SU1722571A1 - Dismembrator - Google Patents

Abstract

The invention relates to a device for grinding and improves the grinding efficiency and durability of equipment by eliminating the gravity and centrifugal separation of bulk material. The dismembrator contains a cylindrical body in which the disks are mounted. Each working element 5 of the movable disk is made in the form of a plate perforated with channels 14 having an asymmetrical pterygoid profile with a pointed tip 11 directed in the direction opposite to rotation, limited to a straight line 12 and convexly forming in the cavity of the housing 1, a direction from straight to convex and inclined towards the straight forming plate at an acute angle a in the direction of its direction of rotation. The lumpy material arriving with the liquid phase from the guiding apparatus 8 is previously destroyed by the working elements 5 and 6, then individual particles of the M material tend to descend under the force of gravity into the lower zone of the housing 1 and, simultaneously rotating, together with the liquid phase under the effect of centrifugal the forces Rc are concentrated in the peripheral part of the chamber 2 of the cylindrical body 1. When bending around the liquid phase with a lumpy material suspended in it, moving at speed V of the wing-shaped working element 5, above its convex generatrix 13 creates a discharge, an ejecting force effect, the G0 of which on the particles M of the lump material predominates over the aforementioned centrifugal-gravitational force effect and promotes the mass transfer of material particles from the peripheral zones of the chamber 2 into the zone of action of the working elements, which improves grinding efficiency and eliminates premature abrasive wear of the cylindrical wall of the dismembrator body. 2 h. p, f-ly, 2 ill. XI K K: oi xj

Description

The invention relates to devices for fine grinding of raw materials of lump materials for wet and dry methods in the flow of energy, namely to grinders with a combination of rotating and stationary working elements, and can find application in the building materials industry, construction industry, chemical and other sectors of the national economy real estate.

. A dismembrator is known, comprising a cylindrical body in which rotating and fixed disks with concentrically arranged rows of working elements, loading and unloading nozzles are installed.

The presence of a large number of grinding stationary elements with a developed braking surface eliminates the likelihood of dispersal of the lump material and its aftermath.

destruction, contributes to the gravitational and centrifugal separation of particles of material into the peripheral zones of the cylindrical body, intensive wear of the latter, which reduces the grinding efficiency and durability of the dismembrator.

The aim of the invention is to increase the grinding efficiency and durability of the dismembrator by eliminating peripheral gravity-centrifugal separation of the lump material.

The goal is achieved by the fact that in a dismembrator containing a cylindrical housing in which rotating and stationary disks with concentricly arranged rows of working elements, loading and unloading nozzles are installed, each working element of the moving disk is made in the form of a perforated plate, an asymmetrical pterygoid profile with a pointed with the apex directed in the direction opposite to the rotation, bounded by a rectilinear and convex forming, with the latter facing the body cavity, and the perforation is through channels tilted to the rectilinear forming plate at an acute angle towards its direction of rotation, and each channel in the plate is made with a flow section increasing in the direction from rectilinear to convex forming the profile of the plate.

FIG. 1 shows a dismembrator, a longitudinal section; in fig. 2, view A in FIG. 1 (with conventionally removed side case and graphic interpretation of power factors).

The dismembrator (Fig. 1) contains a cylindrical body 1, in the cavity of which — chamber 2 is installed movable rotating 3 and stationary 4 disks with concentrically arranged rows of working elements, respectively 5 and 6.

The fixed disk 4 is fixed on the inner wall of the housing 1, and the rotating 3 is mounted on the hub 7 of the tubular guide vane 8 mounted on the bearings 9 in the housing 1 and interacting with the drive 10. Each working element 5 (Fig. 2) of the movable disk 3 as a perforated plate, asymmetrical pterygoid profile, with a pointed tip 11. directed in the direction opposite to the rotation.

The profile of the plate of the working element 5 is bounded by a rectilinear 12 and a convex 13 forming into the cavity of the housing 1, and the perforation is made in the form of through channels 14 inclined to the rectilinear forming plate 12 at an acute angle a in the direction of its direction of rotation, and the flow section of each of channels increases in the direction from

straight line 12 to the convex 13 forming the profile of the plate. The housing 1 of the dismembrator is equipped with an axial loading 15 and a tangential discharge 16 nozzles.

0 Dismembrator works as follows.

The initial lumpy material, for example, coma lime suspended in the liquid phase — the energy carrier enters through 5 loading pipe 15 into the central part of chamber 2 of housing 1 and further along guideway 8 to the zone of location of stationary 6 and rotating with speed V of working elements 5. In this part

0, the lumpy material destroyed by them participates in a circular motion together with a liquid phase induced by the working elements 5 of the movable disk 3 from the drive 10. Under the action of the hydromaterial medium (mass) of the centrifugal force Rc, each M of the particle suspended in the liquid (or gas) of the lumpy material radially moves to the periphery of chamber 2 of housing 1, i.e., to its perimetric curvilinear wall, and under the force of gravity - its own weight G particle M tends to lower the vertical skontsentrirovats locally and at the bottom

5 zone camera. As is known from hydro and aerodynamics (Bernoulli equation), when an asymmetrical pterygoid is displaced in a liquid (gaseous) medium or is flowed past it, the pressure in the layers

0 environments, enveloping the convex surface of the body, are much smaller than in the layers of the environment, enveloping its linear surface.

It is also known that, as a result of the difference in the indicated pressures, there is a constant intense transverse mass transfer — transverse ejection of the medium. Moreover, as applied to the cylindrical body 1 of the dismembrator and the above-indicated arrangement of movable pterygoid working elements 5, transverse ejection is manifested from the periphery — the cylindrical wall of the chamber 2 to its center, i.e.

5 by the Bernoulli equation — from the peripheral zones with a high pressure of the medium (converging from the rectilinear surface 19 of the profile of element 5) to its more discharged central layers (enveloping the convex surface 13 of the working element 5).

Under the action of this mass transfer, each particle M of the lump material acts as an ejection si re, directed towards mass transfer, i.e. into the central part of chamber 2 and superior oppositely directed centrifugal RC and gravitational G force components.

In this case, the partially differentiated involvement of a liquid (or gas) medium with particles of M material suspended in it from the periphery of chamber 2 to its center is carried out through ejection channels 14 in the form of local mass flows, ensuring that particles are fed into the zone of action of working elements 5 and 6 and further grinding. In the said through channels 14 connecting the high pressure zone with the more rarefied zone, free movement of the material particles is provided, and their jamming is prevented by broadening the channels as the particles move.

The main involvement (transverse mass ejection) of material particles from the periphery of chamber 2 into the zone of action of the working elements will occur when the mass flux comes off the pointed ends 11 of the wing-shaped working elements 5, where, in addition to the indicated ejecting factor, the swirling effect is the vortex formation of the mass flux. When installing and installing the work elements 5 of the rotating disk 3 at a certain angle (attack), centrifugal-gravity separation of the material can be eliminated, involve the working elements 5 and 6 in the active zone of the chamber 2, and increase the grinding efficiency.

The specified artificial focusing of material particles in the area of the working elements contributes to the spontaneous shielding of the inner surface of the cylindrical wall of the housing 1.

the sliding contact of the fast-moving (rotating in the hydro-environment) lumpy material and abrasive particles, which eliminates the premature wear of the dismembrator body.

The implementation of rotating working elements of the pterygoid - asymmetric form can be implemented for the same purpose in the structures of disintegrators and other shredders of lump and clod material.

Claims (3)

1.Dismembrator containing cylindrical housing, in which are installed rotating and fixed discs with concentric rows of working elements, loading and unloading nozzles, characterized in that to improve the grinding efficiency and durability of the dismembrator by eliminating the peripheral gravity-centrifugal separation of lump material, each working element of the moving the disk is made in the form of a perforated plate, an asymmetrical pterygoid profile, with a pointed tip directed in the direction opposite to the rotation limited by a straight and convex generators, with the latter facing the body cavity. 2. The disc membrane according to claim 1, characterized in that the perforation is formed by through channels inclined towards the straight line forming plate at an acute angle in the direction of its rotational direction. 3. The dismembrator of claim 2, characterized in that each cocoa in the plate made with a flow section increasing in the direction from the straight to the convex forming profile of the plate.