RU161813U1 - CONTACT GASKET FOR FLANGE CONNECTION OF WAVEGUIDES - Google Patents

Abstract

1. The contact gasket for the flange connection of the waveguides, made in the form of a metal plate with a rectangular window, on both sides of which are made contact elements arranged in a checkerboard pattern, characterized in that the contact elements are made in the form of bullets of the same height, directed in opposite directions perpendicular to the plane a metal plate and combined into groups: a central one and at least two peripheral ones, while the contact elements of the central group are made in rows along the contour a rectangular window, with equal pitch both in rows and between rows, and the contact elements of the peripheral groups are made with the same step as in the central group. 2. Contact strip according to claim 1, characterized in that the beetles are made in the form of truncated cones or in the form of truncated pyramids, while the height (H) of the contact elements is equal to the thickness (S) of the contact strip. 3. The contact gasket according to claim 2, characterized in that the diameter (D) of the lower base of the truncated cone and the diameter (D) of the upper base of the truncated cone are in the ratio: D = 2D, similar to the diagonal (L) of the lower base of the truncated pyramid and the diagonal (L) the upper base of the truncated pyramid are in the ratio: L = 2L, while the step of the contact elements (N) ≤5D or ≤5L.4. Contact strip according to claim 1, characterized in that the first row of contact elements of the central group is removed from the contour of the rectangular window by a distance (A), which is in the range: 4.2S-6.25S, where S is the thickness of the contact strip.

Description

The proposed utility model relates to ultra-high frequency (microwave) technology and can be used for flanged connection of waveguides and waveguide devices in waveguide paths with increased requirements for electrical tightness.

A known gasket for connecting waveguides (SU 614481, published: 07/05/1978, IPC: H01P 1/04), having an elastic metal sheet with a rectangular window, a radius zig made along its contour, and in the corners of a rectangular window at an angle of 45 ° to it slots are made to the sides.

The design of this contact strip has the following disadvantages:

a) possible non-uniformity of the straightening line of the zigs during compression of the contact strip between the flanges of the waveguides, which can lead to a decrease in the electrical leakage of the waveguide connection and loss of power of the microwave signal;

b) the possibility of damage to the galvanic coating of the inner surfaces of the waveguide flanges by the sharp edges of the radius zigs during compression of the contact strip between the flanges;

c) the impossibility of using the contact strip in waveguide flange joints in conjunction with sealing gaskets, as well as in the presence of pins centering the flanges of the waveguides, since the contact elements are placed over the entire surface of the contact strip.

A known gasket for the flange connection of waveguides (SU 1548816, published: 03/07/1990, IPC: H01P 1/04) containing a metal plate in which the contact elements are arranged in a checkerboard pattern. Each of the contact elements is formed by two spring petals, bent in different directions. Spring petals have a rectangular shape and are formed by an H-shaped notch.

The design of this contact strip has the following disadvantages:

a) the presence of a gap between the spring blades reduces the level of electrical leakage of the waveguide path and increases the power loss of the microwave signal;

b) the possibility of damage to the galvanic coating of the inner surface of the waveguide flanges by the sharp edges of the spring lobes when compressing the contact strip between the flanges;

c) the impossibility of using the contact strip in waveguide flange joints in conjunction with sealing gaskets, as well as in the presence of pins centering the flanges of the waveguides, since the contact elements are placed over the entire surface of the contact strip.

Closest to the proposed technical solution is a contact strip for the flange connection of waveguides (SU 1363330, published: 12/30/1987, IPC: H01P 1/04), containing a metal plate, on both sides of which contact elements arranged in a checkerboard pattern are made. Each contact element is formed by at least four triangular spring petals having a common top and bent alternately in different directions.

This technical solution has the following disadvantages:

a) a low level of electrical leakage, which is associated with the features of the formation of contact elements, namely:

- with the presence of grooves forming spring petals, which lead to a decrease in the contact area of the contact elements with the inner surfaces of the waveguide flanges;

- a different amount of elastic deformation in each of two adjacent spring petals, since one of them has a bending line of the petal along the rolled, and the other across the rolled strip material;

b) the possibility of damage to the galvanic coating of the inner surfaces of the waveguide flanges with the sharp edges of the spring lobes;

c) the impossibility of using a contact strip in waveguide flange joints in conjunction with sealing gaskets, as well as in the presence of pins centering the flanges of the waveguides, since the contact elements are placed over the entire surface of the contact strip.

These disadvantages of the known contact pads for the flange connection of waveguides significantly limit their use in the waveguide paths of many radio systems.

The technical result of the proposed utility model is to increase the electrical tightness of the flange connection of the waveguides and reduce the power loss of the microwave signal in the operating frequency range.

The technical result is achieved in that the contact strip for the flange connection of the waveguides is made in the form of a metal plate with a rectangular window, on both sides of which are made contact elements arranged in a checkerboard pattern. Contact elements are made in the form of bullets of the same height, directed in opposite directions perpendicular to the plane of the metal plate and combined into groups: a central one and at least two peripheral ones. In this case, the contact elements of the central group are made in rows along the contour of the rectangular window, with an equal step both in the rows and between the rows, and the contact elements of the peripheral groups are made with the same step as in the central group.

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

FIG. 1 is a general view of a flange connection of waveguides with a contact gasket;

FIG. 2 is a general view of a contact strip with contact elements having the shape of truncated cones;

FIG. 3 is a view A of FIG. 2;

FIG. 4 is a section BB of FIG. 3;

FIG. 5 is a view B of FIG. 3;

FIG. 6 is a general view of a contact strip with contact elements having the shape of truncated pyramids;

FIG. 7 is a view D of FIG. 6;

FIG. 8 is a section DD of FIG. 7;

FIG. 9 is a view E of FIG. 7.

Contact strip 1 (Fig. 2, 6) for the flange connection of waveguides 2 and 3 (Fig. 1) is made in the form of a metal plate with a rectangular window 4, contact elements 5 and holes 6 for fastening elements of the flanges 7, 8.

Contact elements 5 (Fig. 2, 6) are made in the form of beetles having the shape of truncated cones 9 (Figs. 3, 4, 5) or the shape of truncated pyramids 10 (Figs. 7, 8, 9). Contact elements 5 are made on both sides of the contact strip 1 and are directed in a checkerboard pattern on opposite sides perpendicular to the plane of the metal plate, forming “wafer” surfaces (Fig. 4, 8). Moreover, the height H of the contact elements 5 is the same and equal to the thickness S of the contact strip 1: H = S.

If the beetle has the shape of truncated cones 9 (Fig. 4, 5), the diameter D of the lower base and the diameter D _{1 of the} upper base of the truncated cone 9 are in the ratio: D = 2D ₁ . If the beetles are made in the form of truncated pyramids 10 (Fig. 8, 9), then the diagonal L of the lower base and the diagonal L _{1 of the} upper base of the truncated pyramid 10 are in the same ratio: L = 2L ₁ .

The above ratios plus a cone-shaped or pyramidal shape of the pupples make it possible to ensure their uniform elastic deformation during compression of the contact strip 1 between the flanges 7 and 8 of the waveguides 2, 3 and, thus, to ensure reliable contact interaction of the vertices 11 of the contact elements 5 (Fig. 4, 8 ) with the inner surfaces 12, 13 of the flanges 7, 8. In this case, the galvanic coating of the inner surfaces 12, 13 of the flanges 7, 8 remains intact due to the absence of sharp edges at the contact elements 5.

Contact elements 5 on the contact strip 1 are combined into groups: a central one and at least two peripheral ones (Fig. 2, 6). This arrangement of the contact elements 5 allows you to use the contact strip 1 in the flange connection of the waveguides 2 and 3 (Fig. 1) in conjunction with the sealing gaskets 14, as well as in the presence of pins 16, providing centering of the connected waveguides 2, 3.

The contact elements 5 of the central group are arranged in rows along the contour of the rectangular window 4 of the contact strip 1 (Fig. 2, 6), with equal pitch N both in the rows and between the rows (Fig. 3, 4, 7, 8). In this case, the first row of contact elements 5 is removed from the contour of the rectangular window 4 (Fig. 3, 7) by a distance A, which is in the range: 4.2S-6.25 S, where S is the thickness of the contact strip 1. Value A, taken within the specified limits, is the minimum distance to eliminate the formation of cracks and tears of the metal when performing contact elements 5 near the rectangular window 4.

The contact elements 5 of the peripheral groups (Fig. 2, 6) are made with the same step N as in the central group, and can be located along the short and / or long sides of the rectangular window 4, for example, between the holes 6 for the fastening elements of the flanges 7 , 8.

Step N (Fig. 3, 4, 7, 8) of the location of the contact elements 5 in the central and peripheral groups and the diameter D ₁ (Fig. 4) or the diagonal L ₁ (Fig. 8) are in the ratio: N≤5D ₁ or N ≤5L ₁ , which allows to ensure the maximum possible filling density of the groups and, thereby, increase the contact area of the vertices 11 of the contact elements 5 with the inner surfaces 12, 13 of the flanges 7, 8.

Between the Central and peripheral groups of contact elements 5 are made holes 17 (Fig. 2, 6) to accommodate the pins 16.

The proposed utility model works as follows. When the flanges 7.8 of the waveguides 2, 3 are pulled together with the fastening elements, the contact strip 1 is compressed between the flanges 7 and 8, while the tops 11 of the contact elements 5 of the contact strip 1 interact with the inner surfaces 12, 13 of the flanges 7, 8 of the waveguides 2 and 3 providing reliable electrical contact in the region of the contour of the rectangular window 4, which can significantly increase the level of electrical leakage of the flange connection and, thereby, reduce the power loss of the microwave signal.

Installation of the contact strip 1 (Fig. 2, 6) between the flanges 7 and 8 of the waveguides 2, 3 (Fig. 1) is as follows.

Sealing gaskets 14 are placed in grooves on the inner surfaces 12, 13 of the flanges 7, 8.

The contact strip 1 is placed between the flanges 7 and 8 of the waveguides 2 and 3, having pins 16 in the holes 17 of the contact strip 1.

The bolts 18 are placed in the holes 20 of the flanges 7, 8 and the holes 6 of the contact strip 1 and tighten the flanges 7 and 8 of the waveguides 2, 3 with the help of nuts 19.

An example of using the proposed technical solution is a contact strip for the flange connection of waveguides in the waveguide path of the radar transmitter.

This flange connection (Fig. 1) contains two rectangular waveguides 2 and 3 with a cross section of 23 × 10 (mm) with flanges 7 and 8, between which a contact gasket 1 is installed, while in the grooves on the inner surfaces 12, 13 of the flanges 7, 8 are placed sealing gaskets 14, and flanges 7, 8 are pulled together by fastening elements in the form of bolts 18 with nuts 19. Centering of the connected waveguides 2 and 3 is carried out using pins 16, which are installed in holes 15, made from the inner surfaces 12, 13 of flanges 7, 8 .

The sealing gasket 14 is made of a mixture of rubber, for example, grade IRP-1267 or IRGI 354. Contact strip 1 is made of tape DPRNT 0,12 BrB2 GOST 1789 with heat treatment HV≥340 and coating M3.Ср6.

The proposed design of the contact strip allows to increase the electrical tightness of the flange connection of the waveguides and significantly reduce the power loss of the microwave signal.

Claims (4)

1. The contact gasket for the flange connection of the waveguides, made in the form of a metal plate with a rectangular window, on both sides of which are made contact elements arranged in a checkerboard pattern, characterized in that the contact elements are made in the form of bullets of the same height, directed in opposite directions perpendicular to the plane a metal plate and combined into groups: a central one and at least two peripheral ones, while the contact elements of the central group are made in rows along the contour a rectangular window, with equal pitch both in rows and between rows, and the contact elements of the peripheral groups are made with the same step as in the central group. 2. Contact strip according to claim 1, characterized in that the beetles are made in the form of truncated cones or in the form of truncated pyramids, while the height (H) of the contact elements is equal to the thickness (S) of the contact strip. 3. The contact gasket according to claim 2, characterized in that the diameter (D) of the lower base of the truncated cone and the diameter (D ₁ ) of the upper base of the truncated cone are in the ratio: D = 2D ₁ , similar to the diagonal (L) of the lower base of the truncated pyramid and the diagonal (L ₁ ) of the upper base of the truncated pyramid are in the ratio: L = 2L ₁ , while the step of the contact elements (N) ≤5D ₁ or ≤5L ₁ . 4. The contact gasket according to claim 1, characterized in that the first row of contact elements of the central group is removed from the contour of the rectangular window by a distance (A), which is in the range: 4.2S-6.25S, where S is the thickness of the contact gasket.

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