SU1638111A1 - Process and apparatus for vacuum deaeration of liquid - Google Patents

Abstract

The invention relates to the study of the processes of deaeration of liquids and m. used for laboratory research. The purpose of the invention is to improve the accuracy of determining the kinetic characteristics of the deaeration process. Vessels (C) 1 and 2 are filled with the test liquid through pipe (P) 4 with a locking organ 5 with open shut-off organs 10 and 11. Then the tank 13 is filled with water through P 18 with the locking organ open 17. After closing the locking organs 10, 11, and 17 open the shut-off members 7 and 16 on the surge pipe 6 and through II 19 and the shut-off member 21 drain some of the water from the tank 13, creating a vacuum in C 1 and 2. From C 2, devices 22 are sampled for analysis gas concentration in the liquid. The level in C 2 is maintained by displacing a part of the liquid from C 1 to C 2 through pipe 3. Performing the upper section C 2 in the form of a horizontal cylinder makes it possible to reduce the change in level and pressure in C 2. 2 sec. f-ly, 1 ill. WITH/)

Description

The invention relates to the study of the processes of deaeration of liquids and can be used for laboratory research.

The purpose of the invention is to improve the accuracy of determining the kinetic characteristics of the deaeration process.

The drawing shows an installation diagram where the proposed method is implemented.

The installation contains two vertically mounted cylindrical vessels 1 and 2, the lower parts of which are interconnected by a pipeline 3 with a pipe 4 having a locking organ

5, and the upper - equalization pipe 6 with a locking body 7. The upper sections of the vessels 1 and 2 are also equipped with nozzles 8 and 9 with locking bodies 10 and 11, communicated with the atmosphere. The upper portion of the vessel 2 is made in the form of a horizontally located cylinder 12. The installation also contains a tank 13, the upper portion of which is provided with nozzles 14 and 15 with shut-off members 16 and 17, which communicate it with a balance pipe 6 and atmosphere. The lower portion of the tank has nozzles 18 and 19 with locking bodies 20 and 21 for the supply

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and drain the test liquid. Vessel 2 is equipped with liquid sampling devices 22 located at its height.

The method is implemented as follows.

Vessels 1 and 2 are filled with the liquid under study through pipe 4 with a locking organ 5 with open organs 10 and 11 connecting vessels 1 and 2 with the atmosphere. Then, water is filled in the container 13 by opening the locking bodies 20 and 17. After the container 13 is completely filled, the locking bodies 20 and 17 are closed. After settling of the test liquid in the vessels 1 and 2, they are disconnected from the atmosphere by closing the organs 10 and 11.

The creation of a vacuum in the vessels 1 and 2 is performed by draining the water from the tank 1 and 3, opening the locking bodies 16 and 21. At the same time, the required pressure is established in the vessels 1 and 2 by draining a certain amount of water from the tank 13. After a predetermined pressure has been reached, the closure body 16 is closed, and the container 13 is prepared for further work by re-filling it.

As a result of a change in the partial pressure above the interface in vessels 1 and 2, the process of liquid deaeration takes place, accompanied by a change in the concentration of the dissolved gas. To determine the velocity (kinetics) of the process of liquid de-aeration depending on the depth of its position relative to the interface, samples of the liquid are sampled for analysis through devices 22. To eliminate the effect on the decrease in liquid level 2 in the vessel and the depth of vacuum before starting The samples close the valve 7 placed on the equalization pipe 6. Closing it does not change the characteristics of the deaeration process in the vessels 1, 2 and, therefore, in their lower parts the concentration of gas in the liquid is the same. Simultaneously with sampling, the shut-off organ 10 of the vessel 1 is opened through the devices 22 and a part of the liquid is forced out of the latter into the vessel 2, maintaining a constant level and, consequently, the depth of vacuum in it.

Making the upper part of the vessel 2 in the form of a horizontally located cylinder allows for an increased cross-sectional area in it, which significantly reduces the level change during sampling.

Thus, this method and installation allows to obtain the kinetic characteristics of the deaeration process with high accuracy and using the results obtained to optimize the design and operating schemes of industrial deaerators.

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Claims (2)

1. A method of vacuum deaeration of a liquid for laboratory research conducted by reducing pressure in two interconnected vessels, characterized in that, in order to increase the accuracy of determining the kinetic characteristics of the deaeration process, the vessels are filled with the test liquid, they are evacuated, and a sample is taken from one of the vessels for different analyzes at a height the vessel, while maintaining the pressure and the level of the liquid in it continuously by displacing the liquid from the second vessel to the first, and the flow of liquid produced through the lower portions of the vessels. 2. An installation for vacuum de-aeration of a liquid for laboratory research, containing two vertically installed cylindrical vessels, the lower parts of which are connected between the pipeline with the nozzle having a closure member, and the upper ones with an equalizing pipe with the stop organ, while the upper parts of the vessels are provided with nozzles organs communicated with the atmosphere, as well as a container communicated with the indicated vessels, characterized in that the upper portion of the container is equipped with nozzles with shut-off organs; with the equalization pipe and atmosphere, and the lower with pipes with shut-off parts for supplying and draining water, the upper section of one of the vessels i made in the form of a horizontal cylinder one