RU2220916C2 - The tower-type small sized biofilter - Google Patents

Abstract

FIELD: purification of household economy sewage and sewage with highly concentrated organic impurities. SUBSTANCE: invention presents the tower type small-sized biofilter , that has a working chamber with a lid, the lower perforated bottom, a nozzle made of Rashig rings, the upper distributive drain pan with openings, the system of artificial forced ventilation, the pipeline for supply of an incoming water. The ratio of cross-sectional area to the operating height is near or exceeds 1:6 at the cross-sectional area of 0.5-1.2 m sq. Above the working chamber there is a stream dissector with openings and two branch-pipes located under the lower perforated bottom: one is linked with the system of the incoming ventilations, and other has a butterfly cap with a rotation axis made in the form of a bolt for operation in the mode of a natural ventilation . There is a hydraulic lock made in form of a bent pipe mounted on an outlet pipeline. The stream dissector is mounted on the pipeline of supply of initial sewage and has a latch. The upper distributive drain pan has a stopper ring on its perimeter. The lid of the working chamber has the overhead outtake branch-pipe rising over the roof of the building. EFFECT: improved conditions of ventilation, increased oxidative power and resistance against vibration caused by quantities of flows and pollutions. 3 cl, 2 dwg

Description

 The invention relates to installations for the treatment of domestic wastewater and highly concentrated in organic pollution.

Known drip biofilters [1], which are a reinforced concrete structure, rectangular or round in cross section, filled with loading material, usually crushed stone, which is laid on a supporting grid. Air access to the biofilter is provided through the supporting grid by arranging holes in the enclosing surface of the walls located below the level of the supporting grid. The height of the biofilter is not more than 2.0 m. The limitation of height is due to the fact that with its further increase, poor conditions are created for ventilation of the entire height of the loading material, which is exacerbated by extremely small gaps between the individual granules of the load from crushed stone, which has a high density. The relationship between the cross-sectional area and the height is not regulated by any particular value. The ventilation of the loading layer is accepted as natural. Permissible pollution load is not more than 400 g / m ³ BOD per day.

Biofilters in the form of a biological tower are known [2], the design of which is similar to drip biofilters, but modern synthetic loads from polymeric materials are used as loading materials, which somewhat improves ventilation conditions and allows increasing the height of the structure to 6.0 m, thereby increasing contact time loading wastewater and wastewater can be fed continuously using fixed irrigators. The ratio between the cross-sectional area and the height is not regulated by any particular value, but in the drip biofilters and biological towers, the cross-sectional area is much larger than the height. Permissible load on organic pollution - no more than 2400 g / m ³ BOD per day.

The described designs have the following disadvantages:
- significantly worse ventilation conditions in the middle layers of the load than in the upper / especially in drop biofilters / and, therefore, the appearance of anaerobic zones in the middle layers, as a result of which the cleaning process worsens, siltation of the biofilter, unpleasant odors, and the appearance of flies occur. In addition, the biofilm of the middle layers of the biofilter consists mainly of a biofilm washed off from its upper layers, that is, only the top layer of the loading material, the height of which is not more than 0.3 m from the surface of the load, works efficiently - this mainly happens due to poor ventilation conditions of the deep layers of the boot material;
- the structures of these biofilters occupy large areas, which, firstly, requires large areas for their placement, and secondly, does not always allow you to place these biofilters in the room, while the location of these structures in the room significantly increases not only the cleaning effect , especially in the winter, when the cooling of effluents even by 1-2 degrees leads to a sharp deterioration in cleaning, but also greatly facilitates the working conditions of the maintenance staff;
- inefficient use of the load volume, since with its horizontal location it works less efficiently than with the vertical, with the same volume;
- deterioration of ventilation conditions in spring and autumn, since the ventilation of the described structures depends on the temperature difference - between the temperature in the body of the biofilter and the temperature of the outside air;
- CO ₂ removal is bad because of poor ventilation in the body of the biofilter and biological tower, since the special importance of ventilation is not only to saturate the drains with oxygen, but also to remove carbon dioxide formed during the mineralization of organic substances, this is especially true;
- the high cost of construction and its long duration and complexity:
- the impossibility or great complexity of access to the middle and lower layers of the boot material, while often there is such a need due to the possibility of silting the load in these structures;
- the difficulty of uniform distribution of effluents over a large surface area of such structures;
- the impossibility of shutting off any surface area of biofilters from work while reducing the amount of effluent / this is especially true when the fluctuating amount of effluent in sports camps, rest homes /;
- inefficiency of use of artificial ventilation in such structures.

 The most effective at the present time and the closest in technical essence to the proposed invention is a tower-type biofilter [3]. Unlike all other types of biofilters, in towers, the ratio of diameter to height is set by a certain value - 1: 6-1: 8, which creates good air draft like chimneys, so artificial ventilation is optional.

 The tower biofilter is a reinforced concrete column divided by gratings into sections 2-4 m high. A filter charge is located on the gratings, using crushed stone as the base. The separation of the tower biofilter by height gratings into tiers is largely due to the large weight of the crushed stone load and the inability to maintain this weight with the help of only the lower supporting grate. In the lower part of the biofilter, underneath the supporting grid, there is a double bottom space, not filled with a load, 0.4-0.9 m high, and openings for air intake. Wastewater flows through a pipeline with a simple dispenser and is sprayed onto the surface of the filter charge, hitting previously in bump discs in the form of separate plates.

The disadvantages of tower biofilters are:
- high capital costs for construction, since the tower biofilter is a massive reinforced concrete structure that can withstand heavy loads from the weight of crushed stone;
- the impossibility or difficulty of the location of tower biofilters in the room, and in this regard, their rapid cooling in the winter, and associated violations of the cleaning processes during cooling of the effluent;
- the use of inefficient loading material of large weight and not well blown by the air flow;
- the inability to build any required number of tower biofilter columns for stations with an fluctuating amount of drains due to high capital costs, in which it is necessary to periodically turn off individual columns / sections / with a decrease in the number of drains and load the drains with a smaller number of biofilters and, conversely, with an increase in the number of drains distribute them over a larger number of biofilters, that is, the impossibility of flexible regulation of the process.

 The aim of the invention is the creation of a compact efficient installation with improved ventilation conditions, with increased oxidative power, stably working when fluctuating in the number of effluents and pollution, as well as volley discharges in concentrations and hydraulic loads, simple in design, which does not require large capital costs during installation small-sized and easily placed indoors and easy to operate.

This goal is achieved in that the small-sized biofilter of the tower type, including a working chamber with a lid, a lower hole bottom, on which there is a nozzle made of Raschig rings and an upper distribution tray with holes, an artificial ventilation system, a pipeline for supplying source water, characterized in that the ratio of the cross-sectional area to the working height is close to or more than 1: 6 with a cross-sectional area of 0.5-1.2 m ² , above the working chamber there is a jet divider with a branch pipe and a valve, replenished on the supply pipe of the source effluents, two nozzles entering the working chamber under the bottom hole bottom, one of which is connected to the supply ventilation system, and the other, designed for operation in natural ventilation mode, has a rotary plug with an axis of rotation in the form of a bolt and a water seal in the form of a bent pipe section mounted on the outlet pipe, while the upper distribution pan is made with a restrictive ring around the perimeter, while the lid of the working chamber has an upper valve The outlet pipe extending outside the room and rising above the roof of the building, and the upper lid of the working chamber, the upper distribution tray, the jet divider and the upper ventilation pipe have detachable connections for ease of dismantling.

 A small tower biofilter is shown in FIG. 1 (general view and top view).

The small-sized tower-type biofilter includes
- a pipeline for supplying source water 1;
- jet divider 2 with holes;
- upper distribution pan 3;
- a working chamber 4 with a height of h _p ;
- nozzle from Rashig rings 5;
- bottom hole bottom 6;
- double bottom space 7;
- a water seal in the form of a bent section of the pipe 8;
- a pipe connected to the tiled ventilation system 9;
- a pipe designed to operate in natural ventilation 10;
- fan 11;
- walls of the room 12;
- the cover of the working chamber 13;
- upper ventilation pipe 14;
- flange detachable connection of the upper ventilation pipe 15;
- detachable flange connection of the lid of the working chamber 16;
- flange detachable connection with the supply ventilation system 17;
- rotary plug / flange connection / 18;
- a valve on the feed water supply pipe 19;
- a bolt of a rotary plug 20;
- restrictive ring of the upper distribution pan 21;
- supports supporting the lid of the working chamber 22;
- supports supporting the upper distribution pan 23;
- the covers of the working chamber, the upper distribution pan, the lower hole bottom freely rest on the corresponding supports;
- support lower hole bottom 24;
- pipe 25.

 Small-sized biofilter tower type works as follows.

 Wastewater through the source water supply pipe 1 enters the jet divider 2, by which uniform distribution of effluents is achieved over the entire area of the upper distribution pan 3. The restrictive ring of the upper distribution pan 21 prevents the passage of untreated water between the walls of the working chamber 4 and the load from the Rashig rings 5 . Getting on the upper distribution tray 3, the wastewater through the holes in it is evenly distributed throughout the loading area of the rings Rashig 5, on which is formed biological film consisting of microorganisms and carrying out the process of biological wastewater treatment. Having passed through the entire loading height from the Rashig rings, the biologically treated wastewater passes through the lower hole bottom 6 into the double bottom space 7 and is discharged along the water seal in the form of a curved pipe section 8 to further technological units of the treatment facilities. The movement of wastewater in the installation takes place in the direction from top to bottom, while the movement of air, which saturates the effluent with oxygen and is necessary for the life of microorganisms, occurs in the opposite direction - from the bottom up. Air can enter the installation through pipe 10 - during operation of the small-sized tower biofilter in conditions of natural ventilation, while the operating mode of the installation in conditions of artificial ventilation, plug 18 on pipe 10 is closed by turning the plug 18 around the axis of bolt 20. In this case, the hydraulic lock 8 on the drainage pipe does not allow the air pumped by the fan 11 through the pipe 9 to exit through the drainage pipe 8, which also prevents the closed rotary plug 18 during operation Novki under artificial ventilation. The lower hole bottom 6 not only supports the nozzle-loading of the Rashig rings, but also creates a double bottom space 7 for free passage of air, and the holes in the lower hole bottom create conditions for uniform distribution of air over the entire cross-sectional area of the installation.

 To create optimal ventilation conditions, the installation has a lid of the working chamber 13, passing into the upper ventilation pipe 14, rising above the roof of the building and creating additional traction in the working chamber of a small-sized tower-type biofilter. Accepted loading from Rashig 5 rings is much more efficient than the crushed stone loading used in traditional tower-type biofilters. The valve 19 installed on the pipeline 1 of the source water, allows you to adjust the amount of effluent supplied to this particular installation or, if necessary, and a sharp decrease in the amount of effluent to completely stop their flow. For ease of access to the load 5, the lid of the working chamber 13 has a detachable flange connection 16, it is also provided for easy dismantling of the nozzle 25 using the flange 15 from the upper ventilation nozzle 14, easy dismantling of the splitter 2 using the flange connection on the valve 19 / valve flanges / and light lifting the lid of the working chamber 13 from the supports 22, the upper distribution tray 3 from the supports 23 and the lower hole bottom 5 from the supports 24, since the parts 13, 3 and 6 are freely supported by these supports. The installation is located in room 12, which creates the best temperature conditions for wastewater treatment and great convenience during winter operation. The pipe 9 has a flange connection 17 for dismantling from the fan 11. The vertical location of the load-nozzle from the Raschig rings makes the installation more efficient compared to drip biofilters and biological towers. The presence in the installation of a hermetically sealed lid of the working chamber 13 and the connection of this lid by the upper ventilation pipe 14 enhances traction in a small-sized tower biofilter during operation under conditions of not only natural, but also artificial ventilation.

 Small-sized tower-type biofilters can be used not only as an independent unit of biological wastewater treatment, but can also be used as a preliminary additional step before constructions of any capacity and technology to improve the degree of purification, and can also be built into any technological chain during the reconstruction of existing and inefficient treatment facilities.

Sources of information
1. "Sewerage", Fedorov N.F. Shifrin S.M., Higher School Publishing House, Moscow, 1968

 2. "Technology of natural and waste water treatment", M. Hammer, Moscow. Stroyizdat, 1979

 3. "Sewerage", Fedorov N.F., Shifrin S.M., Higher School Publishing House, 1968

Claims (3)

1. A small-sized tower biofilter for wastewater treatment, containing a working chamber with a lid, a bottom hole bottom and an upper distribution pan with holes, an artificial ventilation system, a pipeline for supplying source water, characterized in that the ratio of the cross-sectional area to the working height is close to more than 1: 6 with a cross-sectional area equal to 0.5-1.2 m ² , above the working chamber there is a jet divider with holes installed on the feed pipe of the initial effluent having a valve, two pipes entering the working chamber under the bottom hole bottom, one of which is connected to the supply ventilation system, and the other, designed for operation in natural ventilation mode, has a rotary plug with an axis of rotation in the form of a bolt, and a water seal in the form of a bent pipe section installed on the discharge pipe, while the upper distribution pan is made with a restrictive ring around the perimeter, and the nozzle consists of Raschig rings. 2. The small-sized tower biofilter according to claim 1, characterized in that it has detachable connections for dismantling the upper cover, upper distribution tray, lower hole bottom, upper ventilation pipe and jet divider. 3. The small-sized tower biofilter according to claim 1, characterized in that the lid of the working chamber has an upper ventilation pipe that extends beyond the premises and rises above the roof of the building.

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