RU201007U1 - ILOSOS - Google Patents

Abstract

Sludge pump refers to devices that serve to separate activated sludge from biologically treated water, which includes a central bowl with the possibility of attachment to a central support to ensure its rotation, and connected by a sludge pipe to a single sludge tank, into which sludge pipes go out, connecting the suckers to the sludge tank and equipped with regulators of the sludge flow, which are telescopic pipes with a screw drive, which are a continuation of the sludge pipe in the sludge tank. Sludge collection tank is made with the possibility of connection with a bridge rotating around the central support. The technical result is to increase the efficiency of the sludge pump by placing all regulators of the sludge flow in a single sludge tank. 2 wp f-ly, 2 dwg

Description

1. Field of technology.

The useful model relates to the field of wastewater treatment, in particular to devices serving to separate activated sludge from biologically treated water coming out of aeration tanks.

2. State of the art.

A sludge pump for a radial secondary clarifier is known from the prior art (RF patent for invention No. RU 2625701 C1, published on July 18, 2017). The sludge pump consists of a truss, at least one discharge chute, a central support, a suction system with scrapers. At least one suction cup is made with an individual adjustment system, and at least one discharge chute is made with at least one slide gate.

The disadvantage of this sludge pump is that the discharge chute is an open chute. The flow regulators are distributed along the bridge because they can only be installed where the pipes from the suckers cut into the chute, that is, directly above the suckers. For example, for a secondary sedimentation tank with a diameter of 40 meters, the distance between the extreme regulators will be about 18 meters. Therefore, the operator at such a distance cannot see all the regulators at the same time and compare the sludge flows. Despite the presence of a control system, the design features of this sludge pump do not allow for a qualitative assessment of the concentration of sludge at different radii of the secondary clarifier, since all flows of sucked sludge are mixed in the tray, forming a flow directed towards the central column. The flow from each farther from the center of the secondary settler sucker affects the flow from the closer to the center of the settler of the suction. Therefore, it becomes impossible to visually assess the quality of the sludge on each regulator. The placement of flow regulators along the entire length of the trough creates conditions for a low flow rate of sludge in the trough, which entails the settling of contaminants at the bottom of the trough and necessitates periodic cleaning of the trough. Thus, the well-known sludge pump does not solve the main problems of wastewater treatment in secondary sedimentation tanks.

3. Disclosure of the essence of the utility model.

The sludge pump, which is claimed, is designed to remove activated sludge that falls to the bottom of the secondary clarifier, and is a rotating mechanism with a peripheral drive, systems for supplying sludge mixture and sludge removal.

The technical result, which the utility model is aimed at, is to increase the efficiency of the sludge pump by placing all regulators of sludge flow in a single sludge tank, which gives the following advantages:

- the ability to visually compare the flows and quality of the sludge on each suction, since the flow of sludge passing through one flow regulator does not affect the flow of sludge passing through another regulator;

- Convenience of visual control of the concentration and flow of sludge, the ability to quickly regulate the flow of sludge manually, standing in one place;

- the required speed of sludge flow in the sludge pipes is provided, which excludes the sedimentation of contaminants.

The technical result is achieved in the following device.

The sludge pump consists of a bridge, a central support, a drive trolley with a snowplow unit, a spire with a pivoting device of the bridge, a rotating central nozzle, a rotating device of a central nozzle, a guide cylinder, at least one sludge pipe, at least one regulator of sludge flow, a sucker , sludge collection tank, connecting sludge line, sludge removal pipeline, central ring pantograph, control cabinet, overflow cleaning device.

The bridge structure is a spatial truss. The truss rods are made in the form of a bent profile made of wrought aluminum alloy, which is characterized by high strength and corrosion resistance. The truss is assembled using rivets made of aluminum alloy. Such a constructive solution made it possible to provide the bridge with low windage and high strength with guaranteed, in comparison with a welded structure, corrosion resistance and, as a consequence, increased service life.

The bridge deck is made up of original unified lattice elements (slotted deck) with an anti-slip surface, made of modern polymer material, resistant to UV radiation and low temperatures. Such a constructive solution makes it possible to guarantee a "dry" surface of the flooring and to increase its maintainability under any weather conditions.

At the end of the bridge there is a staircase, stair treads with an anti-slip surface.

All other main parts of the sludge pump, except for wheel disks, bearings and bearing assemblies, are made of stainless steel. To prevent electrochemical corrosion, the connection of aluminum alloy parts with stainless steel parts is carried out using bolted joints using dielectric distance elements.

The sludge suction bridge revolves around the central support. The central part of the bridge rests on the central support through a spire with a rotary support, and the peripheral part of the bridge rests on the side of the secondary sump through a drive bogie. The axle is attached to the slewing ring, which is a large diameter bearing for hoisting applications, via a fork joint.

The central support is a vertical pipe with windows in its upper part through which the sludge mixture enters the secondary clarifier - the central support is installed on the bottom of the secondary clarifier above the supply channel and is attached to it with anchor bolts. The design of the central support allows it to be mounted in secondary sedimentation tanks built according to a standard design. At the same time, the revision of the construction part of a typical secondary sedimentation tank is minimal, not affecting its power building structures. The central support also serves as a load-bearing structure for the central glass and guide cylinder.

The central nozzle is attached to the top of the central support on the rotating device of the central nozzle and is a rotating container, which is connected by a sludge removal pipeline with the sludge chamber of the secondary clarifier. The guide cylinder is attached to the central glass using special brackets, the design of which allows it to be adjusted vertically. The liner of the guide cylinder is made of corrosion-resistant steel or polypropylene sheet.

A sludge tank and sludge pipes, complete with suckers, are suspended from the bridge.

The sludge collection tank is connected to the central nozzle by a connecting sludge pipe. The connecting sludge pipeline is located below the water level in the secondary sump and is equipped with compensators that ensure the leveling of possible movements of the sludge tank and the central nozzle relative to each other during operation of the sludge pump.

The sludge pipes connect the suckers to the sludge collection tank. The pots have a rubber skirt, which eliminates possible unevenness in the bottom of the secondary clarifier, thus ensuring highly efficient removal of settled sludge from it. Each sludge pipe at the entrance to the sludge tank is equipped with an individual flow regulator inside the tank. The flow regulator is a telescopic pipe, which is an extension of the sludge pipe, with an open top end and with a screw drive. The joint between the regulator pipe and the sludge pipe is sealed. The upper cut of the regulator pipe can be moved by means of a screw drive from a position above the water level in the secondary clarifier down to the upper cut of the sludge pipe and back.

Two-wheel drive trolley, with direct drive from a geared motor to the front wheel. The geared motor is controlled by a frequency converter. The choice of the front wheel of the bogie as the drive wheel is due to the vector of loads arising during the operation of the sludge pump due to its design features. The bogie wheels are fitted with solid tires. The snowplow assembly is mounted on the cart, which is a rotating brush with a drive.

The sludge pump is equipped with an overflow cleaning device, fixed on swivel brackets to the bridge above the secondary sump overflow tray and representing an electrically driven brush rotating around a vertical axis.

The sludge suction control cabinet is located near the outer (peripheral) end of the bridge and ensures the operation of the equipment in automatic and manual modes. The power supply to the control cabinet and other electrical equipment of the sludge pump is supplied through the central ring pantograph located on the bridge above the central support.

The foregoing shows that the combination of the declared features ensures the achievement of the set goal, namely, it allows to increase the efficiency of the sludge pump.

4. Brief description of the drawings.

FIG. 1 shows a general diagram of the sludge pump device.

FIG. 2 shows an axonometric projection of the sludge pump with the internal structure of the main units of the sludge pump.

5. Implementation of the utility model.

The sludge suction bridge 1 rotates around the central support 3, the central part of the bridge 1 rests on the central support 3 through the spire with the rotary support device 4, and the peripheral part of the bridge 1 rests on the side of the secondary sump through the drive trolley 2. Bridge 1 is attached to the rotary support device ... The central nozzle 5 is attached to the top of the central support 3 on the rotating device of the central nozzle 13 and is a rotating container, which is connected by a sludge removal pipeline 11 to the sludge chamber 17. The sludge chamber 17 is equipped with a control valve 18. The guide cylinder 6 is attached to the central glass 5. To a sludge tank 9 and sludge pipes 7 are suspended from the bridge 1, complete with suckers 8, as well as sludge flow regulators 12, which are a continuation of sludge pipes 8 in the sludge collection tank 9. Sludge pipes 7 connect suckers 8 to the sludge tank 9. Sludge collection tank 9 is connected with a central nozzle 5, a sludge pipe 10. The control cabinet of the sludge pump 15 is located near the outer (peripheral) end of the bridge 1. The annular pantograph 14 is located on the bridge above the central support 3. The overflow cleaning device 16 is fixed on the bridge 1 above the weir chute of the secondary clarifier.

Revolving around the central support, the bridge transports along the bottom of the secondary clarifier the suckers with sludge pipes and a sludge collection tank with sludge flow regulators installed in it.

When the upper cut of the sludge flow regulator is lowered below the water level in the secondary clarifier, the sludge begins to flow into the sludge tank under the action of the hydrostatic force caused by the difference in the water level in the secondary clarifier and sludge in the sludge tank and the central nozzle with an open gate of the sludge chamber of the secondary clarifier. The lower the top cut of the sludge flow regulator goes, the greater the sludge flow. The difference in the water level in the secondary settling tank and sludge in the sludge tank and the central nozzle is due to the hydraulic resistance of the structural elements along the course of the sludge flow.

The capacity of each sucker is regulated by a sludge flow regulator so that the concentration of activated sludge in the flow from each sucker is the same, and the level in the sludge tank is slightly lower than the level of the clarified water overflow.

The regulation of the total flow of activated sludge removed from the secondary clarifier through all suction pipes is carried out by the regulating gate of the sludge chamber of the secondary clarifier.

Thus, the technical result of the utility model is achieved in the form of an increase in the efficiency of the sludge pump.

Claims (3)

1. Sludge pump, including a central nozzle with the ability to be attached to a central support to ensure its rotation and connected by a sludge line with a single sludge tank, into which sludge pipes exit, connecting the suckers to the sludge tank and equipped with sludge flow regulators, which are telescopic pipes with a screw drive, which are a continuation of the sludge pipe in the sludge tank, while the sludge tank is made with the possibility of being connected to a bridge rotating around the central support. 2. Sludge pump according to claim 1, characterized in that the suckers have rubber skirts at the ends. 3. Sludge pump according to claim 1, characterized in that all metal parts of the sludge pump are made of corrosion-resistant materials.

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