RU90185U1 - MULTIPLE SHOOTING MODULE - Google Patents

Abstract

A multi-barrel firing module containing a block of electrical contacts and a block of trunks carrying functional products connected by tension locks, equipped with a locking unit made in the form of a holder with axially distributed shafts and current leads of the contact block with sockets for electrocapsules, closed by locking bushings mounted with the possibility of longitudinal movement to the bottom the flange of the missile products before the abutment of the annular protrusion, in which there is a nozzle of a fire-transfer confuser hole, characterized by that the body of the electrocapsules is made in the form of a thin-walled cup, the free volume of which from the open end above the igniter charge is combined with the fire-transfer cofuser hole of the locking sleeve and is capable of radial deformation for obturation of the generated gases, while the central electrodes of each electrocapsule interacting with the current leads of the contact block by means of an incandescent bridge placed inside an igniter charge is electrically connected to its body through a current the leading shell of the dielectric block carrying the central electrode.

Description

The proposed utility model relates to the field of multi-barrel weapons technology with external electric control of the shutter and can be used in various samples of small arms, in particular, artillery or fire-extinguishing aerosol generators for throwing generators into a fire source.

The level of development of this technical field is characterized by the Osa pistol complex, which contains a cartridge chamber for four cartridges with an electrocapsule, a spring cartridge lock and a handle pivotally connected to it, in which the firing control unit is located, which includes a contact unit, an electric power supply, and a contact switching mechanism ( see .. The Weapons of Self-Defense magazine, 2000, No. 1, p. 44).

To fire a shot, you must press the shutter button, from which the force is transmitted to the button of the electric current source and the contact switch rod. At the end of the course of the release button, the circuit of an electric igniter of one of the cartridges closes, the current source is triggered - a shot is fired.

The disadvantage of the described construction is that for firing a shot, the next cartridge firing is carried out by the mechanism of moving the contact switch, which reduces the reliability of the complex, as well as the use of a special cartridge with an electrocapsule, which excludes the possibility of using cartridges with a shock capsule, significantly limiting the product’s performance .

The noted drawbacks are eliminated in the multi-barrel firing module according to patent RU 2310805, F41А 7/08, 21/06, 2007 with remote control firing by standard artillery cartridges having a percussion capsule, which is selected as the closest in technical essence and most of the matching features analogue proposed.

To increase reliability and improve performance in a multi-barrel firing module that contains a barrel unit for loading with cartridges, a barrel channel locking unit, a terminal block for transmitting an electrical signal to an electric capsule, fire control is carried out remotely when the standard capsule capsule is energized by the energy of the powder gases generated when the electronic capsule is triggered coaxially mounted in the contact block.

The barrel channel locking assembly is made in the form of a cage with a nut having sockets for equipping electric capsules mounted behind each cartridge, and in the cage between the electric capsule and the cartridge, locking sleeves that have a calibrated hole (nozzle) for guiding the powder gases are mounted in the bolt with the possibility of longitudinal movement from the triggered electrocapsule to the capsule of the standard cartridge.

Dyuza has a conical hole, a large section adjacent to the nest of the locking clip, forming a confuser.

An annular protrusion is made at the front end of the locking sleeve around the calibrated through hole to adjoin the capsule of the artillery cartridge, thereby providing direct transmission of the mechanical effect of the gaseous working fluid generated when the electrocapsule is triggered.

The barrel block in the breech is combined with the adjacent contact block by means of three tension locks.

The muzzle of the barrel block is covered with a protective foil plate, through which firing is being carried out, which is replaced with subsequent equipment.

A disadvantage of the well-known multi-barrel firing module is the unsatisfactory functional reliability, which is determined by the structural design of the standard electrocapsules and their spatial relationship with the nests of the locking sleeve along the landing landing with a guaranteed clearance required for manual equipment.

When firing, part of the generated gaseous products of combustion of the igniter charge of the electrocapsule breaks through the asymmetric annular gap back into the shutter, reducing the calculated working pressure on the capsule of the artillery cartridge.

In addition, an unbalanced force is generated to move the locking sleeve when its annular protrusion with a nozzle does not adjoin the capsule of the artillery cartridge and most of the working fluid fills the volume of the barrel, rather than acting mechanically on the cartridge capsule.

As a result, there may be cases of failure during shooting, since the cartridge capsules may not work due to insufficient mechanical influence of the developed pressure in the shutter during dispersion.

The technical problem, which the real utility model is aimed at, is to increase the functional reliability of the operation of each barrel of the firing module and, ultimately, the effectiveness of its combat use.

The required technical result is achieved by the fact that in the well-known multi-barrel firing module, containing a block of electrical contacts and a block of trunks carrying functional products connected by tension locks, equipped with a locking unit, made in the form of a clip with axially distributed shafts and current leads of the contact block nests for electrocaps, closed with locking bushings mounted with the possibility of longitudinal movement to the bottom flange of the missile products until the annular projection in which there is the nozzle of the fire-transfer confuser hole, according to the authors' suggestion, the body of the electrocapsule is made in the form of a thin-walled cup, the free volume of which from the side of the open end above the ignition charge is combined with the fire-transfer cofuser hole of the shutter sleeve and is capable of radial deformation for obturation of generated gases, while interacting with current leads of the contact block, the central electrodes of each electrocapsule by means of a filament bridge located inside the igniter a charge, electrically connected to its body through a current-carrying shell of a dielectric block carrying a central electrode.

Distinctive features ensured the reliability of firing functional products (artillery cartridges, fire extinguishing aerosol generators) from a multi-barrel module, according to the program, in one gulp or a burst, with strict adherence to the sequence of actions of the actuating elements and the operating schedule of the device as a whole, which increases the reliability and effectiveness of its intended use.

The execution of the shell of the electrocapsules in the form of a thin-walled glass with a free volume from the open end side above the igniter charge is intended for obturation of the generated gaseous products of combustion of its pyrotechnic composition.

This automatically occurs as a result of radial deformation of the body of the electrocapsule with increasing pressure in the confuser hole of the locking sleeve, which dynamically moves to the flange of the projectile until the annular projection adjoins its capsule, practically without loss of energy of the initiated pulse.

The combination of the free volume of the body of each electrocapsule with the fire-transfer confuser hole of the locking sleeve creates a pressure drop: a decrease in front of the nozzle (where gas flow is accelerated) and an increase in the free volume of the thin-walled body of the electronic capsule, which is radially deformed, blocking the clearance of the electronic capsule's landing gear in the socket of the locking sleeve.

The clamping force of the locking sleeve to the flange of the projectile is several times higher than the reaction force on the annular protrusion (proportional to the ratio of the areas of their cross section), which ensures the formation of a sharply directed central jet of gaseous products of combustion, mechanically acting on the capsule of the artillery cartridge or generator.

Under the action of high pressure (260-300 kg / cm ² ), the product capsule inevitably triggers, igniting the propellant powder charge in the shell of the artillery cartridge or the functional charge of the fire extinguishing aerosol generator.

The coaxial arrangement and contact interaction of the central electrode of the electrocapsules with the electrical contacts of the current supply of each barrel of the module ensures the transmission of a control pulse from the connecting switch to a given electrocapsule, closing the control circuit.

In this case, the convective heat generated by the incandescence of the electric bridge ignites the pyrotechnic composition of the igniter charge, initiating the firing of the shot.

The proposed multi-barrel firing module is a universal automatic small arms suitable for the use of various functional products in single and salvo fire mode, simple and reliable in operation without re-equipment.

Therefore, each essential sign is necessary, and their combination in a stable relationship is sufficient to achieve the novelty of quality, that is, the technical problem is solved not by the sum of the effects, but by a new super-effect of the sum of the signs.

The invention is illustrated by the drawing, which has a purely illustrative purpose and does not limit the scope of the claims of the claims. The drawing shows:

figure 1 is a General view of the proposed module;

figure 2 is a block of trunks;

in Fig.3-view A in Fig.2, the locking sleeve in longitudinal section;

figure 4 - electrocapsule;

figure 5 - also when shooting.

The multi-barrel firing module (Fig. 1) includes a drum unit 1 of trunks 2, combined with a hinged unit 3 of electrical contacts 4 using three tension locks 5 mounted on a cylindrical casing 6, which at the end is adjacent to the unit 1 of the trunks 2, thereby shaping the module as functional product.

The breech of the trunks 2 is pressed into the landing holes of the rear base 7 of the block 1, on which a clip 8 is equipped with a longitudinally movable holder 8, equipped with sockets 9 (Fig. 3) under the electric capsule 10. The sockets 9 of the holder 8 are aligned with the shutter chambers 11, where the breech parts of the respective trunks are installed 2 blocks 1.

The muzzle part of the trunks 2 rests on the front base 12 (Figs. 1 and 2), which is closed at the end by a replaceable foil membrane 13 adjacent to the seal 14 and pressed by a cap 15 screwed onto the block 1 with axial trunks 2 holes for free passage of the missile products 16 (figure 3).

Inside the holder 8 of the block 1 with a guaranteed clearance from the ends of the articles 16, in the shafts 2 (in the volume of the shutter chamber 11) movable sleeves 17 with a confuser fire-transfer hole 18 are installed, the calibrated nozzle 19 of which is located in the annular protrusion 20, intended for alignment with the landing hole for the capsule 21 at the end of the product 16.

To prevent the movable sleeve 17 from falling out of the shutter chamber 11 when assembling and disassembling blocks 1 and 3, restrictive pins 22 are mounted in the latter.

The locking sleeve 7 on the rear base 7 of the block 1 is fixed by a threaded nut 23 (figure 2).

The electrocapsule 4 of block 3 by means of loops 24 (Fig. 1) is connected to a switch 25 mounted on a casing 6 for connecting a power cable and firing control (not shown conventionally).

The electrocapsule 10 is an autonomous product that is installed in the socket 9 (figure 3) of the holder 8 before each equipment module.

The central electrode 26 (figure 4) of the electrocapsule 10 is rigidly fixed through a dielectric block 27 in the current-carrying shell 28 adjacent to the housing 29.

The central electrode 26 is electrically connected to the shell 28 by means of an incandescent bridge 30 soldered to them, which is placed in a pyrotechnic igniter charge 31.

The free volume of the open end of the housing 29 (above the pyrotechnic charge 31) performs the functions of a shutter due to its plastic deformation when the gaseous products of combustion of the pyrotechnic composition of the charge 31 are pressurized by pressure.

The proposed firing module operates as follows.

Shooting is conducted through the membrane 13, which is necessary to isolate the internal volume of the module from dust and precipitation, which is changed after each shooting.

To load the multi-barrel firing module, the block 3 of the contacts 4 is separated from the block 1 of the trunks 2, for which three tension locks 5 are released and opened.

Having removed from the block 3 contacts 4 casing 6, unscrew the threaded nut 23 and remove the clip 8, allowing access to the trunks 2 of block 1 for equipment.

In each barrel 2, a product 16 is installed (a fire extinguishing aerosol generator or an artillery cartridge is loaded).

Having screwed the cover 15, a membrane 13 is installed on the end face of the block 1 through the seal 14, and then the cover 15 is screwed.

An electric capsule 10 is installed in each socket 9 of the holder 8, after which the holder 8 is installed on the rear base 7 and clamped with a threaded nut 23.

Next, the power supply cable 24 is connected to the electrical contacts 4 of the block 3, after which the casing 6 is mounted on the clip 8, docking it to the block 1 of the trunks 2, which are interconnected by means of three tension locks 5.

Connecting the switch 25 to the power cable and firing control ensures that the module is ready for operation for the intended purpose by firing products 16, in a burst or in one gulp, which is carried out by supplying electrical signals from the control panel through the program of electrical signals through electrical contacts 4 to the corresponding electrical capsules 10.

The electrical circuit of the electrocapsule 10 (figure 4) is closed through the central electrode 26, the glow bridge 30, the current-carrying shell 28 and the housing 29.

In this case, the incandescent bridge 30 heats up, releasing heat into the adjacent charge 31, the pyrotechnic composition of which ignites and burns.

Gaseous combustion products of a pyrotechnic charge 31 fill the housing 29 and expressively enter the confuser fire-transfer opening 18 of the movable locking sleeve 17 (Fig. 3).

The sleeve 17 is longitudinally moved in the shutter chamber 11 until it stops in the flange of the product 16. In this case, the annular protrusion 20 of the sleeve 17 is tightly adjacent to the capsule 21 of the product 16, which provides an increase in pressure up to 25-30 kg / cm ² .

The pressure of the sharply directed flow of gaseous products of combustion from the nozzle 19 dynamically initiates the ignition of the propellant propellant charge of the product 16, resulting in a shot.

A feature of the functioning of the described mechanism for initiating the throwing of products 16 is the provision of a predetermined accuracy of operation due to the targeted use of the design pressure developed by the equipment of the capsule 10. The gaseous combustion products of the pyrotechnic composition 31, filling the shutter chamber 11, press the shutter sleeve 17 against the flange of the product 16 and are sealed in clip 8, since the housing 29 of the capsule 10 over charge 31 is inflated and tightly adjacent to the surface of its socket 9 (figure 5), excluding the breakthrough of gases through the clip 8 back.

Experienced firing indirectly confirmed the increased efficiency of the product throwing initiation mechanism 16 by the fact of a more accurate firing distance, which provided the expansion of the technological capabilities of using a multi-barrel firing module for throwing fire extinguisher aerosol generators into the fire.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the utility model does not explicitly follow for the ammunition specialist, showed that it is not known, and taking into account the practical possibility of serial production in the current production of multi-barrel firing modules, we can conclude eligibility criteria.

Claims (1)

A multi-barrel firing module containing a block of electrical contacts and a block of trunks carrying functional products connected by tension locks, equipped with a locking unit made in the form of a holder with axially distributed shafts and current leads of the contact block with sockets for electrocapsules, closed by locking bushings mounted with the possibility of longitudinal movement to the bottom the flange of the missile products before the abutment of the annular protrusion, in which there is a nozzle of a fire-transfer confuser hole, characterized by that the body of the electrocapsules is made in the form of a thin-walled cup, the free volume of which from the open end above the igniter charge is combined with the fire-transfer cofuser hole of the locking sleeve and is capable of radial deformation for obturation of the generated gases, while the central electrodes of each electrocapsule interacting with the current leads of the contact block by means of an incandescent bridge placed inside an igniter charge is electrically connected to its body through a current the leading shell of the dielectric block carrying the central electrode.