SU306395A1 - DEVICE FOR DETERMINATION OF DENSITY OF SOLID BODIES - Google Patents

Description

The invention relates to devices for carrying out a physicochemical analysis.

A device for determining the density of solids and liquids is known, which contains a laterally insulated central heat-conducting rod with a longitudinal viewing groove and an internal cavity filled with liquid into which floats are placed, two chambers into which the ends of the rod are pumped and through which thermostatic liquid of different temperature is pumped .

The proposed device makes it possible to increase the measurement accuracy due to the fact that thermally conducting security cylinders equipped with thermal insulation are installed to a coaxially heat-conducting rod, and the ends of the rod and security cylinders are fixed in a heat-conducting ring disk.

Pa drawing presents the proposed device.

The device contains a central cylindrical rod 1 with an internal longitudinal groove 2, sealed with a glass cylinder 3. The rod ends exit into chambers 4 and 5, each of which is equipped with two olives b and 7. The cylinders 8 and 9 are located coaxially with the rod. Outside the cylinder 9 and between the cylinders 8 and 9 there are layers of thermal insulation 10 and / L covering i.h.

The tread surface, except for the part in which the viewing longitudinal grooves 12 and 13 are made, is sealed with transparent prisms 14 and 15. The device together with the reading device 16 is rigidly mounted on the base / 7. Chambers 4 and 5 are thermally insulated from the outside by covers 18 and 19. Tubes 20 and 21 are connected to well 2, with a tap 22 on tube 21.

The device works as follows.

A thermostatic fluid having a temperature Gf from the ultrathermostat (not shown in the drawing) is fed into the chamber 4 through one of the olives 6, washes the upper ends

and, then, returns through the second olive 6 to the ultra-thermostat. From the second ultrathermostat (not shown), a thermostatic liquid of lower temperature T2 () is fed into chamber 5 through one of the olives 7, washes the lower ends of the heat-conducting cylinders /, S and 9 and returns through the second olive 7 to its thermostat. The temperature of the ends of the rods /, 5 and

9 with fluids of various temperatures F and, with a certain geometry, leads to a linear temperature distribution along the rod 7, which is then transmitted to the analytical fluid filling slot 2.

In this case, a vertical density gradient appears downward. Samples (or standard nodes) 23, whose density has a value lying between the density values of the upper and lower layers of the analytical fluid, placed in it and indiderent to it, occupy stable positions at altitudes where their density is equal to the density of the analytical fluid. Stable equilibrium positions are fixed with the aid of a readout device 16 and unambiguously determine the density of the samples or liquid. Samples 23 and the assay fluid are introduced into the groove 2 through the tube 20, and are inserted through the tube 21.

The uncontrolled heat exchange between the rod / and the external medium in the device is almost completely eliminated due to the protective shielding effect of the cylinders S and 5.

Since cylinder 9 is in conditions close to those in which cylinder was located in the absence of cylinders 8 and 9, a longitudinal temperature distribution is formed in it. The presence of thermal contact with the ends of the cylinders 8 and 9 causes the amount of heat exchange between the side surfaces of the cylinders 5 and 5 to be determined by the temperature difference, which does not exceed the temperature difference in the cylinder 9 relative to the case of a linear temperature distribution in it, since the deviation from the linearity of the temperature in the cylinder 8 only reduces this difference. Therefore, the degree of approximation to the linearity of the temperature distribution along cylinder 8 is much higher than that along cylinder 9, and along cylinder I is much higher,

along cylinder 8, in cylinder 1 protected by cylinders 8 and 9, one observes a closer (by several orders) approximation to a linear temperature distribution than in the same cylinder / unprotected.

The described device allows to increase the measurement accuracy by more than an order of magnitude. The remaining characteristics of the instrument are as follows: in rapid analyzes, the measurement time does not exceed 5–10 min, the number of samples for analysis is. The simultaneous measurement of many samples and the graduation of the scale in terms of density are possible.

Subject and reference of FI and

A device for determining the density of solids and liquids containing a heat-conducting rod equipped with a longitudinal m observation groove and an internal cavity filled with a liquid with a float placed on it, two chambers, located at the ends of the rod and connected to the station, a reading device, characterized by the fact that, in order to improve the accuracy of measurements, heat-conducting security cylinders fitted with ten-insulation, with the ends of the heat-conducting rod and security cylinders, are installed coaxially to the heat-conducting rod. ukreplen15 | in the heat pipe weir ring disk.

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