SU284969A1 - The method of cleaning gases from carbon dioxide - Google Patents

Description

The invention relates to the field of absorption purification of the pelvis from carbon dioxide.

A completely absorption method for purifying gases from carbon dioxide is this. that, in the process of absorption of the biloca-CUYu carbon, the pacTBOip of the absorbent-ethanolamtena is divided into two streams, which are previously; In this case, one of the streams iodine the upper part of the regenerator and its output from the hygiene part of it, and the entry points of the second flow to the rasiuyuyu ras absorbent absorbent point of the partial fraction of the regenerating absorbent. However, this method is characterized by a low degree of solution regeneration and a high temperature in the upper part of the regenerator, leading to a lottery and heat from the steam pelvic mixture.

The proposed method differs from the known one in that the point of entry of the flow of the absorbent is located above the outlet of the regenerated absorbent. In addition, the saturated absorbent is divided into three or more flows before entering the regenerator. This increases the degree of regeneration of the thin-regenerated solution to 3 l of CO2 per 1 l of solution, i.e., three times as compared with the known method; at the same time heat consumption is reduced to

0.5-0.6-10 kcal per 1 g of CO2 and depending on specific conditions) as compared with 0.9-1.1-10 kk (l per 1 g of COO in the known method.

On the image of the scheme. {Implementation of the described method.

At m with r. Gas under pressure of 30 atm. containing 20% COO, is sent to the absorber Y, where it is washed with a 20% solution of monoethanolamine D).). Saturated to a COO concentration of 0.65.% CO2 / mol MEA, the solution is divided, for example, into three or more notes, at the top of the regenerator 2 nodayut 10% solution with a temperature of about 60 ° C. Regenerator pressure 1.8 atm. Somewhat lower than the upper flow entry points, 40% of the solution heated to 85 ° C with the waste regenerated solution is fed, and even lower than 50% with a temperature of 113 ° C. The points of introduction of streams are saturated: they are located above the outlet of the regenerated absorbent. Since the flow rate entered into the upper part of the regenerator is higher than the flow rate introduced into its middle part, a higher temperature is reached after the notes in the regenerator and, therefore, a deeper degree of regeneration without additional steam consumption (compared to with existing syosobom).

gps;) atom, pa is significantly reduced, i.e., heat loss with the gas mixture is reduced.

50% of the solution is regenerated to a concentration of 0.3 mol / mol CO molar, 1 Withdrawal from a regenerator with a temperature of 20 ° C and put into a heat exchanger. 3, and 50% of the flow is regenerated to 0.05–0.1 and injected at a temperature of 125–130 ° C in the lower part of the generator.

After using tenla of two notes of a regenerative-fired air heater in teloexchange 3, 4 1 J, they are at a temperature of 65-70 ° C. They are sent to 6 nl refrigerators where they are cooled to 30 ° C. After that, the more finely regenerated solution nap (equals the top of the Absorber for fine cleaning, and the coarsely regenerated solution) into the middle part of the absorber for the rough cleaning.

P r d d e m e and 3 o b e te n u

Claims (2)

1. Method of gas purification from two oxide 1. From 1: 1 by absorption of aqueous solutions of ethanolamines and saturation of the absorbent by separation of the latter into the regenerator; separate flows and heating them due to the heat of recurrent gas; There are no signs of heat that, with the aim of eni / kenn of heat consumption and increasing the degree of perenejiannn, the vanishing point of the abdominal airblock naicbimcu-iioro is higher than the regenerated: non-absorbent output point. 2. A soloor according to Claim 1, characterized in that the absorption of the absorbent is not rarely introduced into the regenerator into three or more streams. g I hLI