RU2156557C1 - Machine for dewinging and separating forest crop seeds from fruit-beans - Google Patents

Abstract

FIELD: forest crop growing. SUBSTANCE: machine has frame 1 carrying housing 2 incorporating feeding hopper 5 made in the form of truncated cone and oriented with its small base to seed charging zone. Feeding hopper 5 is equipped with shaft 7 carrying auger-type feeder 6. Dewinging device 8 disposed in housing 2 has construction similar to that of feeding hopper 5 and turned 180 deg relative to it. Dewinging device 8 is equipped with brush drum 9. Sickle-shaped knives 10 are arranged in helical line on shaft 7 of auger-type feeder 6 in seed feeding zone for engagement with cutting grid 11 fastened under knives. Part of auger-type feeder 6 adjoining knives 10 is made in the form of hollow truncated cone 12 extending in parallel with wall of feeding hopper 5. Screws 13,14 are mounted on outer and inner surfaces of cone 12. Screw 13 mounted on outer surface of hollow truncated cone 12 has coil direction opposite to that of other members of auger-type feeder 6. EFFECT: increased efficiency and simplified construction. 4 dwg

Description

 SUBSTANCE: invention relates to axial-type forest seed cleaning machines, in particular, to machines for dehumidifying seeds of pine, maple, elm and for extracting seeds from bean fruits of gledichia, white and yellow acacia, Amuria maakia and other forest seeds.

 The well-known OVLS-2 machine for deconsolidation of seeds of coniferous and deciduous species and the separation of seeds from bean fruits, consisting of a frame, a loading bucket, a buster, a fan, a sieve fan mill and a transmission system. The machine’s baiter consists of two hollow drums inserted one into the other and having the shape of truncated cones (see the book. Abiants Kh.G., Malov V.F. Collection, processing and storage of seeds of tree and shrub species. M .: Goslestekhizdat, 1940 , p. 88-89).

 The disadvantage of the machine is the inability to control the speed of movement of seeds on the working surface of the buster, which leads to the need to pass seeds and fruit beans through the buster several times for their effective processing. In addition, the location of the smaller base of the cone bouncer in the area of the outlet of the seeds leads to clogging. The machine has low productivity and does not provide high-quality selection of seeds from fruit beans.

Closest to the proposed design in technical essence is a machine for dehumidification and extraction of forest seeds from bean fruits, including a frame, a loading hopper with a wire auger feeder and a baiter with a brush drum. The loading hopper and the bailer are made in the form of identical truncated cones, rotated 180 ^o relative to each other. The machine is equipped with a device for air and screen cleaning (SU, copyright certificate, 967399, class A 01 G 23/00, 1980).

 The disadvantage of this machine is the low quality of separation of hardwood seed lionfish and the destruction of bean leaf flaps during seed processing, because the design of the screw feeder of the hopper does not provide sufficient efficiency for the preliminary destruction of hardwood seed larvae and leaf flaps. Therefore, large fractions of the seed mass and part of the seeds located in the undestroyed flaps of the bean fruit fall into the baits of the machine, along with large impurities, are evacuated to the waste through the unloading window. To increase the efficiency of the processing of seeds and fruit-beans, they must be passed through a dehumidifier several times, which sharply reduces the productivity of the machine. In addition, large fractions and undamaged flaps of bean fruits often clog the transition window, through which the seed mass is fed from the loading hopper to the dehumidifier, which also reduces the performance of the machine.

 The purpose of the invention is to increase the productivity and efficiency of dehumidification and the selection of seeds from bean fruits.

This goal is achieved by the fact that in the known machine for dehumidification and isolation of forest seeds from bean fruits, which includes a frame on which a housing is mounted with a loading hopper in it in the form of a truncated cone, facing a smaller base into the seed loading zone, on the shaft of which is mounted screw feeder, and identical to the feed hopper in the form, rotated 180 ^o relative to it with a broom with a brush drum, on the shaft of the screw feeder in the seed loading zone there are sickle-shaped knives placed f along a helical line, interacting with a knife grate fixed above them, and the part of the screw feeder adjacent to the knives is made in the form of a hollow truncated cone parallel to the walls of the loading hopper, with screw screws on the outer and inner surfaces, while the screw auger located on the outer surface of the hollow truncated cone, has the opposite direction of winding relative to the remaining elements of the screw feeder.

 In FIG. 1 shows a machine for dehumidification and isolation of forest seeds from bean fruits, general view; in FIG. 2 is a view A in FIG. 1; in FIG. 3 is a section BB in FIG. 2; in FIG. 4 - screw feeder loading hopper in a perspective view.

The machine contains a frame 1, on which all nodes are mounted. In the housing 2, mounted on the frame 1 using the axis 3 and the holder 4 with a latch, a loading hopper 5 with a screw feeder 6 mounted on the shaft 7 and a deflector 8 with a brush drum 9 are fixed. The loading hopper 5 and the deflector 8 are made in the form of identical in the form of truncated cones and deployed relative to each other by 180 ^o . The smaller base of the feed hopper 5 faces the feed zone of the seed. In the feed zone of the seed mass on the shaft 7 of the screw feeder 6 are installed along the helix sickle-shaped knives 10, interacting with the knife grate 11 fixed under them in the loading hopper 5. The part of the screw feeder 6 adjacent to the knives 10 is made in the form of a hollow truncated cone 12, parallel to the walls of the feed hopper 5, on the outer surface of which there is a screw auger 13, and on the inside - a screw auger 14. The rest of the screw feeder is made in the form of a wire auger 15 with brushes. The screw auger 13, located on the outer surface of the hollow truncated cone 12, has an opposite winding direction relative to the direction of the helix along which the sickle blades 10 are mounted, the direction of winding of the screw auger 14, located on the inner surface of the hollow truncated cone 12, and the direction of winding of the wire screw 15 with brushes. The walls of the loading hopper 5 above the horizontal axial plane are provided with radially mounted pins 16. The seed mass is supplied from the loading hopper 5 to the buster 8 through the window 17, and large impurities and destroyed flaps of the fruit beans are evacuated through the unloading window 18. Seeds and impurities separated through the mesh bottom of the brooms 8, they are discharged along the tray 19 to an air-sieve device that provides cleaning and sorting of seeds and consisting of a fan 20, a vertical aspiration channel 21 and deleterious mill 22 with a set of different sieves 23. The machine is driven by a motor 24 through a V-belt drive 25.

 The machine operates as follows.

 When the motor 24 is turned on, the rotation through the V-belt drive 25 is transmitted to the shaft 7 of the screw feeder 6 and the brush drum 9 of the deflector 8. The seed mass located in the loading hopper 5, with the screw screw 13 located on the outer surface of the hollow truncated cone 12, moves to the smaller base of the loading the hopper 5 into the installation zone of the sickle-shaped knives 10. Using the sickle-shaped knives 10 and the knife grate 11, the seed mass is crushed and mixed, which is then screw auger 14, placed on the inner th surface of the hollow truncated cone 12, is moved to a larger base of the discharge hopper 5 and falls on the screw 15 with wire brushes. With a wire auger 15 with brushes, the crushed seed mass moves along the loading hopper 5, with the additional destruction of the bean fruit flaps against the pins 16. The part of the seed mass received by the wire auger 15 with brushes, a screw auger 13 placed on the outer surface of the hollow truncated cone 12, returns again to the smaller base of the loading hopper 5 in the installation zone of the sickle-shaped knives 10, where it is crushed again. Through the window 17, the pre-processed seed mass enters the baiter 8, where it is carried away in a helical movement by the brush drum 9. Due to friction, shock and inertial forces, the seeds are finally separated from the lionfish and the crushed cusps of the fruit-beans and together with small impurities pass through the mesh bottom of the bailer 8 and enter the tray 19 into the device for air and sieve cleaning. In the vertical suction channel 21, the seeds are separated from light impurities and sorted into several fractions using sieves 23. Large impurities and broken flaps of the fruit-beans are taken through a special window 18 to the waste collection container (not shown).

 The machine ensures the continuity of the technological process of processing almost all types of forest seeds and the high efficiency of the process of separating seeds from fruit beans, the productivity of this machine exceeds the productivity of the known machines by 1.2-1.4 times.

Claims (1)

A machine for exsanguination and isolation of forest seeds from bean fruits, including a frame on which a housing is mounted with a loading hopper in the form of a truncated cone, facing a smaller base into the seed loading zone, on whose shaft a screw feeder is mounted, and identical to the loading hopper in form unfolded with respect thereto at 180 ^o obeskrylivatelem with brush drum, characterized in that the shaft of the screw feeder in the loading zone seed set sickle knives arranged along a helical line, inter They operate with a knife grate fixed above them, and the part of the screw feeder adjacent to the knives is made in the form of a hollow truncated cone parallel to the walls of the loading hopper, with screw screws on the outer and inner surfaces, while a screw auger located on the outer surface of the hollow truncated cone , has the opposite direction of winding relative to the remaining elements of the screw feeder.

Images