RU137801U1 - CONSTRUCTION OF THE SEALED CONNECTION OF THE HOUSING AND COAXIAL-STRIP CONNECTOR - Google Patents

Abstract

1. The design of the sealed connection of the housing and the coaxial-strip connector, including a sealed coaxial-strip connector, consisting of a housing and a Central conductor, the housing of the device, in the wall of which a hole is made, and a functional device located in the housing of the device and connected to the central conductor by a jumper, moreover, the part of the central conductor protruding outside the housing of the sealed coaxial strip connector is surrounded by a dielectric material, characterized in that additionally contains a metal sleeve located on the housing of the sealed coaxial-strip connector, fixed together with the sealed coaxial-strip connector in the hole in the wall of the housing of the device and having a through hole in the end part in which the central part protruding outside the housing of the sealed coaxial-strip connector conductor, and as a dielectric material used a cured dielectric adhesive composition, filling the space between the surfaces of the central conductor and the holes in the wall of the device. 2. The construction according to claim 1, characterized in that the diameter of the through hole in the metal sleeve is made in accordance with the formula: D = d exp (W√ε), where D is the diameter of the through hole in the metal sleeve; d is the diameter of the central conductor; W - wave impedance of an additional coaxial line formed by the protruding part of the central conductor and the metal sleeve; ε is the relative permittivity of the cured dielectric

Description

The utility model relates to electronics, in particular to sealed coaxial strip connectors.

The known design of the hermetic connection of the housing and the coaxial strip connector (Radio transmitting devices. Edited by OA Chelnokov. - M .: Radio and communications, 1982, S. 28-31, 234-236), in which the housing is sealed coaxial the strip connector is fixed in the wall of the instrument housing, and the central conductor of the sealed coaxial strip connector is placed coaxially in the hole in the wall of the instrument housing.

The known construction of the sealed connection of the housing and the coaxial strip connector is shown in FIG. 1-2, on which are indicated:

FIG. 1 - sealed coaxial strip connector SRG-50-751 FV;

FIG. 2 - sealed coaxial strip connector SRG-50-751 FV in the wall of the body of the microwave device.

In FIG. 1-2 positions 1-5 are indicated:

1 - housing sealed coaxial strip connector;

2 - the central conductor;

3 - the wall of the housing;

4 - metal jumper;

5 - functional device.

In FIG. 2, the housing 1 of the connector is hermetically fixed in the hole of the wall 3 of the housing. The part of the Central conductor 2, protruding outside the housing 1 and having a diameter d, is coaxially placed in the hole of the wall 3 of the housing of the device with a diameter of D ₀ , forming an additional matching coaxial line. The metal jumper 4 is soldered to the end of the Central conductor 2 of the connector and to the strip conductor of the functional device 5.

One example of a sealed coaxial-strip connector is the SRG-50-751 ФВ ВРО.364.049 ТУ connector manufactured by the domestic industry, designed to connect coaxial and microstrip transmission lines with wave impedances W = 50 Ohms. In accordance with the specifications, the diameter d of the center conductor is 0.6 mm. and the recommended diameter D _{0 of the} hole in the wall of the device body is 1.3 ± 0.06 mm. The ratio of diameters D ₀ / d. in this case, equal to 2.17. The indicated dimensions, along with other structural elements of the coaxial part of the connector, provide a standing voltage coefficient (VSWR) of the connector, coupled to the microwave device case, not more than 1.5 in a wide frequency band from 500 to 18000 MHz.

Also known is a sealed coaxial strip connector of the SMP 19S181-5H0E4 type from Rosenberger, used in the frequency range up to 26.5 GHz and similar in design to the SRG-50-751 PV (Fig. 1). In Assembly Instruction MA_19G, for a protruding portion of a central conductor of 1.27 mm and a diameter of d = 0.38 mm, the recommended diameter of the outer conductor of the additional matching coaxial line is D ₀ = 0.9 mm.

The functionally sealed coaxial-strip connector as part of the microwave device is designed to connect the microstrip radio-electronic functional device located in the sealed enclosure of the device with an external standard line with wave impedance W. To achieve low VSWR values of the sealed coaxial-strip connector coupled to the device case, wave the resistance of the coaxial part of the connector and the additional matching coaxial line should be close to the wave W rotivleniyu standard transmission line, which is achieved by excluding or minimizing the irregularities in these transmission lines.

When a sealed coaxial-strip connector is connected to the wall of the device, the eccentricity of the diameters D ₀ and d of the external and internal conductors of the additional coaxial line leads to heterogeneity in this line (Radio transmitting devices / Ed. By OA Chelnokov. - M .: Radio and communication , 1982, p. 30) and, consequently, to an increase in VSWR, which may exceed the norm specified in the technical documentation for a sealed coaxial-strip connector. The smaller the diameter of the hole D ₀ in the wall of the casing at a constant value of the diameter of the inner conductor d, the greater the heterogeneity and the stronger the effect of eccentricity on the VSWR. The reason for the occurrence of eccentricity is the presence of tolerances on the calculated geometric dimensions of both parts of the sealed coaxial strip connector and the device body. Eccentricity of the diameters can be controlled only after soldering a sealed coaxial strip connector in the device body. In case of large eccentricity values, the connector must be removed from the device body with the use of additional heating.

In addition, during the manufacturing and operation of the device, an additional coaxial line may enter the space between the external and internal conductors, i.e. between the surfaces of the holes in the wall of the housing of the device and the protruding part of the Central conductor of a sealed coaxial strip connector, flux and foreign particles that degrade the characteristics of the connector, including VSWR. A strong influence on the value of VSWR is exerted by solder balls with a diameter of several microns, falling into the gap between the inner surface of the hole in the wall of the microwave device with a diameter of D ₀ and the outer surface of the central conductor with a diameter of d with high-tech soldering of the connector into the wall of the device body with solder pastes. The movement of foreign particles and flux in the gap under external mechanical and climatic influences makes the electrical parameters of the connector unstable. Due to the proximity of the diameters D ₀ and d, the guaranteed elimination of flux and foreign particles, even with ultrasonic cleaning of the device, is difficult. The space between the conductors of the additional coaxial line is located in the inner part of the device and is small in size, therefore it is difficult to access for visual inspection. Thus, the presence of flux and foreign particles leads to an increase in VSWR of a sealed coaxial strip connector coupled to the device body, instability and deterioration of the electrical parameters of the device.

Also known is the design of the sealed connection of the coaxial-strip connector from JP patent application No. 6037516, according to which a split sleeve of dielectric material, consisting of two parts, is placed in the space between the protruding part of the central conductor and the surface of the opening of the wall of the device body.

However, the tolerances on the outer and inner diameters of the sleeve must take into account the possible eccentricity of the diameters of the central conductor and the holes in the wall of the device body, which leads to a loose fit of the parts of the sleeve to a friend and to metal surfaces. Foreign particles can also enter these cavities, not allowing you to completely get rid of the above drawback.

The closest analogue to the claimed utility model is the design described in patent application JP No. 63316901. According to this design, the space between the central conductor and the surface of the hole in the wall of the housing is filled with dielectric material.

However, this design does not pay attention to how the above dielectric insulation of the central conductor is made.

The objective of the claimed utility model is to improve the electrical parameters and reliability of the microwave device, which includes a sealed coaxial strip connector.

The essence of the claimed utility model is that in the design of the sealed connection of the housing and the coaxial-strip connector, including a sealed coaxial-strip connector, consisting of a housing and a Central conductor, the housing of the device, in the wall of which a hole is made, and a functional device located in the housing instrument and a jumper connected to the central conductor, the part of the central conductor protruding outside the housing of the sealed coaxial-strip connector surrounded by dielectric material, an additional metal sleeve is introduced, placed on the housing of the sealed coaxial-strip connector, fixed together with the sealed coaxial-strip connector in the hole in the wall of the device body and having a through hole in the end part, in which the sealed coaxial strip connector is a part of the central conductor, and cured dielectric is used as the dielectric material glue composition filling the space between the surfaces of the central conductor and the holes in the wall of the device body.

In addition, a design is claimed in which, along with the above features, the diameter of the through hole in the metal sleeve is made in accordance with the formula:

D = d exp (W√ε),

where D is the diameter of the through hole in the metal sleeve;

d is the diameter of the Central conductor;

W is the wave impedance of the additional coaxial line formed by the protruding part of the Central conductor and the sleeve;

ε is the relative dielectric constant of the cured dielectric adhesive composition.

In addition, a design is claimed in which, along with the above features, the fixing of the metal sleeve on the housing of the sealed coaxial strip connector is carried out by soldering.

In addition, a design is claimed in which, along with the above features, the metal sleeve has the shape of a hollow cylinder.

In addition, a design is claimed in which, along with the aforementioned features, the metal sleeve has a thread on the inner surface that mates with a thread on the body of a sealed coaxial strip connector.

In addition, a design is claimed in which, along with the above features, the fixing of the metal sleeve in the hole of the wall of the device body is carried out by soldering.

The technical result of the claimed utility model consists in decreasing the standing wave voltage coefficient (VSWR) in the operating frequency band of a sealed coaxial-strip coupler coupled to a microwave device and reducing the variation in VSWR both from sample to sample and when exposed to external mechanical and climatic factors. The specified technical result is achieved by introducing a metal sleeve with filling the space between the sleeve and the protruding part of the Central conductor of a sealed coaxial strip connector with a dielectric adhesive.

Filling the space around the protruding part of the central conductor with dielectric adhesive eliminates the possibility of flux and foreign particles. The use of adhesive composition, in contrast to the use of dielectric bushings, eliminates the possibility of capillary penetration of foreign particles between the surfaces of the inner conductor at the junction with the dielectric filling material.

Additionally, the claimed design by increasing the diameter of the outer conductor of the additional coaxial line due to the filling of the gap with the dielectric composition in the event of an eccentricity of the diameters of the inner conductor and the hole in the sleeve reduces the contribution of this kind of heterogeneity compared to known connectors with the same eccentricity.

Using a metal sleeve allows you to fill the space between the protruding part of the Central conductor and the surrounding surface with a dielectric composition until the connector is fixed in the device body. This significantly increases the manufacturability of this operation, allowing the rejection of connectors with an unacceptable eccentricity at an early stage of manufacture. The joint use of the dielectric adhesive composition and the sleeve allows you to use the claimed design for any form of connector housing and the sleeve, since the adhesive composition takes the form of any cavity, providing good adhesion to surfaces and eliminating capillary penetration of foreign particles between them.

The inventive utility model is illustrated using FIG. 3-7, which depict:

FIG. 3 is a longitudinal section of a sealed coaxial strip connector with a metal sleeve;

FIG. 4 is a longitudinal section of the claimed design of a sealed connection of the housing and the coaxial strip connector;

FIG. 5 is a cross-sectional view of an additional matching coaxial line in a known construction of a sealed connection between a housing and a coaxial strip connector in the absence of eccentricity;

FIG. 6 is a cross-sectional view of an additional matching coaxial line in a known construction of an airtight connection of a housing and a coaxial strip connector with an eccentricity;

FIG. 7 is a cross section of an additional matching coaxial line in the claimed design of a sealed connection of the housing and the coaxial strip connector with eccentricity.

In FIG. 3-7 positions 1-7 are indicated:

1 - housing sealed coaxial strip connector;

2 - the central conductor;

3 - the wall of the housing;

4 - metal jumper;

5 - functional device;

6 - metal sleeve;

7 - cured dielectric adhesive composition.

The design of the sealed connection of the housing and the coaxial-strip connector consists of a sealed coaxial-strip connector, the device body, a metal sleeve 6 and a functional device 5. The sealed coaxial-strip connector comprises a housing 1 in which the central conductor 2 is sealed by a dielectric washer metal the sleeve 6 has a through hole in the end part and is fixed on the housing 1 of a sealed coaxial strip connector, a central second conductor 2 which is placed in the through hole of the end portion of the metallic sleeve 6 and forms with it an additional hole matching coaxial line. The space between the surfaces of the central conductor 2 and the holes of the metal sleeve 6 is filled with a cured dielectric adhesive 7. The metal sleeve 6 together with a sealed coaxial strip connector is placed in the hole of the wall 3 of the device body. The end of the central conductor 2 is connected to the functional device 5 by means of a metal jumper 4.

The design of the sealed connection of the housing and the coaxial strip connector is made as follows.

The metal sleeve 6 is performed with the diameter of the through hole in accordance with the formula:

D _ε = d exp (W√ε),

where D _ε is the diameter of the through hole in the metal sleeve 6;

d is the diameter of the Central conductor 2;

W is the wave impedance of the additional coaxial line formed by the protruding part of the Central conductor 2 and the metal sleeve 6;

ε is the relative dielectric constant of the cured dielectric adhesive composition 7.

The wave impedance W is determined by the formula:

,

,

where D ₀ is the diameter of the hole recommended by the manufacturer of the sealed coaxial strip connector in the wall 5 of the device body.

In the particular case of the implementation of the utility model, the metal sleeve 6 can be made in the form of a hollow cylinder, as shown in FIG. 3. The metal sleeve 6 is fixed on the housing 1 with the central conductor 2 being placed coaxially in the through hole in the end part of the metal sleeve 6. The metal sleeve 6 is fixed on the housing 1 by soldering or using a threaded connection followed by soldering. In the case of using a threaded connection, the metal sleeve 6 on its inner surface has a thread mating with the thread on the housing 1 of the sealed coaxial-strip connector. The space between the surfaces of the central conductor 2 and the through hole of the metal sleeve 6 is filled with a dielectric adhesive composition 7, which is then cured in accordance with the mode determined by the specific composition of the adhesive composition. At this stage, a sealed coaxial strip connector can be checked for compliance with the required parameters without a microwave device. If the connector has passed the conformity check, its parameters will not change, and it can be guaranteed that they will correspond to those after installation in the wall of the microwave device housing.

A through hole is made in the wall 3 of the device case, for example, from aluminum alloy D16 (GOST 4784-97), to accommodate a sealed coaxial-strip connector with a metal sleeve 6. A sealed coaxial-strip connector with a metal sleeve 6 is placed in the resulting hole, fixing it soldered connection. Then, the metal jumper 4 is brazed to the protruding part of the central conductor 2 and the strip functional device 5. The cured dielectric adhesive 7 protects the space between the surfaces of the central conductor 2 and the holes in the metal sleeve 6 from droplets of flux, solder and other foreign particles during soldering and further technological operations, as well as from foreign particles during operation.

When using a Rosenberger type SMP 19S181-5H0E4 microwave connector and adhesive composition with ε = 2.7-2.8 on the basis of epoxy resin in the device, the calculated value of the diameter of the through hole in the end part of the metal sleeve is 1.3 mm. In this case, the metal sleeve is fixed to the connector body by soldering.

When using the SRG-50-751-ФВ ВРО.364.049 TU microwave connector in the device and adhesive with ε = 2.7-2.8 based on epoxy resin to form a dielectric layer, the calculated value of the diameter of the through hole in the end of the metal sleeve is 2 , 16 mm. In this case, the metal sleeve has a thread on its inner surface that mates with the thread on the body of the microwave connector SRG-50-751-FV. The metal sleeve is screwed onto the connector housing and fixed by soldering to ensure tightness.

In FIG. 5 shows a cross section of an additional matching air-filled coaxial line with conductor diameters D ₀ = 1.3 mm and d = 0.6 mm in the absence of an eccentricity between them. In Fig. 6 presents the same coaxial line with an eccentricity of the diameters of the conductors of 0.1 mm The additional matching coaxial line in FIG. 7 is filled with a cured dielectric adhesive with ε = 2.7-2.8 and has an eccentricity of 0.1 mm. The diameter of the hole in the end part of the metal sleeve D _ε = 2.16 provides wave impedance, as in the original line. An increase in the diameter of the through hole in the additional matching coaxial line with dielectric filling in the end part of the metal sleeve with a constant diameter of the central conductor leads to a decrease in inhomogeneity for the same eccentricity between the outer and inner conductors of this line compared to the additional matching coaxial line with air filling .

The inventive design allows to improve electrical parameters both under normal conditions and when exposed to climatic and mechanical factors, and, accordingly, to increase the reliability of the microwave device.

Claims (6)

1. The design of the sealed connection of the housing and the coaxial-strip connector, including a sealed coaxial-strip connector, consisting of a housing and a Central conductor, the housing of the device, in the wall of which a hole is made, and a functional device located in the housing of the device and connected to the central conductor by a jumper, moreover, the part of the central conductor protruding outside the housing of the sealed coaxial strip connector is surrounded by a dielectric material, characterized in that additionally contains a metal sleeve located on the housing of the sealed coaxial-strip connector, fixed together with the sealed coaxial-strip connector in the hole in the wall of the housing of the device and having a through hole in the end part in which the central part protruding outside the housing of the sealed coaxial-strip connector conductor, and as a dielectric material used a cured dielectric adhesive composition, filling the space between the surfaces of the central conductor and the holes in the wall of the device. 2. The design according to claim 1, characterized in that the diameter of the through hole in the metal sleeve is made in accordance with the formula: D _ε = d exp (W√ε), where D _ε is the diameter of the through hole in the metal sleeve; d is the diameter of the Central conductor; W is the wave impedance of the additional coaxial line formed by the protruding part of the central conductor and the metal sleeve; ε is the relative dielectric constant of the cured dielectric adhesive composition. 3. The design according to claim 1, characterized in that the fixing of the metal sleeve on the housing of the sealed coaxial strip connector is carried out by soldering. 4. The design according to claim 1, characterized in that the metal sleeve has the shape of a hollow cylinder.             5. The design according to claim 1, characterized in that the metal sleeve has a thread on the inner surface that mates with the thread on the housing of the sealed coaxial strip connector. 6. The design according to claim 1, characterized in that the fixation of the metal sleeve in the hole in the wall of the housing of the device is carried out by soldering.

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