RU2567599C1 - Thin-layer settling tank arranged according to counter-current scheme - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: thin-layer settling tank is arranged according to a counter-current scheme, comprises a body and a sludge chamber. The body consists of two parts. The first part 2 of the body is connected to a spill way 1 and is made in the form of a sand catching chamber with a sand collector 6 in the lower part. The second part 3 of the body comprises a sludge chamber 7. Both parts of the body are separated with a thin-layer block 8, rigidly fixed on a partition 5, which separates parts of the body and is arranged perpendicularly to the axis of the spill way 1. In the second part 3 of the body there is a nozzle 4 for purified water release. The thin-layer block 8 is made in the form of inclined plates or tubular, in which instead of inclined plates they use inclined pipes of average diameter made from plastics.

EFFECT: invention makes it possible to increase efficiency of waste water treatment.

2 dwg

Description

Known wastewater treatment plant in the form of a sedimentation tank USSR 919700, C02F 1/52 of 04/15/82, containing a housing, a sludge collector and a system of water supply trays.

The closest technical solution to the claimed object is a treatment plant in the form of a sump according to RF patent No. 2438992, comprising a housing, a sludge collector and a system of water supply trays with water distribution through a spillway, characterized in that it further comprises a water supply tray with a flow-guide wall mounted in the upper part of the housing, made in the form of a curved plate, consisting of two vertical and one horizontal section adjacent to the vertical plate of the water supply tray with a gap, and at the bottom a drainage part of the housing is installed under the water supply tray adjacent to the bottom part, inclined to the side of the sewage part, and from the side opposite the water supply tray, there is a spillway system made in the form of a vertical plate, the upper part of which is located at a water level in the housing of the sump, and the guide plate with a bend towards the rear wall of the housing, in which two drain pipes are mounted, located at different levels from the upper edge of the housing (prototype).

A disadvantage of the known treatment plant is that it does not provide a high degree of wastewater treatment.

EFFECT: increased efficiency of wastewater treatment.

This is achieved by the fact that in a thin-layer sump made according to a countercurrent scheme containing a housing, a sludge collector and a system of water supply trays with water distribution through a spillway, a water supply tray with a flow guide wall made in the form of a curved plate consisting of two vertical and one horizontal section adjacent to the vertical plate of the water supply tray with a gap, and in the lower part of the body under the water supply tray, the collection part of the body is installed, adjacent to the bottom part, inclined to the side of the collecting part, and from the side opposite to the water supply tray, there is a spillway system made in the form of a vertical plate, the upper part of which is located at the water level in the tank of the settler, and the directional plate with a bend towards the rear the walls of the casing, in which two drain pipes are mounted, located at different levels from the upper edge of the casing, the casing, consisting of two parts, the first of which, connected to the spillway, is made in the form of sand a fishery chamber with a sand collector in the lower part, and the second part of the casing contains a sludge collector, while both parts of the casing are separated by a thin-layer block rigidly fixed to the partition separating the casing parts and located perpendicular to the spillway axis, and a pipe for the outlet of purified water is located in the second casing part, and a thin-layer block can be made in the form of inclined plates or tubular, in which instead of inclined plates, inclined pipes of medium diameter made of plastics are used.

In FIG. 1 shows a general view of a thin-layer sedimentation tank made according to a countercurrent circuit having an upward movement of the fluid flow; FIG. 2 is a variant of a thin-layer sump, made according to the countercurrent flow diagram, with a downward movement of the fluid flow.

A thin-layer sump made according to a countercurrent flow diagram with an upward movement of the fluid flow (Fig. 1) contains a casing consisting of two parts, the first of which, part 2, connected to the spillway 1 (water inlet) is made in the form of a sand trap with a sand pan 6 in the lower part, and the second part 3 of the casing contains a sludge 7. Both parts of the casing are separated by a thin-layer block 8, rigidly fixed to the partition 5, the dividing parts of the casing and located perpendicular to the axis of the spillway 1. In the second part of the casing is located 4 for cutting the output of purified water.

The thin-layer block 8 can be made in the form of inclined plates or tubular, in which instead of inclined plates, inclined pipes of medium diameter, usually made of plastic, are used. Thin-layer blocks 8 must be located at the outlet of the water from the sump in front of the pipe 4 to exit the purified water.

There are two options for a thin-layer sump, made according to the countercurrent scheme: the first option - having an upward movement of the fluid flow (Fig. 1). In the first embodiment of a thin-layer sump made according to a countercurrent flow diagram with an upward movement of the fluid flow (Fig. 1), the thin-layer block 8 is located at its entrance at an angle of 135 ° to the partition 5 from the water level line defined by the spillway 1. In the 2nd a variant of a thin-layer sump made according to a counter-current scheme having a downward movement of the fluid flow (Fig. 2), the thin-layer block 9 is located at its entrance at an angle of 45 ° to the partition 5 from the water level line defined by the spillway 1.

A thin-layer sump made according to the countercurrent scheme works as follows.

Thin-layer shelf sumps are recommended for clarification of weakly concentrated wastewater containing finely dispersed insoluble impurities, mainly of low density. They find application in wastewater treatment at enterprises of various industries. In the treatment of effluents containing polydisperse pollution systems, thin-layer sumps can be used as the second stage of treatment. The technological calculation of thin-layer sedimentation tanks is carried out similarly to the calculation of conventional horizontal sedimentation tanks. The basic input data are the estimated depth (distance between the shelves) of the structure and the hydraulic size of the impurities for which it is intended to be retained.

Thin-layer sedimentation is used when it is necessary to reduce the volume of treatment facilities and, if necessary, increase the efficiency of existing settlers. In the first case, thin-layer sumps act as independent structures, in the second case, existing sumps are supplemented by thin-layer modules located in an improved sump in front of the drainage device.

A constructive variety of thin-layer sedimentation tanks are sedimentation tanks operating according to a countercurrent scheme. All of them can be reduced to the two circuit diagrams shown in FIG. 1 and FIG. 2. The first option involves the upward movement of the fluid flow and is designed to separate suspended particles having a density greater than water. The scheme according to the 2nd option assumes a downward movement of the fluid flow and is intended to separate suspended particles having a density less than water. In this case, water flows horizontally between rows of inclined shelves (plates). Solid suspended particles descend and slide along inclined shelves into the sump for sediment. Oil products rise to the surface of the water in a sump, from where they are removed using an oil recovery device.

To improve the hydrodynamic conditions of the horizontal sump, it is necessary to create such designs of the inlet and outlet of wastewater that will ensure their uniform distribution over the width and depth of the sump. In shallow (1.5–2 m) structures, this distribution is satisfactorily provided by non-flooded spillways with a semi-submerged guide wall at the beginning of the sump. Sludge falling to the bottom of horizontal sedimentation tanks should be periodically removed. The duration of its storage period depends on the amount of sediment and its ability to rot and compact.

The design and dimensions of the mud part of the sumps are selected depending on the method of sediment removal. The most widely used are rectangular sedimentation tanks with one or more funnel-shaped pits for precipitated sediment. The pits are arranged in one or two rows at the beginning of the sump. Precipitated sediment is removed from the sumps using mud pumps.

To ensure sliding of the sediment, the walls of the sump are made at an angle of 45-60 °, and a slope of at least 0.05 is attached to the bottom of the sump, which necessitates an additional deepening of the sump. A slight slope of the bottom of the sump does not always allow the sediment to slide to the pit, which often leads to excessive compaction of the sediment.

Thin-layer shelf sumps are recommended for clarification of weakly concentrated wastewater containing finely dispersed insoluble impurities, mainly of low density. They find application in wastewater treatment at enterprises of various industries. In the treatment of effluents containing polydisperse pollution systems, thin-layer sumps can be used as the second stage of treatment. The technological calculation of thin-layer sedimentation tanks is carried out similarly to the calculation of conventional horizontal sedimentation tanks. The basic input data are the estimated depth (distance between the shelves) of the structure and the hydraulic size of the impurities for which it is intended to be retained.

Thin-layer sedimentation is used when it is necessary to reduce the volume of treatment facilities and, if necessary, increase the efficiency of existing settlers. In the first case, thin-layer sumps act as independent structures, in the second case, existing sumps are supplemented by thin-layer modules located in an improved sump in front of the drainage device.

The plate length l of the thin layer block can be determined by the formula

where ν is the flow velocity in the thin-layer block between the plates; b is the distance between the plates along the normal; u is the deposition rate of solid particles; u ₁ = u sin α is the component of the deposition rate directed along the plates; u ₂ = u cos α is the component of the deposition rate directed along the normal to the plates; α is the angle of inclination of the plates.

The angle of inclination of the plates α is usually taken in the range of 45-60 ° according to SNiP 2.04.03-85 and should ensure that the deposited sediment slides along the shelves under the action of gravity.

The performance of a thin-layer sump, m ³ / h, is calculated by the formula

where ν is the flow velocity in a thin-layer block between the plates, mm / s; L is the length of the thin layer block, m; In - the width of the thin layer block, m; k is the coefficient of utilization of the volume of the sump.

The number of plates in the block is determined from the ratio

where b is the distance between the shelves along the normal; t is the thickness of the plates.

The width of the section of the sump is usually assigned based on the size of the plates intended for the manufacture of blocks (modules). All sizes of other nodes of the sump (the width of the sump tank, its construction depth, etc.) are assigned for design reasons.

Claims (1)

A thin-layer sump made in a countercurrent circuit, comprising a casing, a sludge collector, characterized in that the casing consists of two parts, the first of which, connected to the spillway, is made in the form of a sand trap with a sand pan in the lower part, and the second part of the casing contains a sump in this case, both parts of the body are separated by a thin-layer block, rigidly fixed to the partition separating the parts of the body and located perpendicular to the axis of the spillway, and in the second part of the body there is a pipe for exiting cleanly water, wherein the thin-film unit is in the form of inclined plates or tubular, wherein the inclined plates are used instead of the inclined pipe mean diameter, made of plastics.

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