JP2000202364A - Three-stage sorter of grain or the like - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a three-stage sorter capable of continuously and efficiently sorting grain such as rice grain or the like into three stages, that is, grain having a relatively large size, grain having a slightly small medium size and other crushed grain to treat respective grains smoothly. SOLUTION: A grain lifter B equipped with a grain lifting cylindrical body 3 having two supply hoppers 4, 5 at the lower portion thereof and communicating with a storage tank 6 and a discharge piping 35 at the upper portion thereof through a branch pipe 32 having a flow passage changeover plate is used, and first and second vertical sorters A, C constituted so that the sorting net body and the grain lifting spiral body arranged in sorting shell bodies 53, 53x concentrically are relatively rotated to sort grain into whole grain having a desired grain size or more and screanings having a desired grain size or less during the lifting of grain not only to store whole grain in storage tanks 54, 54x but also to discharge screenings to the outside through discharge chutes 73, 73x are connected to continuously and efficiently sort charged grain into three stages.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to three stages of grains such as rice grains, which are classified into three stages, such as relatively large grains, rather small grains, and immature grains according to the grain size. The present invention relates to a three-stage sorter for sorting grains and processing each grain.

[0002]

2. Description of the Related Art As a grain sorter for sorting grains such as rice grains into sized and immature grains according to the particle size, FIG.
2. Description of the Related Art A vertical sorter as shown in FIG.

[0003] This type of vertical sorter has a sorter net 112 formed in a cylindrical shape by drilling a large number of sorter holes in a peripheral wall, and a hoisting spiral body 113 provided inside the sorter net 112. Are set up inside the shell 103 so as to be rotatable, and the sorting net 112 and the helix spiral 113 are relatively rotated in the opposite directions by the driving source 111, and are supplied from the hopper 105. The kernels are lifted upward by the relative rotation of the sorting net 112 and the helix helix 113, and the grains having a diameter smaller than the sorting hole of the sorting net 112 are sorted as scraps such as immature grains. Released outward from 112,
Grains having a particle size that cannot pass through the sorting holes are fried as sized. Then, the sized particles are discharged to the storage tank 104 side by the scraping blades 114 and stored in the storage tank 104, and the dust particles released from the selection holes of the selection net 112 are
It is configured to drop in the gap between the shell 103 and the outer peripheral surface of the sorting net 112, stay on the lower partition plate 115, and then be discharged from the discharge chute 106 by the scraping blades 116 to the outside of the machine. ing.

[0004] In such a conventional vertical sorter, the sized granules sorted by the relative rotation of the sorting net 112 and the helix spiraling body 113 and stored in the storage tank 104 are placed below a discharge port 104 a of the storage tank 104. Scale 10 installed
9 is used for weighing bags. On the other hand, debris such as small grains and immature grains having a smaller particle size than the sorting hole of the sorting net 112 is discharged from the outlet chute 106 and stored in an appropriate bag or container disposed below the chute. .

[0005]

By the way, the sorting criterion of the grain such as rice cereal is set according to the quality, grade or use, etc. The sorting criterion of the grain in the vertical sorter is a sorting net. Is determined by the mesh size (mesh width) of the sorting hole of (1). In order to increase the quality and commercial value of the grain, the size of the meshes (mesh width) of the sorting holes may be large in order to strictly regulate the size of the grains. In such a case, since the mesh size of the sorting holes of the sorting net is large, a large amount of small grains and debris passing through the sorting holes will be generated. Even small grains that can be used and processed are discharged from the discharge chute together with the crushed grains and debris to the outside of the machine. In such a case, a large amount of small grains and crushed grains discharged from the discharge chute to the outside of the machine are discharged, but in a conventional vertical sorter, these are not measured in an appropriate container. Or simply stored in bags.

[0006] As described above, in order to increase the quality and commercial value of the grain, when a sorting net having a large mesh size of the sorting holes is used, or when a sorting net having a normal mesh size is used, Waste particles including small grains discharged from the sorting hole of the sorting net and discharged from the outlet chute to the outside of the machine,
Again, it is put into a vertical sorter using a sorting net slightly smaller than the sorting net, which is re-divided into small grains and debris although the grains are slightly smaller in diameter than the sized grains. Sorting is also required.

[0007] However, in order to perform the selection twice as described above, it is necessary to exchange the selection nets having different mesh sizes. For example, if the sorting of the grains is performed using a sorting net having a mesh size of 1.85 mm as the sorting hole, the grains having a size of 1.85 mm or more as the sizing (the first opening) and the swarf particles (the second opening) ), The waste particles containing small grains of 1.85 mm or less are sorted out, and the waste particles (2nd mouth) containing small grains of 1.85 mm or less are combined with small grains of 1.70 mm or more, for example. When sorting into crushed particles such as crushed particles of 70 mm or less, a sorted net having a mesh size of 1.85 mm is 1.70.
It was necessary to replace the screen with a screen having a mesh size of mm or the like and re-screen. Thus, when sorting the kernel into three stages of sizing with a relatively large diameter, sizing with a slightly smaller medium diameter, and swarf,
It required two rounds of sorting and replacement of the sorting net, took a long time for the preparation work, and could not continuously and efficiently perform the three-stage sorting work. In addition, scrap rice obtained by normal sorting of rice grains and the like can also be used for various purposes according to the particle size, and the scrap rice is collected and further sorted. It is classified into rice for processing, which is a material for rice crackers and other rice crackers, and rice for miso and beer. In this way, even when performing the three-stage sorting of only the crushed rice of the crushed grain class, it is necessary to exchange the sorting net and to perform the twice sorting, and it is possible to continuously and efficiently perform the three-stage sorting work. could not.

Further, in the conventional vertical sorter, the amount of dust particles and the like discharged from the discharge chute by sorting is usually about 5% to 10% of the supplied grains. In the case of using a sorting net having a large mesh size of the sorting hole or at the time of re-sorting, 50% or more will be discharged as swarf particles, and in the conventional vertical sorter,
The above requirements could not be sufficiently satisfied, for example, a large amount of waste particles including small grains could not be discharged smoothly.

Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and is intended to convert a grain such as rice grain into a relatively large grain and a slightly smaller medium grain according to the grain size. It is an object of the present invention to provide a three-stage sorter for kernels and the like that can continuously and efficiently sort the kernels into three stages such as kernels and other waste particles, and can smoothly process each kernel. Things.

[0010]

In order to achieve the above-mentioned object, a three-stage sorter for grain and the like according to the present invention has a hopper for feeding grain at the bottom and a sorting shell having a storage tank at the top. Body, and a sorting net and a fried spiral are rotatably arranged concentrically in the sorting shell, and the grains supplied from the hopper are rotated by relatively rotating the sorting net and the fried spiral. During the graining, each is sorted into sized particles having a desired particle size or more and debris having a desired particle size or less, and the sized particles are stored in the storage tank and the debris and the like are discharged through a discharge chute. A first and a second vertical sorter configured to be discharged outside the machine, and a storage tank via a branch pipe having two supply hoppers below and a flow path switching plate above. A discharge cylinder connected to the discharge pipe; A fryer provided with frying means for frying, wherein the discharge pipe of the fryer is associated with the hopper of the second vertical sorter, and the discharge pipe of the first vertical sorter is Associating the outlet chute and the outlet of the storage tank with one of the two supply hoppers of the graining machine so that they can be selectively communicated with each other via a connecting pipe or the like; A vertical sorter and a second vertical sorter are connected and arranged via the grain-lifting machine.

In the three-stage sorter for grain and the like of the present invention,
The discharge chute of the first vertical sorter is associated with one of the feed hoppers of the fryer, and the flow passage switching plate of the branch pipe of the fryer is switched to set the fryer cylinder to the By communicating with the discharge pipe, the first vertical sorter sorts into a sizing particle having a desired particle size or more corresponding to a sorting hole of the sorting net and a swarf particle having a desired particle size or less, etc. The sieved granules are stored in the storage tank and the debris and the like are supplied to the fryer through the discharge chute, and the debris and the like are fried by the fryer from the discharge pipe. It can be supplied to the hopper of the second vertical sorter, and the second vertical sorter can further sort the waste particles and the like, and can sort the grains into three stages. In the three-stage sorter for grain and the like according to the present invention, the storage tank of the first vertical sorter is used. The discharge port is connected to the other supply hopper of the fryer via a connecting pipe, and the flow path switching plate of the branch pipe of the fryer is switched to connect the fryer cylinder to the discharge pipe. Thereby, in the first vertical type sorting machine, the sized granules having a desired particle size or more selected in correspondence with the sorting holes of the sorting net body through the storage tank to the other supply hopper of the graining machine. To the hopper of the second vertical sorter from the discharge pipe, and the sized by the second vertical sorter. Can be further sorted to sort the grain into three stages.

In the three-stage sorter for grains and the like of the present invention,
The first and / or second vertical sorter includes an exhaust chamber having a suction opening opened in a hollow portion of a base on which the sorting shell is erected, and an air in the base from the suction opening. An exhaust fan provided in the exhaust chamber for sucking and exhausting the air to the outside of the machine, and a dust exhaust duct disposed in the sorting shell and communicating with the exhaust chamber, The mixed foreign matter is sucked through the dust exhaust duct disposed in the sorting shell and discharged to the outside through the exhaust duct connected to the exhaust chamber, and further, during the sorted sizing. It is preferable that a dust discharging means for separating and removing mixed foreign matter is disposed in the storage tank, and further, the first and / or second vertical sorter is configured to remove dust and the like from the discharge chute. It is preferable to add a kara-min for separating and removing mixed foreign substances.

In the three-stage sorter for grain and the like of the present invention,
It is preferable that measuring instruments are respectively installed below the storage tanks of the first vertical sorter, the fryer, and the second vertical sorter.

[0014]

According to the three-stage sorter for grain or the like of the present invention, the storage tank and the discharge pipe are provided via the branch pipe having two supply hoppers facing each other below and a flow path switching plate above. A first and a second vertical sorter equipped with sorting nets each having a different mesh size of the sorting holes, respectively, are connected to each other through a frying machine having a flouring cylinder that communicates with the first vertical type. In the sorting machine, the initial sorting is performed by the relative rotation of the sorting net and the helix spiral, and the grains to be further sorted (including sized grains of a desired grain size or more or small grains of a desired grain size or less). And the like are sent to a graining machine, where the grains are grained and supplied to a second vertical sorter. By the relative rotation of the grain helix, the grain is sorted for the second time, so that the grain is relatively large according to the particle size. Rice grain and rice grains for processing rice crackers such as middle rice and rice crackers, and miso and beer in three stages: medium grain and slightly smaller grain than small grain and large grain Etc. can be continuously and efficiently sorted into three stages of raw rice, etc., and furthermore, the kernels divided into the three stages are separated and removed from the foreign matter mixed in the kernels, and the kernels of each category are separated. Grain can be processed smoothly, for example, by improving the quality and filling the weighing bag appropriately.

[0015]

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram schematically showing a configuration based on one mode of use of a three-stage sorter for grain and the like of the present invention.
FIG. 2 is a configuration diagram schematically illustrating a configuration based on another use mode of the three-stage sorter for grains and the like of the present invention.

In FIG. 1 and FIG. 2, the three-stage sorter for grains and the like of the present invention has a fryer B disposed between a first vertical sorter A and a second vertical sorter C. The first is
The vertical sorter A and the second vertical sorter C are provided with sorting nets each having a different mesh size of the sorting holes, and rice grains or the like supplied from a hopper (55, 55x) disposed below. Are classified into two types in accordance with the particle size, and the selected large-sized particles are fried and stored in a storage tank (54,
54x) and discharges the small-sized grains to the outside of the machine via the outlet chutes (73, 73x). The graining machine B has two feed hoppers facing downward. (4, 5), the grain supplied from any of the supply hoppers (4 or 5) is fried, and is fried through a branch pipe (32) having a flow path switching plate (33). Storing the kernels in the storage tank (6)
5) so that it can be transported outside the machine. In addition, below the storage tanks (54, 54x, 6) provided in the first vertical sorter A, the second vertical sorter C, and the grain-lifting machine B, weighing bags for grain are packed. 1 and 2 show only the scale (9) attached to the graining machine B, and the first and second vertical Mold sorter A,
The scale attached to C is omitted and not shown. ).

That is, in the three-stage sorter for grain or the like of the present invention, the grain to be sorted is first put into the first vertical sorter A. In the first vertical sorter A,
The initial sorting is performed by the relative rotation of the sorting net and the spiraling helix, and the grains to be further sorted (waste grains including large-sized grains or small-sized grains) are fed to the fryer B. The grain is sent to the second grain sorter C and fed to the second vertical sorter C. In the second vertical sorter C, the second rotation of the supplied grains is performed by the relative rotation of the sorting net and the helix spiral, and the grains are continuously sorted in three stages, Each of the grains selected in the three stages can be appropriately packed in a measuring bag.

Hereinafter, each component of the three-stage sorter for grain and the like of the present invention will be sequentially described in detail.

First, first and second vertical sorters A and C
Will be described with reference to FIGS. 5 to 8. The fryer B has a fryer cylinder 3 erected on the machine stand 2 and having a fryer means 20 (see FIG. 6) therein, and a fryer cylinder 3 for supplying grains such as rice grains. A supply hopper 4 attached below the rear wall surface, and a second supply detachably attached to the supply hopper 4 below the front wall surface of the fried cylindrical body 3 to supply grains. Hopper 5,
It comprises a storage tank 6 attached above the front wall surface of the fried cylindrical body 3 for temporarily storing the fried grains, and a measuring device 9 installed below the storage tank 6. A discharge pipe 35 for discharging and transferring the grain that has been fried to another part outside the machine is disposed adjacent to the storage tank 6 above the fried cylinder 3.

As shown in FIGS. 6 and 7, a supply hole 12 is provided below the wall surface of the fry cylinder 3 so as to communicate with the supply hopper 4, and a supply hole is provided below the front wall surface. A supply hole 13 is provided to face the second supply hopper 5 so as to face the second supply hopper 5. Above the front wall surface of the fried cylindrical body 3, a discharge hole 15 for discharging the fried grains is provided. Further, an arc-shaped bottom plate 27 is provided at the bottom of the fried cylindrical body 3, and the supply hole 1 is supplied from the supply hopper 4 or the second supply hopper 5.
2. The grain supplied through the second supply hole 13 is the bottom plate 2
7 is temporarily deposited.

A bucket conveyor 20 as a means for raising the grain is provided in the cylinder 3 and the bucket conveyor 52 is provided on both side walls of the cylinder 3 as shown in FIG. A drive pulley 23 and a driven pulley 24 rotatably supported at lower and upper portions, respectively, and an endless belt 21 stretched between the pulleys 23 and 24.
And a plurality of buckets 22, 22 attached to the endless belt 21 at predetermined intervals. The driving pulley 23 is connected to a driving motor 25 (FIG. 5), and the driven pulley 24 is connected to the endless belt 21. The upper part of the fried cylindrical body 3 is supported so as to be movable in the vertical direction so that the tension of 21 can be adjusted.

The supply hopper 4 is mounted in correspondence with a supply hole 12 (FIGS. 6 and 7) provided below the rear wall surface of the fried cylindrical body 3, and the second supply hopper 5 is provided in FIG. (A)
5, as shown in FIG. 5, it is detachably attached to a second supply hole 13 provided below the front wall surface of the fried cylindrical body 3 so as to face the supply hole 12. The second supply hopper 5 is formed to have substantially the same width as the width of the front wall surface of the fried cylindrical body 3, and the length in the vertical direction is larger than that of the supply hopper 4 in order to increase the capacity of the grains to be received. Are also formed vertically long.

The second supply hopper 5 includes the supply hopper 4
Is not used when the grains are supplied from the container, and the second supply hole 13 is provided with the lid 14 (see FIG. 7A) or the lid 14.
A (see FIG. 7B). The lid 14 illustrated in FIG. 7A is provided so as to be vertically movable along a pin 14 a fixed to the front wall surface of the fried cylindrical body 3, and when the second supply hopper 5 is not used. Then, the second supply hopper 5 is detached from the front wall surface of the fried cylindrical body 3, and the lid 14 is slid downward to close the second supply hole 13. When the grains are supplied from the second supply hopper 5, the lid 14 is slid upward to open the second supply hole 13, and the second supply hopper 5 is mounted. The sliding movement of the lid 14 can be configured to be performed in a state where the second supply hopper 5 is attached to the front wall surface of the fried cylindrical body 3. The other lid 14A shown in FIG. 7B is attached to the front wall surface of the fry cylinder 3 by bolts 14b or the like after removing the second supply hopper 5 from the fry cylinder 3. ,
The second supply hole 13 is configured to be closed.

As shown in FIGS. 5 and 8, the discharge hole 15 provided in the upper part of the front wall surface of the fried cylinder 3 has a downward and lateral direction from the discharge hole 15 (FIG. 8B). (In the figure, leftward direction), an inclined outlet pipe 31 is connected, and a leading end of the inclined outlet pipe 31 is connected to a branch pipe 32 that branches bifurcated downward. One of the first outlets 32a of the forked branch pipe 32 is connected to the storage tank 6 attached to the front wall of the fryer cylinder 3, and the other outlet 32b is connected to the discharge pipe 35. Is done. A flow path switching plate 33 is rotatably supported at the center branch portion of the bifurcated branch pipe 32 so as to be rotatable.
3 is mounted, and by operating this lever 34, the flow path switching plate 33 is rotated so that the grains discharged from the discharge hole 15 of the fried cylindrical body 3 are stored in the storage tank 6. And the discharge pipe 35 can be selectively fed.

As shown in FIG. 5, the storage tank 6 mounted on the front wall surface above the fry cylinder 3
It is for temporarily storing the grains that are fried by the bucket conveyor 20 as the frying means in the inside, and the upper part thereof is communicated with the first outlet 32a of the bifurcated branch pipe 32, A discharge port 7 is provided at a lower end portion.
Is provided with a shutter 7a driven to be opened and closed by a shutter operating member 7b such as a solenoid.

Below the discharge port 7 of the storage tank 6, a measuring device 9 for measuring the weight of the grains stored in the bag is installed, and this measuring device 9 opens and closes the discharge port 7 of the storage tank 6. Operating member 7b for operating shutter 7a
And electrically connected to control means for controlling these,
The shutter operation member 7b is configured to control the operation of the shutter operation member 7b in accordance with the weighing result of the weighing device 9, and the weighing device 9 measures the weight of the grain stored in the bag placed thereon, When the measured value reaches a predetermined value, a signal is sent to the shutter operation member 7b to operate the shutter 7a to close the discharge port 7. The opening and closing operation of the shutter 7a can be manually performed while watching the display on the measuring device 9.

Further, by constructing the discharge port 7 and the shutter 7a provided at the lower end of the storage tank 6 so as to be able to rotate 90 ° with respect to the storage tank 6, the work of filling the weighing bag of the grains can be performed. It is also possible to selectively perform the operation at an appropriate position. In FIG.
Reference numeral 8 is a guide member attached around the discharge port 7 of the storage tank 6 to guide the grains discharged from the discharge port 7 to the bag and to prevent scattering of the grains. The display operation panel includes a switch and a switch for setting a weight to be packed in a weighing bag, and a display for displaying a set value of the weight and a weighing result of the weighing device.

As described above, the grain-lifting machine B uses the bucket conveyor 20 to grain the grains supplied from either the supply hopper 4 or the second supply hopper 5, and Is discharged from the discharge hole 15 of the fried cylindrical body 3 to the branch pipe 32 side, and can be selectively sent to either the storage tank 6 or the discharge pipe 35 by switching the flow path switching plate 33 of the branch pipe 32. It is configured as follows.

Next, the first vertical sorter A will be described with reference to FIGS.

In the first vertical sorter A, the base 51
The upper hollow base 52 is provided with a substantially cylindrical exhaust chamber 57 as shown in FIG.
Are arranged such that the discharge side having the discharge port 57b projects outward from the side wall of the base 52 and the suction side having the suction port 57a is inserted into the hollow portion S of the base 52. An exhaust fan 58 rotatably driven by a motor 60 disposed on the base 51 via a transmission mechanism is rotatably disposed inside the exhaust chamber 57, and the exhaust fan 58 is rotated by the driving of the motor 60. When driven,
From the suction port 57a to the hollow portion S in the hollow portion S of the base 52,
The air in the sorting shell 53 communicating with the
It is configured so that the air can be exhausted from the exhaust duct 56 to the outside of the machine.

The sorting shell 53 erected on the base 52 is
A storage tank 54 is provided on the upper front side, and a hopper 55 is provided on the lower rear side. Inside the sorting shell 53, a cylindrical supply cylinder 66 having an upper surface opened on the top plate 52a of the base 52 is provided. The upper end is fixed to the lower partition plate 53b, and the chute 55a of the hopper 55 communicates with the side wall of the supply cylinder 66. The guide cylinder 67 disposed concentrically in the supply cylinder 66 has a hopper 5 on its outer peripheral surface.
Induction blade 67a for guiding the grain introduced from 5 downward
And a plurality of grain guiding ports are provided at the lower end, and a flange portion 68 provided at an upper peripheral edge is provided.
The bottom plate 67b has a two-output gear motor 6 which is provided with a dust scraping blade 68a projecting upward.
One low-speed rotation shaft 61a is fixed.

The sorting net 62 is integrated with the guide cylinder 67 by engaging a slit (not shown) formed on the lower edge thereof with a scraping blade 68a protruding from the flange 68 of the guide cylinder 67. It is mounted on the flange portion 68 so as to rotate in the direction shown by the arrow. On the outer peripheral surface near the upper end thereof, the upper partition plate 53c of the sorting shell 53 is rotatably mounted via a support shaft so as not to swing. The supported support roller 71 is in contact.

In the sorting net 62 and the guide cylinder 67, a helix spiral 63 having a spiral wing 63a on the outer peripheral surface is provided concentrically, and a bottom plate 63b of the helix spiral 63 is provided.
The high-speed rotation shaft 61b of the two-output gear mo 61 is fixed to the upper surface 63c of the sorting shell 53.
It is fixed to a rotating shaft 72 rotatably supported by 3a. Further, on the outer peripheral surface of the upper end portion of the hulling spiral 63 protruding above the upper partition plate 53c of the sorting shell 53, a plurality of sizing squeezing blades 69 for squirting the sorted sizing to the storage tank 54. Is protruding.

As shown in FIGS. 3 and 4, inside the sorting shell 53, dust exhaust ducts 64 are formed flat on the inner surfaces of the front and left and right side walls so as not to interfere with the sorting net 62. The dust ducts 64 are provided with a gallery 65 at an upper portion of a surface facing the sorting net 62, and the lower end thereof is communicated with the hollow portion S of the base 52. ing. As a result, each of the dust ducts 64 is connected to the exhaust chamber 5 through the hollow portion S of the base 52.
7, the air in the sorting shell 53 is sucked through the respective burrs 65 by the operation of the exhaust fan 58 in the exhaust chamber 57, and the spikes that have passed through the mesh of the sorting net 62 during the sorting of the grains. Foreign matter such as straw waste and dust is sucked from the gallery 65 into the dust discharge duct 64 and is sucked into the exhaust chamber 57 in the base 52.

A storage tank 54 for storing the sorted granules.
As shown in FIG. 3, a discharge port 5 is provided at the upper front part of the sorting shell 53, and discharges the sized granules at the lower part thereof.
4a, and a shutter 77 for opening and closing the discharge port 54a. In addition, storage tank 5
A plurality of dispersion plates 54c, 54c,... For dispersing and dropping the sized particles repelled into the container 4 downward are attached to the side wall of the storage tank 54, and are mixed in the sized particles stored in the storage tank 54. A dust collector 75 for separating foreign matter such as straw waste and dust and discharging the dust to the outside of the apparatus is disposed above the storage tank 54. In addition, instead of the dust collector 75, the inside of the storage tank 54 communicates with the exhaust chamber 57 through a duct, and foreign matters such as straw chips and dust mixed during the sizing are discharged from the exhaust duct 56 by the action of the exhaust fan 58. It can also be discharged outside the machine.

Therefore, the sorting net 62 and the helix 6
The sizing with a large particle diameter, which is grained without being released from the sorting holes (mesh) of the sorting mesh body 62 by the relative rotation of 3, is moved by the rotation of the sizing blade 69 of the grain spiraling body 63 to the storage tank. When the particles are repelled toward the inside of the particle sizer 54, foreign substances such as straw dust and dust mixed in the particle size distribution are separated from the particle size distribution and discharged outside the machine by the action of the dust collector 75 or the exhaust fan 58. Grain quality can be improved.

An outlet chute 73 provided on the lower side wall of the sorting shell 53 for discharging small grains and debris is formed on the lower partition plate 53b of the sorting shell 53 as shown in FIG. It is formed larger than a normal outlet chute so that a large amount of small grains and debris can be quickly discharged. Further, the lower partition plate 53b has a gradient inward from the sorting shell 53 side so that falling small grains and debris can be collected in the rotation range of the debris scraping blade 68a. I will attach it. Therefore, a large amount of small grains and debris discharged from the selection holes (mesh) of the separation net body 62 and falling downward are quickly discharged through the large discharge chute 73 by the debris scraping blade 68a. You. In the small grains and dust particles discharged from the vertical sorter, foreign matters such as straw dust and dust mixed in the small grains and dust particles have already passed through the dust discharge duct 64 in the sorting shell 53. In order to further improve the quality of small grains and debris by completely separating and removing foreign substances such as straw debris and dust mixed in small grains and debris, Shoot 7
3 can also be provided with a karino (not shown). In other words, in order to separate foreign matter by allowing Karamin having a plurality of falling plates for dropping small grains and debris in a zigzag shape therein to communicate with the exhaust chamber 57 through the hollow portion S of the base 52. The separation air current creates small grains and debris discharged from the vertical sorter into Karinouchi. Separation of foreign matter such as straw dust and dust mixed in the grains
It can be configured to suck the air from the second hollow portion S into the exhaust chamber 57 and discharge the air to the outside through the exhaust duct 56.

Outlet 5 of storage tank 54 of vertical sorter A
A measuring device 79 is provided below 4a, and the measuring device 79 measures the weight of the sized granules stored in the bag placed thereon. The weighing device 79 is configured in the same manner as the weighing device 9 of the above-described fryer B, and controls a shutter operating member (not shown) that operates a shutter 77 that opens and closes the discharge port 54a of the storage tank 54 and controls these members. The control means is electrically connected, and is configured to control the operation of the shutter operation member according to the measurement result of the scale 79.

Next, the second vertical sorter C will be described. The second vertical sorter C is a first vertical sorter A
Is different from that of the first vertical sorter A in the structure of the second vertical sorter C except that the sorting holes have different mesh sizes. The members are indicated by adding “x” to the reference numerals used in the description of the components of the first vertical sorter A described above, and detailed descriptions thereof will be omitted. The grains supplied to the second vertical sorter C are already sorted at the first vertical sorter A at the time of sorting.
Since foreign matters such as straw waste and dust are almost completely removed, a vertical sorter in which dust discharging means for removing foreign matter such as straw waste and dust is simplified can be used.

The operation of the three-stage sorter of the present invention configured as described above will be described.

First, the mode of use shown in FIG. 1 will be described. The outlet chute 73 of the first vertical sorter A is connected to the supply hopper 4 of the graining machine B via the connecting pipe r ₁ and lifted. The flow path switching plate 33 of the branch pipe 32 of the grain machine B is operated to direct the flow of the grain toward the discharge pipe 35. Then, as the sorting net 62 of the first vertical sorting machine A, d ₁
(For example, d ₁ = 1.85 mm) or more, and a screening net having a mesh size of d ₁ (= 1.85 mm) capable of sorting waste particles including small grains having a size of d ₁ or less. Using
As the sorting net 62x of the second vertical sorting machine C, d ₂
(A d ₂ <d _1, for example, d ₂ = 1.70 mm) or more grains and mesh size of the sorting holes for sorting into a debris particle of immature grains such as d ₂ or less d ₂ (e.g., d ₂ = 1.70
mm).

In the first vertical sorting machine A, the two-output gear motor 61 is activated to rotate the sorting net 62 and the helix 63 in relative rotation, and the motor 60 is activated to rotate the exhaust fan 58. At the same time, the fryer B and the second vertical sorter C are similarly activated.

Then, the hopper 5 of the first vertical sorter A
5 is supplied to the supply cylinder 66 and is supplied to the induction cylinder 6.
7 is guided downward by the guide blades 67 a and is introduced into the guide cylinder 67 through a kernel guide port (not shown) formed at a lower portion of the side wall of the guide cylinder 67.

The grains introduced into the guide cylinder 67 are fried by the interaction of the relatively rotating sorting net 62 and the helix spiral 63, and during that time, the size d of the sorting hole of the sorting net 62 is increased.
₁ (= 1.85 mm), particles and particles having a smaller particle size, such as straw waste and dust, are transferred from the mesh of the sorting net 62 to the gap between the sorting net 62 and the sorting shell 53. The foreign matter is released, and a plurality of foreign substances are generated through the respective burrs 65 by the air flow generated in the gap between the sorting net 62 and the sorting shell 53 in the sorting shell 53 by the action of the exhaust fan 58. The air is sucked by the dust exhaust duct 64, and is discharged from the dust exhaust duct 64 through the exhaust chamber 57 to the outside of the machine via the exhaust duct 56.

The small grains and dust particles having a smaller particle size than the size of the mesh fall onto the lower partition plate 53b and are discharged from the discharge port formed in the lower partition plate 53b by the dust particle scraping blade 68a. It is discharged from the first vertical sorter A via a discharge chute 73 having a rectangular shape. At this time, the outlet chute 7
By forming 3 large, a large amount of small grains and debris can be quickly discharged. Also,
By attaching Karino to the outlet chute 73, foreign substances mixed in the waste particles can be completely separated and removed,
It is possible to discharge high-quality small grains and debris that do not contain foreign matter.

On the other hand, the sorting holes (d ₁ = 1.
85mm)
The hulled helical body 63 is hulled by the spiral wings 63a, discharged onto the upper partition plate 53c, and repelled into the storage tank 54 by the sizing and squeezing blade 69, so that the storage tank 5
4 is stored. When the sized particles repelled into the storage tank 54 collide with the plurality of dispersion plates 54c and are dispersed and fall downward, foreign substances such as straw dust and dust mixed in the sized particles are discharged from the dust collector 75 or the exhaust fan 58. By being separated from the sizing by the action and being discharged to the outside of the machine, only high-quality sizing that does not contain foreign matter can be stored. Then, the sized bags are packed in the discharge port 5 of the storage tank 54.
The bag is placed on a measuring device 79 installed below 4a, the shutter 77 of the discharge port 54a is opened, and the sized granules are discharged from the discharge port 54a into the bag, and the amount reaches a predetermined value. Sometimes this can be done by closing the shutter 77.

Small grains and debris discharged from the mesh of the sorting net 62 and quickly discharged from the large discharge chute 73 are supplied to the feed hopper of the graining machine B via the connecting pipe r _1. 4 is introduced. Small grains and debris are supplied to the feed hopper 4
, And flows down into the fried cylindrical body 3, and is sequentially transferred upward by the bucket conveyor 20. When each bucket 22 rotates around the upper driven pulley 24, small grains and debris in each bucket 22 are discharged from the discharge hole 15 to the inclined outlet pipe 31 by centrifugal force, and The gas is transferred from the second outlet 32b of the branch pipe 32 to the discharge pipe 35 by the flow path switching plate 33, and is discharged from the discharge pipe 35.

At this time, when small grains and debris discharged from the discharge chute 73 of the first vertical type sorting machine A are packed without re-sorting, the flow path of the branch pipe 32 is changed. The switching plate 33 is switched to be transferred from the inclined outlet pipe 31 to the storage tank 6 through the first outlet 32a of the branch pipe 32, stored in the storage tank 6, and packed in a measuring bag using the measuring device 9 as appropriate. can do.

The small grains and debris supplied from the discharge pipe 35 of the graining machine B to the hopper 55x of the second vertical sorter C are
Similar to the sorting in the first vertical sorter A, the grain is fried by the interaction between the relatively rotating sorting net 62x and the hulling spiral 63x, and during that time, the mesh size d ₂ of the sorting hole of the sorting net 62x (= The dust particles having a smaller particle size than 1.70 mm) are released from the mesh of the sorting net 62x, fall on the lower partition plate 53bx, and are discharged from the discharge port formed in the lower partition plate 53bx by the dust particle scraping blade 68ax. It is discharged from the second vertical sorter C via a large discharge chute 73x. At this time, since the outlet chute 73x is formed in a large size, a large amount of small grains and small particles can be quickly discharged.

On the other hand, the mesh size d ₂ of the sorting net 62x
(= 1.70 mm), the grain having a particle size not passing through is passed through the spiral blade 63ax of the helix 63x, discharged to the upper partition plate 53cx, and discharged into the storage tank 54x by the sizing rake-out blade 69x. It is repelled and stored in the storage tank 54x. Then, the grain can be packed in a measuring bag using the measuring device 79x.

As described above, in the example shown in FIG.
₁ (= 1.85 mm) or more large-diameter grains and d ₁ or less but d ₂ or more (d _{2 to} d ₁ , that is, 1.7)
Medium diameter kernels (range 0 mm to 1.86 mm) and d ₂
(= 1.70 mm) or less, it is possible to continuously perform three-stage sorting of kernels without the need to exchange sorting nets and the like, and to measure each kernel. Bagging can be performed as appropriate.

Next, the mode of use shown in FIG. 2 will be described. In this use mode, the first vertical sorter A, the second vertical sorter C, and the fryer B have the same arrangement as that shown in FIG. 1 described above, and the first vertical sorter A Instead of the connecting pipe r ₁ connecting the discharge chute 73 of the first and the grain hopper B and the supply hopper 4, the connecting pipe r ₂ is used to connect the discharge port 54 a of the storage tank 54 of the first vertical sorter A to The second of the machine B
And the supply hopper 5. At this time, when the discharge port 54a of the storage tank 54 of the first vertical sorter A is to be connected to the supply hopper 4 of the grain lifter B, either the first vertical sorter A or the grain lifter B is to be connected. It is necessary to move one side or to bend the connecting pipe so as to be connected. But the first
Moving the vertical sorter A and the grain-lifting machine B requires a great deal of labor and cannot be easily moved. Also, if the connecting pipe is bent significantly, the flow of the grain becomes blocked due to bending. However, since the feeder hoppers 4 and 5 are provided on the front and rear wall surfaces of the fryer cylinder 3 respectively, the first vertical sorter A and the fryer B are used in the present invention. without moved using a linear connection pipe r _2, can be connected to a second feed hopper 5, grains are smoothly supplied to the AgeKoku machine C without flow is inhibited.

In each of the sorting networks of the first vertical sorting machine A and the second vertical sorting machine C, the first vertical sorting machine A
Mesh size of the sorting holes as sorting network 62 of d ₁ (e.g., d ₁ = 1.85 mm) by using a sorting network body, in a first vertical sorter A, d ₁ or more grains and d so as to sort into a debris particle such as ₁ or less crushed grains, the d ₁ (d ₁ =
1.85 mm) or more grains are further added to d ₃ (d ₃
> D ₁ , for example, a large-diameter grain of d ₃ = 2.00 mm or more, and d ₃ or less (that is, d _{1 to} d ₃ (1.8)
5 mm to 2.00 mm) in order to sort the kernels into a sorting net 62x of the second vertical sorting machine C, a sorting net having a mesh size of a sorting hole of d ₃ (= 2.00 mm). Use the body.

The operation of the three-stage sorter in this example is shown in FIG.
The operation is substantially the same as that described in relation to the above, and only the different points will be described below.

The grains supplied to the hopper 55 of the first vertical sorter A are fried by the interaction of the revolving sorting net 62 and the helix spiral 63, during which the sorting net 6 is placed.
The dust particles having a smaller particle diameter than the sorting hole 2 (d ₁ = 1.85 mm) and foreign materials such as straw dust and dust are released from the mesh of the sorting net 62 and the foreign materials mixed in the dust particles are completely eliminated. And only the dust particles are discharged from the first vertical sorter A via the discharge port chute 73. On the other hand, a grain having a large particle diameter that does not pass through the sorting hole (d ₁ = 1.85 mm) of the sorting net 62 is fried by the spiral blade 63 a of the filing spiral 63 and stored in the storage tank 54. . The outlet 54a of the storage tank 54 is connected to the connecting pipe r _2, via the connecting pipe r _2, AgeKoku machine second B
Into the supply hopper 5. The grains supplied to the grain-lifting machine B are grain-lifted by the bucket conveyor 20, discharged from the discharge hole 15 of the grain-pulling cylinder 3 to the inclined outlet pipe 31, and branched by the flow path switching plate 33 of the branch pipe 32. Is transferred from the second outlet 32b to the discharge pipe 35, and the discharge pipe 35
To the second vertical sorter C.

At this time, when bags having a particle diameter of d ₁ (= 1.85 mm) or more are packed without re-sorting, the flow path switching plate 33 of the branch pipe 32 is switched and the inclined outlet pipe is switched. It can be stored in the storage tank 6 by being transferred from the base 31 to the storage tank 6 through the first outlet 32a of the branch pipe 32, and can be packed in a measuring bag using the measuring device 9 as appropriate.

The d ₁ (= 1.85) supplied to the hopper 55x of the second vertical sorter C from the discharge pipe 35 of the grain lifter B
mm) or more, the first vertical sorter A
In the same manner as the sorting in the above, the grain is fried by the interaction between the sorting net 62x and the helix 63x that are relatively rotated, and during that time, the mesh size d ₃ of the sorting hole of the sorting net 62x (= 2.
00 mm) is released from the sorting holes of the sorting net 62x, falls onto the lower partition plate 53bx,
The waste particles are discharged from the second vertical sorter C through the discharge port formed in the lower partition plate 53bx through the large discharge port chute 73x by the scraping blade 68ax.

On the other hand, the mesh size d ₃ of the sorting net 62x
The large-diameter grains larger than (= 2.00 mm) are fried by the spiral wings 63ax of the helix spiral 63x, discharged onto the upper partition plate 53cx, and directed into the storage tank 54x by the sizing rake-out blades 69x. It is flipped and stored in the storage tank 54x. The large-diameter grain can be packed in a measuring bag using the measuring device 79x.

[0060] As described above, in the example illustrated in FIG. 2, d ₁ (= 1.85 mm) or less debris particles and, although d ₁ or d ₃ or less (the range of d ₁ to d _3, i.e. , 1.8
Medium-sized kernels (ranging from 5 mm to 2.00 mm) and d ₃
(= 2.00 mm) or more large-diameter grains or more can be continuously subjected to three-stage sorting of the grains, and the respective grains can be packed in a measuring bag as appropriate.

In each of the above-described modes of use, a mode has been described in which kernels are successively and efficiently sorted into three stages: relatively large-diameter grains, slightly smaller medium-diameter grains, and waste grains smaller than them. However, in the three-stage sorter of the present invention, it is also possible to sort waste rice obtained by normal sorting of rice grains and nonstandard rice in three stages. Waste rice and non-standard rice obtained by ordinary sorting of rice grains can be used for various purposes according to the particle size, for example, on the basis of the particle size of the waste rice, etc. By sorting into the middle and lower three stages, "Ura-kuwa" can be used as edible rice for business use as Central America, and "Ura-ku Naka" is used for processing rice crackers and other rice crackers. It can be used as rice, and "under scrap rice" can be used as raw rice for miso and beer.

Therefore, when three-stage sorting of scrap rice using the three-stage sorting machine for grain and the like of the present invention, the sorting nets of the sorting holes of the first and second vertical sorters are used. For example, mesh sizes of 1.70 mm and 1.50 mm are used, respectively. By throwing scrap rice or non-standard rice obtained by normal sorting of rice grains into the three-stage sorter of the present invention, as in the above-described embodiment, depending on the particle size, for example, 1.70.
mm (> 70 mm) and 1.70 mm-1.
Continuous and efficient in three stages according to various uses such as 50mm processing rice ("medium in scrap rice") and 1.50mm or less for miso and beer raw material ("under scrap rice") You can sort well.

As described above, in the three-stage sorter for grain and the like of the present invention, the first vertical sorter A and the second vertical sorter C and the graining machine B connecting these are used. , Rice grains etc. in three stages such as relatively large diameter grains and slightly smaller medium diameter grains and smaller crushed grains, or for processing crushed rice as commercial edible rice and middle rice Rice can be continuously and efficiently sorted into three stages of rice and miso or raw material rice for beer.Furthermore, in each of the grains selected in the three stages, foreign substances mixed in the grains are separated and removed. The grain quality of the section can be improved and optionally weighed.

[0064]

As described above, according to the three-stage sorter for cereals and the like of the present invention, storage is performed via a branch pipe having two supply hoppers below and a flow path switching plate above. Using a fryer equipped with a fryer cylinder that communicates with the tank and discharge pipe,
By connecting first and second vertical sorters each equipped with a sorting net having different mesh sizes of the sorting holes, and successively sorting the grains by the first and second vertical sorters, respectively. , Various types of grains in three stages, that is, three stages, such as relatively large-diameter grains and slightly smaller medium-diameter grains and smaller debris, or three stages of debris rice In addition, each grain selected in three stages can be continuously and efficiently sorted, and foreign matter mixed in the grain is separated and removed, thereby improving the quality of the grain in each section and appropriately measuring. Grains can be processed smoothly, such as by bagging.

[Brief description of the drawings]

FIG. 1 is a configuration diagram schematically illustrating a configuration based on one use mode of a three-stage sorter for grain or the like of the present invention.

FIG. 2 is a configuration diagram schematically illustrating a configuration based on another use mode of the three-stage sorter for grain and the like of the present invention.

FIG. 3 is a cross-sectional view of the vertical sorter of the three-stage sorter for grain or the like according to the present invention, cut along line XX in FIG.

4 is a cross-sectional view of the vertical sorter of the three-stage sorter for grain or the like according to the present invention, which is cut along line YY in FIG.

FIG. 5 is a perspective view of a fryer in a three-stage sorter for grain and the like according to the present invention as viewed from the front.

FIG. 6 is a schematic perspective view showing a partially-fractured barrel of the fryer shown in FIG. 5;

7A is a schematic perspective view showing a relationship between a lower portion of a fry cylinder of the fryer shown in FIG. 6 and two supply hoppers, with a side wall cut away, and FIG. 7) is a schematic perspective view showing another mode in which one second supply hopper is removed and the second supply hole is closed.

8 (a) is a schematic perspective view of the upper part of the graining machine shown in FIG. 5, and FIG. 8 (b) is a cutaway of a bifurcated branch pipe along plane A in FIG. 8 (a). FIG.

FIG. 9 is a cross-sectional view schematically illustrating a conventional vertical sorter.

[Explanation of symbols]

 Reference Signs List A First vertical sorter B Graining machine C Second vertical sorter 3 Frying cylinder 4 Supply hopper 5 Second supply hopper 6 Storage tank 7 Discharge port 9 Meter 10 Display operation panel 12 Supply hole DESCRIPTION OF SYMBOLS 13 2nd supply hole 15 discharge hole 20 bucket conveyor 21 endless belt 22 bucket 23 drive pulley 24 driven pulley 31 inclined extraction pipe 32 (bifurcated) branch pipe 32a first outlet 32b second outlet 33 flow path Switching plate 35 Discharge pipe 53 Sorting shell 54 Storage tank 54a Discharge port 55 Hopper 56 Exhaust duct 57 Exhaust chamber 58 Exhaust fan 61 Two-output gear motor 62 Sorting screen 63 Lifting spiral 63a Spiral wing 64 Dust duct 68a Dust Dispensing blade 69 Sizing rake-out blade 73 Discharge chute 75 Dust collector 77 Shutter 79 Meter

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Seizou Kawashima 4290, Fujioka-cho, Shimotsuga-gun, Tochigi Pref. (72) Inventor Toshiyuki Abe 4290 Fujioka, Shimotsuga-gun, Shimotsuga-gun, Tochigi Prefecture F-term in Tiger Kawashima Co., Ltd. 4D021 AA14 AB02 CA11 CB02 DA01 DA13 DA15 DB20 EA02 EA03

Claims (6)

[Claims] 1. A sorting shell having a hopper for supplying kernels below and a storage tank at an upper portion, and a sorting net and a helix spiral are concentrically disposed rotatably in the sorting shell. During the frying of the grains supplied from the hopper by relative rotation of the sorting net and the helix spirals, sieving of a desired particle size or more and debris of a desired particle size or less are performed. First and second vertical sorters configured to sort and store the sized granules in the storage tank and discharge the debris and the like to the outside of the machine via a discharge chute; A graining cylinder having a plurality of supply hoppers and an upper portion communicating with a storage tank and a discharge pipe through a branch pipe having a flow path switching plate, and graining in the graining cylinder Means for arranging the discharge pipe of the machine. In addition to associating with the hopper of the second vertical sorter, the outlet chute and the outlet of the storage tank of the first vertical sorter are connected to one of two supply hoppers of the graining machine. And the first vertical sorter and the second vertical sorter are connected and arranged via the graining machine so that they can be selectively communicated with each other via a connecting pipe or the like. A three-stage sorter for grain and the like. 2. The method according to claim 1, wherein the outlet chute of the first vertical sorter is associated with one of the supply hoppers of the graining machine, and a flow path switching plate of the branch pipe of the graining machine is switched to perform the lifting. By communicating the grain body with the discharge pipe, the first vertical sorter is sized with a desired particle size or more corresponding to a sorting hole of the sorting net and dust particles with a desired size or less, etc. And storing the sized particles in the storage tank and supplying the debris and the like to the frying machine through the discharge chute, and fusing the debris and the like by the frying machine. And supplying the hopper of the second vertical sorter from the discharge pipe to the hopper of the second vertical sorter, further sorting the waste particles and the like by the second vertical sorter, and sorting the grains in three stages. The three-stage sorter for grain and the like according to claim 1, wherein the three-stage sorter is configured to be able to perform the following. 3. The discharge port of the storage tank of the first vertical sorter communicates with the other supply hopper of the grain-pulling machine via a connecting pipe, and the flow of the branch pipe of the grain-pulling machine. By switching the passage switching plate to communicate the fried cylinder to the discharge pipe, the first vertical sorter has a desired particle size equal to or greater than the desired particle size selected in accordance with the sorting hole of the sorting net. The sizing is supplied to the other supply hopper of the graining machine through the storage tank, and the grained grain is grained by the graining machine, and the grain of the second vertical sorter is discharged from the discharge pipe. The hopper is supplied to the hopper, and the sized grains are further sorted by the second vertical sorter, so that the grains can be sorted in three stages. A three-stage sorter for grains and the like. 4. The first and / or second vertical sorter includes: an exhaust chamber having a suction opening opened in a hollow portion of a base on which the sorting shell is erected; An exhaust fan provided in the exhaust chamber for sucking air in the base and exhausting the air to the outside of the machine, and a dust exhaust duct disposed in the sorting shell and communicating with the exhaust chamber, Foreign matter mixed in the grain is sucked through the dust exhaust duct disposed in the sorting shell and discharged to the outside of the machine through an exhaust duct connected to the exhaust chamber, and further sorted. The three-stage sorting of grains and the like according to any one of claims 1 to 3, wherein a dust discharging means for separating and removing foreign substances mixed in the sized granules is provided in the storage tank. Machine. 5. The first and / or second vertical sorter is characterized in that the discharge chute is provided with a garbage for separating and removing foreign substances mixed in dust particles and the like. Item 3. A three-stage sorter for grain or the like according to any one of Items 1 to 4. 6. A scaler is provided below each of the storage tanks of the first vertical sorter, the fryer, and the second vertical sorter. 6. A three-stage sorter for grain or the like according to any one of 1 to 5.