SU814A1 - Gas Absorption Vessel - Google Patents

Description

When analyzing gases using analyzers, for example, using an Ors device, absorbing vessels are used, which should be designed to bring the gas into contact with the larger surface of the absorbing liquid. Glass tubes placed in this vessel are used for this; when gas enters, it is in contact with the liquid adhering to the inner and outer surfaces of the tubes, so the contact area will be increased many times. Similarly, devices are used to pass gas by bubbles through a layer of liquid, whereby all the existing samples have bubbles only when the gas enters the absorbing vessel. In the proposed absorption vessel, bubbles are formed both when the gas enters the vessel and when it is removed from there. In addition, by a corresponding reduction in the orifice of the tubes, it is possible to obtain bubbles of small diameter, which, firstly, increases their total gas contact surface.

with the liquid, and secondly, the speed of their lifting decreases, and therefore the time of contact increases.

The cross-section absorbing siphon (siphon) shown in the sectional drawing consists of two parts 1 and 3, connected at the bottom by a tube 2. The knee of the siphon 1 is divided by a partition 5 with a small hole. B arranged so that the gas can pass from bottom to top through hole b and nowhere stagnates in the form of bubbles. A partition 5 is injected into the tube 7, which has a bend 8 in the upper part, which serves to direct the liquid rising through this tube to the walls of the vessel 1 and prevent the reagent from entering the upper tube 4. The lower part of the tube 7 is provided with a small opening 9.

According to the author's assumption, the work in the absorption vessel is performed according to the following scheme:

Before the start of absorption, all knee 1 and tube 7 are filled with reagent, and in knee 3, the liquid is low over trestle 2. Then gas is injected through trough 4 into the upper part of knee 1.

Then the liquid from it enters the lower part through the hole b and through the tube 8.7 and hole 9. So it happens that the liquid does not reach the lower edge of the upper hole of the tube 8. After that, gas will flow into the tube 8.7 which gradually fills it all up, and then, having reached the opening 9, in the form of bubbles will rise in the lower part of the track 1, forming the second level of the liquid there. All this time there will be a lowering of the level in the upper part of the knee 1, and since the fluid passes through the hole 6 all the time and the fluid passes through the hole 9: the first time there was liquid and then gas flows, a significant part of the latter will be transferred to the lower part knee 1, and under the hole 6 there will still be a fairly thick layer of reagent. Then comes the discharge of gas from the vessel and, mainly, from the bottom of the knee 1; it is removed through opening 6 by small bubbles through a layer of reagent (secondary action). When the whole

the gas from the bottom will be removed, or it will again be sent to the bottom, as indicated above, or, if the absorption is already completed, raise the fluid level above tube 4 and bring it to the mark, as is usually done.

Due to the high resistance during the passage of fluid through the holes 6 and 9, the level of the mark is brought quite slowly and, therefore,}, the danger of fluid penetration beyond the mark is greatly reduced.

PROPOSED PATENT.

An absorption vessel for analyzing gases, in the form of a double-knee siphon, characterized in that the vessel 1 forming one of the knees of the siphon is divided in height by a partition 5 into two parts communicating between itself through the opening 6 in the partition and through the tube 7 into the partition. with the bottom 9 deflected and the top 8 curved.