RU2836801C1 - Method of filling large-calibre aerial bombs - Google Patents

Abstract

FIELD: ammunition.

SUBSTANCE: invention relates to ammunition filling with explosives. Method of filling large-calibre bombs includes operations for delivery of components of explosive charge directly to airfield, their preliminary preparation – mixing and filling of body of aerial bomb. Components of an emulsion explosive are used as components of the charge, for example, ammonium nitrate, diesel fuel, a sensitizer – glass microspheres and stabilizing additives, and their mixing and subsequent filling of the housing of the aerial bomb is carried out using a mixing-charging machine.

EFFECT: improving safety when equipping aerial bombs at airfields where active attack and bomber aircraft are based.

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Description

The proposed invention relates to the field of equipping ammunition with explosives.

Currently, a widely used method of loading ammunition (BP) is filling their bodies with liquid (low-viscosity) explosives such as TNT and compositions based on it TG-50, TG-40, TGAG [1].

The said patent [1] notes that “the lump method of pouring currently used in industry requires manual compaction of the pieces in the housing, long feeding /up to 2 hours/, and when pouring with TNT - also the most complex operation of “shimozatsija”. The lump-free method has an even longer technological cycle, measured in many hours.”

However, the vacuum-lump filling method proposed there does not completely eliminate the shortcomings of filling methods for equipping BP, since in any case it requires a fairly long time for the crystallization of TNT and does not guarantee the production of its fine-crystalline, defect-free structure.

Along with this, it should be noted that the processes of equipping BP with high-brisant explosives are extremely explosive and fire hazardous, require specially equipped production areas and highly qualified personnel. Equipped BP require special conditions for transportation and storage at bases and arsenals, and then directly at the places of use. Special equipment and armed guards are required to perform transportation and storage operations. The above reasons have a negative impact on the associated financial costs both during equipping BP and during transportation and storage.

At the same time, the domestic ammunition industry has experience in equipping aerial bombs directly at front-line airfields [2] - the components of the explosive charge were delivered directly to the airfield, after which they were pre-prepared and subsequently filled into the bodies of the aerial bombs:

"...At the beginning of the war, when German troops approached Moscow, attempts were made to use oxyliquit bombs developed at NII-6 on the Western Front. For this purpose, the reinforced concrete bodies of the FAB-100 NG and FAB-250 NG were used. They were filled with a mixture of moss (sphagnum) and charcoal, which had a high absorption capacity. Liquid oxygen delivered from Moscow was poured into the bombs at front-line airfields. Bombs loaded in this way retained explosive properties at the level of bombs loaded with 50/50 TNT and ammatol, for 3-4 hours for the FAB-100 and FAB-250."

However, the delivery of liquid oxygen, especially in large volumes, is dangerous, imposing special requirements on transport vehicles and conditions for its preservation in liquefied form. For this reason, the equipping of such aerial bombs was discontinued.

The same information source [2] provides information on the loading of aerial bombs with liquid explosive mixture KD, consisting of nitric acid, dichloroethane and oleum. In terms of explosive characteristics, this mixture is equivalent to TNT. The high explosive effect of FAB-100 loaded with KD mixture was the same as FAB-100 loaded with TNT. Loading of FAB-100 KD was carried out by alternately pouring the components into the body of the aerial bomb and then mixing.

Due to the high toxicity of the components of the KD mixture, as well as its corrosive activity, the use of this mixture for equipping aerial bombs in airfield conditions turned out to be impractical, since it required compliance with special safety measures during transport operations, directly during equipping, and also placed high demands on the corrosion resistance of the equipped bodies.

The technical objective of the proposed invention is to increase safety when equipping aerial bombs at airfields where active attack and bomber aircraft are based.

The solution to the problem is achieved by the fact that in the known method of equipping large-caliber aerial bombs, including operations for delivering the components of the explosive charge directly to the airfield, their preliminary preparation - mixing and filling the body of the aerial bomb, in accordance with the invention, the components of the emulsion explosive are used as components of the charge, for example, ammonium nitrate, diesel fuel, a sensitizer - gas-generating additives or glass microspheres and stabilizing additives, and their mixing and subsequent filling of the body of the aerial bomb is carried out using a mixing and charging machine (MCM).

The necessity and sufficiency of the above-mentioned distinctive features of the proposed technical solution can be explained as follows.

Emulsion explosives (EE) of various grades have become widespread in the mining industry, contain non-deficient and non-explosive components, and are close to TNT in explosive characteristics. Transportation of EE components is safe, unlike ammunition loaded with TNT-containing explosives, since EE acquire explosive properties only after mixing the components.

An example is the explosive explosive Rioflex [3], which is a mechanical mixture of a water-gel matrix TU 2241-013-58472318-2003 (a colloid - a thickened aqueous solution of ammonium and sodium nitrate), granulated ammonium nitrate, diesel fuel, a sensitizing additive and a cross-linking composition according to TU 2499-014-5 8472318-2003.

The ratio of components in Rioflex is set by the regulations of the technological process of its production in mixing and charging machines and is ensured by the regulating and dosing devices of the SZM.

In appearance, Rioflex is a thick, rubber-like mass, from white to pale yellow, with visible inclusions of gas bubbles and ammonium nitrate granules. Its density is up to 1.3 g/ ^cm3 , the heat of explosion is up to 3630 kJ/kg, the TNT equivalent by volumetric energy concentration is up to 1.07, the ideal detonation velocity (at a density of 1.2 g/ ^cm3 ) is up to 6700 km/s. At the same time, the sensitivity of Rioflex to mechanical impacts is extremely low, therefore, intermediate detonators are used for its initiation - such as TGF-850E checkers.

The shelf life of explosive explosives in hermetically sealed containers (cartridges) is from 6 to 9 months, depending on the composition [4].

Thus, explosive explosives have high explosive characteristics comparable to TNT, are cheaper and safer to handle than standard explosives used for military purposes, and are capable of maintaining their characteristics over a long period of time.

The application of the method, i.e. the technological process of equipping aerial bombs with explosives, is supposed to be carried out in the following sequence:

1) At a specially organized technological section in the airfield conditions, where individual components of the explosives are stored, the corresponding containers of the SPM are loaded with the explosives components.

2) Transportation of explosive components to the SZM to the aerial bomb loading area.

3) Calibration (adjustment) of the SZM dosing devices for individual components of the explosive mixture to ensure compliance with the required component composition.

4) Checking the calibration by individually checking the quantity (mass) of each supplied component against the quantity specified using the electronic control panel of the SPM.

5) Mixing of components using the SZM equipment and subsequent feeding of the resulting explosive mixture into the bodies of aerial bombs using the SZM loading hose.

6) Installation of intermediate detonators in an aerial bomb.

7) Transporting the aerial bomb to the appropriate aircraft, screwing the fuse into its body and placing it on the external suspension elements or in the bomb bay.

8) Upon completion of the loading process, the remaining explosives are removed from the side unloading auger and the loading hose of the SZM.

9) The SPM is returned to the process section and, if necessary, it is reloaded with components of the explosive explosive. If there is no need for reloading, unused components are stored in the mixing and charging machine for no more than three days.

10) Before placing the SPM into long-term storage, all its containers are cleaned of residual components of the explosive emulsion.

EVMs are slow-burning substances that contain a large amount of water, so extinguishing possible fires can be carried out without fear that the combustion will turn into detonation.

Bombs not used in combat sorties may be stored, as noted above, for up to 9 months. After this period, the explosives may be removed from the bomb casings by washing them with water, after which the casings may be re-equipped.

Thus, the proposed method provides the possibility of safe equipping of aerial bombs at airfields of the base of active attack and bomber aviation. At the same time, transport operations for the delivery of components of explosives to airfields are also practically safe in comparison with the transportation of high-explosive explosives and ammunition with standard equipment.

At the same time, the use of this method implies significant economic benefits, since the cost of an explosive charge made from explosive explosives is less than when equipping aerial bombs with TNT-containing explosives, and in addition, the costs of carrying out logistics processes are lower than when transporting loaded ammunition from manufacturing plants across the country.

If the appropriate technical capabilities are available, the method can also be used to equip medium and small caliber aerial bombs.

Sources of information taken into account when preparing the application:

1) Russian Federation Patent No. 1841130 Vacuum-lump method for forming explosive charges in large-caliber ammunition casings, C06B 21/00, F42B 33/02, 2016.

2) MARATAKM website. High explosive bombs (FAB). Aviation ammunition https://maratakm.ru/development-calendar/fugasnve-aviabomby-fab-aviacionnve-boepripasy.html

3) Industrial explosives. Explosive substance Rioflex. Technical conditions TU 7276-011-58472318-2005.

4) NIPIGORMASH website https://npgm.ru/product-catalog/proizvodstvo-i-postavka-emulsionnykh-vv.html

Claims (1)

A method of equipping large-caliber aerial bombs, including operations for delivering the components of the explosive charge directly to the airfield, their preliminary preparation - mixing and filling the body of the aerial bomb, characterized in that the components of the charge are components of an emulsion explosive, for example, ammonium nitrate, diesel fuel, a sensitizer - glass microspheres and stabilizing additives, and their mixing and subsequent filling of the body of the aerial bomb is carried out using a mixing and charging machine.