SU450979A1 - Instrument for bithermal isopystic measurements - Google Patents

Description

one

The invention relates to devices for isopiestic pressure measurements by the method of bithermal equilibrium.

A device for bithermal isopiestic measurements is known, comprising two connected in the upper part vertical vessels with thermostatic shirts and vacuum taps, a thermostat and a device for measuring temperature.

The aim of the invention is to simplify and accelerate measurements, as well as to increase the efficiency of the instrument.

The proposed device differs from the well-known in that it is equipped with a thermostat sensor and a vessel for a monometric liquid, connected to two vertical vessels using a tube with taps located in the lower part of the device 2a.

In addition, the thermostat sensor is made in the form of an i-shaped inverted vessel, equipped with a vacuum tap in the upper part, with the electrodes of the thermostat electric circuit placed on one of the sensor bends.

The drawing shows a diagram of the device.

The device consists of vertical vessels 1 and 2, equipped with thermostatic shirts 3, 4 and vacuum valves 5, 6, which serve to fill the vessel 1 with clean water,

and vessel 2 with the test solution and air removal from them.

Vertical vessels are tightly connected in the upper part of the tube 7, having a three-way vacuum valve 8 located in the middle of the tube. The vessel 9 with the gauge fluid and the thermostat sensor 10 are connected using tube I, having taps 12 and 13, with vertical vessels. The thermostat sensor is an inverted L / -o6pa3Hbui vessel having two elbows 14 and 15 with a 16p vacuum valve 17 thickening. In the elbow 14 there are electrodes 18 and 19 of the thermostat electrical circuit (not shown).

Iribor works as follows.

The taps 5, 6, 8, 12, 13, 17 are set to the "Open" position and, through the vessel 9, a heavy gauge fluid, such as mercury, is poured through the funnel with a long spout. As soon as the liquid level reaches about half the height of the lower thickenings 16 of the thermostat sensor 10, the taps 8, 5, 6, 13 are set to the “Closed” position. With a capillary funnel, through the valve 17, the thermostat sensor 10 is poured into the knee 14 with a heavy gauge fluid that conducts electrical current, for example, a concentrated solution of zinc chloride, and then the temperature control sensor 10 is supplemented with a light gauge fluid that does not conduct electrical current , for example, polymethylsiloxane. The valve 17 is closed, and the space under the valve must be filled with liquid as a whole.

Then the taps 5, 6, 13 are opened and under a small pressure from a pressure source (not shown in the drawing) mercury is pumped from vessel 9 into vessels 1 and 2 approximately to the mark "a and" b. The valve 13 is closed, and through the taps 5 and 6 is poured, respectively: in the vessel 1 - clean water, and in the vessel 2 - the test solution. At that, the valve 8 alternately connects with the atmosphere, the vessel 1, the vessel 2, so that the liquids completely fill the space under the valve 8, after which the valve 8 is set to the position “in”, and the valves 5 and 6 are closed. The vessel 9 is connected to a vacuum source (not shown in the drawing), and air is evacuated. Carefully open the valve 13 and allow the mercury to flow back into the vessel 9 until its level in vessels 1 and 2 takes the position “ai and” 6i, after which the valve 8 is set to the position “r” and equalize the pressure over pure water and the test solution . Crane 8 is returned to position “in, and crane 12 is set to“ Closed. Thermostatic jackets 3 and 4 of vessels 1 and 2 are connected to thermostats (not shown in the drawing), one of which maintains the desired temperature of the test solution, and the other regulates the temperature of water in vessel 1, so that the vapor pressure above liquids in vessels I and 2 is equal to.

Pressure equalization occurs automatically using a thermostat sensor 10 and a sensitive relay (not shown in the drawing). If the vapor pressure above the test solution in vessel 2 is less than the vapor pressure above pure water in vessel 1, the interface between the liquids in the thermostat sensor 10 takes a position above the electrode 18, and an electrical circuit occurs

chain, lead it to the relay, which turns off the heater, thermostatic with the help of the jacket 3, vessel 1, as a result, the temperature of the water and pressure above it in vessel 1 decreases. The interface between the liquids in the thermostat sensor 10 will take a position below the electrode 18, an electrical circuit will break leading to a relay that turns on the thermostat heater, and the water temperature and pressure above it in the vessel 1 will increase.

After equalizing the pressure, the temperature of water in jackets 3 and 4 and vessels 1 and 2 will be measured. Then, according to the tables of the dependence of water vapor pressure on temperature, the water vapor pressure is determined at the measured temperature and, therefore, above the solution at a given temperature.

Subject invention

Claims (3)

1. A device for bithermal isopiestic measurements, containing two, connected in the upper part, vertical vessels with thermostatic shirts and vacuum taps, a temperature controller and a temperature measuring device, characterized in that, in order to simplify and speed up the measurements, as well as increase the efficiency the device, it is equipped with a thermostat sensor and a vessel for gauge fluid, connected to two vertical vessels with a tube with taps located in the lower part of the device. 2. Instrument no. 1, characterized in that the thermostat sensor is made in the form of a 7-shaped inverted vessel, equipped in the upper part with a vacuum valve. 3. Apparatus according to claim 2, characterized in that electrodes of the thermostat electric circuit are placed on one of the sensor knees.