FI109092B - Method and apparatus for filtering a liquid containing finely dispersed solid matter - Google Patents

Description

109092

The present invention relates to a method for filtering a finely divided solid containing a porous material filter element in a filtering state, , from which the filtered liquid is removed. In addition, the invention relates to apparatus for the method is implemented in 10 ways.

The small solid particles that appear in the liquid turbidity can be a disadvantage to the quality of the liquid or a problem with the processing of the liquid. The purpose of filtration is to separate such particles from the liquid as completely as possible so that the filtrate is as clear as possible. The particle size varies from a few micrometers to a few micrometers, and the solids in the liquid can range from 1 mg / l to 10 g / l. For the smallest particles to separate from the liquid and result in a perfectly clear filtrate, the pores of the filter material must be small enough, generally less than 5 µm.

The problem with clarification filtration has been that the small colloidal particles 20 tend to clog the micropores of the filter material rapidly, thereby reducing the filtration capacity of the material. The particles that penetrate the surface pores of the filter material may mechanically block the pores or the particles may bind to the surface of the material by chemical or electrical bonding.

'·': The capacity of the clarification filter can be maintained by periodic exchange of the filter material, which, however, is a laborious operation and causes the filtering process to be interrupted. The alternative has been to regenerate the filter material by reverse rinsing, solvent washing or ultrasonic cavitation, which they also require. *. stop the process. Reverse rinsing usually does not achieve the filter material. · · ·. complete purification, but it has been used as a quick supplement to other regeneration.

t ·;: FI patent application 982161 discloses a clarification filter in which a vertical cylindrical filter element is disposed in a cylindrical container where it can be rotated, the liquid to be clarified is fed from the element to the upper end of the element. motion 2 109092 pictures against the diaper surface. The purpose of the arrangement is to achieve self-cleaning of the filter element by tracking the collisions between particles adhering to the surface of the element, clogging the element and a fluid stream fed to the process, resulting in shear forces to release the particles and thereby keep pores of the filter material open. Special features of the described filter include providing a significantly narrow gap between the interior surface of the container and the filter element jacket, and supplying a fluid flow to this slot at a rate greater than the peripheral speed of the filter element.

The filter self-cleaning principle of FI application 982161 has proven to work in practice, but the disadvantage of the implementation described in the application is that the surface of the filter element remains clean only at the upper end of the element in the area where the flow to be clarified occurs. Only there, the flow rate is high enough to cause collisions to release particles adhering to the element shell. Moving downward, the flow rate of the liquid in the gap between the filter element 15 and the inner surface of the container decreases, whereupon the particles cease to separate and the solid accumulates in the cake on the surface of the filter element, i.e. the process becomes conventional cake filtration. The desired increase in filtration efficiency is thus only partially realized, not to the extent that the sheath surface area of the filter element would allow.

It is an object of the present invention to provide a solution that eliminates the aforementioned drawbacks of the filter according to FI application 982161 by allowing a uniform self-cleaning of the filter element throughout its surface area during the filtration process. as. The method according to the invention is characterized in that the liquid to be filtered is introduced into an inlet pressure equalizing housing on the side of the filter element which is provided with an elongate feed slot or row of inlet openings to be discharged towards the filtering element, substantially: the entire length of the element extending along the axial length.

In particular, the invention encompasses a clarification filter, which requires the material of the filter element to have a pore size of up to about 5 µm.

> t .: 30 In the filtration process according to the invention, the flow of liquid to be introduced into the filtration space: ·. collides with the enveloping surface of the filter element which rotates against it as a substantially uniform front to end element, i.e.. as a curtain jet, whereby the effect of keeping the impact element clean is evenly distributed over the entire surface area of the element .. shell. The filtration process is facilitated by the most turbulent flow conditions in the filter element surrounding the filter element, preferably in a narrow cylindrical filtration space. The improved self-cleaning of the filter element achieved by the invention means

Preferably, the fluid to be discharged from the feed slot or inlets is inclined obliquely against the rotating shell surface of the filter element at an angle of up to about 50 ° to the tangential direction of the shell. Most preferably, the collision angle between the fluid flow and the tangent of the jacket is between 15 ° and 45 °.

Preferably, the flow rate of the liquid discharged into the filtration is tracked to a maximum greater than the peripheral velocity of the shell of the element. Suitably, the fluid flow rate is greater than 4 m / s but less than 20 m / s, and most preferably between 8 and 12 m / s, while the peripheral velocity of the element shell is not more than about 1 m / s.

The turbulent flow conditions required by the invention in the filtration space surrounding the filter element are best realized when the space is formed by the narrowest possible gap between the housing of the element and the container wall defining the filtration space. Most preferably, the filter element and the container are vertical circular cylinders, with the filter element generally having an outside diameter of at least about 20 cm, usually 30 to 60 cm. Preferably, the width of the filtering space, i.e. the gap between the cylinders, is up to about 2 cm, most preferably 0.2 to 1.5 cm. The width of the elongate feeder slot 20 is 0.5 to 2.5 mm, most preferably 1 to 2 mm.

; ': The inlet openings which may replace the inlet slot may consist of nozzles which may be arranged in a tight row extending over the entire length of the filter element. . ·. to provide a uniform curved feed jet.

'' In order to increase turbulence, it is preferable to recirculate the unfiltered liquid removed from the filtration chamber to the filtration chamber by pressure directed against the direction of movement of the filter element shell. Recycling can be accomplished separately from the rest of the fluid to be filtered by introducing the recycle stream into its own pressure relief housing, from where it discharges into the filtration space as described above, in the same manner. · '*: As a fresh liquid stream to be fed.

The apparatus of the invention for filtering a liquid of fine solids: '*': by filtration comprises a filter space delimiting container, a filter element rotatable filter element, a filter fluid flow inlet channel, at least one inlet opening for directing liquid through the element's casing surface to remove the filtered 4 109092 liquid. According to the invention, it is essential in the apparatus that the fluid flow passage for filtration leads to a supply pressure equalizing housing on the side of the filter element provided with an elongate feed slot or row of inlets for discharging fluid into the filtration space perpendicular to the element.

The container and the filter element are preferably concentric vertical circular cylinders. Porous ceramic materials such as alumina, silicon carbide or silicon nitride are particularly suitable as the filter element material. Also porous sintered metal such as stainless steel, nickel or titanium may be an issue. The pore size of such 10 elements is preferably in the range of 0.2 to 2 µm, whereby it is capable of separating colloidal particles such as clay particles and even bacteria from the liquid.

The invention will now be described in more detail by way of example with reference to! Fig. 1 is a vertical sectional view Π-Π of Fig. 1 and Fig. 3 shows a vertical sectional view ΙΙΙ-ΠΙ of Fig. 1.

The apparatus according to the drawings comprises a vertical cylindrical container 1 with a centrally located vertical cylindrical filter element 2. The cylindrical sheath 3 of the filter '% 4' 20 is, for example, a sintered ceramic having a pore size: 0.2. —2 pm The diameter of the sheath 3 is e.g. 40 cm, and the distance of the sheath: ,, / from the inner surface of the container 1 is e.g. 1 cm. (Schematic drawings do not exactly correspond to this dimension.) There is thus a 1 cm wide annular filtration space 4 between the jacket 3 and the inside surface of the container 1, which in use is filled with liquid supplied to the apparatus.

The apparatus described describes the clarification of liquids having a finely divided dispersed solids which may form a liquid impervious to the liquid and which may or may not be valuable and therefore desirable to obtain, da recovered. According to the drawings, the apparatus is supplied with liquid to be clarified from two supply channels 5 which lead to vertical housings 6 which form '···. 30 part container 1 wall. The housings 6 serve to equalize the pressure of the feed stream and distribute the flow evenly into a narrow, vertical, substantially reservoir-to-end feed slot 7. As shown in Fig. 2, the slot 7 is cut off: 'by a few narrow stems 8 - 5 109092 fortifying them without affecting fluid supply. Figure 1 shows that, beside the slots 7, the annular filtration space 4 between the wall of the container 1 and the sheath 3 of the filter element is constricted to increase the rate of flow in the space. The liquid stream to be clarified is discharged from each of the feed slots 7 towards the filter element sheath 3 as a substantially continuous end-to-end jet or front which strikes the sheath surface at an angle of approximately 45 ° to the tangential direction of the sheath. The liquid thus supplied to the filtering space 4 is filtered through the mantle 3 of the filter element 2 as a clarified liquid flow which exits the openings 9 into the axial outlet 10 and as the opening 11 in the clarified flow outlet 12 acting as a filter element carrier.

During the brightening process, the cylindrical filter element 2 is rotated about its axis j anticlockwise against the feed direction of the liquid to be clarified from the feed slots 7. The apparatus comprises an electric motor 13 which, via a gear 14, rotates the shaft 15 and the exhaust pipe 10 which extends thereto, which ultimately acts as the axis of the filter element 2. By rotating the filter element 2 through the slits 7, the liquid stream to be clarified is collided with the entire surface of the element shell 3, during which continuous collisions occur during the filtration process, shear forces releasing solids adhering to the shell surface and preventing clogging.

In the clarification process, it is strongly sought to maintain turbulent flow conditions in the narrow annular filtration space 4 between the filter element 2 and the inner wall of the container 1. Turbulence is enhanced by the input *; 'Fluid flow recycling. To this end, the apparatus is provided with a recirculation channel '·' 25 16, which starts from below the filter space 4 at the lower end of the tank 1 and passes through the pump 17 to a housing 18 integrated into the tank wall similar to the aforementioned fresh - t: a row of nozzles 19 extending from space to container 4 towards the shell surface 3 of the recycled liquid filter element which is substantially uniform; '": 30 in a jet or in front of the aforementioned feed slots 7. through a nozzle 19. The recirculated flow of nozzles 19 thus provides similar fluid-to-element collar 3 solids and diaper-clean collisions as mentioned above. Inlet nozzle 7 and a continuous :: sealed row of separate nozzles 19 operate in substantially the same manner and are interchangeable in the apparatus described 35. In other words, the recirculation flow .... could be supplied from an elongated feed slot instead of nozzles 19 or instead of the slots 7, a series of nozzles tracked in a row are used.

In addition to the pressure relief housings 6, 18 already mentioned on the wall of the container 1, the apparatus illustrated has a vertical row of ultrasonic vibrators 20. These 5 ensure that, if solid adheres to the surface of the filter element 2 over time, the brightening process can be interrupted and cleaning or replacement of parts. In the apparatus shown, it is also possible, during interruptions of the process, to perform a backwash washing of the filter element 2 with a pressurized washing fluid fed from the channel 12 which, after passing through the element 10, discharges into the solid drainage channel 21 starting from the

It will be apparent to one skilled in the art that various embodiments of the invention are not limited to the example described above, but may vary within the scope of the following claims.

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Claims (16)

7 109092 s j A method for filtering a liquid containing finely divided solids, wherein the filter element (2) in the filtering space (4) is rotated about its axis (10, 15) and the fluid to be filtered is introduced into the space against the direction of movement of the element shell (3). is filtered through an element casing on the inside of the element from which the filtered fluid is removed, characterized in that the fluid to be filtered is introduced into a supply pressure equalizing housing (6) on the side of the filter element (2). facing towards the shell surface (3) of the element, extending substantially along the entire axial length of the element. Method according to Claim 1, characterized in that the material of the filter element (2) has a pore size of about 5 µm or less, thereby providing clarification of the liquid to be filtered. Method according to claim 1 or 2, characterized in that the liquid to be discharged from the housing (6) is directed obliquely against the rotating surface (3) of the filter element. s Method according to one of the preceding claims, characterized in that the flow rate of the liquid discharged from the housing (6) to the filtration space (4) is greater than '20 than the circumferential velocity of the element shell (3). Method according to claim 4, characterized in that the '· ·. with a back velocity greater than 4 m / s but less than 20 m / s, preferably 8-12 m / s, and that element. · '·. the peripheral velocity of the diaper (3) is up to about 1 m / s. Method according to any one of the preceding claims, characterized in that '' ··. The width of the '' 'gap between the wall (1) delimiting the 25 filter spaces (4) and the sheath (3) of the filter element (2) is up to about 2 cm, preferably 0.2 to 1.5 cm. A method according to any one of the preceding claims, characterized in that the unfiltered liquid is removed from the filtration space (4) and recycled therein, at a pressure directed against the direction of movement of the filter element shell (3). A method according to claim 7, characterized in that the recirculation is effected separately from the rest of the fluid to be filtered by introducing a recirculating flow 109092 8 into its own pressure relief housing (18) from which the liquid is discharged into the filtration (4) facing the shell surface (3). An apparatus for filtering a liquid containing finely divided solids, comprising an enclosure (1) defining a filtration space (4), a rotating filter element (2) in the filtration space, a fluid flow inlet channel (5), at least one inlet (7) against the direction of its movement, as well as through the jacket of the passage (10, 12) to remove the fluid filtered into the element, characterized in that the fluid passage channel (5) leads to a supply pressure equalizing housing 10 (6) on the side of the filter element (2) 7) or a row of inlet openings for discharging the filtering filter (4) towards the shell surface (3) of the element, extending substantially along the entire axial length of the element. Apparatus according to claim 9, characterized in that the reservoir (1) and the filter element (2) are concentric vertical circular cylinders. Apparatus according to claim 10, characterized in that it comprises at least one vertical, integral housing (6) integrated into the wall of the container (1). Apparatus according to one of Claims 9 to 11, characterized in that the feed slot (7) or feed openings (19) of the housing (6) are directed towards the diaper surface (3) of the filter element 20 (2) at an angle of not more than about 50 °. . ; '; Apparatus according to any one of claims 9 to 12, characterized in that The outer diameter of the diaphragm (3) of the data element is at least about 20 cm, preferably 30 to 60 cm, and the gap between the inner surface of the wall of the container (1) and the diaphragm of the filter element is 25 cm or less. , preferably 0.5 to 1.5 cm. »· Apparatus according to one of Claims 9 to 13, characterized in that the gap between the wall of the container (1) and the element: the sheath (3) is adjacent to the feed slot (7) or feed openings (19). »>» Apparatus according to one of Claims 9 to 14, characterized in that the apparatus comprises a circulation channel (16) stolen by a pump (17) from the filtration chamber (4): "; to recirculate the suction unfiltered liquid back to the filtration chamber, ) directed against the direction of movement. * 9 109092 Apparatus according to Claim 15, characterized in that the apparatus comprises a separate pressure equalization housing (18) for recirculation flow, provided with an elongate feed slot or row of feed openings (19) for discharging recyclable liquid into the filtration space (4) facing the diaphragm surface (3). that is, a front extending over the entire axial length of the element.