RU2277979C2 - Stone separating machine for grain cleaning - Google Patents

Abstract

FIELD: grain cleaning equipment, in particular, stone separating machines with recirculation of main air flow, may be used in milling and groats producing industry for cleaning of grain from mineral mixture.

SUBSTANCE: stone separating machine has housing incorporating working deck, sucking collector located in upper part of housing and pressure collector located in lower part of housing, feeding and distributing apparatus, motor-vibrators for imparting vibrations to housing, and air recirculation system. Recirculation system consists of settling device for carried-away material, radial fan, and sluice gate for discharging of carried-away material, and is connected to housing upper and lower parts through air ducts. Settling device for carried-away material is made in the form of spiral settler with inlet and outlet branch pipes, settler horizontal branch pipe and cylindrical baffle-type grid, with horizontal branch pipe and baffle-type grid being arranged within settler. Inlet branch pipe of settler is connected to sucking collector of housing of stone separating machine. External branch pipe of settler is connected to sucking opening of radial fan, in axially aligned relation to baffle-type grid. Horizontal cyclone is connected to spiral settler via single horizontal slit. Horizontal cyclone consists of external housing and internal branch pipe. Cyclone internal branch pipe is connected via air duct to horizontal branch pipe of settler. External housing of cyclone is choked at the side adjoining air duct and is equipped with spiral arranged at opposite side and connected through gravity-flow pipeline with slice gate. Throttling device arranged within spiral of horizontal cyclone is made in the form of cone movable axially of horizontal cyclone for allowing slot between cone and internal branch pipe of cyclone to be adjusted. Pressure collector is equipped with air distributing rotating gates.

EFFECT: stabilized operation of stone separating machine with recirculation air flow owing to increased efficiency in catching of light admixtures within settling device for carried-away materials to thereby increase efficiency in separating of mineral admixtures.

3 cl, 2 dwg

Description

The invention relates to a device for cleaning grain, namely to stone separation machines with recirculation of the main air flow, and can be used in the milling and cereal industry for cleaning grain from mineral impurities.

Known stone separation machine for cleaning grain from impurities, including a housing with a working deck located in it, with a suction collector in its upper part and a discharge collector in the lower part, mounted on vibration mounts mounted on the bed, a receiving and distribution device, motor-vibrators to provide housing vibrations, a recirculation air system consisting of a deposition device, a radial fan, a lock gate for outputting the relays and connected to the housing in the upper and lower its part of the duct. [1]

The disadvantage of the recirculation air system of this stone separation machine is the use of a centrifugal gravity-type precipitating device, which does not have a high efficiency in the separation of light impurities. The unallocated part of light impurities is captured by the air stream leaving the sedimentation device, passes through a radial fan and a discharge manifold, together with the air enters under the working deck, is delayed by it, clogging the metal mesh. At the same time, the air permeability of the deck decreases, its resistance increases and, as a result, the technological mode of the stone separation machine is violated and the efficiency of the separation of mineral impurities is reduced. Thus, the stability of the stone separation machine is violated, which requires frequent stopping of the machine to clean the deck.

A sedimentation device [2] is also known, consisting of a spiral precipitator with an integrated cylindrical louvre grille and a cyclone associated with it. Such a sedimentation device, called a Van Tangeren cyclone, has a higher capture efficiency of light impurities than a centrifugal-gravity type precipitation device due to the concentration of impurities on the inner surface of the spiral precipitator and their subsequent capture in a centrifugal cyclone. However, the vertical arrangement of the axes of the spiral precipitator, the cylindrical louvre grille and the cyclone does not allow for a rational arrangement of this deposition device and stone separation working body.

In the Walter brochure [3], a van-Tangeren-type cyclone precipitating device has a horizontal arrangement of the axes of a spiral precipitator, a cylindrical louvre grille and a cyclone.

The described known sedimentation devices separately can improve the separation of light impurities. However, we did not find a combination of the indicated features of the precipitating devices in stone separation machines; therefore, we took the design [1] as the prototype with the largest number of similar features.

The objective of the invention is to achieve more stable operation of the stone separation machine with recirculation of the air flow and, as a result, a higher efficiency of the allocation of mineral impurities.

The problem is solved in that in a stone separating machine, comprising a housing with a working deck located in it, with a suction manifold in its upper part and a discharge manifold in the lower part, mounted on vibration mounts, a receiving and distributing device, motor-vibrators to ensure vibrations of the housing; recirculation air system, consisting of a deposition device, a radial fan, a lock gate for outputting the relays and connected to the housing in its upper and lower parts by air ducts, the deposition device is made in the form of a spiral precipitator with inlet and outlet nozzles and a horizontal nozzle and a cylindrical louvre located inside it grill, and the inlet pipe of the precipitator is connected to the intake manifold of the stone separation machine body, and the outlet pipe is connected is connected with the suction inlet of the radial fan coaxially with the louvre grille, while a horizontal cyclone is connected to the spiral precipitator by means of a common horizontal slit, consisting of an outer casing and an inner nozzle, the inner cyclone nozzle being connected to the horizontal precipitator nozzle by an air duct, and the outer cyclone casing closed off the side of the duct and is equipped with a spiral scroll located on the opposite side, connected through a gravity pipe with a lock gate m. Inside the spiral scroll of the horizontal cyclone there is a throttling device in the form of a cone that moves along the axis of the horizontal cyclone, which makes it possible to regulate the gap between the cone and the inner pipe of the cyclone. The discharge manifold is equipped with air distribution rotary dampers.

A comparative analysis of the described machine with the prototype shows that it is characterized by the presence of additional structural elements and their interconnection, namely, the deposition device is made in the form of a spiral precipitator with inlet and outlet nozzles and a horizontal precipitator nozzle and a cylindrical louvre located inside it, with the precipitator inlet connected to the intake manifold of the stone separation machine body, and the outlet pipe is connected to the suction port radially of the fan is coaxial with the louvre grille, while a horizontal cyclone is connected to the spiral precipitator by means of a common horizontal slit, consisting of an outer casing and an inner nozzle, the inner cyclone nozzle being connected to the horizontal precipitator nozzle by the duct, and the outer cyclone casing is muffled from the duct side and provided a spiral snail placed on the opposite side, connected through a gravity pipe with a lock gate.

These differences in the prior art are not found.

Thus, the proposed solution meets the criterion of "novelty."

Consider how each of the distinguishing features identified affects the solution of the task.

The implementation of the deposition device in the form of a spiral precipitator with inlet and outlet nozzles and the location of a horizontal nozzle and a cylindrical louvre grille inside it with the inlet of the precipitator connected to the suction manifold of the stone separating machine, and the outlet to the suction port of the radial fan, allows the spiral precipitator to be used as a centrifugal dust collector in which the particles are pressed against the inner wall of the precipitator by centrifugal force, slide along it, concentrating in the form of a thin layer, then falling into the entrance slit of a horizontal cyclone. Moreover, the horizontal nozzle is placed inside the inlet of the fan so that its end is located in the plane of the side wall of the fan, this allows you to increase the vacuum in the horizontal cyclone, which will increase the air velocity with impurities in the inlet slit of the horizontal cyclone and, as a result, will provide better capture efficiency impurities in it, and the conjugation of a horizontal cyclone with a precipitant by means of a common horizontal slit improves the efficiency of trapping light impurities in osoosazhdayuschem device kamneotdelitelnoy machines and eventually achieve a more stable its work by maintaining a constant air permeability of the deck and to maintain its resistance at a given level.

The combined action of a spiral precipitator and a horizontal cyclone coupled with a slit allows it to more easily capture light impurities, because they are first pressed by centrifugal forces to the inner surface of the spiral precipitator, are concentrated in a thin layer on its surface, and then they enter a horizontal cyclone having a small diameter of the outer casing compared to the precipitator, which increases the centrifugal forces of the particles and contributes to their more efficient capture.

The supply of the outer casing of a horizontal cyclone with a spiral cochlea makes it possible to more effectively ensure the removal of light impurities from the cyclone than in the cyclone of the precipitating device manufactured by Walter [3].

The location inside the spiral scroll of the horizontal cyclone of the throttling device in the form of a cone allows you to set the optimum inlet air velocity in the horizontal slit to ensure high efficiency of trapping light impurities in the horizontal cyclone.

The supply of the discharge manifold with air distribution rotary dampers allows to ensure uniform distribution of air flow over the entire surface of the working deck and thereby increase the efficiency of the separation of mineral impurities from grain.

The drawings schematically depict a General view of the proposed stone separation machine for cleaning grain, figure 1 is a frontal projection, figure 2 is the same, profile projection.

The stone separation machine comprises a housing 1 with a working deck 2 located in it, with a suction manifold 3 in its upper part and a discharge manifold 4 in its lower part, mounted on vibration mounts 5 mounted on a bed 6. A receiving and distributing device 7 is also fixed on the housing, two motor vibrators 8, sealing valves 9 and 10, and a recirculation air system 11. The recirculation air system 11 includes a deposition device 12, a radial fan 13, and an air duct 14.

The relative sedimentation device 12, which is part of the recirculation air system 11, includes a spiral precipitator 15 with an inlet pipe 16 and an outlet pipe 17, as well as a cylindrical louvre grille 18 integrated into the spiral precipitator, and a horizontal cyclone 20 connected with it via a common horizontal slot 19. The outlet pipe 17 of the spiral precipitator 15 is located coaxially with the cylindrical louvre grille 18. The inlet pipe 16 is provided with a rotary damper 21. Inside the spiral precipitator 15, its cylinders are coaxial horizontal louvre 18 placed horizontal pipe 22.

The horizontal cyclone 20 consists of an outer casing 23 and an inner pipe 24 connected at one end by means of an air duct 25 to a horizontal pipe 22. The outer casing 23 is muffled from the side of the air duct 25 and has a spiral scroll 26 with a throttling device 27 located inside it, made in the form of a cone. A gravity pipe 28 with a lock gate 29 is connected to the spiral scroll 26. In the discharge manifold 4, air distribution rotary shutters 30 are installed.

The recirculation air system 11 by the inlet pipe 16 of the spiral precipitator 15 is connected to the casing 1 of the stone separation machine in its upper part and by the air duct 14 to the discharge manifold 4 in the lower part. The radial fan 13 with a suction port is connected to the outlet pipe 17 of the spiral precipitator 15, and a discharge port with an air duct 14. The duct 14 is connected to the discharge manifold 4 of the stone separation machine. On the duct 14 there is an aspiration pipe 31.

Stone separation machine operates as follows.

The initial mixture, unrefined grain, through the receiving and distributing device 7 enters the working deck 2, where under the influence of air flow and deck vibrations, the mixture is divided into the purified product and mineral impurities, which are discharged outward through the sealing valves 9 and 10, respectively. through the working deck and containing aspirated extracts extracted from grain, through the intake manifold 3 and the inlet pipe 16 it enters the spiral precipitator 15. Using the rotary damper 21, the air th mode in the stone separation machine. In a spiral precipitator 15, air permeates the cylindrical louvre grille 18, which provides greater uniformity in the distribution of air flow when moving it to the center of the precipitator. Under the action of centrifugal force, the particles of aspiration are pressed against the curved wall of the spiral precipitator and slide along it, falling into the horizontal slit 19 of the horizontal cyclone 20. Here, the air flow acquires movement with a general tendency to move to the free end of the inner pipe of the horizontal cyclone. Further, due to a sudden change in the direction of movement of the air flow, which goes into the inner pipe 24 of the horizontal cyclone 20, and the aerodetachable particles under the influence of inertia fall into the spiral scroll 26, in which under the influence of inertial and gravitational forces the particles of the impurity are separated from the air. The optimum inlet air velocity inside the horizontal cyclone 20 is established using a throttling device 27 moving along the axis of the horizontal cyclone by adjusting the gap between the cone 27 and the inner pipe 24. Separated particles are discharged through a gravity pipe 28 through the lock gate 29. The cleaned air through the internal pipe 24 of the horizontal cyclone 20 and the duct 25 is sucked into the horizontal pipe 22, then connected at the exit from it with the main air stream passing sew through the cylindrical louvre grille 18, and through the outlet pipe of the precipitator 17 enters the radial fan 13. After the fan, the cleaned air through the duct 14 enters the discharge manifold 4 and, having passed the working deck 2 of the stone separation machine, completes its cycle in this way. Using air distribution rotary shutters 30 provide uniform distribution of air flow under the working deck. Part of the air is taken into the suction network through the suction pipe 31 to update part of the air flow circulating inside the stone separation machine.

The implementation of the recirculation air system described above allows to achieve a more stable operation of the stone separation machine with recirculation of the air flow by increasing the efficiency of trapping light impurities in the sedimentation device, which allows to achieve higher efficiency of the separation of mineral impurities.

Information sources

1. Equipment for the production of flour and cereals: Reference book / Comp. Demsky A.B., Boriskin M.A., Veden'ev V.F., Tamarov E.V., Chernolikhov A.S. - St. Petersburg, Publishing House "Profession", 2000, p. 158-160, Fig. 78.

2. Pirumov A.I. Aerodynamic basis of inertial separation. - M .: State publishing house of literature on construction, architecture and building materials, 1961, pp. 106-107, Fig. 55.

3. Walter company prospectus.

Claims (3)

1. Stone separation machine for cleaning grain, comprising a housing with a working deck located in it, with a suction collector in its upper part and a discharge collector in its lower part, mounted on vibration mounts, a receiving and distributing device, motor-vibrators to provide oscillations of the housing, air recirculation a system consisting of a deposition device, a radial fan, a lock gate for outputting the relays and connected to the housing in its upper and lower parts by air ducts, characterized in that the deposition device is made in the form of a spiral precipitator with an inlet and an outlet nozzle and a horizontal nozzle and a cylindrical louvre grill located inside it, the inlet of the precipitator connected to the suction manifold of the stone separation machine body, and the outlet nozzle connected to the suction port of the radial fan coaxially with the louvre grille, in this case, a horizontal cyclone consisting of outward casing and the inner pipe, the inner pipe of the cyclone through the duct connected to the horizontal pipe of the precipitator, and the outer casing of the cyclone is muffled from the side of the duct and is equipped with a spiral scroll located on the opposite side, connected through a gravity pipe with a lock gate. 2. Stone separation machine for cleaning grain according to claim 1, characterized in that inside the spiral scroll of a horizontal cyclone there is a throttling device in the form of a cone that moves along the axis of the horizontal cyclone, which allows you to adjust the gap between the cone and the inner nozzle of the cyclone. 3. Stone separation machine for cleaning grain according to claim 1, characterized in that the discharge manifold is equipped with air distribution rotary dampers.

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