RU2748912C1 - Method for safe handling of energy materials - Google Patents

Abstract

FIELD: energy material handling.

SUBSTANCE: method of energy material handling refers to the direct process of using energy materials in the production cycle and can be used in the production of explosives, pharmaceuticals and chemical fertilizers. The method includes loading the energy material into the container, constant monitoring of the permissible parameters of the loaded energy material status, stabilization of the parameters of the energy material in the container when they deviate from the permissible parameters, transportation of the energy material in the container, storage of the energy material in the container, the energy material discharge from the container. The discharge of the energy material from the container is carried out directly within an operation of the production cycle that is required at the time for an intended purpose. At the same time, the permissible parameters of the status of the energy material loaded into the container are monitored, which is affected by the environment of the production cycle operation. In case of deviation from the permissible parameters, the parameters of the energy material are stabilized or the discharge of the energy material is blocked.

EFFECT: increased safety in the direct process of using energy materials in manufacturing of products or semi-finished products.

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Description

Technology area

The invention relates to a method for handling energy materials, in particular, to the direct process of using energy materials in a production cycle, and can be used, in particular, in the production of explosives, pharmaceuticals and chemical fertilizers.

State of the art

From the prior art energetic materials are known - chemical substances prone to physicochemical transformations under thermal or mechanical effects on them. The term "energetic materials" is used primarily to include all materials that may undergo an exothermic chemical reaction in which thermal energy is released. Traditionally, energetic materials include aromatic nitro and nitroso compounds, which are most widely used for the production of drugs, dyes, solvents, explosives, pyrotechnic, as well as gunpowders and solid rocket fuels, fumigants and many other compounds. The main feature of such energetic materials is their high energy density and the ability to involuntarily release energy condensed in the structure under accidental thermal or mechanical influences. All these substances decompose according to a homogeneous mechanism and lead not only to deterioration of the properties and deterioration of the product, but also to accidents with serious consequences. The decomposition processes that can be generated during the storage, transportation and processing of these energetic materials are part of the classic risk situation, which is associated with almost 90% of accidents during the handling and performance of work at industrial and transport facilities.

For all these hazardous substances, the mechanism of excitation of decomposition, combustion and explosion processes remains not fully understood. Moreover, the mechanism of excitation of these dangerous processes for each of these substances is different for different types of exposure (shock, friction, heating, vibration). The frequency of changes in stresses and deformations, the duration of exposure also remains unknown, since the duration of each cycle of loading a crystal of an energetic material located in the volume of a container is very small. In each act of exposure to a substance, the parameters of electrification of particles (under various conditions of air humidity), their dusting during vibrations and shocks also remain unknown.

It is known that the primary stage of the energy release process is the decomposition of a chemical compound (decay, spoilage) under the influence of external factors (temperature, pressure, air oxygen, shock, vibration, etc.) with the release of heat and gaseous decomposition products.

The only parameter for assessing the rate of decomposition of substances in physics is the half-life. A common characteristic for all chemical reactions is the rate at which they proceed and, which increases very rapidly with increasing temperature. Therefore, for energetic materials, the value of the decomposition onset temperature is the only criterion that reflects the properties of these materials after thermal or mechanical action. It has been established that the reaction of physicochemical decomposition of energetic materials can proceed along two, basically, different paths.

One of them is called homogeneous decomposition, which takes place in an energetic material at any given temperature, pressure and vibration. It flows at the same rate throughout the material, but much faster at higher temperatures, pressures or vibrations. For example, it has been proven that at vibrations of 30 Hz and higher, the processes of chemical decomposition begin in energetic materials. If thermal, vibration or mechanical influences continue, then the process of decomposition of the material is activated. The first type of decomposition process is responsible for the deterioration of the properties of the energetic material (explosive, gunpowder, solid propellant, gaseous compounds such as hydrogen peroxide, pyrotechnic mixture, pharmaceutical or chemical fertilizer) during a long storage period or can cause catastrophic self-heating, for example, if the material (substance) is kept at a high temperature for a long time.

The second type is a process that is considered combustion or surface combustion. This is a faster decomposition that occurs locally, mainly on the free surface in contact with a hot gas such as a flame, which heats the surface causing the material in that zone to decompose while the other part of the material remains cold and stable. This type of decomposition is a process by which all energetic materials are capable of reacting upon ignition, providing a steady flow of hot gases, and it can also be a reactionary process during shock initiation and detonation in porous explosives.

The present invention is aimed at preventing the occurrence of the first type from the described processes of decomposition of the energetic material, while it can be used when the second type of decomposition of the energetic material occurs.

From the RF patent for invention No. 2603339, IPC G01N 27/416, published on November 27, 2016, a method for measuring temperature, humidity and the rate of their change in a sealed container with a gas environment and a device (container) for its implementation are known. So, the specified method includes the installation in the container of the objects under study with time-varying physicochemical parameters (energy materials) and temperature and humidity sensors, dynamic measurement of indicators of the gaseous medium in the container, using the specified temperature and humidity sensors, conversion of the measured analog signals of the sensors into the final form of data and their transfer to an autonomous measuring and conversion unit and a data processing center for their collection and analysis. On the basis of the formed databases, they control the process, make an assessment of the process safety and forecast the further development of the process. The specified method and the container proposed in accordance with it allow only passive observation and do not allow to influence the energy material in real time, to protect against emergencies, and also do not provide for the simultaneous use of the energy material in the required operation of the production cycle.

From the patent of the Russian Federation for invention No. 2508528, IPC G01M 11/00, published on February 27, 2014, there is a known method for assessing the state of the controlled object, including measuring using sensors -temperature, shock pulse, pressure, speed, displacement, parameters of the state of the energy material in the container , as well as a block of code and identification, structurally combined with adapter devices (connectors), information communication channels, a polling console (internal controller), a PC (external control panel), a PC communication interface. The polling console is designed to promptly receive, in light and sound, information about the change in the hazard state of the energy material after emergency impacts, as well as to control the initial states, register, process and store information about the triggering (non-triggering) of each of the primary converters (sensors), the type of impact and data required to identify the energetic material. The received information, if necessary, can be transferred via the interface to a PC for further processing. Despite the fact that the specified method involves more types of measurements (sensors), the specified invention does not allow to control (influence) the state of the energy material in real time, does not protect against emergencies, and also does not provide for the use of the energy material in the required production cycle operations.

From the RF patent for invention No. 2715379, IPC G21F 5/00, published on February 27, 2020, a container with protection and control means is known, including a shock overload control sensor, a temperature sensor and an opening control sensor connected to a passive transponder, and at least one reader, remotely located relative to the container, identifying the passive transponder and monitoring the transponder state by means of radio sounding. In this case, the protection function is achieved through the use of an external power body, a bulletproof protective screen, a heat-protective layer, a damping layer, which together form an internal cavity for placing the protected and controlled cargo, that is, it provides passive protection against emergency situations associated with the state of the energy material, and is aimed primarily not at preventing emergency situations, but at reducing damage and damage from them. Thus, the specified invention does not allow to control (influence) the energy material in real time, does not protect against the occurrence of emergency situations, and also does not provide for the use of the energy material in the required operation of the production cycle.

From the RF patent for invention No. 2362600, IPC A62C 2/00, published on July 27, 2009, a system for storing hazardous chemicals is known, containing a first container for storing chemicals (energy materials) and a second container, while the first container has a device leak detection, which, upon detection of a leak of hazardous chemicals or when exposed to high temperatures (temperature sensor), controls an automatic outlet to automatically open, the second container contains a substantially harmless liquefied gas (inert gas) and has an opening that communicates with the external environment controlled environment. At the same time, the specified system is equipped with protection against emergency situations, during which the release of liquefied gas (safe gas), absorbing the heat of the first container, is carried out so that the temperature of the first container decreases and the pressure in the first container decreases so as to prevent leakage or explosion of the first container caused by overpressure, or increase the viscosity of hazardous chemicals (energetic materials) to reduce the rate of leakage when it occurs. The advantage of this invention is protection from emergency situations without destroying the stored energetic material, while the specified invention allows you to control (influence) the energetic material in a narrow range of the state of the energetic material, but does not provide complete protection against the continuation of the reaction in the energetic material after it has cooled, and also from repetition of emergency situations, since the supply of liquefied gas is limited. In addition, the specified invention does not provide for the simultaneous use of the energetic material in the required operation of the production cycle.

The closest technical solution, chosen as the closest analogue, is a method of inerting to prevent fires or an explosion in a closed protected space (container), known from the RF patent for invention No. 2362600, IPC A62C 2/00, published on July 27, 2009, in in which the oxygen content in the protected space is lowered to the baseline inertization level, while sensors are used to measure the concentration of combustible gases in the protected space / area. The overall quenching effect of this method is based on the principle of oxygen displacement. This method is based on constant monitoring of combustible gases in a closed, protected space containing potentially combustible materials, and the displacement of combustible gases using an inert gas. At the same time, this method does not solve the problem of protection against emergency situations not related to the concentration of combustible gases, for example, with an increase in temperature, pressure, vibration and other influences exerted on the energy material during storage, transportation and use of the energy material in the required operation of the production cycle ... In addition, only a part of emergency situations is associated with the presence of flammable gases in the container, while with substances, including nitroglycerin, in order to prevent emergency situations, additional monitoring of the state of energy materials, as well as methods of exposure to them, is required. In addition, the specified invention does not provide for the simultaneous use of the energetic material in the required operation of the production cycle.

The above-described methods of handling energy materials and containers are used to ensure safety when performing only basic tasks - transportation and storage of energy materials, since they do not have such functionality as continuous-cyclic (constant) monitoring of the state and stabilization of the behavior of an energy material in a container during its use in production, including when dispensing the required amount of material required in a specific technological operation.

In addition, the above-described methods of handling energy materials and containers do not provide for an automatic procedure for admitting an energy material for use in a production operation after exposure to it as a result of unregulated transportation and storage. So, if there is information about the presence in the process of transportation or storage of containers with energy materials of cases of exposure to temperature, pressure and vibration, initiating the process of homogeneous decomposition of the energy material, the decision on the admission of the energy material to further production operations is made based on the experience of the personnel, or based on the results of additional and long-term laboratory research at the user enterprise, or is not taken into account, which increases the risk of an emergency and reduces the quality of finished products / semi-finished products.

Thus, the absence of a system for the safe handling of energy materials in the process of their use in the manufacture of products / semi-finished products requires many additional operations with energy materials, such as: sampling for further research at the user enterprise, repackaging of energy materials into dosing devices / systems. or containers for further use in production, moving the selected amount of energy material through the workshop / user enterprise, storing the selected amount of energy material in the workshop / production site of the user enterprise, cleaning the container and (or) its destruction after carrying out the required operations. So, when such a container comes from a manufacturer with an energy material, the user enterprise, the personnel of the latter have to carry out the above operations with energy materials, which increases the likelihood of emergency situations. At the same time, from two to six people are involved in each hazardous operation, which requires taking into account the costs of ensuring their safety, compensation in case of death or injury, as well as the maintenance of control and industrial safety services. In addition, when using such a container in production, a constant source of danger and non-productive costs remains, the resources of the enterprise are spent on controlling the transport and logistics flows of energy materials, both on the territory of the production zone and in the circuit of industrial facilities of the industry or cooperation.

Disclosure of invention

The objective of the present invention is to create a system for the safe handling of energy materials in the process of their use in the manufacture of products / semi-finished products, which has constant monitoring of the state of the energy material in the container with the direct use of the energy material in the production cycle, which has the ability to stabilize the behavior of the energy material in the container or to produce blocking the unloading (dosing) of the energy material in the event of a deviation of its state from the specified values when it is used in the production cycle, as well as having the ability to control the regulated use of the energy material from the moment it is loaded into the container at the manufacturing enterprise until it is completely consumed in the production cycle of the enterprise -user.

The technical result of the present invention is to improve safety in the direct process of using energy materials in the production of products / semi-finished products, achieved through constant monitoring of the state of the energy material in the container with the direct use of the energy material in the production cycle, the ability to stabilize the behavior of the energy material in the container or blocking of unloading energy material in the event of a deviation of its state from the specified values when it is directly involved in the production cycle, the ability to control without interruption the regulated use of the energy material from the moment it is loaded into the container at the manufacturing plant until it is completely consumed in the production cycle of the user enterprise. An additional technical result is a reduction in production costs, including time and transport costs, due to the exclusion of the following operations from the technological process: sampling for laboratory studies of the characteristics of the energy material at the user enterprise after transportation or storage, repackaging of the energy material into the dosing device / system and a container for further use in production, moving a selected amount of energy material through the workshop / production site of a user enterprise, storing a selected amount of an energy material in a workshop / user enterprise, cleaning containers or destroying it after performing the required operations.

The specified technical result is achieved using a method for the safe handling of energetic materials, including loading energetic material into a container, constant monitoring of the permissible parameters of the state of the loaded energetic material, stabilization of the parameters of energetic material in the container when they deviate from the permissible parameters, transportation of energetic material in the container, storage of energetic material. material in a container, unloading of energy material from the container. According to the declared solution, the unloading of the energy material from the container is carried out directly at the required time and according to the purpose of the operation of the production cycle, while monitoring the permissible parameters of the state of the energy material loaded into the container, which is influenced by the environment of the operation of the production cycle, and in case of deviation from permissible parameters, the parameters of the energetic material are stabilized or the unloading of the energetic material is blocked.

After loading the energy material into the container, they can control access to the volume of the container, control the unloading of the energy material, and control the location of the container. And the control of the permissible parameters of the state of the loaded energetic material can include the control of high-frequency influences, and / or temperature, and / or pressure, as well as the presence in the volume of the container of primary gaseous decomposition products of energetic materials - nitrogen dioxide, nitrogen oxide, hydrogen, ammonia, chlorine ion or carbon monoxide. At the same time, information about any attempt of unauthorized access and unloading of energy material, about the location of the container and about the parameters of the state of the loaded energy material can be used when making a decision to stabilize the parameters of the energy material or block the unloading of the energy material, and can also be stored and / or transmitted via communication channels ...

Also, the stabilization of the parameters of the energetic material can be carried out by forced supply of inert gases, and / or forced supply of phlegmatizing materials, and / or forced supply of water into the volume of the container.

The unloading of the energy material from the container can be carried out continuously and dosed or according to a given technological algorithm and dosed. In this case, the continuous unloading of the energy material from the container can be carried out in the amount necessary for the direct operation of the production cycle or the chemical reaction provided for by the operation of the production cycle. And the unloading of energy material from the container according to a given algorithm can be carried out in volumes and with a frequency, subordinate to the algorithm of the production cycle operation, and necessary for carrying out the specified steps of the production cycle operation or chemical reactions provided for by the production cycle operation.

The specified technical result is achieved with the help of a container for the safe handling of energetic materials, including a container for energetic material, an element for loading energetic material, an element for monitoring the permissible state parameters of the loaded energetic material, an element for stabilizing the parameters of an energetic material in the container when they deviate from the permissible parameters , an element for unloading energy material from a container, a control element. According to the claimed solution, the element for unloading the energetic material from the container is configured to unload the energetic material from the container into the receiving element of the device provided for by the operation of the production cycle, and with the possibility of blocking the unloading of the energetic material in case of deviation of the state parameters of the loaded energetic material from the permissible ones, while the element for control of the permissible parameters of the state of the loaded energetic material is made with the ability to control the parameters of the energetic material at the time of use of the energetic material by the device provided for the operation of the production cycle, and the element for stabilizing the parameters of the energetic material in the container is configured to stabilize the parameters of the energetic material in the event of their deviation from the permissible parameters in the moment when the energy material is used by the device provided for by the production cycle operation.

As an element for loading the energetic material, a cover, or a manhole, or a pipe connection can be used.

In this case, at least one gas analyzer-detector based on MIS sensors (metal-dielectric-semiconductor), and / or a high-frequency (piezoelectric) detector, and / or at least one temperature sensor and / or at least one pressure sensor and / or at least one vibration sensor.

In addition, at least one container with an inert gas equipped with a supply system and / or at least one container with phlegmatizing material equipped with a supply system can be used as an element for stabilizing the parameters of the energetic material in the volume of the container when they deviate from the permissible parameters. and / or at least one water tank equipped with a supply system.

Whereas, a device for unloading bulk cargo, or a device for unloading liquid cargo, or a device for unloading gaseous cargo can be used as an element for unloading energy material from a container.

Also, the element for loading the energetic material and the element for unloading the energetic material from the container can be made as one device.

In addition, a mixer or a reactor can be used as a device provided for a production cycle operation.

In this case, the container may include an access control element in the volume of the container, an element for controlling the unloading of energy material, an element for controlling the location of the container.

The control element can be made in the form of an internal and / or external control element, while a controller can be used as an internal element, and a controller of a device provided for an operation of a production cycle, or an enterprise security system controller, or a control panel controller can be used as an external element. ... And the control element can be equipped with an internal and / or external power supply. In this case, the container can include a communication element made with the ability to transmit information to an external control element from an element for monitoring the permissible parameters of the state of the loaded energy material, an access control element to the container volume, an element for controlling the unloading of energy material and an element for controlling the location of the container, as well as with the ability to receive information from the external control element to control the element for stabilizing the parameters of the energetic material in the container when they deviate from the permissible parameters, the element for unloading the energetic material and the element for loading the energetic material.

Advantageously, the container includes a load frame to prevent damage to the container and elements.

In contrast to the closest analogue, the above method and device (container) are used not only for storage and transportation of energy material, but also in the direct operation of the production cycle to supply energy material to a mixer or reactor. In addition, they carry out continuous-cyclic (constant) monitoring of the state of the energy material not only in order to track emergency situations, but also control the impact (unregulated impact), which leads to a gradual accumulation and increase in the proportion of defects in energy materials that worsen its quality. In addition, in the event of an impact (unregulated impact) or several impacts that do not lead to an emergency situation (explosion, fire, smoke, etc.), but worsen the required (design) quality of the energy material, in contrast to the closest analogue, automatic blocking is carried out unloading energy material from the container.

Implementation of the invention

The proposed invention is illustrated by a specific method of safe handling of energy materials and a container for the safe handling of energy materials, however, the examples given are not the only possible ones, but clearly demonstrate the possibility of achieving these sets of essential features of the claimed technical result.

A method for the safe handling of energy materials includes loading ammonium perchlorate (hereinafter referred to as AP) (energetic material) into a container, constant monitoring of the permissible parameters of the AP state, stabilization of AP parameters in the container when they deviate from the permissible parameters, transportation of AP in a container, storage of AP in a container. , unloading the PHA from the container. In this case, the unloading of PHA from the container is carried out directly in the required time and according to the purpose of the operation of mixing inert and active materials (operations of the production cycle): loading of aluminum grade ASD-6, energy materials PHA and HMX, as well as the hardener EKh-1 into the polymer matrix ( inert, active or azide polymers), based on rubber of the SUREEL type and transformer oil, while monitoring the permissible parameters of the state of the PCA loaded into the container, which is influenced by the environment of the production cycle, and in case of deviation from the permissible parameters, the parameters of the PCA are stabilized or blocking of PHA unloading is performed.

The permissible parameters of the state of the energy material loaded into the container are determined by the manufacturer of the energy material together with the enterprise-consumer of the energy material. At the same time, these parameters are determined for each model of container use, including when used directly in the operation of the production cycle, storage of energy material and its transportation, including parameters of unregulated exposure (effects), after which the energy material should not be used in production as a result of deterioration its quality, as well as critical parameters (high-frequency influences, temperature, pressure, the presence of nitrogen dioxide or carbon monoxide in the container), when exceeded, the stabilization of parameters is automatically activated to protect against emergency situations (explosion, fire, smoke, etc.).

After loading the AP into the container, access control to the volume of the container is carried out throughout the life cycle of the AP in the container. Thus, access control to the container volume is necessary to record cases of unregulated exposure to the AP or the internal atmosphere of the container by external factors - light, moisture, pressure, vibration, etc., leading to a deterioration in the quality of the final product. Also, after loading the PHA into the container, control over the unloading of the PHA and control the location of the container in order to control unregulated unloading and the place of use.

At the same time, at all stages of the life cycle of AP in the container, the permissible parameters of the state of the loaded AP are monitored, including monitoring of high-frequency effects, temperature, pressure, as well as the presence in the container volume of primary gaseous decomposition products of energetic materials - nitrogen dioxide and / or nitrogen oxide. and / or hydrogen and / or ammonia and / or chlorine ion and / or carbon monoxide.

Information about any attempt of unauthorized access, about the unloading of energy material, about the location of the container and about the parameters of the state of the loaded energy material is used when making a decision on stabilization (automatic stabilization) of the parameters of the energy material or blocking (automatic blocking) of the unloading of the energy material, and is also stored and transmitted through communication channels.

Also, through communication channels, signals are received to carry out forced stabilization of the parameters of the energy material, in the event of an unregulated impact on the AP or the internal atmosphere of the container, which can lead to a deterioration in the quality of the final product or an emergency situation (explosion, fire, smoke, etc.), or to block the unloading of PHA, in the event of a transferred unregulated impact (effects), after which the energy material should not be used in production, since its design qualities have deteriorated or an emergency situation (explosion, fire, smoke, etc.) is possible.

Thanks to the guaranteed stabilization of the parameters of the energetic material, the enterprise-user of the energetic material can integrate the container directly into the operation of the production cycle and exclude such operations with the energetic material as the repackaging of energetic materials into dosing devices / systems or containers for further use in production, the transfer of the selected amount of energetic materials through the shop / enterprise, storage of the selected amount of energy material in the workshop / production site. In addition, the user enterprise can eliminate the need for sampling for further research, since the quality of the energy material, which was affected by the environment, at each stage of the life cycle of the container with the energy material, is guaranteed immediately before the use of the energy material in the operation of the production cycle, and in the case, if the energetic material was subjected to unregulated exposure (s), after which (which) the energetic material should not be used in production, then the unloading of the energetic material is blocked.

In case of fixing a case of unregulated exposure to AP or the internal atmosphere of the container by external factors - light, moisture, pressure, vibration, etc., which, with further exposure, can lead to a deterioration in the quality of the final product or an emergency situation (explosion, fire, smoke, etc.) etc.), the parameters of the AP are stabilized by the forced supply of inert gases. In addition, together with the forced supply of inert gases or instead of it, the forced supply of phlegmatizing materials or the forced supply of water can be used.

Unloading of PHA from the container is carried out continuously and dosed in the volume required for the direct operation of the production cycle - mixing. In addition, with respect to other energy materials, it is possible to unload according to a given technological algorithm and dosed, which is carried out in volumes and at intervals, subordinate to the algorithm of the production cycle operation, and necessary for carrying out the specified steps of the production cycle operation or chemical reactions provided for by the production cycle operation.

The container for the safe handling of energy materials includes a container for AP, an element for loading AP, which is used as a lid, an element for monitoring the permissible state parameters of the loaded AP, which is used as a gas analyzer-detector based on MIS sensors (Metal-Dielectric-Semiconductor "), Also called a microelectronic gas capacitive sensor based on a sensor with the MDP structure (" Metal-Dielectric-Conductor "), which allows detecting the target products of thermal decomposition of an energetic material (nitrogen dioxide, nitrogen oxide, hydrogen, ammonia, chlorine ion or oxide carbon), a high-frequency (piezoelectric) detector, a temperature sensor, a pressure sensor, an element for stabilizing the parameters of AP in the container when they deviate from the permissible parameters, which are used as a container with an inert gas equipped with a feeding system and a container with phlegmatizing material equipped with a system feed, element for unloading of PHA from a container, which is used as a device for unloading bulk cargo, an internal control element, which is used as a controller. In this case, the element for unloading the AP from the container is made with the possibility of unloading the AP from the container into the receiving element of the device provided for by the operation of the production cycle - the mixer, and with the possibility of blocking the unloading of AP in case of deviation of the state parameters of the loaded AP from the permissible ones. Also, an element for monitoring the permissible parameters of the state of the loaded AP is made with the ability to control the parameters of AP at the time of using the energy material by the mixer. In addition, to stabilize the parameters of the AP, the container is made with the possibility of stabilizing the parameters of the AP in the event of their deviation from the permissible parameters at the time of using the AP with the mixer.

In this case, instead of a cover, a hatch or a pipe connection can be used as an element for loading energy material, and instead of a device for unloading bulk cargo, a device for unloading energy material from a container can be used as an element for unloading a liquid cargo, or a device for unloading gaseous cargo, which is chosen based on the state of the used energetic material - powder, liquid, gaseous. Also, the element for loading the energetic material and the element for unloading the energetic material from the container can be made in the form of one device, such a combination ensures a decrease in the number of elements of the container and does not complicate its design.

Also, the number of sensors and detectors used as an element for monitoring the permissible parameters of the state of the loaded energy material is selected based on their sensitivity and container dimensions, as well as the reliability requirements for the project.

In addition, the number of these devices used as an element to stabilize the parameters of the energetic material in the container when they deviate from the permissible parameters can be selected based on their properties of the energetic material, the design amount of the material used, as well as the reliability requirements for the project. At the same time, in addition to the indicated devices used as an element to stabilize the parameters of the energetic material in the container when they deviate from the permissible parameters, a container with water equipped with a supply system can be used.

In addition, instead of a mixer, a reactor can be used as a device provided for the operation of the production cycle, which is determined based on the design.

The container includes an access control element in the volume of the container, which is used as a reed switch, and any of the available mechanical, electromechanical or electronic devices can be used to signal the opening of the container. At the same time, the container may not have an element of access control to the container volume, in this case, the user enterprise independently controls the restriction of personnel access to the container volume.

Also, the container includes a control element for unloading energy material, which is used as a dispenser for bulk substances. In this case, the container may not have an element for controlling the unloading of the energy material, in this case, the control element for the unloading of the energy material can be installed in the receiving element of the device provided for by the operation of the production cycle, or the energy material can be taken into account by selecting the flow section of the element for unloading the energy material from the container ...

In addition, the container includes an element for monitoring the location of the container, which is used as a satellite navigation system GPS and GLONASS. At the same time, the container may not have a location control element, in which case the location of the container is controlled by the structures of the manufacturer and the user enterprise.

The control element is connected and receives information (signals) from the element to control the permissible state parameters of the loaded energy material, the access control element to the container volume, the control element for the unloading of the energy material and the container location control element. In addition, the control element is connected and gives control commands to the element to stabilize the parameters of the energetic material in the container when they deviate from the permissible parameters, to the element for unloading the energetic material to block the unloading of the energetic material in case of deviation of the state parameters of the loaded energetic material from the permissible ones and to the element for loading the energetic material. material. In addition, the control is connected to a communication element with the ability to send and receive commands from an external control. In this case, the control element can be functionally executed together with the controller of one of the elements installed in the container, or the controller functions can be programmed (executed), in each of the elements installed in the container, or the functions of the internal controller can be performed by external (external) controllers, in which can be used as the controller of the device provided by the operation of the production cycle, or the controller of the security system of the enterprise, or the controller of the control panel.

In addition, the internal control element is equipped with an internal power source, which is a rechargeable battery, and, if necessary, can be equipped with an external power source from a device provided for the operation of the production cycle or from the power system of the enterprise.

In this case, the container includes a communication element made with the ability to transmit information to an external control element from an element for monitoring the permissible state parameters of the loaded energy material, an access control element to the container volume, an element for controlling the unloading of energy material and a container location control element, and is also configured to receive information from the external control element to control the element for stabilizing the parameters of the energetic material in the container when they deviate from the permissible parameters, the element for unloading the energetic material and the element for loading the energetic material. In this case, the container may not be equipped with a communication element, in which case the internal control element is programmed to perform the required actions in the event of an unregulated impact on the AP or the internal atmosphere of the container or an emergency situation (explosion, fire, smoke, etc.).

The container includes a load-bearing frame made of metal to prevent damage to the container and elements. In addition, various polymeric materials and / or composite materials can be used instead of metal.

Claims (8)

1. A method for the safe handling of energy materials, including loading the energy material into a container, constant monitoring of the permissible parameters of the state of the loaded energy material, stabilization of the parameters of the energy material in the container when they deviate from the permissible parameters, transportation of the energy material in the container, storage of the energy material in the container, unloading of the energy material from the container, characterized in that the unloading of the energy material from the container is carried out directly at the required time and according to the purpose of the operation of the production cycle, while monitoring the permissible parameters of the state of the energy material loaded into the container, which is influenced by the environment of the operation of the production cycle , and in case of deviation from the permissible parameters, the parameters of the energy material are stabilized or the unloading of the en ergic material. 2. The method according to claim 1, characterized in that after loading the energy material into the container, access control to the container volume, control of the unloading of the energy material, and control of the container location are carried out. 3. The method according to claim 1, characterized in that the control of the permissible parameters of the state of the loaded energetic material includes the control of high-frequency influences and / or temperature and / or pressure, as well as the presence in the volume of the container of primary gaseous decomposition products of energetic materials - nitrogen dioxide, and / or nitrogen oxide and / or hydrogen and / or ammonia and / or chlorine ion and / or carbon monoxide. 4. A method according to any one of claims. 2, 3, characterized in that information on any attempt of unauthorized access and unloading of energy material, on the location of the container and on the parameters of the state of the loaded energy material is used when deciding whether to stabilize the parameters of the energy material or block the unloading of the energy material, and is also stored and / or transmitted over communication channels. 5. A method according to claim 1, characterized in that the parameters of the energetic material are stabilized by forced supply of inert gases, and / or forced supply of phlegmatizing materials, and / or forced supply of water into the volume of the container. 6. The method according to claim. 1, characterized in that the unloading of the energy material from the container is carried out continuously and dosed or according to a given technological algorithm and dosed. 7. The method according to claim 7, characterized in that the continuous unloading of the energy material from the container is carried out in the volume necessary for the direct operation of the production cycle or the chemical reaction provided for by the operation of the production cycle. 8. The method according to claim 7, characterized in that the unloading of the energy material from the container according to a given algorithm is carried out in volumes and at intervals, subordinate to the algorithm of the production cycle operation and necessary for carrying out the specified steps of the production cycle operation or chemical reactions provided for by the production cycle operation.