CZ303233B6 - Exhaust system - Google Patents

Abstract

The present invention provides an exhaust system intended for separation of weight-different fractions of a mixture of bulk material from each other, wherein the designed exhaust system comprised an overfall discharge (3), which is arranged between a supply mechanism (1) and a discharge conveyor (2). A suction nozzle (4) connected with a suction portion (51) of a ventilator (5) is disposed above the overfall (3). The ventilator (5) discharge portion (52) is connected with an air separator (6) wherein a collecting chamber (7) is arranged therebelow.

Description

The invention relates to a suction device for separating the different fractions of a bulk material mixture from one another, in particular for separating dust, straw light impurities and impurities from cereal grains.

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BACKGROUND OF THE INVENTION

It is known that devices of various types are used to purify cereal grains from impurities.

One type is a mechanical principle device which comprises a sieve, resiliently mounted on a frame and brought into working motion by a source of vibration, preferably by a vibration electric motor. A blow or suction device is attached to the screen to separate a lighter fraction than that which remains on the screen or falls under the screen. Devices of this type are too massive, which at high kilogram price of steel affects the high purchase price of the device. Devices of this type are also relatively complex, which makes their production difficult, but mainly maintenance. Another disadvantage of some of their representatives is that only a specified type of supply device, such as only a bucket elevator, must be used for stocking.

Extraction devices for extracting light fractions from a flow of bulk material are known in the art of class material. These devices comprise a feed device in the form of a belt feed conveyor under which a discharge conveyor (CZ 285671) is located. A suction nozzle connected to a vacuum source is located above the overflow arranged between the inlet conveyor and the outlet conveyor. At the end of the feed conveyor, an overflow edge is provided, in the action range of which the light fraction is extracted. By light fraction is meant particles that can be carried by the effect of air above the level of the feed conveyor. Equipment of this type can also be used to extract straw, dust and other contaminants from cereal grains. However, a disadvantage of the described apparatus is that a relatively high vacuum must be exerted when the said cereal grain admixtures are sucked out, since a bulk material mixture, i.e. cereal grains and their undesirable admixtures, is inflated in the region of the overflow edge.

SUMMARY OF THE INVENTION

These disadvantages are substantially reduced by the suction device according to the invention intended to separate the different weight fractions of the bulk material mixture from one another, in particular to separate dust, straw light impurities and impurities from the cereal grain. The suction device consists of a feed device of the bulk material mixture, with a discharge conveyor located below the feed device and an exhaust nozzle located above the overflow arranged between the feed device and the discharge conveyor. The essence of the invention is that the suction nozzle is closed at the bottom of the overflow. At the same time the suction nozzle is connected to the suction part of the fan, whose discharge part is connected to the air separator. A collecting chamber is provided under the air separator.

An advantage of the suction device according to the invention is that an efficient tool for extracting light fractions from a mixture of different fractions of bulk material is obtained by simple technical means. This is achieved by loosening the bulk material mixture at the overflow, particularly in the lower part of the transfer point where the suction nozzle opens. From the disintegrated material, the vacuum air then sucks off the light fraction relatively easily.

- 1 GB 303233 B6

The spatially and functionally advantageous arrangement consists in that the fan is provided on the one hand with an axial suction part in which the shaft with radial vanes is directed and on the other hand with a radial discharge part arranged substantially tangential to the trajectory of the radial vanes.

In order to achieve a high suction effect, the suction nozzle is formed by a hollow body, into the casing of which an overflow opens.

In order to prevent a portion of the light fraction from falling below the level of the overflow, a sliding bed is provided below the overflow, leading into the suction nozzle jacket obliquely in the direction of the overflowing bulk material mixture.

The suction effect of the suction device is supported by a modification in which the cross section of the suction nozzle is narrowed from the overflow to the fan.

For the purpose of regulating the suction effect, resp. For the purpose of controlling the amount of the extracted light fraction, a regulating flap is slidably mounted in the suction nozzle housing, the active surface of which extends inside the suction nozzle.

Preferably, the angle between the active surface of the control flap and the tangent plane to the overflow is in the range of 80-100 °.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawing, an example of a suction device according to the invention is schematically shown, in which Fig. 1 represents a kinematic diagram of this suction device.

DETAILED DESCRIPTION OF THE INVENTION

The suction device adapted to separate the different weight fractions of the bulk material mixture 9 from one another comprises an inlet device 1 of the bulk material mixture 9 at the inlet. The feed device 1 may be a chute (not shown) resulting from a bulk material container or a feed conveyor 11. The feed conveyor 11 may be designed, for example, as a screw conveyor or, in accordance with an exemplary embodiment, as a belt conveyor. A discharge conveyor 2 is provided below the feed device 1, which can also be of various designs. An economical and technically advantageous solution lies here also in the application of a belt conveyor. An overflow 3 is arranged between the feed device 1 and the discharge conveyor 2.

Above the overflow 3 there is a suction nozzle 4, which is connected to the lower part of the overflow 3. A preferred embodiment of the suction nozzle 4 consists of a hollow body, into whose jacket 41 the overflow 3 is connected. of the hollow body of the suction nozzle 4 in the direction of the flow of the bulk material mixture 9 overflowing between the feed device 1 and the discharge conveyor 2, thereby providing a sliding bed 42 under the overflow 3 into the housing 44 of the suction nozzle 4. material. The cross-section of the suction nozzle 4, i.e. the cross section of its housing, is narrowed from the overflow 3 to the fan 5. In the housing 41 of the suction nozzle 4, a regulating flap 8 is slidably mounted, the active surface 81 extending inwardly of the suction nozzle 4. Preferably, the regulating flap 8 is substantially perpendicular to the flow of the bulk material mixture 9. In this configuration, the angle α between the active surface 81 of the regulating flap 8 and the tangent plane τ to the overflow 3 is in the range of 80 to 100 °.

The suction nozzle 4 at the opposite end to the overflow 3 is connected to the suction portion 51 of the fan 5. The connection of the suction nozzle 4 to the suction portion 51 of the fan 5 is effected by the inlet tube 55. On the one hand, the radial discharge section 52. In the direction of the axially inlet suction section 51, a shaft 53 with radial blades 54 is mounted in the fan 5 with the blades 54. The radial discharge section 52 is arranged substantially tangential to the trajectory of the radial blades 54. is connected to the air separator 6 by means of the exhaust pipe 56. A light fraction collecting chamber 7 is provided below the air separator 6 and an air outlet 61 is provided above the air separator 6.

In operation of the suction device, a mixture 9 of bulk material containing heavy fractions 91, a heavy fraction 91 and a light fraction 92 arrives downstream of the feed device in the direction of the arrow and to the overflow 3. In the overflow 3 this mixture falls towards gravity conveyor 2 . Ambient air is drawn into the suction nozzle 4 surrounding the overflow 3 during operation of the fan 5, i.e. when it is rotated in the direction of arrow n, in the direction of arrow b. The air stream sucks the light fraction 92, which is carried in the direction of arrow c to the fan 5. After passing through the fan 5, the mixture of air and light fraction 92 is conveyed in the direction of arrow d to the air separator 6. Here, the light fraction 92 is separated from the air which is discharged through the air outlet 61 into the ambient atmosphere, while the light fraction 92 enters the collecting chamber 7 in the direction of arrow e as a result of gravity. i.e. the heavy fraction 91, on the discharge conveyor 2, by means of which it is carried in the direction of arrow f for further processing. The intensity of the air sucked into the suction nozzle 4 is controlled by sliding the flap 8 in the direction of the arrow h. The amount of light fraction 92 which is discharged from the flow of the bulk material mixture 9 is regulated by the suction air control.

Industrial applicability

The suction device according to the invention finds application in a number of areas. However, it is particularly suitable for coarse pre-treatment of cereal grains from dust, straw, light impurities and impurities at the reception points of post-harvest lines, where its efficiency reaches up to 80%.

Claims (7)

PATENT CLAIMS Extraction device for separating mass fractions of a bulk material mixture from one another, in particular for separating dust, straw light impurities and impurities from cereal grains, comprising a bulk material feed device (1), wherein a discharge conveyor (1) is located below the feed device (1). (2) and above the overflow (3) arranged between the inlet device (1) and the outlet conveyor (2) is a suction nozzle (4), characterized in that the suction nozzle (4) is connected to the lower part of the overflow ( 3) and at one end to the suction part (51) of the fan (5), the discharge part (52) of which is connected to an air separator (6) under which a collecting chamber (7) is provided. Suction device according to claim 1, characterized in that the fan (5) is provided on the one hand with an axial suction part (51) in which the shaft (53) with radial blades (54) is directed and on the other hand with a radial discharge part (52) arranged substantially tangential to the trajectory of the radial vanes (54). Suction device according to claim 1, characterized in that the suction nozzle (4) is formed by a hollow body, into whose shell (41) the overflow (3) opens. Suction device according to claim 3, characterized in that a sliding bed (42) is provided beneath the overflow (3) and opens into the housing (41) of the suction nozzle (4) at an angle in the direction of the overflow of the bulk material mixture (9). -3GB 303233 B6 Suction device according to claim 1, characterized in that the cross-section of the suction nozzle (4) is tapered from the overflow (3) to the fan (5). Suction device according to claim 1, characterized in that a regulating flap (8) is slidably mounted in the housing (41) of the suction nozzle (4), the active surface (81) of which extends inside the suction nozzle (4). Suction device according to claim 6, characterized in that the angle (α) between the actuating surface (81) of the regulating flap (8) and the tangent plane (τ) to the overflow (3) is in the range of 80 to 100 °.