RU2142837C1 - Powder fire-extinguishing module - Google Patents

Abstract

FIELD: fire- extinguishing facilities, particularly, self-acting or acting by external signals powder fire extinguishers. SUBSTANCE: module has body filled with fire-extinguishing powder, gas generating substance and device for initiation of gas-generating substance and heat sensitive element attached to body wall for forced initiation of gas-generating substance from external heat flux and provision of self-operation of module. Gas- generating substance and fire-extinguishing powder occupy volume amounting to more than 99% of total volume of body sealed cavity. Module also has power-storing or supplying element, device for formation of command for operation of module and container sealed from ambient medium and secured to body wall. Container accommodates gas-generating substance and initiating device connected with power- storing or supplying elements and device for formation of command for operation of module. Heat-sensitive element is connected with initiating device and/or gas-generating substance, and /or device for formation of command for operation of module. Power-storing or supplying element and device for formation of command for operation of module are connected to stationary system of fire extinguishing and/or to some other module for formation of electric pulse for initiation of gas formation. Container cavity is connected with body cavity for discharge of gases from container into free volume of body cavity. Walls of, at least, one part of body made with parts of weakened section or body weakened material for guaranteed opening of body. Body has bracket mounted for suspension and attachment of powder module. EFFECT: provision of local and/or volume mass one-time dispersed ejection of fire- extinguishing powder into zone of fire seat. 17 cl, 13 dwg

Description

 The invention relates to fire extinguishing means, namely, powder fire extinguishers, self-driving or triggered by an external signal, which is a separate independent module that can be used as a component of automatic powder fire extinguishing systems designed to extinguish fires in industrial, warehouse, administrative and other premises, as well as in local autonomous fire extinguishing installations. The proposed fire extinguisher in the form of a module in the version of self-operation can be used as a separate fire extinguishing independent unit for installation in rooms not connected to a stationary fire extinguishing system.

 Fires in such premises are developing rapidly and lead to the complete destruction of material assets. The use of automatic water, foam or gas fire extinguishing installations in these rooms is not always possible according to the process conditions, sanitary and hygiene requirements, causing great indirect damage or economic costs when these installations are triggered.

 In this regard, the creation of a powder fire extinguisher, self-generating type or triggered by an external initiating signal with a large radius of effective action with a minimum inertia of response and high speed of delivery of the extinguishing powder to the fire, is a modern urgent task to ensure fire extinguishing when causing the least possible damage to people and property . This problem should be solved both with local surface and volume quenching.

 A fire extinguisher module of a stationary fire extinguishing system suspended from the ceiling of the room is known, comprising a body made of fire-resistant plastic, a fire extinguishing composition is placed inside the hermetic cavity, an initiating device in the form of an explosive charge, connected to a thermal sensor system to initiate an explosive charge, and a wick isolated in the center the capacity of the fire extinguishing composition occupies almost the entire volume of the sealed cavity of the housing (EP, 0483901, A 62 C 35/08, publ. 06.05.92).

 The operation of this well-known fire extinguisher, which is a module by the principle of its action and the possibility of working as part of a stationary fire extinguishing system, is carried out by a signal from thermal sensors that are activated by a flame from the outside of the tank. The disadvantage of this fire extinguisher is that it provides only local, strictly directed extinguishing, which is accompanied by a reduced speed of delivery of the fire extinguishing composition and low costs due to the narrow throat for the exit of the powder.

 Another serious drawback is that an explosive charge containing an explosive substance triggered by a wick ignited by a flame is used as an initiating device (for this, the wick is wound from the outside of the case and introduced into the explosive charge). Such a solution, unsafe from the point of view of using explosives, among other things, requires constant monitoring of the wick, as an element on which the operation of a fire extinguisher depends.

 A powder module is known that is used as an independent working unit or as part of a stationary fire extinguishing system, comprising a body made of metal, consisting of two parts that are rigidly connected to each other and inside which there is a fire extinguishing powder, a gas generating substance and an initiating device connected to an alarm system for forced initiation of a gas-generating substance upon receipt of an electrical impulse, or made self-triggering for initiations Nia gas generating substance by the heat of the fire stream, wherein the gas generating agent and the extinguishing powder occupy a volume of not more than 99% of the total volume of the sealed cavity of the housing (RU, 2082472, A 62 C 35/10, publ. 06.27.97).

 The well-known powder module, made according to the embodiment, self-generating, provides a quick response to the heat of the fire caused by heat sensors and coating the body with a high degree of blackness, and also allows you to provide both directional protection sector (emission of fire extinguishing powder) and volume quenching.

 The discharge of the extinguishing powder in this extinguisher is ensured by creating excessive pressure inside the casing, which leads to the opening of the casing along the grooves made on its walls and the formation of a wide passage.

 However, this powder module has serious drawbacks.

 The first serious drawback is that the passage in the casing for the extinguishing powder is made in the form of petals connected by profiled grooves. This leads to the fact that a sharp increase in pressure inside the housing in a limited volume can lead to untimely (i.e., early, premature) opening of the petals. As a result of this, instead of a powerful discharge of powder, the latter will spill out through the slightly opened petals. This is because, as shown in FIG. 5 of this patent, all the petals with their vertices converge in a common zone, which is the most weakened compared to the material and the thickness of the petals themselves at the site of their bases. This configuration of the petal shutter, as a rule, is used only in cases where it is necessary to neutralize a possible increase in pressure inside the tank, and does not provide for the use of this shutter as a retarding element. If it is used in the latter version, it is necessary to equalize the resistance of the zones of the plot of the tops of the petals and the zones of the plot of their bases. Fulfillment of these conditions leads to a significant complication of the design of the fire extinguisher body and deprives it of such an important property as ease of manufacture and manufacturability.

 The second serious drawback is that the initiating substance is fixed inside the body at its bottom. It is known that in fire extinguishers, any initiating substance loses its properties over time. Therefore, it should be periodically replaced with a new one in order to maintain the fire extinguisher for a long time in working condition, which provides for self-operation. The fixing of the initiating substance at the bottom of the casing under conditions when it is covered with a fire extinguishing powder leads to the need for a periodic complete change of one fire extinguisher to another, new. In this case, one of the conditions for the long-term reliability of the fire extinguishing system elements is violated. The constant complete change or replacement of the working units of the fire extinguishing system complicates and increases the cost of servicing the system itself and increases the likelihood of its failure or the probability of failure of any working unit.

 The indicated drawbacks are also inherent in the powder module connected in the embodiment to the alarm system for forced initiation of a gas-generating substance upon receipt of an electrical impulse.

 The present invention is aimed at solving the following technical problems: while maintaining all the positive properties of the known powder module, place the gas-generating substance and the initiating device in a separate container, which must be fixed in the housing or on the housing in order to ensure the possibility of replacing them without replacing the module in as a whole, and also to provide local and / or volumetric mass, volley, dispersed release of extinguishing powder into the zone of the fire source due to the fact that the body must be made with derogation from the cross section or material areas.

 The technical result achieved in this case is to increase the operational reliability and fire extinguishing efficiency by providing the possibility of simultaneous operation of a group of modules in a protected room or volume and the implementation of a powerful ejection pulse and high speed of fire extinguishing powder delivery to the fire source.

 The specified technical result is achieved in that the powder fire extinguishing module containing a housing, inside the airtight cavity of which a fire extinguishing powder, a gas-generating substance and an initiating device for initiating a gas-generating substance are placed, as well as a heat-sensitive element fixed to the surface of the walls of the housing for forcing the gas-generating substance to be forced from an external thermal flow and ensure self-operation of the module, while the gas-generating substance and extinguishing pores the bucket occupies a volume of not more than 99% of the total volume of the sealed cavity of the body, characterized in that it is equipped with an energy storage or supply element, a device for generating a command to activate the module and the container, with the possibility of sealing it to the environment being fixed on the walls of the body, inside the container a gas generating substance and an initiating device associated with an energy storage element or a feeding element and a device for generating a command for activating the module, thermosensitive The first element is connected with the initiating device and / or with the gas generating substance and / or with the device for generating the command for activating the module, while the energy-storage element or power element, the device for generating the command for activating the module are connected to a stationary fire extinguishing system and / or to another module to form an electric pulse to initiate gas generation, the cavity of the container is in communication with the cavity of the housing to release gases from the container into the free volume of the cavity of the housing, while the walls and at least one part of the casing is made with sections of weakened cross-section or weakened casing material for guaranteed opening of the casing and volumetric and / or local surface extinguishing of the fire due to the release of fire extinguishing powder with increasing gas pressure in the cavity of the module casing, and a bracket for pendant is mounted on the casing installation and fastening of the powder module.

 In this case, the housing may be made of at least two interconnected parts or as one integral hollow part, in which at least a portion of the container is placed inside the cavity of the housing or the container is completely placed inside the cavity of the housing, or the container is completely placed outside the housing and secured On him.

 The container can be made in the form of a glass, hermetically sealed with a lid and the bottom of which, facing the inside of the body, is made flat, or cone-shaped, or spherical and can be made integrally with the body or with one of its parts, and the body can be made with hermetically sealed technological window for filling the extinguishing powder into the cavity of the housing.

 The container can be removably fixed in the hole of one of the parts of the housing, intended for filling the extinguishing powder into the cavity of the housing due to a threaded connection, or a bolted connection, or a bayonet connection or any other detachable connection.

 The housing can be made in the form of a sphere, or a hemisphere, or a cylinder, or a pyramid, or a parallelepiped, or is made conical or trough-shaped with walls with a thickness of 0.13 to 5.0 mm.

 For the formation of a sealed cavity, the parts of the body are interconnected by welding or a detachable ring-shaped cross-sectional ring covering the flanges of the parts of the body, or any other connection ensuring its tightness.

 The housing is made of metal, plastic or polymer, while parts of the housing can be made of the same material or of different materials.

 The bracket is mounted on the container or runs in one piece with it.

 The above features are essential with the formation of a stable set of essential features sufficient to achieve the desired technical result.

 So, placing the gas-generating substance and the initiating device in a separate container sealed with a lid allows you to replace the substance after its expiration date, or to replace the container with the contents completely, without having to replace the module as a whole or completely disassemble it, to conduct a technological inspection of the initiating unit.

 The implementation of the housing as a whole or at least one of its parts with sections of a weakened wall section or weakened wall material allows for guaranteed opening of the housing for volumetric and / or directional discharge of extinguishing powder with increasing gas pressure in the cavity of the module housing. By weakened wall cross section it is understood that some sections of the walls have a thickness substantially less than the thickness of the remaining sections of the walls of the housing. And under the sections of the walls of the weakened material refers to a change in the properties of the material of the walls. For example, if the walls are made of metal from sheet steel, then high-frequency currents or high-temperature heating release the material of the walls in some sections, as a result of which the rupture of these sections occurs at a pressure substantially lower than the pressure necessary to break the walls on the rest not subjected to tempering plots. Thus, it is possible to obtain a housing in which the gap in the walls will occur along the lines of weakened section. It is possible that as sections of the weakened material, a material different in composition and nature, for example, polymer, can be used. In this case, the housing is made combined of metal and polymer inserts, opening or breaking with increasing pressure inside the housing.

 The implementation of the sections of the weakened section of the walls with the same properties over the area of the plot (for example, according to the burst resistance) allows us to guarantee a temporary delay in the break of weakened sections of the walls of the body when the pressure inside the housing increases. This allows you to adjust the force of the discharge of the extinguishing powder and to exclude the involuntary opening of the housing at the initial moment of pressure formation. The creation of a certain initial internal increased pressure allows a powerful dispersed volley release to a large area. Powerful instant coverage of a large area with a fire extinguishing powder allows you to guarantee the localization of the fire source and adjacent areas.

 At the same time, an increase in the zones of wall rupture makes it possible to increase the reliability of operation of the fire extinguisher module, even if some of the weakened sections of the housing are not disclosed for any reason (for example, failure to fulfill the condition of equal strength).

 The equipment of the module with a heat-sensitive element, a device for generating a command to activate the module and an energy storage or supply element allows it to be used as a self-operating separate fire extinguishing unit or in closed autonomous fire extinguishing systems or in automatic powder fire extinguishing installations.

 The present invention is illustrated by specific examples, which, however, are not the only possible, but clearly demonstrate the ability to achieve the specified set of features of the desired technical result.

In FIG. 1 - powder module, longitudinal section;
in FIG. 2 is an exemplary embodiment of the module case of FIG. 1 in the form of a single hollow part, a longitudinal section;
in FIG. 3 is a longitudinal section of the wall of the housing;
in FIG. 4 is a section AA in FIG. 3, the first example of execution;
in FIG. 5 is a section AA in FIG. 3, a second example of execution;
in FIG. 6 - node I of FIG. 1, with an increase;
in FIG. 7 is a first example of a container;
in FIG. 8 is a second example of a container;
in FIG. 9 is a third example of a container;
in FIG. 10 is an example of the location of the container inside the housing;
in FIG. 11 - location and securing of the container outside the housing;
in FIG. 12 is a diagram of a connection of modules into a closed autonomous fire extinguishing system;
in FIG. 13 is a diagram of connecting modules to a stationary fire extinguishing system.

 The powder module (see Fig. 1), intended for use as both an integral element of powder fire extinguishing installations, and as an independent fire extinguishing unit, contains a housing made of at least two 1 and 2 parts that are rigidly and hermetically connected to each other with the formation of an internal sealed cavity. In this case, the upper disposable part of the housing may be a lid with respect to the lower disposable part of the housing.

 The case can be made of sheet metal or sheet metal tape (steel, aluminum, aluminum and duralumin alloys, the tape can be made of aluminum, zinc, copper, titanium, nickel, stainless steel), plastic, polymeric materials, or a combination of these materials. Parts of the casing may be made of the same material, or at least one part of the casing may be made of a material different from the material of the other part or other parts. Preferably, the walls of the housing parts are made with a thickness of 0.13 to 5.0 mm.

 For the formation of a tight cavity inside the housing, the housing parts can be connected to each other along the perimeter of their flanges by welding or a split ring-shaped cross-sectional cross-section 3, covering the adjacent flanges of the housing parts 1 and 2 (Fig. 1 and 6), or any other connection, providing tightness of the case. Inside the case there is a fire extinguishing powder 4. The siols decomposing upon heating with evolution of gases are used as this powder: pyrant A (TU 301-11-10-90) or PSB-3 (TU 6-18-139-83) and others.

 The housing can be made in the form of one integral hollow part, as shown in FIG. 2.

 The housing is made with walls having sections of weakened section (Fig. 3-5) or weakened material. This design allows for a shatter-free opening of the body (tearing its walls along the weakened areas) for ejecting the extinguishing powder into the zone of the fire source. The sections of the weakened section are made with strength over the entire area of these sections, less than the strength of the walls of the body in the remaining sections, or sections of the weakened material are made with tensile strength over the entire area of these sections, less than the tensile strength of the walls of the body in the remaining sections of the body.

 Under the weakened section of the walls is understood, for example, the execution of grooves, notches, recesses 5 on the outer side (Fig. 4) of the housing or on the inner side of the housing (Fig. 5). As a result of this, some sections of the walls have a thickness substantially less than the thickness of the remaining sections of the walls of the housing. For example, the weakening of the cross section can be provided by incision of the material of the walls of the housing.

 And under the sections of the walls of the weakened material refers to a change in the properties of the material of the walls. For example, if the walls are made of metal from sheet steel, then high-frequency currents or high-temperature heating release the material of the walls in some sections of the housing, for example, along vertically extended lines, as a result of which the rupture of these sections occurs along these lines at a pressure substantially lower than the pressure to break the walls in other areas not subject to tempering.

 Thus, it is possible to obtain a housing in which the gap in the walls will occur along the lines of weakened section. It is possible that as sections of the weakened material, a material different in composition and nature, for example, polymer, can be used. In this case, the casing is made of a combination of, for example, metal inserts forming the frame of the casing and polymer inserts located between the metal and connected to the latter. In this case, polymer inserts, which may differ in thickness from metal ones, open or break with increasing pressure inside the housing.

 The implementation of the sections of the weakened section of the walls with the same properties over the area of the plot (for example, according to the burst resistance) allows us to guarantee a temporary delay in the break of weakened sections of the walls of the body when the pressure inside the housing increases. This allows you to adjust the discharge head of the extinguishing powder and to exclude the involuntary opening of the housing at the initial moment of pressure formation. The creation of a certain initial internal increased pressure allows a powerful dispersed volley release to a large area. Powerful instant coverage of a large area with a fire extinguishing powder allows you to guarantee the localization of the fire source and adjacent areas.

 The main condition is the implementation of sections of weakened cross section with strength over the entire area of these sections, less wall strength in the remaining sections, and sections of weakened material with tensile strength over the entire area of these sections, less than the tear resistance of the walls of the body in the remaining sections of the body.

 At the same time, an increase in the zones of wall rupture makes it possible to increase the reliability of operation of the fire extinguisher module, even if some of the weakened sections of the housing are not disclosed for any reason (for example, failure to fulfill the condition of equal strength). This eliminates the presence of fragments.

 The powder module is equipped with a container 6, with the possibility of sealing it to the environment fixed on one of the parts of the housing with the placement of at least part of the container inside the cavity of the housing. The container is made in the form of a glass, hermetically sealed with a lid 7, removably fixed in the hole of one of the parts of the casing, intended for filling the extinguishing powder into the cavity of the casing. Removable fastening refers to a threaded connection, or a bolted connection, or a bayonet connection, or any other detachable connection. This allows the container to be installed in the housing and secured there using any of the above methods.

 The container 6 can be made integral with one of the parts of the housing (an example is not illustrated), and the housing is made with a hermetically sealed technological window for filling the extinguishing powder into the cavity of the housing.

 A gas-generating substance 8 and an initiating device 9 are located inside the container. The initiating device 9 and / or the gas-generating substance is connected to a heat-sensitive element 10, which is fixed to the wall surface / body of the housing. The connection of the heat-sensitive element with the initiating device and / or gas-generating substance may be different.

 At least one hole 11 is made in the walls of the container 6 located inside the housing for the release of inert gases resulting from the initiation into the volume of the cavity of the housing. The hole / s can be made in the side walls and / or in the bottom of the container. The number of openings from one or more is determined from the condition of free release of gases from the container cavity into the body cavity and providing a sharp increase in pressure in the body cavity.

 The container 6 can be made in the form of a glass, hermetically sealed with a lid and the bottom of which, facing the inside of the housing, is made flat (Fig. 7), or conical (Fig. 8), or sphere-shaped (Fig. 9).

 The container can be completely placed inside the cavity of the casing (Fig. 10) or the container is completely placed outside the casing and secured to it (Fig. 11). In the last example of the location of the container in the walls of the housing, openings 12 are made to ensure that the container cavity communicates with the body cavity.

 The gas-generating substance and the extinguishing powder occupy a volume of not more than 99% of the total volume of the sealed cavity of the body. Filling the powder module casing with no more than 99% of the total cavity volume ensures the presence of free volume inside the casing, which, with increasing gas pressure, leads to a higher potential energy reserve for intense powerful powder discharge. Filling the casing with fire extinguishing powder by less than 70% of its volume leads to an unreasonable decrease in the amount of fire extinguishing powder in the module, and, therefore, negatively affects almost all the main characteristics that provide extinguishing the fire.

 Extinguishing powder is poured into the body through an opening in which the container is then fixed. According to another example of execution, the container is made integrally with one of the parts of the housing, and the housing is made with a hermetically sealed technological window for filling the extinguishing powder into the cavity of the housing. The technological window, closed hermetically by a lid, can be made on the housing in any place convenient for the production of filling of extinguishing powder into the cavity of the housing.

 It is possible to execute a container, according to which a hole is made in the bottom of the container through which, without removing the container from the housing, it is possible to fill the extinguishing powder into the cavity of the housing. This opening may be closed by a separate lid or not closed at all, but serve as an additional opening for the passage of inert gases into the cavity of the housing.

 A bracket (not shown) is mounted on the module case to enable hanging installation and attachment of the powder module to the ceiling of the room. The bracket may be rigidly or pivotally mounted to the housing or container. This design allows, having given the module, for example, a spherical or spherical shape, to make it similar in appearance to lighting shades and place it in a row of suspended lighting fixtures. By changing the shape of the fire extinguisher and masking in appearance with objects common to human perception, you can organically fit a fire extinguisher as a working fire unit in almost any environment.

 The bracket can be mounted on the container or be made in one piece with it. For example, the container lid of FIG. 1 can be made with fasteners to the ceiling of the room.

 As a gas generating substance, any known blowing agent is used, for example, azodicarbonamide (TU 6-03-408-80) under the brand name 4x3-21 and others.

 The initiating device is made in the form of an electric heater or electric igniter. There is a device 13 for generating a command for activating the module and an energy storage or supply element 14. In this case, the energy storage or supply element 14 and device 13 can be connected to a stationary fire extinguishing system to generate an electrical impulse to initiate gas generation or to device 13 of a similar module. Make-up of the energy storage element and the issuance of an impulse for the operation of the unit (pos. 13 and 14) can be carried out from a stationary fire extinguishing system.

 As an energy storage element, you can use any electric storage device, for example, a capacitor type or a rechargeable battery. And you can use a battery as a power supply.

 As a device for generating a response command, any relay switch can be used that provides switching of circuits from one operating mode to another using an external signal. An external signal is understood as address control of module activation. In practice, it looks like this: in the presence of a large number of modules connected to a common bus, located in different rooms, it is advisable to turn on not all the modules from the control panel, but only those that need to be used to extinguish the fire. Address management allows this to be implemented. In our case, the relay switch operates in two modes. The first is that the "stationary fire extinguishing system - energy storage element" circuit is connected, and the "energy storage element electric heater" circuit is disconnected. The second mode is that the circuit "stationary fire extinguishing system - energy storage element" is turned off, and the circuit "energy storage element - electric heater" is turned on.

 As an address-controlled device in the device 13 for generating a command for activating a module from among the known ones produced by industry, such an address-controlled device as an encoder-decoder K 1852 VZh1-0029 manufactured by NPO Physics or other similar devices, for example, RT-2262, can be used , MS-145026P, MM-53200N, 1806XH1-SD, 1806XH1-771.

 The variety of possible connections of the thermosensitive element with the initiating device and / or with the gas generating substance and / or with the device for generating the module operation command allows obtaining a whole family of applied modules based on the universal module. This feature of the powder fire extinguishing module allows it to work both in stand-alone operation mode and in forced operation mode, and the presence of device 13 in the module allows connecting a number of modules to each other and / or to a stationary fire extinguishing system with the formation of a closed autonomous fire extinguishing system, and with its control mode from a stationary fire extinguishing system.

 In FIG. 12 shows a diagram of the connection of modules into a closed autonomous fire extinguishing system. This circuit is built on the principle of connecting the output of the device 13 for generating a command to operate one module 17 to the input of a similar device 15 of another module 18, and the output of the device 16 for generating a command for actuating the last module 19 is connected to the input of a similar device 13 of the first module 17. In this case, when any of the modules is triggered by a signal from a heat-sensitive element, the device 13, 15 or 16 of this module gives a command to operate the neighboring module connected to it, which, when triggered, also issues a response command to the module connected to it. This process involves all modules included in a serial closed circuit.

 In FIG. 13 shows a diagram of the connection of modules with the connection of at least one of them to a stationary fire extinguishing system. The connection through the devices 13, 15, 16 of the modules 17, 18, 19 to the stationary fire extinguishing system allows forcing the modules to be triggered by an external signal not only from the heat source, but also from the system control panel.

 The powder module operates as follows.

 Upon receipt of an electrical signal (impulse) from the alarm system or under the action of the heat flux directly from the fire in the container 6, a chemical reaction of the gas-generating substance 8 begins with the release of inert gases entering through the opening (s) 11 of the container into the volume of the module casing. Under the influence of inert gases, aeration of the extinguishing powder 4 occurs inside the module housing.

 As the release of inert gases inside the housing, pressure begins to increase. Upon reaching a certain level of excess pressure, the walls of the body are torn in areas of weakened section or weakened material, and under the influence of excessive pressure, a volley of fire extinguishing powder is released into the protected volume. Fire extinguishing occurs.

 The present invention is industrially applicable, since its manufacture does not require special technology and special equipment, except for those that are used in the manufacture of fire fighting equipment or used in technological processes of manufacturing products in mechanical engineering.

Claims (17)

 1. A powder fire extinguishing module, comprising a housing, inside of the sealed cavity of which a fire extinguishing powder, a gas-generating substance and an initiating device for initiating a gas-generating substance are placed, as well as a heat-sensitive element mounted on the surface of the walls of the housing to force the gas-generating substance to be initiated from an external heat flow and to ensure self-operation of the module while gas-generating substance and extinguishing powder occupy a volume of not more than 99% of the total volume of the sealed cavity of the body, characterized in that it is equipped with an energy storage or supply element, a device for generating a command to activate the module and a container with the ability to seal it to the environment, fixed on the walls of the housing, a gas generating substance and an initiating device associated with the energy storage element are located inside the container or by a feeding element and a device for generating a command for activating the module, the heat-sensitive element is connected to the initiating device, and / whether with a gas-generating substance, and / or with a device for generating a command for activating a module, while the energy-storage element or power element, a device for generating a command for activating a module are connected to a stationary fire extinguishing system and / or to another module to generate an electric pulse to initiate gas generation, a cavity the container is in communication with the cavity of the housing for the release of gases from the container into the free volume of the cavity of the housing, while the walls of at least one part of the housing are made with parts of weakened cross-section or weakened material of the case for guaranteed opening of the case and volumetric and / or local surface fire extinguishing due to the release of extinguishing powder with increasing gas pressure in the cavity of the module housing, and an arm is mounted on the housing for suspended installation and fastening of the powder module.  2. The module according to claim 1, characterized in that the housing is made of at least two interconnected parts.  3. The module according to claim 1, characterized in that the housing is made in the form of one integral hollow part.  4. The module according to claim 1, characterized in that at least part of the container is placed inside the body cavity.  5. The module according to claim 1, characterized in that the container is completely placed inside the cavity of the housing.  6. The module according to p. 1, characterized in that the container is completely placed outside the housing and mounted on it.  7. The module according to claim 1, characterized in that the sections of the weakened section are made with strength over the entire area of these sections, less than the strength of the walls of the housing in the remaining sections.  8. The module according to claim 1, characterized in that the sections of the weakened material are made with tensile strength over the entire area of these sections, less than the tensile strength of the walls of the housing in the remaining sections of the housing.  9. The module according to any one of claims 1, 4 and 5, characterized in that the container is made in the form of a glass hermetically sealed with a lid, the bottom of which, facing the inside of the housing, is made flat, or conical, or sphere-shaped.  10. The module according to claim 1, characterized in that the container is made integrally with the housing or with one of its parts, and the housing is made with a hermetically sealed technological window for filling the extinguishing powder into the cavity of the housing.  11. The module according to claim 1, characterized in that the container is removably fixed in the hole of one of the parts of the housing, intended for filling the extinguishing powder into the cavity of the housing due to a threaded, or bolt, or bayonet connection, or any other detachable connection.  12. The module according to claim 1, characterized in that the housing is made in the form of a sphere, or a hemisphere, or a cylinder, or a pyramid, or a parallelepiped, or is made cone-shaped or trough-like.  13. The module according to claim 1, characterized in that the housing walls are made with a thickness of 0.13 - 5.0 mm.  14. The module according to claim 1 or 2, characterized in that for the formation of a sealed cavity parts of the housing are interconnected by welding or a detachable ring-shaped cross-section in cross-section, covering the flanges of the parts of the housing.  15. The module according to claim 1, characterized in that the housing is made of metal, plastic or polymer.  16. The module according to claim 1 or 2, characterized in that the housing parts are made of the same material or of different materials.  17. The module according to claim 1, characterized in that the bracket is mounted on the container or made in one piece with it.

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