RU2131500C1 - Regulating tank - Google Patents

Abstract

FIELD: structures of sewerage systems; applicable in balancing of flow rates of household and industrial sewage waters. SUBSTANCE: regulating tank has separated into parts vessel with supplying pipeline, emptying pipeline, ventilation system and discharge trays. each section of vessel has settling chamber for trapping insoluble impurities and provided with pipelines for periodical roiling and removal of sediments to tank of pumping plant. It is separated in length by partition with opening into two compartments. The first compartment of small size with length equalling 0.2-0.3 of total length of tank provides for formation of main amount of sediments. It has devices ensuring flushing and removal of sediments when emptying of tank. The second compartment being the main accumulator of water occupies the main space of section and its length equals 0.7-0.8 of total length of the whole tank. Sections are separated from one another by thresholds whose height between the adjacent first compartments equals 0.1-0.3 m, and between the adjacent second compartments, it is higher than that between the first compartments by 0.1-0.3 m. Tank bottom plate is made in the form of trapezoidal trays with width over bottom plate of 0.5-1.5 m and inclination 0.2-0.3 of side walls to tray of tank and having inclination 0.005-0.1 to discharge tray. Specific load exerted on chambers of catching of main mass of insoluble impurities is taken equal to 20-25 cu. m/m. h. EFFECT: higher efficiency of system of settled sediments removal from regulating tank and excluding even periodic silting of structure. 5 cl, 6 dwg

Description

 The invention relates to the construction of sewer systems and can be used to average the costs of domestic and industrial wastewater.

 An analogue is a control tank with a central tray used in storm networks [1, p. 264]. This tank does not have special devices that ensure the effective removal of insoluble impurities deposited in the sediment. Its use for averaging domestic and industrial wastewater leads to rapid siltation of the tank.

 The closest analogue to the claimed invention is a regulating tank containing a tank divided into parts with a supply pipe, an evacuation pipe, a ventilation system and bypass trays, to the beginning of which supply pipes with nozzles are connected [2].

 The design of the tank allows for the formation of sediment over a significant area of the tank. The tank flushing system is extremely complex and cannot be reliable in operation; washing sediment from long-length trays with jets is inefficient, therefore, the regulating capacity will periodically become silted.

 The technical result of the invention is to increase the efficiency of the system for removing precipitation from the control tank, eliminating even periodic siltation of the structure.

The technical problem is solved in that in a control tank containing a divided tank with a supply pipe, an evacuation pipe, a ventilation system and drain trays, each section of the tank is equipped with a settling chamber for collecting undissolved impurities, equipped with pipelines for periodically stirring up and removing sediment in the pump station tank . Each section is also divided along the length by a partition with an aperture into two compartments: the first of them is smaller - from 0.2 to 0.3 parts of the total length of the tank, in which the main amount of sediment is formed and which has devices that allow the sediment to be washed off and removed when emptying the tank, and the second compartment, playing the role of the main water reservoir, making up its main volume and having a length of 0.7 to 0.8 parts of the total length of the entire tank. The sections are divided by thresholds, the height of which is equal - between adjacent first compartments - 0.1 - 0.3 m, and between adjacent second compartments - 0.1 - 0.3 m higher than the height of the thresholds between the first compartments. The bottom of the tank is made in the form of trapezoidal trays with a bottom width of B = 0.5 - 1.5 m and a slope of the side walls to the tray 0.2 - 0.3, directed perpendicularly to the bypass tray of the tank and sloping to the bypass tray 0.005 - 0, 1. The specific load on the capture chamber of the bulk of insoluble impurities is taken q ₀ = 20 - 25 m ³ / m ² • h.

 In other words, in the proposed design of the control tank, the technical problem is solved by controlling the process of sedimentation of sediment and the formation of sediment, specially created conditions for the formation of sediment in those parts of the structure that are equipped with systems or devices that ensure effective removal of sediment or rinsing them with water during the period of emptying .

 The new tank design consists of at least two sections. Each section has a chamber for trapping the bulk of undissolved impurities. In it, the sediment is concentrated in a pyramidal or conical hopper and is removed through a pipeline under hydrostatic pressure. In addition, each section consists of two compartments. In the first of them, the formation of a light precipitate is possible, which is removed by the flow of water coming from the neighboring section in the initial period of filling the tank. In the second compartment, which is the main volume of the structure, the formation of sediment is practically impossible, since the water entering it no longer contains sedimentary substances.

 The control tank has a simple design and its silting is excluded, its operation is characterized by high reliability.

 In FIG. 1 shows a plan of a control tank, FIG. 2 is a section through 1-1, in FIG. 3 is a section according to 2-2, in FIG. 4 is a section through 3-3, in FIG. 5 is a section through 4-4, in FIG. 6 - section through 5-5.

 The control tank 5, rectangular in plan, is divided along the length by a partition, not reaching the sides, into two compartments. On the longitudinal axis of each compartment there are thresholds dividing them into two sections. The height of the threshold 8 in the first compartment is 0.1 - 0.3 m, and the height of the threshold 10 is 0.1 - 0.3 meters greater than the height of the threshold 8.

 At the beginning of each section there is a settling chamber 6, made as a vertical settler (or open hydrocyclones) and designed to precipitate the bulk of insoluble impurities from wastewater.

 The chambers may have a round or rectangular shape in plan with a respectively conical or prismatic bottom, forming a tank for the accumulation of sediment. A pipeline 11 is laid in the lower part of the bottom of the chambers 6, which discharges sediment under hydrostatic pressure into the receiving tank of the sewage pumping station 2. Pipelines 4 are designed to supply sewage 5 from the pressure pipes 3 to the upper part of the distribution channel 15 of the chambers 6 of the control tank 5.

 If necessary, the sediment can be agitated with water through pipelines 14 connected to the pipeline 3 through the pipeline 4.

 The longitudinal longitudinal trays 7 with pits 16 are located along the outer sides at the bottom of the control tank. The slope of the trays to the pits is 0.005 - 0.1. The bottom of the control tank over the entire area is ribbed, forming transverse trapezoidal trays having a slope towards the prefabricated (outlet) trays 7, equal to 0.005 - 0.01. The slope of the side walls to the trays is 0.2 - 0.3. The width of the trays at the bottom is B = 0.5 - 1.5 m, and at the top is (3 - 4) V.

 Along the long outer sides of each section of the control tank 5, prefabricated (outlet) trays 7 with sumps 16 are located. Each pit 16 is connected by a pipe 12 to gravity collectors 1, supplying sewage to the sewage pumping station 2. In the upper part of the prefabricated (discharge) tray 7 ( 200 mm below the side of the regulating tank) are receiving funnels of the overflow pipe 13 connected to gravity feed collectors 1.

 The control tank operates as follows.

 When the wastewater flow rate in the gravity network in front of the pumping station is above the average, a part of the wastewater flow rate through the pipe 4 is discharged into the settling chambers 5 of the control tank 5. After sedimentation of the main part of the suspended solids, water flows through the drainage edges of the settling chambers 6 into the first compartments of the control tank. Sludge from the bottom of the settling chambers 6 through pipelines 11 is periodically removed to the receiving tank of the pumping station 2. If necessary, the sediment can be stirred up by sewage supplied through pipelines 14 to the bottom of the settling chambers. During the stay of wastewater in the first compartment (up to partition 9), further clarification of the water is possible and, as a result, sediment accumulation in this part of the control tank.

 From the first compartment of the control tank, wastewater through the free spaces between the outer side walls of the control tank and the ends of the partition 9 enters the second compartment of the control tank. If sediment precipitates during the stay of wastewater in this compartment, it will be so fluid that it will be washed into the tray 7 with draining wastewater when emptying the control tank. This contributes to the shape of the bottom, also made in the form of transverse trays of a trapezoidal shape.

 The emptying of the tank is carried out during the period of minimal influx of wastewater through pipelines 12 into the gravity collector leading to the pumping station.

 If necessary, the first compartment can be washed. In this case, the filling of the tank is carried out through one settling chamber 6 (for example, the right one). Upon reaching the water level in the right section above the edge of threshold 8, the wastewater will begin to flow through threshold 8 into the first compartment of the left section and, moving along the trapezoidal transverse trays to the longitudinal tray 7, flushes the sediment from them. The sludge together with waste water is removed through the pit 16 and the pipe 12 into the inlet collector. After completion of the flushing, the sludge is shut off the corresponding pipe 12 and the control tank is filled through both settling chambers 6.

 The sediment in the first compartment of the right section is washed off when wastewater is supplied to the left settling chamber 6.

The volume of the control tank is recommended to be determined by the empirical formula:
W _p = 0.42 (K _gen.max - 1) • Q,
where Q is the average daily flow rate of wastewater entering the pumping station, m ³ / day;
K _gen.max is the total maximum coefficient of unevenness [3].

The total area of the settling chambers 6 in the plan is recommended to be determined by the formula:
F _to = B • L = q _p / q _about
where F _to - the total area of the settling chambers, sq.m;
B is the width of the control tank, m;
L is the length of the control tank, m;
q _p - the minimum flow rate entering the chamber equal to
q _p = q _maz - q _mid ;
where q _mid = Q / 24 is the average consumption per hour;
q _max = q _mid • K _gen.max ;
q _o - specific load on water, which is recommended to be taken equal to 20 - 25 m ³ / m ² • h, which will ensure the capture of particles with a hydraulic particle size of 5 mm / s (for the calculation of sand traps it is taken equal to 70 - 130 m ³ / m ² • h).

 The length of the first compartment of the tank should be 0.2 - 0.4 parts of the length of the structure. This length is established from the need for deep clarification of water in the first compartment and to ensure a minimum water load per unit length of threshold 8 when washing sediment in the first compartment.

 The length of the second compartment (after partition 3) is 0.6 - 0.8 of the total length of the tank.

 The proposed design of the control tank for averaging the flow of domestic and industrial wastewater ensures a long uninterrupted operation of the structure.

 Sources of information.

 1) Kalitsun V.I. Drainage systems and structures. - M .: Stroyizdat, 1987.

 2) Patent SU 18080048 A3, E 03 F 5/10, 04/07/93.

 3) SNiP 2.04.03-85. Sewerage. External networks and facilities.

 4) Laskov Yu.M., Voronov Yu.V., Kalitsun V.I. Examples of calculations for sewer facilities. - M .: Stroyizdat, 1987.

Claims (5)

 1. A control tank containing a divided tank with a supply pipe, an evacuation pipe, a ventilation system and drain trays, characterized in that each section of the tank is equipped with a settling chamber for collecting undissolved impurities, equipped with pipelines for periodically stirring up and removing sediment in the pump station tank.  2. The control tank according to claim 1, characterized in that each section is divided along the length by a partition with an aperture into two compartments: the first of them is smaller in size 0.2 to 0.3 parts of the total length of the tank, in which the main quantity is formed sludge and which has devices that ensure flushing and removal of sludge when emptying the tank, and the second compartment, which acts as the main reservoir of water, is its main volume and has a length of 0.7 - 0.8 parts of the total length of the entire tank.  3. The control tank according to claim 2, characterized in that the sections are separated by thresholds, the height of which is between 0.1 to 0.3 m between adjacent first compartments, and 0.1 to 0.3 m higher between adjacent second compartments than the height of the thresholds between the first compartments.  4. The control tank according to claim 1, characterized in that the tank bottom is made in the form of trapezoidal trays with a bottom width of B = 0.5 - 1.5 m and a slope of the side walls to the tray 0.2 - 0.3, directed perpendicular to the drain tray of the tank and having a slope to the drain tray of 0.005 - 0.1. 5. The control tank according to claim 1, characterized in that the specific load on the capture chamber of the bulk of undissolved impurities is taken q ₀ = 20 - 25 m ³ / m ² • h.

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