RU1772058C - Hopper device - Google Patents

Abstract

Usage: the invention is intended for unloading from bunkers and volumetric dosed supply of bulk materials and can be used in many technological processes in the chemical and related industries. The inventive device for unloading bulk materials from hoppers contains a detachable housing 1 with a discharge opening 3 in the bottom, a pipe 4 connected to the specified hole 3, two sector rotors 11 and 12. mounted one above the other on the cylindrical part of the rotating divider 10. Sector rotors separated by a flat diaphragm 13 with a filling hole 14, which forms two chambers communicating with each other, and the cultivator is made in the form of rigidly mounted cantilever pins 15, which alternately enter into contact during rotation of the shaft with elastic elements 16 fixed on the housing wall, for example, flat springs. 1 s.p. f-ly, 2 ill.

Description

& ig. 1

The invention is intended for unloading and volumetric dosing of caking and bulk materials from silos and can be used in chemical and other industries related to the processing of bulk media.

A blade-type feeder is known for unloading bulk materials from hoppers, which holds blades fixed to the rim inside the estrus with the help of rotary axes, connected with the drive shaft mounted inside the rim.

However, the design of the feeder does not provide high operational efficiency since it does not exclude arbitrary outflow of material in case of rotation of the blades by a certain angle. In addition, it should be noted the complexity of the design of the drive mechanism of rotation of the blades.

A metering feeder for low bulk materials is also known, comprising a container with a discharge opening, inside which a metering sector rotor and a blade cultivator are located on a rotating shaft, and a sector visor with elastic elements is mounted above the discharge opening.

The disadvantages of said dispensing feeder include the following. The presence of a sector visor between the cultivator and the metering rotor does not exclude the possibility of bulk material flowing from the hopper into the discharge opening, and considerable drive power is required to rotate the blade cultivator and the metering sector rotor located in the bulk of the material.

The aim of the invention is to increase reliability.

This is achieved by the fact that the bunker device comprising a housing with a discharge opening located in the peripheral part of the bottom, and a shaft located in the housing and mounted on it one above the other, a cultivator and a section rotor rotor having identical sections, is equipped with an additional sectional rotor mounted on the shaft and located between the rotors of the separating diaphragm with a hole made on the side opposite to the discharge hole, the cultivator consists of cantilever brackets rationally mounted on the shaft yrey and fixed on the body of elastic elements, wherein the height of the upper rotor blades constitutes a height of 1.0 to 1.5 lower rotor blades and the area of the openings in the diaphragm area is 1.0-1.8 lower rotor section, and

rotor blades on the periphery are interconnected. The shape of the discharge opening of the hopper device may correspond to the shape of the rotor section.

Figure 1 shows the device; on the

FIG. 2 is a plan view from above.

The hopper device comprises a detachable housing 1 with a flat bottom 2, in which there is a discharge opening 3 and

a pipe 4 connected to it. A bearing assembly 5 is installed inside the housing 1, the shaft 7 is vertically placed in the rolling bearings 6 of the shaft 7. The shaft 7 is driven from the gear motor 8 through

V-belt transmission 9. A divider 10 is mounted on the upper end of the shaft 7, on the cylindrical detachable part of which two sector vane rotors 11 and 12 are located, one located on the other.

A flat diaphragm 13 is located between the rotors and forms two chambers communicating with a fill hole 14 in the diaphragm 13.

The cultivator is located above the rotors and

made in the form of cantilever radially directed pins 15 and elastic elements 16, for example, flat springs cantileverly mounted on the housing and entering into

interaction with pins 15.

The blades of the rotors 11 and 12 are interconnected by a shell 17.

The device operates as follows.

The device by the flange of the housing 1 is connected to the hopper (dotted in Fig. 1) in such a way that it is a continuation of the capacity of the hopper in the discharge zone of bulk material. During rotation

of the shaft 7 from the drive 8, the pins 15 alternately engage with the cantilever elastic elements 16 (only two pins and two elastic elements are shown by convention in FIGS. 1 and 2) and are deflected from the pins by force. When the pins 15 disengage from the elements 16, the latter, due to their elasticity, return to their original position. In this case, the arches are destroyed and the material acquires

mobile state over the entire cross section of the hopper discharge neck.

Loose bulk product in this way is captured by the blades of the sector rotor 11, moving it through the opening 14 of the diaphragm 13 into the sector cavities of the rotor 12, which feeds the cut-off portions of the granular medium to the discharge opening 3 and pipe 4 for further processing.

The height of the blades of the upper rotor is 1.0: 1.5 of the height of the blades of the lower rotor.

This range of blade height ratio depends on the physicomechanical properties of bulk materials. For good bulk products, lower blade heights should be taken, and for hard bulk materials, larger values should be taken. This can also explain the choice of the size of the aperture in the diaphragm, the area of which is 1.0-1.8 of the area of the lower rotor section.

Reducing the height of the blades of the upper rotor to less than 1.0 the height of the blades of the lower rotor will not ensure complete filling of the sections of the latter, and an increase of more than 1.5 to the height of the blades of the lower rotor will increase the drive power for rotation of the rotors.

Thus, the described construction of the hopper device allows for stable outflow of bulk materials, including those prone to caking, prevents arching in the hoppers and thereby increases the efficiency of the device. The stability of the outflow of granular medium is achieved by introducing into the device an additional sector rotor and cultivator of a new design, which excludes material formation in the hopper. In addition, this design of the device will ensure complete filling of the materials of the sectors of the lower rotor, which is important for volumetric dosing, due to the greater height of the blades of the upper rotor and the increase in the area of the hole in the diaphragm compared to the area of each sector of the lower rotor.

By connecting the rotor blades to each other along the periphery of the shell, the rigidity of the cantilever blades is achieved, and the presence of the cut-off volume of the rotor cell eliminates the friction of the material on the inner surface of the cylindrical generatrix of the device body.

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Claims (2)

1. A hopper device comprising a housing with a discharge opening located in the peripheral part of the bottom, a vertical shaft located in the housing, and mounted on it one below the other, a cultivator and a sectional rotor rotor having the same sections, characterized in that, in order to increase reliability in operation, it is equipped with an installed on the shaft with an additional sectional rotor rotor and a separation diaphragm located between the rotors with an opening made from the side opposite to the discharge opening, The cultivator consists of pins radially mounted on the shaft and mounted on the housing of elastic elements to interact with the pins, while the height of the blades of the upper rotor is 1.0-1.5 the height of the blades of the lower rotor, the area of the hole in the diaphragm is 1-1.8 of the section area of the lower rotor, and the rotor blades are peripherally interconnected. 2. The device according to claim 1. It is important that the shape of the discharge opening corresponds to the shape of the lower rotor section, and the areas of the discharge opening are equal to or larger than the areas of the rotor section. / 7 / J