RU208821U1 - Mobile orientable antenna for LW and LWB bands - Google Patents

Abstract

The utility model relates to antenna technology, namely to transceiver antennas of the long-wave (LW) and extra-long-wave (VLF) frequency ranges. The technical result of the claimed solution is to selectively increase the range of signal transmission in a given direction. The technical result is achieved by the fact that the mobile orientable antenna of the DV and SV ranges is characterized in that it contains a transceiver magnetic antenna element consisting of an elongated ferrite core, while a solenoid winding is applied to the outer surface of the ferrite core, which can be connected to a power source, while the ferrite core and the solenoid winding are enclosed in an external dielectric frame, made with the presence of two fasteners on its outer surface. 3 w.p. f-ly, 8 ill.

Description

Technical field

The utility model relates to antenna technology, namely to transceiver antennas of the long-wave (LW) and extra-long-wave (VLF) frequency ranges.

State of the art

The prior art multi-element magnetic antenna LW- and VLF-frequency range (utility model RF No. 181783). The disadvantage of such an antenna is the technical complexity of designing the antenna assembly due to the fact that the implementation of such a solution in practice is impossible without the design and manufacture of mechanical devices that fix the antenna elements relative to each other.

Also known from the prior art are magnetic antennas designed for transmitting and receiving electromagnetic signals in the LW and VLF ranges - a transmitting linear magnetic antenna (RU 2428774 C1 IPC H01Q 7/06, pub. 10.09.2011), and a compact parametric antenna (US 5495259A published 02.27.1996, H01Q 7/06).

The disadvantage common to all of the above antennas, which are a typical implementation of the Hertzian magnetic dipole, is the presence of pronounced "blind zones" of the radiation pattern, in the absence of the technical possibility of dynamic movement and orientation in space, in order to control the directivity of the radiation pattern and the polarization vector on the LW and VLF frequency bands.

The essence of the utility model

The objective of the claimed technical solution is to implement a transceiver antenna in the LW and VLF frequency ranges (30 Hz - 300 kHz) with the ability to control the radiation pattern and the radiation polarization vector, while maintaining the increased radiation power and the possibility of using on board mobile objects in motion.

The technical result of the claimed solution is to selectively increase the range of signal transmission in a given direction.

The technical result of the claimed solution is achieved due to the fact that the mobile orientable antenna system of the LV and VLF ranges contains a transceiver magnetic antenna element, consisting of an elongated ferrite core, while a solenoid winding is applied to the outer surface of the ferrite core, which can be connected to a source power supply, while the ferrite core and the solenoid winding are enclosed in an external dielectric frame, made with the presence of two fasteners on its outer surface.

In a particular case of implementation, each fastening device is made in the form of a protrusion with a hole for gripping by hand or mechanical device.

In a particular case of the implementation of the claimed technical solution, the fasteners are made with a degree of freedom of movement relative to the longitudinal axis of the dielectric housing, by means of a manual or electromechanical device.

In a particular case of the implementation of the claimed technical solution, the mounting devices contain an additional hole for mounting the external ballast.

At the same time, the elongated shape of the ferrite core makes it possible to increase the noise immunity and enhance the transmitted power of the antenna without the use of a multi-element layout (utility model RF No. 181783), which technically simplifies its use on mobile platforms with the possibility of controlling polarization by means of orientation.

At the same time, the mobile characteristics of the antenna are preserved and improved in terms of its movement in space on board the mobile platform - the oblong (cigar-shaped) shape of the finished product has a minimum windage in the direction of movement parallel to the length of the antenna, the direction of which, when changing the direction of movement of the carrier platform, it is possible to dynamically adjust to minimize air resistance.

Brief description of the drawings

Details, features, and advantages of the present technical solution follow from the following description of the embodiments of the claimed utility model using the drawings, which show:

Fig. 1 - basic design of a mobile orientable antenna system in the LW and VLF range, in longitudinal view (A) and transverse view (B);

Fig. 2 - execution of the antenna system, in which each mounting device is made in the form of a protrusion with a hole for gripping by hand or mechanical device;

Fig. 3 is an illustration of the radiation pattern of a transceiver magnetic antenna element (as a Hertzian magnetic dipole);

Fig. 4 - execution of the antenna system, in which the mounting devices are made with a degree of freedom of movement relative to the longitudinal axis of the dielectric housing, by means of a manual or electromechanical device;

Fig. 5 - connection diagram of the solenoid winding with a power source;

Fig. 6 - execution of a mobile orientable antenna system of the LW and VLF range, in which the mounting devices contain an additional hole for fastening the external ballast, in longitudinal view (A) and transverse view (B);

Fig. 7 - the result of changing the orientation of the antenna system in the horizontal plane;

Fig. 8 - the result of changing the orientation of the antenna in the vertical plane. The figures indicate the following positions:

1 - ferrite core; 2 - dielectric frame; 3 - solenoid winding; 4 - fasteners; 5 - hole in the mounting device for gripping by hand or mechanical device; 6 - transceiver magnetic antenna element; 7 - directional diagram of Hertz's magnetic dipole; 8 - a device that provides movement and fixation of the fastening device in the desired position along the length of the dielectric frame; 9 - power supply; 10 - additional hole for fastening the ballast; 11 - external ballast; 12 - horizontal surface (side view).

Utility Model Disclosure:

A mobile orientable antenna for the LW and LWB bands, as shown in Fig. 1, in longitudinal (A) and transverse (B) forms, is a transceiver magnetic antenna element, which consists of a ferrite core (1) placed in a dielectric frame (2). At the same time, a solenoid winding (3) is applied to the ferrite core (1), which is configured to be connected to a power source (9). The dielectric frame is made with two fasteners (4). In FIG. 2 shows the version in which these fasteners are provided with a hole (5) for gripping by hand or by a mechanical device.

The length of the ferrite core (1) is orders of magnitude greater than its cross section - due to which an increase in the radiated power of a single transmitting magnetic element is achieved by increasing the length of the passage of the magnetic field lines (induced by the solenoid winding (3)) along the body of the core (1). An increase in radiation power is almost linearly related to an increase in noise immunity and accuracy characteristics of the system, improves resolution and increases the range of signal propagation.

The transceiver magnetic antenna element (6) is of the Hertzian magnetic dipole type. This fact determines the radiation pattern (7) of such an antenna shown in FIG. 3.

The arrangement shown in Fig. 1, allows you to change the orientation of such an antenna in the LW and VLF ranges by exerting a physical impact (pressure / pulling) on one of the fasteners (4) by hand or a mechanical tool (which can be a cable), including when gripping through a hole ( 5) shown in Fig. 2. Also, a change in orientation can be carried out by a simultaneous similar impact on each of the two devices in opposite directions of movement.

Through these physical manipulations, a dynamic change in the spatial position (rotation) of the antenna is carried out, and as a result, a change in the direction of the radiation and / or the polarization vector (vertical / horizontal), and the selective direction of the maximum possible radiated power in a given direction.

In FIG. 4 shows the execution of the claimed technical solution, in which the fasteners (4) and the dielectric frame (2) are made with a degree of freedom of movement along the longitudinal axis of each other, by means of a manual or electromechanical device (8), in this particular case, presented in the form of a sliding along the long body of the dielectric frame (2) of a hollow blank, which, under targeted manual or electromechanical action, drags the fastening device (4) along with it, providing independent movement and fixation of the fastening device (4) in the desired position along the length of the dielectric frame (2).

In FIG. 5 shows the connection diagram of the solenoid winding (3) to the power source (9), in which one of the ends (input) of the winding is connected to the power source, and the other end (output) is brought to the ground. The implementation of the translation by means of a mobile orientable system of the LW and VLF range occurs by supplying power from the output of the power source (9) to the input of the solenoid winding (3).

In FIG. 6 shows the execution of the claimed technical solution, in which the fasteners (4) are made with an additional hole (10), which is used to install the ballast (11), in order to increase the weight of the device and the possibility of unhindered immersion in water and other liquid media, in order to implement broadcasting an electromagnetic signal into space on the LW-LWV frequency ranges in absorbing media (for example, sea water), by means of a magnetic transceiver element.

In FIG. 7 shows the result of the dynamic orientation of the antenna (which is a Hertzian magnetic dipole (6)) in space (top view) as a result of exerting a physical impact on the fasteners (4), - in the horizontal plane, resulting in a change in the radiation pattern (7));

In FIG. 8 shows the result of the dynamic orientation of the antenna (which is the Hertzian magnetic dipole (6)) in space (side view), as a result of exerting a physical impact on the fasteners (4), - in the vertical plane, resulting in a change in the antenna polarization vector: in the original, horizontal position (A) of such a LW-VLF antenna - the polarization vector of the radiation is vertical; when the antenna position changes from horizontal to vertical (B), the radiation polarization vector becomes horizontal.

In more detail, the technical result of the claimed utility model is achieved by increasing the length of the ferrite core of the transceiver magnetic element, thus realizing the design of the antenna, which retains increased radiation power and the possibility of using on board mobile objects in motion, while having the possibility of dynamic orientation in space in a horizontal and / or vertical plane on board a mobile object, by exerting a physical impact (pressure / pulling) on one of the fastening devices by hand or a mechanical tool (which can be a cable), or by simultaneously acting on each of the two devices in equally opposite directions of movement.

In contrast to the technical solution described above - a multi-element magnetic antenna of the LW and VLF frequencies (utility model RF No. 181783), in this utility model, the increased radiation power is realized not due to a plurality of antenna elements fixed relative to each other motionlessly, but due to the use of one transceiver magnetic element having an elongated ferrite core, the length of which (L) exceeds its cross section (S). This arrangement allows:

A) to maximize the path of passage through the body of the core of the magnetic field lines (3) induced by the solenoid winding, thus achieving an increase in the radiated power when using this type of single antenna element;

B) to achieve in this way the maximum increase in the efficiency of receiving and transmitting the antenna, with a minimum violation of aerodynamics and an increase in the windage of the finished product, which thus has an oblong / cigar-shaped silhouette, which has better mobile characteristics than a product of identical total dimensions, while having a cross section (S ) which is equal to or greater than its length (L);

At the same time, the implemented design of the external dielectric housing with two fasteners allows you to dynamically change the position of the antenna in space by exerting multidirectional physical impact on the fasteners manually or mechanically.

An example of the implementation of the claimed technical solution is a transceiver antenna element, which uses a lot of ferrite parts (cylinders) to make a single ferrite core with a round profile, 87 mm in diameter and 4000 mm long. A solenoid winding is applied to the surface of such a core, to which an electric current is supplied from a power source in order to carry out translation. The above elements are placed in a dielectric frame that covers the ferrite core along its entire length (4000 mm) and is made with two fasteners, in this case closed handles, spaced so that each handle is in close proximity to one of the ends of the length products. Thus, it becomes possible to manipulate the directivity of the antenna, turning it in space along the horizontal or vertical axis, by providing a manual or electromechanical push/pull effect on one of the handles, or a multidirectional effect on each of them.

An additional example of the implementation of the claimed technical solution is a transceiver element of a similar design, but made using a variety of ferrite parts (cylinders) to form a single ferrite core 1000 mm long and 56 mm in diameter. Such a design is even more compact, being in essence portable (mobile), and makes it possible to use on small unmanned aerial vehicles (drones) equipped, in addition to the carrier device for installing the antenna, with a mechanism that allows for a controlled effect on the handles by means of cables / rods.

Claims (4)

1. A mobile orientable antenna of the DV and VLF ranges, characterized in that it contains a transceiver magnetic antenna element consisting of an elongated ferrite core, while a solenoid winding is applied to the outer surface of the ferrite core, which can be connected to a power source, while the ferrite core and the solenoid winding are enclosed in an external dielectric frame, made with the presence of two fasteners on its outer surface. 2. The antenna according to claim. 1, characterized in that each mounting device is made in the form of a protrusion with a hole for gripping by hand or mechanical device. 3. The antenna according to claim. 1, characterized in that the mounting devices are made with a degree of freedom of movement relative to the longitudinal axis of the dielectric housing by means of a manual or electromechanical device. 4. Antenna according to claim 1, characterized in that the mounting devices contain an additional hole for installing an external ballast.

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