SU1641393A1 - Rotor-type installation for suspension filtration - Google Patents

Abstract

The invention relates to the filtration of suspensions and can be used in the chemical and pharmaceutical, coal and food industries for filtering suspensions, among them difficult to filter, for example, the culture fluid of antibiotics. The purpose of the invention is to determine the productivity of the plant, reducing the moisture content of the sediment by increasing the working area of the filter. The filter rotor 3 is rotated through the rare OP-22 due to the energy of the drive device 23. Through the nozzle 25, located on the upper and lower covers 2, supply compressed air, which seals the installation. The suspension is fed through fitting 9. Under pressure from the blades 7, the phases are divided, the AIDKEI phase is forced through the filtering material 4 into the rotor 3 in section 5, this is withdrawn into the accumulator, and the solid phase remains on the filtering material 4 of the rotor 3 and then enters the bottom 15 sludge extraction, where, under the pressure of the membrane membrane 11, further dehydration occurs on the sludge, which, on leaving the squeezing zone, is cut off with a knife, blown off with air and dumped onto the conveyor belt. 1 з п.ф-л, 3 Il. СЬ «™ s SA

Description

The invention relates to x tmu-farmatsevticheskoy, coal, food industry, namely, installations for filtering suspensions, such as culture fluid of antibiotics.

The purpose of the invention is to increase the productivity of the plant and reduce the moisture content of the sediment by increasing the working area of the filter,

Figure 1 shows a rotary slurry filtering unit, vertical section; figure 2 - section a - a in figure 1; Fig. 3 is a flow chart of the operation of an apparatus for filtering slurries.

The rotor unit consists of a cylindrical body 1, the top and bottom of a closed filter with a cover 2, a filter rotor 3 equipped with filter material 4. The filter rotor 3 is mounted eccentrically relative to the body. The rotor 3 is divided into a series of sections 5 by radial impermeable partitions 6, inside which are placed the blades 7. The inner side of the blades 7 is fixed in the grooves 8 of the housing covers 1 and fits tightly to its inner surface. 3 and the rotational movement relative to the housing 1 of the installation, followed by the outline of the internal generators of the housing 1,

On the top cover 2 of the housing 1 there is a fitting 9 for feeding the outgoing components. The space between the rotor 3 and the housing 1 under the fitting 9 forms a slurry feed zone 10. Between the wall of the housing 1 and the filtering material 4 of the rotor 3, at the place of their lesser removal, there is a flexible impermeable membrane 11 for sludge pressing fixed on the body 1, which together with the rigid coaxial wall 12 forms a squeezing sludge device 13, where compressed air is fed through fitting 14 . The pressure of the compressed air is controlled by the gap between the membrane 11 and the filter material 4, referred to as sludge pressing zone 15, depending on the properties of the sludge and its predetermined final humidity.

Further along the rotation of the rotor 3, an elastic knife 16 is installed on the housing 1 to remove the dried sludge from the surface of the filter rotor 3. The filter rotor 3 shaft 17 is equipped with a distribution washer 18 with a nozzle 19 for draining the filtrate during filtration and a fitting 20

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and compressed air for the regeneration of the filtering surface successively to each section 5 through individual channels 21 inside the shaft 17 during the rotation of the rotor 3, which is carried out through the gearbox 22 due to the energy of the drive device 23. The tightness of the installation is provided by a pair of sealing rings 24 and supporting air supplied through fittings 25 in the upper and lower covers 2 of the housing 1. The housing 1, the driving device 23 and the conveyor 26 are mounted on the frame 27.

The installation works as follows.

The filter rotor 3 is driven through the gearbox 22 by the energy of the drive device FROM. Through fittings 25. located on the upper and lower cores 2, compressed air is supplied to the region between the covers 2 of the housing 1 and the rotor 3, as well as the sealing rings, which creates a counter-pressure that seals the installation and prevents the lubricant of the bearings from entering the i-zone. 28 and gays are the most observant. The sterility of the suspension being filtered is guaranteed. The suspension is fed and the installation -fa. O-axis through the nozzle 9 into the zone 10 of the suspension. When the rotor 3 rotates, the initial suspension under the pressure of the blades 7 in the closed space of the slurry dewatering zone 29 is divided into phases, the liquid phase is forced through the rotating material 4 into the rotor 3 in section 5, from where through the individual channels 21 into va /, 8 17, distribution the washer g 8 and the nozzle 19 are withdrawn into the accumulator, and the solid phase remains on the filter material 4 of the rotor 3, and then enters the sediment extraction zone 15, where the sludge dehydrates further under the pressure of the flexible membrane 11. At the same time, the filtrate passes through the filter material 4 into the inside of the rotor 3, and the sediment of the required humidity PS out of the pressing zone 15 is cut off with a knife 16, blown off with air and dumped onto the conveyor 26. The pressure in the pressing zone 15 depends on the gap between the housing 1 and the rotor filter material 4 3 and is regulated by the dry air fed under the membrane 11 through the nozzle 14, as well as by the speed of rotation of the rotor 3, which is established by the driving device 23, based on the properties of the sludge and its predetermined final humidity. to conduct a filtration of various suspensions, including trudnofiltruemyh.

Next is the restoration of the filter material 4 in the corresponding zone 30 purge compressed air entering through the nozzle 20, the channels 21 and the distribution washer 18 of the shaft 17, and preparing it for subsequent filtration. Thus, the regeneration zone 31 is only 1/3, and the work area of the filtration zone 28 is 2/3 of the operating cycle of the device, which increases its productivity,

The proposed design of a rotary type filtering installation allows filtration of various suspensions, including difficult-to-filtering, to reduce the moisture content of the sediment, which greatly reduces the economic costs of obtaining the finished product.

Claims (2)

Claim 1. Rotary filtering apparatus for suspensions consisting of a cylindrical body, top and bottom with a capped filter rotor mounted eccentrically inside the body, divided into a series of impermeable sectors five 0 five Webs, inside which are placed the blades, tight to the inner wall of the housing and installed with the possibility of reciprocating movement, characterized in that, in order to increase productivity and reduce the moisture content of the sludge by increasing the filtration area, it is equipped with a flexible impermeable membrane for pressing sediment, with a knife for removing dried sediment mounted on the housing, and the filter rotor hall is equipped with a distribution washer with filtrate drainage pipes and compressed inlet of air and adapted to the filtrate discharge channels and supply of compressed air, wherein a flexible impermeable membrane is disposed between the housing and the filter Stechkov rotor surface at the point of smallest removal and rigidly fixed to the body. 2. Installation according to claim 1, characterized in that sealing rings are located between the covers of the housing and the filter rotor, and fittings for supplying compressed air are installed on the covers of the housing. FIG. 2 Zone Overee Suspension Suspension-29 LodasMuspension- to Filtration zone-28 Zonolrodubm air-30 Sediment deposited-32 Spin zone osodkho-15 Fig.Z Regeneration Zone-Sf