RU2107782C1 - Sewerage return siphon - Google Patents

Abstract

FIELD: sewerage systems. SUBSTANCE: this relates to devices for transportation of liquid waste from territory of inhabited areas by gravity through deep-laid sewage lines, and it can be used for regulation of waste fluid flowing speed, removal of suspended and floating matter in condition of connecting additional lines over length of return siphon pipe. Sewerage return siphon has delivery and discharge manifolds, horizontal pipeline, and inclined delivery and discharge sections. Delivery section has inlet shaft 1, return siphon pipeline 2, domestic effluent pipe 3, immersible shutters 4 at places of conjugating inclined sections with horizontal section, pipeline for air delivery to underwater space 5, ventilation pipe 7. Horizontal section of return siphon is made up of horizontal pipeline of return siphon 8, side connection units 9 connected with horizontal pipeline of return siphon by means of connecting passages 10. Side connection unit 9 is located in shaft 11 with covering 12 divided by means of partition 13 into domestic effluent compartment 14 and rain compartment 15. Installed in covering are domestic effluent riser 16, air evacuation pipeline with non-return valve 18 connected with air vent riser 19, rain flow riser 22 connected with side delivery manifold. Discharge section of return siphon is made up of shaft 24, pipeline 25, and discharge shaft 26. Located in lower part of return siphon 25 is pipeline for removing domestic effluent 31, with its upper discharge end being connected with shaft 26 which is provided with gate 32 above pipeline 31. EFFECT: high efficiency. 3 dwg

Description

 The invention relates to sewage, and in particular to devices for transporting liquid waste from the territories of settlements in a gravity flow mode, deep inherent collectors.

 A device for transporting sewage fluid-duker, including the inlet gravity collector operating in pressureless mode, the inlet chamber, the outlet gravity collector [1].

 The disadvantage of this design is the inability to use it if you need to connect additional fluid costs along the way; the inability to control the fluid flow rate in the pipe of the siphon, which leads to siltation of the base of the pipe of the siphon.

 The closest technical solution to the proposed one is an air-cushioned sewage sump (pneumatically controlled). The duker includes an inlet manifold, an inlet section consisting of an inlet shaft, with an inclined pipe of the siphon, an inlet air pipe connected to the immersion damper at the end in the lower part of the section, and at the top connected to the compressor, the outlet section of the siphon, including the ascending inclined pipe of the siphon, immersed a flap at the bottom and an outlet shaft at the end connected to the outlet manifold, a horizontal section with an air cushion in the underwater space, located between the bottom of the inlet and outlet sections [2].

 This device has a limited scope only with a constant flow rate of liquid along the length of the pipe of the siphon, which excludes the possibility of connecting additional costs along the path of the fluid. With large fluctuations in costs during the year, for example, in general-purpose sewage, siltation of the descending and ascending sections of the duker occurs.

 Accordingly, the use of this design is impossible to control the speed of movement of the waste fluid along the length of the pipe of the siphon and to remove suspended and floating substances when the flow rate of the waste fluid is variable along the length of the pipe of the siphon.

 The technical problem to which the invention is directed is the ability to control the speed of movement of the waste fluid in the horizontal section of the siphon and remove suspended and floating substances, prevent siltation and improve the operation of the sewer network in the conditions of connecting additional costs, i.e. variable fluid flow along the length of the pipe duker.

 The essence of the invention lies in the fact that the duker comprising a pipeline with horizontal and inclined inlet and outlet sections, inlet and outlet sewage collectors, inlet and outlet shafts located respectively in front of the inlet and after the outlet sections of the duker, and submersible dampers installed in the interface inclined sections with horizontal with the formation of an air cushion in the underwater space, to which the air supply pipe is connected from the side of the intake shaft, further comprises at the bottom of the inlet section, the domestic water flow pipe installed by the upper end in the inlet shaft, and the lower one into the pit under the submersible damper, in addition, in addition to the horizontal section, the contaminated air removal pipeline with a movable valve at the lower end and nodes lateral connection shafts connected by a lower end with a connecting channel to the horizontal section of the duker, and the upper one with a lateral supply manifold.

 A vertical partition is installed in the shaft of the lateral connection unit under the overlap so that its lower end is placed at a mark below the estimated depth of the fluid flow, and a water well is made from below. In the ceiling there is a household riser connected to the side intake manifold tray, a pipeline, an air vent with a safety valve connected to the upper end with an air riser, an air purifier, and through a pipeline to a side supply manifold. On the floor there is also a rain flow riser connected to the upper end by means of a drain funnel with a side supply manifold.

 A pit is placed at the bottom of the shaft with an overlap under the pipeline to remove contaminated air, and at the top of the mine is connected to its air purification unit.

 The outlet section further includes a household flow pipe, the upper end of which is connected to the exhaust shaft, and the lower end - with a sump for collecting precipitation, a gate installed above the upper end of the household flow pipe.

 Distinctive features from the prototype are the presence in this design of the duker connection nodes located on the side of the horizontal section of the duker in the mines, divided in the lower part into two compartments for household and rain expenses, using a vertical partition with risers connected to them for household, rain expenses, with also the riser of the air vent and the air removal pipe connected to it with a safety valve, at the upper end of which there is an installation for air purification, the inlet section of the duker laid in the lower part of the household flow pipe, an outlet section with a household flow pipe laid in the lower part of it with sediment, a pit and a gate at the upper end of this section, a contaminated air removal pipeline with a movable valve, a polluted air purification plant at the top of the shaft with overlapping beginning of the exit section.

 The presence of connection nodes located on the side and with two compartments of household and rain expenses at a different combination of expenses makes it possible to organize the intake of waste fluid into the sump along the fluid path.

 The vertical partition in the connection node allows you to separate household consumption from rain and at the same time create an air cushion in the underwater space of the duker with excess air pressure in it.

 The presence of risers-air vents, domestic consumption and rain consumption, a contaminated air removal pipe with a movable valve at the end, allows you to organize the movement of liquid from the air, also allows you to take household liquid flow, which, when falling along the riser, captures air and pumps it into the underwater space duker's pipes, squeezing the fluid flow and providing the necessary speed of transportation of suspended and floating substances, and the riser of the rain flow rate - allows you to divert the rain flow into tdelenie rainwater flow, which also occurs in the air compartment, the air vent riser.

 The presence of an air removal pipeline with a safety valve allows, in case of an increase in pressure in the underwater space of the siphon above the permissible limit, to discharge part of the air and, as a result, lower the position of the piezometric line.

 The presence of a shaft with an overlap allows you to place in them a contaminated air removal pipeline with a movable valve at the end, an air purification plant, an immersion damper, which together allows you to create an air cushion and control the operation of the siphon by changing the fluid flow rate in it.

 The air purification installation allows you to organize the air cycle in the connection nodes and at the same time protect the underwater space of the pipe of the siphon from destruction as a result of gas corrosion.

 The household flow pipe in the inlet and outlet sections increases the efficiency of suspension removal in these sections, and also allows you to transport part of the waste fluid flow with sediment and air to the horizontal section of the duker, where an air cushion is created in the underwater space. The pit and the gate at the outlet section, at the lower and upper end of this section, respectively, allows for the regulation of the fluid velocity and the removal of sediment that accumulates at the beginning of the outlet section.

 It is known to use an exhaust air duct to remove air when it is injected into a collector operating in a duker mode, it is also known to use overlap to prevent flooding of the working and operational compartments of the mine shaft of a device for transporting waste fluid (ed. USSR N 1631140, BI. N 3, 1991). The differences are in the location of the overlap and the presence of a partition. The total application of the known devices is possible only at a constant flow rate, allows the connection of costs along the length of the duker, but does not allow the regulation of fluid velocities in order to remove suspended and suspended solids.

 In FIG. 1 shows a diagram of a siphon, longitudinal section; in FIG. 2 - longitudinal sections of the input and output sections, in FIG. 3 node lateral connection to the duker, section.

 The duker includes the input, horizontal, output sections of the duker. The inlet section consists of the inlet shaft 1 of the siphon, the pipe of the siphon 2, laid with a straight slope, the household flow pipe of a standing liquid 3, laid at the base, the submersible damper 4 at the end of the section, the air supply pipe to the underwater space 5, compressor 6, ventilation pipe 7 .

 The horizontal section of the siphon consists of a horizontal pipe of the siphon 8, lateral connection nodes 9 connected to the siphon pipeline using the connecting channels 10. The lateral connection node 9 to the siphon is located in the shaft 11, which is divided in the lower part under the ceiling 12 using the partition 13 into two compartments namely, domestic flow rate 14 and rain flow rate 15. In the ceiling, respectively, a domestic flow riser with an inlet funnel 16 is connected, connected to the tray of the side supply manifold 17, a discharge pipe an ear with a non-return valve 18, connected to the riser-vent 19, which is connected with the upper end to the air purification unit 20, connected by a pipe 21 to the inlet manifold and the atmosphere, a rain-flow riser with an inlet funnel 22, which is connected to the side inlet manifold and mounted on the level of the calculated fluid flow corresponding to the household fluid flow rate. A water well 23 is installed in the lower part of the mine.

 The outlet section of the siphon consists of a shaft 24, a siphon pipe laid with a reverse slope 25, and an exhaust shaft 26. In this case, the shaft 24 has an overlap 27 in the lower part, and an immersion damper 28 with a lower end at a mark below the depth of the estimated fluid flow is installed under the overlap. A contaminated air removal pipe is installed in the submersible damper with a movable valve at the end 29, which is connected to the air purification unit by the upper end. A sump for collecting sludge 30 is installed in the lower part of the mine. The siphon pipe in this section in the lower part has a household discharge pipe 31, which is lowered into the sump for collecting sludge, and the upper end to the outlet shaft, which is above the household waste pipe has a gate 32.

 For ventilation of the exhaust manifold in its upper part, an air supply pipe 33 is connected, the upper end of which is vented to the atmosphere.

 The supply and discharge of wastewater to the siphon is carried out respectively by supply 34 and discharge 35 collectors.

 Duker works as follows.

 Sewage through the inlet manifold 34 enters the inlet section. Moreover, if the fluid flow rate corresponds to the domestic flow rate, then the main part of it, together with the sediment, enters the domestic flow rate pipeline 3, which allows the transportation of suspended solids and eliminates siltation. The wastewater then flows into the horizontal section of the siphon behind the submersible damper 4. When the flow rate of the wastewater increases, for example during rain, the entire cross section of the siphon pipe 2 is switched on, but the sediment and particles drawn along the bottom move in the household siphon 3. low costs, the waste fluid also carries with it a small amount of air involved in the formation of an air cushion in the underwater space of the horizontal section of the duker. Simultaneously with this lateral inlet manifold 17, the waste fluid enters the household flow riser with an inlet funnel 16 and then into the household consumption compartment 14. In this compartment, air captured by the falling liquid is released and an air cushion is formed in the underwater space. In this case, the excess energy of the incident stream from the riser of domestic consumption with an inlet funnel is extinguished in the water well 23.

 After the water well passes through the connecting channel 10, it enters the horizontal section of the pipe of the siphon 8, where its stratified flow occurs, i.e. in the lower part of the pipe is liquid, and in the upper part of the air under positive positive pressure.

 The air cushion in the duker is carried out by the device of the submersible damper 4 at the entrance to the horizontal section of the duker and the immersion damper 28 at the exit of the horizontal section and the partitions 13 arranged in the nodes of the side connection to the duker. When the flow rate of wastewater increases along the lateral inlet manifold 17, the domestic riser with an inlet funnel operates in a pressure mode and part of the liquid begins to flow into the rainwater riser with an inlet funnel 22, trapping air when it falls. However, excess air flow into the horizontal pipe of the duker can change the hydraulic parameters of the flow and create a sharp rise in the piezometric line, and, accordingly, flooding of the supply manifold. To eliminate this situation, air is released in the rain flow compartment 15, which enters the air purifier 20 to the air purification unit 20, and then through the pipe 21 or back to the collector or to the atmosphere. In the event of a sharp increase in air pressure in the underwater space of the pipe of the duker, a valve opens on the air removal pipe 18, which ultimately eliminates flooding of the supply manifold. The regulation of the liquid level in the horizontal pipe of the siphon is ensured by the contaminated air removal pipeline with a movable valve 29, which is automatically installed in the lower part at a level corresponding to the calculated level of liquid flow. At the output section, the fluid movement can be regulated using the gate 32. Accordingly, at low flow rates, the gate closes and the entire flow with sediment from the sump for collecting sediment 30 through the domestic flow pipe 31 enters the exhaust shaft 26, and then into the outlet manifold 35. For large waste fluid flow, i.e. when it rains, the entire flow rate of the wastewater goes over the entire cross section of the pipe of the siphon 25 and then is discharged to the exhaust manifold 35. If the air flow carried away in the connection nodes is insufficient for the formation of an air cushion, it is necessary to turn on the compressor 6 and the air supply pipe inject it into the underwater space 5. Ventilation of the inlet node is provided using a ventilation pipe, 7, and the outlet node and the exhaust manifold - using the air supply pipe 33.

Claims (1)

 A sewer pipe comprising a pipeline with horizontal and inclined inlet and outlet sections, inlet and outlet sewage collectors, inlet and outlet shafts located respectively in front of the inlet section and after the outlet section of the pipe, and submersible dampers installed at the junctions of the inclined sections with horizontal the formation of an air cushion in the underwater space, to which the air supply pipe is connected from the side of the intake shaft, characterized in that the duker is equipped with a pipe domestic waste water flow gadgets located in the bottom of the inclined sections, the upper ends of these pipelines located respectively in the inlet and outlet shafts, and the lower ones in the pits of the interface of the horizontal section, respectively, behind the submersible damper of the inlet section and after the submersible damper of the outlet section, and a mine located above the pit of the outlet section with overlapping at the level of the horizontal section, in which the contaminated air removal pipeline with moving a lap at the end, in communication with the underwater space and the gate installed in the outlet shaft above the upper end of the sewage flow pipeline, in addition, the duker is equipped with a number of shafts of lateral connection units connected by connecting channels and water wells to the horizontal section of the duker, each shaft being connected with a lateral supply manifold and is divided at the level of the horizontal section by an overlap with a lower vertical partition, while a connected pipeline is placed above the overlap with a lateral inlet manifold and atmosphere, an air purification unit with a riser-air vent and an air removal pipe with a safety valve passed through the ceiling, a rain-flow riser with an inlet funnel mounted on the lateral inlet manifold, and a sewage riser of the lateral inlet manifold, also passed through the ceiling, with the riser and the riser riser passed through the ceiling behind the vertical partition, the lower edge of which is located in the slaughter ohm well at a mark below the estimated depth of wastewater.

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