RU2708810C1 - Ultra-short-wave antenna - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, namely to antenna equipment, and is intended for use in ultra-short wave (VNF) radio communication channels and in equipment of marker signals fixed, for example, by aircraft. VNF antenna consists of emitter 1, pressed into radio-frequency fairing (RFF) 2 and placed above metal screen (MS) 3, which is installed on waterproof cover (VPC) 4, fixed in opening of pit 5. Pit is equipped in semi-conducting medium 6. In the plane of pit 5 there are: a mechanism for controlling the position of the radiator (MCPR), consisting of screw jacks (SJ) 8, a conical reduction gear (KRG) 9, which is fixed on the shaft of the reversible electric motor (REM) 10 of lifting/lowering emitter 1. Depending on the selected operating frequency, radiator 1 is lifted/lowered by the MCPR at a given height relative to the metal screen (MS) 3, which enables to preserve the shape of the DP and to increase the antenna efficiency.

EFFECT: broader range of frequencies at which stability of the shape of the directional pattern (DP) with a maximum oriented at the zenith is provided, and the antenna efficiency is increased.

4 cl, 4 dwg

Description

The invention relates to electrical engineering, in particular to antenna technology, and is intended for use in ultra-short-wave (VHF) communication radio lines as an independent underground transmitting and receiving antenna or as an element in VHF phased antenna arrays (PAR), which have high stability requirements to vibration and shock loads and to the stability of the shape of the radiation pattern (LH) in the operating frequency range, the claimed VHF antenna can also be used as part of the apparatus ry marker signals recorded, for example, by an aircraft (LA).

VHF underground antennas (PA) are known, for example, VHF PA used as an element of an underground PAR according to patent RU No. 2133531, publ. 07/20/1999, the Analogue consists of two orthogonal emitters placed coplanar within the semiconducting medium or on its surface. The emitters are made in the form of a quadrangle symmetrical about its longitudinal axis and with different angles α and β at the vertices. The emitters are connected using a high-frequency feeder to the output of the transmitter.

The disadvantage of the analogue is its low efficiency (coefficient of performance - efficiency) due to the significant attenuation of the radiated field in a semiconducting medium.

Also known PA according to patent RU No. 2472263, publ. 01/10/2013. PA consists of a planar orthogonal emitter located within a semiconducting medium (PPS). Emitters with the help of pieces of coaxial cable are connected to the feeder path. The emitter is located in the pit, at the bottom of which a metal screen (ME) is installed. The pit volume is filled with soil.

A disadvantage of the analogue is also low efficiency due to the absorbing action of PPP.

The closest analogue (prototype) in its technical essence to the claimed object is a VHF antenna according to US patent No. 2120241, publ. June 14, 1938

The prototype antenna is installed in a pit equipped in the thickness of the faculty, for example, in the ground. The walls and bottom of the pit are reinforced with waterproofing and metallized. Opening the pit is equipped with a waterproof and radiolucent cover. A radiator is placed in the foundation pit, connected to a high-frequency (r.h.) feeder and fastened to the radiator position control mechanism (MUPI). MUPI is made in the form of a container held at the bottom of the pit with stops. The role of ME is performed by the metallized bottom of the pit.

Thanks to MUPI, it is possible to orient the emitter radiation pattern in the desired direction.

The disadvantage of the closest analogue is the narrow range of operating frequencies, which ensures the preservation of the required shape of the beam, which is due to a change in the range of operating frequencies of the electric height of the emitter relative to the ME, i.e. a change in h / λ _p , where h is the height of the emitter above the ME, and λ _p is the working wavelength. In addition, the prototype has a relatively low efficiency due to the absorbing action of the faculty.

The technical result achieved when using the claimed VHF antenna is to expand the range of operating frequencies in which stability of the required shape of the beam is ensured, while maintaining the orientation of the maximum beam at the zenith and increasing the antenna efficiency.

The technical result is achieved by the fact that in the well-known VHF antenna immersed in a foundation pit, equipped with a PPS and equipped with a moisture-proof cover (VPNK) installed in the opening of a pit containing a radiator located above the ME and connected to a high-frequency (including) feeder, MUPI located in the pit.

ME installed at VNPK. A radio-transparent fairing (RPO) with a radiator pressed into it is installed above the ME. MUPI consists of screw jacks (VD) interacting with a bevel gear (KR). KR is mounted on the shaft of a reversible electric motor (RED) of the emitter raising / lowering. RPO through coaxial holes in the VNPK and ME is mounted on the upper ends of the stops VD. To control the height of the emitter above the ME, a block for controlling the height of the emitter is raised / lowered.

Inputs BKV connected to the height sensors (LW) of the emitter. DW fixed at the bottom of the stops VD. V.ch. the feeder connected to the input of the emitter is twisted and placed in a tube vertically fixed in the pit. RPO is made of a polymeric material and is fixed on the upper ends of the VD supports by means of rotating nut-bearings.

Thanks to the new set of essential features in the claimed VHF antenna, it is possible to stabilize the emitter over the ME over a wider range of operating frequencies of the electric height (h / λ ratio), which indicates that the orientation of the maximum of the antenna's antenna in the vertical plane (at zenith) is maintained. In addition, the emitter in the entire operating range is located above the opening of the pit, which reduces the loss in the PPP and, therefore, increases the efficiency of the antenna as a whole, i.e. ensures the achievement of the specified technical result.

The claimed antenna is illustrated by drawings, which show:

FIG. 1- general view of the VHF antenna;

FIG. 2 is a top view of an VHF antenna;

FIG. 3 - DN shape depending on the electric frequency of the emitter;

FIG. 4 is a drawing explaining the operation of the antenna in dynamics ;.

The claimed VHF antenna, shown in figure 1, consists of a radiator 1, pressed into RPO 2, made, for example, of a polymeric material. Depending on the required polarization structure of the emitted field (linear or rotating), the emitter is made in the form of a linear symmetric vibrator or two orthogonal symmetric vibrators (see Fig. 2).

In the initial (collapsed) state of the VHF antenna RPO 2 is placed directly on the ME 3, which, in turn, is installed on the VNPK 4, fixed in the opening of the pit 5. The pit 5 is equipped in a semiconducting medium 6, for example, in the ground. The walls of the pit 5 are reinforced with waterproof panels 7, eliminating the collapse of the soil of the pit 5 and the accumulation of moisture in it. In the cavity of the pit 5 is placed MUPI, consisting of VD 8 interacting with a bevel gear (CR) 9, which is mounted on the shaft of the RED 10 of the ascent / descent of the emitter (1). The power supply of the RED 10 is supplied using an electric cable 11. The RPO 2 is mounted through the coaxial holes in the VNPK 4 and the ME 3 at the upper ends of the stops 12 of the VD 8. The lower parts of each of the stops 12 are mounted in a protective pipe 13, on which N magnetic height sensors are fixed ( MDV) 14. In FIG. 1 on each protective pipe 13 shows three MDV 14 (N = 3). The outputs of each of the MDV 14 are connected to the corresponding input of the sensor control unit (BKD) 15, the output of which is connected to the input of the height control unit (BWU) 16 of the emitter 1. The emitter 1 is connected to the RF feeder 17, which is twisted and placed in a tube 18, mounted vertically on the technological partition 19 (see Fig. 1). Part of the military feeder 17 from point " a '" to point " a ''" is pressed into RPO 2 and is a non-removable part. A bevel gear 9 is fastened to the technological partition 19.

RPO 2 through coaxial holes in VNPK 4 and ME 3 is fixed on the upper ends of the stops 12 by means of rotating nut bearings 20. Screw jacks 8 are fastened to the technological partition 19, through the holes in which the corresponding stops 12 of the screw jacks 8 are passed.

BKD 15 is designed to fix the signals from the corresponding MDV 14 when reaching a given height h of the emitter 1 above the plane of ME 3 and the subsequent transmission of these signals from the output of the BKD 15 to the input of the BUV 16 of the emitter, in which they generate a control signal to turn on / off the power of the RED 10 lift / emitter descent 1. An element that sets the command to turn on / off and the direction of rotation of the RED 10 in the figures shown.

As RED 10, a reversible electric motor manufactured by the industry, for example, of the type 6OYN6-2 (see, for example, http://www.lepse.com/products/163/), can be used.

The bevel gear 9 is designed for synchronous transmission of torque from the shaft of the RED 10 to the VD 8 (there are four VD 8 in the antenna design, see Fig. 2).

As a bevel gear 9 can be used commercially available gearboxes for four outputs, for example, type DZ Transmissioni (see, for example, htttp: //www.servomh.ru/reduktory/ konicheskie).

Screw jacks 8 are designed to lift the emitter 1 to a predetermined height h above the ME 3 plane and, using the screw stops 12, to hold the emitter 1 at a selected height h. As a screw jack 8, screw jacks manufactured by the industry, for example, of the type Rhombus - 911 (see, for example, http://sevzappm.ru/domkraty/vintovye) can be used.

MDV 14 are designed to generate a signal about reaching a given height h of the emitter above the ME 3 plane and transmit this signal to the corresponding input of the BKD 15. In the quality of MDV 14, well-known inductive-wire sensors can be used (see, for example, https: // docs. cntd.ru/document/1200112850 GOST 32783-2014 "Inductively-wire sensors. Safety requirements and control methods).

The claimed device operates as follows. In the initial (inoperative) state, RPO 2 is located directly on the ME Z. For a given range of working frequencies (F _min -F _max ), or the corresponding range of working wavelengths (λ _min- λ _max ), the general range is previously divided into several subbands (for example, into 3 subranges), within each of which the condition 0.2 <h / λ <0.3 is fulfilled. Fulfillment of this condition ensures that the required orientation of the maximum of the radiation pattern in the zenith direction is practically maintained. Otherwise, a dip in the anti-aircraft direction is formed in the beam (see Fig. 3).

As an example, we consider the case when the full range of operating frequencies corresponds to (F _min -F _max ) = (100-220) MHz, which corresponds to the range of working wavelengths: (λ _min -λ _max ) = (3-1,4) m

Next, the specified total range is divided into 3 subbands: I subband: (100-140) MHz; (3-2.1) m; λ ' _avg = 2.55 m; 0.25 λ ' _sr = 0.63 m.

II subband: (140-180) MHz; (2.1-1.7) m; λ '' _cf = 1.9 m; 0.25 λ '' _sr = 0.475 m.

III subband: (180-220) MHz; (1.7-1.36) m; λ ''' _sr = 1.53 m; 0.25 λ ''' _sr = 0.38 m.

Therefore, when operating in the I subband, the elevation height h 'of the emitter (1) above the ME (3) should be h' = 0.25 λ ' _sr = 0.63 m; in the second subband, h ″ = 0.25 λ ″ = 0.475 m; in the third subband, h '''= 0.25 λ''' = 0.38 m.

When these conditions are met, the electric height of the emitter above the screen h / λ will vary within:

in the first subband h ₁ / λ ₁ = (0.22-0.28), see figa;

in the second subband h ₂ / λ ₂ = (0.23-0.28), see figb;

in the third subband h ₃ / λ ₃ = (0.21-0.3), see figv.

Such a change in the ratio h / λ in each of the subbands does not change the level of the emitted electromagnetic field in the zenith direction (see Fig. 4), and therefore preserves the energy potential in the radio line, in the entire operating frequency range.

In addition, the emitter is always in the air, which practically eliminates additional heat loss in the faculty 6 surrounding the foundation pit 5.

Thus, thanks to a new set of essential features in the claimed device during its operation, it is possible to maintain the desired shape of the beam with a maximum oriented in the zenith direction and increase the antenna efficiency due to a decrease in heat loss in the PPP, i.e. The specified technical result is achieved.

Claims (4)

1. An ultrashort-wave (VHF) antenna immersed in a pit (5), equipped in a semiconducting medium (PPS) (6) and equipped with a waterproof cover (VNPK) (4) installed in the opening of the pit (5), containing a radiator (1), located above a metal screen (ME) (3) and connected to a high-frequency feeder (17), the emitter position control mechanism (MUPI) located in a pit (5), characterized in that a ME is placed on a moisture-proof cover (4) of a pit (5) (3) over which a radiotransparent fairing (RPO) is installed (2) with pressed the emitter (1) in it, the MPI consists of screw jacks (VD) (8) interacting with a bevel gear (9), mounted on the shaft of a reversible electric motor (RED) (10) raising / lowering the emitter (1), a radio-transparent fairing ( 2) through coaxial holes in the moisture-proof cover (4) and the metal screen (3) is fixed on the upper ends of the stops (12) of the screw jacks (8), and an additional unit (15) for controlling the height of the emitter lifting / lowering (1) (1) the inputs of which are connected to height sensors (14) installed in the bottom of the screw marketing jacks. 2. VHF antenna according to claim 1, characterized in that the high-frequency feeder (17) is twisted and placed in a tube (18) mounted vertically in a pit (5). 3. The VHF antenna according to claim 1, characterized in that the radiolucent radome (2) is made of a polymer material. 4. VHF antenna according to claim 1, characterized in that the radio-transparent fairing (2) is mounted on the upper ends of the stops (12) of the screw jacks (8) by means of rotating nut bearings (20).

Images