RU2435256C2 - Antenna - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: antenna includes capacitive element and inductive element, which are connected in series and made in the form of two pieces of line with distributed parameters. Internal conductor of coaxial line is intended to be connected between capacitive element and inductive element. External conductor of coaxial line is intended to be connected to free end of piece of line of inductive element. Electric line l₁ of piece of line of inductive element to connection point of internal conductor of coaxial line and electric length l₂ of piece of line of capacitive element from its free end to connection point of internal conductor of coaxial line are interconnected by ratio l₂-l₁≅λ₀/4, where λ₀ - average operating length of wave.

EFFECT: reducing the height and simplifying the design.

6 cl, 4 dwg

Description

The invention relates to radio engineering and can be used in antenna-feeder devices, mainly when the transceiver is installed on a mobile object, such as a car, ship, etc. The invention can be used when working in the wavelength range, where the working wavelength is large relative to the size of the antenna.

The practice of using radio communications, especially those that are located on mobile objects of land, sea and air types or whose consumers are directly moving people, constantly needs to reduce the size of the antenna in comparison with the average operating wavelength λ ₀ .

The theory of the construction of antennas treats the question of their size is clear: the length L of the radiator or the height h should be at least close to L≅λ _0/4. With a decrease in the power developed by the transmitter at the output, R _∑ - the radiation resistance of the antenna decreases quadratically as the length of its conductors decreases, and the input resistance of the antenna degenerates into reactivity.

For example, well-known loop antennas have a rather high height (G. Eisenberg and other Short-wave antennas. M: Radio and communication, 1985).

At present, according to the applicant, the lowest value of the ratio h / λ ₀ ≅ 1/24 is for the antenna made according to the RF patent for invention No. 2231179 (RF patent No. 2231179, H01Q 7/00, published on 06/20/2004).

In this technical solution, the antenna contains a piece of coaxial cable, from one end of which the central conductor is designed to connect to a generator or receiver, and from the other end of which the braid is designed to connect to an electrically conductive base. Part of the length of the coaxial cable is made in the form of a loop located in a plane parallel to the conductive base. The ends of the loop are bent and orthogonal to the conductive base. In this case, two parts of the segment of the coaxial cable between the loop and its curved ends are located in the plane of the loop with the location of the curved ends along the longitudinal axis of the loop inside it.

A limitation of the known device is a rather complicated loop design and the practical impossibility of obtaining ratios for h / λ _{0 of} more than 1/25.

For the claimed technical solution, the closest is an antenna containing a capacitive element, an inductive element connected in series and made respectively in the form of two line segments with distributed parameters, while the inner conductor of the coaxial line is designed to connect between the capacitive element and the inductive element (US Patent No. 4730195 H01Q 1/36, published March 8, 1988).

In this device, another element is connected parallel to the capacitive element - an additional inductance, forming a parallel circuit with the capacitive element. The parallel circuit is connected in series to the inductive element, and the outer conductor of the coaxial line is designed to connect to the free end of the parallel circuit.

As follows from the description of the patent, in the known technical solution it is not possible to significantly reduce the length L (or height h) of the antenna. In addition, as follows from the description and noticeably from the figures presented in this patent, in practical implementation, the antenna has a rather complicated structure.

The problem solved by the invention is the improvement of technical and operational characteristics.

The technical result that can be obtained by carrying out the invention is to reduce the height of the antenna and simplify its design.

To solve the problem with achieving the specified technical result in a known antenna containing a capacitive element, an inductive element connected in series and made respectively in the form of two line segments with distributed parameters, while the inner conductor of the coaxial line is designed to be connected between the capacitive element and the inductive element, according to the invention, the outer conductor of the coaxial line is designed to be connected inductively to the free end of the line segment th element, the electrical length l ₁ of the line segment to the point of the inductance element connecting the inner conductor of the coaxial line and the electrical length of the line segment l ₂ of the capacitive element from the free end to the place of connection of the inner conductor of the coaxial line connected by the relation l ₂ -l ₁ ≅λ _0/4 where λ ₀ is the average working wavelength.

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

- the capacitive element was made of disks, electrically conductive and horseshoe-shaped, with a radial gap between two edges for each disk and installed in a row, while the edge of one disk with a jumper (electrically conductive) is connected to the edge of an adjacent disk, and the jumpers along the row are arranged to provide electrical connection opposite edges relative to the longitudinal axis of adjacent discs in one direction;

- Dielectric washers installed between the discs were introduced;

- the inductive element was made of wire in the form of a coil;

- the disks and the coil were located on the same longitudinal axis, and the outer diameter of the coil was chosen larger than the outer diameter of the disks;

- a T-shaped dielectric frame was introduced, and the disks, dielectric washers and coil were located on it outside;

- a dielectric fairing was introduced, installed outside the disks and coils and connected to the dielectric frame.

These advantages, as well as features of the present invention are illustrated by the best option for its implementation with reference to the accompanying figures.

Figure 1 depicts an electrical diagram of the claimed technical solution;

Figure 2 - schematically the claimed device made according to the electric circuit in figure 1, with the connection of conductive elements;

Figure 3 - design of a horseshoe-shaped disk in figure 2;

Figure 4 - design of a technically implemented device (without connecting a coaxial cable).

The antenna (figure 1) contains a capacitive element 1 and an inductive element 2 connected in series and made respectively in the form of two line segments with distributed parameters. The inner conductor 3 of the coaxial line 4 is designed to be connected to a place (to point A) between the capacitive element 1 and the inductive element 2.

The outer conductor 5 of the coaxial line 4 (Fig. 1) is designed to connect to the free end of the line segment of the inductive element 2 (grounded through the housing or the outer conductor 5 of the coaxial line 4) - to point B. The electric length l _{1 of the} line segment of the inductive element 2 to the place connecting the inner conductor 3 of the coaxial line 4 and the electrical length of the line segment l ₂ the capacitive element 1 from its free end to a place of connection of the inner conductor 3 of the coaxial line 4 connected by the relation l ₂ -l ₁ ≅λ _0/4 where λ ₀ - Independent user operating wavelength.

Capacitive element 1 (figure 2, 3, 4) can be made of disks 6 - plates of brass or copper. Each of the disks 6 is made electrically conductive and horseshoe-shaped, with a radial gap between its two edges. The disks 6 are mounted in a row, while the edge of one disc 6 is connected by a jumper 7 (an electrical conductive tape or wire) to the edge of an adjacent disc 6. The jumpers 7 are arranged along the row to ensure electrical connection of the opposite edges C and D relative to the longitudinal axis of adjacent discs 6 in one direction (i.e., without crosses, with a conductivity current along a helical curve without changing the direction of rotation).

The design can be introduced dielectric washers 8 (figure 4) installed between the disks 6 and performing the function of gaskets. Dielectric washers 8 can be made, for example, of foam.

The inductive element 2 (figure 2, 4) is made of wire, such as copper, in the form of a coil 9.

The disks 6 and the coil 9 are located on the same longitudinal axis, and the outer diameter D _{1 of the} coil 9 is chosen larger than the outer diameter d of the disks 6.

A dielectric frame 10 made of a T-shape can be introduced into the structure, and the disks 6, dielectric washers 8 and the coil 9 are located on it outside (Fig. 4).

In addition, a dielectric fairing 11 (radiolucent) may be introduced, mounted outside the disks 6 and the coil 9, connected to the dielectric frame 10 (Fig. 4). Figure 4 also shows the nut-clamp 12 (dielectric).

The antenna works as follows.

When applying EMF to points A and B (1, 2) when the ratio of l ₁ -l ₂ = λ _0/4 where λ ₀ - average operating wavelength, the current flowing through the capacitive element and inductive element 1 2, becomes consistent in one direction from point B to the free end of the capacitive element, which leads to the resonance of the serial circuit and ensures the matching of the feeder - coaxial cable 4 with the antenna.

As shown by experimental studies, when the antenna is implemented in the form of a serial circuit, the following occurs:

- cutoff of feeder currents, usually leading to an antenna effect when feeding the antenna with coaxial cable 4 without the use of a balancing device;

- “automatic” coordination with the supplying coaxial cable 4 (of course, if there is coordination of this feeder with the output of the transmitter - emf generator);

- intense radiation of radio waves into the space surrounding the serial circuit;

- achieved the minimum height h of the antenna and the simplification of its design.

Those skilled in the art will understand that the series circuit (FIG. 1) can be structurally implemented in various ways using elements known from the prior art.

Figure 2, 4 shows the design in which the capacitive element 1 (figure 2, 3, 4) is made of disks 6, and the inductive element 2 is in the form of a coil 9. Each of the disks 6 is made electrically conductive and horseshoe-shaped (figure 3 ) Disks 6 are mounted in a row. The edge of one disk 6 jumper 7 is connected to the edge of an adjacent disk 6 (figure 2). The jumpers 7 along the row are arranged to provide electrically conductive connection of the opposite edges C and D relative to the longitudinal axis of adjacent disks 6 in one direction (point D of the underlying disk 6 is short-circuited with point C of the upper disk 6 for all disks 6, or, conversely, point C of the underlying disk 6 is short-circuited with point D of the overlying disk 6 for all disks 6, i.e., without spatial crosses). To ensure the convenience of connecting the coaxial cable 4 and further reduce the height h of the antenna, the disks 6 and the coil 9 are located on the same longitudinal axis, and the outer diameter D _{1 of the} coil 9 is chosen larger than the outer diameter d of the disks 6.

Figure 4 shows the assembly drawing without connecting the coaxial cable 4 shown in figure 3.

The assembly is carried out on a dielectric frame 10, made T-shaped, one-piece or detachable (for example, the support for the coil 9 can be made in the form of a dielectric cap with a Central hole, through which the leg "T"). Leg "T" in figure 4 is facing up (although it can also be turned down). A coil 9 is wound onto a shelf of a T-shaped dielectric frame 10 with a copper wire. Then, discs 6 are put on the “T” leg, separating them from each other by dielectric washers 8 (gaskets). The dielectric nut-clamp 12 tightens the disks 6 and dielectric washers 8. The connection of the disks 6 with jumpers 7, as well as the connection of the lower disk 6 and the coil 9 are carried out in accordance with figure 3. Install the dielectric fairing 11, which is connected mechanically or with glue to the dielectric frame 10. As can be seen from figure 4, the antenna is characterized by significant simplicity, both structural and assembly.

Conditions l ₂ -l ₁ ≅λ _0/4 enables h / λ ₀ → min. The sign ≅ relative to the sign = is chosen because the average operating wavelength λ ₀ may differ from the actual one on the real frequency response of the antenna (due to “spurious" influences, such as inaccurate manufacturing or the influence of the wiring of coaxial cable 4), but not more than 7%

In an embodiment of the SM antenna (ultralow) it was possible to achieve:

h / λ ₀ = 130 mm / 11000 mm≅1 / 85. Such a balance of height and working wavelength h / λ _{0 was} obtained for the first time for the existing level of technology, and the applicant is not aware of other technical solutions providing such ratios. This refutes the theoretical position that the height h of the antenna may not be less than ₀ h << λ / 4;

- standing wave coefficient (SWR) in the supply feeder with wave impedance Z ₀ = 50 Ohms (coaxial cable 4) SWR = 1.2. This SWR value is inherent in conventional antennas, but in the claimed technical solution it is achieved without the use of special matching elements of the supply feeder.

Thus, for the technical implementation of the antenna, the essential features of the present invention are the use of a sequential oscillatory circuit, the power supply to it described above, and the application of the indicated ratio for l ₁ and l ₂ .

The most successfully declared antenna is industrially applicable:

- on mobile communication objects, where its low height is necessary due to the functional specificity inherent in the moving object itself;

- at stationary communication facilities, where its low height reduces operating costs and the time required for manufacturing, routine maintenance and repair of the antenna itself.

Claims (6)

1. An antenna containing a capacitive element, an inductive element connected in series and made respectively in the form of two line segments with distributed parameters, while the inner conductor of the coaxial line is designed to connect between the capacitive element and the inductive element, characterized in that the outer conductor of the coaxial line is designed for connection to the free end of the line segment of the inductive element, the electrical length l ₁ of the line segment to the point of the inductance element is connected I the inner conductor of the coaxial line and the electrical length of the line segment l ₂ of the capacitive element from the free end to the place of connection of the inner conductor of the coaxial line connected by the relation
l ₂ -l ₁ ≅λ _0/4
where λ ₀ is the average working wavelength. 2. The antenna according to claim 1, characterized in that the capacitive element is made of disks, conductive and horseshoe-shaped, with a radial gap between two edges for each disk and installed in a row, while the edge of one disk is connected by a jumper to the edge of an adjacent disk, and the jumper along the row are arranged to ensure electrical connection of opposite edges relative to the longitudinal axis of adjacent discs in one direction, while the inductive element is made of wire in the form of a coil. 3. The antenna according to claim 2, characterized in that the introduced dielectric washers installed between the disks. 4. The antenna according to claim 2, characterized in that the disks and the coil are located on the same longitudinal axis, and the outer diameter of the coil is chosen larger than the outer diameter of the disks. 5. The antenna according to claim 2, characterized in that the dielectric frame is made T-shaped, and the disks and the coil are located on it outside. 6. The antenna according to claim 5, characterized in that a dielectric fairing is introduced, mounted outside the disks and coils and connected to the dielectric frame.

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