RU2366518C2 - Double aspiration system of multipurpose grain cleaning machine - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: double aspiration system of multipurpose grain cleaning machine includes pneumatic separation channels of first and second aspiration, two settling chambers connected to pneumatic separation channels, transverse fan with air outlet channel, and devices feeding grain heap to pneumatic separation channels and discharging settled components from settling chambers. Flow dividing valve in the form of vane rotating around a joint is installed at the border of air intake zone of transverse fan from settling chambers. Transverse fan can change rotor rotation frequency by frequency converter, and top part of internal wall of pneumatic separation channel conjugated with settling chamber can rotate around a joint mounted in conjugation point of pneumatic separation channel with settling chamber.

EFFECT: enhanced efficiency of grain heap separation, reduced power cost of transverse fan rotor.

1 dwg

Description

The invention relates to machines for separating grain heaps by aerodynamic properties and may find application in agricultural production and grain processing industry.

Air purifications with two successively installed systems have become widespread, the first of which emits lightweight non-cereal impurities from the grain heap and the second - punctured, crushed and biologically defective grains, as well as difficult to separate weeds. The most promising of them are open aspiration systems, which do not contribute to dust saturation of injured grains, the content of which in the grain heap reaches 60 ... 80% after harvesting.

Known aspiration system of a grain cleaning machine (RF patent No. 20033385), including two pneumatic separation channels equipped with mechanisms for controlling the air flow rate and overlapping of each of the sedimentary chambers, a diametrical fan with an air exhaust channel, devices for introducing the grain mixture into the pneumatic separating channels and withdrawing the separated components from the sedimentary cameras.

The disadvantage of this aspiration system is that the throttle valves for regulating the air flow rate in the pneumatic separation channels create additional resistance and lead to an increase in the energy consumption consumed for the operation of the aspiration system, and at the same time, independent regulation of the air flow velocity in the pneumatic separation channels.

In the considered technical solution, when the separation wall is turned in one direction or another, one of the suction systems will not work.

Also known is an aspiration system (RF patent No. 2298441), including pneumatic separating channels of the first and second aspiration with air intake windows located above the aspiration zone and communicating with atmospheric air with a mechanism for controlling their opening, two sedimentary chambers with a stationary dividing wall located between them , a diametrical fan with an air outlet channel, while the diametrical fan is configured to change the rotational speed of its rotor. The presence of air intake windows with a mechanism for opening them, located above the suction zones, provides independent control of the air flow rate in the air separation channels, but at the same time, air intake from the atmosphere leads to an increase in energy consumption for driving the fan rotor.

The technical result from the use of the proposed two-aspiration system of a universal grain cleaning machine - reducing energy costs for driving a fan rotor - is achieved due to the fact that a flow divider is installed at the border of the air intake zones from the sedimentary chambers, made in the form of a blade fixed with the possibility of rotation around the hinge, while the diametrical fan is configured to change the rotational speed of its rotor using a frequency converter, and the upper part It is the inner wall of the second channel pneumoseparating conjugate to sediment chamber is pivotable about a pivot located at the junction pneumoseparating channel and settling vessel.

By changing the position of the flow divider, the necessary ratio of the air flow rates in the channels of the first and second aspiration is provided for preliminary, primary and secondary cleaning of the grain heap. The desired value of the air flow rate when processing grain heaps of a particular crop is set by changing the frequency of rotation of the fan rotor using a frequency converter.

The drawing shows a diagram of a two-aspiration system of a universal grain cleaning machine.

The two-aspiration system of a universal grain cleaning machine includes pneumatic separation channels of the first 1 and second 2 aspiration, two sedimentation chambers 3 and 4, in communication with pneumatic separation channels 1 and 2, the upper part of the inner wall 5 of the second pneumatic separation channel 2, paired with the sedimentation chamber 4 and made movable with the possibility rotation around the hinge 6, the air flow divider 7, made in the form of a blade fixed with the possibility of rotation around the hinge 8, a diametrical fan 9 with an air outlet channel 10 , devices 11 and 12 for introducing a grain of heap into the pneumatic separating channels 1 and 2, as well as 13 and 14 for withdrawing settled components from sedimentary chambers 3 and 4.

Two-aspiration system of a universal grain cleaning machine operates as follows. The grain heap is fed into the feed device 11 and moves through it to the pneumatic separating channel 1, where lightweight impurities are taken from it by an air flow sucked in by the diametrical fan 9 and taken out to the sedimentation chamber 3. There they are deposited and removed from the machine by the device 13 (output I) . Purified from the main part of light impurities, grain heap (yield II) enters the sieve mill (not shown), where it is cleaned on sieves of large and small impurities. The cleaned part of the grain heap is fed into the feed device 12 and moves through it to the air separation channel 2. The air flow rate in the air separation channel 2 should be such that, during preliminary cleaning, only light particles that were not isolated in the first aspiration were carried out into the sedimentation chamber 4. When pre-cleaning the grain heap, the divider 7 is set to a position close to horizontal, i.e. in the direction of movement of the air flow during its intake by the diametrical fan 9 from the sedimentary chamber 4. In this case, an open channel is obtained under the diametrical fan, i.e. sedimentary chambers 3 and 4 communicate with each other. This leads to an equalization of the air flow velocities in the air separation channels 1 and 2. In the primary cleaning of a grain pile (processing of commercial grain), the air flow velocity in the air separation channel 2 should be such that in the sedimentation chamber 4 along with lightweight impurities not separated in the air separation channel 1, punctured grain was also carried out. In this case, the divider 7 is set in such a position as to obtain the desired ratio of speeds in the pneumatic separating channels 1 and 2.

In the secondary treatment of grain heap (seed treatment), the air flow rate in the air separation channel 2 should be such that, along with lightweight impurities not separated in the air separation channel 1, biologically defective as well as part of the injured grain and hard to separate weeds. In this embodiment, together with the components carried into the sedimentation chamber 4, full grains can also fall, which settle on the inclined part of the inner wall 5, where the air flow velocity decreases, and, sliding along it, return to the air separation channel 2. At the same time, the probability of the removal of full grains grains into the sedimentation chamber 4. In the secondary treatment of the grain heap, the divider 7 is installed in a vertical position, i.e. There is no communication between sedimentary chambers. In this case, the ratio of air flow rates in the air separation channels 1 and 2 of the suction will be maximum. The location of the hinge 8 should be selected so that when it is located vertically, it is possible to obtain the air flow velocity in the air separation channel 2, which is necessary for the isolation of biologically defective and crushed grain.

With the selected ratio of air flow velocities in the pneumatic separating channels of the first 1 and second 2 aspirations, the desired speed value when processing a grain pile of a particular crop is established by changing the fan speed using a frequency converter.

The components carried out by the air flow in the air separation channel 2 of the second aspiration are deposited in the sedimentation chamber 4 and the device 14 is removed from the machine (exit III), and the cleaned grain enters through the air separation channel 2 into the clean grain hopper (exit IV).

The proposed two-aspiration system of a universal grain cleaning machine has less resistance to the movement of air flow and eliminates the need for air intake from the atmosphere to establish the necessary air flow rates in the pneumatic separation channels, which reduces the power required to drive the rotor of the diametrical fan by 30%.

Claims (1)

Two-aspiration system of a universal grain-cleaning machine, including pneumatic separation channels of the first and second aspiration, two sedimentation chambers in communication with pneumatic separation channels, a diametrical fan with an air exhaust channel, and also devices for introducing grain heaps into pneumatic separation channels and withdrawing settled components from sedimentation chambers, characterized in that at the boundary of the zones of air intake, a flow divider installed in the form of a fixed fan the possibility of rotation around the hinge of the blade, while the diametrical fan is made with the possibility of changing the frequency of rotation of its rotor using a frequency converter, and the upper part of the inner wall of the second pneumatic separating channel, paired with the sedimentary chamber, is movable with the possibility of rotation around the hinge located at the interface of the pneumatic separating channel and sedimentary chamber.

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