SU1353481A1 - Absorption apparatus - Google Patents

Abstract

The invention relates to the design of absorption apparatuses for cleaning ventilation emissions containing ammonia from photocopier machines used in the printing industry, and can be used for cleaning similar emissions from other industries. The aim of the invention is to increase the efficiency of the process of absorption and trapping of droplets with an increase in the volume flow rate of the gas to be purified by 75% of the nominal. Anna is equipped with a device for uniform supply of the gas to be purified to the chamber with a nozzle, made in the form of a supply pipe with a trapezoidal cut directed to the bottom, while the smaller base of the cutout is facing the gas inlet. The window on the vertical part of the figured partition is made longitudinal and provided with a flap and a device for moving it. The ratio of the diameter of the thread to the size of the cell in the mesh package is 0.2-0.6. The nozzle is assembled from grids with a living cross section of 73-75% with two cell sizes laid at a distance of one to two diameters of the wire mesh, and the sizes of the cells in the nearest grids alternate in a ratio of 1: 2. 2 hp f-ly, 1 ill. S (P

Description

BACKGROUND OF THE INVENTION The invention relates to designs of absorbing apparatuses, prior to. assigned for the cleaning of ventilation emissions containing ammonia from the blueprint machines used in the printing industry, and can be used to clean up similar emissions from other industries.

The aim of the invention is to increase the efficiency of the absorption process and to capture the droplets with an increase of from the nominal volumetric flow rate of the gas to be purified.

The drawing shows the absorption apparatus.

The apparatus contains two stages: the absorption chamber 1 and the drop catcher 2, separated by a figured partition 3. The absorption chamber has a nozzle 4 and a device for uniform supply of purified air consisting of a supply pipe 5 and a plate 6 with perforations placed between the nozzle 4 and pipe 5.

Plant 4 is made in the form of a layer of grids with cells of two sizes, the living section in each of which is 73-75%, placed at a distance from each other equal to two diameters through the gasket; The B cell sizes of the nearest grids alternate in a 1: 2 ratio. The supply pipe 5 of the device for uniform gas flow has a trapezoidal cutout 7 on the side facing the bottom of the apparatus 8. Irrigation of the nozzle 4 with the absorption solution is performed through a nozzle device 9. The bottom of apparatus B has a slope 10 for flow through drain connection 10 with a hydraulic seal.

The absorption chamber is separated from the apparator by a dividing figured partition 3 with a downward bevel, which is at the same time a part of the variable droplet separator flow unit, on the vertical part of which there is a longitudinal window 11 with flaps 12 and a device 13 for moving them. In front of window II, at a distance, its width, in brackets 14, a packet of grids 15 is made, in which the ratio of the diameter of the thread to the dimensions of the cell is 0.2-0.6.

The part of the partition located under the bag of nets 15, due to the downward bevel, forms a collection tray

and removal of the captured droplets through the pipe 16, connected to the drain fitting O by means of a pipe 17. The partition dividing wall is provided with a bevel 18.

The device works as follows.

The contaminated air (gas) enters it through the inlet, which is a continuation of the supply pipe 5 and through its trapezoidal cutout 7 and the perforated plate 6, is supplied to the bottom surface of the tank 4 evenly over its entire area. The nozzle 4 is irrigated with an absorption solution (technical or weakly acidified water) using a nozzle device 9. When mutually

In the opposite direction, the gas-solution inside the nozzle 4 (reaction layer) creates a cell-film process of mass transfer, due to which there is an intensive absorption of ammonia from purified air. This is achieved due to the special laying of layers of grids with a living cross section of 73-75% each at a distance from each other equal to two diameters with alternating cell sizes in the nearest grids in a 1: 2 ratio. The formation of a packet of grids with two cell sizes allows the particles deposited on the filaments to collect into larger ones and, upon reaching a certain mass, flow into the pallets of the packets.

The particles of the absorption solution, which are carried away from the absorption chamber by the upward air flow, are fed into the droplet separator 2 through the longitudinal window 11 in the partitioned partition wall 3. Here the air flow with the liquid particles acquires the velocity determined by the particle size in the entrainment necessary for their inertial entrainment . The required speed is determined by the sectional area of the longitudinal window 11 defined for a given volume flow of air, obtained by moving the movable flaps 12. With a sharp, -90, change in the direction of flow movement with a simultaneous drop in speed as the fluid leaves the window properties are kept at a distance equal to 5-2.0 times the width of the window from its slice, its speed, acquired. in the stream, thanks to which they

five

0

five

pass through the grid cells inside the package from grids 15 placed at a much shorter distance, where they are deposited on the threads of the grids and, collecting into large droplets under their own weight, flow into the collection tray of trapped particles and through the drain nipple 16 and drain fitting 10 through the water seal together with the waste solution is discharged from the apparatus. The variable flow unit thus allows, in the early size of the apparatus, to change the volume of air (gas) to be purified up to 75% of the nominal up or down and to maintain the required ammonia absorption efficiency at optimum specific nozzle irrigation.

Claims (3)

1. Absorbent apparatus, including a housing with a chamber with a nozzle located in it, a droplet separator equipped with a dividing figured partition, which has a downward bevel, windows that are filled with its vertical parts and are installed opposite windows at a distance equal to its width, with mesh packages that differ from in order to increase the efficiency of the absorption process, it is equipped with a device for uniformly supplying the gas to be purified to a chamber with a nozzle, made in the form of a supply pipe with a trapezoidal cutout, which is directed to seeking apparatus, and a perforated plate disposed between the nozzle and the lead-in pipe, while the smaller base of trapezoidal vfeza facing the gas inlet. 2. The apparatus pop. 1, which differs from the fact that, in order to increase the efficiency of catching drops with an increase of 75% of the nominal volumetric flow rate of the gas to be purified, the window on the vertical part of the figured partition is made longitudinal and equipped with a valve and a device for the displacement, while in the grid package, located opposite the window, the ratio of the diameter of the thread to the dimensions of the cell is 0.2-0.6. 3. The apparatus is popp. 1 and 2, characterized in that the nozzle is assembled from grids with a living cross section of 73-75%, with two cell sizes, arranged at a distance of 1-2 diameters of the mesh thread, and the dimensions of the cells in the nearest the grids alternate in a ratio of 1: 2. fff Editor L.Gratillo Compiled by A.Sondor Tehred M.Hodanich Order 5628/8 Circulation 657 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4 Proofreader A. Obruchar