RU2558380C1 - Method of manufacturing of vacuum device, vacuum device casing, and vacuum chamber - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: device casing is located in the vacuum chamber on the holder with hole upwards, at that the hole axis is located vertically, and after device evacuation, and its degassing in the vacuum chamber the casing hole is sealed by the sealing material application on it, for example indium droplets. The vacuum chamber for the device manufacturing is equipped with the device for dosing supply of the sealing material, that contains cone cylinder, with sealing material, equipped with hole in bottom part and fixing element closing this hole. After warm-up the device is located under the device of the sealing material application, coinciding the casing hole axis with hole axis of the cone cylinder of the sealing material dosing device. The fixing element opens the hole, at that the dosed portion of the sealing material drips on the device casing hole under it, and securely seals it.

EFFECT: increased quality of manufactured vacuum device due to absence of the projecting parts on its casing, reduced labour intensity, and increased production effectiveness of the device.

7 cl, 2 dwg

Description

The invention relates to vacuum technology, and in particular to methods of manufacturing and sealing vacuum devices.

The most time-consuming, complex and responsible technological process, which forms the electrical and vacuum characteristics of all types of vacuum devices, is pumping. The vast majority of devices are pumped out through shtangels, which are sealed by cold welding (metal) and heat welding (glass) at low shell temperatures (compared to the degassing temperature). The soldering of the components of the device during tubeless pumping also leads to gas evolution and the deposition of metal from the solder on the elements of the internal reinforcement, which can cause leakages and breakdowns on insulators. In addition, cold-welded and soldered joints of instrument elements do not always withstand thermomechanical loads.

A known method of manufacturing photoelectronic devices and.with. No. 805858, 1979, according to which the arrangement of the nodes of the device is carried out in separate hermetically isolated volumes, equipped with individual pumping means and connected to each other by the transition compartment, after processing the nodes, one unit of the device is moved through the transition compartment to the joint with another node. The disadvantage of this method is the complexity of the equipment used, its high complexity, the difficulty of combining the photocathode with the housing of the device.

Closest to the claimed method, taken as a prototype, is a method of manufacturing a vacuum device (application for invention No. 94024573, 1996, the applicant of the Volga Research Institute), including the manufacture of the housing, installation of valves in the housing, pumping the device with heating in a vacuum chamber . Pumping of the vacuum device takes place through a plug. To do this, the device is hermetically connected through a plug to a vacuum pumping system, pumped out, degassed, after which the plug is soldered off (if glass) or "bites off" by cold sealing (if metal - from oxygen-free copper). At the same time, the walls of the ram are flattened, closing the hole. After removing the plug (glass or metal), part of the plug remains on the device, the larger the dimensions of the device, the greater the proportion of the plug remains on the device, which leads to the need for additional operations. In many cases, the remains of the plug on the device interfere, this problem is especially urgent for vacuum devices of small dimensions. In addition, when sealing metal plugs with cold welding by a welding machine and glass - fire gases from their material, gases are rapidly released that impair the vacuum in the device.

A known design of the housing of a vacuum device equipped with an opening (patent No. 2069916, 1991, patent holder of the Scientific Research Institute of Measuring Systems), this decision is taken as a prototype. According to the known solution, a heat-insulating groove is made coaxially with the hole on the outer surface of the device body, which prevents the case from deforming when the hole is sealed with a laser by providing conditions for the collar material that limits the groove to melt by the laser beam energy and to prevent cracking. However, when performing sealing in this case, the laser beam passes through the gas inlet opening into the device body, which leads to damage to the electronics and protective organic coatings located under it. To exclude this microplate in the device’s housing is placed so that they are not under the gas inlet. This does not allow full use of the internal volume of the housing.

A known vacuum chamber (patent No. 2505883, 2012, patent holder of FSUE NPP Istok), comprising a housing, a pumping system, a holder for placing the workpiece and a heating device. This solution is taken as a prototype. The disadvantages of the known solution are that the device holder is mounted on the tabletop, without the possibility of movement, and the vacuum device is also pumped out via a plug, followed by sealing of the device by means of a cold tap of the plug.This solution has all the disadvantages described above Use the exhaust tube.

The objective of this solution is to improve the quality of the vacuum device, as well as reducing the complexity and improving the manufacturability of its manufacture.

This goal is achieved due to the fact that in the known method of manufacturing a vacuum device, including the manufacture of the housing, mounting the fittings in the housing, pumping the device with heating in the vacuum chamber and sealing the device in the vacuum chamber, for which the housing of the device is placed in the vacuum chamber on the holder with the hole up while the axis of the hole is vertical, and after pumping the device and degassing it in a vacuum chamber, the hole in the housing is sealed by applying a sealing material on it for example, drops of indium, while the device is placed in a vacuum chamber on the holder, and after pumping, the device is moved under the heating device, then under the device for applying the sealing material, combining the axis of the opening of the device body with the axis of the conical cylinder opening of the metering device for the sealing material.

This goal is achieved due to the fact that in the known case of a vacuum device equipped with an aperture, the edges of the apertures are conical, with larger outer and smaller inner diameters, the walls of the apertures are coated with a layer of gold, silver or copper for better adhesion of the sealing material, and the apertures are made with a diameter of 0.3 mm to 5 mm and a mesh with a pitch of not more than 0.5 mm can be installed on the hole on the inside.

This goal is achieved due to the fact that the known vacuum chamber for manufacturing a vacuum device, comprising a housing, a pumping system, a device holder and a degassing device, is additionally equipped with a metering device for supplying sealing material made in the form of a conical cylinder equipped with an opening in the lower part, in the conical cylinder there is a fixing element covering the hole and made with the possibility of movement, for example, by means of an electromagnetic drive.

The technical result provided by the claimed combination of features is expressed in improving the quality of the manufactured vacuum device due to the absence of protruding parts on its body, which eliminates possible mechanical damage to the device case during its transportation and operation, which in turn ensures reliability and durability of the structure. The technical result is also expressed in reducing the complexity and improving the manufacturability of the manufacture of the device, due to the exclusion of operations associated with the need to remove the plug and subsequent cleaning of the protruding parts of it.

The opening on the device body with tapered edges, with a large outer and smaller inner diameters, as well as coating the walls of the hole with a layer of gold, silver or copper, ensure better adhesion of the sealing material and, accordingly, the sealing of the hole. For large diameter holes, a mesh with a pitch of not more than 0.5 mm can be installed on the inside.

The technical result is also achieved by the fact that the vacuum chamber is equipped with a metering device for the supply of sealing material, which contains a conical cylinder, with sealing material, provided with an opening in the lower part and a locking element closing this opening. After warming up, the device is moved under the device for applying the sealing material, combining the axis of the opening of the device body with the axis of the opening of the conical cylinder of the metering device for the sealing material. When the locking element is moved upward, for example, by means of an electromagnetic drive, the opening is opened. In this case, a metered portion of the sealing material flows out and “drips” into the opening of the device body located under the device. Sealing material fills a hole in the device body.

The claimed solution is illustrated by drawings, where

figure 1 shows a vacuum chamber;

figure 2 shows a device for the metered supply of sealing material.

The vacuum chamber for the manufacture of a vacuum device comprises a housing 1 with a window 2, a heating device 3 of the manufactured device 4, which is located on the holder 5, made with the possibility of movement around its axis. The vacuum chamber comprises a pumping system 6 and a metering device 7 for supplying a sealing material 11, for example indium. The device 7 is made in the form of a conical cylinder 8, provided with a hole 9 in the lower part, while in the conical cylinder 8 there is a locking element 10 that covers the hole 9 and is made with the possibility of movement, for example, by means of an electromagnetic drive 12.

In the manufacture of a vacuum device, a hole is made in the case with a diameter of 0.3 mm to 5 mm by glass blowing or drilling, depending on the material of the case. The location and size of the hole depends on the design of the device, while the smaller the dimensions of the device, the smaller the hole. The edges of the holes are tapered, with a larger outer and smaller inner diameters, and the walls of the holes are covered with a layer of gold, silver or copper for better adhesion of the sealing material. A mesh with a pitch of not more than 0.5 mm can be installed on the hole on the inside.

After manufacturing the housing and mounting the fittings, the housing of the device is placed in a vacuum chamber, on the holder 5, which rotates in a circle to move the housing of the device. The body of the device has a hole up, while the axis of the hole is located vertically. Turn on the pumping system 6 and pump out the device. After pumping, move the device 4 under the heating device 3 and produce heating (degassing) it. Then, the holder 5, turning, moves the device 4 under the device 7 for applying the sealing material, combining the axis of the hole of the device with the axis of the hole 9 of the conical cylinder 8. After setting the device in the desired position, by means of the electromagnetic drive 12, the locking element 10 is lifted, which opens the hole 9. When this leads to the leakage of a metered portion of the sealing material 11, which drips onto the opening of the device body located under the device, closing it, sealing it.

The use of the claimed technical solution provides an increase in the quality of manufacture of a vacuum device, as well as a decrease in the complexity and manufacturability of its manufacture.

Claims (7)

1. A method of manufacturing a vacuum device, including the manufacture of the housing, mounting the fittings in the housing, pumping with heating in the vacuum chamber and sealing the device in the vacuum chamber, characterized in that the housing of the device is placed in the vacuum chamber on the holder with the hole up, the axis of the hole being vertically and after pumping the device and degassing it in a vacuum chamber, the holes are sealed by applying a sealing material, for example, an indium drop, on it. 2. A method of manufacturing a vacuum device according to claim 1, characterized in that after pumping, the device is moved under the heating device, then it is moved under the metering device of the sealing material, aligning the axis of the opening of the device body with the axis of the opening of the conical cylinder of the metering device of the sealing material. 3. The housing of the vacuum device, equipped with a hole, characterized in that the edges of the holes are made conical, with a large outer and smaller inner diameters. 4. The housing of the vacuum device according to claim 3, characterized in that the walls of the hole are coated with a layer of gold, silver or copper for better adhesion of the sealing material. 5. The housing of the vacuum device according to claim 3, characterized in that the hole is made with a diameter of from 0.3 mm to 5 mm 6. The housing of the vacuum device according to claim 3, characterized in that a mesh with a pitch of not more than 0.5 mm is installed on the hole on the inside. 7. A vacuum chamber for manufacturing a vacuum device, comprising a housing, a pumping system, a device holder and a device heating device, characterized in that the device holder is movable, and the camera is further provided with a metering device for supplying sealing material made in the form of a conical cylinder equipped with a hole in the lower part, while in the conical cylinder there is a locking element covering the hole and made with the possibility of movement, for example, by means of electromagnetic drive.

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