RU98636U1 - WIDTH VERTICAL RADIATOR - Google Patents

Abstract

 A broadband vertical emitter containing an antenna base on which an antenna mast is supported, made detachable and consisting of M legs, the antenna base is the first antenna feed point, and the second antenna feed point is the electrically connected ends K of counterweights radially placed on the ground surface, the second ends of which located in a circle with a radius equal to the height of the antenna, N working antenna sheets placed along the generatrix lines of two different-height straight lines conjugated by their bases onuses, the upper ends of the N antenna work blades are mechanically connected to the top of the antenna mast, the inflection points of the N antenna work blades are geometrically placed on a circle formed by the connection of the bases of two different-height straight cones, the antenna mast is held up by guy wires, characterized in that the antenna mast is made metal and composite, each knee of the antenna mast is made in the form of a metal pipe and a tip with a groove providing mechanical connection of the knees of the mast between in itself, the knee pipe is mechanically divided in half and the mast knee pipe halves are mechanically connected by a dielectric rod providing electrical isolation of one mast knee from the other, an emitter consisting of N working antenna sheets, the lower ends of which are equipped with contact tips, and the upper glass, mechanically and electrically connecting the upper ends of the antenna working blades and acting as the upper collective ring, the upper glass is mechanically connected to the top of the mast through an insulating rod

Description

The utility model relates to radio engineering, namely to antenna technology and is intended for. use mainly in mobile (highly mobile) transceiver radio nodes of the decameter (DKMV) wavelength range.

Known antennas for mobile transceiver radio nodes, providing a sufficiently high technological (fast deployment / collapse of the antenna) and strength (wind resistance, the number of deployment / collapse cycles before decommissioning, etc.) characteristics: "pin 10 m" ([1], p. 79), “Z-shaped” ([1], p. 86, 87), “inclined beam” ([1], p. 85).

However, these antennas in terms of electrical parameters are characterized by:

- a very narrow frequency range Δf, in which the antenna keeps its parameters constant; Δf = (0.005 ÷ 0.01) f _p , where f _p is the operating frequency;

- low value of the gain (K _y ) in the range of operating frequencies (along the ground, including), K _y = (0.03 ÷ 0.05) [1];

- a significant range of changes in the active and reactive components of the input resistance (for the antenna "pin 10 m" R _a = (2.0-1000) Ohm, X _a = (minus 2000 ÷ plus 200) Ohm; for "Z-shaped" antennas R _a = (10-90) Ohm, X _a = (minus 1200 ÷ minus 50) Ohm; for the antenna "Tilted beam" R _a = (30-3000) Ohm, X _a = (plus 1400 ÷ minus 2400) Ohm), which leads to the need to use expensive and complex antenna matching devices in which a sufficiently accurate measurement of the characteristics and matching of the antenna is ensured with a significant increase in tuning time [2].

The closest in technical essence to the proposed utility model is a broadband vertical radiator - ShVI (patent No. 2289180, [3]), containing a detachable telescopic mast, consisting of M elbows, each of which is made of a dielectric pipe and equipped with a locking lock, the mast is mechanically connected with a support base of the antenna, to which a system of radial counterweights of K> N conductors arranged uniformly in a circle with a radius equal to the height of the antenna, the upper and lower collective and the lower collective ring is the first antenna feed point, and the second antenna feed point is the electrically connected ends of the counterweights, N working blades (emitters) placed along the generatrix lines of two different-height straight cones conjugated by their bases, the upper and lower ends of the N working blades mechanically connected to the top and the support base of the mast, and the inflection points of N emitters (work blades) are geometrically placed on the circumference of the bases of two different-height straight cones , the mast in an upright position is held by guy rods working blades (emitters) are made of segments of a coaxial cable with high-frequency coaxial connectors at the ends, while each connector on the upper end of the blades (emitter) has an inner conductor and a shield electrically connected to the upper collective ring, on which the instrument parts of the coaxial connectors are installed, at the lower end of the working web (emitter) the screen is electrically connected to the main lower collective ring, on which also the instrument parts of the coaxial connectors have been updated, the internal conductors of the instrument parts of the coaxial connectors are connected to an additional lower collective ring, an inductor is connected between the additional lower collective ring and the antenna support base, all guy wires are made of a high-strength low-extensible polymer cord, the required geometric shape of the antenna is ensured by dielectric struts, the number of which is equal to the number of working paintings (emitters) N.

Significant disadvantages of the known device are:

- a limited range of operating frequencies Δf _r , in which the antenna keeps its electrical parameters (R _BX , SWR) constant, due to the resonant properties of the working paintings (emitters) made of a coaxial cable of a certain length, and the inclusion of an extension inductor in the antenna power circuit [4 , 5];

- low reliability of the antenna as a whole under the combined effects of wind loads and extreme temperatures, due to the low mechanical strength of the joints of the working cloths from the coaxial cable with high-frequency coaxial connectors at the ends of the working cloths of the antenna;

- low reliability of spatial antenna shaping elements (dielectric spacers; coaxial cable webs) providing the geometric shape of the antenna when exposed to wind loads and extreme temperatures.

In addition, the deployment of a fully equipped and equipped antenna (provided that the base of the antenna and the first pipe of the telescopic mast are installed on the ground and secured by guy wires) by manually extending, then fixing the mast knees with locks, starting from the highest mast knee and the telescopic mast knees following it , requires significant physical effort of specialists performing this operation, while at the same time it is necessary to keep the antenna mast in a vertical position when it is deployed. An attempt to develop the design of the antenna that provides the lifting of a fully equipped and equipped antenna using the "falling arrow" method has led to the need for a sharp increase in the strength of plastic mast pipes, dielectric struts, and, accordingly, an increase in the cost and weight of the antenna.

The tasks that are solved by the proposed utility model are:

- reduction due to the mechanization of time and the complexity of the processes of deployment / coagulation of a broadband vertical emitter;

- improving the reliability of the operation of the pin vertical emitter by increasing the mechanical strength of the structural elements of the emitter while maintaining the values of its electrical parameters in the range of operating frequencies.

The solution to these problems is achieved by the fact that in a broadband vertical emitter containing an antenna base, on which an antenna mast is supported, made detachable and consisting of M elbows, the antenna base is the first antenna feed point, and the second antenna feed point is the electrically connected ends K of radially placed on the ground surface of counterweights, the second ends of which are arranged in a circle with a radius equal to the height of the antenna, N working antenna sheets placed along the generatrix lines of two expressed by their bases of different height straight cones (K> N), the upper ends N of the antenna working blades are mechanically connected to the top of the antenna mast, and the inflection points N of the antenna working blades are geometrically placed on a circle formed by the connection of the bases of two different height straight cones, the antenna mast in a vertical position held by guy wires, an emitter is introduced, consisting of N working antenna sheets, the lower ends of which are equipped with contact tips, and the upper glass, mechanically and electrically connected which heats the upper ends of the antenna working sheets and acts as the upper collective ring, the upper emitter cup is mechanically connected to the top of the mast through an insulating rod, the antenna mast is made of metal and composite, each knee of the antenna mast is made in the form of a metal pipe and a tip with a groove providing mechanical connection of the knees masts among themselves, each pipe of the knee of the mast is mechanically divided in half and half of the pipe of the knee of the mast is mechanically combined by a dielectric rod, sintering the electrical insulation of one mast knee from another, the additional base is placed on the ground surface and mechanically connected to the lower base of the insulator, the upper base of which is mechanically connected to the metal base of the antenna, acting as the lower collective ring, mechanically and electrically combining N working blades with the contact tips antennas, the mast lift contains a lift rack, consisting of three additional knees, each of which, as well as a track on the masts, consist of a metal pipe and a tip, the first (lower) additional knee of the elevator post with its lower part is mechanically connected by means of a hinge to the base of the antenna, and with the help of a clamp, a traction winch is attached to it with a traction winch cable passing through a pulley fixed in the upper part of the first additional knee of the lift rack, the elevator cup is attached to the second end of the cable of the elevator winch cable, and below the pulley on the first additional knee of the elevator rack is fixed the elevator mechanism, the second additional elbow of the elevator strut, as well as the first additional elbow of the elevator strut, contain steps attached to their metal pipes, and the clamp and sleeve spaced apart in height are mechanically attached to the third additional elbow of the elevator strut, through which as well as through the fixing elevator mechanism, antenna mast passes, guy wires are made of steel cable, sectioned with nut insulators, guy wires are connected to antenna mast using split fl Antsa, which enters the groove of the tip of the mast knee, and a double hook with an earring, inflection points N of the antenna work sheets are mechanically coupled in pairs by insulating screeds, and also connected to additional guy wires, which, like insulating screeds, are made of a non-conductive (polymer) cord , insulating ties and additional guy wires are elements of the spatial shaping of the antenna.

Figure 1 shows a schematic illustration of an antenna, figure 2 shows an antenna emitter, figure 3 shows an embodiment of the mast knee, figure 4 shows a top view of an antenna for an embodiment: N = 8; K = 30, figure 5 shows the base of the antenna.

The broadband vertical emitter contains the base of the antenna 1, on which the mast of the antenna 2 is supported, made detachable and consisting of M knees 3 (3 ₁ ... 3 _M ), K counterweights 4 (4 ₁ ... 4 _K ) radially placed on the ground surface, the second ends of which are arranged in a circle with a radius equal to the height of the antenna, N working antenna sheets 5 (5 ₁ ... 5 _N ), while K> N, the antenna mast is held upright by guy wires 6 made of a steel cable sectioned with nut insulators, antenna mast 2 is made metal and As a result, each knee of the mast of the antenna is made in the form of a metal pipe 7 and a tip 8 with a groove, half of the pipe 7 of the mast of the mast is mechanically connected by a dielectric rod 9, which provides electrical isolation of one knee of the mast from the other, the emitter 10, consisting of N working canvases of the antenna 5 (5 ₁ ... 5 _N ), the lower ends of which are equipped with contact tips 11, and the upper glass 12, the upper glass 12 is mechanically connected to the top of the mast through the base 14 is placed on the ground surface and mechanically connected to the lower base the insulator 15, the upper base of which is mechanically connected to the metal base of the antenna 1, acting as the lower collective ring, the mast lift 16 contains a lift rack, consisting of three additional elbows 17, 18 and 19, the first (lower) additional elbow of the lift rack 17 of its lower part is mechanically connected by means of a hinge to the base of the antenna 1, and with the help of a clamp, a traction winch 20 is attached to it with a cable of the traction winch 21 passing through a pulley 22 fixed in the upper part of the first additional itelnogo knee of the lift rack 17, to the second end of the cable 21 of the traction winch of the lift 20 is attached a cup of the lift 23, the locking mechanism of the lift 24, the second additional knee of the lift rack 18, as well as the first additional knee of the lift rack 17, contain steps 25 attached to their metal pipes and to the third additional knee of the strut of the elevator 19 are mechanically attached a height-distributed collar 26 and a sleeve 27, guy wires 6 are connected to the mast of the antenna 2 using a split flange 28, which is included Knee nozzle bore 8 of the mast 3, and a double hook with a lug 29, the inflection point N workers webs antenna 5 are mechanically combined in pairs insulating tie rods 30 and are also connected with additional braces 31 which as well as to the backstay attached to the ground with stakes.

Sectioning of the antenna mast 2 by dielectric rods 9, as well as the use of an insulating rod 13 in the emitter 10, is due to the need to eliminate powerful broadband contact noise arising in the elements of composite metal masts that are in the electromagnetic field when exposed to wind loads ([6], pp. 64-69 )

The antenna is installed by a calculation of five people as follows.

After marking the installation site of the antenna and driving the stakes into the ground, the mast elevator 16 is connected with the hinge to the base of the antenna 1, as well as to the additional base 14 and insulator 15. The mast elevator 16 is fixed in a vertical position using guy ropes 6, the upper mast elbows through the fixing mechanism the lift 24, the clamp 26 and the sleeve 27 are fed up and hold the upper knees of the mast in this position using the locking mechanism of the lift 24. One person from the calculation, climbing the stairs 25, sets on the top stake not the mast of the antenna 2, the insulating rod 13 and the emitter 10 are assembled, another person from the calculation, located below, using the traction winch 20, successively substituting the knee of the mast 3 and bringing the cup of the elevator 23 under the bottom of the substitution knees, raises the mast 2 with the help of the traction winch 20 until over the sleeve 27 there is a place for fastening the guy wires 6 of the upper tier, which are fixed on the mast of the antenna 2 using a split flange 28, which enters the groove of the tip 8 of the knee of the mast 3, while the flange 28 is fixed in the groove of the with a hook hook with an earring 29, to which a guy cable is attached 6. The mast 2 is kept from falling down by the locking mechanism of the lift 24 while lifting. Three people from the calculation, having sorted the guy wires 6, diverge to the places of their fastening to the stakes hammered into the ground. In the same way, fasteners 6 of the lower tier of fastening, ties 30 and additional guy wires 31 are fixed. After assembling the mast 2, the antenna in the vertical position is fixed using the adjusting lag braces 6. The lower ends of the working blades 5 of the emitter 10 are electrically connected to the metal base using the contact tips 11 antenna 1, which is the first power point of the antenna and acts as the lower collective ring, to which the central core of the coaxial power cable is connected. By adjusting the tension of the additional guy wires 31, the required shape of the working webs 5. antenna is provided. Counterweights 4 are placed evenly on the ground surface around the additional base of the antenna 14 and are electrically connected to it, forming a second antenna feed point, to which the braid of the coaxial power cable is connected. Counterweights 4 and working cloths 5 of the antenna can be made of PV4 (4.0) wire, which is characterized by resistance to radiation (solar - including) and high strength characteristics when exposed to temperature and wind loads.

Comparative tests of prototypes of a broadband vertical radiator - ShVI [2] with known antennas of the VGDSh type ([1], p.15, 16) and “Shtyr” ([1], p.79) showed that:

- for the range of operating frequencies (2-30) MHz with 57 tuning control points (frequency step - 0.5 MHz), the relative number of frequencies at which the tuning of the antenna matching device from the radio transmitting device occurred in one time interval equal to 50 ms, makes up 58% for the proposed Shvi antenna, 2% for the VHS, and 12% for the Shtyr antenna, i.e. the ShVI antenna provides a shorter (5 ... 26) times in comparison with the known antennas of the VGDSh and “Shtyr” type for tuning in general to the operating frequencies of the RPDU as a whole;

- in terms of the value of the traveling wave coefficient, the ShVI antenna is inferior to the known antennas of the VGDSH and Shtyr type only at two points in the operating frequency range at frequencies of 6 and 7 MHz, exceeding their values by 1.5-2 times in the remaining 55 control points of the operating range frequencies (2-30) MHz;

- in the range of operating frequencies (2-30) MHz, the variations of the active component of the input impedance of the antenna are within R _a = (14 ... 160) Ohms, and the variations of the reactive component of the proposed antenna are X _a = (minus 71.7 Ohms ... plus 50 Ohms ), which is significantly less than the variations of these parameters for known antennas [1].

The Shvi antenna passed state tests as part of a transceiver radio center and was mastered in serial production.

Information sources:

1. Zakharov V.P., Levchuk P.F., Muravyov Yu.K. and other characteristics of antennas for radio communications. / Ed. Yu.K. Muravyev. - L .: Ed. VKAS. - 1968 .-- 130 s.

2. Luzan Yu.S., Marenko V.F., Bogdanov A.V. etc. Alignment of decameter transmitting antennas. / Collection of reports of the technological congress "Modern technologies in the creation of military and civilian products." - Omsk: Publ. OmSTU. - 2001. - S.280-283.

3. Patent No. 2289180, Russia. MKI H01Q 9/34 Broadband vertical radiator / - Bull. Number 34. - Publ. December 10, 2006

4. Nikolaev V.A., Bakurova O.A. Self-supporting vertical vibrator for a receiving surface wave antenna // Antennas. - 2007 .-- Issue 6 (121). - S. 37-41.

5. Rothammel K., Krishke A. Antennas / Volume 1. Transl. with him. - Мn .: Publishing house OMO “Our city”. - 2001 .-- 416 p.

6. Vinogradov E.M., Vinokurov V.I., Kharchenko I.P. Electromagnetic compatibility of electronic equipment. - L .: “Shipbuilding”. - 1986 .-- 264 p.

Claims (1)

A broadband vertical emitter containing an antenna base, on which an antenna mast is supported, made detachable and consisting of M legs, the antenna base is the first antenna feed point, and the second antenna feed point is the electrically connected ends K of counterweights radially arranged on the ground surface, the second ends of which arranged in a circle with a radius equal to the height of the antenna, N working antenna sheets placed along the generatrix lines of two different-height straight lines conjugated by their bases onuses, the upper ends of the N antenna work blades are mechanically connected to the top of the antenna mast, the inflection points of the N antenna work blades are geometrically placed on a circle formed by the connection of the bases of two different-height straight cones, the antenna mast is held up by guy wires, characterized in that the antenna mast is made metal and composite, each knee of the antenna mast is made in the form of a metal pipe and a tip with a groove, providing mechanical connection of the knees of the mast between in itself, the knee pipe is mechanically divided in half and the mast knee pipe halves are mechanically connected by a dielectric rod providing electrical isolation of one mast knee from the other, an emitter consisting of N working antenna sheets, the lower ends of which are equipped with contact tips, and the upper glass, mechanically and electrically connecting the upper ends of the antenna working blades and acting as the upper collective ring, the upper glass is mechanically connected to the top of the mast through an insulating rod n, an additional base is placed on the ground surface and mechanically connected to the lower base of the insulator, the upper base of which is mechanically connected to the metal base of the antenna, which acts as the lower collective ring, mechanically and electrically combining the antenna work pieces using the contact tips N, the mast elevator contains a mast stand consisting of three additional elbows, each of which, as well as the mast elbows, consists of a metal pipe and a tip, the first (n below) the additional knee of the lift stand is mechanically connected by its lower part with the hinge to the base of the antenna, and with the help of a clamp, a pull winch is attached to it with a cable of the pull winch passing through a pulley fixed in the upper part of the first additional knee of the lift stand to the second end of the cable a hoist cup is attached to the hoist cup, and below the pulley on the first additional knee of the hoist rack the locking mechanism of the hoist is fixed, the second additional knee of the hoist rack the mannika, as well as the first additional knee of the elevator strut, contain steps attached to their metal pipes, and the third additional knee of the elevator strut mechanically fastens a clamp and sleeve spaced apart in height, through which the antenna mast passes as well as through the locking mechanism of the elevator, the guy wires are made of steel cable, sectioned with nut insulators, guy wires are connected to the antenna mast using a split flange that enters the groove of the mast knee tip, and a double hook th pierced, the inflection point N workers webs antenna pairs are mechanically united by insulating couplers, and are also connected with additional braces, also as insulating screed made of non-conductive (polymer) cord.