SU1727181A1 - Method of manufacture of air-tight unit of shf waveguide - Google Patents

Abstract

The invention relates to the technology of manufacturing microwave devices and can be used in the manufacture of sealed microwave assemblies and diaphragms. The aim of the invention is to simplify manufacture. A method of manufacturing a sealed waveguide assembly includes installing a ceramic diaphragm into a body made of plastic alloy and sealing a crimp coupling from an alloy with a thermomechanical memory, the inner diameter of which is less than the outer diameter of the body, while prior to installing the ceramic diaphragm crimping sleeve annealed at a temperature recrystallization of the alloy, cooled to a temperature below the temperature of the direct martensitic transformation, distributes chilled pressing second clutch to a diameter greater than the outer diameter of the body, and after the aperture in the ceramic body on it is pushed cooled constricting sleeve, it is heated to a temperature above a threshold reverse martensitic transformation compressing the sleeve material but below its recrystallization temperature.

Description

The invention relates to radio engineering and can be used to make sealed assemblies of microwave waveguides in antenna devices, vacuum devices, atomic installations, as well as to seal various types of cylindrical and round windows and windows that separate two volumes with different pressures or environments. engineering, shipbuilding, nuclear energy.

A known method of sealing waveguides using rubber gaskets.

However, when using rubber pads, the temperature range of operating conditions and the microwave power level transmitted through the path are limited.

Therefore, such nodes can not be used in vacuum devices microwave 111.

The closest technical essence and the achieved result is a method of sealing waveguides by the method of elastoplastic radial compression, in which a sapphire diaphragm with a smooth conical face is pressed into a steel hermetic junction with an inner coating of plastic alloy (the diaphragm is pressed inside the hermetic junction and creates a roll of plastic on its side surface. creating a seal).

However, this method is not technologically advanced, since for its implementation

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It is not necessary to carry out complex operations - applying a layer of ductile metal on the inner surface of the housing and precision execution of the chamfer of the diaphragm. In addition, with a small diameter of the seal and a thin diaphragm (for the millimeter range of the microwave), it can be destroyed in the manufacturing process 121 (prototype).

The aim of the invention is to simplify the method of manufacturing a sealed unit of a microwave waveguide.

Simplification of the method of manufacturing ger-. An accurate microwave waveguide assembly allows for increased productivity due to the absence of complex and costly operations of applying a layer of ductile metal to the inner surface of the housing and a precise execution of the chamfer of the diaphragm, as well as reducing the number of scrap by eliminating the destruction of the diaphragm during manufacture. .

 . This goal is achieved by the fact that the method of manufacturing a sealed unit of a microwave waveguide involves installing a ceramic diaphragm into the housing and sealing it by crimping the housing.

According to the invention, a new case is that the case is made of a plastic alloy, and the sealing is performed by a crimp coupling of an alloy with a thermomechanical memory, the inner diameter of which is less than the outer diameter of the housing, while annealing the compression sleeve before installing the ceramic diaphragm into the housing at the recrystallization temperature of the alloy, cooled to a temperature below the temperature of the direct martensitic transformation, the cooled crimping sleeve is distributed to a diameter larger than Diameter of the housing, and after the aperture in the ceramic body on it is pushed cooled constricting sleeve is heated until its temperature exceeds a threshold reverse martensitic transformation compressing the sleeve material but below its recrystallization temperature.

The differences in the proposed method include the manufacture of a plastic alloy case, the implementation of sealing with a crimping sleeve made of an alloy with a thermomechanical memory, and sealing conditions,

The operations of the proposed method are carried out in the following sequence:

- make crimping coupling of alloy with thermomechanical

a memory whose inner diameter (d) is smaller than the outer diameter (D) of the pressure transfer housing (determined by calculation);

- make waveguide transducer from plastic alloy;

- pressing crimping sleeve at the temperature of recrystallization of the alloy;

- cool it to a temperature below the temperature of the direct mertensitic transformation of the alloy;

- the cooled clutch is distributed in diameter so that the inner diameter d becomes larger than the outer diameter D of the pressure transfer housing (d D);

- set the cooled clutch on the hermetic junction housing with a ceramic diaphragm installed inside it;

- heat the assembled unit to a temperature above the threshold of the reverse martensitic transformation of the material of the compression sleeve, but lower than the temperature of its recrystallization.

When calculating the sealed unit of the waveguide, it is necessary to ensure tightness while maintaining the integrity of its parts. The required force to ensure plastic deformations in the joint is achieved by selecting materials for the crimping sleeve and the pressure transfer housing and calculating the difference in diameters d and D with the temperature and physical-mechanical characteristics of the materials known (in particular, the thermoelastic characteristics of the coupling material and the plastic properties of the pressure transfer housing material).

The invention is implemented as follows:

- make a crimping sleeve made of an alloy with a thermomechanical memory, for example titanium nickelide, in particular alloy TN-1K (TU-809-394-84). The temperature range of the martensitic transformation of this alloy is -160-120 ° C;

- make waveguide transducer from ductile, for example, aluminum alloy (BP, AMts, AMG1-6);

- pressing crimping sleeve at the temperature of recrystallization of the alloy TN-1K (at 450 ° C);

- the annealed coupling is placed in a device for deformation, it is cooled to a temperature below the direct martensitic transformation of the TE-1K alloy, pouring liquid nitrogen into it (T -196 ° C); install the device in a hydraulic press and distribute the coupling diameter. After dispensing prior to the assembly process, the coupling must be in the martensitic state (in this case in liquid nitrogen);

- set the cooled clutch on the hermetic junction housing with a ceramic diaphragm installed inside it;

- heat the assembled unit to a temperature above the threshold for the reverse martensitic transformation of the TN-1K alloy, but below its recrystallization temperature (in this case, to room temperature), and the coupling remembers the original shape and compresses the joint.

Claims (1)

 Invention Formula A method of manufacturing a sealed unit of a microwave waveguide, which includes installing a ceramic diaphragm into a housing and sealing it by crimping the housing, characterized in that, for the sake of simplicity, the housing is made of a ductile alloy, and the sealing is performed by crimping a sleeve of an alloy that has a thermomechanical memory, the inner diameter of which is less than the outer diameter of the housing, while prior to installing the ceramic diaphragm into the housing the crimping sleeve is annealed at the temperature of the alloy recrystallization, cooled to perature below the temperature direct martensitic transformation, manufac t distributing the cooled crimping coupling to a diameter larger than the outer diameter of the housing; after installing the ceramic diaphragm, the cooled crimping coupling is placed on the housing and heated to a temperature exceeding the threshold of the reverse crimping coupling, but below its recrystallization temperature.