RU78987U1 - ZIGZAG RADIATOR - Google Patents

Abstract

1. A zigzag emitter, the fabric of which is formed by zigzag conductors made of a metal tube, forming at least two rhombic cells placed symmetrically relative to the power point, and additional conductors placed inside the said cells with an acute angle to their sides emanating from power points, and joined by the end face with the surface of the zigzag conductor in the areas forming the sides of the cells, ending with points of zero potential, I distinguish be that the additional conductors located on one side of the conditional line passing through the points of zero potential, and of which one additional conductor is placed inside one rhombic cell, and the other additional conductor inside the second cell, are formed by a rod common to the mentioned conductors, placed with by imposing its middle part on the angular bend of the zigzag conductor located near the power point, and rigidly connected to it at the intersection. 2. The emitter according to claim 2, characterized in that the rod in the middle part is curved and placed by crossing the angular bend of the zigzag conductor with an arc convex towards the power point. The emitter according to claim 1 or 2, characterized in that it contains at least two rods placed symmetrically with respect to the conditional line passing through the points of zero potential. The emitter according to claim 1 or 2, characterized in that the zigzag conductor and the middle part of the corresponding rod are fastened at their intersection by welding. Radiation

Description

The claimed technical solution relates to antenna technology and relates to the design of a zigzag emitter designed for a range directional antenna operating in the meter and decimeter wavelength ranges. The utility model can be used in television broadcast reception systems, as well as in other communication systems operating in the indicated wavelength ranges.

State of the art

A known emitter of a range directional antenna (see description to ed. St. Petersburg No. 1388277, published in 1961) is formed by zigzag conductors with closed ends, forming two rhombic cells, in the common open top of which there are points of attachment of the antenna feeder ( power point). The emitter sheet is supported by metal racks installed at the connection points of the conductors, i.e. at points of zero potential, and based on the parallel surface of the antenna reflector.

The design of the emitter is characterized by limited geometric dimensions, since an increase in the size of the zigzag conductors, despite the presence of lateral support posts, leads to instability of the position of the emitter blade, which determines the distortion of the electrical characteristics of the antenna during its operation. However, increasing the size of the emitter allows you to increase the gain of the antenna, and, therefore, solving the problem of increasing the rigidity of the design of the zigzag emitter is very relevant.

A known solution of the emitter (see patent for utility model RU No. 68784, IPC H01Q 9/16, publ. 27/11/2007), the zigzag conductors of which form two rhombic cells placed symmetrically relative to the power point, with the sides of the rhombic cells adjacent to the point

power supply, made of at least two, fan-shaped outgoing from the point of supply of conductors. The radiator sheet is fixed relative to the reflector plane with the help of three pillars: two lateral, installed at points of zero potential, and one central, fastening the central part of the radiator with a reflector.

The presence of three racks holding the canvas of the zigzag emitter relative to the reflector allows this emitter to be made of conductors that have larger geometrical dimensions than is usual for such antennas. However, the installation of an additional rack does not solve the problem of increasing the stiffness of the emitter as such. In this case, a metal stand located in the center of the antenna sheet introduces additional losses, reducing the antenna gain.

As a prototype of the claimed utility model adopted the design of the zigzag emitter, information on which is given in the following book: V.P. Kismereshkin. Television antennas for individual reception. M., Publishing House "Radio and Communications", 1982, p. 31. The emitter adopted for the prototype is formed by zigzag conductors forming two rhombic cells placed symmetrically relative to the power point. In this case, additional conductors are located inside the rhombic cells, proceeding from the power cable connection zone and connected by ends to the sides of the rhombic cells, ending with points of zero potential.

Also, as in the analogue described above (ed. Certificate No. 138277), the well-known zigzag emitter adopted as a prototype has the geometric dimensions recommended for such emitters. An increase in geometric dimensions, along with the problem of matching the wave impedance of the 75-Ohm cable supply and the resistances (active and reactive) at the power terminals, which is increasing in this case, leads to the instability of the radiator web in space due to the insufficient rigidity of the radiator design. Too large a radiator, when fixed to the reflector by means of side struts, bends in the central part, as a result, the antenna sheet deviates from the plane,

parallel to the reflector plane, which negatively affects the electrical properties of the antenna.

Utility Model Disclosure

The inventive utility model solves the problem of creating a zigzag emitter, characterized by increased mechanical rigidity and having a design that provides a stable position of the emitter conductors in space without deflection of the central part of its canvas.

The above problem is solved due to the fact that in the design of the zigzag emitter, the fabric of which is formed of zigzag conductors made of a metal tube, forming at least two rhombic cells placed symmetrically relative to the power point, and additional conductors placed inside the said cells with an arrangement below an acute angle to their sides, proceeding from the supply point, and joined by the end end with the side surface of the zigzag conductor in part, the image on the other side of the cell, ending with points of zero potential, according to the claimed utility model, additional conductors located on one side of the conditional line passing through the points of zero potential, of which one additional conductor is located inside one rhombic cell, and the other additional conductor inside the second cell, formed by a single for the mentioned conductors rod, placed with the imposition of its middle part on the angular bend of the zigzag conductor, located near the point pi Ania, and rigidly connected to it in places of intersection.

The technical result of the proposed solution is to increase the rigidity of the frame structure, which is formed by the conductors of the emitter. The specified technical result is achieved due to the execution of at least two additional conductors located in two adjacent cells of the emitter in the form of a single, integral along the length of the rod missed almost the entire size of the emitter, due to the location of this rod with the imposition of its middle part on the corner section (bending ) zigzag conductor, and thanks to fastening

the rod and the zigzag conductor in the places of their crossing by means of a rigid connection (in particular, welding, riveting or bolt connection), and also due to the fact that the rod and the zigzag conductor have a certain thickness, and when one is superimposed on the other, there is always a certain thickness between the two axes distance. If there is a combination of the essential features listed above, the axis of the rod in such a frame structure is located at an angle to the plane of the antenna web formed by zigzag conductors. When the rod is made of a metal tube similar to the tubes of which the zigzag conductors are made, the distance between the axes of the rod and the zigzag conductor at the point of their intersection is equal to the sum of the radii of the intersecting tubes. The triangle formed by the axis of the rod, the line of its projection onto the plane of the rhombic cell and the rigid connection, the size of which is determined by the radii of the intersecting tubes, is a rigid figure that increases the rigidity of the frame structure of the emitter as a whole and reduces the degree of deflection of the emitter web in its central part when the emitter is mounted on side racks fixed at points of zero potential. At the same time, the rod is superimposed on the angular bend of the zigzag conductor, and in its middle part is rigidly connected to the tube of this conductor at two points that are the places of intersection of these elements. Therefore, the middle part of the rod and the angular section of the zigzag conductor in the zone of its bend also form a rigid triangle, which increases the strength characteristics of the emitter design. In a particular embodiment of the inventive device, it is advisable to make the rod in the middle part somewhat curved in an arc and to impose a rod with this curved middle with the bend arc oriented convex towards the feed point of the emitter on the angular bend of the zigzag conductor. When executing the middle part of the rod in the form of an arc, due to the small distance between the points (places) of intersection of the rod and the zigzag conductor, the rigidity of the above triangle, formed by the rod and the angular bend of the zigzag conductor, is maintained. With this implementation of the proposed solution

sections of the rod located inside the cells are close to rectilinear conductors, which ensures their electrical characteristics identical to the characteristics of the conductor-rays located in the frame cells of the emitter adopted as a prototype.

Due to the fact that the designs of zigzag emitters are usually symmetrical, the claimed utility model includes at least two rods placed symmetrically relative to a conditional line passing through the points of zero potential.

A rigid connection between the rod and the zigzag conductor is realized mainly by the welding method, i.e. the most common method of attaching antenna elements used in the manufacture of this product.

With the corresponding geometrical dimensions of the emitter’s conductors, the rigidity of its frame structure and the stability of its web position will be maximum when the rod is made of composite of two longitudinal elements: an outer shell of conductive material, and a longitudinal element closely enclosed by the outer shell in the form of a “core” of a rod made of material, whose strength is higher than the strength of the material of the outer shell. In this case, the conductive properties of the rod are identical as if the rod were made entirely of aluminum alloy tube, i.e. the composite rod in the emitter works as a conductor properly. However, due to the increased strength of the core of the rod, it generally has the greatest resistance to various mechanical loads and best strengthens the design of the emitter.

The design and location of the rod, forming additional conductors of the emitter, allows it to be performed with matching inhomogeneities in the form of metal segments placed in rhombic cells parallel to the vector of the electric field component.

Strengthening the strength characteristics of the frame design of the emitter makes it possible to perform it with geometric dimensions that exceed the dimensions recommended for this type of antenna. At

a specific implementation of the claimed utility model, the emitter can be made with a size in the plane of the vector of the magnetic field strength (8n) of at least 0.98 λ _H. , where λ _H is the wavelength of the lower frequency of the operating range. For the manufacture of zigzag conductors, it is preferable to use an aluminum alloy tube having a diameter of 0.015-0.03 λ _H. If necessary, the rods forming additional conductors can be made with a round, square, or rectangular cross section, or with a cross section in the shape of a channel. The execution of the tubular shaped rods is technologically advanced, and therefore is preferred. In the case of manufacturing a composite rod, the conductive sheath is made of aluminum or copper, and can be made of a tube of corresponding internal and external diameters. Mostly, based on the balance of cost and quality, the conductive sheath is made of aluminum alloys. The longitudinal element is preferably made of steel, in particular, from Art.10.

Matching heterogeneities can be made in the form of segments of a tube of aluminum alloy with a diameter of 0.015-0.03 λ _H. and a length of 0.08-0.12 λ _H. These segments are placed on the sections of the rods inside the cells, i.e. on additional conductors. When making rods from an aluminum tube with a diameter of 0.015-0.03 λ _H , matching inhomogeneities are placed at a distance from the supply point equal to 0.1-0.15 λ _H , where λ _H is the wavelength of the lower frequency of the operating range.

Brief Description of the Drawings

The claimed technical solution is illustrated by the following drawings:

Figure 1 schematically shows the inventive zigzag emitter, a top view (plan view);

Figure 2 is a view A in figure 1;

Figure 3 is a diagram showing the relative position of the axes of the zigzag conductors and rods, a plan view;

Figure 4 is a diagram showing the relative position of the axes of the zigzag conductors and rods in a plane orthogonal to the plane of the radiator web;

Figure 5 - section CC in figure 1;

Utility Model Implementation

The zigzag emitter, the design of which is shown in the drawings illustrating the claimed solution, contains zigzag conductors 1 and 2 made of a metal tube, closed by their ends and forming two rhombic cells 3 and 4, in the common open top of which there are contacts for connecting the power cable 5, t .e. the feeding point 6 is located, with respect to which the rhombic cells are symmetrical. In addition to the zigzag conductors 1 and 2, the emitter contains two rods 7 and 8, which are curved in the middle part (section N) and placed with the superposition of this curved middle part, i.e. with the superposition of section N, on the angular bend 9 of the corresponding zigzag conductor, and with the arc of the curved section N convex towards the supply point 6. The rods 7 and 8 and the zigzag conductors 1 and 2 at the points of their intersection are fastened together by welding. Since the rods and zigzag conductors are thick (have a corresponding size in the cross section), then at the intersection points between their axes there is a certain distance K-K ¹ (see figure 4). The rectilinear sections G of the rods 7 and 8 are located inside the cells 3 and 4, and are additional conductors, forming, together with the zigzag conductors, a radiator web. The rods 7 and 8 are made and arranged in such a way that their straight sections G, i.e. additional conductors of the zigzag emitter are placed inside the cells 3 and 4 at an acute angle ψ to the sides S originating from the supply point 6 and are joined by the ends F with the lateral cylindrical surface of the zigzag conductors 1 and 2 in sections Z forming the sides of the cells ending in points 10 of zero potential. In this way,

additional conductors, i.e. rectilinear sections G (see figure 1), located on one side of the conditional line L passing through the points of zero potential 10, and of which one additional conductor is located inside the rhombic cell 3, and the other additional conductor is inside the rhombic cell 4, formed by a single for the said conductors, a solid along the length of the rod 7 (or rod 8 for the other side relative to the conditional line L). Since the ends F of the rods 7 and 8 are placed in the plane formed by the zigzag conductors 1 and 2, and the middle part of the N rods 7 and 8 is raised above this plane, so that between the axes of the rods and the zigzag conductors there is a distance K- ¹ (see Fig. 4 ), then ¹ formed triangle FKK formed rod axis 7 (8 emitter structure), the line of its projection onto the plane of the orthorhombic cell and rigid link ^K-1 K, the size of which is caused by the radii intersecting tubes. The planes of the triangles FKK ^{1 are} orthogonal to the planes of the rhombic cells 3 and 4, formed by zigzag conductors 1 and 2. These triangles strengthen the design of the emitter, increase its rigidity and reduce the degree of deflection of the emitter web in its central part when the emitter is mounted on side racks fixed at points 10 of zero potential.

However, the rods 7 and 8 are superimposed on the angular bends 9 of the zigzag conductors 1 and 2, and are rigidly connected to them at two points, which are the places of intersection of these elements. This leads to the presence of triangles in the structure of the central part of the radiator sheet and in the plane of this sheet formed by the middle part N of the corresponding rod and the angular section 9 of the zigzag conductor in the zone of its bending, which also increases the strength characteristics of the radiator design.

As noted above, the rods 7 and 8 are made integral in length. However, it is preferable to make these rods composite in cross section, namely: it is advisable that rods 7 and 8 be made (see FIG. 5) consisting of an outer shell 11 and from

covered by the outer shell of the longitudinal element 12. In this case, the outer shell 11 is made of aluminum alloy AMG, i.e. of conductive material, and the longitudinal element 12 is made of steel St10, i.e. from a material whose strength is higher than the strength of the material of the outer shell.

Increasing the stiffness of the emitter allows you to perform it with increased geometric dimensions, namely with a size of S _H - not less than 0.98 λ _H , where λ _H is the wavelength of the lower frequency of the operating range.

For the manufacture of the inventive emitter can be used known technologies and equipment. Zigzag conductors 1 and 2 of the emitter are made of an aluminum alloy tube, for example, AMG or AMC, with a diameter of from 0.015 λ _H to 0.03 λ _H. In this case, the specific size of the tube is selected based on the minimum weight and assortment. Outer sheath rods 7 and 8 and placed on them matching heterogeneity 13 may be made of the same tube, while the matching is performed in the form of inhomogeneities in the form of metal segments length from 0,08 λ _H to 0,12 λ _H and place them in areas G rods 7 and 8 indented from the supply point 6, equal to 0.1-0.15 λ _H.

The emitter operates as follows. The high-frequency signal via coaxial cable 5 is supplied to the emitter. Zigzag conductors 1 and 2 excited in antiphase form an electromagnetic field radiated into space. Additional conductors, representing sections G and matching inhomogeneities, increase the radiating surface of the antenna, improving its broadband.

Claims (9)

1. A zigzag emitter, the fabric of which is formed by zigzag conductors made of a metal tube, forming at least two rhombic cells placed symmetrically relative to the power point, and additional conductors placed inside the said cells with an acute angle to their sides emanating from power points, and joined by the end face with the surface of the zigzag conductor in the areas forming the sides of the cells, ending with points of zero potential, I distinguish be that the additional conductors located on one side of the conditional line passing through the points of zero potential, and of which one additional conductor is placed inside one rhombic cell, and the other additional conductor inside the second cell, are formed by a rod common to the said conductors, placed with the imposition of its middle part on the angular bend of a zigzag conductor located near the power point, and rigidly connected to it at the intersection. 2. The emitter according to claim 2, characterized in that the rod in the middle part is made curved and placed by crossing an angular bend of a zigzag conductor with an arc convex towards the power point. 3. The emitter according to claim 1 or 2, characterized in that it contains at least two rods placed symmetrically with respect to the conditional line passing through the points of zero potential. 4. The emitter according to claim 1 or 2, characterized in that the zigzag conductor and the middle part of the corresponding rod are fastened at their intersection by welding. 5. The emitter according to claim 3, characterized in that the rod is made up of an outer shell of conductive material and of a longitudinal element closely enclosed by the outer shell made of a material whose strength is higher than the strength of the outer shell material. 6. The emitter according to claim 3, characterized in that the rods are made with matching inhomogeneities in the form of metal segments placed in rhombic cells parallel to the horizontal component of the current. 7. The emitter according to claim 3, characterized in that it is made with a size in the plane of the magnetic field vector (S _H ) of at least 0.98λ _H , where λ _H is the wavelength of the lower frequency of the operating range. 8. The emitter according to claim 5, characterized in that the zigzag conductors are made of a tube mainly of aluminum alloy having a diameter of 0.015-0.03λ _H , where λ _H is the wavelength of the lower frequency of the operating range. 9. The emitter according to claim 6, characterized in that the matching inhomogeneities are made in the form of segments of a tube made of an aluminum alloy with a diameter of 0.015-0.03λ _H and a length of 0.08-0.12 λ _H and placed on zigzag conductors made of the same tube diameter 0,015-0,03 λ _H, at a distance from the feed point equal 0,1-0,15λ _H, where λ _H - wavelength of the lowest frequency of the working range.