RU2145375C1 - Pneumoframe quick-erected structure - Google Patents

Abstract

FIELD: pneumoframe large-area quick-erected structures suitable for temporary service in any climatic zones, in extreme conditions inclusive. SUBSTANCE: complex is featured by the fact that the pneumoframe quick-erected structure is additionally furnished with an independently installed block of equipment made in the form of a room-container with a foundation and walls, with a closing entrance, with operating and stand-by heaters mounted inside the room-container on the foundation, electric sets, switchboard and other devices of the system for maintaining the microclimate of the pneumoframe quick- erected structure and life support. The room- container has a space for accommodation of all packing cases of the pneumoframe quick-erected structure and of the set of packing cases of associated accessories while in transit. Attached outside the room-container in the lower part are appliances for its horizontal transportation by towing, and a gripper is attached in the upper part for its lifting. One of the walls of the room- container has manufacturing holes for exhaust of gases at operation of the Diesel-generators, and the other wall has manufacturing holes. The internal volume occupied by all the sets of the life support system by more than 5 times, it is less than the internal volume of the entire pneumoframe structure by more than 50 times, and exceeds the volume of the packing case of the pneumoframe sections by more than 5 times; the height of the room-container is not less than the anthropological height for a medium human-being. The volume in the room-container that is free of the mounted sets of the engineer life support is not less than 50% of the internal volume of the room-container and used for arrangement of the packing cases of the pneumoframe quick-erected structure sections in transit and creation of the servicing zone of sets for the personnel in service of developed pneumoframe quick-erected structure. EFFECT: enhanced load-carrying capacity, reliability and stability of the structure, improved aerodynamic indicators. 7 cl, 8 dwg

Description

 The invention relates to a temporary pre-fabricated pneumatic frame-sized large-area structures adapted for operation in any climatic zones, including in extreme conditions.

 The proposed pneumatic frame construction is intended for use mainly in the form of a regional complex of operational response of the Ministry of Emergency Situations, it also satisfies the conditions necessary for the rapid deployment of army headquarters for various military branches.

 Similar structures can be used for various other purposes, for example, as temporary barracks, administrative buildings to accommodate people with a temporary nature of work: geologists, oil workers, etc., equipment repair shops during repair work in the field, like storage rooms , exhibition halls, spectacular and sports facilities, as command posts of rescuers, degassing points (decontamination, disinfection) and in all other cases when it is necessary to quickly provide an ideal "roof over your head". Modern pneumatic frame prefabricated structures are also used in the armies of the USA, France, Germany and other countries, as well as in emergency departments of almost all countries of the world.

 Pneumatic frame constructions of a more extensive form are also widely used as field hospitals to provide emergency medical assistance to victims in the aftermath of natural disasters, accidents, catastrophes and in other emergency situations, including in remote places and remote areas. Such facilities are special mobile medical facilities, the structure of which includes, for example, blocks such as emergency room, ambulance, preoperative, surgical operating room, postoperative ward, intensive care unit, medicine warehouse, X-ray room, shower, toilets and other systems life support and creating a microclimate in the building (ventilation and heating equipment, lighting, etc.). In the same facilities are located not only the victims, but also the personnel of search and rescue services located in emergency zones, the headquarters of the Rescue Operation Department, etc.

 Inoperative, such structures are packed in light bales, convenient for transportation, including by air, and suitable for landing in emergency zones, for example, on cargo parachute platforms, and stored in warehouses.

 There are a number of designs of pneumatic frame structures that can be used for the above purposes, but each designed concrete structure of a pneumatic frame structure to one degree or another should take into account the specific features required to accomplish the tasks, sizes of areas and volumes of the structure, equipment, specific operating conditions, etc. .P.

 So, according to Italian patent N 563843 IPC A 45 F, the structure has a pneumatic frame, consisting of arches located in the planes of the cross-section of the structure and pneumatic bridges and supporting cylinders connecting them located in the planes of the longitudinal section of the structure. The construction has end conical parts with a blocked entrance and a central part of a semi-cylindrical shape.

 By design, the structure meets individual operational requirements, provides reliable overlap and protection of the area sufficient to organize any one unit of the basic configuration of the pneumatic quick deployment complex.

 However, its drawback is the lack of the ability to connect among themselves a number of such structures to create a single complex with a network of workrooms connected by a common passage.

 The technical solution according to RF patent N 2041332 IPC E 04 H 15/20 "Air support structure" partially eliminates the above drawback noted by Italian patent N 563843 due to the presence of a longitudinal sliding part of the section. The pneumatic structure according to this patent contains end and longitudinal (ordinary) parts. The longitudinal part is made up of sections adjacent to each other, supplementing which you can increase the area of the structure by increasing the length of its longitudinal part.

 The disadvantage of this structure is the impossibility of using it as a multi-turn, often moved object, inconvenience in installation, transportation, as well as the inability to isolate individual rooms for the allocation of functional working areas and, most importantly, this structure is mounted permanently on a specially prepared, complex in structure, base .

 Shelter for A.S. is known USSR N 335357 IPC E 04 B 1/345 of a semi-cylindrical shape without lock parts with a pneumatic frame made of arches fitted with elastic material, in which to increase the bearing capacity and stability of the frame, the shelter is made in length with multiple sections.

 Tents with inflatable supporting arches are known, developed by the French company Technigueg Michel Brochier TMB, a copy of the prospectus of which we received from the international exhibition is attached.

 Pneumatic construction TMV can develop in two mutually perpendicular directions by docking the working and transitional modules through the vestibules, connecting the modules to each other by lacing.

 Inflatable arches are interconnected in the longitudinal direction by rigid connections.

 The TMV awning meets the requirements of quickly preparing it for work when it becomes necessary to deploy large aid points for victims of natural disasters, accidents or command posts, etc.

 The disadvantage of TMV awnings is the absence at the ends of the working module of the gateway module separating the working area from the external environment, which makes it difficult to maintain the working area in the required hygienic condition and thereby limits the scope of the structure. Installation is difficult, since after raising the arches it is necessary to install rigid longitudinal connections, the range of its operation in various climatic zones is limited: there is no double awning, leaks in the tambours, a large number of assembly joints, the connection of which requires considerable time, which is quite acceptable in the subsequent stages, but not a rapid response stage.

 Another prefabricated large-sized pneumatic frame structure developed by the Swedish company "Trelleborg" and a similar structure developed by the company "GAMBRO" consists of a set of working modules interconnected by transition modules. Copies of the prospectus of pneumatic structures developed by TRELLEBORG and GAMBRO, obtained from the international exhibition, are attached. In contrast to the TMB tent, the construction of the structure includes a lock module with a detachably attached tent to the end pneumatic arch of the working or transitional modules, the tent of the lock module from the second end being attached to the smaller half-cylinder pneumatic arch than the transition and working module arch.

 Air supply and heating devices are located directly on the ground outside the pneumatic frame structure. Pneumatic frame products are transported in one packed bale, while air-supply and heating devices are transported in other packages.

 The TRELLEBORG prefabricated building was developed in cooperation between the Swedish armed forces and the medical department, used initially as a surgical operating room and as an intensive care unit, and later as the main ward of a mobile field hospital. This entailed high demands on structural stability, high hygiene requirements, rapid deployment, mobility and flexibility. This structure is applicable for many other purposes: such as the advanced military ambulance station, command post, headquarters. In the civilian area, the TRELLEBORG construction is a good shelter for rescue services in disaster areas, a point for victims, etc.

 In Swedish patent N 468775, priority 15.11.91, a pneumatic frame quick-erected large-sized structure with the development of working areas in mutually perpendicular directions is shown, similar to a pneumatic frame structure developed by TRELLEBORG, each module of which has a cylindrical shape and a rectangle at the base, and workers and transition modules are interconnected by tambours, but only gateway modules at the ends of the working and transition modules are absent in the design.

 With the exception of the deficiencies that have been resolved, the introduction of gateways and the implementation of modules with a semi-cylindrical tent shape, the pneumatic frame quick-erect structure of the TRELLEBORG company has practically the same drawbacks as are inherent in the construction of the French company TMV awning.

 In the author's certificate N 897978 IPC E 04 B 1/345, the structure includes a rectangular flexible shell fixed to the load-bearing circuit, a lock device, as well as an autonomous heat and air supply system located outside the shell on a special foundation. But this solution applies to stationary air support structures.

 Recently, requirements for creating comfortable living conditions for people inside pneumatic frame structures have increased significantly. This is, first of all, controlled heat and air supply, electric lighting and other systems of engineering support of vital functions.

 Pneumatic structures, being a product of a high technical culture of production, require a high culture of operation of all systems included in the structure.

 But the increase in the number of component systems inevitably leads to an increase in the time for collecting their packages in warehouses and preparation for prompt transportation to a given area of the deployment of the structure, leading to a decrease in mobility. Therefore, constructive solutions are required to optimally combine the proper level of comfort and efficiency of deployment and transportation of pneumatic equipment.

 The disadvantage of almost all structures of structures from the above analogues is the unresolved issues of equipping life support systems and increasing readiness for transportation and deployment of structures in a given area.

 In the TRELLEBORG pneumatic construction, air supply and heating devices located directly on the ground outside the pneumatic frame structure are exposed to atmospheric precipitation, it is difficult to maintain them under adverse weather conditions (frost, wind, snow, etc.), and a high operating culture is not observed.

 Even air-blowing units (WU) of a pneumatic structure are in the most complete form a complex unit consisting of several fans: working, backup, additional, spare energy sources and automatic or manual control devices. In its simplest form, a VU is one fan. Working fans provide a given level of excess air pressure and the required volume in normal use. Redundant fans duplicate workers when they fail or during preventative maintenance. The parameters of the backup and operating fans are usually the same. Additional fans are used to support workers in special situations when it is necessary to significantly increase air flow, to compensate for air leaks during sudden depressurization of the shell. Additional fans are distinguished by increased parameters, primarily in terms of pressure. Fans, as a rule, are driven by electric motors powered by an external network for stationary structures and for non-stationary structures, if there is one in the deployment area. Redundant sources of electricity are needed when there is no nearby external network (which most often happens), and in case of a power outage from the network. They are generators powered by internal combustion engines, or mobile power plants. It is not ruled out the use of standby motor fans, directly connected to the internal combustion engine, bypassing the stage of electricity generation. But electricity is needed, for example, to illuminate the working premises of a pneumatic construction and to operate computers and other office equipment and electrical equipment.

 Automatic control of the backup and additional fans, as well as the inclusion of backup energy sources, is done through relay devices, which are sent to commands by sensors that respond to a drop in air pressure, to de-energize the network, increase wind speed, etc.

 The practice of operation has established the optimal types of fans, they must be adapted to a very long uninterrupted operation in any external conditions (temperature, humidity, precipitation, dust, etc.), have protection against in-phase operation, overheating, and be equipped with safety equipment (grounding, nets on the suction pipes, protective casings on the drive belts, etc.), and maybe sound-absorbing casings.

 If there is a requirement of dust removal of the supplied air, then the filters include filters.

 Since the elastic shell of the pneumatic construction is a thin reflective structure that separates the internal space of the structure from the external environment, it is difficult to create a climate in the room that is different from the environment. The small thickness of the single-layer shell of the pneumatic construction serves as the primary cause of intensive cooling of the air in the room in winter, condensation and the formation of ice on the inner surface of the shell or its overheating in summer.

 Therefore, many pneumatic facilities of a comfortable type are carried out with a two-layer shell, the Shell-in-Shell buildings turned out to be very effective not only in terms of their heat engineering performance, especially during summer overheating, but also in sound insulation.

 Since the thermotechnical characteristics of the shells are low, the creation of the required temperature difference requires high heat consumption and the use of heating systems with high heat output. The most proven heating method was heating the supplied air with heaters. The air heater not only heats the air entering its heat exchanger unit, but also maintains excess pressure under the shell, thanks to the pressure created by the fan, which drives cold air through the heat exchanger. Depending on the source of heat that heats the air in the heat exchanger, electric air heaters or special-purpose heaters can be used in pneumatic installations. The most simple in design and operation are electric heaters, but their operation is associated with high energy consumption. The most versatile and autonomous, but at the same time, the most difficult to design fire heaters that run on liquid or gaseous fuels. For example, TG series heat generators are equipped with air-bearing stationary buildings of domestic mass production. A number of foreign companies produce special-purpose air heaters equipped with an automatic control and regulation system.

 The basic package of the regional operational response complex, for example, in addition to pneumatic frame structures, which form the basis and can consist of various types of modules, and the above life support systems: electrical units, heating system, discharge unit, and related accessories: a set of collapsible electrical cables, internal and external , distribution electrical panel, set of lighting equipment, a set of folding furniture (tables, beds, chairs), spomogatelnoe and processing equipment (computers, etc.), toilets and others.

 Now, when folded, each section (module) of the pneumatic frame construction is packed in a separate cover (bale), and their accessories, life support engineering systems also represent separate packages, and all this variety of packages is stored in the regional warehouses of the Ministry of Emergency Situations, military warehouses or in warehouses of other consumers (geologists, etc.). Upon receipt of the assignment, the deployment of the construction complex must be quickly collected in some area from the shelves of the packaging warehouse and loaded into a given vehicle, for example, a truck. It takes a lot of time to search, refine the brand of pneumatic equipment, systems and related tools.

 The method of laying the shells is thought out at the factory by the manufacturer during packaging. It can be compared with laying a parachute in a satchel before jumping. Some methods of packaging pneumatic casings are protected even by inventions, for example, the "method ..." according to the copyright certificate N 1122566, IPC E 04 B 1/345.

 For large modular hospital complexes, for example, the standard structure of the N.S.M (NATO) hospital from pneumatic facilities, in order to facilitate the transportation and storage operation, a standardized system of boxes and pallets was developed, but it only slightly reduced the time for collection before departure for deployment.

 The closest analogue (prototype) to the proposed solution is the "Pneumatic frame construction" according to the copyright certificate N 1348472 IPC E 04 H 15/20, which is large-sized and fast-built and includes a spatial pneumatic frame, consisting of interconnected ordinary joint in the form half cylinder and end lock sections with openings for entry and exit, containing pneumatic load-bearing elements located in the plane of the cross section of the structure and additional pneumatic element s, the axes of which in the ordinary sections are located in planes parallel to the longitudinal axis of the structure, and the casing is an airtight shell-tent, forming a roof and walls, providing overlap of large areas due to the possibility of developing the structure when docking the ordinary and end sections (modules) to each other , a system of engineering life support, including at least air supply, air supply communications, etc., located outside the structure.

 The disadvantage of the proposed solutions for AS 1348472 is filling in-line and end sections from different blowers, there are also no devices for creating comfortable conditions, there are no, for example, heating systems, there is no separation of the internal space of the structure into isolated working areas, air-blowing devices are operated outdoors, without protection from the influence of bad weather , it is not envisaged to increase the efficiency of removing folded shells and other systems from the storage place for transportation to a given deployment area.

 The technical task of the proposed invention is the creation of a multi-turn and "wandering" pneumatic frame prefabricated structure, capable of increasing its size along the length and having a limited number of assembly joints of sections and at the same time, while maintaining increased bearing capacity, reliability of the structure, stability, sufficient rigidity and good aerodynamic performance in all structures, and in the internal space of each section of the structure should be provided for the possibility of allocation of work zones with increased comfortable conditions due to the heat carrier and electric lighting, etc., and all systems of engineering support for vital functions should be constantly ready for immediate shipment (transportation) to a given area of the deployment of the structure and be effectively operated there in various climatic zones, including even in adverse weather conditions, performing the functions assigned to the regional complex of the Ministry of Emergency Situations of an operational response with the optimal combination of the proper level of comfort living accommodation for people in the construction and conditions for servicing life support equipment with the speed of deployment and transportation of the pneumatic frame structure and facilitating the storage operations of the entire structure with maintenance equipment and related equipment.

 The technical result is achieved by the fact that the pneumatic frame prefabricated structure consists of at least one ordinary longitudinal air-bearing section having a lock device along one of the ends with openings for entry and exit, and on the other a pneumatic end arch with elements of the mounting seam, which makes it possible joints along the length are detachable by an assembly seam of at least one other ordinary longitudinal section. The sections contain pneumatic load-bearing elements located in the planes of the transverse and longitudinal sections of the structure and the sheathing - an airtight shell-tent, forming a roof and walls and providing overlap of large areas due to the possibility of developing the structure when docking to each other with the ends of ordinary sections. The construction also includes a system with life support equipment located outside the structure and including, at a minimum, a blower and supply lines for air supply to the premises of the structure.

 Distinctive features of the prototype is that the pneumatic frame structure is additionally equipped with a unit of equipment installed autonomously from it, made in the form of a container building with a base and walls, with a lockable entrance, with working and backup heaters, electrical units, an electric panel mounted inside the container building on the base and other devices of the microclimate maintenance system in the construction and life support. Inside the container room, a volume has been allocated for placement during transportation of all the laying of the pneumatic frame structure and the set of laying of related accessories.

 Outside the container premises, in the lower part are attached devices for towing it horizontally by towing, for example, runners and (or) wheels, and in the upper part there are attached gripping devices for lifting it, for example, made in the form of eyebolts. In one of the walls of the container room there is a technological hole for the exit (exhaust) of gases during the operation of diesel generators and technological holes, one with a ventilation grill, the other for the exit of air ducts and electric cables when connecting them to the corresponding systems of the pneumatic frame sections. The internal volume of the container building was selected with a excess of more than 5 times the volume occupied by all units of the life support system, more than 50 times less than the internal volume of the entire pneumatic frame structure and more than 5 times more than the laying of pneumatic frame sections, and the height of the container room was not chosen less anthropological significance of growth for the average person. The volume free from the installed aggregates of engineering support for vital functions in the room-container is allocated in the amount of at least 50 percent of the internal volume of the container-room and is used to place laying of sections of pneumatic construction and laying of a set of related accessories during transportation and to create personnel for the service area of the units during operation of the deployed pneumatic frame facilities.

 The entry and exit apertures in the gateway device are formed by an inflatable doorway frame of inflatable cylinders connected in one piece to a U-shape, both ends of which in the lower part are connected inseparably with additional inclined horizontal cylinders located on the floor of the lock part of the section with the ends of the supporting cylinders at the nearest the transverse arch, and under the inflatable door to the floor between the vertical components of the door frame is permanently attached an elastic threshold, for example, of foam, enclosed in a shell of floor dimensional material in contact with the upper part with the lower generatrix of the horizontal cylinder of the door.

 The internal space of the pneumoframe sections for the allocation of functional working areas is divided along the length along separate transverse pneumatic elements (arches) with elastic partitions with door openings that can be closed with curtains, and elastic ducts with openings for supplying warm air from heaters located in the room are mounted in the lower part of each working area -container.

 A hermetic flexible shell-tent is attached to the outer surface of the pneumatic frame of the structure, and an air-permeable shell is attached to the inside. The section is equipped with a docking apron made of an elastic cloth, one longitudinal edge of which along the entire length has a pocket with a flexible tension element (cord, rope), and the second is attached along the entire length to a sealed elastic tent sheath, while the width of the docking apron is greater than the diameter of the joined transverse pneumatic elements (arches) at the end opposite to the end with a lock device.

The invention is illustrated by drawings, where
In FIG. 1 shows a pneumatic frame prefabricated structure, consisting of two ordinary longitudinal sections interconnected by a detachable mounting seam in length, a schematic axonometric image, a sectional view;
Figure 2 is a block of equipment in the form of a container room in a perspective view, a General view with a section;
In FIG. 3 - a section of a pneumoframe structure with a longitudinal section and a communication diagram of the wiring for supplying warm air and lighting;
Figure 4 is the same, a top view with a slit;
Figure 5 - the end of the airlock section of the ordinary longitudinal section with an inflatable doorway frame and an inflatable door; view A of FIG. 3;
In Fig.6 - the end of the section of the ordinary longitudinal section with a detachable mounting seam and with an elastic partition with a door opening shutter curtain; view B, FIG. 3;
In Fig.7 is a section aa of an inflatable door with a threshold in Fig.5 ;.

 On Fig - detachable mounting seam along the end arches of two sections of the structure.

 The pneumatic frame quick-erecting structure consists of ordinary longitudinal air-bearing sections 1, each of which has one of the ends of the gateway device 2 with an opening decorated with an inflatable frame 3 and an inflatable door 4, and on the other end there is an elastic partition 5 with a door with a shutter 6 opening and with detachable mounting seam 7, a unit of equipment made in the form installed independently from the sections of the container room 8 with the base 9, the walls 10, a single-leaf door 11. Inside the container 8 on the base to provide During winter season and work in areas with a cold climate, a working heating and ventilation unit 12 of the MASTER company, mounted on fuel, a working electrical unit 13, powered by diesel fuel, was installed, power - 1.75 - 5 kW to ensure minimum life facilities, emergency lighting, backup power unit 14, with a capacity of 4.6 kW for the operation of all electrical equipment, appliances, electronic equipment. Fuel consumption of electrical units from 0.6 to 2 l / h.

 A distribution switchboard 15 with a stabilizing device for the operation of electronic and computer equipment is installed inside the container building.

 Outside the container room in the lower part under the base there are attached devices for towing it horizontally by towing, for example, runners 16 and (or) removable wheels 17, and in the upper part there are attached gripping devices for lifting it, for example, made in the form of eyebolts 18. Eye bolts 18 are also installed on one of the walls to enable horizontal transportation over short distances of the container room in the installation area of the structure or in storage warehouses. In the walls of the container room there are technological openings 19 for exhaust gases, operating electrical units, openings 20 for the exit of air ducts, an opening 21 for the exit of electric cables, an opening 22 for installing ventilation grilles.

 It was established by experimental studies that the internal volume of the container building 8 should be selected with more than 5 times the volume occupied by all units of the life support system, more than 50 times less than the internal volume of the entire pneumatic frame structure and more than 5 times the laying volume of 23 pneumoframe sections, and the height of the container room is chosen to be no less than the anthropological growth value for the average person. Moreover, it was taken into account that the volume free from the installed aggregates of engineering support for vital functions in the container room was allocated in the amount of at least 50 percent of the internal volume of the container room to accommodate laying of pneumatic construction sections and laying of a set of related accessories during transportation and to create a sufficient area for servicing the units for personnel operation of the expanded pneumoframe structure.

 Shown in figure 1, the structure consists of two sections 1 - modules "IPC". The first section depicts a variant of the operational response command post for the leadership of the Ministry of Emergency Situations with the post of the operational duty officer, in the second section, a bedroom-room for 24 people. It is possible to redesign the complex with a unified module (extended section) with 32 beds. The basic delivery package, in addition to the listed products, blocks, devices, assemblies, includes: a pressure unit - provides inflation and maintains the required pressure in the pneumatic frame of the structure; a set of internal and external electrical cables 24 with moisture-proof connectors; set of lighting equipment 25 (8 halogen lamps, 5 sockets); a set of folding furniture: tables 26 (2 pcs.), chairs 27 (6 pcs.), bunk four-bed beds 28; auxiliary equipment (a set of stakes, a fire extinguisher, a shovel, a sledgehammer, etc.); dry closet, litter for installation in unfavorable conditions on the ground, snow, dirt and insulated floors, used for thermal insulation.

 All listed related accessories in the form of separate stackings are placed in the free volume of the container room for transportation and storage.

 Structurally, the module section 1 of the pneumatic frame prefabricated structure consists of a pneumatic frame made of a sealed elastic material, for example, rubberized fabric. The frame contains pneumatic load-bearing elements located in the planes of the cross section, in the form of arches 29, supported by supporting cylinders 30, and in the planes of the longitudinal section, in the form of connecting arches of longitudinal inflatable beams 31. Fastening arches, beams, supporting cylinders to each other and fixing the frame along the entire length of the support cylinders to the elastic floor 32 is made by glue. On the outside, the frame is covered with a sheathing - an airtight shell-awning 33, and on the inside it is glued with an air-permeable shell 34 made of durable fire-resistant material.

 In the airlock part 2, made with an outer surface that is close in shape to a cone-shaped section 1, the inflatable door 4 is fixed by a flexible hinge joint on a pneumatic door frame 3 formed by three cylinders 35. connected in one piece into a U-shaped form, both ends of which are of the lower part are connected inseparably by additional inclined, horizontal cylinders 36 with the ends of the supporting cylinders 30 at the nearest transverse arch 29, and the inflatable door 4 has the ability to open in both directions - both inward and outward, and in In addition, a threshold 37 is made under the inflatable door 4, made of a porous material, for example, foam, placed in a shell of a polymeric material, in contact with the upper part with the lower generatrix of the horizontal lower cylinder of the door 4.

 The horizontal and vertical components of the door frame 3 are also permanently attached by inclined pneumatic ties 38 to the nearest pneumatic arch of section 1, forming the semiconical outer surface of the lock part of the shell 33 of section 1.

 From the opposite lock part of the end face 2, section 1, in addition to the elastic partition 5 with a doorway closed by a curtain 6, a detachable mounting seam 7 is made.

 Sections 1 are interconnected by end faces ending in congruent arches 29 with the help of a mounting seam 7, while the congruent arches 29 of two ordinary sections are pre-contacted in pairs between the side generatrix of the arches. The mounting seam consists of a power and sealing parts, while the power part is made in the form of flexible elastic tension ties (belt) ties 39, tightening until the arches completely contact around the entire perimeter of the arches, one half of the belt ties being located on one section (module) along the end perimeters pneumatic arches mainly in the area of the longitudinal beams 31 and supporting cylinders 30, and the second half on the congruent pneumatic arch of the other docked section, opposite the first half of detachable belt ties nut 39. The sealing part is made in the form of a docking apron 40 from an elastic panel overlapping the casing 33 from the top around the perimeter and the power part of the docking and aligning the groove between the congruent pneumatic arches of the joined sections, the width of the connecting apron of the section being larger than the diameter of the joined pneumatic arches. One of the edges of the docking apron 40 is permanently attached to the casing - a hermetic sheath-awning 33 along the upper generatrix of the end pneumatic arch of the section along the entire perimeter, and the second edge has a pocket with a flexible tension element 41 for tightening around the perimeter of the cross-section of the panel section of the sheathing-awning behind the pneumatic Arch docked section. To tension the element 41 and fix it in a tense position, a quick-release fastener is used, made, for example, in the form of two half rings fixed in an elastic loop located on both sides of the section at its base. To facilitate the fitting of the docking apron onto the arch 29 of the docked section, transverse stiffeners 42 in the form of elastic rods of lightweight porous material are mounted on the upper part of it, in addition, docking apron 40 in the center of the apogee of the arch is additionally equipped with a flexible connection in the form of a rope (not shown) with which the apron can be corrected (moved) from the ground.

 The inner space of each pneumoframe section 1 or only one for highlighting functional working areas is divided along the length along separate transverse pneumatic elements (arches 29) with elastic partitions 5 with doorways closed by shutters 6, and in the lower part of each section 1 mounted along the section at the supporting cylinders 30 elastic ducts 43 with holes for supplying warm air from heaters located in the container room on both sides of the section.

 The pneumatic frame of the building is filled through valves and (or) rubber blowing tubes located along the edges of the base sections and mounted in supporting cylinders 30.

 To ensure comfortable living conditions in the pneumatic frame prefabricated building, in each section there are flexible sleeves 44 for laying an electric cable and sleeves 45 for connecting a heat-ventilation installation, and transparent windows 46 are made in the covering-tent 33 and in the inner shell 34 located in the upper part along sections.

 To create stability against the effects of wind load, the sections are attached to the ground using well-known anchor pins and extensions. The lower part of the sections is strengthened to the ground by a fastening canopy 47 protruding around the entire perimeter of the sections, having grooves for anchor pins located along the canopy 47, serving simultaneously as handles for transferring the sections. To prevent damage to the soil of the sections' floors, a litter of elastic material is placed under it, and removable floors made of porous material can be installed in the structure to increase the thermal insulation properties of the floor.

A pneumatic frame prefabricated structure works as follows:
After receiving the assignment about the location of the regional command post of the Ministry of Emergency Situations of an operational response, the maintenance staff delivers a pneumatic frame prefabricated structure to a specified area, packaging all products, devices and basic equipment which are located in one container room 8. The container room in the warehouse is lifted with slings for the upper eyebolts 18 by means of a lifting means and immersed, for example, in a gazelle-type lorry or with a wheeled version added to a truck - and it can be immediately sent to the area of deployment. There, the door 11 of the container room 8 is opened and unloaded first by packing the sections 23, and then by packing the related accessories.

 Installation of pneumatic frame prefabricated structures delivered to the place begins with the choice of the site and its marking taking into account the wind rose, in parallel, they are working in the container room 8 to alert all the life support systems installed in it (starting generators, heating installation).

 To bring sections 1 to working condition, unpack both covers 23, straighten the sections either directly on the ground or on a special litter, which is preliminarily covered with the mounting pad, and fill the sections through special nozzles using a blower, for example, a vacuum cleaner with a power of about 600 watts. Filling time depending on the type of supercharger and sections is 6-12 minutes. After filling the pneumatic frames of the sections to operating pressure, connect the sections with a weld seam 7, starting with the tightening of the tie rods 39 located along the arches through two metal frames, pair the tie ties with the opposite in pairs, passing the belt through the frames, and tighten until the end congruent arches are completely closed having previously laid the docking apron 40 on the docked section 1 and adjusting the edges of the apron with a flexible connection, tighten the apron along the arch of the docked section with a tensioning element, passing it through quickly detachable fastener, consisting of two metal half rings located on the edge of the base sections. Before the sections are fixed to the ground, the litter is bent under the section base, thereby providing a drain of water, then fixed with anchor pins, pulling the fastening canopy 47 to the ground through the grooves located along the fastening canopy, which serve simultaneously as handles for moving sections or a pneumatic frame quick-erect structure collection.

 To prevent displacement from wind loads of a pneumatic frame prefabricated structure, stretch marks located along sections and fixed on hinges are fixed with anchor pins to the ground, stretch marks are pre-tensioned. Thus, the entire assembly process of the structure does not require the use of mechanical installation tools.

 In the assembled pneumatic frame quick-erected structure, insulated floors are laid on the floors of sections 32, an electric cable is installed through the sleeve, lighting fixtures and other related accessories. They are connected to the hoses located laterally on the - external tight elastic sheath-tent with heater hoses that exit through the opening 20 of the container room.

 Thresholds 37, in the lower part of the doorway under the inflatable door 4, prevent water from entering the room, for example, when snow melts, heavy rain with the formation of water flows, and other undesirable pollution factors.

 The transitions between the working areas of the sections is carried out through partitions with shutters 6, which are rolled up and strengthened with tape ties in the upper part of the formed opening.

To ensure comfortable conditions and work, the complete set of constructions is provided in the container premises: electrical units of the firms "ROBIN", "GECO", "HONDA" with 1.75 kW and 4.6 kW fuel. Fuel consumption of electrical units from 0.6 to 2 l / h. Cables from electric units pass inside the modules through special sleeves made in a sheathing, when working in the winter season and when working in areas with a cold climate, MASTER fuel-based heating systems are used. "WALLAS", with their help, even at the lowest temperatures inside the structure, a temperature of at least 17 ^o C. can be maintained. Fuel consumption, depending on the power of the units and the ambient temperature, is 0.6-2 l / h. Pneumoframe sections are operable when operating in the following climatic conditions: air temperature from minus 40 ^o C to 50 ^o C, wind speed up to 15 m / s, atmospheric pressure, corresponding height above sea level 0-3000 m, relative air humidity up to 98%, at a temperature of 25 ^o C, weather conditions: fog, dew, rain, snow load up to 0.25 kPa (20 kg / m ² .

Thanks to the proposed structural design of the sections with double cladding, tent, inflatable doors, etc., combining them together into a single pneumatic frame quick-erect structure with a container building 8 for equipment to create comfortable living conditions and a favorable microclimate in the sections, the most approximate working conditions of the regional center of the Ministry of Emergency Situations of an operational response to conditions in stationary buildings. Placing all the equipment, life support systems, laying 23 sections of the structure and related accessories in one container room after dismantling the structure at the end of operation, it significantly increased the readiness of the complex to fulfill its tasks. This was also facilitated by the fact that the number of detachable assembly joints was reduced, there were no detachable joints connecting the gateway parts to the ordinary longitudinal sections. A pneumatic frame prefabricated structure, consisting, for example, of two ordinary longitudinal sections, has only one connection node with an assembly seam 7, but creates a working area of ≈90 m ^2, internal volume ≈140 m ³ . The sizes in the filled state, m - 18 (length) x 5 (width) x 2.75 (height), the dimensions of the doorways: pneumatic frame with an inflatable door - 1x1.8, folding curtains - 1.5x1.8, dimensions in the packed state one section, m-1.4 x 0.7 x 0.5, the mass of two sections is 360 kg. Dimensions of the container room, m-2 x1.9 x 1.9. It is possible to work the entire complex in standalone mode, the maintenance staff both in the pneumatic armament sections and in the container room works in normal mode without feeling any discomfort.

 The operation of the equipment of the life support system is not affected by adverse weather conditions, it also works in comfortable conditions.

 The developed "nomadic" regional complex of the Ministry of Emergencies "operational response with such tactical and technical characteristics as compactness, low weight, ease of installation, dismantling, the ability to move the structure manually and carrying out all installation and dismantling works without involving mechanical means and special additional devices - self-lifting modules, the durability of the material of the modules, comfort and creation of amenities for staff to work in educated rooms, as well as ensuring maximum mobility, Parts Required in extreme situations, will be in demand in all regions of the country to create the structure of the complexes there is provided a rapid response.

 The applicant enterprises have all the conditions for the serial production of pneumatic frame prefabricated buildings, since for this there is all the necessary equipment and sufficient qualification of the working staff and proven manufacturing technology.

Claims (7)

 1. A pneumatic frame quick-erecting structure, consisting of at least one ordinary longitudinal air-bearing section, having a lock device along one of the ends with openings for entry and exit, and on the other a pneumatic end arch with elements of a mounting seam, providing the possibility of connection along the length detachable-welded seam of at least one other longitudinal section containing pneumatic load-bearing elements located in the planes of the transverse and longitudinal sections of the structure, and the casing is a sealed shell a cuent forming a roof and walls and providing overlapping of large areas due to the possibility of developing the structure when the ends of ordinary sections and systems with life support equipment are connected to each other, located outside the structure and including at least a blower and supply communications for air supply of the premises of the structure, characterized in that the pneumatic frame structure is additionally equipped with a unit of equipment installed autonomously from it, made in the form of a container building with a base and walls with a lockable entrance, with working and backup heaters, electrical units, an electric panel and other devices of the microclimate maintenance system in the building and life support mounted inside the container building on the base, and the volume for the installation of all pneumatic frame constructions and kit during transportation is allocated accessories, and devices for horizontal work are attached to the bottom of the container room towing it, for example, runners and / or wheels, and gripping devices for lifting it are riveted in the upper part, for example, made in the form of eyebolts, in one of the walls of the container’s premises there is a technological hole for the exit (exhaust) of gases during operation of electrical units and technological holes - one with a ventilation grill, the other - for the exit of air ducts and electric cables when connecting them to the corresponding systems of the pneumatic frame sections.  2. Pneumatic frame prefabricated building according to claim 1, characterized in that the internal volume of the container building is selected with an excess of more than 5 times the volume occupied by all units of the life support system, more than 50 times less than the internal volume of the entire pneumatic frame structure and more than 5 times the volume of laying of pneumatic frame sections, and the height of the container room is chosen no less than the anthropological value of growth for the average person.  3. A pneumatic frame prefabricated building according to claims 1 and 2, characterized in that the volume free from the mounted aggregates of engineering support for vital functions is allocated in the amount of at least 50% of the internal volume of the container room to accommodate laying of pneumatic construction sections and laying of a set of related accessories during transportation and to create for the personnel a sufficient service area for the units during operation of the expanded pneumoframe structure.  4. Pneumatic frame prefabricated building according to claim 1, characterized in that in the middle part of one of the walls of the container room or at the ends of the device for horizontal transportation (skids) is attached another gripping device in the form of eye bolts.  5. Pneumoframe prefabricated building according to claim 1, characterized in that the entry-exit openings in the gateway device are formed by an inflatable doorway frame from inflatable cylinders connected inseparably into a U-shape, both ends of which in the lower part are connected inseparably by additional inclined horizontal cylinders located on the floor of the lock part of the section with the ends of the support cylinders at the nearest transverse arch, and under the inflatable door to the floor between the vertical components of the door frame, one-piece an elastic threshold, for example, of foam, enclosed in a shell of polymeric material, in contact with the upper part with the lower generatrix of the horizontal door balloon, is provided.  6. Pneumo-frame prefabricated building according to claim 1, characterized in that the inner space of the pneumo-frame sections for the allocation of functional working areas is divided along the length along separate transverse pneumatic elements (arches) with elastic partitions with door openable shutter openings, and elastic ones are mounted in the lower part of each working area air ducts with openings for supplying thermal air from heaters located in the container room.  7. Pneumatic frame prefabricated building according to claim 1, characterized in that for ordinary longitudinal air-bearing sections, an airtight elastic shell-tent is attached to the outer surface of the pneumatic frame, and on the inside there is a breathable shell, the section is equipped with a docking apron made of elastic cloth, one longitudinal the edge of which along the entire length has a pocket with a flexible tension element (cord, rope), and the second edge along the entire length is permanently attached to the sheathing-tent on the upper generatrix of the ends pneumatic arch, while the width of the removable docking apron is greater than the diameter of the joined transverse pneumatic elements (arches) at the end opposite the end with the lock device.

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