CS248049B2 - Method of continual filtration of liquids and apparatus to perform this method - Google Patents

Abstract

A process for continuously filtering liquids, the liquid flowing upwards on a downwardly movable granular filter medium, expediently a sand bed, and the filtered liquid being continuously discharged from the liquid space present above the filter medium. In a process of this type, in particular, the speed of the filter medium is to be improved and the washing is to be separately controllable, in order to ensure as a result an adequate regeneration. This is ensured according to the invention in that the filter medium saturated with filtrate at the base of the granular bed is conducted at a controlled rate through vertical transport pipes and is raised above the liquid bed by the controlled part-stream passed into the transport pipes from the untreated liquid entering into the filter section, then, separated from the transport liquid, is returned by gravity to the upper part of the filter bed, the filter medium being washed in countercurrent with the aid of filtered liquid conducted upwards by passing through air, and the contaminated washing liquid being discharged together with the transport liquid.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a process for continuously filtering fluids, in particular waste water, on a moving granular bed.

In the treatment of liquids, especially waste water, there is often a problem of removal of solid or flocculent substances with a high efficiency of the removal process. Frequent filtration equipment with a fixed bed filled with a granular filling is often used for post-treatment to remove suspended matter. While the fluid flows through the filter medium, the suspended particulate matter is retained on the grain surfaces that are deposited in the cavity of the filter bed. Upon capturing a certain amount of hovering substances, a secondary filter layer is formed which, while providing an extremely pure filtrate (so-called crystal filtration), increases the hydraulic resistance of the layer to such an extent that the original filtering performance decreases to a fractional value. In this case, the filter is released and regenerated by introducing water in the opposite direction of flow as well as air, while the water used for regeneration is collected and cleaned. use high flow velocities, which generally cannot be ensured from a common water line, so that a supply of flushing water is needed. · To ensure continuous filtration, the water had to be transferred to another filter while the filter was flushing. This device, which must be equipped with a flushing water tank and a parallel-working filter, increases the specific investment costs on a rather significant scale. A further disadvantage of these known devices is that the regeneration of the filters can only be carried out with pure water, since flushing and regeneration with untreated water could clog the distribution system arranged below the filter bed. It is also disadvantageous that the filter cartridge must consist of grains having the same size, as otherwise the regeneration would result in the formation of a grain. separating the individual grain fractions and bringing the smaller grain size into the top layers of the filter, where these grains would accumulate and speed up filter clogging.

Similar disadvantages also have filters which are a more modern solution in terms of filtration technology and which act radially outwards from the inside. The essence of their function is that the water to be filtered is fed through a tube provided with slits and located in the axis of the device to the inner casing surface of the filter bed. The water flows radially outwardly through the horizontally perforated outer wall of the device into the collecting chamber from which the filtered water exits the device. The advantage of this device is that in the case of the radial flow of filtered water, the size of the filter surface gradually increases and thus also the efficiency of the filter, while the investment costs and the space consumption requirements remain low. Regeneration is carried out periodically by flushing in countercurrent. Such a filtration method and apparatus for performing this method is described in German Patent DOS no. 1 926 934. ⁴

In order to increase filter flushing efficiency and to reduce the amount of flushing water required, periodically operating systems have been upgraded to an embodiment in which the entire filter bed is agitated during flushing and the grain surfaces are cleaned by abrasion with sand grains. One such filtering device is the so-called Bollmann filter (described in Dr. Benedek-Valló's brochure: "Viztisztitás-Szennyviztisztitás", Mtiszaki Konyvkiado, Budapest 1976, p. 180),

When the filter is clogged, the water supplied under high pressure by an injector arranged on the flushing tubes in the center of the filter is cleaned in the tube and is led up again to the top surface of the filter layer, the clogging impurities being carried away waste water.

In order to overcome the disadvantages associated with the periodic operation of the apparatus, a continuous filter has been developed according to the German DAS No. 27 08 340. In this apparatus, a sand bed is arranged below the conical reservoir. The waste water is supplied by a supply element arranged at the bottom of the bed. The waste water is cleaned during its bottom-up movement on the filter bed and the filtered water flows through the overflow edge at the top of the plant. The tube providing movement of the filter bed is located in the axis of the device. When air is introduced into the tube from below, the sand flows through the known effect used. however, in the case of a mammoth pump, upwards in the filter section it flows downwards at a lower speed. The sand is cleaned at the upper end of the pipe in the water column section above the filter bed and falls back onto the upper surface of the filter bed. The flushing water exits the device and carries with it impurities and contaminants.

The disadvantage of this continuous filter is, in particular, that the amount of liquid in the conveying tube and the amount of filtering material to be transferred vary only within narrow limits, although the amount of air to be aerated can vary to a very wide extent. As a result, the regenerative capacity in the filter bed is limited. The amount of water supplied to the conveying tube is limited by the resistance or permeability of the filter bed slowly flowing downward, and increasing this amount of water accelerates the transport of the granular material and thereby improves regeneration. In wastewater filters containing a large amount of suspended matter, the movement of the filter bed is not sufficient, the filter becomes clogged and the movement of the filter bed gradually ceases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for continuous filtration which overcomes the drawbacks of known filtration processes using a movable filter bed, in which the flow rate of the filter substance and the flushing rate can be independently controlled.

This object is achieved by the continuous liquid filtration method according to the invention, characterized in that the filtrate-saturated filter medium is fed in a controlled quantity through a vertical conveying tube to the bottom of the granular filter bed and lifted together with the partial stream of purified liquid entering the controlled - a quantity into the filter section, above the filter bed, after which the filter means, after being separated from the conveying liquid, is guided by gravity back to the upper part of the filter bed, the filter means being countercurrently flushed with purified liquid lifted up with the air; with transport liquid.

In the method according to the invention, the movement and regeneration of the exhausted and filtrate-saturated filter substance from the filter bed can be regulated separately. The movement of the bed is regulated by an adjustable slot in the bottom of the conveying tube and by the amount of liquid, while the flushing of the filter medium is regulated by the amount of air.

If the resistance of the filter bed increases or decreases during filtration, the rate of movement of the filter bed changes as a result of pressure changes in a suitable direction and the system is self-adjusting to a certain narrow range. In the case of major changes, the size of the slot in the bottom of the conveyor pipe and the amount of liquid need to be changed. In the flushing section, the flushing liquid flow can be varied over a wide range by varying the air intake, and thus the conditions of regeneration and its quality can change.

This broad control option is particularly advantageous if the content of contaminants in the filtered water varies within wide limits and, consequently, the amount of filtering agent to be regenerated also varies considerably. Control is also necessary if the filtrate is well attached or sticky, so that filtering conditions and regeneration circumstances must be improved by increasing the surface action.

Overall, the advantages of the solution according to the invention can be summarized as follows: the movement of the filter means can be regulated according to the method according to the invention. requirements; when the filter resistance increases, the speed of movement of the filter means increases due to pressure changes; when the resistance decreases, the speed of movement decreases, i.e. the system is able to automatically adjust to the required values within certain narrow limits; regeneration · filtering material in countercurrent with filtered · liquid and air keeps the filter bed · always clean; flushing conditions can vary according to changing requirements by air supply very easily and independently of the transport of the filter medium; Any plugs formed in the apparatus according to the invention can be removed very simply. At equilibrium, conditions for crystal filtration are continuously formed so that the filtrate is always pure; The process according to the invention can be used over a wide range of different concentrations to continuously filter filtrates with unfavorable filtration properties.

The apparatus for carrying out the method according to the invention is bounded by a cylindrical or planar wall and at the bottom is terminated by a truncated cone-shaped part or a truncated pyramid-shaped part partially filled with filter means; wherein a conveying tube is disposed in the vertical axis of the apparatus to allow movement of the lifted filter material within the interior space of which is a distribution and guide means and which is provided with an overflow edge, the apparatus further having a space for separating and flushing the raised filtering material middle walls. The device according to the invention is characterized in that a slot for adjusting the speed of movement of the filter bed, adjustable by a vertically sliding tube, is provided at the bottom of the conveying tube, and a distribution chamber is provided at the bottom of the flushing space to feed and disperse the air flow. flushing liquids, the manifold chamber being provided with a slot.

According to a preferred particular embodiment, openings are provided in the upper part of the distribution chamber, covered by guide plates. According to another preferred embodiment, a fluid stream is connected to the movable tube.

According to a further advantageous embodiment of the invention, the lower part of the device opening into the chamber of the cone or the chamber of the pyramid part is provided with a distributor for introducing air in which a slot is formed.

An exemplary embodiment of an apparatus for carrying out the method according to the invention is shown in the drawing, in which a longitudinal section through a suitable embodiment of the apparatus is shown.

In the tank · bounded by cylindrical or planar walls 1, passing downwardly through the cone section 2 or the pyramid section, there is a conveying tube 4 for transporting the granular filter means 26. The filter means 26 is guided from the conveying tube 4 through a flushing space 7 , bounded by cylindrical walls 5, 6 along arrow d, by the liquid space 3 to the surface of the filter bed. Meanwhile, the filtering means 26 is regenerated by treatment with upwardly-flowing flushing liquid E, set in motion by a stream 6 of the air introduced into the distribution chamber ^10: a slit 11 and valve 29. The regulated · · For a uniform distribution of the filter means 26 include a cone 12 and a pipe 13, for uniform displacement of the filter bed, the conical guide elements 14, 15. The purified liquid stream Ai is guided by a guide 14 provided with a deaerator 16 and flows in the direction of the arrow and upwards. edge

9.

The flow A2, which is controlled by the valve 27, flows in the direction of arrow c through the distribution chamber 19 and the controllable slot 28 and is fed together with the granular filter means 26 into the conveying tube 4, which flows upwards. The downward movement of the bed saturated with filtrate is supported by flowing purified liquid moving in the direction of the arrow ba and also through the opening 23. The guide plate 24 serves to cover the openings 23 between the granular filter means 26 and the distribution chamber 19. The speed of the filter bed can be controlled an adjustable slot 20, adjusted by the movement of the tube 21.

The grains contaminated by the filtrate are collected in the conveying tube 4 against the guide plate 25 and are partially free of impurities and fed to the flushing space 7. The liquid containing the impurities and consisting of the conveying liquid D and the flushing liquid E is removed from the apparatus by overflow overflow edge 8.

When the clogged, difficult to move filter bed is moved, it is advantageous if the manifold 19 is closed down in the direction of the slot 20 and a liquid flow A3 controlled by the valve 31 is supplied through the tube 21 to the lower part of the conveying tube 4. In this case it is guided only through the opening 23 on the filter bed and, as it moves upwards, causes a grain movement.

If the bottom of the device becomes clogged, the bed can be released by a stream of air G supplied by the manifold 17 and slot 18 and a controlled valve 30. In this case, it is expedient to guide most of the liquid to be cleaned by closing the valve 28 through the manifold 19 into the bottom. parts of the bed. If necessary, the grains can be discharged from the device by the closure element 22.

Claims (7)

Subject A method of continuously filtering liquids, wherein the liquid flows upwardly on the filter means also movable upwardly and the filtered liquid is continuously discharged from the liquid space located above the filter means, characterized in that the filter medium saturated with the filtrate, is fed from the bottom of the granular bed in a controlled amount through a vertical conveying tube and is lifted above the liquid bed by a partial stream of purified liquid which is fed in a controlled amount to the conveying tube through a filter section, then transported separately by gravity a filter bed, wherein the filter means is flushed in countercurrent with the filtered liquid directed upwards by means of the incoming air and the contaminated flushing liquid is discharged together with the transport liquid. Method according to claim 1, characterized in that the amount of flushing liquid is controlled by the amount of air introduced. 3. Apparatus for carrying out the method according to items 1 and 2, provided with cylindrical or planar walls terminated at the bottom with truncated cones or truncated truncated parts, partially filled with filtering means and provided with a conveying tube for conveying clogged filter material provided with dividing means and guiding means and also YNALEZU with a falling edge and for separating and flushing the raised filter means is provided with a space bounded by walls, characterized in that in the bottom of the conveying tube (4) there is an adjustable slot (20), adjustable by a vertically movable tube (21) the filter bed and the device is further provided with a distribution chamber (19) for supplying the liquid stream (Up) and a second distribution chamber (10) at the bottom of the flushing space (7) for supplying and dispersing the air flow (C) (E), wherein the second manifold chamber (10) is provided with a slot (11). Device according to Claim 3, characterized in that openings (23), which are screened by guide plates (24), are arranged in the upper part of the distribution chamber (19). Device according to Claims 3 and 4, characterized in that it is provided with a connection to the movable tube (23) for supplying a liquid stream (A3). Device according to Claims 3 to 5, characterized in that guide plates (25) are arranged in the conveying tube (4). Apparatus according to any one of Claims 3 to 6, characterized in that a distributor (17) having a slot (18) for introducing the air flow (G) is arranged in the lower part of the apparatus ending in the truncated cone or truncated truncated parts.