RU2747732C1 - Feed dispenser - Google Patents

Abstract

FIELD: feed dispensers.SUBSTANCE: feed dispenser includes a feed hopper and an adjoining unloading mechanism in the form of a front impeller located in a housing with unloading windows and a feed line with an intake milling cutter installed at its end. In front of the impeller, there is a lifting flap with a filter element, installed with the possibility of blocking the impeller opening. The filter element is made in the form of a two-stage air-feed mixture separator filter. The first stage of the separator filter is made in the form of a louvered lattice, the walls of which are set to the horizon at an angle exceeding the angle of friction of the feed against the wall material. The second stage is made in the form of a vertical grid for capturing small fractions, fixed on a frame, which is connected to the louver grid by means of elastic rods that allow transverse vibrations of the grid.EFFECT: reduction of feed losses.3 cl, 2 dwg

Description

The invention relates to agriculture and can be used on livestock farms for the distribution of feed to animals

Known is a multifunctional grinder-dispenser of animal feed, including a frame with a chassis and a hopper in the form of a horizontal rotating cylindrical drum, with an opening in the wall, in which a blade rotor is placed in a special housing with discharge windows, the impeller, the blades of which are equipped with grinding knives, and on the front wall inside the hopper is equipped with a lift-and-turn damper, installed with the possibility of overlapping the rotor opening (RF patent No. 2714731, IPC A01K 5/00, 2019). This solution is close enough to the proposed one in terms of a number of technical features.

Known self-loading feed dispenser, including a sealed hopper for feed and an adjacent unloading mechanism in the form of a rotating front impeller, enclosed in a housing. in the walls of which there are unloading windows, and in the wall of the bunker there is also a loading opening, to which a feed line is connected from the outside with an intake milling cutter installed at its end, and the lifting flap is equipped with a filter element (application 2019120891, 2019). This dispenser, in addition to distributing, produces pneumatic self-loading of feed by creating a vacuum in the hopper of an impeller rotating at a high speed, and taking in the feed loosened by the cutter with an air flow through the feed line. In this case, the air leaving the hopper passes through the filter element of the damper.

The disadvantage of the known device is the insufficiently efficient operation of the filter element, which, on the one hand, passes fine particles through the mesh, which leads to their inflation and losses, on the other hand, these particles stick to the mesh, decrease the air flow through the mesh and disrupt the operation of the self-loading system ...

The technical objective of the invention is to improve the efficiency of the filter element and the reliability of the self-loading system, to reduce the loss of feed.

The technical problem posed is achieved by the fact that the feed dispenser, which includes a feed hopper and an adjoining unloading mechanism in the form of a front impeller located in a housing with unloading windows, in front of which there is a lifting damper with a filter element, installed with the ability to overlap the impeller opening, and with an intake cutter installed at its end, according to the invention, the filter element is made in the form of a two-stage filter-separator of the air-feed mixture, the first stage of which is made in the form of a louvred lattice, the walls of which are set to the horizon at an angle exceeding the angle of friction of the feed against the wall material , and the second stage is made in the form of a vertical grid for capturing small fractions, fixed on the frame, which is connected to the louver grid by means of elastic rods that allow transverse vibrations of the grid. In addition, a permanent magnet is attached to the impeller, and the elastic rods are made in the form of a spiral.

The invention is illustrated by drawings.

Figure 1 schematically shows a General view of the feed dispenser, side view; Fig. 2 shows a rotor assembly with filter elements in more detail.

The fodder dispenser contains a rotating cylindrical hopper 3 mounted on the frame 1 of the chassis 2, made in the form of a drum with a blank bottom 4, a loading hatch 5 and a front wall 6. In the wall 6 there is a circular opening, to which a housing 7 with discharge windows 8 adjoins from the outside. A vane rotor-impeller 9 is placed inside the housing 7. The rotor 9 is driven from the power take-off shaft of the towing tractor through the cardan shaft 10. On the wall 6 of the bunker 3, a lift-and-turn damper 11 is installed on the inside, including a two-stage filter - an air-feed separator mixture, which can go down, blocking the opening of the rotor 9, and rise, freeing it. The first stage is a louvred lattice 12 with steeply inclined slats set at an angle to the horizon greater than the angle of friction of the feed on the materials from which the slats are made. The second stage is a vertical grid 13 for capturing small fractions, fixed on a frame, which is connected to the louver grid 12 by means of elastic rods 14, allowing transverse vibrations of the grid 13. To enhance the vibrations of the grid 13, a permanent magnet 15 is fixed on the rotor 9, and to eliminate the possible imbalance of the rotor 9, the magnet 15 must be fixed on the rotor 9 in advance, before it is balanced. Considering that the overall transverse dimensions of the filter should be minimal, and the real length of the elastic rods 14 having the required rigidity may turn out to be large, the rods 14, in order to create a compact structure, can be rolled into a spiral.

At the rear of the dispenser, through a hole in the wall 6, a feed pipe 16 is connected at the end of which a cutter 17 is installed.

The work of the feeder is carried out as follows.

When self-loading, the damper 11 is lowered to the lower position, the cutter 17 and the impeller 9 are switched on in fan mode, which takes air from the hopper 3 and throws it out through the damper 11 and window 8. The air flow generated in the feed line picks up the feed loosened by the cutter and transports it to hopper 3, where it settles and accumulates. Air and the residual amount of suspended light particles of feed passing through the louvers 12 sharply change the direction of movement to an upward, close to vertical, due to which the particles of feed fall out of the stream, fall on the louvers 12 and slide down from them into the hopper 3. This is facilitated by the large angle of installation of the louvers 12 to the horizon, a low coefficient of friction of the surface of the louvers 12, and an increased size of the passage section of the damper 11, several times larger than the size of the passage section of the feed pipe 16, as a result, the transporting air velocity decreases by the same amount between the plates of the louvers 12. The air that has passed through the louvers 12 with the remnants of light and sticky feed particles then passes through the mesh 13, to which the feed particles can stick or be pressed by the air flow, reduce the flow area of the mesh 13 and the air flow and disrupt the self-loading process. To prevent this from happening, the mesh is attached to the shutter 11 on elastic rods 14, allowing it to vibrate (vibrate) relative to the shutter 11 in the transverse direction. In the process of oscillation, feed particles fall off the grid 13, crumble and through the louvers 12 enter the hopper 3. To enhance the vibrations, a magnet 15 is installed on the rotor 9. When the rotor 9 rotates, the magnet 15 alternately attracts different sections of the grid 13 and thus further enhances its vibrations. The installation of the magnet 15 on the finished product can cause an imbalance in the rotor 9, therefore it must be installed in advance, before balancing the rotor 9.

When distributing feed, the flap 11 rises to the upper position, opening the free flow of feed to the impeller 9, the cutter 17 is fixed in a non-working position, the hopper 3 rotates, the feed inside it is evenly poured under the influence of its gravity and is additionally mixed. Since the hopper 3p has a slight forward inclination, the entire mass of feed is evenly moved to the impeller 9, which discharges it through the windows 8 into the feeders.

When using this technical solution at the feed distributor, the efficiency and reliability of the self-loading system increases, and feed losses are reduced.

Claims (3)

1. A feed dispenser, including a feed hopper and an adjoining unloading mechanism in the form of a front impeller located in a housing with unloading windows, in front of which there is a lifting flap with a filter element, installed with the ability to overlap the impeller opening, and a feed line with an intake installed at its end milling cutter, characterized in that the filter element is made in the form of a two-stage filter-separator of the air-feed mixture, the first stage of which is made in the form of a louver grate, the walls of which are set to the horizon at an angle exceeding the angle of friction of the feed against the wall material, and the second stage is made in in the form of a vertical mesh for capturing small fractions, fixed on the frame, which is connected to the louvered grill by means of elastic rods that allow transverse vibrations of the mesh. 2. A feed dispenser according to claim 1, characterized in that a permanent magnet is attached to the impeller. 3. A feed dispenser according to any one of claims 1 or 2, characterized in that the elastic rods are made in the form of a spiral.

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