RU2428551C1 - Tower of collapsible design for antenna systems - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: tower of collapsible design for antenna systems comprises a support-lifting device (SLD) with a working platform adjacent to it at the side, which have frames arranged with the possibility of installation in a fixed position on the appropriate first embedded parts of the prepared site, a mast in the form of a spatial collapsible structure from transportable support sections, which are serially detachably connected to each other as the tower is erected with the help of the SLD and the working platform in the area of the tower development. The tower is detached with the help of guy cables, which are installed between the mast and the second embedded parts of the prepared site. The tower is equipped with detachable guy lines arranged with the possibility of installation between the upper part of the SLD and the third embedded parts of the prepared site, the SLD and the working platform are interconnected to each other in the area of the tower development. At the same time the SLD is detachably connected to the mast and serves as the tower base in its working position, on the upper section of the mast, in the area of the tower development, there is a collapsible platform of the antenna system fixed detachably, where a device is mounted to level the antenna system, which is arranged with the possibility to install the antenna system support-lifting device on it. The collapsible platform is arranged with the possibility of installation of a radiolucent shelter on it. Besides, the SLD and the working platform are arranged with the possibility of arrangement on transport platforms, frames of which are structurally combined accordingly with the SLD and the working frame frames, are arranged with the possibility of detachable connection to the appropriate wheel sets and with the possibility to be installed on the specified prepared site as the wheel sets are disconnected, at the same time in the transport position the working platform serves as a loading platform of the SLD detachable elements.

EFFECT: improved technical and operational characteristics.

6 cl, 7 dwg

Description

The invention relates to antenna technology, in particular to transportable supports of antenna systems of radar stations.

Known transported antenna mount, containing three masts, mounted on a common base, and guy wires, fixed at one end on the tops of the masts (RU 2024125 C1 (H01Q 1/12, 1994). Each mast is assembled from separate sections, fastened using threaded connections. the masts are rigidly connected at several levels by horizontal struts.The platform of the radar antenna system is pivotally mounted on the tops of the masts.

However, the known transported antenna mount is intended for low altitude radars, i.e. has a limited scope. In addition, in the case of using a similar design for an antenna mount of considerable height, installation is significantly complicated.

Known antenna support mast for radio transmitting antennas, containing a barrel of variable cross-section, made of sections that are made of pipes of different diameters and are interconnected using flanges through bolted connections followed by welding (RU 85529 U1, E 04H 12/08, 2009) . In the upper part of the trunk is a platform (platform), which is rigidly fixed to the trunk through the braces. At the edges of the site are installed elements to which the antenna is mounted. Maintenance and installation of the antenna is carried out using a ladder fixed along the entire height to the trunk. The antenna support mast is fixed through the support heel to the concrete foundation grillage by means of anchor bolts. The lower section of the barrel of the antenna support mast can be easily disconnected from the concrete foundation grillage, this allows mobile reinstallation of the antenna support mast. In an embodiment of the invention, the height of the antenna support mast is up to 25 m, the length of the sections is 5 m.

The disadvantages of the known antenna support mast can be attributed to the lack of cables, which does not allow to ensure a stable position of the platform of the antenna system when exposed to wind and, ultimately, reduces the accuracy of guidance. This eliminates the possibility of using an antenna support mast for rotary antenna systems.

A sectional mast is known in the form of a spatial structure of support sections mounted on a foundation, described in the patent specification WO 4076781 A1 (E 04H 12/10, 2004). Sections of such a mast are located inside a lifting installation designed for successive lifting of the mast sections. After lifting the upper mast section, an adjacent mast section is placed underneath it inside the lifting installation and this section is attached to the raised upper section. In this sequence, all mast sections are lifted. The lifting installation has drives connected by a transmission to the lifting sections.

However, the known sectional mast is intended for wind power stations and has a relatively small height.

A well-known tower (mast) collapsible design, including a support-lifting device (OPU) with remote rotating adjustable legs, made with the possibility of installation in a fixed position on the prepared site, the mast in the form of a spatial collapsible structure of transportable modules (support sections) which are sequentially detachably interconnected when erecting the tower with the help of the control tower in the place of deployment of the tower, while the control panel is detachably connected to the mast and serves as the base for ki in its working position, and the tower is unfastened using flexible rods (cables), which are installed between the upper module of the tower and peripheral supports located on the prepared site (essentially on the ground) around the tower (RU 2075643 C1, F03D 11/04, 1997). The tower is also equipped with mechanisms for changing lengths and for tensioning flexible rods. The supporting-lifting device provides positioning and lifting-lowering of the structural elements of the tower during its deployment-folding. The assembly of the tower (mast) is carried out stepwise by successive lifting of the components. The lifting of each of the modules of the tower (mast) is made through the through channel in the OPU. To prevent skewing of the modules when they are pulled out of the control panel inside said through channel, guides interacting with the response elements of the modules are provided. Raised modules are equipped with means for placing and fixing functional equipment (for example, nodes for fixing lighting fixtures, electric cables). The tower (mast) is made of the same type of modules, the lower of which is mounted and fixed inside the control panel. The supporting-lifting device is arranged to be placed on a transport platform. At the same time, the features of the OPU implementation provide the possibility of its loading and unloading without the use of external lifting means. This is achieved, in particular, thanks to the portable, rotating, height-adjustable support legs, which, in the position of support on the ground, form an opening between the soil and the lower parts of the foundation, the height is definitely greater than the height and width of the transport platform for transporting the tower, which allows you to install the transport platform under the support lifting device. In an embodiment of the invention, the installation of the tower (mast) is carried out by two people in 1 hour.

However, the design features of the well-known tower suggest the installation of a relatively small mass and size on its top, which limits the area of use of the tower and does not meet the target characteristics of the antenna mount, designed for sufficiently large antenna systems of a radar with a protective radiotransparent shelter.

The closest set of essential features with the claimed invention is a tower (tower) collapsible design, including a mast in the form of a spatial collapsible design of transportable support sections (modules), and the tower is unfastened using cables that are installed between the mast and embedded parts prepared site (JP 8035358 A, E 04G 21/14, E 04H 12/20, E 04H 12/34, 2002). The cables are tensioned using winches mounted on the embedded parts of the prepared site. The tower is mounted using a temporary support and lifting device and a working platform adjacent to it on the side of the platform, which have frames made with the possibility of installation in a fixed position on the corresponding embedded parts of the prepared site. Mounting the tower is done by growing. One of the sides of the temporary GPC is made open to move support sections from the working platform to its platform. The support sections are sequentially pushed up with the help of a temporary control gear hoist, pre-installing them on the platform of the latter. In this case, each subsequent structural element (module) is fixed under the previous one. In the process of erecting a tower (tower), some ends of the cables are connected to the upper section of the tower, and others to winches.

Such a collapsible tower can be used as a transportable antenna support for large enough radar antenna systems. However, for the installation of the known tower, a separate temporary support and lifting device is used, which in itself is not an integral part of the tower, which increases the deployment-coagulation time when the tower is relocated, increases the complexity of the work and the cost of the structure as a whole.

The objective of the present invention is to provide a portable collapsible antenna support (tower) of considerable height, designed for large enough radar antenna systems with a radiotransparent protective cover and providing the possibility of its rapid deployment-coagulation during relocation, and the possibility of installing a platform with an antenna radar system at a given at a height determined by the terrain, while ensuring sufficient accuracy of the radar guidance.

This problem is solved in that the tower collapsible design for antenna systems, containing a supporting-lifting device adjacent to it on the side of the working platform, which have frames made with the possibility of installation in a fixed position on the corresponding first embedded parts of the prepared site, mast in the form of a spatial collapsible design of transportable supporting sections, which are sequentially detachably interconnected during the construction of the tower using the OPU and the working surface tformy a deployment site tower, wherein the tower raskreplena using shrouds, which are mounted between the mast and a second pad embedded parts prepared according to the invention provided with a detachable back lines adapted to be inserted between the upper part of the OPU and third portions mortgage prepared site. The supporting-lifting device and the working platform are interconnected at the tower deployment site, while the control gear is detachably connected to the mast and serves as the base of the tower in its working position. A folding-folding platform of the antenna system is detachably fixed on the upper section of the mast in the place of deployment of the tower. A device for leveling the antenna system is mounted on a folding-folding platform, which is configured to install a rotary support device of the antenna system on it. The folding-folding platform of the antenna system is made with the possibility of installing a radio-transparent shelter on it. In this case, the control gear and the working platform are arranged to be placed on transport platforms, the frames of which are structurally combined with the frames of the control gear and the working platform, are made with the possibility of detachable connection with the corresponding wheel assemblies and with the possibility of installation on the prepared site when disconnecting the wheel assemblies. In the transport position, the working platform acts as a cargo platform for removable elements of the control gear.

In an embodiment, the barrel is configured to provide a predetermined tower height by changing the number of supporting sections installed during the construction of the tower.

Along with this, the tower contains a lifting means, which is mounted on the platform of the antenna system.

In addition, the tower contains a removable lifting means, which is mounted on the upper part of the control tower in the place of deployment of the tower.

In an embodiment, the tower is equipped with removable hinged stairs and removable service platforms installed on the control tower in the place of deployment of the tower.

The folding-folding platform is configured to provide access from the mast to the equipment and apparatus located on it.

The technical result of using the invention is that it is possible to create a transportable tower of considerable height, the functionality and characteristics of which are not inferior to those of a stationary tower. At the same time, due to the fact that in the proposed device, the frames of the support-lifting device and the working platform are frames of transport platforms, it is possible to create compact mobile modules that reduce the deployment-folding period of the tower during relocation. In addition, the invention, ensuring the adaptability of the tower to the terrain, extends the operational capabilities and allows you to optimize the overall dimensions of the tower. Thus, in General, the technical result of the use of the invention is to improve technical and operational characteristics.

Figure 1 schematically shows the tower collapsible design for antenna systems, General view; figure 2 is the same, view along A in figure 1 (plan view); figure 3 - supporting-lifting device with adjacent working platform, a cross section along BB in figure 1; figure 4 - supporting and lifting device with removable hinged stairs and removable service platforms, a longitudinal section along BB in figure 3, is rotated; figure 5 - supporting-lifting device in the transport position, General view; figure 6 - working platform in the transport position, General view; in Fig.7 - the upper part of the mast of the tower and folding-folding platform with equipment installed on it, general view.

In an embodiment of the invention, the collapsible tower serves as a means for lifting and installing at a height of, for example, 20-50 m antenna systems of radar stations.

The tower of the collapsible design (hereinafter referred to as the tower) comprises a support and lifting device 1 with a working platform 2 adjacent to it from the side and a mast 3. The supporting and lifting device 1 and the working platform 2 have frames 4 and 5, respectively, made with the possibility of installation in a fixed position on the embedded parts 6 of the prepared platform 7. The mast 3 is made in the form of a spatial collapsible design of transportable supporting sections (modules) 8-10, which are sequentially detachably respectively interconnected, for example, with the help of threaded elements in the place of deployment of the tower when it is erected using the control gear 1 and the working platform 2. The tower is erected using, for example, a hydraulic drive of the aforementioned support and lifting device (not shown in the drawing) by successively lifting the support sections (modules ) towers mounted on top of each other in such a way that they form a tower structure. In this case, each subsequent support section to be mounted is introduced under the support section raised before it and is fixed under it. In an embodiment of the invention, the mast is configured to provide a predetermined tower height by changing the number of supporting sections 10 installed during the construction (installation) of the tower at the deployment site. This embodiment, ensuring the adaptability of the tower to the terrain, extends the operational capabilities and allows you to optimize the overall dimensions of the tower.

Supporting and lifting device 1 provides positioning, installation-dismantling and lifting-lowering of the structural elements of the tower during its deployment-folding. In an embodiment of the invention, the RAM 1 is made in the form, for example, of two detachably connected lower “a” and upper “b” sections. In the lower section “a” of the control panel there are placed means for raising and lowering the structural elements (supporting sections) of the tower, including double-acting actuating hydraulic cylinders, and electrical equipment. The upper section "b" is intended, in particular, to ensure the extension of the tower support modules from the control panel. To avoid skewing of the support sections (modules) when extending from the control panel inside its upper section, guides are provided that interact with the response elements of the support sections (not shown in the drawing). The working platform 2 is equipped with a roller table (not shown), made with the possibility of interaction with the supporting sections (modules) of the tower.

The supporting-lifting device 1 is detachably connected to the mast 3 in the place of deployment of the tower and serves as the base of the latter in its working position. To impart the required rigidity to the supporting-lifting device, the tower is equipped with removable adjustable (for example, using lanyards) guy wires 11, made with the possibility of installation between the upper part of the control panel and the embedded parts 12 of the prepared platform 7. Together with this, the tower is unfastened using cables 13 and 14, which are installed between the mast 3 and the embedded parts 15 of the prepared site 7, located around the tower. The cables are tensioned using winches 16-18 installed on the embedded parts, for example, with electric drives (not shown in the drawing). On the upper support section (module) 8, at the deployment site of the tower, a folding-folding platform 19 is detachably fixed with, for example, using struts 20 struts, on which a radiotransparent shelter 21 of the antenna system 22 is installed, which protects the antenna system from the effects of atmospheric precipitation and from the wind exposure. The implementation of the folding platform 19 allows for transportation to ensure its compact placement within the loading envelope. A device 23 is also mounted on the platform 19 for leveling the antenna system 22. The device 23 is configured to mount a rotary support device of the antenna system (not shown). In an embodiment, the leveling device is, for example, an electromechanical device with worm-screw jacks, which is electrically connected to a leveling sensor mounted on the basis of the said rotary support device (not shown in the drawing). Thanks to the device 23, an increase in the operational characteristics of the tower is achieved. Folding-folding platform 19 is made with the possibility of providing the mast access to placed on it equipment and apparatus. For this, a hatch is provided on the platform (not shown in the drawing).

The supporting-lifting device 1 and the working platform 2 are arranged to be placed on transport platforms 24 and 25, respectively. Each transport platform contains a frame and wheel units, which are made in the form of front and rear axles 26, 27, each of which includes a depreciation device, a brake a device connected by a compressed air system and a screw jack (not shown in the drawing). The frames of the transport platforms are structurally combined, respectively, with the frame 4 of the control gear 1 and the frame 5 of the working platform 2. Each transport platform is made in the form of a biaxial trailer transported by the tractor. The frames of the transport platforms (essentially - the frame of the OPU and the frame of the working platform) are detachably connected to the corresponding wheel assemblies and are made with the possibility of installation in a fixed position on the embedded parts of the prepared platform 7 when disconnecting the wheel assemblies. In the transport position, the working platform 2 acts as a cargo area for removable elements of the control tower 1. Such a design of the control tower 1 and the working platform 2 provides the possibility of creating compact mobile modules that allow for quick deployment-collapse during relocation.

In an embodiment of the invention, for the convenience of maintenance during installation and operation, the tower is equipped with a folding (transformable) lifting means 28 and a removable lifting means 29. The folding lifting means 28 is mounted on a folding-folding platform 19 and is transported together with the latter. The removable lifting means 29 is mounted on the upper part (section) of the control tower 1 at the location of the tower deployment and is transported separately from the control tower. Also, the tower is equipped with removable hinged stairs 30 and 31 and removable service platforms 32 installed on the control tower in the place of deployment of the tower. In the central part of the mast 3 (essentially inside the mast), the support sections (modules) 10 connected in series form a gangway with a guard (not shown in the drawing). The two upper supporting sections 8 and 9 are equipped with hinged elements and transitional platforms that provide access for maintenance personnel from the central part of the mast to the folding-folding platform 19 through the hatch provided in this platform. The platform 19 also has a cargo hatch, which is used when working with a lifting means 28. In addition, inside the spatial structure of the mast 3, means are also provided for placing and fixing functional objects (for example, cables, lighting devices, etc.).

The tower collapsible design works as follows.

In the transport position, the lower section “a” of the support-lifting device 1 is placed on the frame 4 of the transport platform 24, and its upper section “b” is placed on the frame 5 of the transport platform 25. Transport platforms 24 and 25 are mounted on the corresponding front and rear axles (wheeled nodes) 26 and 27. In this position, the control tower is delivered to the prepared site 7. In the transportation position to the place of deployment of the tower, the control tower and other structural elements of the tower can be transported by land (rail and road), water (sea Kim and river) and air transport. The transportation of the OPU by road can be carried out using two tractors. Transportation of supporting sections (modules) 8-10 and winches 16-18 can be carried out using onboard vehicles, for example, KamAZ-43118. In this case, two of the on-board vehicles can be coupled with transport platforms 24 and 25, respectively. In an embodiment of the invention, the support section 9 is in the transport position in the lower section “a” of the control deck 1. The folding-folding platform 19 can be transported, for example, with using the MZKT-938B semi-trailer coupled to a BAZ-6402 truck tractor. Loading and unloading operations can be carried out, for example, using a KS-4562 truck crane or another crane with a sufficient lifting capacity.

The embedded parts 6,12 and 15 are supplied separately and mounted in advance at each of the positions located in the areas of operation of the mobile tower.

In an embodiment of the invention, when the tower is delivered to the deployment site on motor vehicles, the latter is deployed as follows. Preliminarily, the support-lifting device 1 and the working platform 2 are installed on the prepared platform 7. When the transport platform 24 (25) enters the prepared platform 7, the corresponding stops and wheel bumpers (not shown) interact with the wheels of the front 26 and rear 27 bridges, providing centering in the transverse direction of the frame of the transport platform relative to the embedded part 6. The transport platform 24 (25) is installed in a predetermined position above the embedded part 6. Then with using screw jacks, which in an embodiment are an integral part of the front and rear axles, the transport platform frame with the OPU 1 (working platform 2) located on it is lowered to the embedded part of the platform 7. The front and rear axles are disconnected from the transport platform frame, which are rolled back to the place their storage. In an embodiment of the invention, the front 26 and rear 27 bridges of the transport platform 24 (25) are adapted to engage with each other, which facilitates the operation of the device.

Installation of the OPU 1 consists in installing and securing the upper section “b” on the lower section “a”. Work is carried out using a truck crane. After the installation of the supporting-lifting device, the hydraulic drive of the control gear is activated. The supporting section 9, installed in a predetermined position in the lower section of the control panel, is raised, for example, by 1.1 m. After the lower section "a" of the control panel 1, one of the supporting sections 10 is fed with the roller table of the working platform 2 and the latter is fixed relative to the control panel. Then, the raised support section 9 is lowered, for example, by 0.1 m. The upper part of the support section 10 is detachably connected to the lower part of the support section 9 using appropriate threaded elements. After that, the support section 9 is assembled with the support section 10 by 1.1 m . On the lower section "a" of the OPU 1 serves the next support section 10. And the cycle repeats. Thus, by successively raising the support sections mounted on top of each other, so that they form a tower structure, they provide a predetermined tower height.

When mounting the tower on the prepared site 7 on the upper support section 8 detachably install a folding-folding platform 19 with a device 23 for leveling the antenna system. Between the platform 19 and the support section 8, adjustable struts 20 are installed. Winches 16-18 are installed on the embedded parts 15 of the prepared platform 7.

After the support section 9 is extended from the OPU 1, the support section 8 and the platform 19 with the equipment installed on it are mounted on it in a predetermined position. Sections 8 and 9 are detachably interconnected. Then, the rotary support device of the antenna system 22 is installed on the device 23 (essentially the antenna system as a whole). On the platform 19 establish a radio-transparent shelter 21 of the antenna system. The corresponding ends of the cables 13 are fixed on the support section 8. Next, the tower is mounted with constant tension of the cables 13 using, for example, ball couplings (not shown) of winches 16 and 17, adjusted for a force of, for example, 1 tf. When the height of the tower reaches, for example, half of the height of the tower in the working position (i.e., half of the set height of the tower), the corresponding ends of the shafts 14 are fastened to the last extended support section 14. The tower is then mounted with constant tension as a cable stay 13 and guy 14. The tension of the latter is ensured by means of corresponding ball couplings of the winches 18, adjusted for a force of, for example, 1 tf (not shown in the drawing).

During the extension of the tower, functional objects are fastened (for example, cables, lighting devices, etc.).

After the tower is extended to a predetermined height, the lower support section 10 is secured to the control rail 1 using the corresponding threaded elements. Then, the aforementioned ball joints of the winches 16-18 are manually locked. The winches 16-18 are turned on, providing, using other ball couplings (not shown in the drawing) of the winches 16-18, the tension of the cables 13 and 14 to a force of, for example, 3 tf. Turn off the winch 16-18. In parallel, with the help of the leveling sensor installed on the basis of the rotary support of the antenna system 22, the angular position of the platform 19 is monitored. If the permissible angular deviation of the platform 19 from the horizontal position is exceeded, the power of the winches is automatically turned off. Using the device 23 in automatic mode, the leveling of the slewing ring of the antenna system is carried out. During the “watch” period of the antenna system, if necessary, in a similar way, the horizontal alignment of the rotary support device of the antenna system is automatically carried out. Thus, when the radar antenna system is operating, the horizontal position of the rotary support device with the antenna system is automatically maintained (essentially, the azimuthal axis of the radar guidance is vertical), which ultimately improves the accuracy of the radar antenna pointing.

The leveling of the rotary support of the antenna system completes the deployment of the tower.

Tower folding is carried out in the reverse order. The difference is that when the tower is dismantled, winch drives 16-18 are activated to create a constant force in cables 13 and 14 (their ball couplings adjusted to a force of 1 tf are triggered) and the expended power of the winch drives and the OPU 1 drive are summed up.

Thus, due to the particular design of the collapsible tower, the invention provides the possibility of creating a transportable tower of considerable height, designed for sufficiently large antenna systems of the radar with a radio-transparent protective shelter and providing the possibility of its rapid deployment-coagulation during relocation, provides the adaptability of the tower to the terrain due to the provision of the possibility of installing a platform with a radar antenna system at a given height, determined by the relief om the terrain, while ensuring sufficient accuracy of the radar guidance, which extends the operational capabilities and allows you to optimize the overall dimensions of the tower. At the same time, it is possible to create a transportable tower of considerable height, the functionality and characteristics of which are not inferior to those of a stationary tower.

Claims (6)

1. A tower of a collapsible design for antenna systems, comprising a support-lifting device (OPU) adjacent to it on the side of the working platform, which have frames made with the possibility of installation in a fixed position on the corresponding first embedded parts of the prepared site, the mast in in the form of a spatial collapsible design of transportable support sections, which are sequentially detachably interconnected when erecting the tower using the control tower and the working platform at the deployment site I towers, while the tower is unfastened with cables that are installed between the mast and the second embedded parts of the prepared platform, characterized in that it is equipped with removable guy rods made with the possibility of installation between the upper part of the control panel and the third embedded parts of the prepared platform, the control panel and the working platform are interconnected at the tower deployment site, while the control gear is detachably connected to the mast and serves as the base of the tower in its working position, on the upper mast section at the deployment site and a folding-folding platform of the antenna system is mounted detachably on which a device for leveling the antenna system is mounted, which is configured to mount a rotary device of the antenna system on it, while the folding and folding platform is configured to install a radiotransparent shelter on it, and the working platform are made with the possibility of placement on transport platforms, the frames of which are structurally combined respectively with the frames of the OPU and the working platform, ying to releasably connect with the respective wheel assemblies and to be mounted on said prepared site when detaching the wheel assemblies, while in the transport position the working platform serves as a loading platform for removable elements OPU. 2. The tower according to claim 1, characterized in that the mast is configured to provide a given tower height by changing the number of supporting sections installed during the construction of the tower. 3. The tower according to claim 1, characterized in that it contains a lifting means, which is mounted on the platform of the antenna system. 4. The tower according to claim 1, characterized in that it contains a removable lifting means, which is mounted on the top of the OPU in the place of deployment of the tower. 5. The tower according to claim 1, characterized in that it is equipped with removable hinged stairs and removable service platforms installed on the control tower in the place of deployment of the tower. 6. The tower according to claim 1, characterized in that the folding-folding platform is configured to provide access from the mast to the equipment and apparatus located on it.

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