RU66332U1 - Wastewater sludge dewatering system - Google Patents

Abstract

The utility model relates to the field of industrial and domestic wastewater and can be used for dewatering their rainfall.

The essence of the invention lies in the fact that the known system comprising the following blocks:

- (a) dewatering, including at least one dewatering production line comprising a sludge metering pump connected to a sludge tank, a flocculant metering pump connected to flocculant solution tanks, a centrifuge, a dehydrated sludge pump, and the pump slurry dispenser and flocculant metering pump are connected to a centrifuge,

- (b) storing dehydrated sludge, comprising a hopper with at least one loading device configured to supply sludge to the pumps of the dehydrated sludge and an unloading bottom containing an unloading opening with at least an overlapping device installed on it one horizontal auger with a drive installed with the possibility of transporting dehydrated sludge to the discharge opening, while the discharge opening is located within the discharge bottom area, in accordance with the utility model and made in the form of a shaft and spirals and blades attached to it, the spiral attached to the shaft sections outside the area of the discharge opening, and the blades at the ends of the shaft and within the area of the discharge opening, in addition, the system is additionally equipped with a block (1) - preparation for sludge dewatering installed in front of block (a) and including at least one pumping station for sedimentation of primary sedimentation tanks with suction and pressure pipelines, gaskets made with the possibility of supplying an excess act to them vnogo yl, serially connected with the pump station densified sludge suction and discharge pipes, wherein the pressure lines pumping station densified

sludge is connected to the sludge tank, and pressure pipes of the pumping station of the sedimentation of primary sedimentation tanks - to the sludge tank and / or with seals;

There are development options when:

- loading device is made in the form of one or more sequentially installed spiral and / or screw conveyors;

- the overlapping device is configured to open the discharge opening along the axes of the horizontal screws;

- the spiral is extended towards the discharge opening no more than half a step of the spiral;

- the system is additionally equipped with a pneumatic drive of the overlapping device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, configured to close the discharge opening when the energy is extinguished;

- the blades are made in the form of a symmetrically curved plate, the ends of which are attached to the shaft, while the distance from the shaft axis to the top of the curved plate is not more than the outer radius of the spiral.

Description

The utility model relates to the field of industrial and domestic wastewater and can be used for dewatering of its sludge (sediments of primary sedimentation tanks and excess sludge).

A known system for dewatering sewage sludge, including a sludge tank, from which it is pumped to consumables, and then by gravity, through a grinder, goes to a centrifuge, and a conveyor belt that delivers dehydrated sludge to special vehicles. The supply tanks are equipped with an overflow pipe, with which, during continuous operation of the pump, a constant pressure is maintained in a centrifuge (see Turovsky I.S. Wastewater Sludge Treatment - 3rd ed., Revised and additional - M: Stroyizdat, 1988. - 256 s.).

The known system due to the gravity flow of precipitation does not fully allow controlling the load on the centrifuge on dry matter. In addition, the reliability of this system significantly depends on the reliability of special vehicles, because in case of interruptions in its operation, there is nowhere to unload the dehydrated sludge.

A known line for processing poultry manure into fertilizer is used, in which, along with the kinematic and mechanical means of transporting the processed raw materials, the droppings accumulator, a centrifuge for mechanical dewatering of the droppings, connected by a pipeline for draining the liquid fraction with a drain accumulator, a drying device and mixing of raw materials and a device for dispensing finished products for packaging. As devices for drying and mixing the raw materials, a static gravity dehydrator and a sterilizer-grinder are used in series, connected by a loading screw, on which a mixer-dispenser of mineral additives is mounted, and static gravity

the dehydrator is communicated through a pipeline for draining the liquid fraction with a drain accumulator, and a granulator is attached to the sterilizer-grinder, behind which there is a device for dispensing finished products for packaging (see patent RU No. 2081539. Line for processing bird droppings into fertilizer. Priority from 1993.07. 09).

Using a centrifuge in this system is not effective, because a rather high humidity product is obtained at its outlet, so there is a need for an additional installation of a gravity dehydrator to separate the liquid phase.

A known system for dewatering sewage sludge, including a sludge tank, from which it is pumped to the centrifuge, and a screw conveyor (or pump) of dehydrated sludge, with which it is sent for further processing. In addition, the system includes:

- installation for the preparation of flocculants, and metering pumps for supplying a solution of flocculants to the cavity of the centrifuge screw;

- a piping system and a reservoir for discharging and collecting the centrate (see Discharge and wastewater treatment in St. Petersburg. Team of authors. St. Petersburg: Novyi Zhurnal Publishing House, 2002, p.565-566, Fig. 10.13).

The use of pumps for transporting dehydrated sludge increases operating costs due to their high energy intensity. In addition, the reliability of this system significantly depends on the reliability indicators of further precipitation treatment systems, since there is no element that performs the functions of a temporary reserve.

A well-known technological scheme for the transportation of dehydrated sewage sludge to the CSA of St. Petersburg, including an emergency hopper-drive with screw conveyors and gates installed in its lower part, blocking the exit from them. Conveyors are designed to empty the hopper and are designed in such a way that they transport the unloaded

sediment outside the bottom of the bunker (see Sewage disposal and treatment of St. Petersburg. Team of authors. St. Petersburg: Publishing House "New Journal", 2002, p. 596, Fig. 10.43).

With this technological scheme, energy costs for emptying the hopper increase because:

- transportation of the unloaded sediment outside the bottom eliminates its unloading under the influence of gravity. Sludge is discharged only when screw conveyors are operating;

- when transporting the discharged sediment outside the bottom (i.e., to an increased distance), additional axial resistance forces are overcome. Therefore, the power consumption on such systems is further increased for this reason.

In addition, an increase in the length of screw conveyors reduces their resource, i.e. reliability indicators.

The closest analogue (prototype) to the claimed utility model is a sewage sludge treatment system comprising (see patent RU No. 2258047. Sewage sludge treatment system. C02F 11/14. Priority from 2003.12.03), at least one technological a dewatering line containing a sludge metering pump with a drive, a suction pipe connected to a sludge hopper, a sludge feed pipe, a flocculant metering pump with a drive, a suction pipe connected to a flocculant solution tanks, with a pressure pipe r flocculant solution, a centrifuge with a drum and auger, a dehydrated sludge pump, while the sludge supply pipe and the pressure pipe of the flocculant solution are connected to the centrifuge. In addition, the system is equipped with a hopper with at least one loading device configured to supply sludge to the pumps with dehydrated sludge and an unloading bottom containing an unloading opening with an overlapping device installed on it, at least one horizontal auger with a drive ,

installed with the possibility of transporting dehydrated sludge to the discharge opening, while the discharge opening is located within the discharge bottom area, and its minimum cross-sectional size is at least 400 mm.

A variant is possible when the loading device is made in the form of a spiral conveyor mounted with an inclination towards the pumps of dehydrated sludge.

Variants are possible when the discharge opening is located at the end of the working area of the horizontal augers, and when the discharge opening is located in the middle of the working area of the horizontal augers.

Variants are possible when the overlapping device is configured to open the discharge opening in a direction perpendicular to the axes of the horizontal screws and to partially open the discharge opening.

Dehydrated sludge pumps can be made in the form of spiral conveyors installed with a slope from the loading device.

The installation can be additionally equipped with drainage pipes installed with the possibility of draining the wash water from the pumps of the dehydrated sludge.

The loading devices can be installed with the possibility of feeding dehydrated sludge into the hopper in the zone of operation of the horizontal screws, and the horizontal screws are structurally redundant with independent drives. At the same time, in the bunker above the discharge opening, a visor with a slope / slopes in the horizontal auger coverage area is installed, and the slope / slope of the peak is not less than the angle of repose of the dehydrated sludge. In addition, the distance from the top of the horizontal screw to the bottom of the visor in the vertical plane is in the range 0.1 · D to 400 mm, where D is the diameter of the screws.

Variants are possible when the hopper volume is V = (28 ÷ 84) · q, or V = (22 ÷ 62) · q, or V = (14 ÷ 57) · q, where q is the hourly average capacity of the system for dehydrated sludge.

The disadvantages of this system are:

1. Low stability in operation, caused by the possibility of sticking of dehydrated sludge on the screws and flow parts of the pumps of dehydrated sludge. In particular, dehydrated sludge can stick on the shaft of horizontal augers, which will exclude the possibility of emptying the hopper through the discharge opening. In addition, when running dehydrated sludge pumps in the form of high-pressure plants (for example, Schwing or Abel pumps), including a screw and a piston group, sticking of dehydrated sludge to the screw shaft can significantly reduce (down to zero) the performance of dehydrated sludge pumps, and, consequently, the entire installation as a whole;

2. The large dimensions of the system, since the implementation of the overlapping device with the possibility of opening the discharge opening in the direction perpendicular to the axes of the horizontal screws, leads to an increase in the dimensions of the installation, because in this case, the drive of the overlapping device will go beyond the discharge bottom, which will require additional space. In addition, the implementation of the loading device in the form of spiral conveyors installed with an inclination towards the pumps of the dehydrated sludge (due to restrictions on the angle of inclination) leads to the fact that the hopper should be at a considerable distance from the centrifuges, or the centrifuges should be installed at a higher elevation. In all these cases, the dimensions of the system increase.

The objective of this utility model is to eliminate the possibility of sticking of dehydrated sludge on the screws and flow parts of the pumps of dehydrated sludge, as well as reducing the size of the system.

The problem is solved in that the system includes the following blocks:

- (a) dewatering, comprising at least one dewatering production line comprising a sludge metering pump with a drive, a suction pipe connected to a sludge tank, a sludge feed pipe, a flocculant metering pump with a drive, a suction pipe connected to solution flocculant containers, with a pressure pipe of the flocculant solution, a centrifuge with a screw, a dehydrated sludge pump, while the feed pipe of the sludge and the pressure pipe of the flocculant solution are connected to a centrifuge,

- (b) storing dehydrated sludge, comprising a hopper with at least one loading device configured to supply sludge to the pumps of the dehydrated sludge and an unloading bottom containing an unloading opening with at least an overlapping device installed on it one horizontal auger with a drive installed with the possibility of transporting dehydrated sludge to the discharge opening, while the discharge opening is located within the discharge bottom area, in accordance with our utility model w, the screws are made in the form of a shaft and spirals and blades attached to it, mounted perpendicular to the axis of rotation of the shaft, the spiral attached to the shaft sections outside the area of the discharge opening, and the blades at the ends of the shaft and within the area of the discharge opening, in addition , the system is additionally equipped with a block (1) - preparation for sludge dewatering, installed in front of block (a) and including at least one pumping station for sedimentation of primary sedimentation tanks with suction and pressure pipes, seals, made with the possibility of supplying excess activated sludge into them, connected in series with the pumped station of compacted sludge with suction and pressure pipes, the pressure pipes of the pumped station of compacted sludge connected to the tank of sludge, and the pressure pipes of the pump station of sediment of primary sedimentation tanks - with the tank of sludge and / or with gaskets.

There is a development option when the loading device is made in the form of one or more sequentially installed spiral and / or screw conveyors.

There is a development option when the overlapping device is configured to open the discharge opening along the axes of the horizontal screws.

There is a development option when the spiral is extended towards the discharge opening no more than half a spiral pitch.

There is a development option when the system is additionally equipped with a pneumatic drive of the overlapping device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, which is configured to close the discharge opening when the energy is extinguished.

There is a development option when the blades are made in the form of a symmetrically curved plate, the ends of which are attached to the shaft, while the distance from the shaft axis to the top of the curved plate is not more than the outer radius of the spiral.

Compared with the prototype, the proposed system has the following distinctive features:

1. The implementation of the screws in the form of a shaft and attached to it spirals and blades (not known);

2. Installation of blades perpendicular to the axis of rotation of the shaft (not known);

3. The attachment of the spiral on the shaft sections located outside the area of the discharge opening, and the blades - at the ends of the shaft and within the area of the discharge opening (not known);

4. Additional supply of the system with block (1) - preparation for sludge dehydration (known);

5. Installing a unit for preparing for sludge dehydration in front of the dehydration unit (a) (known);

6. The implementation of the unit for preparing for dewatering sludge in the form of at least one pump station sediment of primary sedimentation tanks with suction and pressure pipelines, seals made with the possibility of feeding them excess activated sludge, connected in series with the pump station compacted sludge with suction and pressure pipelines (not known);

7. Connection of pressure pipelines of the pumped station of compacted sludge with a sludge tank (known);

8. The connection of the pressure pipelines of the pumping station sediment primary sedimentation tanks with a reservoir of sludge and / or with seals (not known);

9. The execution of the boot device in the form of one or more sequentially installed spiral and / or screw conveyors (not known);

10. The implementation of the overlapping device with the ability to open the discharge opening along the axes of the horizontal screws (known);

11. Extension of the spiral on the auger shaft toward the discharge opening no more than half a spiral pitch (not known);

12. Additional supply of the system with a pneumatic drive of the overlapping device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, made with the possibility of closing the unloading aperture when paying off energy (not known);

13. The implementation of the blades in the form of a symmetrically curved plate, the ends of which are attached to the shaft, while the distance from the axis of the shaft to the top of the curved plate is not more than the outer radius of the spiral (not known).

According to the information available to the authors, the distinguishing features No. 4, 5, 7 and 10 are known in the technical literature, and the rest are not. However, their combined use in the inventive system will provide three technical effects.

The first technical effect is that it eliminates the possibility of sticking of dehydrated sludge on the screws and flow parts of the pumps of dehydrated sludge. It is achieved by the fact that through the combined use of the distinctive features No. 4, 7-8, which allow the process of preparation for dehydration to be carried out in the regimes when fermentation is excluded, since the proposed system can regulate and control the compaction process (sediment fermentation usually occurs in compactors ) Variants of joint compaction in seals are possible, when they additionally (except for excess activated sludge) receive sediment of primary sedimentation tanks, and the option when sediment of primary sedimentation tanks is directed past the sealant directly into the sludge tank. Combined options are possible. Therefore, during operation, it becomes possible to work out the best option when fermentation does not occur. In addition, it can be used in sewage systems allowing partial fermentation of sediments, as the execution of the auger in the form of a shaft and spirals and blades attached to it, on which the spiral is attached to areas outside the area of the discharge opening, and the blades at the ends of the shaft and within the area of the discharge opening (joint use of distinguishing features No. 1-3) coupled with the fact that the weight of the dehydrated sludge located above it acts on the discharge opening, it will allow unloading the hopper even in conditions of partial fermentation of sediments. The latter is achieved by the fact that the presence of blades at the ends of the shaft and within the area of the discharge bottom (i.e., where there is no spiral) creates loosening of dehydrated sludge, which tears it from the shaft. In addition, installing blades perpendicular to the axis of rotation of the shaft (hallmark 2) and extending the spiral on the auger shaft toward the discharge opening by no more than half a spiral step (hallmark 11) will enhance this effect. Confirmation of the aforesaid is the results of experimental studies carried out in the shop for processing sediments of the Pushkin aeration station, where under

the same sludge on the screws not equipped with blades sticking occurred, but on the screws made with the blades - no. In addition, the implementation of the blades in the form of a symmetrically curved plate, the ends of which are attached to the shaft, and the distance from the axis of the shaft to the top of the curved plate is not more than the outer radius of the spiral (hallmark 13) to prevent dehydrated sludge from sticking to them.

The second technical effect is that the dimensions of the system are reduced, because:

- it does not require significant production areas, since the implementation of the overlapping device with the possibility of opening the discharge opening along the axes of the horizontal screws will allow the drive to be placed under the discharge bottom, which will not lead to an increase in the dimensions of the installation.

- the execution of the loading device in the form of one or more sequentially installed spiral and / or screw conveyors will not lead to the fact that the hopper will have to be at a considerable distance from the centrifuges, or the centrifuges should be installed at a higher elevation. The latter is achieved by the fact that the loading device can be presented in the form of a combination of horizontally working spiral and vertically working screw conveyors, which will allow creating more flexible transport schemes for dehydrated sludge.

A new technical effect is that the combined use of these distinctive features allows along the way (in addition to solving the tasks of the utility model) to increase the reliability of the system. The latter is achieved by the fact that:

- the attachment of the blades at the ends of the screw shaft will allow you to relieve the pressure of the dehydrated sludge at the points of intersection of the walls of the hopper. This will increase the durability of the nodes of the seal of the intersection;

- additional supply of the system with a pneumatic drive of the overlapping device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, configured to close the unloading aperture when the energy is extinguished, will avoid the emergency emptying of the hopper when more of the volume of vehicles transported for loading is unloaded from it.

Thus, the claimed system for dehydration of sewage sludge meets the criterion of "inventive step".

The system proposed by the authors is structurally different from the prototype.

Figure 1 shows an embodiment of the general technological scheme of the proposed wastewater sludge dewatering system, figure 2 is an embodiment of a loading device in the form of one or more sequentially installed spiral and / or screw conveyors, figure 3 is an embodiment of an overlapping device according to claim 3 of the formula of the utility model, made with the possibility of opening the discharge opening along the axes of the horizontal screws; 4 is a view A of the discharge bottom of FIG. 3; 5 is an embodiment of the overlapping device according to claim 5 of the utility model formula, when the system is additionally equipped with a pneumatic drive of the overlapping device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, configured to close the discharge opening when the energy is extinguished; 6 is a section B of the horizontal screw 29 of FIG. 4, illustrating an embodiment of the blades in the form of a symmetrically curved plate, the ends of which are attached to the shaft, and the distance from the shaft axis to the top of the curved plate is not more than the outer radius of the spiral.

The general technological scheme of the proposed system includes (see Fig. 1) a block 1 for preparing for sludge dehydration, installed in front of block 2 for dehydration, and block 3 for storing dehydrated sludge.

Block 1 preparing for sludge dewatering includes at least one pump station 4 sediment of primary sumps with suction 5 and pressure 6 pipelines, seals 7 configured to supply excess activated sludge to them, connected in series with pump station 8 of compacted sludge with suction 9 and pressure 10 pipelines. In this case, the pressure pipelines 10 of the pump station of the compacted sludge 8 are connected to the sludge tank 11 of the dewatering unit 2, and the pressure pipelines 6 of the pump station 4 of the sludge of the primary settlers are connected to the sludge tank 11 and / or with seals 7.

Block 2 - dewatering, in addition to the sludge tank 11, includes at least one dewatering process line containing a sludge metering pump 12 with a drive 13, a suction pipe 14 connected to the sludge tank 11, supplying 15 sludge pipe, the metering pump 16 a flocculant with a drive 17, a suction pipe 18 connected to solution containers 19 of the flocculant, with a pressure pipe 20 of the flocculant solution, a centrifuge 21 with a screw 22, a dehydrated sludge pump 23, while the sludge feed pipe 15 and the pressure pipe 20 flocculant solution connected to a centrifuge 21.

Block 3 - storage of dehydrated sludge, includes a hopper 24 with at least one loading device 25, configured to feed sludge into it by pumps 23 of dehydrated sludge, and an unloading bottom 26 containing an unloading opening 27 with a blocking device 28 installed on it at least one horizontal auger 29 with a drive 30, installed with the possibility of transporting dehydrated sludge to the discharge opening 27, while the discharge opening 27 is located within the area of the discharge bottom 26.

Figure 2 shows an embodiment of the loading device 25 in the form of one or more sequentially installed horizontal spiral 31 and / or vertical screw conveyors 32.

Figure 3 shows the embodiment according to claim 3 of the utility model formula, when the overlapping device 28 is configured to open the discharge opening 27 along the axes of the horizontal augers 29. In it, the drive does not extend beyond the discharge bottom.

Figure 4 shows an embodiment when the screws 29 are made in the form of a shaft 33 and spirals 34 and blades 35 attached thereto, mounted perpendicular to the axis of rotation of the shaft 33, and the spiral 34 is attached to portions of the shaft 33 outside the area of the discharge opening 27, and the blades 35 - at the ends of the shaft 33 and within the area of the discharge opening 27. The spiral 34 can be extended towards the discharge opening 27 by no more than half the pitch of the spiral.

Figure 5 shows the embodiment according to claim 5 of the utility model formula, when the system is additionally equipped with a pneumatic drive of the overlapping device 28, including a pneumatic accumulator 36, a pneumatic distributor 37 and a pneumatic cylinder 38, configured to close the unloading aperture when paying off energy.

Figure 6 shows a section B of the horizontal screw 29 of Figure 4, illustrating an embodiment of the blades 35 in the form of a symmetrically curved plate, the ends of which are attached to the shaft 33, and the distance R from the axis of the shaft 33 to the top of the curved plate is not more than the outer radius of the spiral .

The system for dewatering sewage sludge works as follows.

The sediment of the primary sedimentation tanks through the suction pipe 5 is collected and by the pumping station 4 the sedimentation of the primary sedimentation tanks through the pressure pipe 6, depending on the mode determined at the setup stage, is pumped in one of the following three directions (see Fig. 1):

- into the sludge tank 11. In this case, in the seals 7, only the excess activated sludge entering them is compacted;

- seals 7. In this case, in the seals 7, a joint sealing of the excess activated sludge and sediments of the primary settlers entering them is carried out;

- partially into the sludge tank 11 and partially into the seals 7.

The compacted sludge from the seals 7 by the pump station 8 of the compacted sludge is fed through the suction 9 and pressure 10 pipelines to the sludge tank 11. The sediment of primary sedimentation tanks can also be fed into it.

Further, the sludge from the sludge tank 11 through the suction pipe 14 (for example, dehydration processing line No. 1) is collected by a sludge metering pump 12 with a drive 13 and, through the sludge feed pipelines 15, is fed to a dewatering centrifuge 21 with a screw 22. At the same time, from solution containers 19 of the flocculant using a metering pump 16, the flocculant is fed to the centrifuge 21. As a result of the separation of the centrifugal forces in the centrifuge, a centrate and dehydrated sludge are obtained. The latter, using a dehydrated sludge pump 23, is supplied to the loading device 25. The dehydrated sludge from other dewatering processing lines, for example, No. 2, also enters it.

The loading device 25 feeds the dehydrated sludge to the hopper 24, the volume of which during operation increases due to the operation of the loading device 25 and decreases due to shipment through the unloading opening 27 to automobile transport, or to a conveyor, or for subsequent processing, for example, incineration. As a result, due to the volume of the bunker 24, the system for further processing or transportation has a temporary reserve for its restoration t = V / q, where V is the volume of the bunker of dehydrated sludge, q is the average hourly capacity of the system.

Shipment of dehydrated sludge in the proposed system through the discharge opening 27 is carried out (depending on the moisture content of the dehydrated sludge) sequentially in three ways.

The first method involves partially opening the overlapping device 28 until the required dehydrated sludge flow begins to flow through the discharge opening 27. The requirements for consumption (volume, weight, etc.) are formulated by the system for further processing of sludge and can be controlled by various additional devices. Depending on the flow rate and humidity of the dehydrated sludge discharged, the degree of opening of the overlapping device may be different. Moreover, as the emptying of the hopper 24, it will change.

The second method is used when the first has exhausted its capabilities, i.e. when the discharge opening 27 is fully opened.

The third method is used in cases where the second has exhausted its capabilities, i.e. when the unloading aperture 27 is completely open, the dehydrated sludge either does not arrive or is supplied in insufficient quantities. This means that there is no sludge above the opening. In this case, include a horizontal screw 29 (or several screws) for supplying dehydrated sludge to the area of the discharge opening 27.

During the rotation of the screws 29 made in the form of a shaft 33 and attached to it a spiral 34 and blades 35 mounted perpendicular to the axis of rotation of the shaft 33, in which the spiral 34 is attached to sections of the shaft 33 that are outside the area of the discharge opening 27, and the blades 35 - at the ends shaft 33 and within the area of the discharge opening 27, the following occurs:

- three forces act on the dehydrated sludge within the area of the discharge opening 27: the gravity of the dehydrated sludge located in the hopper 24; the shear force of the dehydrated sludge created by the rotation together with the shafts 33 of the spirals 34, the mixing force created by the rotation together with the shafts 33 of the blades 35. Together, this creates conditions when even partially fermented sludge with adhesion properties does not hang in the discharge opening 27, but is unloaded from the hopper 24. Strengthening this effect also contributes to the extension of the spiral 34 towards the discharge opening 27 no more

than a half step of the spiral, as well as the execution of the blades 35 in the form of a symmetrically curved plate, the ends of which are attached to the shaft 33, and the distance R from the axis of the shaft 33 to the top of the curved plate is not more than the outer radius of the spiral. The latter prevents the dehydrated sludge from sticking to the blades themselves 35.

- the dehydrated sludge at the intersection of the shafts 33 of the walls of the hopper 24 is affected by the mixing force created by rotation together with the shafts 33 of the blades 35 located at the ends of the shafts 33 of the screws 29. This allows to relieve the pressure of the dehydrated sludge in these places and thereby increase the durability of the seal assemblies.

It is possible that when the discharge opening 27 is open, the energy is paid off. At high humidity of the discharged dehydrated sludge being discharged, in this case, unloading under the influence of gravity may turn out to be uncontrollable when emptying occurs in a fully loaded vehicle.

In the present utility model, when the system is additionally equipped with a pneumatic drive of the shut-off device 28 including a pneumatic accumulator 36, a pneumatic distributor 37 and a pneumatic cylinder 38, the discharge opening is closed due to the volume and pressure of the air in the pneumatic accumulator 36. Thus, uncontrolled unloading does not occur.

Claims (6)

1. Wastewater sludge dewatering system, comprising the following units: - (a) dewatering, comprising at least one dewatering process line comprising a sludge metering pump with a drive, a suction pipe connected to a sludge reservoir, a sludge feed pipe, a pump a flocculant dispenser with a drive, a suction pipe connected to flocculant solution tanks, a flocculant solution pressure pipe, a centrifuge with a screw, a dehydrated sludge pump, and a sludge feed pipe the pressure line of the flocculant solution is connected to a centrifuge; - (b) storing dehydrated sludge, comprising a hopper with at least one loading device configured to supply sludge to the pumps of the dehydrated sludge and an unloading bottom containing an unloading opening with at least an overlapping device installed on it one horizontal auger with a drive installed with the possibility of transporting dehydrated sludge to the discharge opening, while the discharge opening is located within the discharge bottom area, characterized in that the screws are made in the form of a shaft and spirals and blades attached to it, mounted perpendicular to the axis of rotation of the shaft, the spiral attached to sections of the shaft outside the area of the discharge opening, and the blades at the ends of the shaft and within the area of the discharge opening, in addition, the system is additionally equipped with a block (1) - preparations for sludge dewatering, installed in front of block (a) and including at least one pumping station for sedimentation of primary sedimentation tanks with suction and pressure pipelines, seals made with possible the ability to supply excess activated sludge to them, connected in series with the pumped station of compacted sludge with suction and pressure pipelines, while the pressure pipelines of the pumped station of compacted slurry are connected to the slurry tank, and the pressure pipelines of the pumping station of the sediment of primary sedimentation tanks are connected to the slurry tank and / or seals. 2. The wastewater sludge dewatering system according to claim 1, characterized in that the loading device is made in the form of one or more sequentially installed spiral and / or screw conveyors. 3. The wastewater sludge dewatering system according to claim 1, characterized in that the overlapping device is configured to open the discharge opening along the axes of the horizontal screws. 4. The wastewater sludge dewatering system according to claim 1, characterized in that the spiral is extended towards the discharge opening no more than half a spiral pitch. 5. The wastewater sludge dewatering system according to claim 1, characterized in that the system is additionally equipped with a pneumatic drive of the shut-off device, including a pneumatic accumulator, a pneumatic distributor and a pneumatic cylinder, configured to close the discharge opening when the energy is extinguished. 6. The wastewater sludge dewatering system according to claim 1, characterized in that the blades are made in the form of a symmetrically curved plate, the ends of which are attached to the shaft, while the distance from the shaft axis to the top of the curved plate is not more than the outer radius of the spiral.