RU2386198C1 - Discone antenna to be installed on telescopic tower - Google Patents

Abstract

FIELD: radio engineering. ^ SUBSTANCE: according to invention, discone antenna consists of conductive disc and conductive cone, which are made of movable and fixed tubes. In order to install discone antenna on telescopic tower, the antenna has upper and lower attachment points, which are located at the top and at the bottom of the cone. Upper point will be fixed at the top of telescopic tower, and lower point in deployed position of antenna is installed on the section of telescopic tower, which is the second one from above. Also discone antenna has guides, system of rods and retention mechanism for automatic deployment and retraction of antenna on telescopic tower. At that, the drive which provides discone antenna deployment and retraction is telescopic tower itself. Movement of tower induces movement of antenna, additional drive mechanisms are not required. ^ EFFECT: quick and effective deployment and retraction of discone antenna having the height of about several metres, and the whole antenna-tower device in general. ^ 4 dwg

Description

The invention relates to antenna-feeder devices and can be used as an antenna for installation on a telescopic mast.

Known constructions of disc-cone antennas intended for installation on telescopic masts in a position when the cone is below the disk [1, 2, 3]. They are fixed on the masts or the base of the cone [2], or from the inside of the top of the cone [1]. But both of these mounting methods [1, 2] are unacceptable in the case when the disk-cone antenna has a vertical size of the order of several meters. In this case, with significant lateral loads, for example, in strong winds, the forces acting on the disk-cone antenna are so large that they can cause its deformation and lead to destruction. In this case, the telescopic mast is also subject to premature wear.

A technical solution is known [3], which allows to securely mount a disc-shaped antenna several meters in size on a telescopic mast. This antenna is fixed at two points: at the top and at the base of the cone. This discus antenna [3] is the closest to the proposed invention. It works reliably and is able to withstand maximum wind loads, designed to work in stationary conditions. In the mobile version, with frequent folding and deployment of the antenna mast device, this antenna for transportation must be disassembled each time. To work on the air, it is again assembled and installed on a telescopic mast, and upon completion of work it is removed from the mast and disassembled for transportation. The need to assemble and disassemble the antenna requires additional time, and due to the large dimensions of the antenna an additional number of people and additional safety measures. If the antenna needs to be deployed and collapsed in a short time, this option is not suitable.

Thus, the main disadvantage of the prototype is that when working in a mobile version, the antenna prototype requires additional: time, labor and safety measures.

The main task to be solved by the claimed invention is directed is to reduce time and labor costs, as well as to increase safety when working with a discus antenna in a mobile version.

The specified technical result is achieved by the fact that in a discus antenna for installation on a telescopic mast, consisting of a conductive disk and a conductive cone, made of tubes containing a mount, consisting of two parallel parts that do not have an electrical connection to the cone, the upper of which is rigidly connected with the second section from the top of the telescopic mast, and the bottom is made with the possibility of its movement along the telescopic mast and has a structural connection with a cone near its base, at In the upper part, holes are made through which parallel to the telescopic mast guides connected to the cone near its apex pass, the disk and cone consist of movable and fixed tubes interconnected by hinges, while the fixed cone tubes are fixed at the top of the cone and the stationary tubes of the disc fixed near the top of the cone, the upper rods are connected on one side to the movable tubes of the disk by means of hinges, and on the other hand to the movable tubes of the cone by means of hinges and carriages, replicated on the cone tubes with the possibility of moving along them, the middle rods are connected on one side to the movable tubes of the cone by means of hinges and carriages, and on the other hand by means of hinges with a supporting vertical pipe attached to the top of the cone, the lower rods are connected by hinges on one side with moving tubes of the cone, and on the other hand with the lower part of the mount, having holes for rigid guides with stops at their ends, to fix the connection of the lower part to the upper yokes with return springs located on the lower part on hinges and corresponding rollers located on the upper part, as well as levers rigidly fixed at the ends of the lower rods on the lower part.

Figure 1 and figure 2 shows the design of the discus antenna for installation on a telescopic mast in the initial and operating positions, respectively. Figure 3 shows the position of the hooks 15, the rollers 16 and the levers 17 before or after connecting the upper 10 and lower 12 parts of the lower attachment during deployment or folding of the discus antenna on the telescopic mast 11. Figure 4 shows their position during fixing the connection top 10 and bottom 12 parts of the mount of the disk-cone antenna.

The discus cone antenna consists of a conductive disk and a conductive cone made of tubes. The disk consists of movable 3 and fixed 5 tubes, interconnected by hinges. The cone also consists of movable 1 and fixed 6 tubes connected by hinges. The upper rods 4 connect the movable tubes 3 of the disk with the movable 1 tubes of the cone by means of carriages 9 mounted on the movable tubes 1 of the cone with the possibility of movement along them. The middle rods 8 connect, through the carriages 9, the movable cone tubes 1 to the vertical support tube 7. The lower rods 13 connect the cone movable tubes 1 to the lower 12 part of the attachment point. The upper 10 part of the mount is mounted on the second section of the telescopic mast 11. Through the holes in the lower 12 and upper 10 parts of the mount are guides 2 having a rigid structure. Hooks 15 with return springs 14 are located on the lower 12 part of the fastener assembly. The corresponding rollers 16 are located on the upper 10 part. And at the ends of the lower rods 13, levers 17 are rigidly fixed at the ends of the lower link 13.

The device operates as follows.

Before installing the discus antenna, the telescopic mast 11, when folded, is mounted on the ground in a vertical or inclined position, depending on the dimensions of the antenna. Then, sections of the mast 11 are partially extended and, at its top, by means of a vertical support pipe 7, a disk-cone antenna is fixed in a collapsed position. In the collapsed position, the movable tubes 3 of the disk and the movable tubes 1 of the cone are parallel to the longitudinal axis of the antenna. When installing the antenna, the mast 11 is sequentially drawn through the holes in the lower 12 and upper 10 parts of the mount located at the base of the cone. Next, the top of the cone by means of a supporting vertical pipe 7 is fixed on the upper, first section of the mast 11, and the top 10 part of the attachment point is fixed on the second from the top of the mast section 11. After attaching the antenna, the mast 11 is installed in a vertical position and fixed to the ground by guy wires. Further, by means of a winch, the sections of the mast 11 are extended to the working height of the antenna installation. The antenna in a collapsed position begins to rise up. As the antenna rises, due to the difference in the speeds of movement of the first and second sections of the mast, the distance between the upper 10 and lower 12 parts of the mount is reduced. The lower 12 part of the fastener assembly connected through the cone structure to the first section of the mast 11 moves faster and catches up with the upper 10 part fastened to the second section of the mast 11. Upon further lifting of the mast 11, the upper 10 and lower 12 parts of the fastener assembly moving along the guides 2 meet Further, under the pressure of the upper 10 part, the lower 12 part of the fastener assembly begins to move downward relative to the top of the cone. The force caused by the pressure of the upper 10 part through the lower 12 part and lower rod 13 is transmitted to the movable tubes 1 of the cone, and the antenna begins to unfold, like an umbrella. In this case, the entire design of the discus cone antenna unfolds simultaneously. The upper 10 part and the lower 12 part move down, and the lower rods 13, mounted on hinges, begin to rotate in a vertical plane. The levers 17, rigidly fixed at the ends of the lower rods 13 from the side of the lower 12 of the fastener assembly part, rotate together with the lower rods 13 and deviate downward, freeing the hooks 15. Under the action of the return springs 14, the hooks 15 turn on their axes in a vertical plane after the levers 17 and engage with the rollers 16 mounted on the top 10 of the part. Thus, the connection of the upper 10 part of the mount with the lower 12 part is fixed. The force acting from the side of the lower rods 13 has a component perpendicular to the longitudinal axes of the movable tubes 1 of the cone. It lifts up the movable tubes 1 of the cone and the carriages 9 fixed on them. The middle rods 8 are fastened at one end by hinges to the vertical support tube 7 and are connected in the same way to the carriages 9. Therefore, when moving upwards, the carriages 9 are described in a vertical plane an arc of constant radius. This arc is directed upwards so that the tangent at its upper point is close to the vertical. Moving along the arc, the carriages 9 at the same time rise up along the tubes 1 of the cone, as along the guides, towards the top of the cone. Together with the carriages 9, the upper links 4 connected with them also rise, which, in turn, lift up the movable tubes 3 of the disk connected to them. The movable tubes 3 of the disk rise up simultaneously with the movable tubes 1 of the cone, and at the end of the lift they also simultaneously occupy the working position. Thus, when the mast 11 is pulled up, at the same time, the cone movable tubes 1 are lifted up by means of the lower attachment point and the lower rods 13, and the movable tubes 3 of the disk are lifted up by means of the middle rods 8, the carriages 9 and the upper rods 4. The movable tubes 3 of the disk rise up, firstly, due to the upward deflection of the movable tubes 1 of the cone, and secondly, due to the movement of the carriages 9 up the movable tubes 1 of the cone. This allows a non-equidistant rise of the movable tubes 3 of the disk in comparison with the movable tubes 1 of the cone. Despite the fact that the movable tubes 3 of the disk are driven by the movable tubes 1 of the cone, they are deflected by a larger angle than the movable tubes 1 of the cone. In this embodiment, when the movable cone tubes are deflected upward by 20 °, the movable disc tubes deflect upward by 90 °. The simultaneous upward extension of the mast sections 11, downward movement along the guides 2 of the fastener, the deployment of the movable tubes 1 of the cone and the movable tubes 3 of the disc ends when the fastener reaches the lower ends of the guides 2. At the lower ends of the guides 2 there are stops designed to stop the mount . Simultaneously with the stop of the attachment site, the deployment of the disk and the cone ends, while the movable tubes 3 of the disk occupy a horizontal position, and the angle between the movable tubes 1 of the cone and the axis of the cone reaches a predetermined value. The antenna is raised to a working height, brought to a working position and securely mounted on a mast 11 at the top and bottom of the cone.

After the end of the operation of the antenna on the air, the antenna mast device is collapsed. In this case, by reverse rotation of the winch, the mast 11 is collapsed and the antenna is collapsed simultaneously. As a result of the rotation of the winch, the sections of the mast 11 move in the opposite direction down to the ground. The folding of the antenna, as well as its deployment, occurs due to the difference in the speeds of the sections of the mast 11, which are associated with the upper 10 and lower 12 parts of the antenna mount. The top 10 part moves up and pulls the bottom 12 part along, because hooks 15 and rollers 16 fix their connection. The entire lower attachment point moves inside the antenna toward the top of the cone. He pulls the lower rods 13, which in turn pull the movable tubes 1 of the cone. The angle between the axis of the cone and the movable tubes 1 of the cone is reduced. The moving tubes 1 of the cone, dropping down, pull the middle 8 and upper 4 rods behind them by means of the carriages 9. The middle rods 8, rotating on the axes mounted on the vertical support tube 7, are deflected down, and the carriages 9 move along the moving tubes 1 of the cone down from tops of the cone. Moving down, they pull the upper rods 4, which in turn pull the movable tubes 3 of the disk. The movable tubes 3 of the disc deflect downward. The antenna coagulates. At the end of coagulation, the antenna assumes a transport position in which the movable tubes 3 of the disk and the movable tubes 1 of the cone become parallel to the mast 11. At this point, the hooks 15 and the rollers 16 are disengaged, freeing the upper 10 and lower 12 parts of the mount. Following this, the upper part 10 is separated from the lower 12 and moves upward, towards the top of the cone, following the movement of its mast section 11, and the entire antenna, remaining in the folded transport position, goes down. Thus, the antenna coagulates. After the collapse of the mast 11, the antenna is removed from it. It is already ready for transportation and does not require additional disassembly.

Thus, this technical solution allows the entire process of lifting to a working height, deploying the antenna to the working position, fixing it on the mast 11 in this position, as well as the subsequent lowering of the antenna and its folding to the transport position, using the standard winch included in the mast 11 and designed to expand and collapse the mast 11. In this case, the mast 11 itself is a drive that deploys and collapses the antenna, i.e. no additional drive device is required. The proposed technical solution allows for automatic deployment and folding of the disk-cone antenna on the telescopic mast, excluding the operations of antenna assembly before installation on the mast and disassembly after removing it from the mast. This makes it possible to significantly (several times) reduce the deployment and coagulation time of the entire antenna mast device, which is especially effective in conditions of time pressure. Fewer people are required to fix the compact (in the collapsed, transport position) antenna on the mast and to remove it from the mast, for the same reason it becomes safer to work with the antenna. The application of the proposed technical solution will significantly reduce time and labor costs, as well as increase safety when working with a discus antenna in a mobile version. In other words, to quickly and efficiently deploy and collapse the antenna mast device.

LITERATURE

1. Rodionov V.M. VHF transmission lines and antennas. M .: Energy. 1977, p. 173.

2. Ilnitsky L.Ya., Balbot A.A. Antenna devices of civil aviation airports. M .: Transport. 1983, p. 75.

3. RF patent No. 2207672 (prototype).

Claims (1)

The disk-cone antenna for installation on a telescopic mast, consisting of a conductive disk and a conductive cone made of tubes, contains a mounting unit consisting of two parallel parts that are not electrically connected to the cone, the upper of which is rigidly connected to the second section of the telescopic mast from the top, and the bottom is made with the possibility of its movement along the telescopic mast and has a structural connection with a cone near its base, with holes made in the upper part through which parallel to the telescopic mast are guides connected to a cone near its apex, characterized in that the disk and cone consist of movable and fixed tubes interconnected by hinges, the fixed cone tubes fixed at the apex of the cone and the fixed tube of the disc fixed near the apex of the cone, the upper rods are connected on one side to the movable tubes of the disc by means of hinges, and on the other hand to the movable tubes of the cone by means of hinges and carriages fixed to the cone tubes with by moving along them, the middle rods are connected on one side to the moving tubes of the cone by means of hinges and carriages, and on the other hand by means of hinges with a supporting vertical tube attached to the top of the cone, the lower rods are connected by means of hinges on one side to the moving tubes of the cone, and on the other hand, with the lower part of the mounting unit having holes for rigid guides with stops at their ends, hooks with return springs are designed to fix the connection of the lower part to the upper dix on the lower parts on hinges and the corresponding rollers on the upper part, as well as leverage, fixed to the ends of the lower links on the bottom of the details.

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