RU2805574C1 - Antenna masking method and device for its implementation - Google Patents

Abstract

FIELD: antenna technology.

SUBSTANCE: invention is related to the field of masking ground-based antennas, in particular to antenna shelters (AS) 1, disguised as an installation object or the surrounding landscape. The technical result is achieved by the fact that the outer surfaces of external interlocking three-coordinate corner posts 3, external interlocking two-coordinate sections 4 of inter-modular step expanders, internal interlocking base panels 2 and internal interlocking base panels 6 of extensions of the gables, half-interlocking base panels 5 of side access doors are camouflaged in a planar or three-dimensional manner, the appearance of which is determined by the object of installation or the surrounding landscape.

EFFECT: creation of a disguised AS 1 using planar or volumetric camouflage of the outer surface of AS 1, identical to the installation object, radio-transparent frameless modular type with the function of modular expansion with a constant step for any size: length, width, height.

8 cl, 7 dwg

Description

The invention relates to the field of camouflage of antennas and antenna complexes (AC), namely to camouflage as an installation object or the surrounding landscape with protective radio-transparent dielectric antenna shelters (AU) of a modular type with functions of expanding dimensions with a constant step along any overall dimension (length, width, height ) stationary ground and mobile AKs in order to create a visual perception in which the camouflaged AK was perceived identical to the object of its installation or the terrain, and can find application on objects, for example, in the form of ground structures, structures on the roofs of buildings, on car trailers, in the back freight vehicles, on railway platforms.

Radio-transparent dielectric AC AKs with camouflage elements have a wide range of applications.

So, for example, AU AK can be installed:

- on the roof of buildings, for example, in the form of a superstructure, or in the form of a ventilation pipe or fireplace pipe, while the camouflage is carried out by painting or volumetric decorative finishing made on the external surface of the AC, emitting a building structure and harmoniously fitting into the architecture of the building;

- on the ground in urban or rural areas, while camouflage is carried out, for example, as a change house, or garage, or as an outbuilding with appropriate external finishing in the form of painting or volumetric decorative finishing;

- on the ground in a park or forest area, while camouflage is carried out, for example, under the surrounding landscape;

- in the back of cars (such as a pickup truck), trucks or special vehicles, on car trailers or platforms, for example, under a change house or a residential trailer;

- on railway platforms, for example, disguised as a passenger or freight car.

AKs located outside any protective cover or camouflage have visual unmasking signs by which one can determine: - the type of antenna and its dimensions, and therefore the frequency range; - width of the main lobe of the radiation pattern; - orientation in azimuth and elevation of the direction of the main lobe of the radiation pattern; - the level of the side lobes and the angles of their orientation in space relative to the main lobe of the radiation pattern; - polarization; - the ability to change the position of the antenna in space, namely electrical or electromechanical scanning, or a stationary position.

Knowledge of these parameters makes it possible to determine the true purpose of the AK, which allows, if necessary, to carry out either physical destruction of the AK, or to carry out a destructive targeted effect on the AK, for example, in the direction of the main lobe of the radiation pattern and in the direction of the side lobes, destructive electromagnetic fields, or, for example, by setting polarization interference, which is currently widely and effectively used in electronic warfare tasks and which is difficult to identify as targeted interference, or by short magnetic or electromagnetic pulses, as well as electromagnetic fields based on new physical principles, for example longitudinal electric and magnetic waves: longitudinal electric waves (in direction E); longitudinal magnetic waves (in the H direction); torsion waves (along H with vortex component E); Tesla waves (along with the vortex component H).

For example: Electronic resource: [Access mode] (zhu-nal.lib/ru/e/etkin_w_a/prodolnyevolnykaksledstvieuravneniymaksvella.shtml); (www.prometeus.nsc.ru/partner/zarubin/waves.ssi).

A destructive effect on the AC can lead, for example, to temporary electromagnetic blinding with subsequent restoration of operation or burning out of the input circuits of the AC, i.e. physical destruction.

There is a known method for creating protective radio-transparent frame-type amplifiers, made in a dome-shaped form in the form of a fiberglass-based sphere, for example, for large ground-based reflector antennas. The sphere is assembled from regular-shaped geometric segments, for example, triangular or hexagonal, mounted on a frame, which is usually made of metal. The frame structure consists of hundreds of uniform metal beams, pins and connecting mechanisms that are assembled into a single structure. (For example: Electronic resource: [Access mode] (https://locplayer/ru/47442744-Ukrytiya-antennyh-ustroystv-dioprozrachnye/html).

Such AC designs have only a protective function from external climatic and mechanical influences, while there are two unmasking signs: the first is the AC, and the second - the frequency range can be approximately determined by its diameter.

There is a known method for creating a frameless radio-transparent AU to protect spherocylindrical antennas. For example (RF patent No. 2419927 MPK H01Q 1/42, “Radio-transparent cover for antennas, method of its manufacture and fastening”). The radio-transparent AU has a one-piece, one-piece design and is made of multilayer composite materials based on fiberglass and epoxy resin. The design of the AU is made for a certain type of antenna and certain dimensions and is attached to a supporting platform or base.

The main function of such ACs is protection only from external climatic and mechanical influences. Such AUs are used, for example, for mirror antennas or truncated parabolic antennas, for phased array antennas.

Such AC designs have two unmasking features: the first is the AC, and the second - the diameter can roughly determine the frequency range.

There is a known method of camouflaging an AK from visual surveillance equipment using radio-transparent camouflage nets located on the frame. For example (RF patent No. 2546470, MCP F44N 3/00). This method of camouflaging an AK is used as a temporary and highly limited operation due to weather conditions and, as a rule, is used for short-term camouflage under the terrain.

There are known methods of camouflage in the open space of AKs, presented in the foreign press, in particular, one of the areas of application is the camouflage of communications antennas camouflaged under bushes, for example, in the Arizona desert, the type of camouflage fits into the surrounding landscape. Also, for example, in other conditions, trees and rocks can serve as antenna camouflage. For example: Electronic resource: [Access mode] (https://novostel.ru/2017/10/24/ American operators disguise antennas as cacti), Electronic resource: [Access mode] (http://pageperso.aof.fr/ tsf70/images/fox/drol47_3.ipg).

There are known ways to disguise an antenna as building elements, for example, water towers, church crosses, church bell towers, ventilation pipes on the roof of a building, chimneys similar to speakers, flagpoles. For example: (Electronic resource: [Access mode] (www.radioscanner.ru/forum/topic22958.html).

There are known methods of disguising antennas in the form of a super-tree, in the form of a palm tree, in the form of a flagpole in Texas, the tower and bell tower of an Episcopal church in Dallas, a tree trunk in Arizona, in a brick window frame in Sopot Poland, as a work of art, a decorative tower, under the cross at the Church of Lack Worth, Florida, in the form of a bell tower in LaVista New England. For example (Electronic resource: [Access mode] (https://bigpicture.ru/?p=318259).

The considered camouflage methods are not universal and are used only for ground-based stationary AKs under vegetation, a building structure, or a fragment attached to a building structure, and are used for a very limited type of AK antennas, for example, vibrator antennas, non-protruding rhombic antennas, flat phased array antennas.

Such camouflage methods, by their design, are not prefabricated and universal and are manufactured specifically for the AK and the installation object; in addition, they cannot be used to camouflage a wide class of large-sized (volumetric) antennas, for example, mirror antennas.

From the analysis carried out, it follows that there are no known technical solutions for the design of ground-based guns that simultaneously meet the requirements for a wide range of camouflage options and versatility in forming type-sizes for a wide range of missile launchers installed inside such guns.

The versatility of the AU lies in the frameless and panel-step expansion, with a constant step along any overall dimension (width, length, height), design, which makes it possible to form the AU for a wide range of types and sizes of AC antennas without expanding the range of types of sizes of structural elements, and simply by a corresponding increase in their number. This versatility of the AU construction makes it possible to mask both low-profile antennas and antennas of significant dimensions, such as mirror antennas.

The panel expansion step is determined by the dimensions of the base panel (BP), the dimensions of which depend on: - the dimensions of the antenna; - location of antenna installation at the site; - methods of delivery to the facility (by automobile or cargo transport, aviation, sea container); - assembly method (manual or using lifting mechanisms). The best option is the versatility in choosing the size of the power supply for a wide range of dimensions of AK antennas, delivery and assembly, which significantly simplifies production and reduces the cost of production of the AC. In this case, the type of camouflage, a planar or three-dimensional pattern on the outer surface of the AC, must be produced in production specifically for the installation location.

At the same time, quite stringent requirements are imposed on the radio-transparent dielectric material for all structural elements of the AC, namely: - the value of the relative dielectric constant is of the order of (2.0-3.0); - dielectric loss tangent values of the order of 10 ^-3 in the frequency range from the mid-wave range to tens of GHz; - resistant to a wide range of external climatic influences in the temperature range ±50° C and air humidity up to 100%; - resistant to ultraviolet radiation and increased solar radiation; - resistant to snow, rain, sandstorms, aggressive environments (chemical rain); - resistant to dry thunderstorms and increased air electrification, which eliminates the need for grounding; - have thermal insulation properties; - easy to machine with cutting tools (milling, turning); - the ability to perform a three-dimensional pattern on the outer surface of the AC to create a three-dimensional camouflage pattern; - the ability to glue AC parts, similar to the cold welding method; - have high adhesion when painted with special paint.

Electronic resource: [Access mode] (GOST 30299-95 Interstate standard. Fiberglass structures. Radio-transparent antenna device covers. General technical requirements).

The technical objective of this invention is to create: - a method for masking an AC installed in an AC, the outer surfaces of which are made with a planar and/or three-dimensional pattern, which make it possible to imitate a wide range of objects on which the AC can be installed and not harmoniously fit into it or into the environment while creating visual unmasking signs; - AU consisting of two constructs, one constructive is the base module (BM) in the shape of a cube or parallelepiped and the second constructive is the roof module (MK) in cross section in the shape of a trapezoid; - AU of a modular frameless design with a minimum range of types of sizes of structural elements and with the possibility of expansion by the value of the internal tongue-and-groove base panel (VSHBP), which determines the expansion step according to any size of the AU (length, width, height, which corresponds to the coordinates OX, OY, OZ of the AU), by increasing the number of VSHBP without increasing the range of structural elements connected to each other by external interpanel tongues (IPSH), and such an internal tongue-and-groove connection of VSHBP provides reliable protection from external climatic influences; - the presence of an internal access door or hatch in the side wall of the control unit; - the possibility of assembling three solid walls of the BM and MK AU with the final assembly of the fourth side wall made solid or with a door or hatch.

The technical result is achieved by the fact that the method of masking the AU through the use of a protective radio-transparent panel - expandable with a constant step along any of the coordinates OX and OY of the base and OZ of the height of the sides of a dielectric ground antenna shelter, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which is made camouflage in the form of decorative finishing, imitating the appearance of an object or landscape where the AC is installed, and fitting harmoniously into it, consisting of a frameless assembly of the floor module (MF), with a frameless transition to the BM, made in the form of a parallelipiped, with a frameless transition to the MK assembly , made as a single-pitch inclined one in the shape of a right triangle, by installing external tongue-and-groove three-coordinate corner posts (VShTKUS) MP of the BM base, external tongue-and-groove two-coordinate sections (VShDKS) of inter-panel step expanders (MPShR) with orthogonal tongues along the OX and OY coordinates of the BM base on external tongues and according to the OZ coordinate of the height of the side walls (BS) of the BM of a rectangular coordinate system, VShTKUS of the transition from the straight pediment to the inclined part of the MK, VSHTKUS of the transition from the BS BM to the inclined part of the MK, VSHDKS MPSHR with inclined tongues of the inclined transition from the BS BM to the inclined part of the MK, VShDKS MSHR with inclined tongues of the inclined part of the MK, internal tongues of the VShBP, internal tongue-and-groove base panels (VShBPD) of the gables of the MK, half-tongue base panels (PSHBP) of the side access door, and the VShBP, made of a square shape, form the MP, BS BM, gables of the MK, the inclined part MK with the corresponding VSHBP and VSHBP, while the PSHBP form a hatch or a side access door inside the BM, while the transverse dimensions of the PSHBP are equal to the transverse dimensions of the VSHBP, and the depth and thickness of the internal tongue and groove of the VSHBP and the depth and thickness of the half-tongue PSHBP are the same, while the VSHBP, PSHBP and VShBPD are interconnected by VMSH, which are made in the form of a rectangular plate, the width and thickness of which are equal to twice the depth and thickness of the internal tongue of the VSHBP, respectively, and the length of the VSHBP is equal to the length of the side of the VShBP and/or PSHBP interconnected and/or the length of the side of the connected VSHBP, with In this case, camouflage and assembly of the AU is carried out in the following stages:

- masking of the external surfaces of VShBP, PShBP, VShBPD, VShTKUS MP of the base of the BM, VShDKS MPShR with orthogonal tongues VShTKUS from the straight pediment to the inclined part of the MK, VShTKUS of the transition from the BS BM to the inclined part of the MK, VShDKS MPSHR with inclined tongues of the inclined transition from the BS BM on the inclined part of the MK, VShDKS MPSHR with inclined tongues of the inclined part of the MK by performing planar or volumetric decorative finishing that imitates the appearance of the object or landscape on which the AU is installed;

- the formation of the base of the MP BM AU is carried out along the coordinates OX and OY by installing in the four corners of the base of the MP BM four VShTKUS MP bases of the BM, respectively, and each VShTKUS MP of the BM base is located in its own rectangular coordinate system, while the VShTKUS MP of the BM base is made of three identical bars located along the coordinates OX, OY and OZ of the rectangular coordinate system, respectively, and the bars are made of a square cross section, the side of the square is equal to the thickness of the VShBP, and the length is equal to half the length of the VShBP, while in three coordinate planes ZOX, ZOY and XOY on the bars of each VShTKUS MP of the BM base along the longitudinal axis there are three identical ⎣-shaped plates, the right angles of which are located at the origin of the coordinate system, respectively, the ⎣-shaped plate consists of a horizontal branch plate and a vertical branch plate, and on each VShTKUS MP of the BM base in the plane XOY plates of four branches oriented horizontally are located, and in the ZOY plane and in the ZOX plane there are one plate of branches oriented vertically, respectively, while the ⎣-shaped plates of the horizontal and vertical branches are made of the same length and are equal to half the length of the VShBP, and the width and thickness of the plates horizontal and vertical branches are equal to the depth and thickness of the internal tongue and groove of the VShBP, respectively, and are external tongues for the VShBP, and along the OX coordinate and along the OY coordinate between the horizontal bars of the four VShTKUS MP bases of the BM are installed in each of the four horizontal openings, at least two VShDKS MPSHR with orthogonal tongues, while at the OZ coordinate the vertical bars of four VShTKUS MP BM bases with orthogonal tongues with VShDKS MPSHR with orthogonal tongues installed at coordinates OX, OY and OZ form four side openings, and VShDKS MPSHR with orthogonal tongues are made in the form of a bar square cross-section, the side of the square is equal to the thickness of the VShBP, and the length is equal to the length of the side of the VShBP, while on two adjacent sides of the block of square cross-section, two identical rectangular plates are installed in the center along the longitudinal axis, respectively, the length of which is equal to the length of the side of the VShBP, and the width and the thickness is equal to the depth and thickness of the internal tongue and groove of the VShBP, respectively, which are the external tongues of the VShDKS MPSHR with orthogonal tongues, and the external tongues of the VShDKS MPShR with the orthogonal tongues of the MP base of the BM are combined with the external tongues of the MP of the BM base;

- the MP BM AU circuit is assembled by installing VShTKUS MP BM on external horizontal tongues along the entire perimeter with internal tongues of VShBP, thereby forming MP BM, while in the area of connection of the end walls of adjacent VShBPs, VMPSH are installed, which are made in the form of rectangular plates whose length is equal or less than the length of the side of the VShBP, and the width and thickness are equal to twice the depth and thickness of the internal tongue of the VShBP, respectively;

- the formation of the side walls of the first row of BM AU with a hatch or side access door is carried out by installing in four side openings on the external horizontal and vertical tongues VShTKUS MP bases BM and VShDKS MPShR with orthogonal tongues and internal tongues VShBP forming the first row of side walls of the BM, while, at least one FSBP is installed in at least one side opening, and in the area of connection of the end walls of adjacent SSBPs of the first BM, BMSPs are installed in the internal tongues;

- the formation of the side openings of the BS BM AU is carried out by installing, along the OZ coordinate, on the vertical bar of each VShTKUS MP base of the BM, at least one VShDKS MPShR with orthogonal tongues, the outer tongues of which are combined with the external tongues of the corresponding vertical bars of the VShTKUS MP base of the BM, forming BM side openings in height;

- the formation of BS BM AU is carried out by installing in four side openings on the external tongue-and-groove VShDKS MSHR with orthogonal tongues and on the VMPSH VShBP of the first row of VShBP, and the number of additional rows of VShBP along the height of the opening is equal to the number of VShDKS MSHR with orthogonal tongues, while on the first row PSHBP at least one PSHBP door or hatch is installed, with the VShBP and PShBP connected to each other by the VMPSH;

- the formation of pediments of a single-pitched inclined part of the MK is carried out, consisting of one high straight pediment, which determines the angle of inclination, and two side inclined pediments, which are installed on the last row of the VSHBP BM, while a high straight pediment is formed on one side of the BM by installation at the corresponding two angles , as a continuation of the height of the BM, along at least one VShDKS MSHR with orthogonal tongues, the number of which determines the height of the straight pediment, while in the resulting opening of the straight pediment, as a continuation of the VShBP BS BM, VShBP, interconnected by VMPSh, are installed on the external tongues, at the same time, in the resulting opening of one and the other inclined side pediment, in the shape of a right triangle, formed as a convergence in a straight line from the height of the straight pediment on the BS BM, as a continuation of the VShBP BS BM, VShBP and VShBPD are installed, forming an inclined pediment and interconnected by the VMPSH;

- MK is formed by installing a high straight pediment on two adjacent corner VSHBPs and an inclined pediment on one and the other side of the last row of VSHBP, and on two adjacent corner VSHBP BM and VSHBPD inclined pediments on one and the other side of the last row of VSHBP, VShTKUS transitions with VSHBP are installed direct pediment on the inclined part of the MK, which are made by analogy with the VShTKUS base of the MP, respectively, in which two bars on each rack are located orthogonally and the external tongues of these two bars are installed in the internal tongues of the corresponding two adjacent corner VShBP of the high straight pediment and the side inclined pediment, respectively, and the third bars of one and the other VShTKUS transition are made inclined with an orthogonal external tongue, which are parallel to the inclination generatrix of the side inclined pediment, while in the formed horizontal openings between the VShDKS of one and the other VShTKUS transition from a high straight pediment and VShTKUS transition to an inclined pediment, VShDKS MPSHR with orthogonal and inclined tongues of the transition from the BS of the last row of the VShBP of a high straight pediment to the inclined part of the MK, respectively, while the orthogonal tongue is installed in the internal tongue of the VSHBP, and the inclined tongue of the VShDKS MPSHR is located at an angle of inclination equal to the angle of inclination of the external tongue of the third bar of the corresponding VShTKUS transition, Moreover, the number of VShDKS MPSHR with orthogonal and inclined transition tongues is equal to the number of VShDKS MPSHR with orthogonal tongues MP BM along the corresponding coordinate side of the BM, while in the resulting openings between the third inclined VShDKS of the corresponding VShTKUS transition along the generatrix of the inclined pediment, VShDKS MPSHR with orthogonal tongues identical to VShDUS are installed MSHR with orthogonal tongues MP BM, with one tongue installed in the internal tongue VShBP of the inclined pediment, and the second tongue lies in the same plane with the external tongue of the third inclined external tongue-and-groove two-coordinate beam VShTKUS transition along the generatrix of the inclined transition;

- the flat part of the MK is assembled by installing on the external tongues four VShTKUS transitions to the flat inclined part of the MK and on the external tongues VShDKS MPSHR transitions to the flat part of the MK VShBP and VShBPD of the flat part of the MK, while the end walls of the adjacent VShBP of the flat part of the MK are connected to each other VMPSH.

The method consists in strengthening the rigidity of the connection on the inside of the BM end walls of adjacent VShBP, VShBP MP and VShBP and VShBPD MK by installing dielectric internal interpanel stiffeners (VMPUZH), which consists of a rectangular base plate and a plate located on it, perpendicular to the longitudinal axis stiffening amplifier, wherein the width of the base plate is equal to the width of the VMPSH, and the length of the base plate and the length of the stiffening amplifier plate are equal to or less than the length of the VMPSH, and the base plate of the VMPUS is attached by rigid fixation to the VSHBP.

Since the MP and MK are assembled from identical VSHBMs, dielectric VMSLMs can be used to enhance the rigidity of their connection.

The method consists of vertically strengthening the rigidity of the connection from the inside of the BM VShBP MP with the VShBP BS BM and the VShBP BS BM with the VShBP MK by installing dielectric interpanel transition corner stiffeners (MPPUUZH), made of two plates in the shape of an internal corner, with one plate MPPUUZH is installed on the area of connection of the end walls of adjacent VShBP BS BM, and for the MP the internal angle is made straight and another plate is installed on the area of connection of the end walls of adjacent VShBP MP, and for the MK the internal corner is made with a slope corresponding to the inclination of the MC in relation to the VShBP BS BM, and the other plate is installed on the area of connection of the end walls of adjacent VShBP MK, and the MPPUUZh plates are rigidly attached to the corresponding VShBP BS BM, MP and MK.

The method consists in making the MPPUUZH in the form of a ⊥-shaped bearing plate, which is one face of the MPPUUZH, in the center of the vertical beam of which a thrust stand is installed perpendicularly, which is the other face of the MPPUUZH, made in the form of a rectangular plate, while the length of the horizontal beam of the bearing plate is shaped is equal to the length of the side of the VShBP, and the height of the vertical beam and the length of the thrust post are equal to half the length of the VShBP, and the vertical beam of the ⊥-shaped supporting plate is installed on the area of connection of the VShBP BS BM with the MSHR.

The method consists of strengthening the rigidity of a vertical corner joint, on the inside of the BM, VShBP of neighboring BM BSs, connected to each other through the MSR, by installing dielectric vertical interpanel internal corner stiffeners (VMPVUUZH) BM BSs, made in the form of a right dihedral angle, one and the other the edges of which are made in the form of rectangular plates, wherein the length of the dihedral angle face is equal to or less than the length of the VMPSH, and the width is equal to or greater than half the width of the VMPSH, while on the inner side of the right dihedral angle VMPVUUZh a dielectric, at least one dielectric corner spacer is installed in in the form of a plate, the outer contour of which is made in the form of an equilateral hyperbola, the asymptotes of which are mutually perpendicular, while one and the other branches of the outer contour of the corner spacer are installed on one and the other plate of the internal faces of the VMPVUUZH, respectively, while the VMPVUUZH plates are attached to the corresponding VShBP using studs with fixation with nuts or cold welding. (For example - “Equilateral hyperbola”, I.N. Bronstein and K.A. Semendyaev, Handbook of Mathematics, M.: Nauka, 1967, p. 210).

The method consists in strengthening the rigidity of the BM MC by installing at least one dielectric horizontal load-bearing beam installed symmetrically between one and the other side walls of the BM, and the ends of the load-bearing beam are fixed to the opposite edges of the MPPUUZH VShBP of one and the other BS BM, while between the horizontal The load-bearing beam and MPPUUZH BP MK are equipped with dielectric slopes in the form of dielectric plates, forming triangular trusses that form the floating ceiling of the MK. This floating roof design eliminates the possibility of sagging and thereby eliminates the possibility of accumulation of precipitation in the form of water.

For example: (Electronic resource: [Access mode] (уаn-dех.ru/search/?tехt=frame%20floating%20ceiling%20in%20hangars&1r=2 13).

The method consists in power strengthening of the BM by installing guy wire clamps in the corners of the upper row of the VShBP and/or in the lower rows of the VShBP on the outer and/or inner side of the BM.

Guy rope clamps are made of dielectric material with holes for fastening guy ropes. Guy rope clamps are installed both on the outside and on the inside of the AU.

Rigid fixation of VShBP with each other through VMPSh, fixation of VShBP with VShTKUS, with VShDKS MShR, with VShDKS, as well as fixation and/or connection of MPPUUZH, fixation of coordinate MPSHR, VMPUZH, MPPUUZH, VMPVUUZH is carried out by a threaded connection using dielectric pins and/or dielectric bolts and /or cold welding (glue).

Threaded holes for installing dielectric pins or bolts are made blind, so as not to disturb the external appearance of the AC, i.e. disguise.

The use of cold welding with glue together with dielectric studs or dielectric bolts can significantly increase the strength of the AC structure, especially under weather and wind loads.

AC masking can be done in two ways.

The first method of camouflage is carried out by performing a planar pattern by applying radio-transparent paint to all external surfaces of the AC.

The second method of masking is carried out by performing a three-dimensional pattern using mechanical processing, for example, by milling or installing by cold welding (with glue) dielectric panels imitating the building material of the installation object, on the side walls of the BS BM, and on the MK dielectric panels imitating the roof covering of the installation object. The color of dielectric panels is selected either by paint or by the own color of the dielectric material. All this work must be performed in production and for a specific facility.

The door or hatch for access to the inside of the AU is assembled from at least one PSHBP and can be connected to the VMPSH installed in the VShBP and/or to the VShTKUS, and/or to the external tongues of the VShDKS MPShR using dielectric hinges, which are secured using dielectric bolts.

In this case, the VMPSH VShBP for the PShBP door or hatch at the places of their installation acts as an internal limiting door frame. If a door or hatch is made of several PSHBP, then they are connected to each other by VMPS and fixed with dielectric bolts or studs, and additionally fixed by cold welding.

An AC door made using this method can be installed on one or several side walls at the same time. The peculiarity of this design of the AC is the possibility, if necessary, at the assembly stage of the AC not to assemble, or to disassemble, with the structure already assembled, one side wall of the BM with the door, while the integrity of the AC is not violated. This operation is performed at the stage when it is necessary to install bulky equipment inside the AC. In this case, the equipment is installed, and then this side wall of the AC is assembled or added.

If the dimensions of the equipment can be installed through a door or hatch, then the AU is assembled completely.

It is possible to partially or completely close the MP AC by installing VShBP in the free openings of the MP circuit, while in the area of connection of the end walls of adjacent MP VShBP, VMPSH are installed.

Partial or complete closure of the MP VShBP is determined by the installation conditions at the site and/or operating conditions of the AK.

The MP AC base contour, formed from VSHBP, allows for fastening to the foundation of an object, for example, with anchor bolts, or bolts to a car body or to a railway platform.

The dimensions of the AC according to this method can be carried out with an arbitrary expansion step equal to the size of the VShBP, along any coordinate OX, OY and OZ (width, length, height) without changing the nomenclature of the type of dimensions of the parts, but simply changing their number, which ensures the versatility of the design, and this means the possibility of using camouflage for a wide range of antenna types, including large ones.

The nomenclature of the type of part sizes allows you to build internal partitions into the BM AC, as well as attach an extension to the BM from the outside without violating the unity of the AC design.

Forced or natural air exchange of the internal volume of the AC is carried out by making ventilation holes in the VSHBP, where fans or air ducts can be installed, for example, for an air conditioning system.

The invention is illustrated by the following drawings.

In fig. 1 - shows a schematic general view of an AC with planar masquerading, with an inclined pitched roof made, for example, with a BM in the form of a parallelepith and a MC with a slope in the shape of a right triangle, with the expansion of the VShBP of the transverse dimensions of the base of the AC 1 VShBM, for example, six by eight VSBP and BM height five VSBP, with a double-leaf door of internal access, with the size of each leaf one per four PSHBP, installed on hinges with a lock, with external guy fasteners installed in the corners of the upper and lower rows of VSBP side walls of the BM, with frameless transition to MK , with a canopy over the door;

in fig. 2 - shows a fragment of the side wall of the BM AC (Fig. 1) with the implementation of volumetric camouflage of external BS BSBM, for example, under brickwork, when the imitation of brickwork is made of dielectric plates of the appropriate size and color, installed (for example by cold welding) on the GSBP, PSHBP , VShBPD of pediments, and the external surfaces of the VShTKUS base of the BM, the transition from the BM to the inclined part of the MK, VShDKS MSHR are painted in the appropriate color or volumetric dielectric linings are also made in the appropriate color, or a volumetric pattern is milled and with external brace fasteners installed in the corners of the upper row of the VShBP side walls;

in fig. Figure 3 shows a fragment of the formation of the base of the BM and the base of the MP AC (Fig. 1) by installing four corner VShTKUS in the four corners of the base of the BM, in the horizontal openings between them VShDKS MPSHR are installed, for example, seven and five respectively, on the external tongues of which they are installed VShBP, forming the first row of BM with an opening for the side entrance door, and with VShBP installed in the opening, forming a closed perimeter base of the MP, on the vertical bars of the four corner VShTKUS along the OU coordinate, VShDKS MPSHR are installed, respectively;

in fig. 4 - shows a fragment that completes the formation of the base of the BM AC 1 (Fig. 1) by installing the VMPSH between the VShBP and the installation of the VMPUZH and the installation of the MPPUUZH;

in fig. Figure 5 shows a fragment of a completed BM assembly with a side access doorway, for example, the height of the side access doorway is four PShBP and the width is two PShBP, with the installation of VMPUZH, the installation of MPPUUZH and the installation of VMPVUUZH;

in fig. 6 - shows a fragment of the BM AU (Fig. 5) with a double-leaf side door installed on hinges;

in fig. 7 - shows a fragment of the BM (Fig. 5) with an installed single-slope inclined MC and fastening the BM to the foundation using anchor bolts.

The method of masking the AC and its implementation is as follows.

Masking is a decorative finishing of the external surface of the AC, which can be performed in two types - planar or volumetric.

Decorative finishing is performed on the external surfaces of the following structural elements of AU 1 (Fig. 1): VShBP 2 side walls of the BM; PSHBP 5 side access doors; VSHBPD 6 side gables of the inclined part of the MK; VSHTKUS 3 BM bases; VSHDKS 4 MPSHR with orthogonal tongues along the OX and OY coordinates of the base of the BM and along the OZ coordinate of the height of the side walls of the BM; VSHTKUS 7 transition from VShBP 2 straight pediment to the inclined part of the MK; VSHDUS 8 МПШР with an orthogonal tongue and groove for the transition from the straight pediment of the side walls of the BM to the inclined part of the MK; VSHTKUS 9 transition from the side wall of the BM to the inclined part of the MC; VSHDUS 10 MPSHR with an orthogonal tongue and groove for the transition from the side wall of the BM to the inclined part of the MK; visor 11 over PSHBP 5 side access doors; dielectric loops 12; retainer for external guy wires 13.

Planar decorative finishing is carried out in the form of a continuous monochromatic coating of paint on a flat surface or in the form of a pattern imitating a building material, for example: brickwork, masonry made of building blocks, wooden or plastic panels or other building materials.

Volumetric decorative finishing AU 1 (Fig. 2) is made in the form of a volumetric pattern and can be technologically performed, for example, mechanically by milling the outer surface, or by cold welding using special glue, overlay elements made of similar electrophysical parameters and electrodynamic characteristics dielectric material, and subsequent decorative finishing either by selecting the color of the dielectric material or by painting.

Decorative finishing of the external surfaces of VSHBP 2 of the inclined part of the MK can be carried out either by the planar method, by painting, or by the volumetric method, by making a volumetric pattern with a profile identical to the profile of the coating material used for the installation object AU 1, for example, corrugated iron, metal tiles, andulin , slate and subsequent painting.

Work on decorative finishing of AU 1 is carried out, as a rule, in production during the manufacture of structural elements for a known installation object or terrain.

A fragment of one side wall AU 1 with volumetric decorative finishing of the VShBP 2 side walls made, for example, (Fig. 2) is schematically represented as brickwork, imitation brick 14 is made, for example, from thin dielectric plates the size of a brick, installed by cold welding on the VShBP 2, and the seam, in the form of a brick mortar, can be made with paint. The guy wire clamps 13 are installed on the side walls of the AC 1, for example, along the top row of the VShBP 2 BM.

The formation of the base of the BM AU 1 (Fig. 3) is carried out by installing four VShTKUS 3 in the four corners of the base of the BM, in the horizontal openings between the VShTKUS 3 there are installed VShDKS 4 MPSHR with orthogonal tongues along the coordinates OX and OY in some openings seven and in other openings five, with installed VShBP 2, forming the first row of side walls of the BM with an opening for the side entrance door, and installed VShBP forming the MP base closed along the perimeter.

Complete formation of the base of BM AC 1 (Fig. 4) is carried out by installing VMPSH 15 between VSHBP 2 and the installation of VMPUZH 16 and the installation of VMPVUUZH 17.

Full-height BM assembly (Fig. 5) with a side access doorway, for example, the height of the side opening of four PShBP 5 and the width of two PShBM 5.

Fully completed assembly of BM AU 1 (Fig. 6) with a double-leaf side door installed on hinges 12.

Fully assembled AC 1 with MK (Fig. 7) and an example of fastening the MP, formed from VShBP 2, to the foundation using anchor bolts 18.

To create a monolithic AU structure, the tongue and groove connections of all AU 1 elements can be glued together with a special glue (cold welding), which creates a seemingly monolithic structure and, in addition, ensures high waterproofing of the joint seams. Additionally, you can improve the waterproofing of the lining by sealing the seams with silicone sealant.

Claims (20)

1. A method for masking an antenna device by using a protective radio-transparent modularly expandable with a constant step along any of the OX and OY coordinates of the base and OZ of the height of the sides of a dielectric ground antenna cover, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which camouflage is made in the form decorative finishing that imitates the appearance of an object or landscape where an antenna shelter is installed, consisting of a frameless assembly of a base module made in the form of a parallelipiped, with a frameless transition to the assembly of a roof module made of a gable roof with a flat top in the shape of a trapezoid, by installing external tongue-and-groove sheets on external tongues three-coordinate corner posts of the base module base, external tongue-and-groove two-coordinate sections of inter-panel step expanders along the OX and OY coordinates of the base module and along the OZ coordinate of the height of the side walls of the base module of the rectangular coordinate system, external tongue-and-groove three-coordinate corner posts of the transition from the side walls of the base module to the inclined part of the roof module , external tongue-and-groove two-coordinate sections of inter-panel-step expanders of the inclined transition from the side walls of the base module to the inclined part of the roof module, external two-coordinate two-coordinate sections of inter-panel-step expanders of the inclined part of the roof module, external tongue-and-groove three-coordinate corner posts of the transition from the inclined part of the roof module to the flat part of the roof module, external tongue-and-groove two-coordinate sections of inter-panel-step expanders of the inclined transition from the inclined part of the roof module to the flat part of the roof module with internal tongue-and-groove base panels, half-tongue base panels and internal tongue-and-groove base panels for adding the roof module, wherein the square-shaped intra-tongue base panels form the floor module, side walls of the base module, gables of the roof module, inclined and flat parts of the roof module with corresponding internal tongue-and-groove panels for complementing the base panels, while the half-tongue base panels form a hatch or side access door inside the base module, and the transverse dimensions of the half-tongue base panels are equal to the transverse dimensions of the internal tongue-and-groove panels base panels, and the depth and thickness of the internal tongue of the internal tongue-and-groove base panels and the depth and thickness of the half-tongue of the half-tongue base panels are the same, while the internal tongue-and-groove base panels, half-tongue base panels and internal tongue-and-groove panels of base panels are connected to each other by external interpanel tongues, which are made in the form of a rectangular plate , the width and thickness of which are equal to twice the depth and thickness of the internal tongue and groove of the internal tongue-and-groove base panel, respectively, and the length of the external inter-panel tongue is equal to the length of the side of the interconnected internal tongue-and-groove base panels, and/or half-tongue base panels, and/or the length of the side of the interconnected internal tongue-and-groove base panels of the extension, In this case, camouflage and assembly of the antenna cover is carried out in the following stages: - masking of the external surfaces of internal tongue-and-groove base panels, half-tongue base panels, internal tongue-and-groove base extension panels, external tongue-and-groove three-coordinate corner posts of the base module base, external tongue-and-groove two-coordinate sections of inter-panel-step expanders with orthogonal tongues, external tongue-and-groove three-coordinate corner posts of the transition from the side walls of the base module to the inclined part are carried out roof module, external tongue-and-groove two-coordinate sections of inter-panel-step expanders of the inclined transition from the side walls of the base module to the inclined part of the roof module, external tongue-and-groove two-coordinate sections of inter-panel-step expanders of the inclined part of the roof module, external tongue-and-groove three-coordinate corner posts of the transition from the inclined part of the roof module to the flat part of the roof module , external tongue-and-groove two-coordinate sections of inter-panel step expanders of the inclined transition from the inclined part of the roof module to the flat part of the roof module by performing planar or volumetric decorative finishing that imitates the appearance of the object or landscape on which the antenna shelter is installed; - the base of the base module of the antenna shelter is formed along the OX and OY coordinates by installing in the four corners of the base of the base module four external three-coordinate corner posts of the base module, respectively, with each external three-coordinate corner post of the base module located in its own rectangular coordinate system, with the outer tongue the three-coordinate corner post of the base module is made of three identical bars located along the OX, OY and OZ coordinates of the rectangular coordinate system, respectively, and the bars are made of a square cross-section, the side of the square is equal to the thickness of the internal tongue-and-groove base panel, and the length is equal to half the length of the internal tongue-and-groove base panel, Moreover, in three coordinate planes ZOX, ZOY and XOY, three identical plates are made along the longitudinal axis on the bars of each external three-coordinate corner post of the base module -shaped, the right angles of which are located at the origin of the coordinate system, respectively, the plate -shaped consists of a plate of a horizontal branch and a plate of a vertical branch, and on each external tongue-and-groove three-coordinate corner post of the base of the base module in the XOY plane there are plates of four branches oriented horizontally, and in the ZOY plane and in the ZOX plane there are one plate of branches oriented vertically accordingly, while the plates -shaped horizontal and vertical branches are made of the same length and are equal to half the length of the internal tongue-and-groove base panels, and the width and thickness of the plates of the horizontal and vertical branches are equal to the depth and thickness of the internal tongue of the internal tongue-and-groove base panel, respectively, and are external tongues for internal tongue-and-groove base panels, and along the OX coordinate and along the OY coordinate between the horizontal bars of the four external tongue-and-groove three-coordinate corner posts of the base module, at least two external tongue-and-groove two-coordinate sections of intermodular step expanders with orthogonal tongues are installed in each of the four horizontal openings, while along the OZ coordinate the vertical bars of the four external tongue-and-groove three-coordinate corner posts the bases of the base module with external two-coordinate two-coordinate sections of intermodular-step expanders with orthogonal tongues installed along the coordinates OX, OY and OZ form four side openings, and the external two-coordinate sections of inter-modular-step expanders with orthogonal tongues are made in the form of a block of square cross-section, the side of the square is equal to thickness of the internal tongue-and-groove base panel, and the length is equal to the length of the side of the internal tongue-and-groove base panel, while on two adjacent sides of a block of square cross-section, two identical rectangular plates are installed in the center along the longitudinal axis, respectively, the length of which is equal to the length of the side of the internal tongue-and-groove base panel, and the width and thickness are equal the depth and thickness of the internal tongue and groove of the internal tongue-and-groove base panel, respectively, which are the external tongues of the external tongue-and-groove two-coordinate sections of the intermodular-step expanders with orthogonal tongues, and the external tongues of the external tongue-and-groove two-coordinate section of the intermodular-step expanders with orthogonal tongues of the base of the base module are combined with the external tongues of the external tongue-and-groove three-piece ordinate angular base module supports; - the circuit of the antenna shelter floor module is assembled by installing the base module base on the external horizontal tongues along the entire perimeter with internal tongues of internal tongue-and-groove base panels, thereby forming a floor module, while in the area of connection of the end walls of adjacent internal tongue-and-groove base panels, external intermodular tongues are installed, which are made in the form of rectangular plates, the length of which is equal to or less than the length of the side of the internal tongue-and-groove base panel, and the width and thickness are equal to twice the depth and thickness of the internal tongue of the internal tongue-and-groove panel, respectively; - the side walls of the first row of the base module of the antenna shelter with a hatch or side access door are formed by installing in four side openings on the external horizontal and vertical tongues external tongue-and-groove three-coordinate corner posts of the base module and external tongue-and-groove two-coordinate sections of intermodule-step expanders with orthogonal tongues and internal tongues of internal sheet piles base panels, forming the first row of side walls of the base module, wherein at least one half-tongue base panel is installed in at least one side opening, and in the area of connection of the end walls of adjacent intra-tongue base panels of the first base row, external intermodular tongues are installed in the internal tongues; - the height of the side walls of the base module of the antenna shelter is formed by installing, along the OZ coordinate, on the vertical block of each external tongue-and-groove three-coordinate corner post of the base module of at least one external tongue-and-groove two-coordinate section of an intermodule-step expander with orthogonal tongues, the external tongues of which are combined with the external tongues of the corresponding vertical bars of external tongue-and-groove three-coordinate corner posts of the base of the base module, forming the height of the side openings of the base module; - the formation of the full height of the side walls of the base module of the antenna shelter is carried out by installing in four side openings on external tongue-and-groove two-coordinate sections of intermodular-step expanders with orthogonal tongues and on external intermodular tongues of internal tongue-and-groove base panels of the first row of internal tongue-and-groove base panels, and the number of additional rows of internal tongue-and-groove base panels panels along the height of the opening are equal to the number of external tongue-and-groove two-coordinate sections of intermodular-step expanders with orthogonal tongues, while at least one half-tongue panel for adding a door or hatch is installed on the half-tongue panel of the first row, and the internal tongue-and-groove base panels and half-tongue panels are connected to each other by external intermodular tongues; - the transition is assembled from the last row of internal tongue-and-groove base panels of the two side walls of the base module to the inclined part of the roof module while simultaneously continuing the assembly of two other opposite side walls of the straight gables of the roof module by installing external tongue-and-groove three-coordinate corner posts of the transition on the four corners of the last row of internal tongue-and-groove base panels of the base module from the side walls of the base module to the inclined part of the roof module, which are made on the basis of an external tongue-and-groove three-coordinate corner post of the base module, in which two bars are located along the orthogonal coordinates OX and OZ or orthogonal coordinates OY and OZ, while the external tongues of the three-coordinate corner posts of the transition are installed into the internal tongues of two adjacent corner internal tongue-and-groove base panels of the side wall, respectively, and the third bar of the three-coordinate corner transition post is located at an angle corresponding to the angle of inclination of the inclined part of the roof module in the direction of the pediment edge, while in the resulting horizontal openings in the area of the inclined transition along the OX or along the OY coordinate, between the horizontal two-coordinate bars of external tongue-and-groove three-coordinate corner posts of the transition from the side walls of the base module to the inclined part of the roof module, external tongue-and-groove two-coordinate sections of inter-panel-step expanders for the transition from the side walls of the base module to the inclined part of the roof module are installed, in which one external horizontal tongue is located orthogonally two-coordinate beam and installed in the inner tongue of the internal tongue-and-groove base panel of the last row of the base module, and the other tongue is located obliquely at an angle to the two-coordinate beam corresponding to the angle of inclination of the inclined part of the roof module, and the number of external tongue-and-groove two-coordinate sections of inter-panel-step expanders for the transition from the side walls of the base module to the inclined part of the roof module is equal to the number of external tongue-and-groove two-coordinate sections of intermodule-step expanders with orthogonal tongues of the base module on the corresponding side, with the external tongues of the third bars of three-coordinate corner transition posts located at an angle, and the external tongues of external tongue-and-groove two-coordinate sections of inter-panel-step expanders located between the horizontal bars three-coordinate corner posts of the transition, form two side openings, while external intermodular tongues are installed into the internal tongues of the internal tongue-and-groove base panels of the last row of gables of the base module; - the first row of the inclined part of the roof module is assembled, consisting of two side openings and two straight gables, which are a continuation of the side walls of the base module, respectively, and consists of installing the side openings on the external tongues with the internal tongues of the internal tongue-and-groove base panels, and on the side of the straight gables on external intermodular tongues installed in the internal tongue-and-groove base panels of the side walls of the last row of the base module, internal tongue-and-groove base panels and internal tongue-and-groove base panels for the addition of the pediment row; - the formation of full-size openings of the inclined part of the roof module is carried out by installing on the end of the third bar of each three-coordinate corner post of the transition, located at the angle of inclination of the roof module of at least one external tongue-and-groove two-coordinate section with orthogonal external tongues of intermodular-step expanders of the base module, while the external tongues external tongue-and-groove sections with orthogonal external tongues of intermodular-step expanders are combined with external tongues of the corresponding third bars of the three-coordinate corner post of the transition of the roof module, forming two opposite side inclined external tongue-and-groove openings of the inclined part of the roof module and two side opposite external tongue-and-groove openings of the direct pediment of a trapezoidal shape; - the formation of the lateral inclined part and straight gables of the roof module is carried out by installing on external tongues in two lateral inclined openings and in two lateral straight openings, internal tongue-and-groove base panels and internal tongue-and-groove base panels for adding gables, respectively, and the total number of rows of internal tongue-and-groove base panels of the inclined part and straight ones gables of the roof module is equal to the number of external tongue-and-groove two-coordinate sections with orthogonal external tongues of intermodular-step expanders forming the width of the full-size slope, while the end walls of adjacent internal tongue-and-groove base panels of inclined openings and internal tongue-and-groove base panels of straight gables are connected by external intermodular tongues; - the transition from the last row of internal tongue-and-groove base panels of the inclined part of the roof module, internal tongue-and-groove base panels and internal tongue-and-groove base panels for the addition of straight gables to the flat part of the roof module is assembled by installing external three-dimensional corner posts of the transition from the inclined part of the roof module on the four corners of the last row of internal tongue-and-groove base panels and straight gables on the flat part of the roof module, which are made on the basis of an external tongue-and-groove three-coordinate corner post of the base module, in which two bars are located along the orthogonal coordinates OX and OY, and the third bar is located at an angle corresponding to the angle of inclination of the inclined part of the roof module in the direction of the edge pediment, and the external tongues of the inclined beam of external tongue-and-groove three-coordinate corner posts are installed in the internal tongues of the last row of two adjacent corner internal tongue-and-groove base panels of the last row, one of which is the base panel of the straight pediment, and the other is the base panel of the inclined part of the roof module, while in the internal horizontal the tongues of these two corner internal tongue-and-groove base panels are installed, the external vertical tongues of two orthogonally located along the OX and OY coordinates of the three-coordinate corner posts are installed, respectively, and the other tongues of these bars are located horizontally in the plane of the roof module, while in two formed opposite horizontal openings of an inclined transition between the ends of the horizontal bars of four external tongue-and-groove three-coordinate corner posts for the transition from the inclined part of the roof module to the flat part of the roof module, external tongue-and-groove two-coordinate sections of the inclined transitional intermodule-step expander are installed from the inclined part of the roof module to the flat part of the roof module, in which one external tongue is made at an angle to the plane of the bar and located in the same plane with the external tongue of the third external tongue-and-groove two-coordinate beam of the external tongue-and-groove three-coordinate corner post of the transition from the inclined part of the roof module to the flat part of the roof module and is installed in the internal tongue of the last row of internal tongue-and-groove base panels of the inclined part of the roof module, and the second external tongue is made perpendicular to the beam and is located in the flat part of the roof module, while between the ends of the horizontal bars located in the internal tongue-and-groove base modules of the straight gables of the four external tongue-and-groove three-coordinate corner posts of the transition from the inclined part of the roof module to the flat part of the roof module, external tongue-and-groove two-coordinate sections with orthogonal external tongues of intermodular-step expanders of the base module are installed , providing a perpendicular transition from the gable plane to the flat part of the roof module, wherein one external tongue is installed in the internal tongue of the last row of internal tongue-and-groove base panels of the gable and internal tongue-and-groove base panels for the addition of gables, and the second external tongue forms the flat part of the roof module, while the number of external tongue-and-groove two-coordinate sections the intermodular-step gable extender determines the size of the roof module on the corresponding side; - the horizontal part is assembled in the coordinate plane OX and OY of the roof module by installing on the external horizontal tongues of external tongue-and-groove three-coordinate corner posts of the transition from the inclined part of the roof module to the flat part of the roof module, on the external horizontal tongues of external tongue-and-groove two-coordinate sections of transitional intermodular-step expanders from the inclined part roof module to the flat part of the roof module and to the external horizontal tongues of external tongue-and-groove two-coordinate sections of direct transitional intermodular-step expanders from the pediment of the roof module to the flat part of the roof module of internal tongue-and-groove base panels and internal tongue-and-groove base panels for completing the flat part of the roof module, while the end walls of adjacent internal tongue-and-groove base panels The panels of the flat part of the roof module are connected to each other by external intermodular tongues. 2. The method according to claim 1, which consists in vertically strengthening the rigidity of the connection from the inside of the base module of the end walls of adjacent internal tongue-and-groove base panels, internal tongue-and-groove base panels of the floor module, and internal tongue-and-groove base panels, and internal tongue-and-groove base panels of the roof module extension by installing dielectric interpanel corner reinforcements rigidity, which consists of a rectangular base plate and a stiffening amplifier plate located on it perpendicularly along the longitudinal axis, wherein the width of the base plate is equal to the width of the external intermodular tongue, and the length of the base plate and the length of the stiffening plate are equal to or less than the length of the external intermodular tongue, and the plate The base of the intermodular stiffener is fixed with rigid fixation to the internal tongue-and-groove base panels. 3. The method according to claim 1, which consists in vertically strengthening the rigidity of the connection on the inside of the base module of the internal tongue-and-groove base panels of the floor module with the internal tongue-and-groove base panels of the side walls of the base module and the internal tongue-and-groove base panels of the side walls of the base module with the internal tongue-and-groove base panels of the roof module by installing dielectric intermodular corner amplifiers made of two plates in the form of an internal corner, with one plate of the intermodular corner amplifier being installed on the area of connection of the end walls of adjacent internal tongue-and-groove base panels of the side walls of the base module, and for the floor module the internal corner is made straight and the other plate is installed on the area of connection of the end the walls of the adjacent intra-tongue base panels of the floor module, and for the roof module, the internal angle is made obtuse with a slope corresponding to the inclination of the roof module, and another plate is installed on the area of connection of the end walls of the adjacent intra-tongue base panels of the roof module, and the plates of the inter-modular corner amplifiers are rigidly attached to the corresponding intra-tongue panels base panels for the side walls of the base module, floor module and roof module. 4. The method according to claim 3, which consists in making intermodular corner amplifiers in the form of a carrier plate -shaped, which is one face of the intermodular corner amplifier, in the center of the vertical beam of which a thrust stand is installed perpendicularly, which is the other face of the intermodular corner amplifier, made in the form of a rectangular plate, while the length of the horizontal beam of the carrier plate -shaped is equal to the length of the side of the internal tongue-and-groove base panel, and the height of the vertical beam and the length of the thrust post are equal to half the length of the internal tongue-and-groove base panel, and the vertical beam of the load-bearing plate -shaped is installed on the area of connection of the internal tongue-and-groove base panels of the side walls of the base module with the coordinate inter-module step expander. 5. The method according to claim 1, which consists in making intermodular corner amplifiers in the form of a right dihedral angle, one and the other faces of which are made in the form of rectangular plates, while on the edge of the intermodular corner amplifiers from the side of the internal right angle, a corner amplifier plate is installed perpendicular to the center -shaped, the length of the horizontal and vertical beams of which is equal to the length of the face of the right dihedral angle on which it is installed, and the length of the plate of one and the other face is less than or equal to half the length of the external intermodular tongue, and the width of the plate of one and the other face is equal to the width of the external intermodular tongue , while one and the other face of the intermodular corner amplifiers are attached to the studs of rigid fixation of the internal tongue-and-groove base panels of the floor module, internal tongue-and-groove base panels of the side walls of the base module and internal tongue-and-groove base panels of the roof module, respectively. 6. The method according to claim 1, which consists in strengthening the rigidity of the vertical corner connection on the inside of the base module, the internal tongue-and-groove base panels of the adjacent side walls of the base module connected through a coordinate intermodule-step expander by installing dielectric vertical internal corner stiffeners of the side walls of the base module, made in the form of a right dihedral angle, one and the other faces of which are made in the form of rectangular plates, and the length of the dihedral angle face is equal to or less than the length of the external intermodular tongue, and the width is equal to or more than half the width of the external intermodular tongue, while on the inside of the right dihedral angle of the vertical internal corner stiffener, a dielectric at least one corner strut is installed in the form of a plate, the outer contour of which is made in the form of an equilateral hyperbola, the asymptotes of which are mutually perpendicular, while one and the other branches of the outer contour of the corner strut are installed on one and the other plate of the internal faces of the vertical internal corner stiffeners respectively. 7. The method according to claim 3, consisting in strengthening the roof module of the base module by installing at least one dielectric horizontal load-bearing beam installed symmetrically between one and the other side walls, and the ends of the load-bearing beam are fixed to intermodular stiffeners of the internal tongue-and-groove base panels of one and other side walls, while dielectric slopes in the form of dielectric plates are installed between the horizontal load-bearing beam and the intermodular stiffeners of the internal tongue-and-groove base panels of the roof module, forming triangular trusses that form a floating ceiling. 8. The method according to claim 1, consisting in power strengthening of the base module by installing guy clamps in the corners of the top row of internal tongue-and-groove base panels, and/or in the lower rows of internal tongue-and-groove base panels on the outside and/or inside of the base module.

Images