SU512776A1 - Vibrating filter for liquids - Google Patents

Description

one

: The invention relates to devices: for filtering, in particular, vibration filters used in the chemical, petroleum, chemical, food industry, it can also be applied in the Building Materials Industry, I A vibration filter for liquids is known, comprising a housing, equipped with a vibration; drive of its vertical movement; And a filter screen placed vertically in the housing on the drainage support. A disadvantage of the known filter is that, during long-term operation, the cells of the filtering mesh are clogged, especially fibrous, resinous and other contaminants, and the formation of sediment, which under the action of gravity does not move down to the discharge chutes, but is grouped on the surface of the mesh, As a result, the resistance of the filtering mesh increases dramatically, causing a deflection. This leads to a violation of the mode of vibration of the filtering mesh, and consequently, to a violation of the hydrodynamic process section. no suspension.

 The purpose of the invention is to increase the efficiency of regeneration. The goal is achieved by the fact that the filter is equipped with a regenerating device ohm, made in the form of 5 radial duct rotating on the cell shaft, divided into two compartments, the edges of which are facing the working surface of the grid. It is advisable to install a drainage support on the shaft, and its perforation should be made in the form of an Archimedes spiral.

 FIG. 1 shows the proposed filter, a longitudinal section; in fig. 2 shows an AA in FIG. one; in fig. 3 shows a section along BB in FIG. 2; in fig. 4 - section along

15 | B-B in FIG. 1: in FIG. 5 is a section along G ‑ Y in FIG. four.

 The vibration filter is a detachable housing consisting of two covers 1 and 2, which are attached:

20, a filter cavity, which is covered by a filtering screen 3, stretched in an annular tension device 4, divides the cavity into two chambers; chamber 5, formed by lid 1; and filtering mesh 3, filled

25 (through the nozzle 6 of the initial suspension, and the chamber 7i formed by the lid 2 and the same filter screen 3 when operated filled with a filtrate, which is discharged through the nozzle 8. 3 the chamber 5 on the cell shaft 9 is loosely floating on the key U n pressed to the filter a grid 3 with a coil spring 11, a regenerating device made in the form of a radial duct 12 divided into two compartments. The radial duct rests on the device 4i providing a predetermined working gap between the filter mesh and the working surface of this device The cell shaft 9 is made by a cell 13 for withdrawing the highly emitting suspension and a cell 14 for removing the contaminated filtrate going in the return flow to flush the mesh. The removal of the contaminated suspensions and the Filtrate from both cells is carried out by means of an annular coupling 15 and branch pipes 16 and 17. In the chamber 7, a drainage support for the filter screen is inserted, which includes a shaft 18, a support disc 19 to prevent the screen from bending and draining the filtrate with a system for draining the filtrate of channels 20 (see FIG. 5) and the support device system 21. The support device, while rotating, comes into contact with the grid 3, also has radial beats on the value of eccentricity e. The filter vibrates through the rod 22 driven by rotation of unbalanced masses or an eccentric vibrator. The entire filter is held elastically by a suspension, consisting of support pads 23 and 24, twisted springs 25 located around the perimeter of the vibration filter housing and a continuous powerful shell 26. A device for continuous grid regeneration represents a rim 27 connected to the hub 28 with needles 29, one of which is wide and has two slots L and o, milled to a certain depth, with the end planes of the walls of which form a gap with a working grid. The gap formed by the end of the shortened wall and the grid serves to create a high velocity of the flow of suspension along the grid, and the channel 30 to discharge this suspension along one of the wells of shaft 9 (see Fig. 1). Highly. small gaps formed by other ends of the walls and filtering mesh have a very large hydraulic resistance and serve to drain contaminated filtrate in reverse current through the slot, Channel 31 (see. Fig. 3) and one of the shaft cells 9 (see Fig. . one). The rims and the spokes, besides the wide one, are made so that they are at a significant distance from the grid, the rim being used to set the gaps on the surface of the working grid, the spindles for fixing the rim. The drainage support to prevent the mesh from bending and removing the filtrate consists of a disk 19 with stiffening ribs 32, on which a steel support 33 is mounted, and a shaft 18. The disk 19 with Archimedes spiral channels or through perforation contacts to grid and protects it from deflection. The shaft ekdentsentrstvents provides movement of the contact surface of the disk with a filtering mesh over its entire surface in the rez yggat friction. I Vifation filter works as follows. The suspension to be separated at a certain pressure in a continuous flow through the nozzle 6 enters the chamber 5, where during movement along the filter axis through the filter mesh 3 it is divided into a filtrate (or purified suspension) passing through the channels of the drainage support into the chamber 7, and sediment (or contamination) deposited on the surface of the filter mesh 3. Cleaning the filter mesh from sediment (or contamination) is due to the vibration of the filter mesh 3, washing the sediment (contamination) with a slurry flow through the gap and Application grid reverse flow of filtrate through tsel§. Vibration of the filtering mesh 3 or the entire body together with the suspension leads to the destruction of the structure of the suspension, and therefore to a sharp decrease in its effective viscosity, to a decrease in the resistance of the filtrate to movement through the filtering mesh and solid particles under the action of gravity and vibration. The latter contributes to the coagulation of solid particles and their more rapid aggregation or floating. In the presence of fibrous and other like contaminants in the suspension, the adhesion forces and mechanical adhesion in the interlacing areas of the filter screen or in the cells of this screen are firmly held on it. Over time, such accumulation of associations, not removed by the forces of gravity and vibration, increases and eventually completely clogs the grid, leading to a significant pressure drop on the filter grid, to its destruction. Additional cleaning of the filtering mesh from the contamination of this type is performed from the surface of the filtering mesh with a suspension flow through the air, caused by a significant pressure difference in chamber 5 i in channel 30. Channel pressure

30 atmospheric air is close to it and is controlled by a flow valve.

Washing the filter screen from sediment or contaminants wedged in its cells is carried out by intensive intensification of the filtrate in the opposite direction through filter mesh 3 and channels 30 and 31. The pressure in channel 31, as in channel 1 of DL, is low, it is pex lire. Such cleaning is carried out continuously as the device is turned for continuous regeneration of the filter mesh. In the event of a significant accumulation of sediment jperei, the developing device has the potential JHOCTb, compressing the spring 11, to move (along the axis of the cell shaft 91, the space between the device and filter mesh 3 conditions arise (an increase in the resistance of the filter screen) leading to a deflection of the filter network. Under these conditions, the deflection of the filter grid 3 is prevented continuously raschayuschims supporting ring 19 provided with channels for discharging filtrate 2O, support disk Rashen .uslovie provides continuous regeneration the entire surface of the filter mesh and the continuous removal of filtrate from the surface thereof.

By varying the pressure of the suspension in 5, the filtrate in chamber 17. And also in cells 13 and 14, by changing the speed of rotation of the device for continuous regeneration, the frequency and amplitude of oscillations can be controlled within the filtering mode in the proposed filter.

Claims (2)

1. A fluids filter for liquids, comprising a housing equipped with an internal vertical displacement and filtering mesh placed vertically in Kqpnyce and a drainage support, due to the fact that, with a chain for improving the efficiency of the regeneration of your filter, it It is equipped with a non-contoured reg device made in the form of a rotating radial cell vapa divided into two compartments of the duct, the edges of which are facing the working surface of the grid. 2. The filter according to claim 1, of which is that the drainage support is mounted on the shaft: And its perforation is made 9 in the form of an Archimedes spiral. 30 S-B S-r i t i Y ///// 7/7 /// A ///////////// i Fig.Z