UA79133C2 - Methofd for utilization of articles containing explosive substances - Google Patents

Abstract

A method for utilization of articles that contain explosive substance in which initiation of articles is performed in liquid that is salt solution at temperature not less than temperature of initiation of explosion of explosive substances present in articles, and at the way of discharge of gas explosive products formed damping elements are additionally installed. The invention makes it possible to increase safety of process of utilization, to decrease losses and to increase general productivity of process.

Description

Description of the invention

The invention belongs to methods of disposal of products containing explosive substances (hereinafter, explosives). The invention can be used, in particular, during the disposal of ammunition, including small-caliber ammunition such as cartridges of small arms and shots of automatic guns of caliber from 5.45 to ZOmm, combat parts of other similar ammunition, means of initiation, detonators, etc., unsuitable for further use and

Storage at bases and arsenals, as well as anti-personnel mines prohibited for use by the UN Ottawa Convention, or for the disposal of explosive objects, for example, in the course of preventing an attempted 710 terrorist act.

A well-known method of detonation of explosives by means of individual or group detonation in trenches using a charge charge in an open area in the conditions of a landfill | see, for example, Schilling N.A.

Explosive substances and ammunition equipment. Moscow: Oborongiz, 1946; Shchukin Y.G., Kutuzov B.N., Matsevich B.M.,

Yu.A. Tatishchev Industrial explosives based on recycled ammunition. M.: Nedra, 1988. p. 12,734. The disadvantage of the method is its low productivity and the danger of carrying out work.

A known method of explosive disposal of explosives by detonating them in a vacuum device located on a solid foundation in a natural depression below the level of the day surface, see patent application OE 4 240 394 C2, R 42 O 5/04). The method is implemented with the help of an explosive armor chamber and includes sluicing operations for loading VVR and releasing the products of the explosion; fastening of products in 20 armored chamber, protection of armored chamber; removal of secondary gaseous and solid products formed in the process of disposal of hazardous waste.

The advantage of this method is the reduction of the number of dangerous operations for the removal of the products of VVR planting.

The disadvantage of the method is the direct impact of the explosion energy on the walls of the chamber, as a result of which the device that implements this method has large dimensions, significant material consumption, and construction cost. Another disadvantage of the Ge) method is its high energy consumption and explosiveness, associated with the presence of operations to remove the means of landing, as well as low reliability and low workability.

There is a well-known method of disposal of VVR using their thermal destruction in armor furnaces. The most perfect method is based on the type 5K rotary armor furnace manufactured by the Voiog5 concern, Sweden |see. Technical description of the 5K400, 5K8O00, KI 200, 5KI 600, 5K2000, 5K2000, 5K400, 5K8O00, 5K2000 series armor furnaces of the Oupazaie Ziaiis Kiip brand, 1993). The process of disposing of VVR in this armored furnace consists of conducting operations in two chambers: the outer one, the working space of which is heated (incandescent) due to the direct burning of liquid fuel; and the inner one, which has a small-fraction embankment on its bottom and is heated to a temperature of 400-60092С from the heat of the outer chamber. dz

The working volumes of the chambers are separated from each other and have independent gas paths, so that each chamber

Zo communicates with the environment independently of each other. With the help of a special conveyor, the VBP is fed only to the internal heating chamber, where the BBP is destroyed either by the mechanism of an instant flash, or by the combustion of the BBP, or by their detonation on a red-hot embankment at the bottom of the internal heating chamber.

The process is practically uninhabited, has quite high productivity indicators (from 2 kg/hour to 40 kg/hour of VVR and from 100 grams to 2000 grams of maximum single loading (VVR weight is given in З7Z TNT equivalent). c The disadvantages of this method are the complexity of the method , high material and energy consumption, significant dimensions (from 1200x1500x2200 to 800x3600x4800) and mass (from 3000kg to 33000kg) of devices implementing this method.

Part of these shortcomings is eliminated by the method of disarming ammunition, according to which the armored chamber, in which the ammunition is detonated, is filled to the third of its volume with water | see stalemate. Russian Federation Mo2055302, 6E42833/00, 19961. -1 no As a result of filling the working volume of the armored chamber with a denser (approximately 1000 times) medium than the usual air or gas filling, the kinetic energy of the warhead fragments and its explosion products in this se) method extinguish much more effectively. Therefore, the advantage of the specified method (patent of the Russian Federation Mo2055302, - бЕ42833/00, 1996) is increased stability of the walls of devices (armored chambers) that implement this method and lower energy consumption. This method, in its technical essence, is the closest to the claimed invention. (65) 50 The disadvantages of this method are the high complexity of the design and the consumption of scarce materials. So, the chamber with a specific (semispherical) shape has an internal diameter of 4m (volume ZZm7), a wall thickness of armor steel at least 100mm. A significant disadvantage of this method is its low reliability and low workability, since the landing of the VVR is carried out by installing on the VVR with the help of plasticine (mastic) a standard explosive bomb and an electric detonator, which are detonated when the contact of the detonator touches the positive bus isolated from the ground, which is additionally installed immediately outside gateway (F. type of loading hole to the armored chamber. But the probability of loss of integrity of the electrical circuit in

The GI in this case is very large and a significant amount of undisposed ammunition can accumulate in the armored chamber over time, which can easily detonate and destroy the armored chamber. In addition, the cost of disposal in this way increases due to the need to carry out an additional operation of installing the checkerboard and detonator and the costs of their purchase. Thus, this method is characterized by increased labor losses and material and energy consumption.

The invention is based on the task of improving the method of disposal of products containing explosive substances by detonating them in a liquid, which is a salt melt at a temperature not lower than the temperature of initiation of detonation of explosive substances contained in the products and installing damping elements that reduce the energy of the explosion on the elements of devices for the disposal of VBP, reduces their material intensity, and energy intensity, the efficiency of disposal, endangers the disposal process, and reduces capital costs for the creation of the installation.

Solving this problem makes it possible to increase the safety of the disposal process, reduce capital costs for creating a facility that implements the method of waste disposal, reduce operational losses and increase the overall productivity of the process.

The task is achieved by the fact that in the known method of disposing of products containing explosives, which includes their supply through a sluice device into an armored chamber filled with liquid, the subsequent initiation of their detonation, the release of the formed gaseous products of the explosion into the cleaning system, the detonation of products containing explosive /o substances, according to the invention, are carried out in a liquid, which is a salt melt at a temperature not lower than the temperature of initiation of detonation of explosive substances contained in the products, and damping elements are additionally installed on the path of ejection of the formed gaseous products of the explosion.

The replacement of the environment in which the explosive device detonation is carried out in the armored chamber is a fundamental feature, since the environment according to the prototype (water under normal conditions) is only able to reduce the intensity of mechanical 7/5 Vii products and remnants of the explosion on the walls of the armored chamber, while the environment according to the invention ( high-temperature salt melt) allows, in addition to weakening the mechanical effect of the products and the remains of the explosion on the walls of the armored chamber, to initiate the explosive substances contained in the products. Therefore, there is no need to install an additional TNT checker and an electric detonator to it on the VVR, as required by the method according to the prototype. Due to this, the material capacity is reduced and the productivity is increased by the proposed method.

In addition, since the viscosity and density of the salt melt is two or more times higher than that of water, the function of weakening the mechanical effect of the products and remnants of the explosion on the walls of the armored chamber in the proposed method is enhanced accordingly. Also, due to the fact that the heat transfer coefficient in the liquid is one to two orders of magnitude higher than in the gas or air environment, the heating rate of the VVR in the proposed high-temperature liquid high-temperature liquid increases, which, accordingly, increases the productivity of the method in comparison with ordinary armored furnaces of the ZK type of production of the Voiog5 concern, Sweden | see Technical description of the armored furnace of the Oupazaie brand i)

Ziais Kiip series 5K400, 5K800, KI 200, ZKI 600, Z5K2000, 19931),

The installation of additional damping elements on the path of ejection of the formed gaseous products of the explosion allows to reduce the pressure in the armored chamber, which leads to an improvement in the reliability of the equipment that implements the method of disposal of explosives. The continuous throttling of explosion products to the cleaning system allows organizing a continuous process of waste disposal. at

Damping elements for absorbing the energy of the shock wave of the explosion use those that are usually "- used in the localization of explosions, for example, flexible perforated elements with poorly streamlined planes. To illustrate the operation of the method, a set of poorly flowing discs on the common axis is used. me)

The use of salt melts is a fairly well-known operation in the art. Yes, well-known electric bath furnaces with salts of alkali metals, alkalis and their mixtures, which are usually used for heating during tempering of steel products. You can choose the composition of the salt melt for almost any operating temperature, but this temperature should not be lower than the temperature of thermal initiation of the blast. To obtain a high rate of heating of the VVR, it is advisable to use temperatures at the limit of thermal stability of structural materials, "

From which the armored furnace was built, that is, of the order of 800...900250. з с Compared with the prototype, the proposed method is more energy efficient. This is achieved due to the accumulation of the heat of the VVR explosion by the salt melt. In the prototype, this energy is dissipated in the water and completely lost.

In some cases, a high-temperature liquid can be used as a heat agent for thermal destruction (pyrolysis, gasification) of BVR compounds, which is completely impossible in the prototype method, where water can only be a solvent.

The figure shows a device for implementing the proposed method. o This device contains an armored chamber 7 with liquid 2; electric heater 3, thermal insulation 4; cover 5 of the armored chamber; - product containing VVR, 6 (initial position before feeding it into the liquid); the rotary part of the gateway for presenting products containing BVR, 7; the guide part of the gateway for presenting products containing BVR, 8; thrown against a perforated pipe 10; damping element 11. The number 9 indicates the limit momentary position of the liquid mirror in the exhaust pipe 10 and the damping element 11; the number 72 indicates the momentary position of the product containing the VVR in the liquid at the time of its detonation.

An example of a specific implementation of the method for the case of disposal of MD-7, MD-8 type explosives weighing about 1 g of initiating explosive substance (hereinafter Detonator 6) is presented below.

They use an armored chamber, which is essentially an armored conventional electric furnace with iF) high-temperature heating medium, the melting temperature of which determines the working temperature of the disposal process. This stove-bath is equipped with a cover of the type of flange connection and improved insulation. As a heating medium, it is advisable to choose a salt melt, namely sodium chloride (table salt, or table salt). Mass! at its melting point of 8502С. The liquid at this temperature ensures a high rate of heating of objects, as well as a high degree of reliability of thermal initiation of detonation of explosives. It is possible to use salt melts from other salts or their mixtures. But sodium chloride, on the one hand, is a cheap, environmentally friendly material, and on the other hand, according to literature | see Wolf 0.0. Explosion. K.:

Science Dumka, 1973. - P.47), it has the inherent property of lowering the temperature of the explosion products to 65 1500-19002С, which significantly improves the operation of disposal devices.

Thus, before the start of the disposal process, similar to the prototype, the armored chamber / about 3/4 of the volume is loaded with MaSi salt. Then it reaches the working condition by heating the armor furnace with the help of an electric heater 3. After preheating and turning the salt into a liquid (salt melt) 2, i.e. reaching the working mode process, start the disposal process. Detonator b is fed through the sluice device, which consists of a rotary part 7, into which the detonator 6 is loaded, and a guide part 8, which, when rotating the rotary part 7, directs the detonator b to the bath with salt melt 2. Under the action of gravity, the detonator 6 sinks into liquid During its stay in the liquid, which is at a temperature of 8502C, a rapid heating process of the detonator 6 takes place, and after it reaches the detonation initiation temperature at point 12, the detonation takes place and thus the detonator 6 is neutralized. Gaseous products of the explosion and the shock wave 70 under the action of excess pressure and due interactions with the walls of the armored chamber 7, form a directed flow of the shock wave and explosion products, which is directed to the cleaning system (not conventionally shown in Fig. 1) through the exhaust perforated pipes 10 and damping elements 11. Thus, the gaseous products of the explosion are continuously throttled and ejected from armored cameras into the cleaning system regardless of the rate of operation of nodes 7, 8 of the sluice device.

When landing an anti-aircraft missile (in this example, blaster 6), thermal energy is released, which, due to the very low heat capacity of the gaseous products of the explosion, is lost to a lesser extent when the gaseous products of the explosion are ejected from the armored chamber 7. | on the contrary, the thermal energy of the explosion of the VVR is mostly absorbed by liquid 2 and is spent on maintaining its operating temperature. Thus, in the presence of thermal insulation 4, there is no need for continuous operation of the electric heater Z and it is disconnected from the power grid.

That is, the energy released during the explosion is used in the process of waste disposal, providing a reduction in energy costs, due to which high energy efficiency of the disposal method is achieved

The proposed VVR.

As a result of the high temperature of liquid 2 in the armored chamber 7, conditions are provided for high-intensity thermal decomposition or combustion of non-metallic compounds from which VVRs are built, and their

Residues to the state of simple oxides, that is, the conditions for their disposal are improved, including incineration, if necessary, in the purification system of

Thus, the proposed method makes it possible to dispose of products containing explosive substances with a significant reduction in the energy of the impact of the shock wave on the walls of the chamber during the explosion. Therefore, the practical use of the proposed invention will significantly increase the safety of disposal of products containing explosive substances. Application of the proposed method makes it possible to significantly reduce the dimensions and material consumption of means of localization of the explosion and significantly reduce their cost. The proposed method provides the greatest advantages and. during the disposal of products containing explosive substances from which it is impossible to remove explosive devices before "-- disposal. (at)

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Claims (1)

The formula of the invention is a method of disposing of products containing explosive substances, which includes their feeding through a sluice device into an armored chamber filled with liquid, the subsequent initiation of their detonation, the ejection of the formed gaseous products of the explosion into the cleaning system, which is characterized by the fact that the detonation of products containing explosive substances, 2 s are carried out in a liquid that is a salt melt at a temperature not lower than the temperature of initiation of detonation of explosive substances contained in the products, and on the path of ejection of the formed gaseous products of the explosion h . . and? damping elements are additionally installed. -i se) - (95) syu» ime) 60 b5