RU157113U1 - CLEANING FAN - Google Patents

Abstract

1. The fan of the cleaning system, containing several radial impellers located on a common shaft, rotating in the fan casing, each of which sucks air in a direction parallel to the axis of rotation of the shaft, and pumps it into two ventilation ducts, one ventilation duct is tangent to the direction of movement the blades and ensures the movement of air flow along the arcuate line to the additional sieve of the shaking board, the second ventilation channel is located tangentially to the direction of movement of the blades and has straight sections of the channel above and below, providing air flow to the upper and lower screens of the combine, while in the inlet part both ventilation channels are equipped with a metal sheet having cuts in the form of concavity at the edges, characterized in that two wedge-shaped shields are inserted into it, which, during operation, divide the air flow from each impeller into four uniform air flows directed to the lower and upper parts of the additional sieve of the shaker board and to the upper and lower sieve. 2. The fan according to claim 1, characterized in that the wedge-shaped shields are installed in the ventilation ducts. 3. The fan according to claim 1, characterized in that the shaft is made of a hexagonal metal rod, and the impellers are mounted on it with clamping clamps.

Description

The inventive utility model relates to agricultural machinery, in particular, to fans of the cleaning system for combine harvesters, in which there is at least one impeller and a housing with a tangentially connected air exhaust channel through which the air flow produced by the impeller is supplied to the elements of the cleaning system during operation, in this case, the air flow ensures the separation of grains from lighter particles, such as chaff and sex, and should be equally intense throughout Irina purification system to achieve the desired degree of purification.

To ensure the desired degree of cleaning, the fans for combine harvesters for the most part consist of several radial impellers located on a common shaft, rotating in the fan casing, which suck in air in a direction parallel to the shaft axis and pump it into the air duct located tangentially or tangentially to direction of movement of the blades. The location of such a cleaning fan in the combine is described in patent EP 1733610 A1 dated June 16, 2005. The air flow is blown at an angle from below the sieve, while lighter components are carried away from the harvested mass moving in the sieves and are thrown out of the combine, and the grain mass is returned either to the pre-grinding device, or moves to the bunker of the combine. With such a known cleaning system, the problem is that the air flow passes through the sieves, mainly in their front area facing the fan. In contrast, in the posterior region of the sieves, airflow is weakened or even absent. This leads to an uneven distribution of the air flow, which leads to an uneven separation of straw and small heaps from the harvested mass, which must be cleaned.

Closest to the claimed technical solution is the fan of the cleaning system for combine harvesters according to patent EP 0683970 A2 of 11.29.1995, containing several radial impellers located on a common shaft, rotating in the fan housing, each of which sucks air in a direction parallel to the axis of rotation shaft, and pumps it into two ventilation ducts: one ventilation duct is located tangential to the direction of movement of the blades and provides air flow not in a straight line, but in an arc oh, on the additional sieve of the shaking board, the second ventilation channel is located tangentially to the direction of movement of the blades and has straight sections of the channel above and below, providing an air flow to the upper and lower sieves of the combine, while in the inlet part both ventilation channels have a metal sheet in the form tongue, having a cutout in the form of concavity on the edge.

The disadvantages of the prototype are: the presence of obstacles to the movement of the air flow when exiting the ventilation ducts in the form of front end walls of the additional sieve of the shaker board, as well as the upper and lower sieves, which reduces the efficiency of the air flow; the difficulty of ensuring an accurate fit in the connection of the circular shaft with the impeller, which leads to an increase in the cost of the product.

The objective of the utility model is to provide a more favorable blowing of sieves with obtaining high separation efficiency along the entire length of the sieves, reducing the cost of manufacturing the shaft in conjunction with the impeller.

The technical result is achieved by the fact that the fan of the cleaning system contains several radial impellers located on a common shaft that rotate in the fan housing, each of which sucks air in a direction parallel to the axis of rotation of the shaft and pumps it into two ventilation ducts, with one ventilation duct located tangent to the direction of movement of the blades and provides air flow not in a straight line, but in an arcuate manner on an additional sieve of the shaking board, the second ventilation duct l is located tangentially to the direction of movement of the blades and has straight sections of the channel above and below, ensuring the flow of air to the upper and lower screens of the combine, and in the inlet part both ventilation channels have a metal sheet in the form of a tongue, having a concavity cutout on the edge, introduced two wedge-shaped shields, one in each ventilation channel, which during operation divide the air flow from each impeller into four uniform air flows directed to the lower and upper hours and an additional sieve of the shaker board, as well as the upper and lower sieves, while the shaft is made of a hexagonal metal rod on which the impeller is mounted using a clamping clip, thereby preventing rotation and axial movement of the impeller relative to the shaft, while not required, in comparison with the prototype, additional mechanical processing of the shaft at the place of mounting of the impeller, which reduces the cost of manufacturing the shaft.

The inventive utility model is illustrated by drawings:

FIG. 1 - cleaning system, left view;

FIG. 2 - fan of the cleaning system, left view;

FIG. 3 - fan of the cleaning system, section AA from FIG. one;

FIG. 4 - fan of the cleaning system, section BB of FIG. 2;

FIG. 5 - tongue in the inlet of the ventilation ducts in the form of concavity.

The inventive utility model includes the following structural elements (Fig. 1-5): 1 - additional sieve with the end wall 2 and the lower zone 3; 4 - shaking board; 5 - the upper sieve with the end wall 6; 7 - the lower sieve with the end wall 8 and the lower zone 9; 10 - impeller; 11 - shaft; 12 - case; 13, 14 - ventilation ducts; 15, 16 - wedge-shaped shields with the base 17; 18, 19 - convex and concave walls of the ventilation channel 13; 20, 21 - the upper and lower walls of the ventilation duct 14; 22 - clamping clamp; 23, 24 - entry parts of the ventilation channels 13, 14; 25 - language; 26 - side walls of the ventilation channel 13; 27 - side walls of the ventilation channel 14; 28 - bearing bearings; 29 - hydraulic motor; 30 - frame; 31 - input holes of the housing 12.

The impellers 10 are fixed on the shaft 11, having a cross section in the form of a hexagon, using clamping clamps 22 (see Fig. 2), which prevents the rotation and axial movement of the impeller 10 relative to the shaft 11, the hydraulic motor 29 is attached to the latter, while the shaft 11 is installed in bearing bearings 28, mounted on a frame 30, to which, in turn, is attached a housing 12 together with ventilation ducts 13, 14 having languages 25 in the entry portions 23, 24 (see Fig. 2, 3). The bore of the ventilation channel 13 is formed at the top and bottom of the convex 18 and concave 19 walls (see Fig. 2) and side walls 26 (see Fig. 3). The bore of the ventilation channel 14 is formed by the upper 20, lower 21 and side 27 walls (see Fig. 4). Inside the ventilation channels 13, 14, wedge-shaped shields 15, 16 are fixed (see. Fig. 1, 2).

The inventive utility model works as follows. The hydraulic motor 29 rotates the shaft 11, which is mounted by means of bearing bearings 28 on the frame 30, on which the impellers 10 are fastened with clamping clips 22. When the impellers 10 rotate through the inlet openings 31, air is drawn into the housing 12 (see Fig. 3) . The air goes to the inlet parts 23, 24 and passes through the tongues 25 (see Fig. 5), after which it rushes with a stream into the ventilation channels 13, 14 (see Fig. 2). Inside the ventilation channel 13, using the installed wedge-shaped shield 15, the air flow is divided into two, one of which blows the harvested mass when leaving the shaking board 4 to an additional sieve 1, the second flow blows the lower zone 3 of the additional sieve 1 and the harvested mass when leaving additional sieve 1 on the upper sieve 5 (see Fig. 1). Inside the ventilation duct 14, using the installed wedge-shaped shield 16, the air flow is divided into two, one of which blows the mass to be removed as it leaves the additional sieve 1 to the upper sieve 5, and the other stream blows the lower sieve 1 in the lower zone 9 (see Fig. . one). The shape of the wedge-shaped shields 15, 16 provides a uniform direction of air flow without compromising efficiency in the passage of the harvested mass due to the base 17, which prevents air flows from reaching the end walls 2, 6, 8 of the additional, upper and lower sieves, which can serve as an obstacle.

The technical result consists in providing a more favorable blowing of the sieves with obtaining high separation efficiency along the entire length of the sieves and in reducing the cost of the device.

Claims (3)

1. The fan of the cleaning system, containing several radial impellers located on a common shaft, rotating in the fan casing, each of which sucks air in a direction parallel to the axis of rotation of the shaft, and pumps it into two ventilation ducts, one ventilation duct is tangent to the direction of movement the blades and ensures the movement of air flow along the arcuate line to the additional sieve of the shaking board, the second ventilation channel is located tangentially to the direction of movement of the blades and has straight sections of the channel above and below, ensuring the flow of air to the upper and lower screens of the combine, while in the inlet part both ventilation channels are equipped with a metal sheet having cutouts in the form of concavity at the edges, characterized in that two wedge-shaped shields are inserted into it, which, in the process, divide the air flow from each impeller into four uniform air flows directed to the lower and upper parts of the additional sieve of the shaker board and to the upper and lower sieve. 2. The fan according to claim 1, characterized in that the wedge-shaped shields are installed in the ventilation ducts. 3. The fan according to claim 1, characterized in that the shaft is made of a hexagonal metal rod, and the impellers are mounted on it with clamping clamps.

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