RU2175881C2 - Water cleaning plant and method of its regeneration - Google Patents

Abstract

FIELD: water services; methods of regeneration of water cleaning unit filters. SUBSTANCE: starting water enters filter 1 with floating medium 3 through injector 5; simultaneously, pulse flow is fed to perforated tubes 11 through one of switching devices 12; perforated tubes 11 are mounted at upper level of the lowest layer of floating medium. Pulse flow are fed from opposite sides of housing 1 of filter provided with floating medium. Water is supplied in wavy manner, thus creating alternating areas of increases pressure and rarefaction. Then pulse flows are created in next higher layer via tubes 10, then next layer, and so on as far as extreme upper layer. Time intervals for forming pulse flows at subsequent layers are experimentally defined. Duration of said intervals is dictated by degree of contamination and volume of filter. EFFECT: enhanced operating efficiency due to improved quality of regeneration. 6 cl, 2 dwg

Description

 The invention relates to water management, and more specifically to methods of regeneration of filters of water treatment plants, and can be used in the treatment of groundwater and domestic water.

 The problems of treating contaminated water are becoming increasingly important in today's unfavorable environmental conditions.

 As you know, the water purification process consists of the following stages: oxidation, coagulation and filtration. During the oxidation process, water-soluble chemical compounds are transformed into insoluble oxides, salts, etc. During coagulation, coalescence of semi-finished and water-containing compounds into colloidal particles occurs. As it moves through the filter, colloidal particles settle on the filter elements, the filter becomes clogged, its hydraulic resistance increases, and the filtrate level in it begins to decrease, the dirt capacity decreases and finally reaches a threshold when water purification is no longer possible and filter regeneration is necessary.

 A known method in which the regeneration of the floating filter load is carried out by expanding it in a downward flow of clarified water [M. Zhurba and Girol N. N. Calculation and design of filters with a floating load. Express Information, Series 3, no. 5, TsBNTI, Ministry of Water Economy of the USSR, M., 1976, p. 3].

 The main disadvantage of this method is its low efficiency in cases of cleaning the filters of the floating charge used for the treatment of high-water waters or for iron removal, since even a stream of high power cannot destroy the formed colloidal films. In addition, in these installations for water purification, separate washing of filters of floating and granular loading is provided, which leads to a large consumption of water.

 Known methods in which the regeneration of filters of a floating load by rotating it with a mechanical stirrer relative to the axis of the filter in a downward flow of water [Gamer P. Water purification for industrial enterprises. M., 1968, p. 327; author testimonial. N 891115, cl. B 01 D 24/46, application. 05/05.80, publ. 12/23/81, bull. N 47].

 The main disadvantage of these methods is also the high water consumption due to the separate regeneration of the filters, as well as the fact that during the rotation of the particles of the floating load can be destroyed by collision with the elements of a mechanical mixer.

 A known method of regeneration of filters of the installation for deferrization during the accumulation of contaminants (iron compounds, suspended solids), accompanied by an increase in hydraulic resistance and a possible deterioration in the quality of water treatment, developed by the Foundation PROGRESS [Installation for deferrization of water (UOVZh-02). Technical description and operating instructions, PROGRESS Fund LLP, M., 1999].

 The essence of this method is that the regeneration of filters is carried out in two stages; at the first stage, in a filter with a floating charge, it is flushed with a downward stream of source water, which, after cleaning, is directed by an upward flow into the filter with a sand and a floating charge with an upward flow of only pure (deferrized) water.

 To implement the method, an installation is used that contains two housings with filters for floating and sand loading and a tank with clean water, interconnected by pipelines and switching devices that regulate the opening of the respective pipelines. A water injector and an air ejector are installed above the inlet of the floating loading case.

 The main disadvantage of this method is the low cost-effectiveness and low-quality regeneration of the floating load, since a powerful injected stream of source water is required to flush the floating load 2-8 times more than for water treatment.

 But the flow of such power does not guarantee separation from the filter elements of the floating load of the colloidal particles deposited on them and pushing them through the drain pipe into the sand loading filter.

 The operating experience of such an installation has shown that it is practically impossible to realize its potentially high dirt capacity, since areas with increased adhesive properties of the colloidal film are formed in the thickness of the floating loading, which the downward or upward washing flows pass around the channels pierced by them in layers with a less dense film.

 As a result, the dirt capacity of the filter decreases and, finally, the regeneration of the filter becomes impossible, which means that the functioning of the filter itself becomes impossible.

 The dirt capacity of the floating load is not fully restored after regeneration in this way. In addition, for the regeneration of the sand filter, water is used, supplied from a tank with clean water by a special installation.

 The method is ineffective, since in the regeneration process a water stream is used with a flow rate that exceeds several times the nominal water flow rate during filtration. In addition, increasing the power of the injected flow can lead to leaching of the sand load.

 The objective of the present invention is to increase the efficiency of the installation by improving the quality of its regeneration, increasing the dirt capacity of the filter of the floating load and increasing the life of the filters of both loads.

 The problem is solved in that if in a known installation containing two buildings, one of which is filled with a floating load, and the other with a sand loading, and drainage pipes connecting the outlet of the floating loading case with the inlet of the case with sand loading, above the inlet an injector is installed on the floating filter, and two outlet openings are made on the side surface of the sand-loaded filter housing, which are connected through switching devices, one with a capacity for water, the other with sewage, the floating load is divided into at least three parts, holes are made in the housing at the top of each part of the floating load, in which perforated pipes are inserted, connected through switching devices to the source water supply line.

 To break the electrical bonds in a colloidal film, a source of electromagnetic radiation is installed on the surface of the floating-load housing.

 The problem can be solved if, in the known method of regeneration of filters for water purification, including washing filters of floating and sand loads with an injected stream of water, simultaneously with the injected stream, washing of the floating load is carried out by pulsed flows supplied from opposite sides of the filter housing in opposite directions, at In this case, pulse washing is performed in parts, starting from the upper level of the lowest of the sections into which the cavity of the filter housing is divided, then including pulse flows at the upper levels of the next upper layers towards the outlet, after washing with pulse flows, they are turned off and then the injected stream that provides filtration displaces dirty water into the sand-loaded filter, which is then sent to the sewer.

 In order to destroy the electrical bonds in the colloidal film, simultaneously with the pulsed fluxes they act on the floating load by electromagnetic radiation, which ensures its better regeneration.

 Better regeneration can be obtained if layer-by-layer washing of the floating load is carried out by pulsed flows, the power of which is 2-3 times greater than the power of the injected stream.

 When regenerating not so dirty filters, washing with pulse flows is carried out separately in layers, disabling the pulse stream of the previous lower layer.

 The claimed solution differs from the prototype in that the washing of the floating load is carried out, starting from the upper level of the filtrate layer closest to the output, by pulsed water flows supplied from opposite sides of the filter housing in opposite directions, gradually including pulsed flows directed from higher layers, rising to floating loading inlet.

 The installation is characterized in that in the filter housing of the floating load at the top height of each part into which the floating loading is divided, holes are made in which perforated pipes are inserted, connected through switching devices to the source water supply line, while the output of the floating loading housing is connected with sand inlet inlet.

 Thus, a comparative analysis with the prototype showed that the claimed solution meets the criteria of the invention of "novelty."

 The invention consists in the following.

 As experiments showed, the colloidal films of the highest density are formed in the lower part of the filter, the largest particles are concentrated in its middle part, and smaller particles are deposited on the filter elements of the floating charge closer to the inlet.

 Therefore, in order to remove particles settled on the charge from the filter, it is necessary to open the outlet for the filtrate with colloidal particles from the upper layers of the floating charge. This means that it is necessary to destroy the mechanical bonds in colloidal films, enveloping the filter elements and filling the gaps between them.

 Therefore, it is proposed to begin the regeneration of the filter with a floating charge from the layer closest to the filter outlet. Since the mechanical bonds in colloidal films are quite strong, they can be destroyed by supplying water jets with local increased pressure. To do this, simultaneously with the downward injected flow from the upper level of the floating loading layer closest to the outlet of the filter direct pulse flows supplied from opposite sides of the filter housing in opposite directions.

 In the part of the floating charge transported by the pulsed streams, the colloidal film is destroyed under the action of increased local pressure of the water jets and is injected into the slotted filter by the injected downward flow. Thus, the exit for large and small particles from higher layers is open. After that, the flows on the next layer of the floating load are turned on, after its cleaning, the next is turned on and so on to the highest layer. After cleaning all the layers, the pulse flows can be turned off and washing can be continued only with a downward injected stream of water, the power of which does not exceed the power of the stream during cleaning. Through a drainage pipe, water from a floating load enters the sand load and upstream cleans it of contaminants settled on the elements.

 Thus, pure water is not used in the regeneration process, rotation of the load by pulsed flows destroys colloidal films and particles, and the fact that washing with pulsed streams is carried out starting from the lower layers of the load allows free gaps between the filter elements in the lower part of the floating load, and prevents formation congestion at the outlet.

 The invention is illustrated by drawings, where in FIG. 1 is a diagram of an apparatus for implementing the method, and FIG. 2 is a diagram of the processes occurring during operation of the installation.

 The installation comprises housings 1 and 2, in which respectively filters of a floating load 3 and a sand filter 4 are placed, an injector 5 installed in front of the inlet of the filter of a floating load, the inclusion of which is controlled by switching devices 6. An electromagnet 7 coil is installed on the outer surface of the housing 1 (Fig. 2 ) The outlet of the floating filter housing is connected by drainage pipes 8 to the inlet of the sand filter housing 2. The floating loading is divided into three parts, at the top height of each part in the side walls of the housing 1 holes are made in which perforated pipes 9, 10, 11 (Fig. 2) are installed, connected by switching devices 12 to the water supply line. The outlet of the sand-loaded housing 2 is connected to a switching device 13, which regulates its switching to the sewer during regeneration or to a container with clean water during filtration. The spiral arrows show the direction of the rotating flow during layer-by-layer washing of the filter, and the curved arrows show the direction of the lines of force of the electromagnetic field created by the electromagnet 7 coil mounted on the housing.

 The installation works as follows.

 At the time set by the timer, the water treatment mode is turned off, and the installation is switched to the regeneration mode.

 Through the injector 5, the source water enters the filter 1 with a floating charge 3, at the same time through one of the switching devices 12, a pulsed stream of the source water is supplied into the perforated pipes 11 installed at the upper level of the lowest layer of the floating charge. Pulse flows are supplied from opposite sides of the floating filter housing 1. Water is supplied in waves so that alternating areas of high pressure and vacuum are created.

 After some time, the pulse flows in the next higher layer through the pipes 10, after a while the next and so on to the very top layer. The time intervals through which pulse flows on the next layers are included are experimentally established. The duration of these intervals depends on the degree of contamination and the volume of the filter.

 If the filters are very dirty, for example, during emissions of iron-containing dirt, so as not to increase the flow of water, you can use electromagnetic radiation to destroy the colloidal films, which is generated by a source 7, for example, an electromagnet coil mounted on the surface of the housing 1.

 Adequate filter regeneration can be ensured, as was established by experiments, if the total power of the pulsed fluxes is 2-3 times greater than the injected flux.

 After the regeneration of the floating load is completed by impulse flows, they are turned off, and the injected stream is switched to the regime of replacing the wash water remaining after washing off the dirt particles in the filter elements to clean water.

 The injected downward flow directed into the filter with a floating charge displaces dirty concentrate from it into the housing 2 with a sand loading 4.

 This stream, passing through the drainage pipes 8 into the sand load, becomes an upward flow, weighs the particles of the sand load, and then flushes dirt particles deposited on the filter elements.

The duration of replacing the remaining mud concentrate with wash water with clean water in both filters is determined in a known manner, based on the expression
T = V _b / Q,
where T is the time required to replace the dirty water (mud concentrate) in both filters with clean water;
V _b is the filter volume in liters (l), since usually the volume of both filters is half occupied by displaced water.

 Q - fixed filter capacity in liters per 1 s (l / s).

 This flow is enough to regenerate the sand load completely. From the sand-loaded filter, dirty water is sent through a switching device to the sewer.

 With a slight contamination of the filters, pulse flows can be switched on gradually, disabling the previous ones. This will reduce water consumption.

 An example of a specific use.

 The method was implemented in the installation for iron removal and degassing of water, which contains a filter with a floating charge, which used granules of expanded polystyrene with a diameter of 2-8 mm, and a filter with sand loading.

 A floating filter with a height of 100 cm and a diameter of 150 cm is placed in a housing 160 cm high. The filter is divided vertically into four parts. At the upper level of each part in the holes on opposite sides of the body are installed tubes, the diameter of which is 22 mm, with holes for nozzles. The entrances to the tubes and to the injector are connected to the water supply line by switching devices in the form of electromagnetic valves controlled by a time relay.

 A layer with a sand load of 90 cm is placed on a gravel substrate 20 cm in a case with a diameter of 22 cm. At a height of 140 cm, a hole for the exit of clean water is made in the body of the sand load filter, closed by an electromagnetic valve controlled by a timer. At the level of the sand load, an overflow hole with a diameter of 50 mm was made with access to the sewer.

 The performance of this installation with an iron content of 5-8 ml / l 200-300 l / h.

 The duration of washing with purified water is 30 minutes, of which 10 minutes are loosening washing with impulse flows, with a productivity of 600 l / h and then 20 minutes - washing with source water at a filtration rate (flow rate 200 l / h).

 The total volume of washing water is 130 l.

The washing interval with an iron content of 5-8 m ² / l through 1.5-2 m ^{3 of} purified water.

Compared with the prototype, the water consumption is two to three times less, since with the same level of contamination in the known method, 150-160 liters of water are consumed for washing, of which 120-130 liters are already purified, and its washing interval after 0.5- 1 m ³ .

Claims (6)

 1. Installation for water purification, comprising two housings, one of which is filled with a floating load, and the other with a sand loading, an injector is installed above the inlet of the filter with a floating loading, and two outlet openings are made on the side surface of the filter housing with a sand loading, which are connected through a switching device, one with a tank for clean water, and the other with sewage, characterized in that the floating load is divided into at least three parts, in the housing at the top height of each part of the floating load Openings in which the perforated tubes are installed, connected via switching devices to the water supply main.  2. Installation for implementing the method according to claim 1, characterized in that an electromagnetic emitter is installed on the surface of the floating-load housing.  3. A method of regenerating a water treatment plant containing filters with floating and sand loads by supplying an injected stream of source water to the load, characterized in that at the same time as the injected stream, the floating load is flushed with pulsed flows supplied from opposite sides of the filter housing in opposite directions while pulse washing is carried out in parts, starting from the upper level of the lowest of the sections into which the cavity of the filter housing is divided, then turn on the imp The pulse flows at the upper levels, located above the layers towards the outlet, after washing with pulsed flows, they are turned off and then with water displaced from the filter with a floating charge, the filter with a sand charge is washed and then dirty water is sent to the sewer.  4. The method according to claim 3, characterized in that simultaneously with the pulsed flows affect the floating load of electromagnetic radiation.  5. The method according to claims 3 and 4, characterized in that the layer-by-layer washing of the floating load is carried out by pulsed flows, the power of which is 2-3 times greater than the power of the injected stream.  6. The method according to PP.3 and 4, characterized in that the washing with pulsed flows is carried out separately in layers, turning off the pulsed flow of the previous lower layer.

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