igniting a primary igniter, and an electric current source for initiating an electric igniter, characterized in that it further comprises a pyrotechnic heater of an electric current source, and comprises a thermally activated chemical source as an electric current source current with solid electrolyte (for example, based on aluminosilicate or aluminophosphate glass ) Having a high ionic conductivity and low coefficient of linear thermal expansion.  2. The fuse according to claim 1, characterized in that the electric circuit of the electric igniter for igniting the primary igniter contains a shock or electrically controlled type switch.  3. The fuse according to claim 1, characterized in that its primary igniter is connected to the main explosive charge of the munition with an ignition or detonating cord for transmitting an initiating pulse to the main explosive charge of the munition.  4. The fuse according to claim 3, characterized in that the igniter or detonating cord is connected to the main explosive charge of the ammunition through the detonation relay to delay for a predetermined time interval the transmission of the initiating pulse from the primary igniter to the main explosive charge of the ammunition.  5. The fuse according to claim 1, characterized in that the pyrotechnic heater of the electric current source is equipped with an igniter-switch driven by an encoded radio signal or an electric signal, and / or connected to an ignition cord through which an initiating pulse is started to ignite the heater of the electric current source .

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