SU1158897A1 - Device for determining density of metal melts - Google Patents

Abstract

A device for determining the density of metal melts containing a two-capillary vacuum pycnometer, distinguished by the fact that, in order to improve the efficiency of determining the density of metal melts of various concentrations, it is equipped with a second vacuum two-capillary pycnometer, while the adjacent capillaries of the pycnometer are located in the center of the pycnometer, there is a hole in the center of the pycnometer, and there is a hole in the center of the pycnometer, and the pycnometer has a second vacuum two-cap pycnometer, while the adjacent picnometers are located in the center of the pycnometer, and the pycnometer is located in the center of the vacuum pycnometer, and the adjacent vacuum capnometer pycnometer is located at the distance of the pycnometer, and the pycnometer has the second vacuum pycnometer, the adjacent picnometer is located in the center of the pycnometer, and the pycnometer meter is located in the center of the vacuum pycnometer. planes and are connected between a cot5o tube located above the graduated part;

Description

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The invention relates to the measurement of the density of liquids and can be used to determine the concentration dependence of the density of metal melts.

A device is known for determining the concentration dependence of the density of metal melts prepared without disturbing the vacuum insulating shell using the areometer ll.

The disadvantages of this device are relatively low measurement accuracy, inherent in areometric methods, high metal consumption and a limited range of concentrations studied after one filling.

Closest to the technical essence of the present invention is a device for determining the density of metal melts, containing a two-capillary-vacuum pycnometer 2.

The drawbacks of the device are the complexity and laboriousness of determining the density of metal melts of various concentrations without disturbing the vacuum insulating cap, since the density determination of melts of various concentrations is made using repeated filling of the pycnometer with melts of various concentrations.

The purpose of the invention is to increase the efficiency of determining the density of metal working mixtures of various concentrations. The delivered value ay is achieved by the fact that a device for determining the density of metal melts containing a two-capillary vacuum pycnometer is equipped with a second two-capillary vacuum pycnometer, with adjacent capillaries}) pycnometers being located at. one vertical plane and interconnected by a tube located above their graduated part.

In the drawing. The scheme of the proposed device -

Two two-capillary vacuum pycnometers consisting of lower tanks 1 and 2, capillary tubes 3-6 with labels 7 and 8 affixed to them, upper tanks 9 and 10, and tubes 11 and 12 that serve to fill the device are connected to a tube 13, The tube 13 and the capillary tubes 5 and 6 that it directly connects lie in a plane closer to the observer than the 5 plane in which the capillary tubes 3 and 4 lie. Capillary 4 is located to the right of capillary 6, and capillary 3 5 seconds to the left of the capillary. point of view of the observer. Each O of the two pycnometers constituting the device is pre-calibrated in volume with respect to marks 7 and 8, the connecting tube 13 is located above the graduated portion of 5 capillaries 5 and 6,

The device works as follows.

After preliminary thermal vacuum treatment, the left pycnometer 0 is filled with one melt, and the right one with another melt, and the device is sealed from the vacuum unit. Here melts are components of the liquid metal system under study. The masses of each of the components of the melts contained in the device are known. The device is placed in a thermostat with viewing windows. The device in the thermostat is attached to the 0 frame (not shown), which allows the device to rotate around the X-X and Y-Y axes. The Y-Y axis is perpendicular to the plane of the drawing.

Measuring with the help of a cathetometer from the level of the liquids liquids relative to marks 7 and 8, the volume occupied by the melts is determined. Knowing their masses, determine the density. Then the tilt of the device, for example, in a 0-hour hand around the axis YY, is poured over the tube 13 part of the melt from the left pycnometer to the right.

To speed up the homogenization of the melts, the device is tilted around the S axis X – X and, returning it back, transfer the melt through the capillary tubes 3 and 4 from the lower tanks 1 and 2 to the upper 9 and 10 and vice versa. The location of the capillaries 5 and 6 and the tube 13 in the plane which in the drawing lies closer to the observation than the plane parallel to it in which the capillaries 3 and 4 lie, makes it possible to carry out procedure 5 of homogenization by moving so that the capillaries 5 and 6 were not filled with metal tilted around the axis X-X and, consequently, not

uncontrollable displacement of melts occurring in different pycnometers through tube 13 occurred.

At the end of the homogenization, the surface levels of the melts in the capillaries of the pycnometers are measured with reference marks 7 and 8. For these data,. calculate the decrease in the volume of the melt in the left pycnometer and the volume of the melt in the right pycnometer. Knowing the density of melts in pycnometers before overflow, the mass loss in the left 11knomet and the mass of the melt in the right pycnometer are determined. Then calculate the density of the solution formed in the right pycnometer. Knowing the compositions of the melts in pycnometers and the melt transferred from the left to the right, the composition of the solution formed in the right pycnometer is calculated.

By tilting the device counterclockwise around ocHY-V, a part of the melt is transferred from the right picnicmeter to the left. Next, the same

operations, as in the previous transfusion, only the right and left pycnometers change roles.

In this way, the concentration flux of the density varies over the entire concentration range of the melt until the compositions in both pycnometers approach each other. For all overflows, it is necessary that the LEVELS of the melts in the measurements be in the graduated part of the capillaries.

The use of the proposed device allows one to investigate the density of metal melts in vacuum over the entire concentrated interval after one filling of the pycnometers with the original metal components, which increases the control efficiency, and the accuracy of measurements depends only on the accuracy class of the pycnometers used. In addition, the consumption of the metals studied is reduced.

Claims (1)

DEVICE FOR DETERMINING THE DENSITY OF METAL MELTS, containing a two-capillary vacuum pycnometer, characterized in that, in order to increase the efficiency of determining the density of metal melts of various concentrations, it is equipped with a second vacuum two-capillary pycnometer, with adjacent capillaries a vertical plane and interconnected by a tube located above their graduated part; SP QO 00 with m>