RU2568702C1 - Device for adjustment of flow and treatment of waste water - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: most preferable area of usage is adjustment of flow and treatment of urban runoff drained from the territory of settlements and (or) industrial enterprises, and also from roads and bridges. The device comprises a cylindrical reservoir (1) with systems of treated water supply (2) and treated water drainage (3). The device is equipped with an underwater facility of sludge movement in the form of a truss with scrapers (4), capable of turning in horizontal plane during switching of a drive (8). In this device rotation from the drive (8) to the truss (4) is transmitted via a hoist drum (11), a rope (12) and a system of horizontal (9) and vertical (10) blocks. On the water surface in the cylindrical reservoir there is a system of collection of floating admixtures in the form of a floating skimmer (13). The system of treated water drainage is additionally equipped with a flexible pipeline (15), one end of which is submerged under the water level and is fixed to the skimmer (13).

EFFECT: increased extent of water treatment from settled and floating admixtures with simultaneous flow adjustment, at the same time reliability of device operation increases, and its design simplification is provided.

4 cl, 3 dwg

Description

The invention relates to sewerage (water disposal) and can be used to regulate (averaging) costs and treat domestic, industrial and rain wastewater. It can also be used in water supply for regulating the flow and purification of wash water from clarifying or deferrizing filters. The most preferred area of use is the regulation of the flow and treatment of rain wastewater discharged from the territory of settlements and (or) industrial enterprises, as well as from roads and bridges.

A device [1] for regulating the flow and treatment of wastewater is known, having the name "Regulating reservoir" and containing a divided tank, a supply pipe, a discharge pipe. In the presented device, each section of the tank is equipped with a settling chamber for collecting undissolved impurities, equipped with pipelines for periodically stirring up and removing sludge (sludge) into the tank of the pumping station.

The disadvantages of the device include the high humidity of the sludge removed from the sump, due to the fact that the sludge is transported to the sump by agitation with water, and water dilutes this sludge. High humidity of the sediment is the reason for the low cleaning effect of suspended solids, because it is not advisable to send the diluted sludge for further processing, so it is pumped into the tank of the sewage pumping station, from where it again enters the control tank, increasing the concentration of suspended solids at the inlet to the control tank and thereby reducing the overall effect of cleaning suspended solids. The disadvantages include the lack of the ability to purify water from floating impurities.

Known settling tank-averager [2], designed for receiving, settling and treatment of wash water quick filters with a view to their reuse. The settling tank-averager comprises a housing divided by vertical partitions into settling tanks, regulating and combined, supply and discharge pipelines and a sludge removal system. In this settler, the middle part of the partition between the settling and regulating tanks is made movable towards the settling tank. It is pivotally mounted at the height of the maximum water level. Windows are located above the movable partition at a mark above the maximum water level in the settling tank by an amount equal to the pressure loss in the openings of the partition to collect water.

When salvo water enters the settling tank, water is poured through the windows from the settling tank into the regulating tank, and at the end of the salvo discharge it again returns to the settling tank through movable partitions. The sludge removal system from the settling and control tank is made of hydraulic pressure.

The given settling tank-averager is characterized by high humidity of the sediment discharged from it and a low effect of purification from suspended solids associated with the presence of a hydraulic system to remove sediment. It is also not possible to purify water from floating impurities.

Known radial sump [3], containing a cylindrical tank, a system for supplying purified water, a system for removing purified water, a means for removing sludge in the form of a farm with scrapers, and a drive, the means for removing sludge is a movable farm connected to scrapers installed with the possibility of movement bottom sludge into a sludge pit communicated with a sludge pump, while the center of the farm is aligned with the center of the hull, and the farm itself is installed below the water level. In this sump, the movable truss is an annular support connected by at least four jumpers to the central axis of the housing. A continuous treadmill in the form of a ring, oriented perpendicular to the end of the annular support, is attached to the sump along the outer perimeter of the annular support of the truss, the annular support touches the rollers mounted in a horizontal plane, perpendicular to the axis of the housing, while the friction mechanism connected to a drive located above the surface of the water.

In the presented device, it is possible to ensure the removal of sediment from the sump with a lower water content, but this is achieved by complicating the design of the sump, due to the presence of 2 rings of large diameter (close to the diameter of the sump). Considering that the designs of settling tanks are usually significant (in the Russian Federation, typical designs of settling tanks are 18, 24 and 30 m), the presence of these rings is also the reason for the high material consumption (metal consumption) of the structure.

Such a sump does not have the ability to purify water in the event of an uneven supply to the sump. The sump can only perform the functions of removing suspended solids and floating impurities from water, but at the same time it cannot provide regulation (averaging) of the flow rate.

Closest to the claimed invention is a device in the form of a radial sump [4] containing a cylindrical tank, a system for supplying purified water, a system for removing purified water, a sludge removal device in the form of a truss with scrapers, endowed with the possibility of rotation in a horizontal plane around an axis aligned with the axis a cylindrical tank, while the scrapers are installed with the ability to move the bottom sludge into the sludge pit in communication with the sludge pump, and the farm with scrapers is installed below the water level and equipped with a connection nennym her farm drive. The described device is taken as a prototype of the invention.

In this device, a farm with scrapers is connected to the drive by means of a vertical drive shaft with a drive wheel attached to it, kinematically connected by a traction chain with guide wheels, and the purified water drainage system is made in the form of an annular tray.

The device manages to reduce the consumption of materials, however, its disadvantage is the low reliability due to the influence on the operation of the means of removing sludge thermal elongation of the traction chain when the temperature of the water fluctuates. With such extensions, the traction chain sags and disengages from the wheels. Especially great are the elongations in the manufacture of a traction chain made of plastic, for which the temperature coefficient of linear expansion is more than 10 times higher than for steel.

In radial sedimentation tanks of great height (more than 4 m), an additional decrease in reliability is due to the presence of a long leading vertical shaft, which leads to its runout (the longer the shaft, the higher the probability of its runout).

Another disadvantage of the device is the complexity of its implementation, due to the uniqueness of the manufacture of the drive wheel and the traction chain. These elements can only be manufactured at specialized enterprises with a high degree of sophistication of sophisticated equipment.

Given radial sump there is no possibility of water purification in case of uneven flow into the radial sump, including with volley tributaries. The sump can only perform the functions of removing suspended solids from water, but at the same time it cannot provide regulation (averaging) of the flow rate. It also cannot provide water purification from floating impurities.

The technical problem solved by the present invention is to create a device design capable of operating at a variable water temperature and at any height of the device. In this case, the device must ensure the purification of water from settling and floating impurities with simultaneous regulation of flow.

The technical result of the invention is to increase the reliability of the device, simplifying the design and making it possible to purify water from settling and floating impurities in case of uneven inflow.

To solve this problem, a device for controlling the flow rate and wastewater treatment is proposed, in which the truss with scrapers is connected to the truss drive through a system of horizontal and vertical blocks, a reversing winch drum and a cable wound with at least one turn on a reversing winch drum and attached to its ends to the peripheral end of the truss, while the horizontal and vertical blocks are attached with brackets to the wall of the tank from its inner side, the attachment point of the cable to the truss is made from the tr a wasp facing the container wall, and the gap between the lower plane of the horizontal block and the top of the bracket is less than the diameter of the cable; inside the cylindrical container there is a system for collecting floating impurities in the form of a floating skimmer with a flexible discharge pipe for floating impurities attached to it, while the purified water removal system is also equipped with a flexible pipe, one end of which is submerged under the water level and attached to the skimmer. The end of the flexible pipe of the purified water drainage system submerged under the water level is equipped with an additional pipe connected to it, which communicates the internal cavity of the flexible pipe with the atmosphere near its inlet section, and the immersion depth of the inlet section of the flexible pipe corresponds to the flow rate in the purified water drainage system.

The device further comprises an overflow pipe, the inlet section of which is located below the emergency water level in the cylindrical tank at a depth corresponding to the flow rate of the water in the overflow pipe, and the internal cavity of the overflow pipe is in communication with the atmosphere near its inlet section. The proposed device is equipped with a stand for a skimmer with a height exceeding the height of the zone of accumulation of sludge.

During the operation of the device, water enters the cylindrical tank through the purified water supply system with a flow rate exceeding the flow rate through the purified water drainage system, as a result of which the water level in the cylindrical tank begins to rise. When the water level in the tank rises to a height that reaches the end of the flexible pipe of the treated water drainage system, water begins to be removed from the tank with a constant flow rate corresponding to the immersion depth of the inlet section of the flexible pipe. Simultaneously with the described movement of water through the tank, the processes of sedimentation of suspended matter to the bottom of the tank and the emergence of floating impurities, for example, petroleum products, occur. The latter by means of a skimmer are discharged from the tank, for example, into the oil reservoir. From the sediment settling to the bottom of the sludge tank, sludge is formed, which is raked by means of moving the sludge in the form of a farm with scrapers into the sludge pit, from where the sludge is discharged outside the tank.

When the farm drive is turned on, the winch drum is rotated, as a result of which one end of the cable starts to be wound on the winch drum, and the other end of the cable is wound from the drum. The rotation of the winch drum leads to the rotation of the farm with scrapers and the movement of bottom sludge into the sludge pit in communication with the sludge pump. When the cable moves, its attachment to the truss passes between the block and the surface of the inner wall of the tank. When the edge of the pit is reached, the reverse winch drum is turned off from work, and then turned on for rotation in the opposite direction (for example, by a signal from the limit switch). After such a switch, the movement of bottom sludge into the sludge pit is carried out to the other side of the pit in the manner described above, after which the cycle repeats.

When water volumes exceeding the calculated values enter the device (for example, in rare rains of high intensity), an overflow pipeline is included in the operation. In the case of processing the entire volume of water in the sump, the skimmer is lowered onto the stand and the water drain from the tank stops until the treated water arrives again.

New in the claimed invention is:

- connecting the truss with scrapers to the truss drive through a system of horizontal and vertical blocks, a reversing winch drum and a cable wound with at least one turn on the reversing winch drum and attached with its ends to the peripheral end of the truss, while horizontal and vertical blocks are attached using brackets to the wall of the tank from its inner side, the attachment point of the cable to the truss is made from the side of the cable facing the wall of the tank, and the gap between the lower plane of the horizontal unit and the top of the bracket m nshe cable diameter;

- retrofitting the device with a system for collecting floating impurities, with the end of a flexible pipeline for discharging floating impurities attached to it and the end of a flexible pipe for a system for removing purified water;

- placement of the inlet section of the pipeline of the purified water drainage system at a depth corresponding to the flow rate in the purified water drainage system;

- retrofitting the device with an overflow pipe, with the placement of its inlet section at a depth corresponding to the flow rate of water in the overflow pipe;

- communication of the internal cavity of the pipeline of the drainage system of the cleaned and overflow pipeline with the atmosphere near the inlet section;

- equipment of the device with a support under the skimmer equal to the height of the zone of accumulation of sludge.

The use of these distinguishing features in devices for regulating the flow and treatment of wastewater in order to increase the reliability of the device, simplify the design and provide the ability to purify water from settling and floating impurities in case of uneven inflow is not identified from the existing prior art, which allows us to conclude that the claimed invention the criterion of "inventive step".

The connection of the truss with scrapers with the truss drive through a system of horizontal and vertical blocks, a reversing winch drum and a cable wound with at least one turn on the reversing winch drum and attached with its ends to the peripheral end of the truss, increases the reliability of the device and simplifies its design. The placement of the attachment point of the cable to the truss from the side of the cable facing the vessel wall provides unhindered passage of this node through the gap between the vessel wall and the block. Limiting the gap between the lower plane of the horizontal unit and the top of the bracket so that it is less than the diameter of the cable allows you to further increase the reliability of the device, because in this case, a possible displacement of the cable relative to the groove of the unit does not lead to an emergency stop of the device - when the winch drum is turned on, the cable is pulled and again moved to the groove of the unit.

This excludes the effect of temperature changes and increasing the height of the tank on the reliability of the device. In addition, opportunities are expanding to increase efforts to ensure the movement of the farm, including in cases of raking compacted sludge.

The equipment of the tank with a system for collecting floating impurities in the form of a floating skimmer with the ends of a flexible pipe attached to it for discharging floating impurities and a flexible pipe for a purified water removal system, the last of which is immersed under the water level, makes it possible to eliminate the influence of a variable level on the quality of water treatment and to ensure this cleaning with simultaneous flow control. The flow rate of purified water discharged from the unit remains unchanged throughout the “fill-empty” cycle and does not depend on the inflow of treated water and the level of water in the tank. A numerical characteristic of the quality of regulation may be a control error, which is the ratio of the difference between the maximum and minimum values of the flow rate in the system for the removal of purified water to the average value of this flow rate. In the proposed device, the indicated ratio (the value of the control error) is close to 0.

The communication of the internal cavity of the flexible pipe of the purified water removal system and the internal cavity of the overflow pipe with the atmosphere near their inlet sections further reduces the control error, preventing the formation of a funnel, and excludes the ingress of floating impurities into the pipelines.

The equipment of the device with a stand for a skimmer, the height of which exceeds the height of the zone of accumulation of sludge, improves the quality of treatment, eliminating the ingress of sludge into the system for discharging purified water.

The invention is illustrated in the drawing, where figure 1 shows a diagram of the device, figure 2 is a drawing of the mounting of the horizontal unit to the wall of the tank, and figure 3 is a plan of the tank.

A device for controlling the flow rate and wastewater treatment comprises a cylindrical tank 1, a purified water supply system 2, a purified water drainage system 3, a sludge transfer device in the form of a truss with scrapers 4, endowed with the possibility of rotation in a horizontal plane around axis 5, aligned with the axis of the cylindrical container while the scrapers (not shown in the drawing) are installed with the possibility of moving the bottom sludge into the sludge pit 6, in communication with the suction pump 7, and the farm with the scrapers is installed below the water level (not shown in the drawing) and about equipped with a farm 8 drive connected to it. A farm with scrapers 4 is connected to a farm 8 drive through a system of horizontal 9 and 10 vertical blocks, a reversing winch drum 11 and a cable 12, wound with at least one turn on the reversing winch drum 11 and attached at its ends to the peripheral the end of the truss 4. The horizontal 9 and vertical 10 blocks are attached using brackets to the wall of the tank from its inner side, while the attachment site 21 of the truss to the cable is made from the side of the cable 12 facing the inner wall bone 1, and the gap between the lower plane of the horizontal block 9 and the top of the bracket 22 is less than the diameter of the cable.

Inside the cylindrical container there is a system for collecting floating impurities in the form of a floating skimmer 13 with an end attached to it of a flexible pipeline for discharging floating impurities 14, while the system for removing purified water 3 is also equipped with a flexible conduit 15, one end 16 of which is submerged under the water level and attached to the skimmer 13. Submerged under the water level, the end 16 of the flexible pipe 15 of the purified water drainage system is equipped with an additional pipe 17 connected to it, communicating the internal cavity of the flexible pipe water 15 with atmosphere near its end 16.

The device further comprises an overflow pipe 18, the inlet section 19 of which is located below the emergency water level in the cylindrical tank. In this case, the internal cavity of the overflow pipe is in communication with the atmosphere by the pipe 20.

The device contains a stand 23 under the skimmer 13, the height of which exceeds the height of the zone of accumulation of sludge. The specified stand can be installed on the bottom of the tank or attached to the skimmer.

The device for controlling the flow and wastewater treatment is as follows. Water is supplied to the cylindrical container 1 through the purified water supply system 2 with a flow rate exceeding the flow rate through the treated water drainage system 3, as a result of which the water level in the cylindrical container starts to rise. At the same time, the process of precipitation of suspended solids to the bottom of the tank and the movement of floating impurities to the surface of the water proceeds. Sludge is formed from suspended solids at the bottom of the tank, which is scooped up by means of moving the sludge in the form of a truss with scrapers 4. Sludge is scrapped when the truss with scrapers 4 is incompletely rotated around axis 5 into the sludge pit 6, from where the sludge pump 7 is pumped outside the cylindrical tank 1.

The rotation of the truss with the scrapers 4 around the axis 5 is carried out when the drive 8 is turned on, which drives the drum of the reversing winch 11, as a result of which one end of the cable 12 starts to be wound on the winch drum, and the other end of the cable 12 is wound from the drum, which leads to the said rotation farms. The movement of the cable is then guided by horizontal blocks 9 and vertical blocks 10. In the process of moving the cable 12, the attachment node 21 passes through the gap between the horizontal block 9 and the inner surface of the wall of the tank 1.

When the farm with the scrapers 4 reaches the edge of the silt pit 6, the drum of the reversing winch 11 switches to rotation in the opposite direction (for example, by a signal from the limit switch - not shown in the drawing). After such a switch, the movement of bottom sludge is carried out to the other side of the sludge pit 6 in the manner described above, after which the cycle repeats.

The collection of floating impurities from the surface is carried out in a known manner by means of a floating skimmer 13 through the end of the flexible pipe 14 connected to it.

With a further rise in the water level in the cylindrical tank to a height reaching the end 16 of the flexible pipe 15, water begins to be discharged from the tank through the purified water drainage system 3 with a constant flow rate corresponding to the immersion depth of the flexible pipe end 16 under the water level in the tank. During the movement of water through the inlet section of the end 16 of the flexible pipe 15, the pressure in its initial section is maintained at atmospheric pressure through the pipe 17, which eliminates the possibility of the formation of a funnel and suction of floating impurities into the system for removing purified water 3.

When water volumes exceeding the calculated values enter the device (for example, in rare rains of high intensity), an overflow line 18 is turned on, water into which flows through the inlet section 19 from a depth determined by the calculation of the known flow rate during overflow. To exclude the possibility of a funnel and suction of floating impurities, the pressure near the inlet section 19 is balanced by means of the pipe 20. The immersion depth of the inlet section of the end 16 of the flexible pipe 15 and the inlet section 19 of the overflow pipe 18 is determined by the formula known from hydraulics

where λ is the hydraulic resistance coefficient of the treated water drainage system 3 or overflow pipe 18;

L is the length of the pipeline system for the removal of purified water 3 or overflow pipe 18;

d is the diameter of the pipeline system for the removal of purified water 3 or overflow pipe 18;

Σξi is the sum of the coefficients that take into account local hydraulic resistance in the pipelines of the treated water removal system 3 or in the overflow pipe 18;

g is the acceleration of gravity;

v is the speed of movement of water in the pipeline of the purified water removal system 3 or in the overflow pipe 18.

The speed of water in the pipeline is found from the formula

v = 4Q / πd ² ,

where Q is the flow rate in the pipeline of the purified water removal system 3 or in the overflow pipe 18.

In the case of processing the entire volume of water in the sump, the skimmer 13 is lowered to the stand 23, the height of which exceeds the height of the zone of accumulation of sludge. This completes the process of processing the volley inflow received by the device and the device is ready to receive and process new volumes of wastewater. In case of a small flow of purified water to the tank 1, the device operates as described above, while the water level and, accordingly, the skimmer 13 in the tank 1 rise to a lower height, however, the flow rate in the treated water drainage system 3 remains unchanged.

Thus, the device provides an increase in the degree of purification of water from settling and floating impurities while controlling the flow rate, while increasing the reliability of the device and simplifying its design.

A device for controlling the flow rate and wastewater treatment and its operation do not contain elements and operations that may not be feasible with the current level of technological development, which allows us to conclude that the claimed invention meets the criterion of "industrial applicability".

Information sources

1. Patent RU 2124480 C1, E03F 5/10, C02F 1/00, 10.01.99.

2. Patent RU 2131500 C1, C02F 1/00, 06/10/99.

3. Patent RU 2164437 C2, B01D 21/06, 03/27/2001.

4. Finnchain Company [Electronic resource]: Products. Systems for radial sedimentation tanks. URL: http://www.fimchain.fi/sistemy-dlja-radialnyx-otstojnikov.htm (accessed 04.02.2014).

Claims (4)

1. A device for controlling the flow and treatment of wastewater, containing a cylindrical tank, a system for supplying purified water, a system for discharging purified water, a sludge conveyor in the form of a truss with scrapers endowed with the possibility of rotation in a horizontal plane around an axis aligned with the axis of the cylindrical container the scrapers are installed with the possibility of moving the bottom sludge into the sludge pit communicated with the sludge pump, and the farm with scrapers is installed below the water level and equipped with the farm drive connected to it which consists in that the truss with scrapers is connected to the truss drive through a system of horizontal and vertical blocks, a reversing winch drum and a cable wound at least one turn on a reversing winch drum and attached at its ends to the peripheral end of the truss, while horizontal and vertical blocks are attached to using brackets to the wall of the tank from its inner side, the attachment point of the cable to the truss is made from the side of the cable facing the wall of the tank, and the gap between the lower plane of the horizontal unit and the top m bracket less than the diameter of the cable; inside the cylindrical container there is a system for collecting floating impurities in the form of a floating skimmer with a flexible discharge pipe for floating impurities attached to it, while the purified water removal system is also equipped with a flexible pipe, one end of which is submerged under the water level and attached to the skimmer. 2. The device according to claim 1, characterized in that the end of the flexible pipe of the purified water drainage system immersed under the water level is equipped with an additional pipe connected to it, which communicates the internal cavity of the flexible pipe of the purified water removal system with the atmosphere near its inlet section, and the immersion depth of the end the flexible pipeline of the purified water drainage system corresponds to the flow rate in the purified water drainage system. 3. The device according to claim 1 or 2, characterized in that it further comprises an overflow pipe, the inlet section of which is located below the emergency water level in the cylindrical tank to a depth corresponding to the flow rate of the water in the overflow pipe, and the internal cavity of the overflow pipe is connected to the atmosphere by pipes near its inlet section. 4. The device according to p. 1 or 2, characterized in that it further comprises a stand for the skimmer, the height of which exceeds the height of the zone of accumulation of sludge.

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