JPS6331544A - Vertical type shock system gluten remover - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a vertical impact type deburring device.

(Prior art) Conventionally, grains were fed out radially by rotation of a feeding body fixed to a vertical rotating shaft, and an annular elastic plate was provided on the outside of the feeding body to enable vertical impact demulsing. Things are publicly known.

(Problems to be Solved by the Invention) The known vertical impact demolition device is required to be ejected from the ejecting body at a high speed within the possible range, but this does not mean that the ejecting body is unnecessarily high-speed. It cannot be rotated, and if the feeder is rotated at high speed, the unhulled rice will be solidified and ejected, which will impede the dehulling performance.

(Means for Solving the Problems) Accordingly, the present invention has been devised so that grains are fed out radially by the rotation of a feeding body opening fixed to a vertical rotation shaft, and an annular elastic plate mortar is provided outside the feeding body opening. is installed to enable vertical impact deburring, in which a dispersing body for rotating and dispersing the supplied grain is provided on the upper part of the feeding body, and a dispersing body for rotating and dispersing the supplied grain, and a dispersing body for rotating and dispersing the dispersed grain downward while increasing the speed. This is a vertical impact type deburring device which is provided with a feeder body for feeding the material to the feeder body U, and is configured to gradually increase the speed and feed the material to the feeder body U.

(Embodiment) An embodiment of the present invention will be described with reference to the drawings. Reference numeral 1 denotes an outer case that surrounds the whole, and is formed into a rectangular tube shape from a thin iron plate. Inside the outer case 1 is a cylindrical inner case 2.
is provided. Reference numeral 3 denotes the upper wall of the inner case 2, which has a horizontal disk shape, and has a through hole 4 formed in its center, and a hopper mounting bracket 5 is placed and fixed in the upper part of the through hole 4. A paddy hopper 6 is detachably attached to the hopper mounting bracket 5.

A vertical supply inner cylinder 7 is fixed to the lower surface side of the hopper mounting bracket 5. 8 is an opening/closing shutter provided on the hopper mounting bracket 5, and 9 is an outer supply cylinder surrounding the outer circumference of the vertical inner supply cylinder 7 at intervals. The outer supply cylinder 9 is formed to extend considerably below the lower end 10 of the vertical inner supply cylinder 7.

A vertical annular gap 11 is formed between the upper ends of the vertical supply inner cylinder 7 and the upper end of the supply outer cylinder 9, and the vertical al! Fit the llS cylinder. The upper end of the vertical adjustment cylinder 4 is provided so as not to move below the lower end 10 of the vertical supply inner cylinder 7.

The inner end of an outwardly protruding horizontal engagement round rod 13 is fixed at a desired position on the upper part of the vertical adjustment cylinder arrangement, and the horizontal engagement round rod 13 passes through an inclined groove 14 formed in the supply outer cylinder 9. It further protrudes outward, and its tip engages the lower end of the vertical fork 16 of the vertical movement operating body 15. The vertical movement operating body 15 has a toothed portion 1 formed on the annular collar portion 17 of the hopper mounting bracket 5.
8 and moves in an arc shape one tooth at a time. 1
9 is its operation. Therefore, when the vertical movement operating body 15 moves horizontally in an arc shape, the horizontal engagement round bar 13 is moved by the vertical fork 16, and the vertical adjustment cylinder 12 is moved by the action of the inclined groove 14. move up and down.

At the center of the outer supply cylinder 9, there is provided a vertical rotation shaft which is long in the vertical direction.A first dispersion body 21 having a conical shape and an integral structure made of ordinary casting is fitted to the uppermost end of the 0wc rotation shaft. Fixed at Porto η. A plurality of first dispersion protrusions n are formed radially on the outer surface of the first dispersion element 21 . The first distributed protrusion n is preferably formed from six pieces of wood.

The lower end 24 of the first dispersion body 21 faces near the lower end B of the vertical adjustment cylinder l, and the action of the zero dispersion protrusion n that forms a paddy fall adjustment n3 between the lower end 24 and the lower end This is to cause the paddy to collide with the inner wall of the vertical adjustment cylinder l to be uniformly dispersed in a single grain state, and to fall as a single grain from the drop adjustment n3.

The second dispersion element n is provided under the first dispersion element 21 without any gap. The same number of second dispersion protrusions n as dispersion protrusions n are also provided on the upper surface of the second dispersion element I. The second dispersion element n has a conical shape with a slightly gentler slope than the first dispersion element 21, and the position of the second dispersion element n is such that the outer supply cylinder 9 faces the outer circumference thereof with an annular gap therebetween. and the size is the second distributed protrusion 2
8 is directly below the drop adjustment port 3, and therefore, the outer end of the second dispersion H is located outward from the drop adjustment port.

The second dispersion protrusion is provided to have a receding angle with respect to the rotational direction. Therefore, when the paddy exits the second dispersion protrusion, it is distributed as if sliding and is swung outward. Since the number of zero dispersion protrusions n and second dispersion protrusions n that collide with the inner surface of the cylinder 9 and further uniformly disperse the rice grains is the same,
The paddy guided by the dispersing ridges n is smoothly transferred to the second dispersing ridges 28.

A first feeding body n is provided below the second dispersion element n. The second dispersing element n and the first feeding body 3 are usually cast as an integral structure, and a vertical inner sleeve 30 is integrally formed inside thereof, and a vertical inner cylinder (9) is connected to the vertical rotation axis. On the other hand, it is inserted from above.

A first grain feeding thread 31 is formed on the outer periphery of the second feeding body 3. The first grain feed thread 31 is formed with a gentle slope so as to gradually feed downward the grains rotating together with the rotation of the first dispersion element 21 and the second dispersion element n. The first grain feeding screw 31 has a shape that is low at the top but increases in height as it reaches the bottom.The lower end of the first grain feeding screw 31 is the highest, and in this part, the grain is It is formed to rotate within the supply outer cylinder 9 at the same speed.

As a result, the second grain feeding thread U of the lower second feeding body is formed so that it can be easily retracted.The first feeding body n and the second feeding body are formed to have the same diameter from beginning to end. The first feeding body n and the second feeding body 33 are formed independently.

A double shaft 5 is rotatably attached to the inside of the second sending body wing via a bearing. The double shaft is extended long to the bottom end. The upper end of the double shaft faces the lower end of the vertical inner cylinder (9), and the second feeding body wing is engaged with the outer periphery of the double shaft. The upper end of the vertical inner cylinder of the second feeding body wing is lower than the upper end of the double shaft, and the double shaft protrudes upwardly than the vertical inner cylinder. screw together, and fix the second feeding body wing from above.

38 is a bearing holding fitting. A small diameter pulley is indirectly attached to the lower end of the double shaft 35, so that the double shaft rotates faster than the vertical rotation shaft.

Accordingly, the second grain feeding screw 34 has a second speed increasing section at the lower end of the second feeding body which rotates faster than the first grain feeding screw 31, and a second speed increasing section at the lower end of the second speed increasing section. has a second speed increasing section 41, a third speed increasing section 42 at its lower end, and a fourth speed increasing section 43 at its lower end.
be provided integrally.

The -th speed increasing part sum has a conical shape whose outer diameter gradually increases as it reaches the lower end, and has a vertical inner cylinder housing inside, and has a vertical inner cylinder 44.
Fit the outer circumference of the double shaft.

Reference numeral 45 denotes a flange formed on a double shaft. The lower end of the vertical inner cylinder 44 comes into contact with the flange 45 and stops, and the lower end of the vertical inner cylinder 44 is joined to the upper end of the vertical inner cylinder 44. The upper end of the tube I is tightened and fixed with the screw g.

Twice as many first speed increasing protrusions 46 as second grain feed threads U are provided on the outer peripheral surface of the first speed increasing section 40. The height of the first speed increasing protrusion 46 is low at the upper end and gradually increases to the middle, and is the same height from the middle to the lower end.

A second speed increasing protrusion 47 is provided on the upper surface of the second speed increasing section 41 .

The second speed increasing protrusions 47 have the same height throughout, but are twice as many as the first speed increasing protrusions. The first speed increasing protrusion 6 is formed to have a sweepback angle, but the second speed increasing protrusion 47 is provided in the radial direction and does not have a sweepback angle.

The third speed increasing section C and the fourth speed increasing city center are formed separately from the second speed increasing section 41, and are fixed by desired fixing means. The third speed increasing section C has a conical shape with a gentler slope than the first speed increasing section 40, and has third speed increasing ridges 48 three times as many as the second speed increasing ridges 47 on its upper surface. establish. A step 49 is formed at the boundary between the third speed increasing section 42 and the fourth speed increasing section 43, and the same number of fourth speed increasing ridges as the first speed increasing ridges 6 are provided above the center of the fourth speed increasing section ( capital). A cover 51 is provided on the upper surface of the first speed increasing section 41 and the second speed increasing section 41 . The cover 51 is connected by a connecting body 52 that protrudes from the first speed increasing section cutout.

Therefore, the cover 51 rotates integrally with the first speed increasing section. The cover 51 is formed in a shape parallel to the first speed increasing section C and the third speed increasing section C, and grains ejected by the first speed increasing protrusion 46 are reflected on the inner surface of the cover 51 and are transferred to the second speed increasing section C. It is configured to be supplied between the protrusions 47. 53 is a reflective surface.

An umbrella-shaped alignment body is integrally attached to the terminal end of the cover 51 via an annular connection body. The umbrella-shaped alignment body 55 is formed so as to approach the fourth speed increasing part as it reaches the lower end, and has a circumferential injection port between the lower end μs of the umbrella-shaped alignment body 5 and the lower end 57 of the fourth speed increasing part. A vertical belt-shaped elastic plate μs is provided on the outer periphery of the 0-circumference injection port forming the base.

The belt-shaped elastic plate mortar is belt-shaped and elastically fitted vertically to the inner surface of the annular support member. The vertical width between the annular supporting members is larger than the vertical width of the belt-like elastic plate 59, and a fitting groove 61 into which the belt-like elastic plate μs fits is formed on the inner surface of the annular supporting member 60. is elastically reduced and the mating tI! After fitting into I61, it is elastically expanded and fitted.

On the outer periphery of the annular support member (material), horizontal shaft portions protrude radially at intervals of 120 degrees, and rotating horizontal shaft portions are provided near each horizontal shaft, and the rotating horizontal shaft 8 is located on the inner case z side. mounted on the
A worm gear 65 is provided at one end of the 0-rotation horizontal shaft in which a ring rod is loosely fitted between the horizontal shaft U and the rotary horizontal shaft mill, and has a worm that engages with the worm gear I. Provide a vertical rotation shaft frame.

Therefore, when the rotating horizontal shaft 8 rotates, the ring rod 64 moves 3
Since it rotates in a dimension, the belt-like elastic plate 59 moves in a three-dimensional circle via the ring rod.

the first speed increasing section off, the second speed increasing section 41, the third speed increasing section 42,
Fourth speed increasing section 43, cover M51. A feeding body opening is formed by the annular connecting body I and the umbrella-shaped aligned body I.

A downward bowl-shaped air passage cover 68 is provided below the feeding body retainer. A fixed vertical cylinder 71 is provided on the outer periphery of the double shaft through a bearing blade 70, and the upper end of the fixed vertical cylinder 71 is slightly lower than the lower end of the vertical inner cylinder I. fix the part. The air passage covering portion is formed of a horizontal, perfectly circular upper wall portion η and a vertical annular side wall n. A triangular protrusion 74 is formed on the outside of the lower end of the annular side wall n. 75 is a horizontal air passage within the air passage cover.

A vertical suction cylinder π is provided between the fixed vertical cylinder 71 and the annular side wall n. The upper end of the suction tube cloth faces the center of the horizontal air passage 1, and the lower end of the suction tube π is connected to the fixed rod n via the connecting portion stomach. A discharge weight is formed on the outer periphery of the annular side wall π, and an upper inclined flow plate is provided at the bottom of the discharge weight, which gradually approaches the annular side wall n. A fall port 81 is formed at the lower end of the upper inclined flow plate (equipment), and objects falling from the fall port 81 are guided outward by the impact of the protrusions 74 on the inclined upper wall.
At the lower end, it hits the lower inclined flow plate and flows down in a winding pattern.

Since the speed at which the grains are ejected from between the circumferential injection ports is quite high, the grains are bent and flowed down several times, and when they fall from the drop port U of the lower sloped flow root blade, the grains are slowed down considerably. do. A separation cylinder 6 is provided at the lower part of the suction cylinder π and below the falling eyelid.

An adjustment cylinder part is fitted into the upper part of the separation cylinder 6 so as to be vertically adjustable. The annular gap r between the adjustment tube shell and the suction tube cloth serves as the inlet.

Inclined grooves are provided at multiple locations in the W joint, and the pin blades protruding from the separation tube 6 are fitted into the inclined grooves, and the adjustment tube can be rotated circumferentially in a desired manner to adjust the adjustment tube. Move up and down.

An annular member 9 is connected to the outside of the separation tube 6 via a connecting fitting (material).
1 will be provided. The cross section of the annular member 31 is chevron-shaped, and the area between the separation tube 6 and the annular member 91 becomes a droplet of brown rice. The annular member 91 is located below the lower inclined flow lower root blade, and a suction hatch is formed between the lower inclined flow lower plate portion and the annular member 91.

84 is an annular rising air passage between the suction cylinder cloth and the annular side wall n;
5 is an annular downward air passage between the fixed vertical cylinder 71 and the suction cylinder π.

The brown rice that has fallen by one centimeter is guided below the brown rice falling hita, and a sorting perforated plate 96 is provided there. 97 is a large-diameter rotating body. The rotating body 87 is rotated by a pulley 98 attached to the lower end of the vertical rotating shaft, and the horizontal part 9
8 and an inclined portion 100. The inner end of the horizontal portion 89 is provided close to the connecting portion, and the outer end of the horizontal portion 98 is provided close to the inner case 2 . The upper end of the inclined part 100 is close to the lower end of the suction tube cloth.

A waste rice removal body 102 is provided via a connecting fitting 101 on the upper part of the horizontal portion 99. The waste rice removal body 102 has a horizontal portion 103
, a vertical portion 104 and an inclined portion 105 .

The upper end of the inclined part 105 is close to the lower end of the separation cylinder 6, and the space between the inclined part 100 and the inclined part 105 is formed as a lower ram passage 10B. Between the horizontal part 99 and the horizontal part 103 is a swinging part 107.
bawl.

At the upper end of the vertical portion 104, an engaging groove 108 is formed, in which the perforated screening plate 9B is engaged. A sorting perforated plate i placing frame 109 is fixed in a horizontal position below the engagement groove 108. The zero sorting perforated plate placing frame 109 is made by connecting an inner ring 110 and an outer ring 111 with a connecting piece 112. The outer ring 111 is L-shaped and has an engagement groove 113.

The sorting porous plate 96 is divided into four parts, the inner end 114 of which is inserted into the engagement groove 108, and the outer end 115 of which is inserted into the engagement groove 113 from above.

The perforated sorting plate 96 rotates integrally with the rotating body 97, and the space between the perforated sorting plate 96 and the horizontal portion 103 becomes a waste rice shaking chamber 116. An insertion opening 11 is provided at a desired position on the outer periphery of the inner case 2.
7 is provided, and the mounting rod 11 of the cleaning body 118 is inserted from the insertion port 117.
Insert and secure 9. The cleaning body 118 rubs the lower surface of the sorting porous plate 86.

120 is a good wood outlet, 121 is a good wood guide wall, 122 is a waste rice outlet, 123 is a waste rice guide wall, 124 is a picket outlet, 1
25 is a rod guide wall, 12B is a pulley, 127 is a vertical shaft roller, and 128 is a horizontal shaft roller.

A wind turbine chamber 128 is provided at the lower part of the annular downward air passage 95,
A windmill 130 is provided within a windmill chamber 129. The windmill 130 is
It is fixed to a shaft cylinder 131 fitted on the outside of the lower end of the double shaft. 132 is a discharge port.

(effect) Next, we will discuss the effect.

When the vertical rotation shaft μs, the pulley blades, and the pulley 126 are rotated by a prime mover installed at a desired position, the second feeding body blade is rotated from the pulley blades via the shaft tube 131 and the double shaft a, and is fed out at the same time. The body U also rotates, and the other pulley 1
28 causes the first dispersion 21.
The second dispersion element I and the first feeding body 4 rotate.

In the above case, since the pulley 126 is larger than the pulley blades, the rotation of the second feeder blades, first speed increaser 40, and second feeder n is faster than the rotation of the first dispersion element 21 and the second feeder n. Fast section 41
, third speed increasing section C, fourth speed increasing section 43. Cover 51. The annular connecting body 8 and the umbrella-shaped alignment body 55 rotate faster.

Further, the rotation of the shaft cylinder 131 causes the windmill 130 to rotate, and the air sucked from the suction port is blown out of the machine through the annular upward air passage 94, the annular downward air passage 95, the wind turbine chamber 129, and the discharge port 132.

Further, when the vertical rotating shaft portion rotates, the worm gear 65 rotates, and the rotation of the worm gear group rotates the rotating horizontal shaft port, so that the ring rod fixed to the rotating horizontal shaft port rotates the rotating horizontal shaft port. The belt-shaped elastic plate 8, which rotates around the center and is fitted into the fitting groove 61 and between the annular support members, is moved in a three-dimensional circular motion through the horizontal shaft which is loosely fitted in the rotating part of the ring rod. let

When unhulled rice is supplied to the upper paddy hopper 6 in this state, the unhulled rice flows from the inside of the hopper mounting bracket 5 into the vertical supply inner cylinder 7 and is supplied to the upper part of the first dispersion body 21. The dispersed rice is stirred and dispersed by the dispersion protrusion n, and the dispersed unhulled rice is transferred to the vertical m provided beside the first dispersion body 21.
It collides with the inner surface of the knotted cylinder 12 and is reflected, changes its direction downward, and falls in the form of a single grain from the drop adjustment n3 between the lower end 24 and the lower end 3.

Therefore, the second dispersion body n is provided at an interval below the drop adjustment port, and the second dispersion protrusion is formed on the upper surface of the second dispersion body n. Although it is supplied to the bidispersed protrusions and dispersed again, the second dispersion element n is formed to have a larger diameter than the first dispersion element 21 compared to the first dispersion element 21. , the falling objects from the drop adjustment port 3 are dispersed more vigorously. Since the outer supply cylinder 9 is located next to the second dispersion body H, the grains dispersed by the action of the second dispersion ridge are radiated toward the inner wall of the outer supply cylinder 9 and reflected. I will do it.

After the grain emitted by the second dispersion body V is reflected within the outer supply cylinder 9, it is subjected to the action of the first grain feed screw 31 of the second feeder 3. In this case, although the rotation of the first grain feeding body is quite high speed as described above, since the first grain feeding screw 31 is formed at a pitch close to horizontal, the effect of the second distributed ridge is Grain that has been blown away is not lowered suddenly, but gradually lowered.

Moreover, the first grain feeding screw 31 is at the lower end! Because it is taller and has a larger diameter, the circumferential speed of the lower end blade is maximum,
Hence the bottom end! In this case, almost a co-rotation phenomenon occurs, and this is smoothly transferred between the grain feeding screws of the second feeding body, which has a faster rotation speed than the first feeding body 3.

Since the rotational speed of the grain feeding screw U of the second feeding body wing is faster than that of the second feeding body 3, the grain feeding screw U of the second feeding body wing is further gradually accelerated and sent downward, and this is transferred to the first speed increaser of the first speed increasing part cutting. Take over between 46 quick protrusions.

The grain taken over between the first speed increasing ridge catches is gradually accelerated, reflected on the reflection frame, bounced back and supplied between the second speed increasing sections 41, and swung outward. The grain is distributed between the fourth speed increasing protrusion sum of the lower third speed increasing part C1 and the fourth speed increasing part 43, the fourth speed increasing protrusion (material) and the protrusion on the inner surface of the upper umbrella-shaped alignment body 55. However, this grain finally flows into the umbrella-shaped array 5
The third speed increasing protrusion 48 at the bottom is emitted along between the protrusions.
, and between the fourth speed increasing protrusion (capital), it comes to assist this.

Therefore, the unhulled rice discharged from the circumferential injection port 58 along the protrusions between the umbrella-shaped aligned bodies is transferred to the belt-shaped elastic member fitted into the inner surface of the fitting groove 61 supported by the annular support member 60. It collides with the inner surface of the plate 59 and is dislodged.

The belt-shaped elastic plate μs moves up and down in a three-dimensional manner through the rotational horizontal axis, ring column, and horizontal axis due to the rotation of the worm gear I, so that the belt-shaped elastic plate 8 is evenly distributed over the entire surface. Paddy rice collides and hits only a specific part, preventing only that part from being worn out.

Therefore, the belt-shaped elastic plate μ is emitted from the circumferential injection port.
The rice husks that collided with s are discharged to the discharge chamber 4 and fall to the fall chamber 81. The brown rice falls downward through the droplet mixer and is sorted by the suction wind flowing in from the suction Hita.
fall on top.

Since the perforated sorting plate 96 horizontally rotates at a considerable speed around the vertical rotation axis 4, the scrap rice is sorted and falls into the scrap rice shaking chamber 11B below, and the horizontal rotation of the scrap rice shaking chamber 11 The grains remaining on the zero-sorting perforated plate s6, which are shaken outward and taken out from the waste rice take-out port 122, are taken out from the grain take-out port 120.

On the other hand, the shackle that has entered the annular gap r flows into the shackle dispensing section 107 via the lower swinging passage 108, and is swung outward by the horizontal rotation of the staking discharging section 107 and taken out from the striking opening 124.

The rice husks separated by the wind blowing through the suction port are passed through the annular ascending air passage 9.
4, and is sucked into the wind turbine 130 from the horizontal air path through the annular downward air path 95 and discharged from the discharge port 132.

(Effects) Conventionally, grains were fed out radially by rotation of a feeding body fixed to a vertical rotating shaft, and an annular elastic plate was provided on the outside of the feeding body to enable vertical impact dehulling. is publicly known.

The above-mentioned known vertical impact deburring device is required to be ejected from the above-mentioned dispensing body at a high speed within the possible range, but even so, the dispensing body cannot be unnecessarily rotated at high speed. When it is rotated, the unhulled rice is hardened and released, which impedes the dehulling performance.

However, in the present invention, the grain is fed out radially by the rotation of the feeding body nail fixed to the vertical rotating shaft part, and an annular elastic plate part is provided on the outside of the feeding body nail, thereby making it possible to perform vertical impact deburring. In such a case, at the top of the above-mentioned drawing-out structure,
A dispersing body that rotates and disperses the supplied grain, and a feeder that rotates and sends the dispersed grain downward while increasing the speed are provided, thereby gradually increasing the speed and feeding the grain to the feeder nail. Since this is a vertical impact type dehulling device, the fed grain is fed at gradually increased speed until it reaches the above-mentioned feeder, so that it maintains a sparse state even while the speed is increased. In this way, even when sprayed at high speed, it does not become hard.

You can expect complete deburring by uniformly dispersing it from the entire circumference.

[Brief explanation of the drawing]

Figure 1 is a perspective view of the overall appearance, Figure 2 is a partially cutaway side view, Figure 3 is a longitudinal side view, Figure 4 is an enlarged view of the supply section, Figure 5 is a perspective view of the same, and Figure 6 is an extraction. FIG. 7 is a partially cutaway plan view of the same portion, and FIG. 8 is a plan view of the supply portion. Explanation of symbols 1...Outer case, 2...Inner case, 3...Top wall, 4...Through hole, 5...Hopper mounting bracket, 6...
・Paddy hopper, 7... Vertical supply inner cylinder, 8... Opening/closing shutter, 9... Supply outer cylinder, 10... Lower end, 1
1... Annular gap, 12... Vertical adjustment cylinder, 13...
・Horizontal engagement round bar, 14... Inclined groove, 15... Vertical movement operating body, 16... Vertical forked part, 17... Annular collar part, 18... Engagement tooth part, 19 ...Operation lever, J...
Vertical rotation axis, 21...first dispersion, η...volt, n
...first distributed protrusion, 24...lower end, b...lower end,
Redundancy...falling FA node, n...second dispersion, redundancy...
2nd distributed protrusion, 4... 1st feeding body, addition... vertical inner shaft, 31... 1st grain feeding screw, support... lower end, O... 2nd feeding body , words...second grain feeding screw, 35...double shaft,
36...Vertical inner cylinder, correction...screw, feather...pressing metal fitting,...pulley, 40...first speed increasing section, 41...
・Second speed increasing part, C...Third speed increasing part, 43...Fourth speed increasing part, Easy...Vertical inner shaft, 45... Flange part, 46...
First speed-increasing ridge, 47... Second speed-increasing ridge, K... Third speed-increasing ridge, 49... Step, (capital)... Fourth speed-increasing ridge, 51. ...Cover, 52... Combined body, 8... Reflective surface, 54... Annular connecting body, Audience... Annular alignment body, 56.
...lower end, 57...lower end, 58...circumferential injection port, goose...belt-shaped elastic plate, (material)...annular support member, 6
1... Fitting groove, Akira... Horizontal axis, 0... Rotating horizontal axis, 6
4...Ring rod, ring...worm gear, mark...vertical rotation axis, U...feeding body, problem...air passage cover, mortar...bearing, 70...bearing, 71 ... Fixed vertical cylinder, η ... Perfectly circular upper wall part, n ... Annular side wall, 74 ... Projection, no ...
・Horizontal air path, red...suction pipe, n...connection, τ...
・Fixed frame, π...Discharge chamber, (capital)...Upper slanted flow plate, 81...Falling port, wings...Earth wall, wings...Lower slanted flow plate, cave...Falling Mouth, 6... Separation tube, enclosure...
Adjustment tube, r... annular gap, wing... inclined groove, wing...
Bottle, (capital)... Connection fitting, 91... Annular member, J... Brown rice falling port, Guo... Suction port, 94... Annular ascending air passage, 85... Annular descending air passage. , 8B... Sorting perforated plate, 97... Rotating body, 98... Pulley, 89...
・Horizontal part, 100... Inclined part, 101... Connection fitting, 102... Waste rice removal body, 103... Horizontal part, 1
04... Vertical part, 105... Inclined part, 10G...
Lower passageway, 10? ... Swinging part, 108 ... Engagement groove, 109 ... Sorting perforated plate mounting frame, 110 ... Inner ring, 111 ... Outer ring, 112 ... Connecting piece, 113. ...Engagement groove, 114...Inner end, 115
... Outer end, 11B... Waste rice shaking chamber, 117... Insertion port, 118... Cleaning body, 119... Mounting rod, 12
0... Spring water outlet, 121... Good wood guide wall. 122... Waste rice removal o, 123... ; Waste rice guidance wall,
124... holder outlet, 125... holder guide wall, 12B
...Pulley, 127...Vertical axis roller, 128...
Horizontal axis roller, 129...Windmill room, 130...Windmill, 1
31... Axial tube, 132... Discharge port.

Claims (1)

[Claims] The grain is fed out radially by the rotation of a feeding body 67 fixed to the vertical rotating shaft 20, and an annular elastic plate 59 is provided on the outside of the feeding body 67 to enable vertical impact removal. , a dispersing body for rotating and dispersing the supplied grains and a feeding body for rotating and sending the dispersed grains downward while increasing the speed are provided on the upper part of the dispensing body 67. A vertical impact-type debonding device that gradually increases the speed until it reaches the end.