FI73892B - SJAELVRENANDE FILTER FOER VISKOESA SUSPENSIONER. - Google Patents

Description

73892

Self-cleaning filter for thick suspensions

The invention relates to filtration devices and relates in particular to a self-cleaning filter for thick suspensions, such as fuel.

The invention can most preferably be used to clean very thick fuel in marine power engines.

Self-cleaning filters designed for cleaning thick fuels and comprising a housing and a filter element are generally known. The housing has connection pipes for fuel supply and discharge and also a flushing pipe for sludge removal. The filter elements can be of the surface, slot or screen type.

15 Self-cleaning of filters is based on the generation of a countercurrent flow or the use of: ·· ’mechanical cleaning devices (scrapers).

• A self-cleaning filter with a cylindrical housing and connecting pipes for fuel supply and discharge is known. The housing includes a surface and slit filter element to which a hydraulic self-cleaning system is connected. The filter element consists of a frame with longitudinal slats on which a calibrated, small-diameter stainless steel wire is wound. Muo-25 tore grooves made in slats provide en--. there is a certain clearance between the turns of wire which form the slit surface of the filter element, and thus the desired purity in the filtration of the fuel is guaranteed. The fuel passes through the filter element from the perimeter towards the center. Mechanical] ·. 30 contaminants remain on the outer surface of the element.

The hydraulic self-cleaning system consists of a hydraulic * * motor driven by the flow of fuel to be filtered and a propeller device mounted inside the filter element. The vanes rotate about an axis so that they rapidly get closer to each other at regular intervals, creating a countercurrent flow of fuel in one sector of the filter element. The propeller device performs a complete cleaning of the filter element four times a minute.

However, the propeller device makes the filter quite complicated.

The wire may break when filtering very thick liquids or disassembling the device, indicating that the swamp-1Q data element is quite weak and causes certain difficulties in repairing the surface of the filter element and the propeller device. In addition, when handling very thick resinous fuels, the self-cleaning ability of the filter is considerably impaired, which impairs its reliability because the surface of the filter element 15 is heavily soiled with resinous substances.

The reverse flow of fuel generated by the propeller device is not capable of removing the surfactant resinous substances that are abundant on the surface of the 2Q filter element. When the filter is still dirty, the wings get stuck and the filter stops working.

A self-cleaning filter with a conical sieve filter element with the tip mounted downwards is also known. The screen filter element has a vibrating device.

However, the purity of the filtration in such a filter depends on the size of the screen opening. Furthermore, such a structure of the filter element cannot guarantee long-term and high-quality cleaning of the fuel, since complete removal of mechanical particles 3Q from the filter element screen can only occur during vibration if the particles ** ** come into contact with the screen wire in the direction of the wire cross-section. , which is at right angles to the baseline of the cone of the filter element. In the other 35 cases, mechanical impurities penetrate the opening along the circumference of the wire. If the size of the mechanical impurities is approximately the same as the size of the orifice, the impurities can enter the pure liquid state and the pulsating fluid flow together with a thin filter barrier consisting of 5 screens can only contribute to this penetration, thus degrading the filtration quality. It is very unlikely that mechanical particles will hit the screen wire when the diameter of the wire is the same as the opening; while coarse contaminants enter the openings, they become clogged because the openings form a kind of recess in the surface that is filled with coarse mechanical contaminants during the vibration of the filter, especially in reverse-phase motion.

As a result, a deposit is formed in the screen filter element and accumulates even during its vibration, and this deposit is removed only when its mass becomes large enough to detach the vibrating screen from the screen. due to the inertia forces generated by the For this reason, \; the lawful screen operates at varying throughput. In addition •. 20 it is not possible to completely remove the deposit from the screen; when handling very thick fuels with a large amount of surfactants, because the screen acts as a kind of "crystal mesh" and makes self-cleaning of the filter element even more difficult.

The object of the invention is to provide a self-cleaning filter for thick suspensions, preferably for thick * · .. fuel, with which a better Y is obtained as a filter; fuel cleaning due to the better design of the filter element.

* "* 30 This problem is solved by a self-cleaning filter for thick suspensions comprising a hollow housing with connection pipes for suspending the feed, removing the filtrate and removing the sludge, a conical filter element mounted in the housing. According to the invention, according to the invention, the filter element comprises a plurality of plates with openings forming a central channel and which are mounted in a central channel and having a central channel communicating with the filter outlet pipe and a vibrating device rigidly attached to the filter element. spaced apart to form slit-like channels less than the thickness of the plates and communicating with the central channel, the outer edges of the plates being chamfered at an angle of less than 30 ° so as to form a conical surface of the filter elements 10 when assembled.

The plates may consist of flat plates with radial spacers interposed between them, or with truncated cone-shaped plates with radial projections on the inner surface.

15 The plates are preferably connected together by means of rods and a pressure plate mounted at the bottom of the filter element.

When the filter element is made of a plurality of plates joined together, a stronger structure is achieved than with screen or wire filter elements. This improves the reliability of the filter 20 without compromising the filtration conditions. Due to the simplicity of the structure, it is possible to disassemble the device quickly and efficiently for inspection and repair. In addition, the structure according to the invention ensures a very homogeneous homogenization of the fuel during its purification. The homogenization of the fuel 25 takes place in the filter according to the invention in two steps: - at the inlet of the filter element, - in the channels of the filter element.

The asphalt and resin compounds 4 (Figure 1) decompose into particles at the inlet of the 30 filter elements due to strong cavitation near the filter surface. When the cavitation bubbles disintegrate, the energy of the micro-explosion is always directed towards the heavy phase of the liquid, which causes the asphalt and resin particles to comminute. Cavitation 35 is caused here by rather large compression zones and negative pressure zones as the surface of the filter element oscillates, and such a phenomenon cannot occur near the screen surface due to its high permeability. The mechanical impurities and intact asphalt and resin components that enter the oscillating channel formed by the plates of the filter element are exposed to varying impact loads as they pass through the channel and are divided into small particles.

The invention will now be described in detail with reference to a self-cleaning filter for thick suspensions, in particular thick fuels, according to the invention, illustrated in the accompanying drawings, in which: Figure 1 is a schematic drawing showing fuel purification and homogenization; , with a vibrating device and plates consisting of flat plates, Fig. 3 shows the filter element of the self-cleaning filter shown in Fig. 2 seen from above a flat plate; 20, Fig. 4 is a sectional view taken along line IV-IV in Fig. 3, Fig. 5 shows a self-cleaning filter having plates of truncated cone-shaped plates, and Fig. 6 is a partial perspective view of the conical plate of the filter shown in Fig. 5.

According to the invention, in a self-cleaning filter comprising plates 1 (Fig. 1), the mechanical particles 2 fall down, while the asphalt and resin particles 3Q entering the slit-like channels 3 between the plates 1 are crushed by the vibration of the plates.

The self-cleaning filter for thick fuel comprises a hollow housing 5 (Fig. 2) with a connecting pipe 6 for supplying fuel, a connecting pipe 7 for removing the filtrate 35 and a pipe 8 for removing the sludge. A filter element 11 is mounted in the cavity 9 of the housing 6 73892 5, which is rigidly attached to the vibrating device 10 and the tip is mounted downwards and has a central channel 12 which communicates. to the filtrate outlet pipe 7. The filter element 11 5 comprises a number of plates 1, each of which has an opening 13 (Figs. 3, 4). The openings 13 of the discs 1 form a central channel 12 (Figures 2, 5). The plates 1 are mounted at a certain distance from each other so that slit-like channels 3 with a height of less than 10 plate thickness are formed between them and which communicate with the central channel 12.

The outer edges of the plates 1 (Figures 1-6) are chamfered at an angle of 30 ° or less and, when assembled, form a conical surface of the filter element.

Increasing the angle to more than 30 ° is inappropriate because it would not improve the quality of fuel cleaning and would result in lower strength of the filter element due to the large differences in the diameters of the top and bottom plates. It has been found that the angle ok is best:: the value is 19 °, although this value may be different in different applications depending on the density of the suspension to be cleaned. .

The plates 1 may be in the shape of a flat plate 14, as shown in Figures 2, 3 and 4, or in the shape of a truncated cone 15, as shown in Figures 5 and 6. To form the slit-like channels 3 (Figures 2 and 5), radial strips are formed. The spacers are placed between the plates. Alternatively, the surface of the plates may have radial projections 16, as shown in Figure 6.

The plates 1 are connected together by rods 17 (Figs. 2, 5) 30, which are connected in some suitable way at the top of the filter element 11 to the support plate 18 and at the bottom to the press plate 19. The support plate 18 has a cavity 20 which communicates with the central a passage 12 and openings 21 connecting the roll 20 to the assembly chamber 22 of the housing 5 for collecting clean fuel 35.

7 73892

The chamber 22 of the housing 5 communicates with the filtrate outlet pipe 7.

The support plate 18 is attached to the shaft 23 of the vibrating device 10 and the vibrating device can be of any known type 5 suitable for use in a self-cleaning filter.

The space 9 and the cavity 22 of the housing 5 are sealed at the mounting points of the shaft 23 and the support plate 18 by seals 24.

The filter element 11 is brought into place in the housing 5 by means of a tape 25 and a spring 26 which protrude into a recess in the pressure plate 19.

When using conical plates 15 (Fig. 5), it is recommended that the rods 17 be provided with vanes 27 which form support surfaces on the plate so that it is possible to clean the inner surfaces of the plates when treating deposition with very thick fuels with a large amount of mechanical impurities. The press plate 19 has a central opening 28: for collecting deposits in the cavity 29 of the housing 5, which is separated from the space 9 by a seal 30 and a sleeve which together. center the filter element in the housing 5. The cavity 29 has a connecting pipe 31 with a stopcock for removing sludge. The sludge is drained in such a way that the pressurized fuel * ·: forces the sludge out when the stopcock is opened.

The filter according to the invention operates in the following way.

The fuel is pumped through the filter so that a certain predetermined pressure is generated in the cavities 9, 22 of the housing 5. Fuel is discharged through an inlet - connection pipe 6 - into the interior 9 formed between the housing 5 30 and the filter element 11. At the same time, the vibrating device 10 generates vertical oscillations in the filter element 11 via the shaft 23 at a predetermined frequency and amplitude. The fuel moves from the circumference of the housing towards the filter element. Then it passes through the filter element -. · 35 through the slit-like channels 3 to the channel 12 and is led to the hollow 73892 through the slits 20 and 22 into the clean fuel connection pipe 7. The filtration takes place horizontally.

The vibration of the filter element 11 causes variable local expansion and pressure rise points in the fuel, leading to a cavitation phenomenon, strong turbulence and shear stresses, which contribute to the homogenization of the fuel. Those fuel particles that do not decompose in the cavitation zone become entrained in the fuel flow and come into contact with the vibrating edges of the filter element, causing the particles to decompose into smaller particles. Mechanical impurities larger in size than the gap between the edges of the plates of the filter element 11 are ejected downwards or away from the plates by the action of the vibration. They then re-enter the fuel stream and travel back to the filter element, from where they again receive a certain force pulse which throws them away. It is clear that the mechanical particles therefore gradually move downwards along the edges of the plates (the path shown approximately in Figure 1) and are ejected down into the lower cavity, from which they are removed by rinsing. Due to the continuous ejection of mechanical impurities into the surface of the filter element and also due to the strong cavitation near the wall which decomposes the resin substances at the edges of the plates 1, the surface of the filter element is continuously cleaned of deposits. At the same time, those particles and mechanical impurities that penetrate the slotted channels 3 between the plates move along the oscillating channel and are subjected to varying impact loads, which grind 3Q and distribute them so as to obtain finer fuel.

As a filter according to the invention, the loss of the combustible fraction of the fuel from the total stream is reduced by 0.5% compared to previously known filters due to the separation of mechanical impurities from combustible components and the formation of a slurry which is removed without loss of useful fuel components.

Il

Claims (4)

73892 A self-cleaning filter for thick suspensions, comprising a hollow housing (5) with connection-5 dots (6, 7, 8) for feeding the suspension, removing the filtrate and removing the sludge, a conical filter element (11) mounted the housing (5) with the tip pointing downwards and having a central channel (12) communicating with the filtrate outlet pipe (7) and a vibrating device (10) rigidly attached to the filter element (11), characterized in that the filter element (11) ) comprises a plurality of plates (1) having openings (13) forming a central channel (12), the plates (1) being mounted at a distance from each other so as to form slit-like channels (3) therebetween, whose height is less than the thickness of the plates (1) and which communicate with the central channel (12), the outer edges of the plates (1) being chamfered at an angle of less than ·. * * 30 so as to form a conical filter element (11) surface. : 20 Self-cleaning: ***: filter according to Claim 1, characterized in that the plates (1) consist of • flat plates (14) with radial spacers arranged between them. Self-cleaning filter 25 according to Claim 1, characterized in that the plates (1) consist of truncated cone-shaped plates (15) with radial projections (16) on the inner surface. Self-cleaning filter according to one of Claims 1 to 3, characterized in that the plates (1) are connected to one another by means of rods (17) and a pressure plate (19) mounted on the lower part of the filter element (11).