RU2387058C1 - Folded dipole - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: folded dipole is formed with bent conductors so that two rhombic cells are formed of two pieces of coaxial cable; at that, one piece of coaxial cable forms two adjacent sides of one rhombic cell, and the other piece of coaxial cable forms the second rhombic cell and two other adjacent sides of the first rhombic cell.

EFFECT: reaching harmonisation, possible manufacture of dipole of small overall dimensions, simplifying the design and improving manufacturability of folded dipole.

3 cl, 6 dwg

Description

FIELD OF THE INVENTION

The invention relates to antenna technology and can be used both as an independent transceiver antenna and as a radiating element of antenna systems of various radio complexes. Mostly, the inventive vibrator is intended for use in the composition of the irradiator mirror antennas of radio relay stations of special and general technical purpose. Moreover, it is preferable to use the inventive solution for vibrators operating in the centimeter wavelength range.

State of the art

A known design of the loop antenna (see patent RU No. 2054764, IPC H01Q 7/00, publ. 02.20.1996), which is made of two pieces of coaxial cable, each of which forms at least one turn. Cable turns are wound in the opposite direction relative to each other. At the first ends of each piece of cable between the central and external conductors, loads are connected, and the external conductors are short-circuited, and this connection point is the midpoint of the antenna and can be grounded. At the other ends, the central and external conductors of one cable segment are connected respectively to the external and central conductors of another cable segment.

The antenna according to patent No. 2054764 is intended for measuring variable and pulsed magnetic fields in conditions of high electrical noise and cannot perform the function of a directional transceiver antenna in the range of centimeter waves.

A known antenna (see the description of the invention to patent RU No. 2231179, IPC H01Q 7/00, publ. 06/20/04), containing a piece of coaxial cable, part of which is made in the form of a loop located in a plane parallel to the conductive base, and the ends of the loop are bent and orthogonal to the conductive base, while the sections of the coaxial cable between the loop and the bent ends are located in the plane of the loop. The central conductor of the said segment of the coaxial cable, from one end thereof, is intended to be connected to a generator or receiver, and the braid from the other end of the segment is connected to the electrically conductive base. According to the above invention, the shape of the loop can be close to an oval, or it can be made with additional bends in the plane of the loop, forming a wavy or meander line. The technical solution according to patent No. 2231179 can be used in antenna-feeder devices when the transceiver is mounted on a moving object, such as a car, a ship, etc., and is aimed at eliminating the asymmetry of the antenna pattern in the E and H polarization planes, to reduce the height antennas and simplification of its design in comparison with a similar antenna made of a coaxial cable with the formation of L-shaped radiating elements.

However, the design of such an antenna, as well as the above described analogue, is characterized by low directional properties, and such an antenna is designed to operate in the wavelength range with a relatively long length.

Zigzag antennas with reflective screens have a high coefficient of directional action and the ability to work in a wide range of frequencies, including in the microwave range.

Known technical solution of the zigzag antenna according to patent SU No. 1617501 (IPC H01Q 19/00, publ. 30.12.90). The specified solution contains a rectangular metal screen, the dimensions of which are greater than or equal to λ × λ (where λ is the working wavelength), and two identical zigzag ribbon conductors located in a plane parallel to the plane of the said screen. Zigzag conductors form two diamond-shaped sections having a common axis of symmetry, the plane of the zigzag ribbon conductors aligned with the outer surface of the dielectric plate installed between the conductors and the screen parallel to the latter. The length and width of the dielectric plate is equal to the corresponding dimensions of the metal screen, and additional ribbon conductors are made on both sides of it, parallel to the axis of symmetry of the zigzag conductors. The diamond-shaped sections of the zigzag ribbon conductors are excited by the in-phase supply coaxial cable, the inner conductor of which is connected to the middle of one zigzag ribbon conductor, and the external conductor to the middle of another zigzag ribbon conductor. In this case, a coaxial cable is passed along two sides of one of the diamond-shaped sections.

In the antenna according to SU patent No. 1617501, electromagnetic fields due to currents in the periodic structure of additional tape conductors made on the surface of the dielectric plate compensate for the change in reactive electromagnetic fields that occur when the height of the zigzag tape conductors is reduced under a rectangular metal screen, while the presence between the additional tape conductors of slots excited by the current of zigzag conductors and strongly interconnected in the field, providing Chiva more uniform amplitude distribution at the aperture of the proposed zigzag antenna. These factors contribute to an increase in the antenna gain compared to the known analog antennas and the ability to perform antennas with small dimensions.

However, the manufacturing process of the tape emitter of the antenna, the design of which is presented in the description of the patent SU No. 1617501, is characterized by multi-operation technology and requires appropriate equipment, which significantly increases the cost of the product, which is not always advisable.

As a prototype of the claimed technical solution, the design of a band antenna was adopted (see the book: V.P. Kismereshkin. Television antennas for individual reception. 2nd ed. M., Radio and Communications, 1982, pp. 27-37, 77), the loop vibrator of which is formed by zigzag emitters that form two diamond-shaped cells facing each other with open vertices through which the symmetry axis common to the cells passes. The emitters are made of a pipe with a diameter of 22 mm (see page 36 of the above source). A power cable, a coaxial cable, the inner conductor of which is connected to the middle of one zigzag conductor, is missing along the adjacent sides of one of the diamond-shaped cells inside the pipe forming this cell. with its bend in the area of the rhombus vertices facing each other, and the outer conductor is connected in the same zone with another zigzag conductor.

The design of the vibrator adopted for the prototype is characterized by ease of manufacture. At the same time, due to obtaining a directional diagram in a plane perpendicular to the longitudinal axis of the vibrator, it is characterized by an increased, in comparison with the usual half-wave vibrator, directional coefficient. This predetermined the widespread use of antennas based on the above vibrators in the meter and decimeter wavelengths. However, antennas of this design are characterized by complexity matching. The use of a radiator in the form of a pipe with a cable inserted inside leads to the appearance of “spurious” reactances that impair coordination, which is especially problematic for antennas designed to operate in the centimeter wavelength range.

Disclosure of invention

The claimed invention solves the problem of improving coordination while simplifying the manufacturing and assembly technology of a vibrator with symmetrical excitation.

The problem is solved due to the fact that in a loop vibrator formed by curved conductors with the formation of two rhombic cells facing each other by the vertices of rhombs, through which passes their common axis of symmetry, which coincides with the diagonal of each rhombus, containing the first piece of coaxial cable laid along the adjacent sides of one of the rhombic cells on one side of the said axis of symmetry, one end of which is the input of the vibrator, according to the claimed invention, the external conductor of the aforementioned The first segment of the coaxial cable is used as a conductor of a loop vibrator, other curved conductors forming a second rhombic cell and two other adjacent sides of the first rhombic cell, mirrored to the sides formed by the first segment, are made of a second segment of coaxial cable, while the output of the central conductor of the first cable segment connected to the external conductor of the second length of the cable in the area of its bend in the Central part of the vibrator and forms the first point of its power, the output of the external conductor of the first cable segment is connected to the input of the outer conductor of the second cable segment, forming a second point of powering the vibrator and the output of the outer conductor of the second cable segment is connected to the outer conductor of the first segment on its input.

The technical result of the claimed invention is to achieve agreement, the possibility of manufacturing a vibrator of small overall dimensions, which should be necessary for the emitter, designed to work in the centimeter wavelength range, simplifying the design and improving the manufacturability of the loop vibrator.

In a particular implementation of the claimed technical solution, it is preferable to place the curved conductors forming the rhombic cells on the surface of the dielectric plate. This will ensure the rigidity of the vibrator and the location of the cells in one plane.

To increase the level of coordination, the vibrator contains two loops, each of which is made in the form of an arcuate curved metal tape with a L-shaped branch. The loops are placed symmetrically relative to the common axis of the rhombic cells with the direction of the bulges of the arcs to the center of the vibrator and with the orientation of the L-shaped branches inside the corresponding rhombic cell, and the bends of the L-shaped branches are oppositely directed relative to each other. The ends of the loops are galvanically connected to the curved conductors in the areas forming the outer sides of the rhombic cells, the ends of one loop connected to the external conductor of the second cable segment, and the ends of the other cable connected: one end to the external conductor of the second cable segment and the second end to the external conductor of the first cable section.

Brief Description of the Drawings

The essence of the claimed invention is illustrated by the following drawings, in which:

figure 1 schematically shows a General view of the inventive loop vibrator located on the surface of the dielectric plate;

figure 2 is a view of the loop vibrator depicted in figure 1 from its reverse side and without a dielectric plate (view from the side of the loop loops);

figure 3 is a section aa in figure 1;

figure 4 - fragment I in figure 1;

figure 5 is a section bb in figure 4;

figure 6 is a section CC in figure 2.

The implementation of the invention

The inventive loop vibrator can be reproduced industrially using any of the well-known brands of radio frequency coaxial cable having a solid copper screen and the corresponding electrical characteristics.

The loop vibrator, the design of which is shown in the drawings illustrating the claimed solution, contains curved conductors forming a vibrator sheet in the form of two rhombic cells Q and G facing each other with open vertices of rhombuses in the central part of the vibrator. Through these and through opposite vertices of the rhombuses there passes the common axis of symmetry L for both Q and G cells, which coincides with the diagonals of the mentioned rhombic cells. The bent vibrator conductors are formed by two segments of a coaxial cable: the first segment 1, which forms two adjacent sides of the rhombic cell G, located on one side of the mentioned axis of symmetry L; and a second section 2, which forms the entire second rhombic cell Q and two adjacent sides of the first rhombic cell G, which are mirror-like to the aforementioned adjacent sides of this cell G, formed by the segment 1 of the coaxial cable. The segment 1, one end K ₁ being the input of the vibrator, is connected to a transceiver, in particular to a microwave power generator. At the other end K ₂ (see FIG. 5), segment 1 is connected to segment 2 of the coaxial cable in the central part of the vibrator, while the output of the central conductor of segment 1 (i.e., the core of the coaxial cable) is connected to an external conductor (i.e. copper screen of the coaxial cable) of section 2 on the plot of its bend in the Central part of the vibrator, thus forming the first point 3 of the vibrator. The external conductor (screen) of the segment 1 at its end K _{2 is} connected to the external conductor of the segment 2 at its input, forming the second point 4 of the vibrator. The second end of the outer conductor of section 2 is connected to the outer conductor of section 1 at its input - point 5. Thus, the outer conductor of section 1 of the coaxial cable, which is the power cable of the vibrator, is the screen of this cable and at the same time serves as the radiating element of the loop vibrator, which allows to improve its coordination and symmetry of excitation.

It is advisable, in order to increase the structural strength of the product and the manufacturability of its manufacture, to perform a vibrator with conductors made of two pieces of coaxial cable with the placement of these conductors on the surface of the dielectric plate 6. As such a plate, in particular, a plate made of material can be used based on polystyrene. On the front surface of the plate, grooves are repeated, repeating the contour of the rhombic cells of the vibrator, in which pieces of coaxial cable are placed. The conductors are interconnected by a galvanic method widely used in antenna manufacturing.

In order to improve coordination, external loops 7 and 8 are connected to the external conductors of section 1 and section 2 of the coaxial cable, made in the form of arcuate curved metal strips or metal strips. The loops are located symmetrically relative to the common axis L of the rhombic cells with the direction of the bulges of the arcs to the center of the vibrator. Loops with matching inhomogeneities in the form of L-shaped branches 9 and 10 oriented inside the corresponding rhombic cell are made, and the limbs of the L-shaped branches are oppositely directed relative to each other. The ends of the loop 7 are galvanically connected to the outer conductor of the segment 2 of the coaxial cable in the sections corresponding to the outer sides of the rhombic cells G and Q. The ends of the loop 8 are galvanically connected: one with the outer conductor of the segment 2 of the cable in the section corresponding to the outer side of the cell Q, and the second with the outer conductor of the first length 1 of the cable in the area corresponding to the outer side of the cell G.

The vibrator works as follows.

The signal fed to input 1, along the central core of segment 1 of the coaxial cable, is fed to the feeding point 3 of the vibrator. The signal through the external conductor of cable 1 is supplied to the power point 4 of the vibrator, while the conditions of symmetric matching are strictly met. When the vibrator operates as a transmitting antenna, currents are emitted on the external conductors of segments 1 and 2 of the coaxial cable, emitting energy into space at a given frequency.

The use of a rigid coaxial cable with a copper screen as a radiating element of a vibrator and at the same time as an element supplying energy to a feeding point (and not just as a power cable placed in a tubular conductor, as is the case with known solutions), does not require a radio-sealed output cable from the pipe to maintain stability during operation. This greatly simplifies the manufacturing technology of the vibrator.

It was experimentally found that the vibrator, made according to the above construction, in the frequency range 1.5-1.85 GHz, provides good coordination in the 50-ohm path.

Claims (3)

1. A loop vibrator formed by curved conductors with the formation of two rhombic cells facing each other with unclosed vertices of rhombs in the central part of the vibrator, through which their common axis of symmetry coincides with the diagonal of each rhombus, containing the first segment of the coaxial cable laid along adjacent sides one of the rhombic cells on one side of the axis of symmetry, one end of which is the input of the vibrator connected to a generator or receiver, characterized in that outside the first conductor of the said first segment of the coaxial cable is used as one of the curved conductors of the vibrator, the other curved conductors forming the second rhombic cell and two other adjacent sides of the first rhombic cell, mirror sides of the first segment, are made of the second segment of the coaxial cable, with the output the Central conductor of the first cable segment is connected to the external conductor of the second cable segment in the area of its bend in the Central part of the vibrator and forms the first point of its feeding, the output of the external conductor of the first cable segment is connected to the input of the external conductor of the second cable segment, forming the second point of feeding the vibrator, and the output of the external conductor of the second cable segment is connected to the external conductor of the first segment at its input. 2. The vibrator according to claim 1, characterized in that the curved conductors forming the rhombic cells are placed on the surface of the dielectric plate. 3. The vibrator according to claim 1, characterized in that it contains two loops, each made in the form of an arcuate curved metal tape with a L-shaped branch, located symmetrically relative to the common axis of the rhombic cells with the direction of the bulges of the arcs to the center of the vibrator and with the orientation of G- shaped branches inside the corresponding rhombic cell, and the bends of the L-shaped branches are oppositely directed, while the ends of the stubs are galvanically connected with curved conductors in the areas forming the outer sides p mbicheskih cells, and the ends of the loop are connected to the outer conductor of the second cable segment, one end of the other loop connected to the outer conductor of the second cable segment, and a second end connected to the outer conductor of the first cable segment.

Images