RU2396120C1 - Device for grinding and separation of feed grains - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to devices for grinding feed grains, followed by separation of products of grinding and can be used in agriculture, particularly on livestock farms and feed shops. The device for grinding and separation of feed grain includes the grinding chamber a loading hopper and the vertical cylindrical body, where the rotor is placed, the grinding chamber with a sieve, separating it into upper and lower sections, the latter of which has a sloping bottom, and the separation device positioned between the grinding chamber and the separation camera with a gap in relation to the walls of the chambers of 15-30 mm and made in the form of two successively installed at a height screens, the upper of which is placed horizontally, and the lower is placed obliquely, with the angle of slope 10-15°, and parallel to the sloping bottom of the lower section of the separation chamber. The device is equipped with a vacuum system, communicating the upper section of the separation chamber through the unloading window with the upper part of the grinding chamber and consisting of a collection of overtail with a flap turning around its axis at 90°, drop tubes and blade disk with replaceable blades and slots mounted on the rotor directly under the lid of the grinding chamber. Socket of the drop tubes is mounted into the lid of the grinding chamber in the intake area, which is limited to 0.5 R from the axis of the grinding chamber rotor, and the rotor discs have holes corresponding to holes of the blade disc and located coaxially beneath them in the vertical plane.

EFFECT: invention enables to reduce the size of the device, reduce metal consumption, energy consumption, to ensure consistent grinding and serviceability.

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Description

The invention relates to a device for grinding feed grain followed by separation of grinding products and can be used in agriculture, in particular on livestock farms and animal feed workshops.

A device for grinding grain (SU 1329818 A1, 1991) is known, comprising a crushing chamber with a hammer rotor located inside it and a separation chamber connected to the crushing chamber by a feed pipe made curved and tapering along its entire length.

However, this design does not allow reliable control of the degree of separation of the products of grinding, because the separator sieve is often clogged, does not provide reverse operation of the crusher rotor, which grinds the product only in half of the crushing chamber, and the other half is busy with “loading” and “unloading” of the product.

The closest in technical essence of the invention is the "Installation for grinding and separation of feed grain" (RU 2236294 C1, 2003), including a crusher with a vertical cylindrical body, in which the crushing chamber and the separation chamber are arranged in series, with the upper and lower sections of the chamber separations are communicated respectively with the small and main pneumatic systems with cyclones, where the cyclone of the small pneumatic system is in communication with the feed hopper of the crusher.

The disadvantage of this installation is the presence of two pneumatic systems with cyclones and electric drives, which complicate the design, make it cumbersome, which in turn requires large production areas for its placement, increases metal consumption and energy consumption.

The objective of the invention is to create an installation for grinding and separation of feed grain by sieving the crushed mass (heap) and transporting a large part (gathering) for re-grinding (recirculation) using the vacuum created by the rotor of the crushing chamber, while eliminating two pneumatic systems, thereby reducing installation dimensions, reduce metal and energy consumption, ensure fractional grinding and ease of maintenance.

The task is achieved in that the installation for grinding and separation of feed grain, including a crushing chamber with a feed hopper and a vertical cylindrical body in which the rotor is located, a separation chamber with a sieve separating it into upper and lower sections, the last of which has an inclined bottom, and a separation device located between the crushing chamber and the separation chamber with a gap relative to the walls of the chambers of 15-30 mm and made in the form of two screens successively installed along the height, the upper of which is located horizontally, and the lower one is inclined, with an angle of inclination of 10-15 °, and parallel to the inclined bottom of the lower section of the separation chamber, is equipped with a vacuum system that communicates the upper section of the separation chamber through an unloading window, with the upper part of the crushing chamber and consisting of a collector a descent with a 90 ° rotary valve around its axis, a feed pipe and a blade disk with interchangeable blades and holes mounted on the rotor directly under the crushing chamber cover, while the feed pipe fitting is integrated into the cr shku grinding chamber into the suction zone which is bounded 0,5 R from the rotor axis of the grinding chamber and the rotor disks have openings corresponding to the openings of the vane disc and located underneath in a vertical plane.

The installation on the rotor directly under the cover of the crushing chamber of the blade disk with removable blades and holes, as well as the presence of holes in the rotor disks corresponding to the holes of the blade disk, and their location strictly under the holes of the blade disk in a vertical plane, enhances the vacuum (discharged air) created by the rotor during operation, while embedding the nozzle of the feed pipe of the vacuum system into the cover of the crushing chamber directly in the suction zone, limited to 0.5 R from the axis of the rotor (R is the distance about t of the rotor axis to the sieve), provides constant suction of the fraction that did not pass through the woven sieve from the collection box, where it enters from the separation chamber through the discharge window, for grinding again, which together allows eliminating pneumatic systems with cyclones, while maintaining uniformity of fractional grinding.

The suction zone of 0.5 R from the axis of the rotor was established experimentally for this design of a blade disk with replaceable blades, which is selected from the theory and calculations of fans (Sherstyuk AN “Pumps, fans, compressors.” M.: Higher School, 1972 G., p. 83-84; MP Kalinushkin, “Pumps and fans.” M.: Higher School, 1987, p. 23-25). According to the theory, the suction zone starts from the axis of the fan rotor, and the discharge zone is located on the periphery of the wheel (in our case, the blade disk). Experimental data showed that the partition between the two zones is within the range of (0.5-0.6) R. For a more reliable operation of the crushing chamber, a value of 0.5 R is adopted. The geometric parameters and speed are selected depending on the set capacity of the installation, and The main aerodynamic dimensions are determined on the basis of statistical analysis. The use of removable blades minimizes the changeover time of the installation.

The presence of an adjustment flap in the vanishing unit allows you to control the flow rate and the amount of vanishing stream sent for re-grinding by turning it around its axis by 90 ° depending on the set capacity (2-10 t / h), which provides a wider application for grinding and separation of feed grain in any farms. The design of the vacuum system, in communication with the upper section of the separation chamber and the crushing chamber, allows to reduce the dimensions of the installation, reduce metal consumption, energy consumption and ensure ease of maintenance of the installation.

Figure 1 presents a General view of the installation for grinding feed grain, figure 2 is a section along aa of figure 1, figure 3 is a section along b-b of figure 1, figure 4 is a view In fig. one.

Installation for grinding and separation of feed grain contains a crushing chamber with a cylindrical body 1 (figure 1), on the cover 2 of which is mounted an electric motor 3 and a loading hopper 4. In the housing 1 there is a vertical rotor including a shaft 5 with a vane disk 6 firmly mounted on it (figure 1, 2), equipped with removable blades 7 and holes 8, the rotor disks 9 (figure 1, 3) having holes 10 corresponding to the holes 8 of the blade disk 6, hammers 11 (figure 1), freely rotating on the axes 12, and a cylindrical sieve 13.

The installation has a separation device located between the crushing chamber and the separation chamber, installed with a gap relative to the walls of the chambers, 15-30 mm and made in the form of two screens successively installed in height, one of which 14 is made round and arranged horizontally, and the second 15 is made square and located obliquely, with an inclination angle of 10-15 °. The separation device communicates the crushing chamber with the upper section of the separation chamber. The upper and lower sections of the separation chamber are separated by a woven sieve 16 installed obliquely in the opposite direction to the inclination of the screen 15 and the inclined bottom 17 of the separation chamber, while the screen 15 and the inclined bottom 17 are parallel.

To the unloading window 18, located in the square case 19 of the separation chamber, is attached to the collection of the descent 20 (Figs. 1, 4) of the vacuum system, equipped with an adjustment flap 21, rotating around its axis 22 by 90 °. The gathering assembly 20 informs the upper section of the separation chamber by means of a feed pipe 23 provided with an elastic pipe 24 (Fig. 1) and a pipe 25, with a crushing chamber, into the cover 2 of which a pipe 25 of the feed pipe 23 is built directly into the suction zone, limited to 0.5 R from the axis rotor. An electric vibrator 26 is installed on the housing 19 of the separation chamber. The installation for grinding and separation of feed grain is mounted on the frame 27.

Installation for grinding and separation of feed grain works as follows. The electric motor 3, mounted on the cover 2, of the cylindrical body 1 of the crushing chamber, and the electric vibrator 26, mounted on the square case 19 of the separation chamber, are started. Feed grain enters from the feed hopper 4 into the crushing chamber, is between the blades 7 of the blade disk 6, is discarded by the blades onto the cylindrical sieve 13, is reflected from it, falls under the blow of hammers 11 freely rotating on the axes 12, and returns to the cylindrical sieve 13, with this is partially collapsing. Particles smaller than the diameter of the hole in the sieve, under the action of hammers and air, are removed beyond the sieve. The higher the coefficient of living cross-section of the sieve (the sum of the areas of holes in it), the better the sifting and the higher the homogeneity of the grinding product. In the steady state, the material to be crushed is evenly distributed over the height and the entire sieve and accumulated in the crushing chamber. Under the influence of blows of hammers 11, dead weight, air pressure created by a blade disk 6 rigidly mounted on the rotor shaft 5, equipped with removable blades 7, and rotor disks 9, the crushed grain is in a fluidized state, and along the central part of the rotor (at the axis of the shaft 5) a vacuum is created, which is amplified by the blades 7 and the holes 8 of the blade disk 6 and the holes 10 in the rotor disks 9, respectively made and arranged coaxially one below the other in a vertical plane, while at the same time the surface of the sieve is created pressure. Thus, the volume of the crushing chamber is divided into a vacuum (suction) zone and a pressure (injection) zone.

Being in a fluidized state and from a constant back-up of partially crushed material continuously entering the crushing chamber, the heap passes through the annular gap between the sieve 13 and screen 14 and enters the inclined screen 15. Screens 14 and 15 separate the air regime of the crushing chamber from the separation chamber, quench the food-air layer and prevents the heap from being sucked by the vacuum system through the discharge window 18. The heap is concentrated in the upper part of the fabric sieve 16, by which under the action of vibration generated by An electric vibrator 26 mounted on the square case 19 of the separation chamber separates its fraction, the gathering - what remains on sieve 16 and the passage - what passed through it. The exit through the unloading window 18, located in the separation chamber housing 19, is poured into the collection container 20, which is an integral part of the vacuum system, while the adjustment flap 21, which is equipped with the collection container 20, due to its rotation around its axis 22, the outflow rate is regulated and the magnitude of the vanishing flow. Under the influence of the vacuum formed between the blade disk 6 with removable blades 7 and the cover 2 of the cylindrical body 1 of the crushing chamber, the flow of descent moves through the feed pipe 23, containing an elastic pipe 24 and pipe 25, and enters the crushing chamber in the suction zone for re-grinding (recycling) . The presence of an elastic pipe 24, with constant vibration of the square case 19 of the separation chamber, provides the vacuum system with stable operation, and the reliability of the entire installation is due to its placement on the frame 27.

Passage - finished products along the inclined bottom 17 of the lower section of the separation chamber enters the container or vehicles. The frequency and strength of the vibration is regulated by an electric vibrator 26. If necessary (regulation of the degree of grinding) hammers 11, a woven sieve 16 and a cylindrical sieve 13 are replaced.

This installation, due to the presence of a vacuum system for returning the descent, eliminates two pneumatic systems with cyclones, reduces the dimensions of the installation, reduces metal consumption, energy intensity, ensures uniform grinding and ease of maintenance.

Claims (1)

Installation for grinding and separation of feed grain, including a crushing chamber with a loading hopper and a vertical cylindrical body, in which the rotor is located, a separation chamber with a sieve separating it into upper and lower sections, the last of which has an inclined bottom, and a separation device located between crushing chamber and separation chamber with a gap relative to the walls of the chambers 15-30 mm and made in the form of two screens successively installed along the height, the upper of which is located horizontally, and lower inclined, with an angle of inclination of 10-15 ° and parallel to the inclined bottom of the lower section of the separation chamber, characterized in that the installation is equipped with a vacuum system that communicates the upper section of the separation chamber through an unloading window with the upper part of the crushing chamber and consisting of a collection pan with a rotary around its 90 ° axis with a shutter, a feed pipe and a blade disk with interchangeable blades and holes mounted on the rotor directly under the cover of the crushing chamber, while the pipe of the feed pipe is built into the crushing cover action in the suction zone, which is bounded 0,5 R from the rotor axis of the grinding chamber and the rotor disks have openings corresponding to the openings of the vane disc and arranged coaxially underneath in a vertical plane.

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