RU2173491C1 - Method and device for raising safety of nuclear ammunition - Google Patents

Abstract

FIELD: safety in storage and application of nuclear weapons. SUBSTANCE: proposed method and device are characterized in that liquid or suspended explosive is used as high explosive charge of atomic warhead and is stored in additional compartment and that prior to or in the course of its use ammunition is fed to charge pocket of atomic warhead by means of pumping-and- metering device thereby providing for its arming. Used as high explosive is liquid glycerin nitroisobutyltrinitrate or octogen suspension in following proportion, mass percent: liquid high explosive (glycerin nitroizobutyltrinitrate) 100,0 - 71,94; solid high explosive (octogen) 0,0 - 27,06; auxiliary dopes 0,0 - 01,00. Additional compartment holding liquid or suspended high explosive is stored and transported separately from nuclear ammunition. When nuclear ammunition is placed on carrier, additional-compartment line is joined with ammunition line through coupling to form integral pipeline. Liquid or suspended explosive is fed on command from nuclear-weapon control system to charge pocket of atomic warhead through valve arrangement thereby ensuring its arming. Radioactive charge is located in design-assigned point of atomic warhead; initiating means are installed in its case. Atomic warhead arm time is 2 to 5 minutes. EFFECT: eliminated probability of accidental or unauthorized operation of atomic warhead during ammunition storage and transportation. 2 cl, 2 dwg, 2 tbl

Description

 The invention relates to techniques for improving the safety of storage and operation of nuclear weapons. The primary area of its use is the operation of nuclear munitions containing chemical explosives (explosives), radioactive substances (RS) and other harmful components.

 Known technical solution for the device of atomic and thermonuclear charges (Protection against weapons of mass destruction // Handbook, edited by Myasnikov VV - M .: Military Publishing, 1989).

The atomic charge (AZ), which has a compact shape that is close to spherical, is made of PB (for example, U ₂₃₅ , Pu ₂₃₉ ), which are enclosed in the charge cavity of the blasting explosive, as well as initiating means located in the AZ case. The design of the thermonuclear charge includes an AZ and one or more thermonuclear cascades enclosed together inside the reflective shell of the body. AZ serves as the primary fuse for igniting thermonuclear cascades.

 Currently, there are known methods and devices for improving the safety of nuclear weapons related to the protection of nuclear weapons by using heat shields, protective power shells and external protection — special containers in their design. AZ also uses blasting explosives with reduced sensitivity to shock and thermal heating. This allows you to reduce the risk of unauthorized explosion of AZ during storage and transportation. The disadvantage of these nuclear munitions is that when certain levels of intense emergency and other influences are exceeded, a rather high probability of explosive charge detonation remains. As a result of the explosion of the explosive, the munition shell is destroyed and the atomized explosives are released into the environment, which can lead to the development of a radiation accident of catastrophic scale (Mikhailov V., Ilkaev R. et al. // Minatom of Russia and ensuring the safety of nuclear weapons of the Russian Federation // International life.N 6. 1996 [5].

 Closest to the technical nature of the claimed invention from those considered (Auth. St. USSR N 906229, F 42 D 7/00, F 42 B 3/04. 1978 Aut. St. USSR N 828810, F 42 D 7/00 1979, Pat. Of Russia N 2043984, C 06 V 25/10. 1992 Pat. Russia N 2063944, C 06 B 25/10. 1996) should be considered a way to improve the safety of nuclear munitions, which consists in the removal of nuclear munitions from operational readiness by disconnecting the AZ containing explosive and radioactive substances from the ammunition and placing the AZ in an autonomous explosion-proof container for separate containment I AZ from the rest of a nuclear weapon until the onset threatened. (Russian Pat. N 2090830, 6 G 21 J 1/00, G 21 F 5/00. 1996).

 The disadvantages of the prototype include the following. Additional work associated with the dismantling of the AZ, its packing in a container and reassembling into a thermonuclear charge are especially dangerous. With a sufficiently large amount of ammunition with reduced operational readiness, the problem of the readiness of nuclear weapons as a whole arises. Known container designs do not provide reliable localization within their volume of products of emergency explosive detonation and do not impede the release of atomized explosives into the environment in the event of an accident. The authorized destruction of nuclear munitions inside a container by undermining the latter in emergency mode is unacceptable, as there is a problem of their further storage, transportation and disposal.

 When implementing the above method, the task of reducing the likelihood of a large-scale radiation accident is practically not solved, since the main materials contributing to this continue to be in tight assembly. This method can be used only for certain types of ammunition, but in this case it does not solve the problem associated with the risk of radiation contamination of the area during the explosion of AZ.

 The objective of the invention is to develop a method and device that improves the safety of nuclear munitions during storage, transportation, operation and authorized removal of them from a healthy state [5].

 EFFECT: practical elimination of the risk of a radiation accident and large-scale environmental contamination, a significant increase in the fire and explosion safety of nuclear munitions. The method and device additionally allows to solve the problem of authorized withdrawal of nuclear munitions from an operational state in the event of a threat of enemy capture without the need to undermine the AZ. Group explosion safety is almost completely ensured without the use of expensive materials, design solutions and the funds spent on the conversion of external protection facilities (storage locations, transportation means, etc.).

 In the device, a nuclear munition including an AZ and at least one thermonuclear cascade is taken out of a state of operational readiness by disconnecting an explosive from its composition. According to the invention, a liquid or suspension explosive is used as a blast explosive charge, which is initially placed in an additional compartment, and before use as intended or in the course of it, it is fed into the charging chamber of the AZ using a discharge-dispensing device through a pipeline. The additional compartment contains a container for explosives with a discharge-metering device, a power drive, a valve device, a non-return valve, a supply line for explosives and an emergency discharge line for explosives. Through the valve device, the coupling and the ammunition line, an additional compartment is connected to the charge chamber of the AZ equipped with safety valves. Storage and transportation of an additional compartment with explosives are carried out separately from the ammunition. It can be mounted on a carrier of nuclear weapons (NW) or mounted together with ammunition. In this case, the choice of installation location should provide a minimum length of pipelines for supplying explosives from an additional compartment to the charging chamber of the AZ. Full filling with a liquid or suspension blasting explosive explosive charge chamber AZ ensures its "cocking". The process of delivering explosives begins at the command of the nuclear weapons control system and can be carried out both in the conditions of prelaunch preparation of nuclear weapons, and in the process of moving it toward the target, and depends on the conditions of combat use (flight time, overloads, etc.).

 The method and device provides that the means of initiation are located in the enclosure AZ. The charging cavity is free of explosives. The charge from the explosive is held at the place provided by the design of the AZ.

The use of liquid or suspension blasting explosives, close in power to regular solid explosives, and their spatial separation from the explosive allows you to:
- virtually eliminate the likelihood of emergency or unauthorized operation of the AZ during storage and transportation of ammunition;
- to increase the overall security of storage, transportation and operation of nuclear weapons by increasing "internal security",
- exclude particularly dangerous operations with AZ,
- eliminate the need to increase internal and external protection;
- maintain high readiness of nuclear weapons for use;
- exclude the possibility of unauthorized operation of the ammunition in case of its capture by the enemy.

 The ability to remove liquid or suspension explosives outside the additional compartment can also increase the fire and explosion safety of nuclear weapons in general.

 Figure 1 shows a General view of a device that implements the proposed method. Figure 2 - diagram of the injection-metering device for supplying explosives according to the proposed method.

 The method and device are implemented as follows.

The charge from the RV (1) is located inside the charging cavity (2) of the ammunition in a place established by the design. Initiation means are installed in the AZ case (3). A liquid or suspension blasting explosive is located in an additional compartment (4) in an airtight container (5) along with means for pumping it. The injection-metering device is made using a screw extruder (6) and a piston displacer (7). As a power drive (8), an electric drive or a powder gas generator can be used. The operation of the power drive (8) and the opening of the valve device (9) in the normal mode begin only upon a command from the nuclear weapons carrier control system. The pipeline through which the explosive is pumped consists of a nuclear munition line (10) and a charging compartment line (11). The mains are connected into the pipeline during installation through the connecting sleeve (12). The tightness of the pipeline and the charging cavity of the AZ, as well as reliable cocking of the AZ is ensured by safety valves (13). The emergency release line (14) automatically opens in the event of a fire or an authorized failure of a nuclear munition, while the power drive (8) is simultaneously triggered. The valve device (9) provides:
- opening of a pipeline for supplying explosives to the charging chamber of the AZ (Pos. 1);
- opening of the emergency release line (Pos. 2) in the event of a fire or an authorized failure.

 The neutral position of the valve device is the position at which the explosive does not enter any of the lines (Pos. 0).

 Nitroisobutyl trinitrate glycerol (NIBTNG) can be used as a liquid blasting explosive (LBVV), which in energy content exceeds nitroglycerin by 7%, and operational characteristics, including sensitivity to mechanical stress, are significantly more favorable than the latter [4].

 Suspension explosives can be made by filling concrete compounds with octogen granules of various fractional composition, the volume fraction of which is limited only by the rheological properties of the suspension. Filling with concrete with octogen allows approximating the energy characteristics of the suspension to regular solid blasting explosives.

 There are a number of technical solutions that make it possible to create conditions for pumping a liquid or suspension explosive from an additional compartment into the AZ charging cavity. In this case, the main condition is the creation of a safe overpressure (ΔР) in the area of the additional compartment. The speed of transferring the mass of explosives through the pipeline depends on the rheological properties of the explosives, diameter, shape of the pipeline and ΔP.

 Since for cocking AZ it is necessary to supply a small amount of reinforced concrete or suspension blasting explosive (10-20 kg) and this process is designed for only one cycle, it is possible to achieve a cocking time of AZ in several minutes. A cocking time of 2 to 5 minutes can be considered acceptable (depending on the type of nuclear munition and the conditions for its use).

In cooperation with the association manufacturing industrial explosives, experiments were carried out to pump liquids and suspensions on a neutral model of the device. As working fluids, we used a liquid and a suspension based on it, which are close in rheological properties to reinforced concrete (NIBTNG) and suspension explosive, respectively. So, glycerol was used as a prototype of a liquid explosive, and a mixture of glycerol and granular HMX (fraction 160 • 10 ^-6 -315 • 10 ^-6 m) with a volumetric degree of 0.20-0.25 was used as a suspension.

Examples of specific performance of the method and device
Example 1. Conditions: glycerin, displacer: piston-type injection and metering device, pipeline length 1.4 m, pipeline internal diameter 0.01 m, liquid volume 0.007 m ³ (7 L), T = 20 ^o C. Filling time (t) of the charging cavity in seconds. ΔP was measured in MPa. The necessary overpressures were measured to ensure a given time for pumping fluid from one volume to another. The results are shown in table. 1.

Example 2. Conditions: a suspension comprising glycerin filled with granular octogen with a volumetric degree of filling Φ = 0.22 (27 wt.%); displacer: screw-type metering device of screw type (extruder), pipeline length 1.4 m, internal diameter of the pipeline 0.01 m, suspension volume 0.007 m ³ (7 L), T = 20 ^o C. Filling time (t) of the charging cavity in seconds. ΔP was measured in MPa. Technological additive - lecithin (0.5 wt.%). The necessary overpressures were measured to ensure a given time for pumping the suspension from one volume to another. The results are shown in table. 2.

Sources of information
1. Protection against weapons of mass destruction // Handbook, ed. Myasnikova V.V. - M .: Military Publishing, 1989.

 2. Mikhailov V., Ilkaev R. et al. // Minatom of Russia and ensuring the safety of nuclear weapons of the Russian Federation // International life. N 6. 1996.

 3. RU Patent N 2090830, 6 G 21 J 1/00, G 21 F 5/00. 1996 year

 4. Orlova E.Yu. // Chemistry and technology of blasting explosives. - L.: Chemistry, 1981.

 5. Radaev NN // Principles of setting requirements for nuclear weapons for safety // Military Thought. N 2. 1999.

Claims (1)

1. A way to increase the safety of nuclear munitions, including an atomic charge and at least one thermonuclear cascade, which consists in removing a nuclear munition from a state of operational readiness by disconnecting an explosive from its composition, characterized in that the charge is a blasting explosive use a liquid or suspension explosive, which is placed in an additional compartment, and before using the ammunition for its intended purpose or in the course of it, it is fed into the charging cavity of an atomic charge using an injection-dosing the device through the pipeline, while as a blasting explosive, use liquid nitroisobutyl trinitrate glycerol or a suspension of HMX therein in the following proportions, wt.%:
Liquid blasting explosive - nitroisobutyl trinitrate glycerol - 100.0 - 71.94
Solid blasting explosive - octogen - 0.0 - 27.06
Technological additives - 0.0 - 01.00
2. Device for improving the safety of nuclear munitions, including an atomic charge and at least one thermonuclear cascade, characterized in that an additional compartment is introduced into the device, containing an explosive-containment tank with a discharge-metering device, a power drive, a valve device, a check valve , an explosive release line and an emergency release line for explosives, which is connected to the charge cavity of an atomic charge equipped with safety valves through a coupling and an ammunition line.

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