RU2674516C1 - Antenna - Google Patents

Abstract

FIELD: antenna equipment.SUBSTANCE: invention relates to the ultra-wideband antennas with vertical polarization and circular radiation pattern in the horizontal plane, and can be used in information transmission / receiving systems. Antenna contains a base including a cup, a shock absorber, the first dielectric bushing with the Edison thread on the outer surface, connector, matching transformer, and two pieces of cable. Lower sub-band emitter includes the second dielectric bushing with the Edison thread. Connector counterpart is located inside the second dielectric bushing with possibility of the counterpart connection to the connector receiving part. At the end faces the second dielectric bushing is provided with connected by the conductive strip contact rings. Between two metal tubes the hollow and dielectric insert is located. Cable third section is located inside the second dielectric bushing, the first metal tube, the insert and the second metal tube. Upper sub-band emitter includes the third dielectric bushing, the third metal tube, the spiral coil, the conductive cable and mounted on the third cable section outer surface inside the third dielectric bushing ferrite rings.EFFECT: invention allows to reduce the SWR, simplify the design, reduce the antenna longitudinal dimensions and improve the usability.5 cl, 6 dwg

Description

The invention relates to the field of antenna devices, in particular, to ultra-wideband antennas with vertical polarization and a circular radiation pattern in the horizontal plane, and can be used in transceiver information transmission systems. The antenna allows for the reception and transmission of signals of physical channels in the frequency range from 30 to 520 MHz with pseudo-random tuning of the operating frequency (MHF), and can be used as a transmitting and / or receiving antenna with transportable and base radio stations.

From US patent application US2010302116 (published 02.12.2010; IPC H01Q9 / 16, H01Q21 / 12, H01Q21 / 00), an antenna operating in the frequency range 30-512 MHz, having a base with a shock absorber, a radiator of the lower subband (MV range) and emitter of the upper subband (range DMV1). The antenna is made of a set of metal tubes and a conductive cable. The dipole of the upper subrange consists of two pipes interconnected by an insulating disk, inside of which there is a capacitive element - a conductor covered with insulating material. The dipole of the lower subrange is formed by a set of metal tubes of a smaller diameter and a conductive cable. To separate the lower and upper subranges, the device is equipped with a filter. The limitations of this device are the need to use a filter, insufficient broadband in the high frequency region and large longitudinal dimensions.

Closest to the claimed invention is an antenna company Trival Antene AD-27 / V150-3512-DF, operating in the frequency range 30–88 MHz and 225–512 MHz (published on the website http://www.trivalantene.si/sites/default/ files / brochures / AD-27-V150-3512-DF% 20Rev-A% 20ANG_0.pdf, accessed June 2017). This antenna has a base, realized in the form of a cup equipped with a flange for mounting it to the base surface, a shock absorber made in the form of a coil spring from segments of two coaxial cables for the MV and DMV1 ranges, respectively, a single radiator of the lower and upper subranges made of metal tubes, and a radio frequency separation filter board located at the base. The limitations of this technical solution are:

- a sufficiently large SWR up to 3.5;

- the need to use radio frequency filters, which when using a single emitter are a complex and time-consuming product;

- large longitudinal dimensions (the length of the antenna along with the base is 1.55 m);

- insufficiently high degree of usability due to the integral design of the antenna to the base.

The problem solved by the present invention is to improve the technical and operational characteristics of the antenna.

The technical result achieved by the claimed technical solution is to reduce the SWR of the antenna, simplifying its design by eliminating the RF separation filter board from the base of the antenna, reducing the longitudinal dimensions and increasing the usability of the antenna.

To solve the problem with the achievement of the claimed technical result, the antenna includes installed one after the other along the longitudinal axis of the base, implemented in the form of a glass equipped with a flange designed for mounting it to the base surface; a shock absorber made in the form of a coil spring; the first dielectric sleeve with a flange located on the side of the shock absorber and on the outer surface of which an Edison thread is made; a radio frequency connector with a cutting means of articulation, the receiving part of which is located on the side of the first dielectric sleeve facing away from its flange; matching transformer made with a winding of a two-wire line on a ferrite ring installed in the hole, which is made in the side wall of the first dielectric sleeve; the first contact ring mounted on the flange of the first dielectric sleeve on the side facing the connector; the first and second lengths of cable located inside the cup, shock absorber, the first dielectric sleeve, the first length of the cable connected to the connector, and the second length of the cable through the matching transformer 8 to the first contact ring.

The emitter of the lower subband includes a second dielectric sleeve, on the inner surface of which an Edison thread is made with the possibility of connecting the second dielectric sleeve with the first dielectric sleeve through the Edison thread, and the counterpart of the said connector is located inside the second dielectric sleeve with the possibility of connecting the counterpart with the receiving part of the connector when connecting a second dielectric sleeve outside the first dielectric tube, a second dielectric sleeve provided at the end second and third slip rings connected by a conductive strip disposed on an outer surface of said second dielectric sleeve, the second contact ring is installed with the possibility of contact with the first slip ring mounted on the flange of the first dielectric sleeve; two metal tubes; a dielectric hollow insert installed between the first and second metal tubes; and a third cable section located inside the second dielectric sleeve, a first metal tube, an insert, a second metal tube, arranged one after the other along the longitudinal axis, wherein one end of the third cable segment is connected to a mating part of the connector, and it is installed in the end region of the first metal pipe providing contact with the third contact ring of the second dielectric sleeve.

The upper subband emitter includes a third dielectric bushing, a third metal tube, a helical spiral, a conductive cable, and ferrite rings, mounted one after another along the longitudinal axis. The third dielectric sleeve is installed in the end region of the second metal tube. The third cable segment is located inside the third dielectric sleeve and the third metal tube, and its central core at its other end is connected to one end of the helical spiral, and the braid is connected to the third metal tube. The other end of the helical spiral is electrically connected to the conductive cable, with ferrite rings mounted on the outer surface of the third cable section inside the third dielectric sleeve.

Additional embodiments of the device are possible, in which it is advisable that:

- the base was equipped with a plug, which is made in the form of a glass with Edison thread on its inner side wall, intended for installation on the first dielectric sleeve, and a spring clip installed in the slots of the flange of the first dielectric sleeve with the possibility of detachable fastening of the outer surface of the side wall of the plug between the ends spring retainer;

- the base shock absorber was made in the form of a spiral shaped barrel-shaped spring, and the glass was conical;

- the emitter of the upper subband was equipped with a hollow, dielectric, cone-shaped nozzle installed in the area of the helical spiral on the third metal tube and on the conductive cable;

- the first, second and third metal tubes, insert, third dielectric sleeve were provided with configuration protrusions and recesses with the possibility of placing adjacent adjacent configuration protrusions in configuration recesses.

These advantages, as well as the features of the present invention are explained using its implementation with reference to the figures.

In FIG. 1 shows the base of the antenna (for the convenience of reading the drawing in a disassembled state).

In FIG. 2 shows the same as FIG. 1, with the plug installed and removed (in the assembly).

In FIG. Figure 3 shows the emitter of the lower subband (MV range) (for the convenience of reading the drawing, in an disassembled state).

In FIG. 4 shows an emitter of the upper subband (DMV1 range) (for the convenience of reading the drawing, in an disassembled state);

In FIG. 5 shows a wiring diagram;

In FIG. 6 shows a general view of the antenna when installing the emitter on the base.

The claimed antenna (Fig. 1-4) contains the following elements.

The base 1 (Fig. 1, 2) includes a glass 2 mounted one after the other along the longitudinal axis, equipped with a flange 3, intended for its fastening to the base surface; shock absorber 4, made in the form of a coil spring; the first dielectric sleeve 5 with a flange 6 located on the side of the shock absorber 4 and on the outer surface of which an Edison thread is made; a radio-frequency connector 7 with a cutting means of articulation, the receiving part of which is located on the side of the first dielectric sleeve 5, facing away from its flange 6.

The base 1 has a matching transformer 8, made with a winding of a two-wire line on a ferrite ring, which is installed in the hole made in the side wall of the first dielectric sleeve 5.

On the flange 6 of the first dielectric sleeve 5, on the side facing the connector 7, a first contact ring 9 is installed. Two cable segments - the first cable section 10 and the second cable section 11 - are located inside the cup 2, the shock absorber 4, the first dielectric sleeve 5. The first segment 10 of the cable is connected to the connector 7, and the second length of the cable 11 through the matching transformer 8 to the first contact ring.

In FIG. 1 also shows a plug 12 and high-frequency connectors 13, 14. FIG. 2, a plug 12 is installed on the left, and in FIG. 2 on the right - removed and installed in the spring retainer 15.

The emitter 20 (Fig. 3) of the lower subband (MV range) is realized from the second dielectric sleeve 21, on the inner surface of which an Edison thread is made with the possibility of connecting the second dielectric sleeve 21 with the first dielectric tube 5 through the Edison thread (Fig. 1), and the response part of said connector 7 is located inside the second dielectric sleeve 21 with the possibility of connecting the mate with the receiving part of the connector 7 when connecting the second dielectric sleeve 21 outside the first dielectric tube 5.

The second dielectric sleeve 21 is provided at the ends with a second contact ring 22 and a third contact ring 23 connected by a conductive strip 24 located on the outer surface of the second dielectric sleeve 21. The second contact ring 22 is installed with the possibility of contact (connection) with the first contact ring 9 (Fig. .1) mounted on the flange 6 of the first dielectric sleeve 5. The emitter 20 includes a first metal tube 25, a second metal tube 26 and an insert 27 made of a dielectric and hollow, which Credited between the first and second metal tubes 25, 26. The third cable segment 28 is disposed within a second dielectric sleeve 21, the first metal tube 25, insert 27, the second metal tube 26, which are arranged one behind the other along the longitudinal axis. One end of the third cable section 28 is connected to the mating portion of the connector 7. In the end region of the first metal tube 26, it is installed in contact with the third contact ring 23 of the second dielectric sleeve 21.

The emitter 30 (Fig. 4) of the upper sub-band (DMV1 range) is implemented from a third dielectric sleeve 31, a third metal tube 32, a helical spiral 33 and a conductive cable 34 installed one after the other along the longitudinal axis, as well as from ferrite rings 35. The third dielectric the sleeve 31 is installed in the end region of the second metal tube 26 (Fig. 3). Said third cable section 28 is located inside the third dielectric sleeve 31 and the third metal tube 32, and its central core of the other end is connected to one end of the helical spiral 33, and the braid is connected to the third metal tube 32. The other end of the spiral spiral 33 is electrically connected to the conductive cable 34. Ferrite rings 35 are mounted on the outer surface of the third cable section 28 inside the third dielectric sleeve 31.

In addition, the base 1 (Fig. 1, 2) can be equipped with a plug 12, which is made in the form of a glass with Edison thread on its inner side wall, designed for installation on the first dielectric sleeve 5, and a spring clip 15 installed in the flange slot the first dielectric sleeve 5 with the possibility of detachable fastening of the outer surface of the side wall of the plug 12 between the ends of the spring retainer 15. To simplify the design, the Edison thread on the inner side wall of the plug may be absent. In this case, the plug 12 is attached with a wire, as shown in FIG. 2 left.

To improve ease of use and improve vibration protection of the antenna, the shock absorber 4 of the base 1 can be made in the form of a spiral shaped barrel-shaped spring, and the cup 2 is conical (Fig. 1, 2).

In addition, the upper subband emitter 30 may be provided with a nozzle 36 of a hollow, dielectric, cone-shaped, mounted in the area of the helical spiral 33 on the third metal tube 32 and on the conductive cable 34. In FIG. 4 also schematically shows the contact parts 37 for connecting the braid of the third segment 28 of the coaxial cable with the third metal tube 32.

For ease of assembly and reliability of connection of structural elements, the first, second, third metal tubes 25, 26, 32, insert 27, and the third dielectric sleeve 31 may be provided with configuration protrusions and recesses with the possibility of placing adjacent adjacent configuration protrusions in configuration recesses (Fig. 3, four).

The antenna operates as follows (Fig. 1, 5).

The first segment 10 of the cable is connected to the high-frequency connector 13 and to the connector 7 by compression to ensure the operation of the antenna in the range DMV1 (220-520) MHz.

The second segment 11 of the cable 11 is connected to the high-frequency connector 14 by crimping and to a matching transformer 8, one of the windings of which is soldered to the first contact ring 9 by soldering, and the other to the central core of the second segment 11 of the cable (Fig. 5) to ensure the operation of the antenna in the range of MV (30-220) MHz.

The antenna (Fig. 6) consists of two parts, one of which is the base 1, and the other is a common emitter 40, which, in fact, includes two emitters - the emitter 20 of the lower subband (Fig. 3) and the emitter 30 of the upper subband (Fig. 4).

At the base of the antenna 1 (Fig. 2) there is a matching transformer 8 - a broadband lower subband matching device, which inside the first dielectric sleeve 5 is connected to the first contact ring 9, which serves to ensure the matching of the matching transformer 8 with the lower subband emitter 20 (MV range). Matching transformer 8 is made on a ferrite ring core, which is placed in a special hole in the first dielectric sleeve 5, made radiolucent (for example, from polyamide).

The first dielectric sleeve 5 is equipped with an Edison thread, with which two parts of the antenna are mated with each other - the base 1 and the common emitter 4 (Fig. 6). Edison thread is noteworthy in that it has a high resistance to dynamic loads, is well screwed and unscrewed in conditions of high pollution and has a long service life.

Also, the base 1 of the antenna (Fig. 1) is equipped with a connector 7 (for example, SR-50-902FV), which allows the feeders laid in the base 1 and the emitter 40 to be connected simultaneously with twisting of these two parts of the antenna, i.e. when assembling the antenna (Fig. 6).

Improves the operational characteristics of the antenna and the shock absorber 4, which is designed to compensate for the mechanical stresses destroying the antenna caused by the bending moment that occurs when the antenna encounters an obstacle, as well as when the speed or direction of movement of the antenna or its vibration changes abruptly. For this reason, the claimed antenna can be installed not only on stationary objects, but also on vehicles and other moving vehicles.

The protection of the connector 7 when the emitter 40 is removed is the plug 12. It is wound on the first dielectric sleeve 5 or installed in the spring clip 15 for fastening in the removed state (Fig. 2).

The radiator 20 (Fig. 3) of the antenna consists of a second dielectric sleeve 21 and two metal tubes 25, 26 (for example, aluminum) connected by an insert 27 (radiolucent, capacitive, for example, of polyamide), which perform the function of a lower-band radiator (range MV ) On the generatrix of the cylindrical surface of the second dielectric sleeve 21 is a conductive strip 24, which connects the second and third contact rings 22 and 23 and provides electrical contact of the emitter 20 of the lower subband with the base 1 of the antenna. Inside the specified emitter 20 of the lower subband passes the third length of the cable 28 with the connector 7 (for example, CP-50-903FV), feeding another emitter 30 located in the upper part and which is the emitter of the upper subband (range DMV1).

The emitter 30 of the upper sub-band (range DMV1) is a pin radiator, in which the role of the inductance is played by a helical spiral 33, which is part of a sheet of conductive cable 34 (for example, steel). For reliability, the conductive cable 34 is crimped by a sleeve to which the helical spiral 33 is soldered. On the opposite side from the conductive cable 34 to the helical 33 through the contact parts 37, a third length of cable 28 is soldered, which passes through the third metal tube 32 (aluminum), which is a counterweight emitter 30 of the upper subband connected to these contact parts 37. Next, the third metal tube 32 is connected to the third dielectric sleeve 31 (radiolucent), in the cavity of which ferrite rings 35 are placed (for example, in the amount of eight), worn on the third length of the cable 28 in order to cut off common-mode currents. Next, the third dielectric sleeve 31 is connected to the second metal tube 26 of the emitter 20 of the lower subband.

As tests have shown, the claimed antenna has an SWR of no more than 3.1. Simplification of the design is achieved by eliminating the separation of radio frequency filters from the base of the antenna. In addition, the claimed antenna is shorter than the closest analogue in height by about 0.5 m.

The international standard ISO 9241-11 defines usability as the degree to which a product can be used by certain users in a specific use context to achieve certain goals with due efficiency, productivity and satisfaction.

The term "usability" can be considered a synonym for the word "ergonomics" with the difference that the latter determines the minimum of specific physical efforts when using a thing, and the first - the final total degree of convenience, a measure of the intellectual effort necessary to obtain useful qualities of this thing, and speed achieving a positive result when managing it.

Improving the usability is directly manifested in the design by reducing the longitudinal dimensions, detachability and ease of installation of the emitter 40 (Fig. 6), as well as the use of Edison threads when connecting.

The most successfully declared antenna is industrially applicable in transceiver products of information transmission systems. The antenna allows for the reception and transmission of signals of physical channels in the frequency range 30–520 MHz and can be used as a transmitting and / or receiving antenna with mobile transport and base radios.

Claims (14)

1. An antenna containing: base including: mounted next to each other along the longitudinal axis of the glass, equipped with a flange for attaching to the base surface, a shock absorber made in the form of a coil spring, a first dielectric sleeve with a flange located on the side of the shock absorber, on the outer surface of which is made an Edison thread, a radio-frequency connector with a cutting joint the receiving part of which is located on the side of the first dielectric sleeve facing away from its flange, as well as a matching transformer made with a two-wire winding lines on the ferrite ring installed in the hole in the side wall of the first dielectric sleeve, the first contact ring mounted on the flange of the first dielectric sleeve on the side facing the connector, the first and second cable sections located inside the glass, shock absorber, first dielectric sleeve, and the first segment the cable is connected to the connector, and the second length of the cable through the matching transformer to the first contact ring, emitter of the lower subband, including: a second dielectric sleeve, on the inner surface of which an Edison thread is made with the possibility of connecting a second dielectric sleeve with a first dielectric tube through the Edison thread, the counterpart of said connector being located inside the second dielectric sleeve with the possibility of connecting the counterpart to the receiving portion of the connector when connecting the second dielectric sleeve from the outside the first dielectric tube, the second dielectric sleeve is provided at the ends of the second and third contact rings mi connected by a conductive strip located on the outer surface of the second dielectric sleeve, and the second contact ring is installed with the possibility of contact with the first contact ring mounted on the flange of the first dielectric sleeve, the first and second metal tubes, a dielectric insert, hollow, installed between the first and second metal tubes, and a third length of cable located inside installed one after another along the longitudinal axis of the second dielectric sleeve, the first metal tube, insert, the second metal tube, wherein one end of the third cable segment is connected to the mating part of the connector, and in the end region of the first metal tube it is installed in contact with the third contact ring of the second dielectric sleeve, emitter of the upper subband, including: installed one after the other along the longitudinal axis of the third dielectric sleeve, a third metal tube, a spiral coil and a conductive cable, as well as ferrite rings, the third dielectric sleeve is installed in the region of the end face of the second metal tube, the third cable segment is located inside the third dielectric sleeve and the third metal tube, its central core of the other end is connected to one end of the helical spiral, and the braid is connected to the third metal tube, the other end is screw the spiral is electrically connected to the conductive cable, and ferrite rings are mounted on the outer surface of the third cable section inside the third dielectric sleeve. 2. The antenna according to claim 1, characterized in that the base is equipped with a plug made in the form of a glass with Edison thread on its inner side wall for installation on the first dielectric sleeve, and a spring clip mounted in the slot of the flange of the first dielectric sleeve with the possibility of detachable fixing the outer surface of the side wall of the plug between the ends of the spring retainer. 3. The antenna according to claim 1, characterized in that the base shock absorber is made in the form of a spiral shaped barrel-shaped spring, and the glass is conical. 4. The antenna according to claim 1, characterized in that the emitter of the upper subband is equipped with a hollow, dielectric, cone-shaped nozzle installed in the area of the helical spiral on the third metal tube and on the conductive cable. 5. The antenna according to claim 1, characterized in that the first, second and third metal tubes, the insert and the third dielectric sleeve are provided with configuration protrusions and recesses with the possibility of placing adjacent adjacent configuration protrusions in the configuration recesses.

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