SU1527195A1 - Installation for treating sediments of natural and waste water - Google Patents

Abstract

The purpose of the invention is to increase the efficiency of the treatment process by providing high yield of the treated sludge and intensifying the melting process. The plant is equipped with a recirculation station and a variator communicated with the crystallizer, the sediment deposition unit in the crystallizer is made in the form of irrigation nozzles, and the frozen sludge removal unit is equipped with flexible pick-ups, the melter is equipped with a drive screw, flushing and irrigation nozzles, the latter being communicated with a heat exchanger-condenser . Flexible pick-ups in the crystallizer are mounted for movement relative to the heat exchange surface. Watering nozzles in the crystallizer application unit are located in the upper part of the heat exchange surfaces at an angle of 30-60 ° to their radial cross section and in the direction opposite to their movement. The recirculation station is made in the form of a tank with an overflow pipe and a metering valve and is provided with a collection of liquid osazhka with a control valve communicated with it and installed under the watering nozzles of the mold. The screw with the drive is placed in the lower part of the melter, the irrigation nozzles in its upper part. 4 hp ff, 2 ill.

Description

The invention relates to the treatment of sediments formed during the treatment of natural and waste waters, and can be used in sewers, as well as in the desalination of salt water.

A device is known for improving the water recovery ability of natural water sediments, including a horizontal cooling drum with a knife device for separating frozen sediment from the drum surface and a defrost tank with a heater and a mixing device P.

During the operation of a rotating drum, difficulties arise with a uniform distribution of coolant over the inner surface of the drum, as well as the need to constantly monitor the operation of packing seals. In addition, only one-sided sedimentation of the sludge is maintained, and the displacement device turbulizes a large layer of water in the defrost tank and complicates the process of sedimentation of the solid phase released during the melting of the frozen sludge.

Closest to the invention to the technical essence and the achieved result is a plant for sludge dewatering of treated water, consisting of a crystallizer and a melter. The mold contains a double-walled drum with internal and external heat exchange 1-1 and surfaces and devices for applying a sediment layer to the heat exchange surfaces of the layer and for cutting frozen sludge from these surfaces. Sludge is applied to the heat exchange surfaces using chambers, and the frozen sludge is removed using knives or cutters. The unit's melter has a tank having a cylindrical partition inside, on the outer surface of which a tubular heat exchanger is placed. The bottom of the melter is made in the form of a cone L2J.

The precipitate, which has thixotropic properties, being in the chamber, partially restores its structure disturbed when it is supplied for freezing. The process of restoring an impaired structure proceeds unevenly in the sediment, as a result of which floc forms in it, having different viscosities and sizes. In this case, on the heat exchange surfaces,

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an uneven layer of frozen sediment, which leads to an uneven fit of the sealing elements of the chambers to the heat exchange surfaces and leakage of liquid sediment, causing a drop in its level in the chamber. In addition, the sedimentation of the sediment in the chamber to the heat exchange surfaces is possible in the event that the cutters and chambers stop moving.

Knives or cutters in a known device are installed at a certain distance from the heat exchange surfaces, therefore, part of the frozen sludge remains uncut. This leads to an increase in local thermal resistance, to an incomplete freezing of the next layer of sediment, as well as to an uneven fit of the chambers to the heat exchange surfaces.

Considering that sediment properties vary over a wide range depending on the quality of the source water, season, water treatment technology, etc., it is necessary to change the freezing mode and, in particular, the speed of rotation of the deposition and removal units. In the known device it is not provided,

The indicated deficiencies in the design of the crystallizer do not allow to reduce the water withdrawal capacity of the precipitated sediment as much as possible.

In addition, there is no agreement in time between the freezing and thawing processes due to the possible accumulation of frozen sediment on the surface of the water in the melter.

In the melter, heat transfer from the refrigerant to the sediment proceeds with a low heat exchange coefficient (from the sediment side), which does not exceed 100 Bt / m, therefore the heat exchanger of the melter must have a large surface, which significantly increases the intensity of the apparatus. The design of the melter provided in the prototype does not ensure complete removal of the solid phase of the sludge due to its sedimentation and accumulation on the walls of the conical bottom.

The aim of the invention is to increase the efficiency of the sludge treatment process in natural and waste waters due to the provision of high water loss of the treated sludge and the intensification of the smelting process.

freezing sediment to frozen at least 2.

A flexible pickup assembly pickup is positioned directly behind the knife or cutter with a uniform fit to the heat exchange surface. Using a pick-up, the heat exchange surface is cleaned of the remaining pieces of frozen sludge, which ensures uniform application of the next layer of sludge. The adjustment device of the removal unit allows you to set the most appropriate mode for cutting and removing the frozen sludge from the heat exchange surface.

In order to intensify the process of melting the sediment, irrigation nozzles are installed in the upper part of the melt, to which clarified heat is supplied by a pump from the melting tank. The presence of the auger and flush nozzles located at the bottom of the melter (at the bottom) ensures complete removal of the sediment from dehydration.

FIG. 1 shows the installation for processing natural and sewage sludge, general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. one; in fig. 4 - recirculation station, longitudinal section.

The installation for processing natural and sewage sludge contains a crystallizer 1, under which a melter 2 is installed, a refrigeration compressor unit 3 and a dewatering device 4.

The mold 1 has a recirculation station 5, heat exchange surfaces 6 and 7, watering nozzles 8 with a regulating device 9, shut-off valves 10, bolts 11 and 12, mills (knives) 13 and flexible pickers 14, which equip with regulating devices 15, a shaft 16, on which the application units (8-10) and sludge removal (13-15) are fixed, as well as the collection of liquid sediment 17 and the drive wheel 18.

The rotation of the drive wheel is carried out with the help of the electric motor 19 and the variator 20. The supply of the refrigerant to the mold 1 is controlled by the valve 21.

The melter consists of a tank 22, equipped with a partition 23, a screw with a drive 24, flush nozzles 2i,

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with mca 26, irrigation nozzles 27, pump 28 clarified water, heat exchanger-condenser 29, shut-off valves 30 and 31.

The recirculating station of the crystallizer contains a tank, 32, overflow pipe 33, metering valve 34, control valve 35, collection of liquid sediment 17 and pump 36.

The proposed installation works as follows.

The sludge being processed goes through the metering valve 34 into the tank 32 of the recirculation station 5, from where it is picked up by the pump 36 and sent to the irrigation nozzles 8. The sludge flow is controlled by the valves 35 and 10. The incoming sludge is freely drained from the nozzles 8 and is applied evenly to the heat exchangers noBenvnosti 6 and 7. The excess liquid sediment draining from the surfaces is collected in a collector 17 installed under the irrigation nozzles 8 in the lower part of the crystallizer, and is discharged back to the tank 32 of the recirculation station 5,

Sludge is frozen due to heat exchange with a boiling refrigerant flowing through valve 21 into a closed cavity formed by heat exchange surfaces 6, 7 and crust 11, 12. Refrigerant vapor is sucked off by a compressor unit 3. Frozen sediment is removed from surfaces 6, 7 by means of cutters (knives) 13 and flexible pick-ups 14.

The cut sediment falls into the melter tank 22, where due to direct contact with the water coming from the irrigation nozzles 27 heated in the heat exchanger-condenser 2, the precipitate melts. The precipitate is separated in the process of gravitational sedimentation into a solid phase and water. The solid phase of the sludge is collected using clarified water coming through the valve 30, flush nozzles 25 and a screw drive 24, and is discharged into the tank 26, from where it is removed to the dewatering apparatus 4. The clarified water 28 is taken from the zone the formed wall 1 of the tank 22 and the partition 2-3, and is directed to the heat exchanger-condenser 29. In the heat exchanger-condenser 29 the heating is carried out. The above purpose is achieved by the installation of a sludge treatment containing a mold with heat-exchanging surfaces For the removal and removal of frozen sludge, a melter, a heat exchanger-condenser, a dehydrating unit, a compressor-refrigeration unit, pumps and process piping, is equipped with a recirculation station and a variator, the application unit is made in the form of watering nozzles, the removal unit is equipped with bending tools and pickers, the melter is equipped with a screw with a drive, flush and irrigation-1 and nozzles, while the melter and irrigation nozzles communicate with a heat exchanger-condenser using a pump and piping system, which is located outside the tank melter.

The recirculation station is made in the form of a tank, equipped with a metering valve and an overflow pipe, which is connected to the crystallizer by means of a pump, a piping system with a control valve and a collection of liquid sludge.

Watering nozzles are placed in the upper part of the mold, the removal unit of the frozen sludge is equipped with adjusting devices for installing flexible pickers relative to the heat exchange surfaces. In addition, watering nozzles set in such a way that their holes are directed in the direction opposite to the movement of the nozzles, at an angle of 30 - 60 ° to the radial cross section of the heel-exchange surfaces.

In addition, a screw with a drive and flush nozzles are located in the lower part of the melting tank, and irrigation nozzles are located in its upper part.

The recirculation station serves to reduce the viscosity of the sludge and feed it to the crystallizer for freezing in an amount that provides complete liquid coating for those areas of heat transfer surfaces that are in the irrigation zone.

Using a metering valve, the working level of the sludge in the tank of the recirculation station is established and maintained. The emergency level of sediment in the tank is determined by the overflow pipe. The sediment, the pump pass, lowers its viscosity and acquires

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homogeneous structure, which contributes to the deposition on the heat exchange surfaces of an even layer of sediment and its simultaneous freezing. The collection of liquid sludge prevents the sludge flowing from the heat exchange surfaces from entering the melter and contaminating the frozen sludge.

Using the variator installed on the drive of the crystallizer, depending on the properties of the treated sludge, the most efficient freezing mode is selected, ensuring the maximum increase in the water-carrying capacity of the sludge at the minimum energy consumption.

Using as a site for application of watering nozzles, which are installed in a certain position with the help of adjusting devices, allows you to create such a mode of deposition on the heat-exchange surfaces, in which stratifications, jet streams and their intersection on the surface are not formed, and there is no rasps - deposition of air. By directing the nozzles in the opposite direction to their movement, it is possible to reduce the rate of sediment convergence to the heat-exchanging surface and thereby reduce the degree of turbulence in the flow, and also to exclude the possibility of liquid sediment getting into the cut off frozen wasp.

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When the sludge is introduced at an angle of less than 30 A, the formation of a jet stream on the surface is observed and the sludge is sprayed after it is in contact with the heat exchange surface. When the feed angle is more than 60 °, the width of the application zone increases, which leads to multiple layering of sediment, as well as an increase in the amount of liquid sediment discharged from the heat exchange surfaces. The most favorable mode of deposition is observed at an angle of supply of sediment to the heat exchange surface of 30 - 60 °, while the nozzles of the nozzles should have a circular or elongated in the vertical plane section. The flow rate of the sediment supplied to the heat-exchanging surfaces and the flow area of the irrigation nozzles is chosen in such a way that the rate of outflow of the sediment is not overshoot. em 1 m / s with the ratio of

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incorruptible water due to the heat of condensation of vaporous refrigerant, which comes from the compressor unit 3. The amount of clarified water. The pumps supplied to the irrigation nozzles 27 are controlled by a valve 31, moreover, the excess water is discharged into the sewer system.

In production, it is advisable to use one common melter for several molds.

The advantages of the proposed installation for the treatment of sediments of natural and waste waters in comparison with the known zak95

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This is due to the fact that there is a high water loss effect on the sediment due to the application of an even layer of liquid sediment on the heat exchange surfaces, its freezing and complete removal from the surface. The use of a variator in the drive of the crystallizer allows you to set the duration of frosting necessary for a specific sludge. In addition, the process of sludge melting and heat exchange of clarified water with a condensing refrigerant is intensified; mechanizes: the collection and removal of solid sediment from the smelter.

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Claims (5)

1. INSTALLATION TREATMENT FOR SEDIMENTS OF NATURAL AND SEWAGE WATER, comprising a crystallizer with heat exchange surfaces and units for applying sludge and removing frozen sludge, a melter, a heat exchanger-condenser, a dewatering apparatus, a compressor-refrigeration unit, pumps and process pipelines, characterized in that, in order to increase efficiency sludge treatment process by ensuring high water yield of the processed sludge and the intensification of the melting process, it is equipped with recirculation connected to the crystallizer station and variator, the sedimentation unit in the mold is made in the form of irrigation nozzles, and the frozen sediment removal unit is equipped with flexible pick-ups, the melter is equipped with a screw with a drive, flushing and irrigation nozzles, the latter being in communication with a heat exchanger-condenser. 2. Installation according to p. ^ Characterized in that the flexible pick-ups in the mold are mounted with the possibility of movement relative to the heat-exchange surface. 3. Installation according to paragraphs. 1 and 2, characterized in that the watering nozzles in the application unit of the crystallizer are located in the upper part of the heat exchange surfaces at an angle of 30-60 to their radial section and in the direction opposite to their movement, 4. Installation pop. ^ characterized in that the recirculation station is made in the form of a tank with an overflow pipe and a metering valve and is equipped with a sediment collector with a control valve connected with it and installed under the mold watering nozzles. SU, „. 1527195 5. Installation according to π. 1, characterized in that the auger with a drive is located in the lower part of the melter, irrigation nozzles ~ in its upper part.