RU2438799C2 - Device to classify solid materials to sizes - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to separation and classification of solid loose or lumpy materials to sizes. It may be used in various industries, in particular, for grading diamonds and crystals to sizes. Proposed device comprises round vibrating bin wherein initial material is fed via spiral chute into bin top section. Further, initial material fractions follow each other in ring-shaped chute arranged on bin outer wall to be discharged therefrom. Ring-shaped chute bottom is inclined toward bin sidewall and tapered along material path for sorting purposes. Intake containers are arranged behind said ring-shaped chute to receives classified fractions.

EFFECT: higher efficiency, simplified design.

4 dwg

Description

The invention relates to the field of sorting and separation of solid bulk or lump materials, as well as various parts and blanks in size. The inventive device for sorting solid materials by size contains a circular vibratory hopper in which the end of the spiral tray in the upper part of the hopper is joined to the beginning of the annular tray, horizontally placed on the outer wall of the hopper, consisting of one side wall (hopper wall) and the bottom made obliquely to the side wall and tapering to the end of the tray, under which there are receiving containers for sorted fractions.

The device is designed for sorting and separation of solid bulk or lump materials, as well as parts and blanks by size and can be used in various industries, including agriculture, and, in particular, for the separation of crystals and diamonds by size.

Both in mechanical engineering and in other industries, various designs of devices are used to sort parts and blanks, as well as to separate, calibrate and classify solid bulk or lump materials by size. Moreover, in most known devices, the sorting of the source material, i.e. fractions of various sizes are selected by successive sieving through gratings (sieves) having openings (cells) of a certain size.

The closest analogue to the proposed device is a bunker vibratory orientator-sorter (see Shapran V.Z. Automatic feeders for wrapping machines (Fundamentals of theory, calculation and design). Kiev: Technika, 1969, p. 239), which by combination of characteristics and purpose adopted as a prototype. This device contains a bowl (round vibro-hopper) with a spiral tray and ring-shaped storage trays horizontally placed on the outer wall of the bowl. On the side wall of the bowl along the spiral tray there are outlet openings corresponding to the shape and size of the items to be sorted and the number of which is equal to the number of types of items loaded into the bowl. On the outside of the bowl for each size of products have their own ring-shaped storage trays. Sorting of products in this device occurs, as in many known devices, by passing products through specific openings and then placing them on the corresponding ring-shaped storage trays.

A disadvantage of the known device is that it can not work reliably when sorting bulk and lump materials, consisting of fractions of an indefinite shape. This is due to the fact that individual fragments of the sorted materials will inevitably jam and get stuck in the outlet openings of the bowl before they exit to the storage tray.

The aim of the present invention is to increase the reliability of the device and simplify its design when sorting it according to the size of bulk and lumpy materials.

The technical essence of the invention lies in the fact that the annular tray is made with an inclined bottom towards the side wall of the hopper and tapering in the direction of movement of the material to ensure its sorting, and receiving containers are located under it, into which the sorted fractions are unloaded.

Figure 1 shows a structural diagram of the proposed device. The device consists of a circular vibratory hopper, in which the end of the spiral tray 1 in the upper part of the hopper 2 is joined with the beginning of a horizontally arranged annular tray 3 attached to the outer wall of the hopper 2 through a slot (hole) 4. Tray 3 consists of one side wall, which serves the outer wall of the hopper itself, and the bottom, made obliquely to the side wall and tapering to the end of the tray. Slot 4 connects the end of the spiral tray 1 with the widest part of the bottom of the tray 3. Along the outer surface of the wall of the hopper 2, a set of containers 5 is installed under the tray 3, which are used to receive sorted fractions of various sizes.

The original solid material in the form of placers or pieces of various sizes, loaded into the hopper 2, is fed through a spiral tray 1 to the upper part of the hopper 2. Through the slot 4, the source material is sent to the widest part of the bottom of the annular tray 3 and then moves along it in one row and faster due to its horizontal position. With further movement of the source material in the tray 3, fractions of different sizes will fall from it into the corresponding containers 5 in accordance with the width of the bottom of the tray 3. Thus, the entire batch of the source material loaded into the vibro-hopper will be sorted by size in one go.

Their figure 1 shows that the proposed device is simple in design and, as shown by tests of its current layout, reliable in operation.

Figure 2, 3 and 4 presents photographs of the current layout of the proposed device, which clearly shows the result of his work on examples of sorting salt crystals (figure 2), sorting parts (figure 3) and separation of buckwheat and millet grains (figure 4 )

Claims (1)

A device for sorting solid materials by size, containing a round vibratory hopper, in which the source material is fed through a spiral tray to the top of the hopper, then its fractions are moved one after another along the annular tray located on the outer wall of the hopper, and unloaded from the hopper, characterized in that the bottom of the annular tray is made inclined towards the side wall of the hopper and tapering in the direction of movement of the material to ensure its sorting, and under the annular tray there are receiving e container in which and unloaded sorted fraction.

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