RU2044555C1 - Disk filter - Google Patents

Abstract

FIELD: liquid or suspension filters production. SUBSTANCE: disk filter has at least one filtering disk 3, that is partially dipped in tank with subjected to filtration liquid or suspension. In the case the filtering disk has great number of ring-shapely located filtering sections 4 and is capable to rotate relatively to collecting tray for solid substance, that is settling on outer side of filtering sections 4 and following from them down. Each filtering section has hole for filtrate, through which inner part of filtering section communicates with axial canal 8 for filtrate discharge. Hole for filtrate is located on rear edge of filtering section in respect to direction of rotation and is connected with front side of axial canal 8 in respect to direction of rotation. As a result of it filtering sections are made so as to be located radially outside and also radially inside axial canals 8. EFFECT: simplified design. 6 cl, 8 dwg

Description

 The invention relates to a disk filter device comprising at least one filter disk partially immersed in a reservoir for a filtered liquid or suspension, said filter disk comprising a plurality of annularly arranged filter sectors rotatably relative to a collecting tray for solids deposited on the outside of the filter sectors and falling from them down, with each sector of the filter has an opening for the filtrate, through which the inside of the sector the filter communicates with the axial channel for discharging the filtrate, and the aforementioned hole for the filtrate is placed on the rear edge of the filter sector with respect to the direction of rotation and, when the filter disk rotates, is connected to the front side of the axial channel with respect to the rotation direction.

 Filters of this type are mainly used in the pulp and paper industries for thickening the fiber suspension and for treating industrial water of the so-called fiber extraction.

 The purpose of the invention is the preservation of high performance with small dimensions of the rotor.

 Figure 1 shows the proposed filter, a cross section (with the location of the axial channels of the output of the filtrate along the middle circumference of the annular disks); in FIG. 2 node I of figure 1 (the location of the output channels of the filtrate along the periphery of the annular disks); figure 3 node I of figure 1 (the location of the axial channels of the output of the filtrate at the inner circumference of the annular disks); figure 4 filter, end view (connection of the output channels of the filtrate with the central outlet without filter sectors); figure 5 section aa in figure 4; in Fig.6 section BB in Fig.5 on an enlarged scale; in Fig.7 node B in Fig.5; in FIG. 8 part of the filter sector in more detail and the corresponding axial channel for output of the filtrate on an enlarged scale.

 In the reservoir 1 for a suspension or other filter fluid, the filter rotor 2 is partially submerged under the liquid level L, the rotor including a plurality of filter annular filter discs 3. Each filter disk 3, in turn, includes a plurality of filter sectors 4 arranged in a ring and forming a hole 5 in the center. Through the holes 5 of all filter disks, a tray 6 is installed to collect solid matter falling down from the filter sectors. At the bottom of the collecting tray 6, an exhaust screw 7 is disposed to remove solids collected in the tray.

 To rotate the filter rotor 2 in the direction of rotation indicated by the arrow R, a drive is provided (not shown in the drawing).

 Each filter sector 4 has two spaced apart layers of filter cloth and filter means 27 through which the liquid contained in the reservoir 1 is filtered. Due to this, a solid precipitates on the outside of the filter medium, while the filtrate flows through it into the filter sector. To output the filtrate from the inside of the filter sectors, there are axial channels 8, which are connected to the radial channels 9 for the filtrate, going to the central outlet 10 at one end of the filter. The axial channels 8 for the filtrate are connected to the radial channels 9 for draining the filtrate, form part of the filter rotor 2 and form a structural housing forming sectors 4. The number of axial channels 8 corresponds to the number of filter sectors 4 of each filter disk 3, each axial channel for the filtrate each other connected to one filter sector of each filter disk. Issue 10 is made of a rotating type and is intended for serial connection of radial channels 9 for output of the filtrate and through them axial channels 8 for output of the filtrate with a source of reduced pressure (not shown). The ends opposite to the outlet 10, the axial channels are connected to a circular support ring 11, on the inside of which are located (not shown) supporting means for the filter rotor.

 According to the proposed technical solution, each filter sector 4 is connected with its edge leading in the direction of rotation into the axial channel 8 for output of the filtrate. Such a connection is made on the part of the axial channel for the filtrate, facing up when the filter rotor rotates, when the axial channel is raised above the surface of the liquid. Such a device makes it possible to install filter sectors so that they are radially inward (see figure 2), i.e. on the periphery of the disk, radially outward (see figure 3) or the inner circumference of the disk, i.e. along the middle circumference of the disk (see figure 1) from the axial channels 8 for the filtrate.

 It is desirable that the axial channels 8 have a cross-sectional shape better represented in FIGS. 6 and 8, i.e. triangular with the long side 12 and two short sides 13 and 14. On the long side 12, which is turned up when the axial channel is raised above the liquid level L, a series of holes 15 are made corresponding to the number of filter disks. As shown not in great detail, the filter sector 4 is mounted against each such hole 14 so that its inside communicates with the inside of the axial channel 8 through the corresponding hole 16 (see Fig. 8) at the edge of the filter sector.

 The long side 12 provides a relatively long connection distance for the filter sector and thereby a large area of the hole 15, as well as a stable connection of the filter sector. The long side 12 is connected to the short sides 13 and 14 by means of curved surfaces 17 and 18 so that a large internal cross section is created. The short sides 13 and 14 are interconnected by an end 19, which faces downward when the axial channel for the filtrate is raised above the liquid level L. Due to this, a channel is created having two lateral sides 13 and 14, inclined towards the end 19.

 As mentioned above, the filter sector can be installed so that it is facing both radially inward and radially outward from the axial channel to output the filtrate. Most preferred are filter sectors (see FIG. 1), which are located radially inward as well as radially outward from the axial channels for the filtrate.

 Such a filter sector is separately shown in Fig. 8 together with a corresponding axial channel for the filtrate. In a known manner, this filter sector 4 has an outer arcuate edge 20 from which the edge 21, front in the direction of rotation, and edge 22, rear or rear in the direction of rotation, are located to the center. The edge 22 is divided into a radially outer part 23 of the edge and a radially inner part also of the straight part 24 of the edge. The edge portions 23 and 24 form such an angle that these edge portions are inclined downward to the axial channel 8 for the filtrate, to which the said filter sector is connected when the filter sector and its corresponding axial channel for the filtrate are raised above the liquid level L. This is well represented in FIG. 1, where the axial channel 8 for the filtrate is located just above the surface of the liquid. The filter sector in FIG. 8 is shown in the same position. In the shown example, the outer parts 23 of the filter sectors are provided with openings 16 and connected to the openings 15 of the axial channels 8 for the filtrate. From Fig. 1 it is also clearly seen that the entire filter sector is raised above the surface of the liquid, i.e. that the filtrate can no longer occur at the time when the axial channel 8 has short sides 13 and 14 of its cross section tilted down to the bottom of the filtrate channel, namely towards the end 19.

 This ensures that the filter sector is completely emptied before it is turned so far that the filtrate can flow radially inward and again moisten the solid that has settled on the filter sector.

 The front edge in the direction of rotation 21 of the filter sectors 4 form two parts 25 and 26 at an angle to each other (see Fig. 8).

 To make it possible for leachate to flow out of the axial channels 8, they are tilted down to the radial channels 9 for the filtrate at a certain stage of rotation, namely, shortly before the corresponding filter sector rises above the liquid level before the axial channel for the filtrate is raised above the liquid level (see Fig. 5). The slope becomes greater when the axial channel for the filtrate passes the liquid level (see Fig. 1). As can be seen from figure 5, the radial channel 9 for the filtrate is also tilted down to the outlet 10 in the corresponding rotational positions.

Claims (6)

 1. DISK FILTER containing at least one filter disk partially immersed in a reservoir for filter liquid or suspension and including a plurality of filter sectors located on the ring, the disks are mounted for rotation relative to collecting for a solid substance deposited on the outside of the filter sectors and falling downward from them, with each filter sector on the back wall with respect to the direction of rotation of the wall has a hole for output of the filtrate, through which friction portion of a filter sector communicates with an axial channel for discharge of filtrate having the front in relation to the rotation direction until the side opening, characterized in that the filter sectors are disposed radially outwardly and radially inwardly of the axial channels.  2. The filter according to claim 1, characterized in that the front edge in the direction of rotation of each filter sector includes two edge parts mounted at an angle to one another.  3. The filter according to claim 2, characterized in that the two edge parts are tilted to the filtrate hole in the axial channel when the front channel of the filter sector is in a liquid raised above the level L in the tank.  4. The filter according to claims 1 to 3, characterized in that the front edge of the filter sector is connected to the front side of the axial channel in which a hole is made corresponding to the hole for the filtrate of the filter sector.  5. The filter according to claims 1 to 4, characterized in that the axial channels are inclined downward to the outlet of the filter when the filter layer is raised above the liquid level L.  6. The filter according to claim 5, characterized in that the radial channel connected to each axial channel and with the outlet of the filter is configured to tilt to the outlet in the respective rotation positions.

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