SU1674893A1 - Mass transfer apparatus for cleaning sewage water - Google Patents

Abstract

The invention relates to the instrumentation of mass transfer processes occurring in a solid-state fluid system, and may find application in wastewater treatment technology more specifically when discharging waste solid particles from pressure columns. The purpose of the invention is to increase the efficiency of the apparatus by preventing the solid material of the discharge slurry pipeline from clogging. The middle part has a nozzle with openings located tangentially to the inner surface of the nozzle which is enclosed. in the shell connected to the puloatsion chamber 3 silt E

Description

The invention relates to the instrumentation of mass transfer processes occurring in a liquid-solid gel system, and may find application in the chemical industry in wastewater treatment technology during the removal of spent solid particles from pressure columns.

The aim of the invention is to increase the efficiency of the apparatus by preventing clogging of discharge pipelines with solid material.

FIG. 1 shows a countercurrent mass transfer apparatus for wastewater treatment, a general view; in FIG. 2, node I in FIG. 1. in FIG. 3 a section A-A in FIG. 2

The mass transfer apparatus contains a vertical case 1, in the middle part of which there is a contact chamber 2 filled with solid material, in the upper part of the feeder 3 of the cobent, connected by a mesh tube 4 to a drainage device 5 in the lower part - a wire grate 6 under which the settling chamber 7 is located with gel dispensing 8 effluent level sensor 9 of sediment and discharge slurry pipe 10 with valve 11 for removal of spent solid material

On the slurry pipeline 10, a perforated pipe 12 is installed, the holes of which are located tangentially to its inner surface. The perforated pipe 12 is enclosed in a shell 13. In which the exhaust air discharged from the pulsation chamber 14 through the air pipe 15 through the valve 16 is fed. The shell 13 relative to the pipe is coaxial.

The pulsation chamber 14 is connected to the settling chamber 7. It has a sensor of the upper 17 and lower 18 levels and through the valve 16

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the air pipe 15 is connected to the shell 13 located on the outlet slurry pipe 10

The countercurrent mass transfer apparatus has a valve 19 for supplying compressed air to the pulsation chamber. The control unit 20 provides automatic operation of the apparatus.

The device works as follows

When sediment reaches the solid material in the settling chamber 7 of the sediment level sensor 9, the control unit 20 receives a signal. The control unit 20 turns on the valve 16 on the air duct 15 The valve 16 opens and the exhaust air from the pulsation chamber 14 goes through the duct 15 through the valve 16 passes tangentially through the openings of the nozzle 12 and twists the spent solid material in the pipeline 10 preventing it from clogging

After a predetermined time from the control unit 20, the valve 11 of the discharge slurry line 10 receives a signal. The valve 11 opens and the spent solid material from the settling chamber 7 is removed along the discharge slurry line 10 through the valve 11

As exhaust air is discharged from the pulsation chamber 14, the liquid level in it reaches the upper level sensor 17. The control unit closes the valves 16 and 11 and the solid material is withdrawn.

Technical and economic advantages of the proposed device are to increase the efficiency of the counter-mass mass exchange apparatus and the efficiency of dehydration.

Claims (1)

Invention Formula A mass transfer apparatus for wastewater treatment comprising a vertical casing at the bottom of which a settling chamber is placed with a discharge slurry of waste solid material connected to a pulsation chamber, which in order to improve the efficiency of the apparatus by preventing the slurry pipeline from clogging with a solid material the parts are provided with a perforated branch pipe, the holes of which are located tangentially to the internal surface of the branch pipe coaxially in bechayku connected to a pulse kama swarms  1 & VS & -19 Air / 15 FIG. 2 FIG. 3