RU2659433C2 - Disintegrating device - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: disintegrating device includes a hopper, a working chamber with an elastic bottom on the base, an elastic plate membrane made with a set of elastic plates and installed in an elastically compressed state with detented fixation in the middle part of the drive pivoting shaft. The butt ends of the plates are fixed in pivoting shafts with adjustable wedge fixation. The pivoting shaft of the butt plate fastening is equipped with adjustment in the plane of the base. The working chamber with an elastic bottom is connected to the base by means of a set of spring connections spaced along the outer perimeter of the working chamber and installed at an angle to the base. The loading hopper is equipped with a grizzley, and along the perimeter of the hopper there is a sprinkler pipe with a cross-over tube. The base of the disintegrating device in the area of the loading hopper is equipped with a mechanism for adjusting the angle of the disintegration device inclination to the horizontal plane. The working chamber at the unloading side is equipped with a rotatable retaining tray.

EFFECT: increased efficiency of washing, increased structural reliability of the plate membrane.

6 cl, 4 dwg

Description

The invention relates to the field of ore preparation and mineral processing, in particular, to technical means for washing clay materials and can also be used to obtain homogeneous mixtures in the chemical, construction and other industries.

A device for washing minerals, including a working chamber equipped with emitters of the membrane type (see AC No. 1344416, class B03B 5/02, 1985).

A closer analogue in technical essence is a flushing device that includes a working chamber with membranes in the form of elastic plates (see RF Patent No. 2173581, B03B 5/02, 2001).

The disadvantages of these devices are the low reliability of the plate membrane and the insufficiently high disintegration efficiency of high clay material.

The aim of the invention is to increase the structural reliability of the plate membrane and the washing efficiency.

This goal is achieved by the fact that the end ends of the plates are fixed in the rotary shafts with adjustable wedge fixation. The plate membrane is made of a set of elastic plates installed in an elastically compressed state with the end ends fixed in the rotary shafts, and the middle part of the membrane is fixed to the rotary drive shaft. Such fastening of the middle part of the plates on the rotary shaft allows the plates to be transferred from one stable state to another by turning the shaft alternately in one and the other. The elastic properties of the plates determine the high rate of transition of the plates from one stable state to another after passing through the plates in the middle position. Each transition is accompanied by a sharp “snapping” of the plates. The “snap” speed is sufficient to excite the wave process in the pulp. The end fastening of the elastic plates in the rotary shaft will allow the plates to rotate together with the shaft during bending during the transition of the plates from one stable state to another without bending at the attachment point. Adjustable wedge fixation of the ends of the plates will provide a reliable and at the same time detachable connection of the plates on the rotary shaft. The ability to adjust each plate when it is mounted on a rotary shaft will allow for precise adjustment of the plane of the entire membrane, which will cause an even load across all membrane plates, and this will increase the service life of the entire structure.

The rotary shaft of the end plate mounting is equipped with adjustment in the plane of the base. Additionally, for fine adjustment of the membrane plane, screw adjustment of the entire rotary shaft of the end fastening of the membrane plates is used. The duration of operation of the membrane under harsh “snapping” conditions during the transition from one stable state to another substantially depends on the high accuracy of the flatness state of all the plates in the membrane. This is carried out by screw adjustment at the attachment point of the rotary shaft.

The working chamber with an elastic bottom is connected to the base by means of a set of spring connections spaced along the outer perimeter of the working chamber and installed at an angle to the base frame. The spring connection of the working chamber with the base of the disintegration device reduces the vibration load on the base and increases the efficiency of disintegration by supplementing the vibration load in the working chamber through its body. The installation of spring joints at an angle to the base allows the material to be advanced inside the working chamber by means of directed vibrational vibrations of the entire working chamber in the discharge direction.

The loading hopper is equipped with a grate screen, and an irrigation pipe with a connecting pipe is placed around the perimeter of the hopper. Grate rumble eliminates the ingress of oversized pieces into the working chamber. The sprinkler located around the perimeter of the hopper provides a regulated supply of water to the working chamber, which allows the unit to operate autonomously, not as part of the technological circuit of the apparatus.

The base of the disintegration device in the area of the loading hopper is equipped with a mechanism for adjusting the angle of inclination of the disintegration device to the horizontal plane.

The working chamber on the discharge side is equipped with a rotary retaining tray. The use of the retaining tray allows you to adjust the load level of the working chamber to achieve optimal operating parameters of the disintegration device.

In FIG. 1 shows a disintegration device, general view; in FIG. 2 - shows a membrane from a set of elastic plates; in FIG. 3 - shows the end fastening of the plates on the rotary shaft; in FIG. 4 - shows the rotary shaft for fastening the end ends of the plates, where 1 is the feed hopper, 2 is the working chamber, 3 is the grate, 4 is the sprinkler, 5 is the spring mount, 6 is the base frame, 7 is the plate membrane, 8 is the rotary drive shaft , 9 - wedge mount, 10 - rotary shaft of the mechanical fastening of the plates, 11 - rotary retaining unloading tray, 12 - adjusting screw for the angle of inclination.

We will consider the operation of the device using an example of a specific design.

The material intended for processing in the disintegration device enters the feed hopper 1 into the working chamber 2 through the grate screen 3. Water is supplied through the sprinkler 4 located along the perimeter of the feed hopper 1 to the working chamber 2. The working chamber 2 with spring mounts 5 is mounted on the base frame 6. On the base frame 6, under the elastic bottom of the working chamber 2, a plate membrane 7 is assembled from spring steel plates on a drive rotary shaft 8 with a plate torus mount by a wedge mount 9 on the rotary end plate mounting shaft . The lamellar membrane 7 mounted on the base frame 6 under the working chamber 2 emits vibrations inside the working chamber 2 by deflection of the lamellar membrane 7, which is accompanied by a sharp “snap” with each rotation of the drive rotary shaft 8. When “clicked”, the middle part of the plate membrane 7 in the place of the maximum amplitude of the oscillation has a high velocity of transverse motion, sufficient for the formation of shock waves. Since the plate membrane 7 is connected to the elastic bottom of the working chamber 2, sharp (shock) vibrations are transmitted to the volume of the working chamber 2 and spread to the pulp. The passage of shock waves through the pulp in the working chamber leads to the appearance of a number of secondary effects in the pulp, including local shock waves and cavitation, which have high destructive actions. Under the influence of these effects, an intense breaking of bonds (disintegration) between individual particles in clay aggregates occurs. Disintegrated material from the working chamber 2 is discharged through the rotary retaining unloading chute 11. The processing time of the material in the working chamber 2 is controlled by the filling level of the working chamber by means of the position of the rotary supporting unloading chute 11 and the angle of inclination of the installation to the horizontal by means of an adjusting screw of the angle of inclination 12.

Claims (6)

1. Disintegration device, comprising a loading hopper, a working chamber with an elastic bottom on the base, an elastic plate membrane made of a set of elastic plates and installed in an elastic-compressed state with fixed fixing in the middle part on the rotary drive shaft, characterized in that the end ends of the plates fixed in rotary shafts with adjustable wedge fixation. 2. The device according to p. 1, characterized in that the rotary shaft of the end fastening of the plates is equipped with adjustment in the plane of the base. 3. The device according to p. 1, characterized in that the working chamber with an elastic bottom is connected to the base by means of a set of spring connections spaced along the outer perimeter of the working chamber and installed at an angle to the base. 4. The device according to claim 1, characterized in that the feed hopper is equipped with a grate screen, and an irrigation pipe with a connecting pipe is placed around the perimeter of the hopper. 5. The device according to p. 1, characterized in that the base of the disintegration device in the area of the loading hopper is equipped with a mechanism for adjusting the angle of inclination of the disintegration device to the horizontal plane. 6. The device according to p. 1, characterized in that the working chamber on the discharge side is equipped with a rotary retaining tray.

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