RU2090257C1 - Carbon dioxide absorbent - Google Patents

Abstract

FIELD: gas absorbents. SUBSTANCE: solid chemical carbon dioxide absorbent that may be utilized in purification means for breathing gas media contains 75-82 wt % lithium hydride and 18-25 wt % asbestos. EFFECT: increased stoichiometric absorption capacity. 1 tbl

Description

The invention relates to solid porous chemical CO ₂ absorbers that can be used in purification of a respiratory gas medium in ecologically closed volumes, as well as in diving breathing apparatus.

Known absorbers of carbon dioxide based on oxides and hydroxides of alkali and alkaline earth metals, characterized by a low stoichiometric capacity for CO ₂ [Melnikov A. Fundamentals of chemisorption. M. -L. Oborongiz, 1938, p.142]
The disadvantage of such absorbers is their low kinetic characteristics.

Known absorbent CO ₂ containing lithium hydroxide 85-90 wt.% And calcium hydroxide 10-15 weight. [TU6-16-24-97-81, TP VT347-81] Its stoichiometric capacity is 467 lCO ₂ / kg, the degree of working off is 0.32.

 The disadvantages of this absorber is its low chemical characteristics, lack of mechanical strength.

Closest to the invention, the achieved result is a CO ₂ absorber containing asbestos and an alkali metal compound [UK patent N 1361913, CIA, 1974, prototype] Sodium hydroxide was used as the alkali metal compound. Its stoichiometric capacity was 280 lCO ₂ / kg.

The disadvantages of this absorber are its low kinetic characteristics, significant hygroscopicity and a low degree of development of CO ₂ .

The objective of the invention is to provide an absorber with a high stoichiometric capacity and a degree of CO ₂ exhaustion, as well as low hygroscopicity and the ability to compensate for gas losses during operation.

This goal is achieved in that in the CO ₂ absorber containing asbestos and an alkali metal compound, according to the invention, lithium hydride is contained as an alkali metal compound in the following ratio of components (wt.):
lithium hydride 75-82
asbestos 18-25
The technical result that is obtained by the implementation of the present invention is to obtain a high-capacity CO ₂ absorber. The absorption process of the proposed absorber can be represented by the following equation:
2LiH + CO ₂ + 2H ₂ O _ → Li ₂ CO ₃ + 2H ₂ + H ₂ O
Hydrogen released can be used to form hydrogen-containing DHAs in diving breathing apparatus, as well as to compensate for H ₂ leaks in the life support systems of diving pressure chambers.

The proposed absorber was obtained as follows. Lithium hydride was ground and sieved. A powder with a particle size of less than 300 microns was mixed with asbestos fiber, followed by formation on the press. The pressing pressure was 1040 kgf / cm ² . Pressed at various ratios of lithium hydride asbestos, the samples of the absorber in the form of tablets with a diameter of 5 mm and a height of 2 mm were tested for CO ₂ activity in a dynamic tube under the following conditions: temperature 20 ^° C, relative humidity 98%, specific gas flow rate through the absorber layer 0.5 l / min. cm ² , the pressure of the gas medium 0.1 MPa.

 The test results are presented in the table.

For comparison, a CO ₂ prototype absorber was prepared. For this, sodium hydroxide was crushed, mixed with a small amount of asbestos and pressed.

 The test results of the prototype sample are presented in the table.

As can be seen from the data given in the table, the samples of the absorber obtained by the claimed composition (examples 1-4) have a high stoichiometric capacity and the degree of development. Throughout the entire time of work, the samples retain their shape. Absorbent samples containing less asbestos (Example 5) are completely destroyed. The destruction of the sample leads to its melting and crystallization due to the interaction of the resulting LiOH with CO ₂ and H ₂ O, which increases the resistance to the gas flow and, thus, makes it difficult or completely stops the diver's breathing. Absorbent samples containing more asbestos (for example 6) swell rapidly, increasing in volume by 2.5 times. Swollen samples sharply increase the resistance to a single flow and completely stop the diver's breathing.

 The prototype absorber (Example 7) is characterized by a significantly lower stoichiometric capacity by 3 times, as well as a lower degree of processing by 2.8 times.

Thus, the proposed CO ₂ absorber is characterized by a high stoichiometric capacity, a significant degree of processing, low hygroscopicity, and the ability to compensate for gas losses due to the release of H ₂ . In addition, when CO _{2 is} absorbed by the claimed absorber in the presence of moisture, a large amount of heat is released, which can be used to heat DHS.

Claims (1)

 A carbon dioxide absorber containing asbestos and an alkali metal compound, characterized in that it contains lithium hydride as the alkali metal compound in the following ratio, wt. Lithium Hydride 75 82
Asbestos 18 25v

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