WO2020197371A1 - Method for installing a support tower on the roof of a building - Google Patents

Abstract

The present method is directed toward the installation of a support tower to which, during assembly in a horizontal position, equipment for transmitting and receiving electromagnetic waves is mounted and a wind turbine or solar panels can also be mounted. The invention allows assembly on the roof of a building within confined conditions, and also allows a main rim and the support tower to be pivoted independently of one another, with the position of the equipment being raised as the rim and tower are brought into a vertical position. Providing access to equipment with the aid of an extendable ladder that is based on an auxiliary rim, while allowing adjustment of the geometrical dimensions of a structure made of materials that are impermeable to electromagnetic waves, makes it possible to enhance the performance of the equipment by increasing the power handling capacity of same and to attenuate the electromagnetic field to the point of completely eliminating same in a given region of the roof of the building.

Description

METHOD FOR INSTALLING A HEIGHT SUPPORT ON THE ROOF OF A BUILDING

The invention relates to the field of construction, in particular to methods for the construction of long high-rise structures, and can be used on the roof of a building for mounting a high-rise support, on the upper part of which, during assembly, in a horizontal position, cellular antennas, radio relay, radar antennas or other emitting and receiving electromagnetic waves equipment, along with which it is possible to place a wind power plant and solar panels.

There is a known method of mounting a high-rise support, including the assembly of a high-rise support in a horizontal position and its rotation from a horizontal position to a vertical one, in which the base of the high-rise support is fixed on a previously prepared site, while before assembling the high-rise support in place of its horizontal placement, a rail track is laid on which a trolley with a rope drive, the high-rise support is pivotally connected to the trolley using a bar, while the cart is placed on the side of the top of the high-rise support, the attachment point of the bar hinge to the high-rise support is taken from its base by an amount less than the length of the bar, with the formation between the bar and the high-rise support of a blunt angle, and the rotation of the high-rise support from the horizontal to the vertical position is carried out by means of a bar, moving the trolley with a cable drive along the rail track to the base of the high-rise support, and insuring from the ground with a winch cable connected to the top of the high-rise support, with all work performed without using a car transport or aviation equipment, in particular, truck cranes or heavy-duty helicopters, which ensures low labor intensity (Patent of the Russian Federation No.2451145, app. 09/13/2010, publ. 05/20/2012, cl. E04H12 / 34, E04EG12 / 08U

The main disadvantage of the known method is the relatively low efficiency of using the equipment placed on the support. This problem is associated with the insufficient height of the equipment and is due to the fact that the permissible length of the high-rise support is limited due to the bending moment created by wind loads relative to its base.

The closest in technical essence to the claimed one is a method of mounting a high-rise support, including the assembly of a high-rise support in a horizontal position and its rotation from a horizontal position to a vertical one, which consists in the fact that before assembling the high-rise support, the main and auxiliary rims are assembled, each of which is supplied with lever mechanisms and when with the help of lifting and traction mechanisms, they provide the ability to rotate in both directions relative to their axis passing through the ends of the corresponding rim, and the pivot axes of the two rims are chosen perpendicular to each other and the height support during assembly is laid along the pivot axis of the auxiliary rim, while the main rim is turned from a horizontal position to a vertical position together with a high-rise support placed on its upper part (Eurasian patent JN ° 030853, filed 04/06/2015, publ. 10/31/2018, according to class E04H12 / 34).

5 The known method has a number of serious drawbacks when it is implemented on the roof of a building with people, although it solves the main problem of the previously considered analogue due to the fact that the bending moment for the high-rise support is created relative to the junction point of the upper parts of the two rims. The main disadvantage of the known method is that the Yuvysotny support is rotated by placing it on the upper part of the main rim, which limits the maximum possible height of the equipment, because in the cramped conditions of a site on the roof of a building, it is difficult to manufacture a bulky structure and a heavy main rim with sufficient strength to transverse loads at the point 15 of the connection of its upper part with the base of the high-rise support. Another important problem is due to the fact that when placing equipment emitting electromagnetic waves on a high-rise support, in order to improve the performance of the equipment by increasing its permissible power, in order to limit the level of the electromagnetic field within the permissible range and to protect people from exposure to electromagnetic waves, it is required to provide a relatively safe access to equipment for regulating the level of the electromagnetic field in a given area of the roof of the building, however, in the known method, it is difficult to carry out these works in the vertical position of the tower at the height of the building. Significant rotating forces are created with respect to the device implementing the known method, both from wind loads, which depend on windage and have an effect during operation, and from torques during the installation of the high-rise support during its turns with equipment on its top, which also requires Reinforcement of the rim base mountings, as a result of which leads to an increase in the degree of damage to the building coating. If there is not enough space on the roof, during assembly it is impossible to install the equipment in a horizontal position at a sufficient distance from the intersection of the pivot points of the two rims. As a result, due to insufficient height, when radio relay or radar antennas are placed on a high-altitude support, the values of the received signals turn out to be insufficient to cover the planned territory, which requires an increase in the height of the equipment, since with increasing altitude, the levels of received signals for antenna systems increase. When placed on a high-altitude support of cell communication antennas, due to insufficient height, direct and complete visibility of neighboring buildings is not ensured, which leads to an increase in the number of obstacles in the signal path and limits the efficiency of equipment use. The technical problem to be solved by the present invention is to raise the equipment to a sufficient height for placement in conditions of a lack of space for horizontal assembly, providing access to equipment located at a height, due to which it becomes possible to improve the performance of equipment emitting electromagnetic waves by increasing its allowable power and carrying out adjustments at a height to restrict the electromagnetic field in a predetermined area of the roof using the rims.

The technical result is an increase in the efficiency of the use of equipment on a high-rise support, rotated and held using two rims, by solving the problem.

The problem is solved by the fact that when implemented on the roof of a building, in the method of mounting the high-rise support, including the assembly of the high-rise support in a horizontal position and its rotation from the horizontal position to the vertical position, which consists in the fact that before assembling the high-rise support, the main and auxiliary rims are assembled, each of which they are equipped with linkage mechanisms and, using lifting and traction mechanisms, provide the possibility of turning in both directions 20 relative to their axis passing through the ends of the corresponding rim, and the pivot axes of the two rims are chosen perpendicular to each other and the high-rise support during assembly is laid along the pivot axis of the auxiliary rim, According to the invention, the main rim and the height support are provided with the possibility of turning separately from each other, at 25 this, the bases of the rims and the height support are made expanded in the form of polygons and, through the hinge mechanisms, are installed on supports, the overall dimensions of which are chosen to provide ground-based placement of linkage and lifting and traction mechanisms, and the stand of the high-rise support is installed at the central point of the segment connecting the ends of the main rim, while the auxiliary rim is made consisting of two identical, parallel parts, between which in one half of the auxiliary rim the space is left free, and the distance is chosen to ensure the passage of a high-rise support, which is rotated by means of a lifting and traction mechanism along a vertical plane relative to an axis passing through one of the sides of its base, and the sides connecting the ends of the rims with their upper parts are retractable with the possibility of changing their slopes, while a telescopic ladder is formed on the base of the auxiliary rim, the steps 40 of which are attached to the sides of two parts of the second half of the auxiliary rim, which is not used for passing the high-rise support, and at the level of the upper part of the main rim along the high-rise support from the st the orons of its apex place a cellular antenna or other equipment that emits and receives electromagnetic waves, when In this case, in the interval between the upper part of the main rim and the equipment along its rack, a structure is installed, which is performed to limit the return of signals reflected from it to the equipment and is made of materials that do not transmit electromagnetic waves 5 with the possibility of adjusting its slope, shape, size and distance using an auxiliary rim to the equipment, and by means of the lifting and traction mechanism, the equipment is provided with the possibility of sliding along with the structure along the vertical axis from the level of the upper part of the main rim to the maximum placement height 10 and back, while the assembly begins with laying the beams along the pivot axes of the two rims, then the stands are installed on the beams , moreover, the beam along the axis of turns of the auxiliary rim is laid with coverage of the equipment location in a horizontal projection during its installation, while after assembly and subsequent rotation of the auxiliary rim from the horizontal position into vertical, assembled and turn the main rim and the high-rise support one after another from horizontal to vertical positions, with each base fastening along its perimeter to the corresponding stand, then the equipment together with the structure is lifted along the vertical axis and its position is fixed at 20 maximum placement height, and the upper parts of the two rims are interconnected with the possibility of vertical sliding along the high-rise support with the subsequent fixation of the selected position, and with the help of the auxiliary rim they improve the performance of the equipment by increasing its permissible power without the need to further increase the maximum placement height, while in the vertical position of the high-rise support, with using a telescopic ladder based on an auxiliary rim on the roof of the building where the equipment is located, they provide permissible levels of the electromagnetic field by adjusting the geometric dimensions of the ZO of the structure, then I complete t work on setting up equipment, and in the premises of the building, on the roof of which a cellular antenna is located, communication is provided using cellular antennas located on the roofs of other buildings.

In the claimed invention, the technical result 35 is achieved by performing this set of actions in the above sequence. The method provides for the assembly on the roof of the building in the cramped conditions of the site with the possibility of access to the equipment in the vertical position of the high-rise support, as well as turns of the main rim and the high-rise support separately from each other, with a further increase in the height of the equipment after bringing them into vertical positions. This is achieved due to the manufacture of an auxiliary rim consisting of two parts, between which the high-rise support is turned, then along the high-rise support in its vertical position, the equipment slide from the level top of the main rim to the maximum stowage height. The use of beams along the pivot axes of the two rims ensures the stability of the structure against rotating loads. Taking into account the geometrical features of the roof of each building and the most various options for the location of the designated space for placing the antennas on it, with the help of two rims, it is possible to increase the permissible power of the equipment by adjusting the geometric dimensions of the structure from materials that do not transmit electromagnetic waves. To this end, providing access to the equipment using a retractable Yustremyanka based on an auxiliary rim with an emphasis on four supports of two rims attached to the beams, allows you to increase the performance of the equipment by increasing its permissible power and, in safe conditions, weaken the electromagnetic field to almost completely eliminate it in the specified area of the building roof.

15 Thus, the solution of the technical problem, which consists in raising the equipment to a sufficient height of placement in the cramped conditions of the site, with providing access to the equipment located at a height for carrying out adjustment work to limit the electromagnetic field in a given area of the building roof, allows to obtain a technical result - to increase the efficiency using the equipment on a tower pivot and supported using two rims.

Figure 1 shows a device that implements the inventive method, where the high-rise support 1 and the main rim 2 are indicated during assembly in 25 horizontal positions, and the auxiliary rim 3 is in a vertical position.

The method of mounting a high-rise support on the roof of a building is implemented as follows. Before assembling the high-rise support 1, the main 2 and auxiliary 3 rims are assembled, each of which is equipped with lever mechanisms and, with the help of lifting and traction mechanisms 4, they provide the possibility of turning in both directions relative to its axis passing through the ends of the corresponding rim, and the axis of rotation of the two rims 2, 3 are selected perpendicular to each other and the high-rise support 1 during assembly is laid along the pivot axis of the auxiliary rim 3.35 To avoid blocking the circuit, the linkage and hinge mechanisms at the bases 5 of the rims 2, 3 and the high-rise support 1, as well as lifting and traction mechanisms at the bases 5 auxiliary rim 3 is not specified. In the claimed invention, the main rim 2 and the height support 1 are provided with the possibility of turning separately from each other. The bases 5 of the rims 2, 3 and 40 of the high-rise support 1 are expanded in the form of polygons and, through the hinge mechanisms, are installed on supports 6, the overall dimensions of which are chosen to ensure the ground placement of the linkage and lifting-and-draft mechanisms 4. The support 6 of the high-rise support 1 is installed at the central point of the segment, connecting the ends main rim 2. Auxiliary rim 3 is made consisting of two identical, parallel-located parts, between which in one half of the auxiliary rim 3 the space is left free, and the distance is chosen to ensure the passage of the high-rise support 1, 5 rotated by means of the lifting and traction mechanism 4 along the vertical plane relative to the axis passing through one of the sides of its base 5. The sides connecting the ends of the rims 2, 3 with their upper parts are retractable with the possibility of changing their slopes. On the basis of the auxiliary rim 3, a telescopic step-ladder is formed, the Yuusupeni 7 of which is attached to the sides of the two parts of the second half of the auxiliary rim 3, which is not used for the passage of the high-rise support 1. At the level of the upper part of the main rim 2 along the high-rise support 1, a cellular antenna is placed on the side of its top or other equipment emitting and receiving electromagnetic waves 8. In the 15th interval between the upper part of the main rim 2 and the equipment 8 along its rack, a structure 9 is installed, which is made to limit the return of signals reflected from it to the equipment 8 and is made of materials that do not transmit electromagnetic waves with the possibility regulation with the help of an auxiliary 20 rim 3 of its slope, shape, size and distance to the equipment 8 in the vertical position of the high-rise support 1.

The assembly begins with laying the beams 10 along the pivot axes of the two rims 2, 3, then the supports 6 are installed on the beams 10. Beam 10 along the pivot axis of the auxiliary rim 3 is laid to cover the location 25 of the equipment 8 in a horizontal projection during its installation. After assembly and subsequent rotation of the auxiliary rim 3 from a horizontal position to a vertical one, they are assembled and from horizontal positions to vertical ones, the main rim 2 and the high-rise support 1 are rotated one after another, with each base 5 fastening along its perimeter to the corresponding support 6, then the equipment 8 together with the structure 9 is raised along the vertical axis and its position is fixed at the maximum placement height, and the upper parts of the two rims 2, 3 are interconnected with the possibility of vertical sliding along the high-rise support 1 with subsequent fixation of the selected 35 position. With the help of the auxiliary rim 3, the performance of the equipment 8 is improved by increasing its allowable power without the need to further increase the maximum stowage height. In the vertical position of the high-rise support 1, using a telescopic ladder based on the ^ auxiliary rim 3 on the roof of the building where the equipment is located, they provide the permissible levels of the electromagnetic field by adjusting the geometric dimensions of the structure 9, then using the telescopic ladder, they complete the adjustment of the equipment 8. premises of the building, on the roof of which the cellular antenna 8 is located, provide communication using cellular antennas located on the roofs of other buildings.

In the particular case of the implementation of the proposed method, in order to reduce the point load, in vertical positions the high-rise support 1 and the upper 5 parts of the two rims 2, 3 are interconnected in such a way that the load from the high-rise support 1 with the equipment 8 installed on it is distributed between all supports 6. Under the beams 10 connecting the supports 6, metal sheets are placed, connected to each other and to the beams 10, and the structure 9 is made of a Yskladny metal mesh with cell sizes less than the wavelength emitted by the equipment and a radio-absorbing material based on a flat elastic matrix. In this case, the structure 9 is placed along a plane perpendicular to the axis of the high-rise support 1, and as part of the structure 9, a folding metal mesh is installed between the radio-absorbing material 15 and the upper part of the main rim.

Figure 2 shows a high-rise support 1 in a vertical position.

In another particular case of the implementation of the proposed method, the upper part of the high-rise support 1 is made with the possibility of attaching the equipment rack to the metal holder 11. Provide the possibility of 20 longitudinal sliding of the equipment 8 along the high-rise support 1 together with the holder 11 in both directions using a reversible rope drive 12 installed at supports 6 of the high-rise support 1. One end of the rope, leaving the drive 12, through the inner space along the high-rise support 1 and the roller system in its upper part is connected to the 25 upper part of the holder 11, and the other end of the rope, leaving the drive 12, through the outer space along of the high-rise support 1 is connected to the lower part of the holder 11. On the high-rise support 1, an antenna of a cellular operator is placed as equipment 8, and the structure 9 is made of a metal plate or a metal mesh with 3O cell sizes less than the wavelength emitted by the antenna 8. By adjusting the geometric dimensions of the structures ui 9, taking into account the shape of the base of the roof of the building, along the antenna pole 8, a truncated pyramid or a truncated cone is formed, the larger base of which is directed towards the upper part of the main rim 2. Along the high-rise support 1 from the 35 side of its top, behind the antenna 8, there is an antenna 13 of the second cellular operator communication. In the interval between the two antennas 8 and 13, two structures 9 with large bases of the same shapes and sizes directed at each other are installed along their common rack. If necessary, antennas of other operators and structures for them are installed one after another from the side of the top of the tower in the same way. A folding mounting platform 14 is provided with the ability to slide along the vertical axis next to the high-rise support 1 in its vertical position. After raising antennas 8 and 13 to the maximum placement height, using the folding mounting platform 14 by adjusting the geometric dimensions of structures 9, they ensure the passage of signals emitted by antennas 8, 13 outside the circle or polygon formed by the boundaries of the roof of the building in the area protected from electromagnetic waves, then work 5 is completed on adjusting the antennas 8, 13. In the premises of the building, on the roof of which there are antennas 8, 13 provide communication due to antennas of cellular operators located on the roofs of other buildings.

In the next particular case of the implementation of the proposed method, the high-rise support 1 is made folding into two parts and with a cross-section in the form of a polygon. A hinge mechanism 15 is installed between two folding parts of the high-rise support 1 along an axis passing through one of the sides of the polygon. The structure 9 is made in the form of a flat container filled with radio-absorbing material and placed along a plane 15 perpendicular to the axis of the high-rise support. A liquid is used as a radio-absorbing material in the container, and all surfaces of the container are made of a material that transmits electromagnetic waves, for example, of plastic, porcelain or glass, and along the flat base of the container from the side of the upper part of the main rim 2, a folding metal mesh with dimensions that does not transmit electromagnetic waves is installed cells are shorter than the wavelength emitted by the equipment. The height support 1 can be in the form of a cylinder, a truncated cone or a truncated pyramid, and the slopes of the sides of the rims 2, 3 can be reduced to zero by regulation.

25 In Fig.Z shows a high-rise support as part of the device during its rotation.

In a particular example of the implementation of the proposed method, the upper part of the high-rise support is made in the form of metal pipes 16, 17 inserted into each other, which provide the possibility of longitudinal sliding of the ZO relative to each other similarly to the rods of a telescopic hydraulic cylinder, and the lower part of the high-rise support is made in the form of a frame 18 mount the lifting and traction mechanism 19. One of the sides of the base of the frame 18 is connected to the hinge mechanism installed under it on the stand 6, and at the other end the frame 18 is connected to 35 a pipe with the largest diameter 16 partially inserted into it. Equipment 8 is installed along the pipe with the smallest diameter 17, the lower part of which is connected through a metal rod to the working element of the lifting and traction mechanism 19. For simplicity, the diagram shows two end pipes 16 and 17 without intermediate ones.

40 In another particular example of the implementation of the proposed method, the upper part of the high-rise support is made in the form of prefabricated structures of metal elements inserted into each other with a cross-sectional shape in the form of a circle or polygon. The main rim 2 and the high-rise support are alternately turned using a reversible rope drive 20, which is installed at the support 6 of the high-rise support. One end of the rope 21, leaving the drive 20, through the roller system in the upper part of the auxiliary rim 3, is alternately connected to the main rim 2 and the high-rise support, and the other end of the rope 22, leaving the drive 20, is alternately connected to the main rim 2 and the high-rise support through the roller system 23, which is placed in the closest support 6 of the auxiliary rim 3 for the high-rise support 3. The high-rise support is rotated using a vertical block based on the two rims 2 and 3 connected to each other.

In the particular case of the implementation of the proposed method, each of the two rims 2 and 3 are made consisting of several levels in height. The high-rise support 1 is made in one piece and is installed on a double-acting hydraulic cylinder inserted into the frame 18. Along the high-rise support 1, metal rings are put on it, which are attached to the frame 18 and in the vertical position of the high-rise support 1 provide longitudinal sliding of the equipment 8 with it relative to the rings. The telescopic ladder is formed on the base of the upper level of the auxiliary rim.

A device that implements the inventive method is assembled segment by segment, from non-bulky elements, i.e. it is collapsible, in which the component parts of the device can be removable. With small dimensions and the necessary efforts, some operations, for example, turning the rims, can be performed using lifting and traction mechanisms with a mechanical drive, incl. manually.

Claims

Claim

METHOD FOR INSTALLING A HEIGHT SUPPORT ON THE ROOF OF A BUILDING

5 1. A method of mounting a high-rise support on the roof of a building, including the assembly of a high-rise support in a horizontal position and its rotation from a horizontal position to a vertical position, which consists in the fact that before assembling the high-rise support, the main and auxiliary rims are assembled, each of which is provided with link mechanisms and when The lifting and traction mechanisms provide the possibility of turning in both directions relative to their axis passing through the ends of the corresponding rim, and the rotation axes of the two rims are chosen perpendicular to each other and the high-rise support during assembly is laid along the axis of rotation of the auxiliary rim, characterized by the fact that the main rim and the high-rise support is provided with the possibility of turning separately from each other, while the bases of the rims and the high-rise support are made expanded in the form of polygons and, through the hinge mechanisms, are installed on supports, the overall dimensions of which are chosen to ensure the ground placement of the lever and lifting-pull mechanisms, and the stand of the high-rise support is installed at the central point of the segment connecting the ends of the main rim, while the auxiliary rim is made consisting of two identical, parallel-located parts, between which in one half of the auxiliary rim the space is left free, and the distance is chosen to ensure the passage of the high-rise support, rotated by means of a lifting and traction mechanism along a vertical plane relative to an axis passing through one of the sides of its base, moreover, the sides connecting the ends of the rims with their upper parts are retractable with the possibility of changing their slopes, while a telescopic ladder is formed on the basis of the auxiliary rim, steps which is attached to the sides of the two parts of the second half of the auxiliary rim, which is not used for the passage of the high-rise support, and at the level of the upper part of the main rim along the high-rise support from the side of its top, a cellular antenna 35 is placed or other equipment emitting and receiving electromagnetic waves, while in the gap between the upper part of the main rim and the equipment along its rack, a structure is installed that limits the return of reflected signals from it to the equipment and is made of materials that do not transmit electromagnetic waves, with the possibility of regulation by means of an auxiliary the rim of its slope, shape, size and distance to the equipment, and by means of the lifting-traction mechanism, the equipment is provided with the ability to slide along with the structure along the vertical axis from the level of the upper part of the main rim to the maximum placement height and back, while the assembly start with laying the beams along the pivot axes of the two rims, then the supports are installed on the beams, and the beam along the pivot axis of the auxiliary rim is laid with coverage of the equipment location in a horizontal projection during its installation, while 5 after assembly and subsequent rotation of the auxiliary rim from the horizontal position to vertical, assembled and turn the main rim and the high-rise support from horizontal to vertical one after another, with each base fastening along its perimeter to the corresponding stand, then the equipment, together with the structure U, is lifted along the vertical axis and its position is fixed at the maximum placement height, and the upper parts of the two rims are interconnected with the possibility of vertical sliding along the high-rise support with subsequent fixation of the selected position, and with the help of the auxiliary rim, the performance of the equipment is improved by increasing its permissible power unnecessarily This further increase in the maximum height of placement, while in the vertical position of the high-rise support, using a telescopic ladder based on an auxiliary rim on the roof of the building where the equipment is located, ensure the permissible levels of the electromagnetic field by adjusting the geometric dimensions of the structure, then completing the adjustment of the equipment, and in the premises of the building, on the roof of which a cellular antenna is located, communication is provided using cellular antennas located on the roofs of other buildings.

25 2. The method according to claim 1, characterized in that in vertical positions the high-rise support and the upper parts of the two rims are interconnected in such a way that the load from the high-rise support with the equipment installed on it is distributed between all supports, while under the beams connecting stands between themselves, metal ZOlists are placed, connected to each other and to beams, and the structure is made of a folding metal mesh with cell sizes less than the wavelength emitted by the equipment and a radio-absorbing material based on a flat elastic matrix, while the structure is placed along a plane perpendicular to the vertical axis supports, and 35 a folding metal mesh is installed between the radar absorbing material and the upper part of the main rim.

3. The method according to claim 1, characterized in that the upper part of the high-rise support is made with the possibility of attaching the equipment rack to the metal holder, while providing the possibility of longitudinal sliding of the equipment along the high-rise support together with the holder in both directions using a reversible cable drive installed at supports of the high-rise support, and one end of the rope leaving the drive through the inner space along the high-rise support and the roller system in its upper part is connected to the upper part of the holder, and the other end of the rope leaving the drive, through the outer space along the high-rise support is connected to the lower part of the holder, while the antenna of the cellular operator is placed on the high-rise support as equipment and the structure is made of a metal plate or metal mesh with cell sizes 5 different wavelengths emitted by the antenna, and by adjusting the geometric dimensions of the structure , taking into account the shape of the base of the roof of the building, a truncated pyramid or a truncated cone is formed along the antenna rack, the larger base of which is directed towards the upper part of the main rim, while along the high-rise support from the Uee of the top, antennas of other cellular operators are placed one after another, and in each gap between adjacent two antennas along their common rack, two structures are installed with large bases of the same shapes and sizes directed at each other, while a folding mounting platform is provided with the possibility of sliding along the vertical axis next to the height support in its vertical position, and after raising the antennas to the maximum placement height, using a folding mounting platform, by adjusting the geometric dimensions of the structures, they ensure the passage of the signals emitted by the antennas outside the circle or polygon formed by the boundaries of the building roof in its area protected from electromagnetic waves, then completing work on adjusting the antennas, while in the premises of the building, on the roof of which the antennas are located, they provide communication due to the antennas of cellular operators located on the roofs of other buildings.

25 4. The method according to claim 1, characterized in that the high-rise support is made folding into two parts and with a cross-section in the shape of a polygon, while between the two folding parts of the high-rise support along an axis passing through one of the sides of the polygon, a hinge mechanism is installed, moreover, the structure of the ZO is made in the form of a flat container filled with a radio-absorbing material and placed along a plane perpendicular to the axis of the high-rise support, while liquid is used as a radio-absorbing material in the container and all surfaces of the container are made of a material that transmits electromagnetic waves, for example, of plastic, porcelain or glass , and along the flat base of the container from the side of the upper part of the main rim, a folding metal mesh that does not transmit electromagnetic waves is installed with mesh sizes smaller than the wavelength emitted by the equipment.

5. The method according to claim 1, characterized in that the upper part of the height support is made in the form of metal pipes inserted into each other, which provide the possibility of longitudinal sliding relative to each other, similarly to the rods of a telescopic hydraulic cylinder, and the lower part of the height support is made in the form of a frame, in which mount the lifting and traction mechanism, while one of the sides 45 of the base of the frame is connected to the hinge installed under it mechanism on a stand, and at the other end the frame is connected to a pipe with the largest diameter partially inserted into it, and the equipment is installed along the pipe with the smallest diameter, the lower part of which is connected to the working element of the lifting and traction mechanism through a metal rod.

6. The method according to and. 5, characterized in that the upper part of the high-rise support is made in the form of prefabricated structures of metal elements inserted into each other with a cross-sectional shape in the form of a circle or polygon, while the main rim and the high-rise support are alternately rotated using a reversible rope drive, which is installed at the stand high-rise support, and one end of the rope leaving the drive, through the roller system in the upper part of the auxiliary rim, is alternately connected to the main rim and the high-rise support, and the other end of the rope, leaving the drive, is alternately connected to the main rim and the high-rise support through the roller system, which placed in the support of the auxiliary rim closest for the high-rise support, while the high-rise support is turned using a vertical block based on two rims connected to each other.

7. The method according to claim 5, characterized in that each of the two rims is made consisting of several levels in height, while the high-rise support is made in one piece and it is installed on a double-acting hydraulic cylinder inserted into a metal frame, and metal is put on it along the high-rise support the rings, which are attached to the frame and in the vertical position of the high-rise support, provide longitudinal sliding of the equipment with it relative to the rings, while the telescopic ladder is formed on the base of the upper level of the auxiliary rim.