SU1000415A1 - Apparatus for biochemical purification of effluents - Google Patents

Description

This invention relates to biochemical treatment of & LT and sewage and industrial wastewater and can be used in the communal household, food, woodworking, chemical and other industries of the industry ..

A device for biochemical wastewater treatment (biofilter) is known, including a housing within which a charge is placed, a water distribution device supplying and discharging pipelines. The wastewater is fed to the biofilter, distributed over p6 to the top 1 of the load by the water dispenser, and the stack is loaded with a biochemical purification; ke under the action of aerobic micro-or- ganisms attached to its surface. In order to intensify the process, air under pressure 1 is supplied to the load by the blower.

The disadvantages of this device were the short duration of the stay of wastewater in the biofilter loading (about 3-5 minutes), incomplete use of the volume of the structure, not-. There is a sufficient uniform distribution of the liquid over the loading surface, and consequently, a short time of wastewater co-tact with bibfilm and insufficient cleaning efficiency to increase the efficiency of re-directing the purified liquid to the biofilter, (repirculation), which reduces the device performance and requires additional energy sewage pumping.

The closest to the present invention is a device for biochemical wastewater treatment, containing a sealed enclosure, divided by a vertical partition that does not reach the bottom into two communicating sections, a load, a blower, on the discharge line of which a pulsator is installed, connected with pipes by wires with each section . The latter are equipped with valve-float controllers that are connected to the input and output units of the treated water.

Claims (2)

The sections of the housing are connected by perforated pipes laid on the bottom of the housing, through which the fluid under pressure of air is periodically displaced from one section to another, alternately flooded and emptied the load. Due to the repeated repeated flooding of the load and the displacement of fluid by air from one section of the hull to another, the duration of contact of wastewater with the load increases, the efficiency of their purification 2 increases. However, as the duration increases, the contact of wastewater with the load sharply decreases - due to the need to introduce the smallest portions of the original liquid, it is also possible to slip through the device of insufficiently cleaned portions of water, which reduces the efficiency of its work; The disadvantage is also low reliability of the device due to the use of float-valve regulators in it, which are quickly clogged with large impurities contained in wastewater. The purpose of the invention is to increase the efficiency of using the device by increasing the duration of contact with wastewater, increasing productivity and reliability. device operation. This goal is achieved by the fact that in the device containing a sealed enclosure divided by partitions into sections, loading, blower with pipes and a pulsator, input water input and output units processed, partitions of three parallel plates, the pulsator is communicated by separate pipelines with even and odd sections and the atmosphere. In addition, the outermost plates of the partitions are attached to the housing cover and at a distance from its bottom for, and the middle ones are attached to the bottom of the housing and to the distance from its cover, while their height varies in the direction of water flow. Figure 1 shows schematically the structure of the device proposed; figure 2-5 - the same in the work process. The device consists of a sealed enclosure 1 with loading 2, partitions 3, each of which consists of three elements, the extreme elements are vertical walls that do not reach the bottom of the tank, the middle ones are vertical stacks that do not reach its cover. . Moreover, the middle element of each subsequent partition is lower than in the previous one by the amount of hydraulic losses between adjacent sections, which prevents the water from being forced into the previous extension section, blower 4,: water pipelines: inlet 5 and outlet b; receiving tank 7., which is connected to the first section by means of a hydraulic lock 8, which ensures that a new portion of the source liquid enters only if atmospheric pressure is established in the first section and prevents air from leaking into the receiving tank at elevated pressure in it. In the last section, in front of the discharge pipe 6, a partition wall 9 is installed, acting as a water seal and preventing air leakage into the exhaust pipe b. . On the discharge line 10 of the air blower 4, a pulsator 11 is connected, connected by two piping systems 12 and 13, respectively, with odd and even hull sections and connected to the atmosphere, each of the piping 12 and 13 can be connected to the atmosphere. Air enters each section through the system of air distribution pipes 14 located in the lower part of the section. There are also pipelines 15 of sludge removal. The device works as follows. By the blower 4, along the pressure line 10, the air is alternately supplied to the odd and even sections through pipelines 12 and 13 by means of the pulsator 11, successively displacing a portion of the liquid from the previous section to the next. Air enters the lower part of the sections, is distributed by a system of pipes 14 and aerates the liquid in them. When air is supplied to odd sections, the fluid in them is forced out into subsequent even sections (Fig. 2). The hydraulic lock 8 is closed at this, since the increased pressure in the first (odd) section does not allow water from the receiving tank 7 to pass through the hydraulic lock B. Then using the pulsator 11, the air supply stops and the pipeline 12 and, consequently, the odd sections are connected with the atmosphere. A hydraulic shutter 8 breaks down and the initial waste liquid from the receiving tank 7 begins to flow into the first section (Fig. 3), atmospheric pressure is established in the other odd sections. Then, using the pulsator 11, the air through the pipeline 13 is supplied to the even sections, the liquid is forced out into the subsequent odd sections. The purified water is displaced from the last section to the discharge pipe 6, while the partition 9 prevents slipping through this pipeline (Fig. 4) -. Then the pulsator 11 (Fig. 5) connects the pipe 13 (3 with the atmosphere (atmospheric pressure is established in the even sections; -. Then the operation cycles of the device are repeated. Periodic contact of the wastewater and air with the load ensures the necessary conditions for the intensive biochemical purification process In case of successive movement of a liquid from one to another under the pressure of the air, intensive mixing of the liquid and its saturation with oxygen occur, which increases the speed of exchange processes, and In addition, due to the sequential movement of the liquid through the sections, the likelihood of a portion of the raw liquid is prevented, the duration of the contact of the wastewater with the biomass attached to the load increases, the efficiency of the process increases. The proposed device allows ( to increase the efficiency of wastewater treatment by 15% compared with the prototype and other known biofilter designs, reduce the cost of wastewater treatment plants by 15-20% and reduce the export cost by 10-15% luatatsionny expenses. Claim 1. Device for biochemical sewage treatment, containing a sealed enclosure divided by partitions into sections, loading, blower with pipelines and pulsator, input water input and treatment output units, so that , in order to increase the efficiency of use by increasing the duration of contact of wastewater with loading, increasing productivity and reliability of the device, the partitions are made of three parallel plates, the pulsator is communicated by individual t uboprovodami with even and odd sections and the atmosphere. 2. The device according to claim 1, O t li. Because the outermost plates of the partitions are attached to the housing cover and at a distance from its bottom, the middle ones are attached to the bottom of the housing and to the distance from its cover, and their height decreases in the direction of water flow. Sources of information taken into account in the examination 1. S. Yakovlev. and other biological filters. M., stroiizdat, 1975, pp.5-37. 2. USSR author's certificate No. 865843, cl. From 02F 3/04, 1980. L g 1 // FIG g eleven one PS L / 7 X lg.4 //  z; FIG. // / th V7 7 / 5