RU2237000C2 - Charging device for uniformly filling vertical containers with loose material - Google Patents

Abstract

FIELD: industry, construction, agriculture.

SUBSTANCE: invention relates to devices for charging hoppers or silos. Proposed charging device contains hollow deflecting truncated cone widening downwards and provided with central charging hole in upper smaller base over which discharge end of feed conveyor is located, spreading disk installed for rotation inside deflecting cone under charging hole and rigidly secured on lower end of vertical shaft installed on axle of deflecting cone for reciprocation in vertical at rotation. Shaft rotation drive is located outside deflection cone and is provided with device for reciprocation in vertical when shaft rotates and it is mechanically connected with upper part of shaft. Deflecting cone is made sectional in height, being assembled of interconnected rings of different size diameters increasing in downward direction. Diameter of hole of each underlying ring exceeds outer diameter of higher adjacent ring. Inner surface of deflecting cone is formed by connecting edge of hole of each underlying ring with outer edge of higher adjacent ring through surface of rotation around axis of deflecting cone by smoothly curved line pointed with concavity inside deflecting cone. Invention provides uniform filling of vertical containers with loose material, simplified design, reduced labor input at manufacture, increased overhaul period.

EFFECT: improved convenience in operation, and repairability of charging device.

4 cl, 2 dwg

Description

The invention relates to devices designed to load bulk materials into vertical containers, for example bins or silos, and can be used in various industries, construction and agriculture.

A loading device is known for uniformly filling with bulk material vertically standing containers, preferably of circular cross-section, comprising a feed conveyor, a loading funnel, a vertical shaft, a drive kinematically connected to a drive located above the loading funnel, rigidly mounted on the lower end of the shaft, centrifugal ring plates coaxially located along the shaft with intervals between them in height and made with outer diameters and diameters of their central holes, increasing yuschimisya in a direction away from the disk to the hopper, and supports, rigidly connecting the adjacent annular plates and the bottom of which have a disk which is formed with a diameter smaller than the outer diameter dish at [1].

The above-known known boot device, quite simple in design, simple to manufacture and reliable in operation, however, has drawbacks which consist in its low efficiency due to the low uniformity of filling of vertically standing containers with bulk material due to the fact that when the shaft rotates bulk material due to the action of centrifugal forces descends from the annular plates and disk by separate annular flows, and not by a continuous rain stream over the entire cross section vertically toyaschey capacity; as well as its low universality for bulk materials with different masses of particles or grains, which leads to the need to change the distances between the centrifugal ring plates and the lower one and the disk and change the number of named plates when moving to loading bulk material with a different mass of particles or grains, those. to the need for dismantling, disassembling and subsequent assembly of the boot device with the mentioned design changes. The closest in technical essence to the analogue of the invention is a loading device for uniformly filling with bulk material vertically standing containers, mainly of circular cross section, containing a hollow reflective truncated cone, expanding downward and having a central loading hole in the upper smaller base, a vertical shaft kinematically connected to the drive its rotation, the spreading disk mounted rotatably inside the reflective cone under a loading hole, and a feed conveyor, the discharge end of which is located above the loading hole of the reflective cone [2].

In addition to the above-mentioned features common with the invention, in this known loading device, the spreading disc is mounted to rotate around a vertical axis and to adjust its vertical position on this axis, which is located along the geometric axis of the reflective cone, and the vertical shaft is mounted under the spreading disc concentrically to its rotation axis , the lower end is kinematically connected with the rotation drive and has a friction rotary roller interacting with the lower hour at the upper end thw flange made around the perimeter of the spreading disc.

When the spreading disc of this known loading device rotates with the upper part of the flange protruding upward above the surface of the disk along its perimeter, the loaded bulk material is directed onto the inner surface of the reflective cone and, hitting it and partially rolling along it, falls in the form of a continuous rain stream along the entire transverse section of a vertically standing container.

The disadvantages of the aforementioned closest analogue are the low efficiency of the known loading device due to the uneven distribution of bulk material over the cross-sectional area of a vertically standing container in the aforementioned rain stream, due to the fact that when the spreading disc rotates with the upper part of its flange, the bulk material is sent to one sufficiently a narrow annular zone on the inner surface of the reflective cone, resulting in a rain stream under this zone the content of bulk material exceeds its content in other parts of the rain stream; as well as the complexity of the design and manufacturing difficulties, inconvenience of operation and low maintainability of the known loading device, due to the fact that the vertical shaft and its rotation drive are located in an inaccessible place under the spreading disk, which, in addition, is characterized by increased dust content, i.e. It is dust-hazardous for the drive and its structural elements, subjected in this case to increased abrasive action and wear.

The objective of the present invention is to increase the efficiency of the boot device by increasing the uniformity of filling upright containers with bulk material, as well as reducing the complexity of manufacturing the boot device, increasing its ease of use, increasing the maintenance-free life and increasing maintainability by simplifying the design of the boot device and the removal of the drive and its structural elements beyond hard-to-reach and wear-hazardous areas of the device.

The solution to this problem is achieved by the fact that in the loading device for uniformly filling with bulk material vertically standing containers, mainly of circular cross section, containing a hollow reflective truncated cone expanding downward and having a central loading hole in the upper smaller base, a vertical shaft kinematically connected with its drive of rotation, a spreading disc mounted rotatably inside a reflective cone under the loading hole, and a feeding tray an exporter, the discharge end of which is located above the loading hole of the reflective cone, according to the invention, the spreading disk is rigidly fixed to the lower end of the shaft, which is mounted along the axis of the reflective cone with the possibility of reciprocating movement vertically during rotation, passed through the loading hole of the reflective cone and is made with a length providing the location outside the reflective cone of the upper part of the shaft during its reciprocating movement vertically, and the drive The shaft of the shaft is located outside the reflective cone, equipped with a device for simultaneous vertical rotation of the reciprocating movement of the latter and kinematically connected with the upper part of the shaft, in addition, the reflective cone in height of the vertical movement of the spreading disc mounted on the lower end of the shaft is made of interconnected rings of different diameters increasing downward, and the diameter of the hole of each lower ring is made large of an external diameter with an upstream annular ring, wherein the inner surface of the reflective cone is formed by connecting the edge of the hole of each inferior ring with the outer edge of the adjacent upstream ring by a surface of rotation around the axis of the reflective cone of a smoothly curved line curved inwardly into the reflective cone.

In the predominant case of the design of the loading device, the surfaces connecting the edges of the holes of each lower ring of the reflective cone with the outer edge of the adjacent upper ring are the inner surfaces of the ball belts of different diameters increasing downward.

In a preferred case, the design of the boot device, the drive is configured to control the speed of rotation of the shaft.

In the most preferred case of the structural design of the boot device, the device for simultaneously rotating the shaft of the reciprocating movement of the latter vertically is configured to control the speed and / or frequency of the reciprocating movement of the shaft vertically.

The invention is illustrated by drawings, where Fig. 1 shows a loading device for uniformly filling vertically standing containers with bulk material, a longitudinal vertical section; figure 2 - node a in figure 1.

A loading device for uniformly filling vertical containers with predominantly circular cross-section with bulk material, contains a hollow reflective truncated cone 1 expanding downward and having a central loading hole 2 in the upper smaller base, a vertical shaft 3 kinematically connected to the drive (not shown in the drawings) its rotation, the spreading disk 4, mounted for rotation inside the reflective cone 1 under the loading hole 3, and the feeding conveyor 5, unloading to Heff, which is located above the loading opening 2 deflector cone 1.

The spreading disc 4 is rigidly mounted on the lower end of the shaft 3. The shaft 3 is mounted along the axis of the reflective cone 1 and is made with a length that ensures that the upper part of the shaft 3 is positioned outside the reflective cone 1 when it is reciprocating vertically. The drive (not shown in the drawings) of the rotation of the shaft 3 is placed outside the reflective cone 1, is equipped with a device (not shown in the drawings) for simultaneous vertical rotation of the shaft 3 of the reciprocating movement and kinematically connected with the upper part of the shaft 3.

The reflecting cone 1 along the height of the vertical movement of the spreading disc 4, mounted on the lower end of the shaft 3, is made up of interconnected rings 6 of different diameters increasing downward, and the diameter of the hole 7 of each lower ring 6 is made larger than the outer diameter of the adjacent upstream ring 6. Inner the surface of the reflective cone 1 is formed by connecting the edge of the hole 7 of each downstream ring 6 with the outer edge of the adjacent upstream ring 6 on top awn 8 rotating around an axis 1, the deflector cone smoothly curved line curve concavity facing inwards deflector cone 1.

In the predominant case of the design of the boot device, the surfaces 8 connecting the edges of the holes 7 of each lower ring 6 of the reflective cone 1 with the outer edge of the adjacent upper ring 6 are the inner surfaces of the ball belts of different diameters increasing downward.

In a preferred case, the design of the boot device, the drive is configured to control the speed of rotation of the shaft 3.

In the most preferred case of the design of the loading device, the device for simultaneously rotating the shaft 3 of the reciprocating movement of the latter vertically is configured to control the speed and / or frequency of the reciprocating movement of the shaft 3 vertically.

This boot device can be made stationary or portable. In a stationary embodiment of the loading device, the reflective cone 1 is mounted in the upper part of the vertically standing container 9 of circular cross section so that it becomes a continuation of the cylindrical part of the container 9 (see figure 1). In the portable embodiment of the loading device, before loading with the bulk material a vertically standing container 9, which in this case may not be of circular cross section, a reflective cone is mounted on top of the container 9 or inside its upper part.

A loading device for uniformly filling with bulk material vertically standing containers, mainly of circular cross section, works as follows.

Given the type and properties of bulk material loaded into a vertically standing container 9, determine the necessary speed of rotation of the shaft 3 and the speed and / or frequency of the reciprocating movement of the shaft 3 vertically, then adjust to these specific parameters and include a drive rotation of the shaft 3 with the device for simultaneous vertical rotation of the shaft 3, and then the feed conveyor 5 is driven. To eliminate the possibility of spillage of the feed conveyor 5 into gruzochnoe opening 2 of particulate material described device may be additionally equipped with a suitable means such as a pitched board, the guide chute, hopper or loading arm which is installed between the inlet opening 2 and the unloading end of the feed conveyor 5.

The bulk material supplied by the conveyor 5 passes through the loading hole 2 and enters the spreading disk 4. The rotating disk 4 scatters the bulk material coming to it through the circumference by directing centrifugal forces, directing the latter to the reflective cone 1, which dampens the speed of movement of the bulk material and, thanks to of its design, directs bulk material down. In this case, the particles of bulk material slide along the lower surfaces of the rings 6 of the reflective cone 1 and along the surfaces of rotation 8 connecting the rings 6 around the axis of the reflective cone 1 of smoothly curved curved lines facing concavity into the reflective cone without adhesion and adhesion to these surfaces. Due to the reciprocating movement of the shaft 3 during its rotation, the spreading disk 4, mounted on the lower end of the shaft 3, alternately directs the flow of bulk material to the narrow and wide parts of the reflective cone 1, as a result of which the downward flow of bulk material has the form of alternating concentric diverging and convergent rings. This ensures a uniform distribution of the loaded bulk material over the cross-sectional area of a vertically standing tank 9, which can have any height. Such loading may be carried out by bulk materials, particles or grains of which are not subject to deformation or small damage due to impacts on the disk 4 and reflective cone 1 or are not afraid of such deformation or destruction.

When switching to the loading of other bulk material, the particles or grains of which have a different mass, or if necessary additional tincture, adjustments can easily be made to the operation of the loading device by adjusting part or all of its variable parameters: shaft rotation speed 3, speed and / or frequency simultaneous with the rotation of the reciprocating movement of the shaft 3 vertically.

This loading device expands the arsenal of technical equipment designed for uniform filling of vertically standing containers with bulk material, is simple in design and manufacturing, reliable and easy to use, universal for various types of bulk materials and highly efficient in operation due to the uniform distribution of bulk material across the transverse section of a vertically standing container. In addition, due to the location of the drive and its structural elements outside the inaccessible and wear-hazardous areas of this loading device, the latter has a fairly long maintenance-free life and high maintainability.

Sources of information

1. Application of Germany 2703329, IPC B 65 G 65/32, 09/11/1980.

2. US patent 3698574, IPC B 65 G 65/32, 10/17/1972.

Claims (4)

1. A loading device for uniformly filling with bulk material vertically standing containers of predominantly circular cross-section, containing a hollow reflective truncated cone expanding downward and having in the upper, smaller base a central loading hole, a vertical shaft kinematically connected to the drive of its rotation, spreading a disk, mounted rotatably inside the reflective cone under the feed opening, and a feed conveyor, the discharge end of which is located on d loading hole of the reflective cone, characterized in that the spreading disk is rigidly mounted on the lower end of the shaft, which is mounted on the axis of the reflective cone with the possibility of reciprocating movement vertically during rotation, passed through the loading hole of the reflective cone and made with a length that provides an location outside the reflective cone of the upper part of the shaft when it is reciprocating vertically, and the shaft rotation drive is located outside the reflective cone CA is equipped with a device for simultaneous vertical rotation of the shaft of the reciprocating shaft and kinematically connected with the upper part of the shaft, in addition, the reflective cone in height of the vertical movement of the spreading disc mounted on the lower end of the shaft is made up of various interconnected rings increasing diameter, and the diameter of the hole of each downstream ring is made larger than the outer diameter of the adjacent upstream ring, while inside the surface of the reflective cone is formed by connecting the edge of the hole of each downstream ring with the outer edge of the adjacent upstream ring by a surface of revolution around the axis of the reflective cone of a smoothly curved curve line facing concavity inward of the reflective cone. 2. The boot device according to claim 1, characterized in that the surfaces connecting the holes of each lower ring of the reflective cone with the outer edge of the adjacent upper ring are the inner surfaces of the ball belts of different diameters increasing downward. 3. The boot device according to claim 1 or 2, characterized in that the drive is configured to control the speed of rotation of the shaft. 4. The boot device according to claim 1, or 2, or 3, characterized in that the device for simultaneously with the rotation of the shaft of the reciprocating movement of the latter vertically is configured to control the speed and / or frequency of the reciprocating movement of the shaft vertically.

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