RU195909U1 - ROTARY ANTENNA ORIENTATION - Google Patents

Abstract

The utility model relates to the field of communication and can be used to set and adjust the position of satellite dishes. The device contains a support in the form of a first tripod, on which a second tripod is mounted with upward rotation with respect to the vertical geometric axis, each of which has an antenna mounting element . One of the racks of the second tripod is sliding, and the other two have a constant length, while the device is equipped with two sliding rods, one end of each of which is pivotally connected to the upper part of one of the racks of constant length, and the other end is pivotally connected to the lower part of the leg of the first a tripod located between the racks with which the rods are connected. The technical result of the claimed utility model is to increase the rigidity of antenna fixation with high windage in azimuth and elevation to maintain its working individuality in gusty winds. 2 ill.

Description

The utility model relates to the field of communication and can be used to set and adjust the position of satellite antennas in azimuth and elevation in almost all areas where wearable satellite antenna devices are used.

Known rotary support device for orienting the antenna, containing made in the form of a frame device for mounting the reflector, the frame is connected to a rack located in the mast, mounted on a support. The frame is connected to the rack with the possibility of rotation about the horizontal axis by means of a rotation mechanism, which is made in the form of a spindle with a handle connected to the frame by the end and screwed into the threaded hole of the axis mounted on the rack, and the rack is mounted on the mast with the possibility of rotation relative to the vertical axis and fixing in a predetermined position by means of a rotation and fixing mechanism made in the form of tightening rods (see RF patent No. 2461926, CL H01Q 3/08, 2012).

As a result of the analysis of the well-known slewing device, it should be noted that the presence of a mast having a considerable length significantly reduces the rigidity of the structure, which does not allow maintaining the given position of the antenna during its operation, especially in adverse weather conditions.

Known rotary support device for orienting the antenna, containing the support, a device for mounting the antenna placed on the support, as well as mechanisms for adjusting the position of the antenna in azimuth and elevation. The support is made in the form of a base element - a sleeve and telescopic support racks connected at one end to the base element with the possibility of their information-breeding and fixing in a given angular position, the antenna mounting device is made in the form of a mounting element - an axis and three racks connected to the installation element at one end with the possibility of their information and breeding and fixing in a given angular position, and the installation element is designed to be placed with the possibility of rotation on the base element of the support, ant the antenna can be mounted rotatably on the first and second antenna racks, the antenna position adjustment mechanism in elevation is located on the third antenna rack and has the ability to connect to the antenna, and the antenna azimuth adjustment mechanism is mounted on one of the support racks and connected to one from antenna racks (see RF patent for utility model No. 161587, IPC H01Q 3/08, 2016) is the closest analogue.

As a result of the analysis of the known device, it should be noted that the sliding rod for fixing the elevation angle and the antenna rack connected to it are not loaded with the weight of the antenna, as a result of the backlash in the axes and bushings of their connections do not allow you to rigidly fix the elevation angle of the antenna with high windage when wind gusts.

In addition, the antenna and support posts, to which the sliding azimuth fixing rail is connected, can bend when wind gusts affect the mirror with high windage, which can lead to twisting of the design of the support-rotary device.

The antenna stand, to which the sliding azimuth fixing rail is connected, does not have rigid connections with the mirror attachment points from below, which can also lead to torsion of the structure under the influence of wind gusts on the mirror with high windage.

Thus, the known device does not allow for sufficient rigidity of the antenna fixation in azimuth and elevation with gusts of wind.

The technical result of the claimed utility model is to increase the rigidity of antenna fixation with high windage in azimuth and elevation to maintain its operability in a gusty wind.

The specified technical result is ensured by the fact that in the support-rotary device for orienting the antenna, containing the support in the form of a first tripod, on which the second tripod is installed with upward rotation with respect to the vertical geometric axis, each of which has an antenna mounting element, is new the fact that one of the racks of the second tripod is made sliding, and the other two have a constant length, while the device is equipped with two sliding rods, one end of each of which is a ball nirno connected to the upper part of one of the racks of constant length, and the other end is pivotally connected to the lower part of the legs of the first tripod, located between the racks to which the rods are connected.

The essence of the claimed utility model is illustrated by graphic materials on which:

in FIG. 1 - rotary support device for orienting the antenna in the deployed position, side view;

in FIG. 2 - rotary support device for orienting the antenna in the deployed position, top view.

The rotary support device consists of a support tripod and a device placed on it for mounting the antenna and adjusting its position in azimuth and elevation in the form of a second tripod facing upwards.

The supporting tripod (first tripod) consists of three legs 1, 2 and 3, each of which is pivotally connected to the crosspiece 4 with one end with the possibility of rotation and fixing in a predetermined angular position. Legs 1, 2 and 3 are advisable to perform sliding, that is, adjustable in length, as is the case in the solution - the closest analogue. On the free (lower) ends of the legs 1, 2, 3, support pads can be pivotally mounted, which are shown in the figures, but are not indicated by positions.

A vertical axis 5 is pivotally inserted into the hole of the crosspiece 4 of the support tripod, a housing 6 is fixed at its upper end, which rests with its lower surface on the upper surface of the crosspiece 4. A sleeve 7 is fixed on the axis 5 under the crosspiece 4. sleeve 8, at the lower end of the sleeve there is a clamping element 9, which is two clamps rigidly fastened in parallel. The clamping element 9 on the sleeve 8 is fixed with its upper clamp, and the lower clamp is fixed on the axis 5 with the possibility of release when folding the device. The upper clamp is pulled together with a regular screw, and the lower screw with a handle. On the sleeve 8, above the clamping element 9, a sleeve 10 is pivotally mounted, which, with its lower surface, rests on the upper surface of the clamping element 9. With the sleeve 10, the ends are rotatably coupled 12, 13 and 14, the other ends of which are rotatably connected with legs 1, 2 and 3 of the supporting tripod. A crosspiece 11 is fixed above the sleeve 10 on the sleeve 8, with which the lower ends of the antenna racks 15, 16 and 17 of the second tripod are connected rotatably, the upper ends of which are equipped with antenna fasteners 18, 19 and 20, made in the form of screw connections with washers and nuts lamb.

Antenna posts 16 and 17 have a constant length, and the antenna stand 15 is sliding, for example, in the form of two tubes, one of which is inserted into the other, with the possibility of axial movement. The clamping element 21 is rigidly fixed to the thicker tube with its upper clamp, which is tightened, for example, with a screw and nut. The lower clamp of the clamping element 21 fixes the thinner tube in a predetermined position that determines the length of the antenna rack 15. The lower clamp of the clamping element is pulled together by a tensioned cable (not indicated by the position) and its compressed braid 22. The tension of the cable and compression of the braid 22 is provided by the spring that extends the clamp handles 23 in the first handle of which the braid of the cable rests, and the second handle pulls the cable fixed on it.

The ends of the couplers 24 and 25 are rotatably connected to the housing with 6 axes. Their other ends are rotatably connected by the axes with the antenna posts 16 and 17. There is an opening in the upper tube of the antenna rack 15 from the axis side. A cable is inserted into it and from the inside of the tube, the tip fixed on the end of the cable abuts against the wall. The other end of the cable runs into the opening of the housing 6. From the side of the strut 15, inside the housing, a clip is installed on the cable in the form of a bolt with a diametrical hole in the threaded part, nuts and washers.

The rotary support device is equipped with two sliding rods 26 and 27, each of which can be made of two tubes (one inserted into the other), with the possibility of axial movement and relative rotation. The rods 26 and 27 are equipped with clamping elements 28 and 29. Each of them can be made in the form of two rigidly connected clamps. The lower clamp is mounted on a thicker tube, and the upper on a thinner one. The screw of the clamp tightening the thinner tube is equipped with a handle. He fixes a thinner tube in a predetermined position that determines the length of the rod. Clamps with eccentrics or collets similar to those used in tripods can be used to tighten the clamps.

At one end, each of the rods 26 and 27 is rotatably connected by an axis to a U-shaped bracket 30 or 31, which is rotatably connected by an axis to the antenna rack 16 or 17 in its upper part. At the other end, each of the rods, with an axis, rotatably connected to a bracket 32 or 33, which, with an axis, rotatably connected to the lower part of the leg 3 located between the antenna posts 16 and 17. At the upper end of the leg 3 from the inside The support tripod has a loop (not shown) from the cable to press the device to the ground surface using a load or soil anchor.

The antenna 34 with the upper hinges of the hinges 35, 36 and 37 fixed on it, having vertical slots on the lower cusps, can be mounted on a support and fixed on it by putting the lower cusps of the hinges through the slots on the screws under their heads and pressing the lower cusps of the hinges 35, 36 and 37 screw heads 18, 19 and 20.

The rotary support device for orienting the antenna operates as follows.

A device deployed in working position, with an antenna mounted on it, is turned in azimuth in the direction of the satellite with an accuracy of + -40 degrees. Draw with a lanyard or screed to the soil anchor for the loop of the cable at the upper end of the leg 3.

To point the antenna at the satellite, the clamp handles 23 are squeezed along the elevation angle, this weakens the cable and its braid 22, as well as the clamp 21. It releases the inner tube of the antenna post 15 and allows you to change its length. Hand over the upper edge of the mirror turn the antenna 34 relative to the horizontal axes of the loops 36 and 37 mounted on it at a predetermined satellite elevation angle, guided, for example, by the level of the inclinometer. The telescopic parts of the antenna rack 15 while freely moving relative to each other. The handles of the fixation device are released, fixing the inner tube and antenna rack 15 along its length. The antenna is pointing at the corner of the place.

To direct the antenna to the satellite, the screws with the grips of the clamping elements 28 and 29 of the extension rods 26 and 27 are released. The antenna is rotated in azimuth around the geometric axis passing through the physical axis 5 in the range of about + - 50 degrees. After detecting the satellite signal and adjusting to the maximum of its power, the antenna is fixed in azimuth by tightening the screws with handles on the clamping elements 28 and 29. Usually, after that, the antenna is again adjusted according to the elevation angle, to the maximum power of the satellite signal. Thus, after several iterations, the antenna is pointed.

Folding the slewing device to the position for transportation and storage is as follows.

The wing on the three screws of the antenna mounts 18, 19 and 20 is loosened. Then, the lower hinges 35, 36 and 37 are removed from the loosened screws through the slots along with the antenna by moving it upward.

Loosen the screws with the handles on the clamping elements 9, 28 and 29.

Turn the device for mounting the antenna relative to the reference tripod so that the angles between the legs 1, 2 and 3 and the antenna posts 15, 16 and 17 are approximately 60 degrees. The stand 15 is pressed by hand against the axis 5.

The sleeve 7 is pulled up and the clamping element 9 down. As a result, they are moved apart, and legs 1, 2 and 3 with ties 12, 13 and 14, antenna stands 16 and 17 with ties 24 and 25, rods 26 and 27 are reduced to axis 5. The device folds almost like an umbrella. Take one of the grips of the clamp 23 together with the cable and its braid 22 from the antenna rack 17, wrap the cable with a braid and a clamp. The rolled-up device is inserted into the bag. The device is ready for transport.

Deployment and translation into working condition is carried out in the reverse order.

The claimed device provides a rigid fixation of the antenna with a large windage in elevation due to:

1. A uniform distribution of the weight of the antenna between the racks, which presses the axis of the device to the edges of the bushings and thereby reduces the backlash in them, as well as presses the heels to the surface of the earth and closes the rigidity triangles of the support tripod through its surface.

2. Triangles of rigidity, including a fixed along the length of the sliding antenna rack 15, resting through the crosspiece 11, the sleeve 8 and the sleeve 10, ties 12, 13 and 14 on the legs of the support tripod 1, 2 and 3, standing firmly on the ground.

3. The design of a device that uses the rigidity of the structure of the antenna mounted on it.

The claimed device provides a rigid fixation of the antenna with high windage in azimuth due to:

1. Triangles of rigidity, including sliding rods 26 and 27, rigidly connecting the mirror of the antenna with the lower ends of the legs of the support tripod firmly standing on the ground.

2. Antenna posts 15, 16 and 17 of the device, supported through the crosspiece 11, the sleeve 8 and the sleeve 10 on the legs 1, 2 and 3 of the support tripod.

3. The design of the device, which use the rigidity of the installed antenna.

4. A uniform distribution of the weight of the antenna between the racks, which presses the axis of the device to the edges of the bushings and thereby reduces the backlash in them, as well as presses the heels to the ground and closes the rigidity triangles of the support tripod through its surface.

The rigidity of the structure allows the use of its non-rigid elements, which can significantly reduce its weight and dimensions when folded and thereby make it convenient to use.

The design allows you to quickly turn it from its working position to stowed (almost like an umbrella) and turn it back, and also allows you to quickly install an antenna on the device and remove it.

The design of the device provides smoothness and ease of rotation when adjusting the antenna in azimuth and elevation due to the fact that the center of gravity of the antenna is above the axis, and the weight of the transceiver on the antenna rod can be compensated by a gas spring mounted in a sliding antenna rack.

Claims (1)

A rotary support device for orienting the antenna, comprising a support in the form of a first tripod, on which a second tripod is mounted with upward rotation with respect to the vertical geometric axis, each of the posts of which is equipped with an antenna mounting member, characterized in that one of the posts of the second tripod is made sliding, and the other two have a constant length, while the device is equipped with two sliding rods, one end of each of which is pivotally connected to the upper part of one of the racks of constant d lines, and their other end is pivotally connected to the lower part of the leg of the first tripod, located between the racks to which the rods are connected.

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