RU2799348C1 - Antenna masking method and device for its implementation - Google Patents

Abstract

FIELD: masking of ground-based antennas.

SUBSTANCE: invention relates to antenna shelters (AS) 1, disguised as an installation object or the surrounding landscape. The technical result of this invention (Fig. 1) is the creation of disguised AS 1 by 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. The technical result is achieved by the fact that the outer surfaces of external interlocking three-coordinate corner posts, external interlocking two-coordinate sections of inter-modular step expanders, internal interlocking base panels and extensions of gables of internal interlocking base panels, half-interlocking base panels 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 disguised antenna shelters.

8 cl, 7 dwg

Description

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

Radiotransparent dielectric AC AK with masking 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 a chimney pipe, while masking is carried out by painting or a three-dimensional decorative finish made on the outer surface of the AC, which emits a building structure and harmoniously fits into the architecture of the building;

- on the ground in urban or rural areas, while camouflage is carried out, for example, under a change house, or a garage, or under an outbuilding with an appropriate exterior finish in the form of painting or a three-dimensional decorative finish;

- 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 (pickup type), 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.

AK, located outside any protective shelter or camouflage, have visual unmasking features that can be used to determine: - type of antenna and its dimensions, and hence the frequency range; - the width of the main lobe of the radiation pattern; - orientation in azimuth and elevation of the direction of the main lobe of the AP; - the level of the side lobes and the angles of their orientation in space with respect to the main lobe of the AP; - polarization; - the possibility of changing the position of the antenna in space, namely electrical or electromechanical scanning, or a stationary position.

Knowing these parameters makes it possible to determine the true purpose of the AK, which allows, if necessary, to either physically destroy the AK, or to carry out a destructive targeted effect on the AK, for example, in the direction of the main lobe of the DN and in the direction of the BL, with destructive electromagnetic fields, or, for example, setting polarization interference, which is currently widely and effectively used in electronic warfare tasks and which is difficult to identify as targeted interference, or short magnetic or electromagnetic pulses, as well as electromagnetic fields based on new physical principles, such as longitudinal electric and magnetic waves: longitudinal electric waves (in direction E); longitudinal magnetic waves (in the direction H); torsion waves (along Η with a 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 AC can lead, for example, to temporary electromagnetic blindness with subsequent restoration of functioning or burning out of AC input circuits, i.e. physical destruction.

A known method of creating protective radio-transparent AU frame type, performed dome-shaped in the form of a sphere based on fiberglass, for example, for large terrestrial reflector antennas. The sphere is assembled from the correct form of geometric segments, for example, triangular or hexagonal, mounted on a frame, which, as a rule, is made of metal. The frame structure consists of hundreds of homogeneous metal beams, pins and connecting mechanisms that are assembled into a single structure. (For example: Electronic resource: [Access mode] (https://locplaver/m/47442744-Ukrytiva-antennvh-ustroystv-dioprozrachnye/html).

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

A known method of creating a frameless radio-transparent AU to protect antennas spherical shape. For example (RF patent No. 2419927 IPC H01Q 1/42, "Radio-transparent shelter for antennas, method of its manufacture and fastening"). Radiotransparent AU has a one-piece one-piece design and is made of multilayer composite materials, which is based on fiberglass and epoxy resin. The AU design is made for a certain type of antennas and certain sizes and is attached to a carrier platform or base.

The main function of such AC is protection only from external climatic and mechanical influences. Such AUs are used, for example, for reflector antennas or truncated parabolic antennas, for phased antenna arrays.

Such AU designs have two unmasking signs: the first is AU, and the second - the frequency range can be roughly determined by the diameter.

A known method of masking AK from the means of visual observation using radio-transparent camouflage nets located on the frame. For example (RF patent No. 2546470, MCP F44H 3/00).

This method of AK camouflage is used as a temporary and severely weather-limited operation and, as a rule, is used for short-term camouflage under the terrain.

Known methods of camouflage in the open space of the AK, presented in the foreign press, in particular as one of the areas of application - this is the camouflage of communications, camouflaged as bushes, antennas, for example, in the Arizona desert, the type of camouflage fits into the surrounding landscape. Also, for example, in other conditions, trees, rocks can serve as masking antennas. 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 mask the antenna under the elements of buildings, 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.htmn.

There are known methods of masking 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 the Episcopal Church in Dallas, a tree trunk in Arizona, in a brick-like window frame in Sopot Poland, as a work of art a decorative tower, under a cross at Lac Worth Florida Church, in the form of a bell tower in LaVista New England. For example (Electronic resource: [access mode] (https://bigpicture.ru/?p=318259).

The considered masking methods are not universal and are used only for ground stationary AK 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 antenna arrays.

Such methods of masking by their design are not collapsible universal and are made specifically for the AK and the installation object, in addition, they cannot be used to mask a wide class of large-sized (volumetric) antennas, for example, reflector antennas.

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

The AU versatility lies in the frameless and panel-step expansion, with a constant step for any overall size (width, length, height), design, which makes it possible to form the AU for a wide range of types and sizes of AK antennas without expanding the range of type sizes of structural elements, and just a corresponding increase in their number. Such versatility of the AU construction allows masking both low-profile antennas and antennas of significant dimensions, for example, reflector 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; antenna installation locations at the facility; methods of delivery to the object (by automobile, passenger or freight transport, aviation, sea container); assembly method (manual or using lifting mechanisms). The best option is the versatility in choosing the PSU size for a wide range of AK antenna dimensions, delivery and assembly, which greatly simplifies production and reduces the cost of AU production. At the same time, the type of masking, a planar or three-dimensional pattern on the outer surface of the AC, must be produced at the factory specifically for the installation site.

At the same time, sufficiently stringent requirements are imposed on the radio-transparent dielectric material for the execution of all structural elements of the AC, namely: the value of the relative dielectric constant of the order of (2.0-3.0); the value of the tangent of the dielectric loss angle of the order of 10 ^-3 in the frequency range from the medium wave range to tens of GHz; resistant to a wide range of external climatic influences in the temperature range of ± 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 allows not to use grounding; have thermal insulation properties; easy to be machined with a cutting tool (milling, turning); the ability to perform a three-dimensional pattern on the outer surface of the AC to create a three-dimensional masking pattern; the ability to glue parts of AC, similar to the method of cold welding; - have high adhesion when painting with special paint.

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

The technical objective of this invention is to create: a method of masking the AK installed in the AU, the outer surfaces of which are made with a planar and / or with a three-dimensional pattern, which allow you to simulate a wide range of objects on which the AU can be installed and harmoniously fit into it or into the environment, without creating visual unmasking signs; AU consisting of two constructs, one constructive base module (BM) in the form of a cube or parallelepiped and the second constructive roof module (MK) in cross section in the form of a trapezoid; AU of a modular frameless design with a minimum nomenclature of the type of dimensions of structural elements and with the possibility of expanding by the value of the tongue-and-groove base panel (VSHBP), which determines the expansion step for any size of the AU (length, width, height, which corresponds to the coordinates ΟΧ, ΟΥ, OZ AU), by increasing the number of VShBP without increasing the range of structural elements connected to each other by external interpanel sheet piles (EPP), and such an internal sheet pile connection of VSBP provides reliable protection against external climatic influences; the presence of a door or an internal access hatch in the AC side wall; the possibility of assembling three solid walls of BM and MK AU with the final assembly of the fourth solid side wall or with a door or a hatch.

The technical result is achieved by the fact that the method of masking the AC by using a protective radio-transparent panel-expandable with a constant step along any of the coordinates OX, OY of the base and OZ of the height of the sides of the radio-transparent dielectric ground AC, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which is made disguise in the form of a decorative finish that imitates the appearance of an object or landscape where the AU is installed and harmoniously fits into it, consisting in a frameless assembly of the BM, made in the form of a parallelepiped, at the base of which lies a square or rectangle, with a frameless transition to the assembly of the MC, made of a gable with a flat top in the form of a trapezoid, by installing external sheet pile three-coordinate corner posts (VSHTKUS) of the BM base, external sheet pile two-coordinate sections (VSHDKS) of direct inter-panel-step expanders (MPSHR) of the BM base along the OX and OY coordinates and along the OZ coordinate of the height of the side walls BM in a rectangular coordinate system, VSHTKUS of the transition from the side walls of the BM to the inclined part of the MC, VSHDKS MPSHR of the inclined transition from the side walls of the BM to the inclined part of the MC, VSHDKS MPSHR of the inclined part of the MC, VSHTKUS of the transition from the inclined part of the MC to the flat part of the MC, VSHDKS MPSHR of the transition from the inclined part of the MK to the flat part of the MK with internal sheet piles VShBP, VShDKS direct transitional MPSHR from the pediment of the MK to the flat part of the MK, VShBP, half-tongue base panels (PShBP) and VShBP for additional MK, moreover, VShBP, made of square shape, form a floor module (MP) , side walls of the BM, pediments, inclined and flat parts of the MC with the corresponding VSHBP of the additional VSHBP, while the PSHBP form a hatch or a side access door into the BM, and the transverse dimensions of the PSHBP are equal to the transverse dimensions of the VSHBP, and the depth and thickness of the internal sheet pile of the VSHPB of the tongue and groove panels and the depth and the thickness of the half-tongue of the SHBP are the same, while the VShBP and FShBP are connected to each other by VPSHP, 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 SHPB inner sheet pile, respectively, and the length of the SHBPH is equal to the length of the side of the connected VShBP and / or PShBP and / or the length of the side of the connected VShBPD, while the masking and assembly of the AU is carried out with the following steps:

- masking of the outer surfaces of the VShBP, PShBP, VShBP dobor, VShTKUS base of the BM, VShDKS MPSHR with orthogonal sheet piles, VShTKUS transition from the side walls of the BM to the inclined part of the MK, VShDKUS MPSHR of the inclined transition from the side walls of the BM to the inclined part of the MK, VShDKUS MPSHR of the inclined part MK, VSHTKUS of the transition from the inclined part of the MK to the flat part of the MK, VSHDKS MPSHR of the inclined transition from the inclined part of the MK to the flat part of the MK, by performing a planar or volumetric decorative finish that imitates the appearance of the object or landscape on which the AC is installed;

-образной формы состоит из пластины горизонтальной ветви и пластины вертикальной ветви, причем на каждой ВШТКУС основания БМ в плоскости XOY расположены пластины четырех ветвей ориентированных горизонтально, а в плоскости ZOY и в плоскости ZOX расположены по одной пластине ветвей ориентированных вертикально соответственно, при этом пластины

-образной формы горизонтальной и вертикальной ветвей выполнены одинаковой длины и равны половине длины ВШБП, а ширина и толщина пластин горизонтальной и вертикальной ветвей равны глубине и толщине внутреннего шпунта ВШБП соответственно, и являются для ВШБП внешними шпунтами, причем по координате ОХ и по координате OY между горизонтальными брусками четырех ВШТКУС основания БМ устанавливаются в каждый из четырех горизонтальных проемов, по меньшей мере, по две ВШДКС МГДИР с ортогональными шпунтами, при этом по координате OZ вертикальные бруски четырех ВШТКУС основания БМ с установленными по координатам OX, OY и OZ ВШДКС Μ МПШР с ортогональными шпунтами образуют четыре боковых проема, причем ВШДКС МПШР с ортогональными шпунтами выполнены в виде бруска квадратного поперечного сечения, сторона квадрата которого равна толщине ВШБП, а длина равна длине стороны ВЩБП, при этом на двух смежных сторонах бруска квадратного поперечного сечения по центру вдоль продольной оси установлены две одинаковые прямоугольные пластины соответственно, длина которых равна длине стороны ВШБП, а ширина и толщина равны глубине и толщине внутреннего шпунта ВШБП соответственно, которые являются внешними шпунтами ВШДКС межмодульно-шаговых расширителей (ММШР) с ортогональными шпунтами, причем внешние шпунты ВШДКС ММШР с ортогональными шпунтами основания БМ совмещены с внешними шпунтами ВШТКУС основания БМ;- the base of the BM AU is formed along the coordinates OX and OY by installing four VSHTKUS of the base of the BM, respectively, in four corners of the base of the BM, respectively, and each VSHTKUS of the base of the BM is located in its rectangular coordinate system, while the VSHTKUS of the base of the BM is made of three identical bars located along the coordinates OX, OY and OZ of a rectangular coordinate system, respectively, moreover, the bars are made of a square cross-section, the side of the square of which 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 of the BM base along the longitudinal axis, three identical L-shaped plates are made, the right angles of which are located at the origin of the coordinate system, respectively, the plate

-shaped form consists of a plate of a horizontal branch and a plate of a vertical branch, and on each VSHTKUS of the BM base 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, respectively, while the plates

-shaped horizontal and vertical branches are made of the same length and equal to half the length of the VSHBP, and the width and thickness of the plates of the horizontal and vertical branches are equal to the depth and thickness of the internal sheet pile of the VSHBP, respectively, and are external sheet piles for the VSHBP, moreover, along the OX coordinate and the OY coordinate between horizontal bars of four VSHTKUS of the BM base are installed in each of the four horizontal openings, at least two VSHDKS MGDIR with orthogonal sheet piles, while along the OZ coordinate, vertical bars of four VSHTKUS of the BM base with VSHDKS Μ MPSHR installed along the coordinates OX, OY and OZ with orthogonal sheet piles form four side openings, and the VSHDKS MPSHR with orthogonal sheet piles is made in the form of a bar of square cross-section, the side of the square of which 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 bar of square cross section in the center along the longitudinal axis two identical rectangular plates are installed, respectively, the length of which is equal to the length of the side of the VShBP, and the width and thickness are equal to the depth and thickness of the internal sheet pile of the VShBP, respectively, which are the outer sheet piles of the VSHDKS intermodular-step expanders (MMSHR) with orthogonal sheet piles, and the outer sheet piles of the VSHDKS MMSHR with orthogonal sheet piles of BM base are combined with external sheet piles VSHTKUS of BM base;

- the MP AC circuit is assembled by installing the BM base on the outer horizontal sheet piles along the entire perimeter with the internal sheet piles of the VSHBP, thereby forming the MP, while in the area of \u200b\u200bconnection of the end walls of adjacent VSHBP, external intermodular sheet piles (VMMSh) 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 VShBP side, and the width and thickness are equal to twice the depth and thickness of the internal sheet pile of the VShBP, respectively;

- the formation of the side walls of the first row of BM AU with a hatch or a side access door is carried out by installing in four side openings on the outer horizontal and vertical sheet piles of the VSHTKUS bases of the BM and VDKS MMSHR with orthogonal sheet piles of the internal sheet piles of the VSHBP, forming the first row of side walls of the BM, while, at least one side opening has at least one PSHBP, and in the area of connection of the end walls of adjacent VSHBP of the first base row, VMMSH are installed in the internal tongues;

- the height of the BM AU side walls is formed by installing along the OZ coordinate on the vertical bar of each VSHTKUS of the BM base, at least one VSHDKS MMSHR with orthogonal tongues, the outer tongues of which are aligned with the outer tongues of the corresponding vertical bars of the VSHTKUS of the BM base, forming in height side openings BM;

- the formation of the full height of the side walls of the BM AU is carried out by installing in four side openings on the external sheet piles of the VSHDKS MMSHR with orthogonal sheet piles and on the external VMPSH BM 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 MMSHR with orthogonal sheet piles, while on the first row PShBP, at least

one PSHBP dobora door or hatch, and VSHBP AND PSHBP connected to each other VMPSH;

- the transition from the last row of the VShBP of two side walls of the BM to the inclined part of the MK is being assembled while continuing to assemble the other two opposite side walls of the straight gables of the MK by installing on the four corners of the last row of VT UPS BM VSHTKUS of the transition from the side walls of the BM to the inclined part of the MK, which are made on the basis of the VSHTKUS of the BM base, in which two bars are located along the orthogonal coordinates OX and OZ or orthogonal coordinates OY and OZ, while the outer tongues of the TKUS transition are installed in the inner tongues of two adjacent corner VShBPs of the side wall, respectively, and the third bar of the transition TKUS is located at an angle , corresponding to the angle of inclination of the inclined part of the MC in the direction of the gable rib, while in the formed horizontal openings in the area of the inclined transition along the OX coordinate or along the OY coordinate between the horizontal two-coordinate bars VSHTKUS from the side walls of the BM to the inclined part of the MK, the VSHDKS MPSHR of the transition from the side walls of the BM on the inclined part of the MC, in which one external horizontal tongue is located orthogonally to the two-coordinate bar and is installed in the inner tongue of the VShBP of the last row of BM, and the other tongue is located obliquely at an angle to the two-coordinate bar corresponding to the angle of inclination of the inclined part of the MC, and the number of VShDKUS MPSHR of the transition from the side walls BM on the inclined part of the MK is equal to the number of VSHDKS MMSHR with orthogonal sheet piles BM on the corresponding side, and the outer sheet piles of the third bars of the VSHTKUS transition located at an angle, and the external sheet piles of the VSHDKS MPSHR located between the horizontal bars of the VSHTKUS transition form two side openings, while in the internal VShBP sheet piles of the last row of BM gables are installed by VMPSH;

- the assembly of the first row of the inclined part of the MK is carried out, consisting of two side openings, and two straight gables, which are a continuation of the side walls of the BM, respectively, and consists in installing the side openings on the outer sheet piles with the internal sheet piles of the VSHBP, and from the side of the straight gables on the VMPS, installed in the VShBP of the side walls of the last row of the BM VShBP and the internal tongue-and-groove base panels of the extension (VShBPD) of the gable row;

- the formation of full-size openings of the inclined part of the MC is carried out by installing at the end of the third bar of each VSHTKUS transition, located at an angle of inclination of the MC, at least one VSHDKS with orthogonal external sheet piles MMSHR of the BM base, while the external sheet piles of the VSHDKS with orthogonal external sheet piles MMSHR aligned with the outer tongues of the corresponding third bars of the TKUS transition MK, forming two opposite side inclined external tongue openings of the inclined part of the MK and two lateral opposite external tongue openings of a straight gable of a trapezoidal shape;

- the formation of the lateral inclined part and straight pediments of the MK is carried out by installing on the outer tongues in two lateral inclined openings and in two lateral straight openings, VShBP and panels for adding gables, respectively, and the total number of rows of VShBP of the sloping part and straight pediments of the MK is equal to the number of VSHDKS with orthogonal outer sheet piles MMSHR, forming the width of a full-sized slope, while the end walls of adjacent SHBP inclined openings and SHBP additions of straight gables are connected by VMMSh;

- the transition from the last row of VShBP of the inclined part of the MK, VShBP VShBPD of straight gables to the flat part of the MK is being assembled by installing on the four corners of the last row of VShBP VSHTKUS the transition from the inclined part of the MK and straight gables to the flat part of the MK, which are made on the basis of the VSHTKUS of the BM base, in which two bars are located along 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 MK in the direction of the pediment rib, and the outer tongues of the inclined bar VSHTKUS are installed in the inner tongues of the last row of two adjacent corner VShBPs of the last row, one of which the base panel of the straight pediment, and the other base panel of the inclined part of the MK, while the outer vertical tongues of two VSHTKUS bars orthogonally located along the coordinates OX and OY, respectively, are installed in the inner horizontal tongues of these two corner VShBP, and the other tongues of these bars are located horizontally in the plane MK, while in the two formed opposite horizontal openings of the inclined transition between the ends of the horizontal bars of four VSHTKUS of the transition from the inclined part of the MK to the flat part of the MK, the VSHDKS of the inclined transition MMSR from the inclined part of the MK to the flat part of the MK, in which one external tongue is made at an angle to the plane of the bar and is located in the same plane with the outer tongue of the third external tongue-and-groove two-coordinate bar VSHTKUS of the transition from the inclined part of the MK to the flat part of the MK and is installed in the inner tongue of the last row of the VShBP of the inclined part of the MK, and the second outer tongue is made perpendicular to the bar and is located in the flat part MK, while between the ends of the horizontal bars of the straight gables of the four VSHTKUS of the transition from the inclined part of the MK to the flat part of the MK, VSHDKS with orthogonal external tongues MMSHR BM are installed between the ends of the horizontal bars, providing a perpendicular transition from the plane of the pediment to the flat part of the MK, and one external tongue is installed in the inner the tongue of the last row VShBP gable and VShBPD gables, and the second outer tongue forms a flat part of the MC, while the number of VShDKUS MMSHR of the pediment determines the size of the MC on the corresponding side;

- the horizontal part is assembled in the plane of coordinates OX and OY of the MK, by installing on the external horizontal sheet piles of the VSHTKUS a transition from the inclined part of the MK to the flat part of the MK, on the external horizontal sheet piles of the VSHDKS transitional MMSR from the inclined part of the MK to the flat part of the MK and to the external horizontal sheet piles VSHDKS of direct transitional MMSR from the direct pediment of the MK to the flat part of the MK VShBP and VShBPD of the flat part of the MK, while the end walls of adjacent VShBP of the flat part of the MK are interconnected by the VPSH.

The method consists in vertically strengthening the rigidity of the connection from the inside of the BM to the end walls of adjacent VShBP, VShBP MP and VShBP and VShBP MK by installing dielectric interpanel corner stiffeners (MPUUZH), which consists of a rectangular base plate and located on it, perpendicularly along the longitudinal axis , plates of the stiffener, while the width of the base plate is equal to the width of the SMPS, and the length of the base plate and the length of the stiffening plate are equal to or less than the length of the SMPS, and the base plate of the intermodular stiffener is fixed by rigid fixation to the VShBP.

Optimal is the location of the MPUUZH on the vertical end connections of the adjacent HSBP side walls, and the MPUUZH MP and MK are their continuation, respectively. If necessary, it is possible to install MPUUZH on the horizontal joints of the side walls, BM, MP and MK.

There are two possible ways to perform MMCU.

One method consists in vertical strengthening of the connection rigidity on the inside of the BM VShBP MP with VShBP side walls of the BM and VShBP side walls of the BM with VShBP MK by installing dielectric interpanel corner amplifiers (MPUU) made of two plates in the form of an internal corner, while one the MMUU plate is installed on the connection area of the end walls of adjacent SHBP side walls of the BM, and for MP the inner corner is made straight and the other plate is installed on the connection area of the end walls of adjacent GShBP MP, and for MK the internal corner is obtuse with a slope corresponding to the slope of the MK and the other plate is installed on the connection area of the end walls of adjacent SHBP MK, and the plates of the MMCU are rigidly attached to the corresponding HSBP of the side walls of the PM, MP and MK.

-образной формы, являющейся одной гранью МПУУ, по центру вертикального луча которого перпендикулярно установлена упорная стойка, являющаяся другой гранью ММУУ, выполненная в виде прямоугольной пластины, при этом длина горизонтального луча несущей пластины

-образной формы равна длине стороны ВШБП, а высота вертикального луча и длина упорной стойки равна половине длины ВШБП, причем вертикальный луч несущей пластины

-образной формы устанавливается на область соединения ВШБП боковых стенок БМ с координатным ММШР.Another method, which consists in making the MPCU in the form of a carrier plate

-shaped, which is one face of the MPUU, in the center of the vertical beam of which a thrust post is perpendicularly installed, which is the other face of the MMUU, 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 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 carrier plate

-shaped form is installed on the area of connection of the HSBP of the side walls of the BM with the coordinate MMSR.

In both ways of performing the MPUU, the faces of the MPUU MP and MPUU MK are installed symmetrically on the connection area of the corresponding IDTs and, as a rule, are attached to them on studs that have already been used to connect the corresponding IDTs with the HSTKUS and the VMPSh.

The method consists in making the MPUU 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 MMUU face from the side of the inner right angle, an L-shaped corner amplifier plate is installed perpendicularly in the center, the length of the horizontal and vertical beams 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 outer MFPS, and the width of the plate of one and the other faces is equal to the width of the outer MFFS, while one and the other faces of the MMCU are mounted on the studs of a rigid fixing VShBP MP, VShBP side walls of BM and VShBP MK, respectively.

The location of the MPUZh along the vertical end connections of the SHBM side walls and the MPUU with the MP and MK form a Π-shaped stiffener.

A method consisting in strengthening the rigidity of the vertical corner joint, on the inside of the BM, VShBP of adjacent side walls of the BM connected through the coordinate MPSR by installing dielectric vertical internal corner stiffeners (VUUZh) of the side walls of the BM, made in the form of a right dihedral angle, one and the other faces of which are made in the form of rectangular plates, while the length of the face of the dihedral angle is equal to or less than the length of the TMPS, and the width is equal to or greater than half the width of the TMPS, while on the inside of the right dihedral angle of the vertical VUUZh, a dielectric at least one angular spacer is installed in the form plate, the outer contour of which is made in the form of an isosceles hyperbola, the asymptotes of which are mutually perpendicular, while one and the other branches of the outer contour of the angular strut are installed on one and the other plates of the inner faces of the vertical VUUZH, respectively (For example - "Equilateral hyperbola", I.N. Bronshtein and K. A. Semendyaev, Handbook of Mathematics, Moscow: Nauka, 1967, p. 210).

The method consists in strengthening the MC BM by installing at least one dielectric horizontal carrier beam installed symmetrically between one and the other side walls of the BM, and the ends of the carrier beam are fixed on the MPUU VShBP of one and the other side walls, while between the horizontal carrier beam and MPUU VShBP MK installed dielectric slopes in the form of dielectric plates, forming triangular trusses that form a floating ceiling.

For example: (Electronic resource: [access mode] (yan.dex.ru/search/?text=frame%20floating%20ceiling%20%20hangars&lr=2 13).

This design of the floating roof eliminates the possibility of sagging and thus eliminates the possibility of accumulation of precipitation in the form of water.

The method, which consists in the power reinforcement of the BM by installing braces clamps in the corners of the upper row of the VSHBP and / or in the lower rows of the VSHBP from the outer and / or inner side of the BM.

Guy fixators are made of dielectric material with holes for fastening guy cables. Fasteners of guy wires are installed both from the outside and from the inside of the AC.

Rigid fixation of VShBP with each other through VMPSh, fixation of VShBP with VShTKUS, with VShDKS, with MSHR, with VShTKUS, with VShDKB, as well as fixation and / or connection of MPUUZH, coordinate MPShR, MPMUU and VUUZH with VShBP is carried out by threaded connection by means of dielectric studs and / or dielectric bolts and/or cold welding (glue).

Threaded holes for installing dielectric studs or bolts are made blind in order not to disturb the external appearance of the AU, i.e. disguise.

The use of cold welding with glue in conjunction with dielectric studs or dielectric bolts can significantly increase the strength of the AC structure, especially to wind loads.

AU masking can be done in two ways.

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

The second masking method is carried out by performing a three-dimensional pattern by mechanical processing, for example, milling or installing by cold welding (on glue) dielectric panels that imitate 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 the dielectric panels is selected either by paint or by the color of the dielectric material. All these works must be carried out in production and for a specific object.

The door or access hatch into the inside of the AC 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 loops, which are fixed using dielectric bolts.

At the same time, the VMPSH VShBP for the PShBP door or hatch in the places of their installation act as an internal bounding box. If the door or hatch is made of several PShBP, then they are interconnected by VMPSH and fixed with dielectric bolts or studs, and additionally fixed by cold welding.

The AC door, made according to this method, can be installed on one or more side walls at the same time. The peculiarity of this design of the AU is the possibility, if necessary, at the assembly stage of the AU, not to assemble or disassemble, with the structure already assembled, one side wall of the BM with a door, while the integrity of the AU is not violated. Such an 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 is assembled.

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

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

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

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

AU dimensions according to this method can be performed with an arbitrary expansion step equal to the size of the SHBP along any coordinate OX, OY and OZ (width, length, height) without changing the nomenclature of the type of part sizes, but simply changing their number, which ensures the versatility of the design, and this means the ability to use masking for a wide range of antenna size types, including large ones.

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

The invention is illustrated by the following drawings.

In FIG. 1 shows a schematic general view of the AU, for example, in the form of a parallelepiped with an expansion of the transverse dimensions of the base of the AU BM six by eight BP and a BM height of five BP, with a double-leaf internal access door, two by four BP, mounted on hinges with a mortise lock, with latches braces installed in the corners of the upper and lower rows of the BP of the side walls of the PM, with a frameless transition to the MK, made of an inclined gable in the form of an isosceles trapezoid, and a planar masking of the AC in the form of a continuous monochromatic coating, for example, paint;

in fig. 2 shows a fragment of the BM AU side wall (Fig. 1) with volumetric masking of the outer side walls, for example, under brickwork, when the imitation of brickwork is made of dielectric plates of the appropriate size and color, installed (for example, glued) on VShBP, PShBP, VShBPD of the side walls, and the outer surfaces of the VShTKUS of the base of the BM, the transition from the BM to the inclined part of the MK and the transition to the flat part of the MK, VShDKS MPSHR are painted in the appropriate color or volumetric dielectric pads are also made in the corresponding color, go for a three-dimensional pattern by milling and with external fasteners of the braces, installed in the corners of the upper row of the HSBP of the side walls;

in fig. 3 shows a fragment of the formation of the BM AU base (Fig. 1) by installing four VSHTKUS in the four corners of the BM base, VSHDKS MPSHR are installed in the horizontal openings in two of the openings of seven and in the other two openings of five, respectively, on the outer sheet piles of which the VSHBP forming the first row of BM with an opening for the door of the side entrance, and VShBP were installed forming a base of MP closed around the perimeter;

in fig. 4 shows the final fragment of the formation of the base of the BM AU (Fig. 1) by installing the VMPSh between the VShBP and the MPUU installation and the MPUUZh installation;

in fig. 5 shows a fragment of the completed BM assembly with a side access doorway, for example, the height of the side opening of four PSUs and the width of two BMs and the installed VUUZH;

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

in fig. Figure 7 shows a fragment of the BM (Fig. 5) with the MC installed and the MP fixed to the foundation using anchor bolts.

The method of masking AC 1 and its implementation is as follows.

Camouflage is a decorative finish on the outer surface of AC 1, which can be performed in two types of execution - planar or volumetric.

Decorative finishing is performed on the outer surfaces of the following structural elements of AC 1 (Fig. 1):

VShBP 2 side walls BM, PShBP 5 side access doors; VShBPD 6 side gables, inclined and flat parts of the MK; VSHTKUS 3 BM bases; VSHDUS MPSHR 4 with orthogonal sheet piles along the coordinates OX and OY of the BM base; VSHDUS MPSHR 7 with orthogonal sheet piles along the coordinate OZ of the height of the side walls of the BM; VSHTKUS 8 angular transition from the side walls of the BM to the inclined part of the MK; VSHDUS MPSHR 9 with an orthogonal tongue and corner tongue for transition from the side walls of the BM to the inclined part of the MK; VSHDUS MPSHR 10 with orthogonal sheet piles extension of the sloping part of the roof module; VSHTKUS 11 angular transition from the inclined part of the MK to the flat part of the MK; VSHDUS MPSHR 12 with an angled tongue and an orthogonal tongue for the transition from the inclined part of the MK to the flat part of the MK along the side wall; VSHDUS MPSHR 13 with orthogonal sheet piles expansion of the pediment of the flat part of the MK; visor 14 over PSHBP 5 side access doors; dielectric loops 15; retainer for external braces 16.

A planar decorative finish is either a solid, solid color coating of paint on a flat surface, or a pattern that mimics a building material such as brickwork, building block masonry, wood or plastic panels, or other building materials.

Volumetric decorative finishing is performed in the form of a three-dimensional 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 a dielectric material similar in electrophysical parameters and electrodynamic characteristics, and subsequent decorative finishing either by selecting the color of the dielectric material, or by painting.

Works on decorative finishing of AC 1 are carried out, as a rule, in production during the manufacture of its structural elements.

Decorative finishing of the external surfaces of the VSHBP 2 flat part of the MK can be carried out both by the planar method, by painting, and by the volumetric method, by performing a three-dimensional pattern with a profile identical to the profile of the coating material used, for example, corrugated or sheet iron, metal tiles, andulin, glass isol and subsequent painting.

Execution of AU 1 (Fig. 1), for example, with planar disguise in the form of a decorative monophonic finish, with the expansion of the transverse dimensions of the base of the AU BM six by eight VSHBP and the BM height of five VSHBP, with a double door 5 internal access, two by four VSHBP, mounted on hinges 14 with braces retainers 16 installed on the upper and lower rows of the VShBP 2 of the side walls of the BM.

A fragment of one side wall AU 1 with a volumetric decorative finish VShBP 2 side walls made, for example, (Fig. 2) is schematically presented under the brickwork 17, imitation brick 15 is made, for example, from thin dielectric plates the size of a brick, installed by cold welding on VShBP 2, and the seam, in the form of a mortar of brickwork, can be made with paint. Latches braces 9 installed on the side walls of AC 1, for example, on the top row 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; VSHBP 2 forming the first row of BM with an opening for the door of the side entrance, and installed VSHBP forming a base of MP closed around the perimeter;

The complete formation of the base of the BM AU (Fig. 4) is carried out by installing the VMPSH 18 between the VSHBP 2 and the MPUU 19 installation and the MPUUZH 20 installation.

Full height BM assembly (Fig. 5) with a side access doorway, for example, the height of the side opening of four PShBP and the width of two PShBM and installed VUUZh 21.

Fully completed assembly of BM AU 1 (Fig. 6) with a double-leaf side door mounted on hinges for the formation of MK.

Fully assembled AU 1 with installed MK (Fig. 7) and an example of fastening the MP, formed from VShBP 2, to the foundation using anchor bolts 22.

To create a monolithic structure of the AU, the tongue and groove joints of all elements of the AU 1 can be glued together (cold welding), which creates, as it were, a monolithic structure and, in addition, provides high waterproofing of the joint seams. Additionally, you can improve the waterproofing of the MC by sealing the joints 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 coordinates OX and OY of the base and OZ of the height of the sides of a dielectric ground-based antenna shelter, made entirely of one type of radio-transparent dielectric material, on the outer surfaces of which masking is made in the form decorative finish that imitates the appearance of the object or landscape where the antenna shelter is installed, consisting in a frameless assembly of the base module, made in the form of a parallelepiped, with a frameless transition to the assembly of the roof module, made of a gable with a flat top in the form of a trapezoid, by installing external sheet piles on the outer sheet piles 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 base and along the OZ coordinate of the height of the side walls of the base module of a 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 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 with internal tongues of the tongue-and-groove base panels, half-sheet pile base panels and sheet pile base panels of the addition of the roof module, moreover, the square-shaped intra-sheet pile base panels form the floor module, side walls of the base module, the gables of the roof module, the inclined and flat parts of the roof module with the corresponding tongue and groove panels for adding base panels, while the half tongue and groove base panels form a hatch or a side access door inside the base module, and the transverse dimensions of the half tongue and groove base panels are equal to the transverse dimensions of the tongue and groove base panels, and the depth and thickness of the inner tongue of the tongue and groove base panels and the depth and thickness of the half tongue of the half tongue and groove base panels are the same, while the tongue and groove base panels, half tongue and groove base panels and the inner tongue and groove panels of the base panel extension are connected to each other by external interpanel tongues, which are made in the form of a rectangular plate, width and thickness which are equal to twice the depth and thickness of the inner tongue of the tongue-and-groove base panel, respectively, and the length of the outer tongue-and-groove base panel is equal to the length of the side of the tongue-and-groove base panels and / or half-sheet pile base panels connected to each other and / or the length of the side of the connected tongue-and-groove base extension panels, while masking and assembling the antenna shelters are carried out with the following stages: - the masking of the outer surfaces of the inner tongue and groove base panels, semi-tongue base panels, inner tongue and groove base extension panels, outer tongue-and-groove three-coordinate corner posts of the base module base, outer tongue-and-groove two-coordinate sections of interpanel-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 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 a planar or volumetric decorative finish that imitates the appearance of the object or landscape on which the antenna shelter is installed; - the base module of the base module of the antenna shelter is formed along the coordinates OX and OY by installing four external sheet pile three-coordinate corner posts of the base module base, respectively, in four corners of the base module base, respectively, each external sheet pile three-coordinate corner post of the base module base is located in its rectangular coordinate system, while the external sheet pile the three-coordinate corner post of the base module 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 square cross-section, the side of the square of which is equal to the thickness of the tongue-and-groove base panel, and the length is equal to half the length of the tongue-and-groove base panel, at the same time, in three coordinate planes ZOX, ZOY and XOY, on the bars of each external tongue-and-groove three-coordinate corner post of the base module base, three identical plates are made along the longitudinal axis

-shaped, the right angles of which are located at the origin of the coordinate system, respectively, the plate

-shaped form 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 module base 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, respectively, while the plates

-shaped horizontal and vertical branches are made of the same length and equal to half the length of the 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 inner tongue of the tongue-and-groove base panel, respectively, and are external tongues for the tongue-and-groove base panels, moreover, along the coordinate ОХ and along the OY coordinate between the horizontal bars of four external tongue-and-groove three-coordinate corner posts of the base module base, at least two external tongue-and-groove two-coordinate sections of inter-module-step expanders with orthogonal tongues are installed in each of the four horizontal openings, while along the coordinate OZ vertical bars of four external tongue and groove three-coordinate corner posts of the base module base with external tongue-and-groove two-coordinate sections of intermodule-pitch expanders with orthogonal tongues form four side openings, and the external tongue-and-groove two-coordinate sections of intermodule-pitch expanders with orthogonal tongues are made in the form of a bar of square cross-section, side the square of which is equal to the thickness of the tongue-and-groove base panel, and the length is equal to the length of the side of the tongue-and-groove base panel, while on two adjacent sides of the bar 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 tongue-and-groove base panel, and the width and thickness are equal to the depth and thickness of the inner tongue of the tongue-and-groove base panel, respectively, which are the outer tongues of the outer tongue-and-groove two-coordinate sections of the intermodule-pitch expanders with orthogonal tongues, and the outer tongues of the outer tongue-and-groove two-coordinate section of the intermodule-pitch expanders with orthogonal tongues of the base module base are aligned with the outer tongues of the outer tongue-and-groove three-coordinate corner posts of the base module base; - the contour of the floor module of the antenna shelter is assembled by installing the base module base on the outer horizontal tongues along the entire perimeter with the inner tongues of the tongue-and-groove base panels, thereby forming the floor module, while in the connection area of the end walls of adjacent 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 tongue and groove base panel, and the width and thickness are equal to twice the depth and thickness of the inner tongue of the tongue and groove panel, respectively; - the formation of the side walls of the first row of the base module of the antenna shelter with a hatch or a side access door is carried out by installing in four side openings on the outer horizontal and vertical tongues of the external tongue-and-groove three-coordinate corner posts of the base module base and the external tongue-and-groove two-coordinate sections of the inter-module-step expanders with orthogonal tongues, internal tongues of the internal sheet piles base panels, forming the first row of side walls of the base module, while 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 inside-tongue base panels of the first base row, internal tongues are installed external intermodular sheet piles; - the height of the side walls of the base module of the antenna shelter is formed by installing along the OZ coordinate on a vertical bar of each external sheet pile three-coordinate corner post of the base module base, at least one external sheet pile two-coordinate section of the intermodule-step expander with orthogonal sheet piles, the outer sheet piles of which are aligned with the outer sheet piles of the corresponding vertical bars of external tongue-and-groove three-coordinate corner posts of the base module base, forming side openings of the base module in height; - 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 the outer tongues of the outer sheet pile two-coordinate sections of intermodule-step expanders with orthogonal sheet piles and on the external intermodular sheet piles of the sheet pile base panels of the first row of sheet pile base panels, and the number of additional rows of sheet pile base panels of panels along the height of the opening is equal to the number of external tongue-and-groove two-coordinate sections of inter-module-step expanders with orthogonal tongues, while at least one half-groove panel of the door or hatch is installed on the semi-groove 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 sheet piles; - the transition is being assembled from the last row of sheet pile base panels of the two side walls of the base module to the inclined part of the roof module while continuing to assemble the other two opposite side walls of the direct gables of the roof module by installing external sheet pile base panels of the base module of external sheet pile three-coordinate corner posts of the transition at the four corners 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 base, in which two bars are located along orthogonal coordinates OX and OZ or orthogonal coordinates OY and OZ, while the outer tongues of the three-coordinate corner posts of the transition are installed in inner sheet piles of two adjacent angular internal sheet pile base panels of the side wall, respectively, and the third bar of the three-coordinate corner post of the transition is located at an angle corresponding to the angle of inclination of the inclined part of the roof module in the direction of the gable rib, while in the formed horizontal openings in the area of the inclined transition along the coordinate OX or along coordinate OY 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 interpanel-step expanders of 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 to the two-coordinate bar and installed in the inner tongue of the 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 bar 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 the interpanel-step expanders of the transition from the side walls of the base module to the inclined part of the roof module is equal to, equal to the number of external tongue-and-groove two-coordinate sections of inter-module-step expanders with orthogonal tongues of the base module on the corresponding side, and the outer tongues of the third bars of the three-coordinate corner posts of the transition located at an angle, and the outer tongues of the external tongue-and-groove two-coordinate sections of the inter-panel-step expanders located between the horizontal the bars of the three-coordinate corner posts of the transition form two side openings, while external intermodular tongues are installed in the internal tongues of the internal sheet pile base panels of the last row of gables of the base module; - the assembly of the first row of the sloping part of the roof module is carried out, consisting of two side openings, and two straight gables, which are a continuation of the side walls of the base module, respectively, and consists in installing the inner sheet pile base panels on the outer tongues of the side openings, and on the side of the straight gables on the external intermodular sheet piles installed in the sheet pile base panels of the side walls of the last row of the base module, the sheet pile base panels and the sheet pile base panels of the gable row extension; - the formation of full-size openings of the inclined part of the roof module is carried out by installing at 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, at least one external tongue-and-groove two-coordinate section with orthogonal external tongues of the intermodule-step expanders of the base module, with in this case, the outer tongues of the external tongue-and-groove two-coordinate sections with orthogonal outer tongues of the inter-module-step expanders are aligned with the outer 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 a straight trapezoidal gable; - the formation of the lateral sloping part and straight gables of the roof module is carried out by installing on the outer sheet piles in two side inclined openings and in two side straight openings, the internal sheet pile base panels and the internal sheet pile base panels for the addition of gables, respectively, and the total number of rows of sheet pile base panels of the inclined part and direct gables of the roof module is equal to the number of external tongue-and-groove two-coordinate sections with orthogonal external tongues of inter-module-step expanders forming the width of a full-size slope, while the end walls of adjacent internal sheet-piled base panels of inclined openings and internal sheet-piled base panels for the addition of straight gables are connected by external intermodular sheet piles; - the transition from the last row of tongue-and-groove base panels of the inclined part of the roof module, the inner-sheet pile base panels and the tongue-and-groove base panels for the addition of straight gables to the flat part of the roof module is assembled by installing on the four corners of the last row of the tongue-and-groove base panels of the external three-coordinate corner posts of the transition from the inclined part of the roof module 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 base, in which two bars are located along 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 rib of the gable, and the outer tongues of the inclined bar of the external tongue-and-groove three-coordinate corner posts are installed in the inner tongues of the last row of two adjacent corner tongue-and-groove base panels of the last row, one of which is the base panel of the straight gable, and the other is the base panel of the inclined part of the roof module, while in the internal horizontal tongues of these of two angular internal tongue and groove base panels, external vertical tongues of two bars of three-coordinate corner posts orthogonally located along the coordinates OX and ΟΥ, respectively, are installed, and the other tongues of these bars are located horizontally in the plane of the roof module, while in the two formed opposite horizontal openings of the inclined transition between the ends of the horizontal bars of 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 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 is located in on the same plane with the outer tongue of the third outer tongue-and-groove two-coordinate bar of the outer 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 inner tongue of the last row of the inner tongue-and-groove base panels of the inclined part of the roof module, and the second outer tongue is made perpendicular to the bar and is located in the flat parts of the roof module, while between the ends of the horizontal bars located inside the sheet pile base modules of straight gables of four external sheet pile three-coordinate corner posts of the transition from the inclined part of the roof module to the flat part of the roof module, external sheet pile two-coordinate sections are installed with orthogonal external sheet piles of inter-module-step expanders of the base module providing a perpendicular transition from of the gable plane on the flat part of the roof module, wherein one outer tongue is installed in the inner tongue of the last row of the inner tongue and groove base panels of the gable and the inner tongue and groove base panels for the addition of gables, and the second outer tongue forms the flat part of the roof module, while the number of external tongue and groove two-coordinate sections of the intermodule-step gable expander determines the size of the roof module on the corresponding side; - the horizontal part is assembled in the plane of the coordinates OX and OY of the roof module, by installing on the outer horizontal sheet piles of external sheet pile 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 sheet piles of the external sheet pile two-coordinate sections of transitional intermodule-step expanders with an inclined parts of the roof module on the flat part of the roof module and on the outer horizontal sheet piles of the outer sheet pile two-coordinate sections of direct transitional intermodule-step expanders from the gable of the roof module to the flat part of the roof module of the sheet pile base panels and the sheet pile base panels of the addition of the flat part of the roof module, while the end walls of adjacent sheet pile the base panels of the flat part of the roof module are interconnected by external intermodular tongues. 2. The method according to claim 1, which consists in vertically strengthening the connection rigidity on the inside of the base module of the end walls of adjacent intra-sheet pile base panels, sheet pile base panels of the floor module and sheet pile base panels and sheet pile base panels of the roof module extension by installing dielectric inter-panel corner stiffeners, which consists of a rectangular base plate and a stiffener plate located on it, perpendicularly along the longitudinal axis, while 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 stiffener plate are equal to or less than the length of the external intermodular tongue, and the plate the base of the intermodular stiffener is rigidly fixed to the internal sheet pile base panels. 3. The method according to claim 1, which consists in vertically strengthening the connection from the inside of the base module of the tongue-and-groove base panels of the floor module with the tongue-and-groove base panels of the side walls of the base module and the tongue-and-groove base panels of the side walls of the base module with the tongue-and-groove base panels of the roof module by installing dielectric intermodular corner reinforcements made of two plates in the form of an internal corner, while one plate of the intermodular corner reinforcement is installed on the connection area of the end walls of adjacent tongue-and-groove base panels of the side walls of the base module, and for the floor module the internal corner is made right and the other plate is installed on the connection area of the end walls walls of adjacent tongue-and-groove base panels of the floor module, and for the roof module, the inner corner is obtuse with a slope corresponding to the slope of the roof module, and another plate is installed on the connection area of the end walls of adjacent tongue-and-groove base panels of the roof module, and the plates of the intermodular corner reinforcements are rigidly fixed to the corresponding tongue-and-groove base panels side walls of the base module, the floor module and the roof module. 4. The method according to p. 3, which consists in the implementation of intermodular corner amplifiers in the form of a carrier plate

-shaped form, which is one side of the intermodular corner amplifier, in the center of the vertical beam of which a thrust post is perpendicularly installed, which is the other side 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 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 tongue-and-groove base panel, and the vertical beam of the carrier plate

-shaped form is installed on the area of connection of the tongue-and-groove base panels of the side walls of the base module with a coordinate inter-module-step expander. 5. The method according to claim 1, which consists in the implementation of 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 inner right angle, a plate of the corner amplifier is installed perpendicularly in the center

-shaped, the length of the horizontal and vertical rays 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 side is equal to the width of the external intermodular tongue, in this case, one and the other faces of the intermodular corner reinforcements are fastened to the rigid fixation studs of the tongue-and-groove base panels of the floor module, the tongue-and-groove base panels of the side walls of the base module, and the 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 joint, on the inside of the base module, of the tongue-and-groove base panels of adjacent side walls of the base module connected through a coordinate inter-module-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, while 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 greater than half the width of the external intermodular tongue, while on the inside of the direct dihedral at the corner of the vertical internal corner stiffener, a dielectric is installed, at least one angular strut in the form of a plate, the outer contour of which is made in the form of an isosceles 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 plates inner faces of vertical inner corner stiffeners, respectively. 7. The method according to claim 3, which consists in reinforcing the roof module of the base module by installing at least one dielectric horizontal carrier beam installed symmetrically between one and the other side walls, the ends of the carrier beam being fixed on the intermodular stiffeners of the internal sheet pile base panels of one and other side walls, while dielectric slopes in the form of dielectric plates forming triangular trusses that form a floating ceiling are installed between the horizontal carrier beam and the intermodular stiffeners of the internal sheet pile base panels of the roof module. 8. The method according to claim 1, which consists in reinforcing the base module by installing braces in the corners of the upper row of tongue-and-groove base panels and/or in the lower rows of tongue-and-groove base panels on the outer and/or inner side of the base module.

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