RU2303747C2 - Device for removing carbon dioxide from flue gases - Google Patents

Abstract

FIELD: heat power engineering.

SUBSTANCE: device comprises transient gas duct provided with a port in its bottom, housing that abuts against the gas duct and receives heat exchanger, fluid distributor, and absorption unit that ended with pockets for collecting saturated absorbent and is provided with distributing chutes. The side walls of the desorption-cooling section are provided with horizontal slots covered from inside with horizontal sloping shutters and abut against the vertical exhaust passages with perforated bottom and exit that is connected with the top section of the transient gas duct.

EFFECT: enhanced efficiency.

1 dwg

Description

The present invention relates to a power system and can be used in the processes of purification and utilization of flue gases from power plants to reduce the greenhouse effect of the surrounding atmosphere.

A device for producing carbon dioxide from exhaust gases is known, comprising a housing, inside of which there is a heat exchanger and an absorber located outside the housing, a stripper with a boiler in the lower part, a refrigerator cooled by a stream of outdoor air supplied by a fan [1].

The disadvantages of the known device include complex hardware design, non-compact placement of equipment and the inability to use it to clean flue gases from carbon dioxide of powerful heat power plants, which reduces the reliability and efficiency of the device.

Closer in technical essence to the present invention is a device for separating carbon dioxide from flue gases, containing a transit duct, in the bottom of which there is a window connected to a vertical housing, inside which a shell-and-tube heat exchanger, a liquid distributor, and an absorption section filled with a nozzle with a large diameter are placed desorption-cooling section, filled with a nozzle with a small diameter, a suction umbrella connected to a fan and a desiccant, and a conical bottom orpusa connected via a circulating pump with liquid distributor pipes [2].

The disadvantages of the known device include the lack of redistribution of the saturated absorbent at the outlet of the absorption section, which entails a decrease in the density of irrigation in the central part of the desorption-cooling section, the absence of exhaust channels for the removal of lighter diatomic gases (N ₂ ) back into the transit duct, which creates back mixing of fresh flue gases falling down with lighter diatomic ones rising up, thereby reducing the absorption driving force, thereby lowering Xia mass transfer rate, decreasing the amount of absorbed carbon dioxide and the efficiency of the installation.

The technical result of the invention is to increase the efficiency of the process of purification of flue gases of thermal power plants from carbon dioxide.

The technical result is achieved in a complex device for cleaning flue gases from carbon dioxide and its utilization, containing a transit duct, in the bottom of which there is a window connected by the upper edge of the sides of the housing with a conical bottom, inside of which, from top to bottom, a heat exchanger, liquid distributor, absorption a section filled with a nozzle with a large equivalent diameter, the lower part of which is equipped with pockets for collecting saturated absorbent material connected to the distribution tray si, a desorption-cooling section filled with a nozzle with a small equivalent diameter, the vertical side walls of the absorption and desorption-cooling sections being provided with horizontal slots, horizontal sashes covered from above at an angle from the inside, and adjacent to vertical exhaust channels with a perforated bottom, whose mouths communicate with the upper zone of the transit gas duct, a suction umbrella connected to a fan and a dehumidifier, and the conical bottom of the body is connected by a pipe through a circulation pump with liquid distributor.

The work of the proposed device is based on: features of the composition of the flue gases of heat power units, the main components of which, based on experimental data and calculation of the composition of the products of combustion, are nitrogen (76-82)% vol., Carbon dioxide (7-14)% vol., water vapor (5-17)% vol., the concentration of which depends on the type of fuel and method of its combustion [3, p.15]; the excess of the solubility of carbon dioxide over the solubility of nitrogen in water is approximately 100 times [4, p. 316]; excess of carbon dioxide density over nitrogen density by 1.5 times, which stimulates the movement of carbon dioxide molecules under the action of gravity downward, and nitrogen molecules upward [5, p. 483]; the ability of gases to be desorbed from the absorbent with decreasing pressure in accordance with the laws of Henry and Dalton [6, p. 289]; a decrease in the temperature of the absorbent during its partial evaporation, similar to water cooling in a steam ejector refrigeration machine [7, p. 167]; a rigid dependence of the resistance of nozzle devices on the equivalent nozzle diameter and gas velocity [8, p. 491].

A comprehensive device for cleaning flue gases from carbon dioxide and its disposal is shown in the drawing.

The device comprises a transit gas duct 1, in the bottom of which a window 2 is arranged, connected by the upper edge of the body sides with a conical bottom 3, inside of which, from top to bottom, a vertical heat exchanger 4, a liquid distributor 5, an absorption section 6 filled with a nozzle with a large equivalent diameter are placed, pockets for collecting saturated absorbent 7, connected to distribution trays 8, desorption-cooling section 9, filled with a nozzle with a small equivalent diameter, with vertical side walls the absorption 6 and desorption-cooling 9 sections are equipped with horizontal slots 10, horizontal shutters 11 covered from above at an angle from the inside, and are adjacent to the vertical exhaust channels 12 with a perforated bottom 13, whose mouths 14 communicate with the upper zone of the transit gas duct 1, a suction umbrella 15 connected with a fan 16 and a dryer 17, and the conical bottom of the housing 3 is connected by a pipe 18 through a circulation pump 19 with a liquid distributor 5.

Cleaning flue gases from carbon dioxide and its disposal is carried out in the proposed device as follows.

Flue gases, the amount of which is due to the performance of the device, from the transit gas duct 1 through the window 2 under the influence of gravity enter the tube space of the heat exchanger 4, cooled, for example, by blast air or raw water, where it is cooled to a temperature of (60-70) ° С with the formation condensate flowing down the walls of the pipes and flowing together with the flue gases into the absorption section 6, filled with a nozzle with a large equivalent diameter, for example, 50 × 50 mm Rashig rings, where it mixes I recirculating the cooled absorbent liquid coming from the distributor 5, forming the absorbent a quantity sufficient to provide the necessary irrigation density spreads over the nozzle surface and selectively absorbs carbon dioxide from flue gas, simultaneously cooling them. Moreover, due to the presence of exhaust ducts 12 and the vacuum existing in them, due to communication with the upper part of the transit gas duct 1, most of the lighter non-absorbed nitrogen is sucked out through horizontal slots 10 into the vertical exhaust ducts 12 and then through the mouth 14 it enters the upper part of the transit gas duct 1, the inclined flaps 11 preventing the absorption of absorbent material into the vertical exhaust ducts 12, a smaller part of the remaining nitrogen due to its lower density compared to carbon dioxide and large from a nozzle absorption section 6 also rises in transit flue pipe 1, making room for the receipt of the transit duct 1 fresh flue gases and, thus, at a depth _H1 absorber section 6, which is selected according to the maximum saturation of the absorbent in accordance with the laws The absorption gas phase consists practically of one carbon dioxide. Then, under the influence of gravity, the saturated absorbent enters the collection pockets of the saturated absorbent 7 and trays 8, from where, together with carbon dioxide, it is lowered into the desorption-cooling section 9, filled with a nozzle with a small equivalent diameter, for example, 10 × 10 mm Rashig rings, whose height N ₂ is selected so that attachment layer could provide resistance sufficient to create a vacuum required for the desorption process most of the carbon dioxide from the rich absorbent and evaporated Nia Part of the absorbent, followed by cooling the absorbent. In this case, the removal of the remaining lighter nitrogen occurs similarly to its removal in the absorption section 6, and the size of the liquid layer h, which is formed due to the ingress of part of the absorbent from sections 6, 9 through horizontal slots 10 above the perforated bottom 13 of the exhaust channel 12, provides the necessary resistance, equal to the amount of vacuum created by the fan 16. The necessary amount of vacuum is provided by the operation of the suction fan 16, which through the suction umbrella 15 sucks desorbed carbon dioxide and water vapor from the lower part of the housing 3 and delivers the dried carbon dioxide through the dryer 17 to the consumer, and the regenerated and cooled absorbent is piped 18 through the circulation pump 19 to the liquid distributor 5, where it is mixed with fresh condensate, after which the cycle repeats, as a result of which purification of flue gases from the majority of carbon dioxide.

The obtained carbon dioxide can be used, for example, to restore the carbon dioxide balance in the cooling water of turbine condensers [9, p. 506] or as a commercial product, and excess recirculation condensate can be used for decarbonization in the process of water preparation [9, p. 406].

Thus, the proposed device provides an increase in the efficiency of the process of carbon dioxide emission from flue gases with their simultaneous utilization, using the heat of water vapor, and also reducing the threat of the greenhouse effect of the surrounding atmosphere.

Literature

1. A.S. USSR No. 339500, M.Kl. СВВ 31/20, 1972.

2. RF patent №2217221, M.Kl. B01D 53/14, 53/62, 2003.

3. N.V. Kuznetsov et al. Thermal calculation of boiler units (normative method). - M .: Energy, 1973, 296 p.

4. Handbook of a chemist, vol. III. - M. - L .: Chemistry, 1965, 1006 p.

5. K. Nenitsesku. General chemistry. - M .: Mir, 1968, 816 p.

6. A.N. Planovsky, P.I. Nikolayev. Processes and devices of chemical and petrochemical technology. - M.: Chemistry, 1972, 496 p.

7. A.I. Azarov and others. Refrigeration machines. Directory. - M .: Easy. and food. prom., 1982, 220 p.

8. V.V. Kafarov. Basics of May with the transfer. - M .: Higher. School, 1962, 655 pp.

9. NN Abramov and others. Water supply. - M.: Gosstroyizd. 1960, 580 p.

Claims (1)

A comprehensive device for cleaning flue gases from carbon dioxide and its utilization, including a transit gas duct, a vertical body with a conical bottom connected by a top edge of the sides with a window in the bottom of the transit gas duct, inside of which a vertical heat exchanger, a liquid distributor, and an absorption section are filled from top to bottom, filled nozzle with a large equivalent diameter, desorption-cooling section, filled with a nozzle with a small equivalent diameter, a suction umbrella, connected th with a fan, the conical bottom of the housing being connected by a pipeline through a circulation pump to a liquid distributor, characterized in that the lower part of the absorption section is provided with pockets for collecting saturated absorbent material connected to the distribution trays, the vertical side walls of the absorption and desorption-cooling sections are provided with horizontal slots, covered with horizontal leaflets, covered from above at an angle from the inside, and adjacent to the vertical exhaust channels with a perforated bottom, whose mouths communicating with the upper zone of the transit duct.