UA25405U - Broadcasting device of grain separator - Google Patents

Abstract

A broadcasting device of grain separator comprises a broadcasting disk, L-like blades installed thereon and a wall with a deflector arranged at right angle to each other, a driving mechanism cinematically connected with the broadcasting disk, a source of ascending air located above the disk. The blades are placed in such a way that walls thereof are located at the various angles to the disk plane.

Description

Description of the invention

The useful model refers to agricultural production and can be used for cleaning, 2 separation and sorting of grain, seeds and other loose materials.

There are well-known spreading devices of grain separators that use ring vertical pneumatic separating channels that clean the grain according to the aerodynamic properties of the particles before they enter the sieve

Universal vibro-centrifugal grain separator. Goncharov V.S., 1984. Art. 15-18). To introduce grain into the channel, rotary spreading discs are used, the drive of which is carried out from the rotor of the grating part 70 directly or through a gearbox, which accelerates the rotation of the spreader in relation to the speed of rotation of the rotor. The first option is more often used, as it simplifies the design of the drive and increases the reliability of the pneumatic separator.

Such spreading discs must introduce the grain mass into the separating channel with a given speed and direction and a thin loosened layer that is evenly distributed along the circle of the upper edge of the spreading disc. Since the speed of rotation of the spreading disk is limited by the speed of rotation of the rotor (gearless drive), and its dimensions are limited by the dimensions of the vertical pneumatic separating channel, the quality of separation of light impurities directly depends on the design of the spreading disk.

Also known is the spreading device of the grain separator, which consists of inner and outer cones, between the surfaces of which radial vanes are installed, and the height of the vanes is lower than the height of the outer cone

Av. St. USSR Mo889142, IPC? VO781/001. The radial vanes are evenly spaced between the cones with a constant angle coefficient. The axis of symmetry of the scattering disk is the axis of its rotation and is placed vertically in space.

During the operation of such a spreading disk, the supplied grain slides along the surface of the inner cone and displaces the grain mass in the radial direction into the zone of active acceleration, where the radial vanes are located. These 729 vanes give the grain an angular velocity equal to the angular velocity of the spreading disc, due to which part of the grain slides along the spreading surface along the vanes, and then along the area of this surface that does not contain vanes. The blades and the surface of the outer cone adjacent to them are intended for the primary intensive dispersal of the grain mass, and the upper part of the surface of the outer cone is transported for smoothing individual jets! of grain mass and its additional dispersal. o 3o Since the spreading disk must introduce all the grain particles into the pneumatic separation channel at the same (av) speed (by value), the layer-by-layer movement of particles during transportation along the surface of the disk is undesirable. Therefore, when using such a disk, there is a restriction on the choice of frictional properties of the spreading surface of the disk. The coefficient of external friction of the grain mass on the surface of the spreading disc should be less than the coefficient of internal friction of the grain. From which it follows that in order to qualitatively perform the technological process on various grain crops, it is necessary to change the physical condition of the surface of the spreading disk. Since the vanes have the same design parameters, each vane ejects a grain particle in approximately the same direction.

This creates a rather condensed layer of the grain mass, which is blown by the rising air flow, from which it is difficult to separate light impurities. An analogue can also be a centrifugal spreading disk, which is kinematically connected to the drive mechanism and is made in the form of a conical disk consisting of interconnected bottoms and sidewalls with blades installed on the disk and rigidly attached to it. The bottom of the scapula forms an acute angle with the axis of rotation of the disk :z" (Av. St. USSR Mo257190, IPC? ДО1ТС17/00).

During the operation of this scattering device, particles of material under the action of centrifugal forces move along the bottom of the blade at an angle to the horizontal plane, and therefore in free flight the vectors of absolute velocities of these

HF particles are also directed upward at an angle to the horizontal plane. As a result, at equal absolute velocities, the trajectories of the movement of grain particles are more elongated (paraboloid), which allows the upward air flow to better blow the grain mass coming off the disc. Since the grain particles are thrown into the rising air stream at the same angles to the horizon, the 5p rarefaction of the grain layer remains satisfactory. ("in the Prototype can be considered a spreading device of a grain separator containing a spreading disc, sl installation on the spreading disc of vanes (from 2 to 4), and the vanes are made flat in the form of walls and fixed on the plane of the spreading disc at a right angle, a drive mechanism that leads in motion the spreading disk and the source of the upward air flow (optional). The blades are made of different lengths and 5B of different heights and are installed at different angles to the radius of the disk |patent of Russia Mo2134947, MPK?, AOTS17/00).

During the operation of the specified machine, the processing material is uniformly supplied to the specified area from the spreading disk, which rotates. Next, the material is captured by the vanes and under the action of odontogenic forces, the material particles move with acceleration along the vanes from the center of the disk to its periphery. After separation from the blades, the particles of material leave the disk with different velocities in terms of value and direction. At small feeds on the surface of the disk, the grain particles interact with the highest blades. As the supply of material to the surface of the disk increases, the middle blades are included in the work, and when the largest material supply is reached, the lowest blades are included in the work. Due to the fact that in this spreading device, all blades are of different lengths and are set at different angles to the radial direction of the disk, particles of material breaking away from the surface of the disk receive different speeds and angles of convergence in relation to the disk, 65 due to which they are distributed over a greater distance and evenly. The installation of paddles of different lengths and heights on the disk contributes to the improvement of the quality of the distribution of material particles in space. Thus, the blades, fixed at right angles to the plane of the disk, distribute the material in a thin layer, and this layer is quite dense.

The disadvantage of the known spreading device is that the layer of material coming from the spreading disc is dense enough, light impurities are not sufficiently removed.

The task of a useful model is to create a scattering device of a grain separator, in which, by changing the design of the blades, the ascent of the material at different angles to the horizon is achieved, and the trajectories of the movement of particles are sprayed in space, which contributes to better separation of light impurities by air flow.

The task is solved due to the fact that the spreading device of the grain separator, which contains a spreading disc, the blades are installed on the spreading disc, are made L-shaped and include a wall and 7/0 Visor, the angle between which is straight, a drive mechanism, kinematically connected to the spreading disc and the source of the upward air flow, located above the disk, differs in that the walls of the blades join the plane of the disk at different angles.

Due to the fact that the walls of the L-shaped blades are placed at different angles in relation to the plane of the disk, the material comes out in a wide strip and with a small density from the periphery of the disk. This makes it possible to blow better /5 with an upward air stream and to more completely isolate light impurities.

In addition, the angles between the walls of the L-shaped blades and the plane of the disk are successively increased along the arc of the circle of the disk, as a result of which the uniformity of the descent of the material improves.

Thus, since the walls of the L-shaped blades are set at different angles in relation to the plane of the disc, when the L-shaped blade interacts with the material fed to the disc, individual particles of the material when descending from the disc receive different directions and values of the speed of descent , as a result of which the mass becomes more rarefied. This contributes to better aspiration by the upward air flow, accordingly, light impurities are better removed from the mass of grain material coming off the disk.

The essence of the useful model is explained by the drawings, where Fig. 1 is the implementation scheme of the useful model; Fig. 2 - scheme of the spreading device of the grain separator; Fig. 3 - cross-section of the spreading device of the grain separator.

The grain separator consists of a casing 1, which houses a vertical aspiration channel formed by a vertical cylindrical sieve 2, to which vanes 3 are attached. Unloading trays 4 are attached to the casing 1. A spreading device 5 is placed inside the vertical aspiration channel, which consists of a spreading disk b , distribution cone 7 and blades 8, which are L-shaped and consist of a wall and a visor (Fig. 2). The vertical cylindrical sieve 2 and the spreading device 5 are kinematically connected to the drive pulley 10. Above the spreading device, there is a grain pipe 11 and a collector 12, which is connected to the source of air flow (not shown in the figure). at

The grain separator works as follows. The cleaned material is fed to the grain pipe 11, and from the "E" of the grain pipe 11, the material is fed to the spreading device 5, while the distribution cone 7 evenly feeds the material to the walls of the blades 8. Then the particles move along the walls of the blades 8 from the distribution cone 7 about

To visors. Since the walls of the blades 8 are placed at different angles o to the spreading disk b, particles of the material fly out of the visors in different directions relative to the spreading disk b (Fig. 3). Next, the mass of material dropped by the spreading device 5 is blown by the upward air flow inside the vertical aspiration channel formed by the vertical cylindrical sieve 2. The light particles captured by the upward air flow are transported by it to the collector 12 and removed from the vertical aspiration channel. "

The material cleaned of light impurities is further separated by a vertical cylindrical sieve 2 in the field of centrifugal forces. Separated fractions of the material are transported to unloading trays 4 by blades 3. The implementation of a useful model of a pneumatic centrifugal separator is obvious from the description of the operation of the pneumatic centrifugal separation machine.

Thus, the spreading device of the grain separator, consisting of a spreading disc, L-shaped blades, in which the angle between the visor and the wall is straight and placed in such a way that the walls of the L-shaped blades form different angles relative to the spreading disc, the drive mechanism, kinematically connected to the spreading disk, the source of the upward air flow - provides better layering of the material and other mixing in the air flow, and as a result of increasing the efficiency of material separation and "increasing" the productivity of the grain separator (according to approval data on 18-2596) and increasing the aeration of the loosened layer by 5o material (on 15-2096). (c) sl

Claims (2)

The formula of the invention 1. The spreading device of the grain separator, which contains a spreading disk, blades installed on the spreading disk, made L-shaped, and a wall and a visor, the angle between which is straight, a drive mechanism, kinematically connected to the spreading disk, a source of upward air flow, placed above the disc, which differs in that the blades are installed in such a way that their walls are placed at different angles in relation to the plane of the disc. 60 2. The spreading device of the grain separator according to claim 1, which is characterized by the fact that the angles between the walls of the blades and the plane of the disk are successively increased along the arc of the circle of the disk. b5