RU2747190C1 - Grain cleaner - Google Patents

Abstract

FIELD: agriculture engineering.SUBSTANCE: proposed invention relates to agricultural engineering and can be used in machines for cleaning grain in all sectors of the national economy. The device of the grain cleaner consists of a frame, two sieve mills of approximately the same mass, located one above the other, and the sieve mills are attached to the frame using suspensions and racks, while the drive shaft for giving the sieve mills plane-parallel and antiphase vibrations is installed between them. The connecting rods transmitting movement from the shaft to the sieve box are connected to the upper sieve box in the area of its bottom and to the lower sieve box in the area of its cover. A counterweight is mounted on the drive shaft so that when the sieve mills are in the middle position, the counterweight is at the bottom.EFFECT: increased dynamic balance of the grain cleaner.1 cl, 1 dwg

Description

The invention relates to agricultural machinery and can be used in machines for cleaning grain in all sectors of the economy.

Known devices are grain cleaning machines ZVS-20M, MOV-1 and MOS-0.5 (product catalog of the Voronezhselmash plant, www.vselmash.ru) with frames, air and sieve parts, while the sieve part of each machine includes two sieve mills installed one above the other, and the drive shafts to give the reshetny mills plane-parallel and antiphase vibrations are installed between the reshetny mills, and the connecting rods transmitting movement from the shaft to the reshetny mills are attached to the upper reshetny camp in the area of its bottom, and to the lower reshetny camp in the area its cover. The disadvantage of the described structures is the low dynamic balance caused by unbalanced moments of inertia, the maximum value of which occurs in the extreme positions, and in the middle positions of the sieve camps they are equal to zero and their value is determined by the shoulder between the line of action of the inertia force applied to the center of gravity of the sieve camp and the point of connecting the connecting rod to the sieve camp, while the moments of inertia from the two sieve mills add up, increasing the alternating load on the machine supports.

The closest in technical essence to the claimed device, which we have chosen as a prototype, is a grain cleaning machine (patent RU No. 2628433, 2017, В07В 1/10) containing only a sieve part in which there are also two sieve mills of approximately the same mass and located one above the other, and the drive shaft, to give the reshetny mills plane-parallel and antiphase vibrations, is installed between the reshetny mills, while the connecting rods transmitting the movement from the shaft to the reshetny mills are attached to the upper reshetny camp in the area of its bottom, and to the lower reshetny camp in its area covers, and to balance the forces arising in the frame of the machine in the extreme positions of the sieve mills from their weight force, they are installed on suspensions and racks.

The disadvantage of this device is the low dynamic balance caused by unbalanced moments of inertia, the maximum value of which occurs in the extreme positions and their value is determined by the shoulder between the line of action of the inertia force applied to the center of gravity of the sieve camp and the point of attachment of the connecting rod to the sieve camp, and the moments of inertia from two sieve camps have one direction and they are summed up, increasing the alternating load on the machine supports.

The objective of the claimed invention is to increase the dynamic balance of the grain cleaning machine - the prototype by reducing the alternating load on the machine frame supports by creating a counter-moment to the unbalanced total moment from the inertial forces of the sieve mills.

The problem is solved by the fact that the grain cleaning machine has a frame, two sieve mills, of approximately the same mass, and located one above the other, and the sieve mills are attached to the frame using hangers and racks, while the drive shaft for giving the sieve mills plane-parallel and antiphase vibrations are installed between them, and the connecting rods transmitting movement from the shaft to the reshetny camp are attached to the upper reshetny camp in the area of its bottom, and to the lower reshetny camp in the area of its cover.

However, unlike the prototype, a counterweight is installed on the drive shaft so that the centrifugal force of inertia generated by it forms a moment of the opposite direction to the unbalanced total moment from the inertial forces of the sieve mills, which reduces the alternating load on the machine frame supports.

In all cases of the implementation of the claimed grain cleaning machine, it is possible to balance only a part of the unbalanced total moment, i.e. remove no more than 50% of the load on the frame supports, since in the middle position of the sieve mills, the total unbalanced moment is zero.

The essence of the proposed technical solution is illustrated by a drawing. The drawing shows a diagram of a sieve grain cleaning machine, side view. The drawing adopted the following designations: 1 - frame; 2 - suspension; 3 - the place of attachment of the suspension to the frame; 4 - upper reshetny camp; 5 - bottom; 6 - counterweight; 7 - connecting rod; 8 - cover; 9 - the place of fastening the rack to the lid of the sieve bed; 10 - rack; 11 - the place where the connecting rod is attached to the bottom; 12 - the place of attachment of the rack to the frame; 13 - the place of attachment of the suspension to the frame; 14 - suspension; 15 - the place of attachment of the suspension to the bottom of the sieve bed; 16 - support surface; 17 - cover; 18 - lower reshetny camp; 19 - drive shaft; 20 - connecting rod; 21 - bottom; 22 - the place of attachment of the rack to the frame; 23 - rack; 24 - the place of attachment of the rack to the reshetny camp; 25 - the place of attachment of the connecting rod to the cover of the sieve bed; 26 - the place of attachment of the suspension to the bottom of the sieve bed; P3 - grain flow; M ₁ - moment of inertia from the upper sieve bed; M ₂ - moment of inertia from the lower sieve bed; M _{3 is the} moment of inertia from the counterweight; F is the force of inertia from the mass of the upper or lower reshetny camps; Ц ₁ - the center of gravity of the upper sieve bed; Ц ₂ - the center of gravity of the lower sieve bed; a, b, c - the shoulders of the action of inertial forces; A, B - frame supports; P ₁ ; Р ₂ - forces acting on the supporting surface; ω - direction of rotation of the drive shaft; α is the angle of inclination of the sieve camps to the horizon; V is the speed of movement of the sieve camps.

The device of the grain cleaning machine contains a frame 1 on which, with the help of suspensions 2, 14 and racks 10, 23 (suspensions and racks standing on the other side of the sieve camp are not shown in the figure), the upper sieve camp 4 and the lower sieve camp 18 are installed, a drive shaft is installed between them 19 with counterweight 6. Assemble the shaft with counterweight as follows.

The sieves are set in the middle position and the counterweight is attached to the shaft when it is in the down position. The drive shaft with the upper reshetny camp is connected by means of a connecting rod 7 at the point of attachment 11 of its bottom 5, and is connected to the lower reshetny camp by means of a connecting rod 20 at the point of fastening 24 of its cover 17. The frame of the machine is attached to the supporting surface 16 with supports A and B. the mills are installed at an angle a to the horizontal, and the drive shaft rotates in the direction from.

The grain cleaning machine works as follows.

The drive shaft 19 rotates in the direction from or in the other direction and, with the help of connecting rods 7 and 20, brings the sieve mills 4 and 18 into plane-parallel and antiphase vibrations fixed to the frame 1 by means of suspensions 2, 14 and racks 10, 23.

Due to the fact that the sieve mills are installed at an angle a to the horizon, the grain flow PZ moves along the sieve mills and is divided into grain and impurities. In this case, the sieve mills move with variable speed V and experience the action of inertial forces applied in their centers of gravity C ₁ and C ₂ . The maximum value of the inertia force F occurs at the moment of the maximum acceleration of the sieve camps, i.e. in the extreme positions, and in the middle position the sieve mills move without acceleration and, accordingly, the inertia force in this case is zero. The moment of inertia M ₁ from the force F arising from the movement of the upper reshetny camp will tend to rotate the reshetny camp around the attachment point of the connecting rod to the reshetny camp 11. In this case, turn clockwise. The same processes will occur with the lower reshetny camp, and its moment M ₂ from the inertia force F will tend to turn around the attachment point of the connecting rod 20 to the lower reshetny camp at point 25 and in the same direction clockwise. Thus, the moment M ₁ and M ₂ will add up to the total moment, which, through the suspensions and racks, will create forces on the frame supports A and B. In this case, the total moment will tend to raise the support, and press the support B against the supporting surface 16. After turning the drive shaft by 180 ° the picture will be reversed. The moments of inertia will tend to raise the support B, and press the support A against the supporting surface 16.

Unlike the prototype, the drive shaft 19, mounted on the machine frame, has a counterweight 6 attached to it so that the centrifugal force arising during the rotation of the counterweight, when its direction is parallel to the horizon, it creates a reverse moment to the total moment and the forces arising from it on the supports A and B will be subtracted from the efforts created by the total moment. In the case shown in the figure, the force from the moment M ₃ on the support A will be directed towards the supporting surface, and on the support B from the supporting surface.

The total moment from the forces of inertia of approximately the same mass of sieve mills M _s will be equal to the sum of the moments M _s = M ₁ + M ₂

The moment from the centrifugal force of the counterweight F _c , i.e. the balancing moment will have the value M _c = F _c ⋅s

In the middle position, the sieve mills move without acceleration, so the total moment is zero, and the counterweight will be in the lower or upper position and the centrifugal force from the counterweight will tend to raise the frame or press it against the supporting surface, creating an alternating unbalanced load on the frame supports. Thus, the forces arising on the frame supports depend on the value of the centrifugal force of the counterweight and its value is set so as to balance only a part of the total moment, and if the counterweight is in the lower or upper position, the forces that raise or press the frame to the supporting surface should not exceed total efforts on the supports, when the moments of inertia forces of the sieve camps act.

In all cases, the installation of a counterweight on the drive shaft makes it possible to balance a part of the moments of inertia forces that create a dynamic imbalance of the prototype machine.

The use of the claimed invention will improve the dynamic balance of grain cleaning machines, reduce vibrations and dynamic loads on supporting surfaces, such as floors, foundations and floors of industrial buildings.

Claims (1)

The device is a grain cleaning machine containing a frame, two sieve mills of approximately the same mass, located one above the other, and the sieve mills are attached to the frame using suspensions and racks, while the drive shaft for giving the sieve mills plane-parallel and antiphase vibrations is installed between them, and the connecting rods, transmitting movement from the shaft to the reshetny camps, are attached to the upper reshetny camp in the area of its bottom, and to the lower reshetny camp - in the area of its cover, characterized in that a counterweight is installed on the drive shaft so that when the reshetny camps are in the middle position, the counterweight is at ...

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