RU2536798C2 - Self-levelling device to investigate surface phenomena, wetting and spreading under heating in vacuum and inert or active gas media - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: invention relates to gyroscopic devices. It may be preferably used to investigate surface phenomena of wetting and spreading under heating in vacuum and inert or active gas media. A self-levelling device includes a body 1, made from ceramics, molybdenum or steel, in the upper part of which an intermediate element 2 is installed, made of the same material as the body 1 or differing from it, fixed by two rods 3 to the wall of the body 1, a self-levelling table 4, made of the same material as the body 1 or differing from it, in the lower part of which there is a massive weight 5, which may be made as detachable and be connected via a connection rod 6; the self-levelling table 4 is fixed by two rods 7 in the intermediate element 2, besides, rods 3 and 7 are located mutually perpendicularly to each other. In the lower part of the body 1 there are stops 8 to fix the massive weight 5.

EFFECT: device makes it possible to carry out investigation while it is placed in a furnace with a controlled atmosphere and in a furnace with air heating.

9 cl, 2 dwg

Description

The invention relates to gyroscopic devices. It can be mainly used to study the surface phenomena of wetting and spreading when heated in vacuum and inert or active gas environments.

A gyroscopic device is known, comprising a base 1 with a support 2 for an axis three and a rotor 4 located on the axis, which has the ability to maintain the direction of the axis line 0-0 of its own rotation ω. The gyroscopic device can be used mainly on vehicles, in particular, containing gyroscopes with massive rotors. Rotors 5A and 5B with opposite directions of rotation are placed sequentially along the line OO of the axes on the axes 4A and 4B, connected to the side supports 2A and 2B and a common central support 3. Each of the rotors is located asymmetrically on its axis relative to the supports of the axis with a smaller distance from each of rotors to the central support in comparison with the distance from each of the rotors to the lateral support of the axis. In this case, the gyroscopic forces act on the central support jointly in one direction from the side of both rotors, and the gyroscopic force acts on each of the lateral supports only from the side of one of the rotors. The invention allows to expand the scope of the gyroscopic device (RF patent No. 2390725).

The disadvantage of the analogue is the inability to use methods for studying surface phenomena (wetting and spreading) when placing the device in a furnace with a controlled atmosphere (vacuum oven, container), placed in an air-heated oven or oven with a temperature of 50 to 400 ° C.

A device for determining the surface tension and contact angles of wetting of metallic fluids. The installation consists of a vacuum chamber 1, 2 — an oven, 3 — a steam-oil pump, 4 — a fore-vacuum pump, 5 — a lens, 6 — a cassette part, 7 — springs, 8 — a metal sample on the test substrate, 9 — successive samples, 10 — a bellows 11 - a vacuum valve, 12 - a reservoir for purified inert gas, 13 - a horizontal rod, 14 - a quartz prism or a mirror, 15 - a capacitor, 16 - a illuminator, 17 - a vertical rod. Leveling was carried out by means of springs (Contact phenomena in metal melts. Yu.V. Naidich, Naukova Dumka, Kiev - 1972, p. 45).

The closest in technical essence and the achieved result is a setup for studying the kinetics of spreading, consisting of: 1 - a vacuum chamber, 2 - monometric lamps, 3 - nozzles with flanges, 4 - steel plates, 5 - frame, 6 - shock absorbers, 7 - screw support, 8 — resistance furnace, 9 — measuring cell, 10 — illuminator, 11 — telephoto lens, 12 — three mirror system, 13 — photographic plate, 14 — movie camera. This device was horizontal by aligning the screw supports (Research methods and properties of the interfaces of the contacting phases. "Naukova Dumka", Kiev - 1977, p. 54).

The analogue and prototype have the disadvantage of not being able to use methods for studying surface phenomena (wetting and spreading) when placing the device in a furnace with a controlled atmosphere (vacuum oven, container), placed in an air-heated oven or oven with a temperature of 50 to 400 ° C , as well as the fact that leveling is carried out completely throughout the installation.

The objective of the invention is to develop a self-installing device that allows research when placing the device in a furnace with a controlled atmosphere (vacuum oven, container), placed in an oven with air heating.

The problem is solved in the proposed self-installing device, including a housing, in the upper part of which an intermediate element is mounted, fixed by two rods to the wall of the housing, a self-installing table, in the lower part of which there is a massive load, the table is fixed by two rods in the intermediate element, and the rods are located mutually - perpendicular to each other, and in the lower part of the body there are stops for fixing a massive load.

It is advisable to carry out the housing, the intermediate element and the table in the form determined by the shape of the furnace or container.

It is advisable to carry out the case from ceramics, molybdenum or steel.

It is advisable to make the intermediate element of the same material as the housing or to differ from it.

It is advisable to make a self-leveling table of the same material as the case or to differ from it.

It is advisable to make rods for fixing the elements of the device from a more heat-resistant material and a low coefficient of friction than the material from which these elements are made.

It is advisable to carry out a massive load of the same material as the body or differ from it.

It is advisable to carry out a massive load removable.

It is advisable to connect a massive load with a self-leveling table through a connecting rod.

The housing, the intermediate element and the table perform any shape determined by the shape of the furnace or container. For example, in the case of using the device in a square container, it is advisable to produce a square-shaped device for the greatest placement of the test samples on the surface of the table. In the same way, if the furnace has a circular shape, it is advisable to produce a device of a circular shape.

The case, an intermediate element, a self-leveling table, a massive load can be made of ceramic, molybdenum or steel. The material is selected depending on the temperature regime of the studies of surface phenomena.

Options for combining the performance of these elements of the device from different materials can be excellent, in order to save expensive material.

The device allows you to study the processes of wetting and spreading when heated in vacuum and inert or active gas environments at temperatures up to 1500 ... 2000 ° C.

Massive cargo is removable and connected through a connecting rod in order to conveniently replace the table and save in case cargo is made of expensive material.

The table is attached to the intermediate element using two rods located on the same axis. The intermediate element is attached to the housing in the same way, but the rods are located on an axis perpendicular to the first axis. Since the rods are located on two intersecting axes, they allow the load to adjust the position of the table in two planes. The table takes a horizontal position due to the severity of the massive load and the rods installed in this way.

A self-leveling device can be placed in a furnace, an oven, a vacuum furnace, the base of which is not horizontally aligned and does not require leveling of the entire installation in which it will be located.

This device can be used in any gaseous media and temperatures.

The rods for fixing the elements of the device are made of a more heat-resistant material with a low coefficient of friction than the material from which these elements are made.

The invention is illustrated by drawings.

In Fig. 1 - a general view of the device is round; Fig. 2 is a top view.

Self-housing device includes a housing 1 made of ceramic, molybdenum or steel, in the upper part of which an intermediate element 2 is installed, made of the same material as the housing 1 or different from it, fixed by two rods 3 to the wall of the housing 1, a self-mounted table 4 made of the same material as the housing 1 or differing from it, in the lower part of which there is a massive load 5, which can be removable and connected via a connecting rod 6; self-leveling table 4 is fixed by two rods 7 in the intermediate element 2, and the rods 3 and 7 are located mutually - perpendicular to each other. In the lower part of the housing 1 there are stops 8 for fixing a massive load 5. In Figs. 1 and 2, the positions 9 indicate the sample weights and the position 10, the plates of the material under study.

The housing 1, the intermediate element 2 and self-mounted table 4 are made in the form determined by the shape of the furnace or container.

The device operates as follows.

On the surface of the self-leveling table 4 (Fig. 1, 2), plates 10 of the test material are placed, on the surface of which samples of samples 9 are placed. Table 4 is fixed in the intermediate element 2 with two rods 7 located on the same axis, installed in the upper part of the housing 1, and fixed with two rods 3 to the wall of the housing 1. The device is placed in the furnace and the supports 8 are removed, which are necessary in case of performing a massive load 5 of brittle materials (molybdenum, ceramics) to prevent chips from accidental impact, and connected to izontiruemym table 4 by a connecting rod 6.

Since the rods 3 and 7 are located mutually - perpendicular to each other on two intersecting axes, they allow the massive load 5, located at the bottom of the self-mounted table 4, to adjust the position in two planes, as a result of which the table takes a horizontal position.

Self-alignment ensures the formation after spreading of circles of a geometrically regular and constant shape, the area of which is easily measured, calculated when measuring the diameters of two mutually perpendicular directions. The latter circumstance provides a correct determination of the influence of temperature, the chemical composition of the contacting materials, and the activity of the gaseous medium.

After the study, the self-mounted device is removed from the furnace, cooled, and the stops are set 8. From the self-mounted table 4, plates 10 are removed from the test material, on the surface of which samples of samples 9 were placed.

The device is ready for further use.

The technical result is that the device allows you to conduct research when placing it in a furnace with a controlled atmosphere and in a furnace with air heating.

Claims (9)

1. Self-aligning device, comprising a housing, in the upper part of which an intermediate element is mounted, fixed by two rods to the wall of the housing, a self-installing table, in the lower part of which a massive load is located, the table is fixed by two rods in the intermediate element, the rods being mutually perpendicular to each other , and in the lower part of the body there are stops for fixing a massive load. 2. Self-aligning device according to claim 1, characterized in that the housing, the intermediate element and the table can be made in the form determined by the shape of the furnace or container. 3. Self-aligning device according to claim 2, characterized in that the housing is made of ceramic, molybdenum or steel. 4. Self-aligning device according to claim 3, characterized in that the intermediate element can be made of the same material as the housing or differ from it. 5. Self-installing device according to claim 4, characterized in that the self-installing table can be made of the same material as the case or differ from it. 6. Self-aligning device according to claim 5, characterized in that the rods for fixing the elements of the device are made of a more heat-resistant material with a low coefficient of friction than the material from which these elements are made. 7. Self-aligning device according to claim 4, characterized in that the massive load can be made of the same material as the body or differ from it. 8. Self-aligning device according to claim 7, characterized in that the massive load can be made removable. 9. Self-leveling device according to claim 8, characterized in that the massive load is connected to the self-leveling table through a connecting rod.

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