RU2001108168A - METHOD OF CHLORIDE METHYLENE RECOVERY AND INSTALLATION FOR ITS IMPLEMENTATION - Google Patents

Claims (6)

1. The method of recovery of methylene chloride, including the removal of methylene chloride using carrier gas from technological equipment in the form of vapors, the absorption of vapors from the carrier gas stream in the process of its contact with the absorber, the separation of methylene chloride from the spent absorber in the form of concentrated vapors, followed by condensation into the liquid phase upon cooling, characterized in that the carrier gas is sequentially passed through all the apparatuses of the technological chain countercurrent to the movement of the material emitting methylene chloride, the absorption of methylene chloride vapors removed from the process chain in the carrier gas stream is carried out by absorption of high boiling organic substances in the ideal mode of displacement during countercurrent flow of contacting phases and contact conditions that ensure the complete removal of methylene chloride from the carrier gas stream at the same time complete saturation of the absorbent removed for regeneration with methylene chloride, and the separation of methylene chloride from the saturated absorbent is carried out by heating the absorbent during its flow along the heated surface, followed by condensation of the saturated methylene chloride vapors that are removed during cooling under conditions that, in turn, ensure complete extraction of methylene chloride from the absorbent while at the same time extremely deep condensation of its vapors, while being heated and freed from methylene chloride the absorbent is cooled by a stream of saturated absorbent supplied to the separation of methylene chloride and returned to the absorption. 2. The method according to p. 1, characterized in that freon oil is used as absorbent, for example, HF 22s-16 oil, while the concentration of methylene chloride in the carrier gas stream entering the absorption is maintained at 700-1200 g / m ³ , the height of the working absorbent layer in the absorption zone on the nozzle is provided equal to 1.70-1.95 m, the irrigation density is set equal to 3.7-4.2 dm ³ absorbent per m ^{3 of} the gas phase being cleaned, the linear velocity of which in the absorption zone is maintained equal to 0.04-0.06 m / s. 3. The method according to PP. 1 and 2, characterized in that the heating of the saturated absorbent is carried out sequentially in two stages, first in the process of film flow along a surface heated to a temperature of 105-110 ^o With an irrigation density of 25-30 m ³ / m ² • h and the residence time of the absorbent on a heated surface for 36-40 s, then in the process of its jet-drop flow along a heat-conducting nozzle heated to a temperature of 115-120 ^o with an irrigation density of 8-9 m ³ / m ² • h and a contact time of 12-15 s.  4. The method according to PP. 1-3, characterized in that the removal of methylene chloride vapor from the zone of its allocation during thermal regeneration of the absorbent is carried out by thermal diffusion due to the pressure difference of the vapor of methylene chloride in the zone of its separation from the saturated absorbent and in the condensation zone resulting from cooling of superheated steam of methylene chloride and condensation at boiling point, with the withdrawal from the condensation zone of the continuously formed condensed phase of methylene chloride and its further cooling to ambient temperature s, excluding direct contact with the atmosphere of the condensed phase.  5. Installation for the recovery of methylene chloride, containing a source of methylene chloride vapor, equipped with a pipe for introducing liquid methylene chloride, connected through a pipe and fittings with a flow tank of liquid methylene chloride, a pipe for outputting a carrier gas saturated with methylene chloride vapor, connected by means of a duct and a regulating gate with a suction of the ventilation unit, a nozzle for suction of a carrier gas in communication through a gas duct and a regulating gate with the atmosphere, a device for the sensations of methylene chloride vapors from the carrier gas stream, connected by a nozzle for introducing a cleaned gas stream with a source of methylene chloride vapors and a nozzle for discharging a cleaned gas stream with atmosphere, a cooled condenser for condensing methylene chloride vapors removed from the spent absorber into the liquid phase, connected to a device for absorbing methylene chloride vapor and a collector of liquid methylene chloride, characterized in that it is additionally equipped with a compressor connected by gas ducts with its suction pipe through an expansion vessel with an exhaust unit exhaust, and with its exhaust pipe, respectively, through a gas duct through a receiver and a valve with a pipe for introducing a cleaned gas stream into a device for absorbing methylene chloride vapor, made in the form of two consecutively installed and connected to each other by means of gas ducts directly and through pipelines through the pump and valves of the cooled absorption packing columns and through the gas duct and valve with expansion a vessel and its own suction pipe, a device for separating saturated vapors of methylene chloride from the spent absorbent, a connected pipe for introducing a coolant with a source of heating steam, a pipe for discharging condensate with a condensate collector, a pipe for discharging saturated vapors of methylene chloride with an annulus of a cooled methylene chloride vapor condenser into the liquid phase, the pipe for the output of the liquid phase of methylene chloride which is connected via a refrigerator to the liquid chloride collector methylene, connected, in turn, through a gas duct and valve with the annular space of the methylene chloride vapor condenser, a heat recuperator, connected through pipelines to the pipes, respectively, for introducing the spent and withdrawing the regenerated absorbent of methylene chloride vapors of the device for separating methylene chloride from the spent absorbent through pipelines and valves through a pump with a nozzle for outputting the spent absorbent first along the cleaned gas flow of cooling my absorption packed column and via a conduit and valve through a pump and a refrigerator with a pipe for the cooled second input absorbent absorption packed column.  6. Installation according to claim 5, characterized in that the device for separating methylene chloride from the spent absorbent is completely heat-insulated in the form of a shell-and-tube heat exchanger with side pipes, respectively, the upper one for introducing heating steam into the annular space and the lower one for condensate drainage from the annular space heating steam, connected by its upper tube sheet through the upper conical diffuser, equipped with a lateral pipe connecting with the distribution comb for input into the pipe the space of the spent absorbent, with a drip catcher, which is a cylindrical element with a top cover, inside of which the lower and upper gratings are installed, forming a space filled with granular or fibrous material, communicating through a side inclined confuser installed above the upper grate with a side pipe to exhaust the overheated methylene chloride vapor , and its lower tube sheet through the lower conical diffuser with a heater, which is enclosed in heating an element is a cylindrical body with an inclined bottom and a lower side pipe for outputting the regenerated absorbent, while inside the heater a horizontal support grid is installed above the lower side pipe, over which vertical plates are rigidly fixed to the side surface of the cylindrical body, the free space between which is filled with a heat-conducting nozzle, for example, metal Rashig rings, and the upper ends of the pipes in the shell-and-tube heat exchanger are in higher than the surface of the upper tube sheet, forming with it a distribution plate filled with spent absorbent material, each pipe of which is equipped with a wick, which is a sleeve wetted by absorbent material, one part of which is placed inside the pipe and pressed against its inner surface with an annular groove using a pressure ring, the other part of which is turned inside out and stretched onto the pipe up to the surface of the tube sheet.