RU177146U1 - WAVE WAVE LOAD - Google Patents

Abstract

The proposed utility model relates to the field of radio engineering, namely to microwave technology, and can be used as a standalone device for absorbing reflected electromagnetic waves at the output of the waveguide path, or as an element of complex functional devices: directional couplers, power combiners, measuring bridges, filters and others. The waveguide load contains a short-circuited segment of a rectangular waveguide with a flange at one end and a short-circuiting metal plug located inside, interacting with a screw, at the other end, a wedge-shaped absorber located inside a short-circuited segment of a rectangular waveguide, whose inclined surface faces a wide wall of a rectangular waveguide. The short-circuiting metal plug is made in the form of a symmetrical expanding collet with a longitudinal groove and bevels directed into the groove, which interacts with the wide walls of a rectangular waveguide with the possibility of moving along the waveguide channel and fixing inside it through the insert. The liner interacts on one side with the end surface of the absorber, and on the other side, made with symmetrical bevels of the faces interacting with the wide walls of the rectangular waveguide, with an expanding collet, moreover, the symmetrical bevels of the liner come in contact with the bevels of the groove of the expanding collet, and the screw passing through the through cylindrical opening of the expanding collet collets are screwed into the blind threaded hole of the liner. At the same time, an adjusting nut interacting with the outer surface of the expanding collet is placed on the threaded surface of the screw. The utility model provides a minimum level of the microwave signal reflected from the load due to the possibility of adjusting the location of the absorber and the short-circuiting metal plug to ensure reliable electrical contact with the wide walls of a rectangular waveguide. 2 s.p. f-ly, 4 ill.

Description

The inventive utility model relates to the field of radio engineering, and in particular to microwave technology, and can be used as a standalone device for absorbing reflected electromagnetic waves at the output of the waveguide path, or as an element of complex functional devices: directional couplers, power combiners, measuring bridges, filters and others.

Known waveguide load (SU No. 559315, IPC: H01P 1/24, published: 05/25/1977) containing an absorber, a reflector and a mechanism for moving them, while the reflector is tightly mounted on the absorber, made in the form of a circular straight cone and mounted with the possibility of rotational and translational motion.

The disadvantages of this waveguide load include the complexity of the design of the mechanism for moving the absorber and reflector.

Known waveguide load (SU No. 1681350, IPC: H01P 1/26, published: 09/30/1991), containing a short-circuited segment of a rectangular waveguide, inside which there is a wedge-shaped absorber in the form of a symmetrical wedge, the inclined surfaces of which are facing the wide walls of the short-circuited segment of a rectangular waveguide, wherein the wedge-shaped absorber is mounted to rotate around an axis perpendicular to the narrow walls and the axis of the short-circuited segment of the rectangular waveguide.

The disadvantages of this waveguide load include the complication of its design in connection with the provision of rotational movement of the absorber.

Closest to the claimed technical solution is the waveguide load (IP Bushminsky "Production of structural elements of the microwave. Waveguides and waveguide devices", M .: Higher school, 1974, p. 176, Fig. 3.3), containing a short-circuited segment of a rectangular waveguide with a flange at one end and a short-circuiting metal plug at the other end, placed inside a rectangular waveguide and fixed with a screw fastener, while inside a short-circuited segment of a rectangular waveguide, a gesture A wedge-shaped absorber is fixed, the inclined surface of which is facing the wide wall of a rectangular waveguide.

The disadvantage of this waveguide load is the inability to move the absorber in order to ensure a minimum level of the microwave signal reflected from the load.

The technical problem solved by the claimed utility model consists in a significant level of the microwave signal reflected from the load due to the inability to adjust the location of the absorber and insufficiently reliable electrical contact of the short-circuiting metal plug with wide walls of a rectangular waveguide.

The technical result of the claimed utility model is to provide a minimum level of the microwave signal reflected from the load due to the possibility of adjusting the location of the absorber and the short-circuiting metal plug to ensure reliable electrical contact with the wide walls of a rectangular waveguide.

The technical result is achieved by the fact that the waveguide load contains a short-circuited segment of a rectangular waveguide with a flange at one end and a short-circuiting metal plug located inside, interacting with a screw, at the other end, a wedge-shaped absorber located inside a short-circuited segment of a rectangular waveguide, whose inclined surface faces a wide wall rectangular waveguide. The short-circuiting metal plug is made in the form of a symmetrical expanding collet with a longitudinal groove and bevels directed into the groove, which interacts with the wide walls of a rectangular waveguide with the possibility of moving along the waveguide channel and fixing inside it through the insert. The liner interacts on one side with the end surface of the absorber, and on the other side, made with symmetrical bevels of the faces interacting with the wide walls of the rectangular waveguide, with an expanding collet, moreover, the symmetrical bevels of the liner come in contact with the bevels of the groove of the expanding collet, and the screw passing through the through cylindrical opening of the expanding collet collets are screwed into the blind threaded hole of the liner. At the same time, an adjusting nut interacting with the outer surface of the expanding collet is placed on the threaded surface of the screw.

The essence of the proposed utility model is illustrated by drawings:

FIG. 1 - waveguide load;

FIG. 2 is a general view of a short-circuiting metal plug with a loose leaf assembly;

FIG. 3 - general view of the liner;

FIG. 4 is a general view of a short-circuiting metal plug.

The waveguide load (Fig. 1) contains a short-circuited segment of a rectangular waveguide 1 (Fig. 1), inside which there is a wedge-shaped absorber 2 (Fig. 1), the inclined surface of which faces the wide wall 3 (Fig. 1) of a rectangular waveguide 1.

At one end of the short-circuited segment of the rectangular waveguide 1, there is a flange 4 (Fig. 1), and at the other - a short-circuit metal plug 5 (Fig. 1, 2, 3), located inside the rectangular waveguide 1 with the possibility of movement and fixing using the insert 6 ( Fig. 1, 2, 4), screw 7 (Fig. 1, 2) and the adjusting nut 8 (Fig. 1, 2). In this case, the insert 6 interacts with the end surface of the absorber 2 (Fig. 1).

Short-circuiting metal plug 5 (Fig. 3) is made in the form of a symmetrical expandable collet 5, proportional in cross section to channel 12 (Fig. 1) of a rectangular waveguide 1, with a longitudinal groove 9 (Fig. 3), for example, U-shaped, made with bevels 10 (Fig. 2, 3), which are directed inside the groove 9, expanding it in the outer part.

The groove 9 (Fig. 3) is made symmetrical to the walls 11 (Fig. 2, 3) of the expanding collet 5, which interact with the wide walls 3 of the rectangular waveguide 1. Symmetrically to the axes of the groove 9, a through cylindrical hole 13 is made (Fig. 3).

The insert 6 (Fig. 2, 4) is made in the form of a rectangular prism, proportional in cross section to the channel 12 of the rectangular waveguide 1, with symmetrical bevels 14 faces (Fig. 2, 3), which interact with the wide stacks 3 of the rectangular waveguide 1. From the side one of the wide walls 15 (Fig. 2, 4) of the insert 6 symmetrically to its bevels 14 made a blind threaded hole 16 (Fig. 2, 4).

The angle of symmetrical bevels 14 of the faces of the liner 6 is proportional to the angle of the bevels 10 of the groove 9 of the expanding collet 5 (Fig. 2).

Inside the channel 12 of the rectangular waveguide 1 (Fig. 1), the insert 6, with its symmetrical bevels 14, is in contact with the bevels 10 of the groove 9 of the expanding collet 5, while the screw 7 passing through the through cylindrical hole 13 of the expanding collet 5 is screwed into the blind threaded hole 16 of the insert 6 and the adjusting nut 8 located on the threaded surface of the screw 7 interacts with the outer surface of the expanding collet 5. The opposite wide wall 17 (Fig. 4) of the insert 6 interacts with the end surface of the absorber 2 (Fig. 1).

When the adjusting nut 8 is rotated along the threaded surface of the screw 7, the symmetrical bevels 14 of the insert 6 interact with the bevels 10 of the groove 9 of the expanding collet 5 (Fig. 2). In this case, the insert 6 expands the walls 11 of the groove 9 of the expandable collet 5, interacting with the wide walls 3 of the rectangular waveguide 1, fixing the expandable collet 5 (Fig. 1) inside the rectangular waveguide 1.

The implementation of the short-circuiting metal plug 5 in the form of a symmetrical expandable collet 5, commensurate in cross section to the channel 12 of the rectangular waveguide 1, allows both its movement along the channel 12 of the rectangular waveguide 1 together with the absorber 2, and its subsequent fixation inside the rectangular waveguide 1 with liner 6, screw 7 and adjusting nut 8.

Adjustment and assembly of the waveguide load is as follows.

Place the adjusting nut 8 on the threaded surface of the screw 7 and passing the screw 7 through the through cylindrical hole 13 of the expanding collet 5, screw it into the blind threaded hole 16 of the insert 6.

Combine the symmetrical bevels 14 of the insert 6 with the bevels 10 of the groove 9 of the expanding collet 5 and fix the assembled assembly using the adjusting nut 8.

The assembled unit with the absorber 2 fixed on the insert 6 is placed inside a rectangular waveguide 1 and a standing wave voltage coefficient (VSWR) is measured.

If the measured value of the VSWR does not meet the established technical requirements for the waveguide load, then the location of the absorber 2 inside the channel 12 of the rectangular waveguide 1 is changed by moving it to the region of the maximum electric field and controlling the VSWR.

Having achieved the required value of the VSWR, the position of the absorber 2 is fixed, for example, with glue.

Then, by rotating the adjusting nut 8, the insert 6 is pulled into the groove 9 of the expanding collet 5, ensuring its fixation inside the rectangular waveguide 1.

By means of the sealing compound 18 (Fig. 1), a local sealing is made of the area of interaction of the expanding collet 5 with the walls of the rectangular waveguide 1.

The waveguide load operates as follows.

When the absorber 2 of the waveguide load moves along the channel 12 of the rectangular waveguide 1 to a region close to the maximum of the electric field, the absorption of energy by the absorber 2 increases and the level of the microwave signal reflected from the load decreases, which improves the matching with the load in the waveguide channel and obtain the most uniform SWR characteristic in operating frequency range at a level of no more than 1, 2.

When fixing a short-circuiting metal plug 5 inside a rectangular waveguide 1, the insert 6 expands the walls 11 of its groove 9, providing tight contact interaction with the wide walls 3 of the rectangular waveguide 1, which improves the quality and reliability of electrical contact.

An example of the use of the claimed utility model can serve as a node of the waveguide load used in the waveguide path of the airborne module of the radar system.

The waveguide load (Fig. 1) contains a short-circuited segment of a rectangular waveguide 1 with a cross section of 7.2 × 3.4 (mm) with a flange 4 at one end and a short-circuiting metal plug 5 at the other end, placed and fixed inside the rectangular waveguide 1 using an insert 6 , screw 7 and adjusting nut 8.

The absorber 2 of the waveguide load (Fig. 1), placed inside the short-circuited segment of the rectangular waveguide 1, is made of absorbing material (composition 19) in accordance with the requirements of OST 107.460007.006-92. To fix the absorber 2, glue of the K-300-61 type was used.

The insert 6 (Fig. 1, 4) of the waveguide load is made of alloy L63, and a screw of type M 1.6 is used as an attachment element 7 (Fig. 1). Local sealing of the interaction region of the short-circuiting metal plug 5 with the walls of the rectangular waveguide 1 is made by the epoxy compound EZK-6.

Thus, the claimed utility model allows to minimize the microwave signal reflected from the load by providing the possibility of moving the absorber and the short-circuit metal plug at the assembly stage, as well as to ensure reliable electrical contact of the short-circuit metal plug with the wide walls of the rectangular waveguide when it is fixed.

Claims (3)

1. A waveguide load comprising a short-circuited segment of a rectangular waveguide with a flange at one end and a short-circuiting metal plug located inside the screw, interacting with a screw, at the other end, a wedge-shaped absorber located inside a short-circuited segment of a rectangular waveguide, whose inclined surface faces a wide wall of a rectangular waveguide, characterized in that the short-circuiting metal plug is made in the form of a symmetrical expandable collet with a longitudinal groove and bevels directed inside the groove interacting with the wide walls of the rectangular waveguide with the possibility of moving along the channel of the waveguide and fixing inside it through the liner interacting on one side with the end surface of the absorber and the other side made with symmetrical bevels of the faces interacting with the wide walls of the rectangular waveguide , with a spreading collet, moreover, the symmetrical bevels of the liner are in contact with the bevels of the groove of the expanding collet, and the screw passing through the through cylinder cal hole expansible collet is screwed into the blind threaded hole of the insert, wherein the threaded surfaces of the screw is placed an adjusting nut cooperating with the outer surface of the expansible collet. 2. The waveguide load according to claim 1, characterized in that the short-circuiting metal plug is made in the form of a symmetrical expandable collet with a longitudinal groove of a U-shape, and a through cylindrical hole is made symmetrically to the axes of the groove. 3. The waveguide load according to paragraphs. 1 and 2, characterized in that the angle of the symmetrical bevels of the faces of the liner is proportional to the angle of the bevels of the groove of the short-circuiting metal plug.

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