KR20160128232A - Hulling apparatus - Google Patents

Abstract

While rice is uniformly arranged in a shaft core direction of an impeller part, the rice is allowed to collide into a dehulling part, thereby efficiently performing a work. An impeller part (6) is installed along the outer circumference of a rice supply part, and rotates to guide the rice, which has been discharged from the rice supply part (7), to the outside in a diameter direction. A dehulling part (9) collects the rice and dehulls the rice through collision. The rice supply part (7) has a cylindrical-shaped space with a width corresponding to the width in a rotation shaft core direction of the impeller part (6). The impeller part (6) includes: a plurality of blade sieves (14) extended in a radial direction; and a dispersion guide part (15) for dispersing the rice discharged from the rice supply part (7) in a rotation shaft core direction. The dispersion guide part (15) includes a plurality of rice passage parts (36) parallel with each other in the rotation shaft core direction. The rice passage part has a horizontal width to allow the passage of one grain of rice through the outside in a diameter direction along the rotation shaft core. The plurality of rice passage parts are hung on the entire region in a circumferential direction.

Description

{HULLING APPARATUS}

The present invention relates to an impeller type mezzanine device.

In the impeller type weft apparatus, the periphery of the impeller portion is covered by the casing, and a liner (demoulding portion) made of a soft material such as urethane, for example, is provided at a position corresponding to the outer peripheral portion of the impeller portion in the casing. The rice is supplied from the rice supply portion provided in the radially inward side of the impeller portion and the impeller portion is rotated so that the rice is guided radially outward by centrifugal force to collide with the debris portion and the debris treatment is performed by the impact have. A plurality of through holes are formed in the cylindrical rice guide body provided in the rice supply portion so as to allow rice to pass through one by one so that the rice is supplied to the impeller portion in a state in which the rice is evenly distributed in the direction of the rotation axis, (See, for example, Patent Document 1).

Japanese Patent Application Laid-Open No. 2001-205113

In the above-described conventional configuration, the rice is uniformly arranged in the direction of the rotation axis of the impeller portion so as to collide with the debris portion in a state of no deviation, so that good debris treatment is performed. However, in the above-described conventional structure, when rice is carried in a state in which it is superimposed on the rice supply portion, the rice can not pass smoothly through the through hole, and the rice stays in a large amount, so that there is a possibility that the rice can not be efficiently eaten.

Therefore, it is desired that the rice can be efficiently collided while being able to collide with the debris while keeping the rice as uniform as possible in the direction of the axis of rotation of the impeller.

In the characteristic configuration of the saucer apparatus according to the present invention,

A rice feeder for discharging the rice transferred from the outside to the outside in the radial direction,

The rice feeder is provided along the outer periphery of the rice feeder to receive the rice discharged from the rice feeder and rotates about the rotation axis located at the center of the rice feeder to guide the rice discharged from the rice feeder outward in the radial direction An impeller portion,

Wherein the impeller portion receives the rice guided by the impeller portion,

Wherein the rice supply portion has a width corresponding to the width of the impeller portion in the direction of the rotation axis,

Wherein a guide surface for guiding the rice carried from one side in the direction of the axis of rotation to the other side is provided on the outer periphery of the rice feed portion from the one side to the other side,

Wherein the impeller portion includes a plurality of blade bodies extending radially outwardly from an inner side in the radial direction and a plurality of blade bodies extending in a radial direction from the inner side in the radial direction, And a dispersion guide portion

Wherein the dispersion guiding portion includes a plurality of rice passage portions arranged in parallel in the direction of the rotation axis,

The rice passage portion has a lateral width allowing passage of rice or a plurality of rice eggs in the radial direction outward along the direction of the rotation axis, and is provided so as to extend over the entire circumferential direction.

According to the present invention, rice is fed from one side in the direction of the axis of rotation to the rice feeder, and the fed rice is guided to the other side in the direction of the axis of rotation by a guide surface provided from one side to the other side in the direction of the axis of rotation. Then, the loaded rice is discharged outward in the radial direction. That is, even when rice is uniformly fed from one side in the direction of the axis of rotation in the rice feed section, the rice becomes a state of spreading from one side to the other side, and is discharged toward the impeller section in a state where there is little bias.

The impeller portion is provided with a dispersion guide portion for dispersing the rice discharged from the rice feed portion along the direction of the rotation axis. The dispersing guide portion has a plurality of rice passage portions arranged in parallel in the direction of the axis of rotation. Since the rice passage portion has a lateral width allowing only one or a plurality of rice balls to pass radially outward along the direction of the axis of rotation, the rice overflowing without passing through one rice passage portion is sequentially So that it can be surely dispersed along the direction of the rotation axis.

Further, since the rice passage portion is provided so as to extend over the entire circumferential direction, even if rice is supplied in a superimposed state from the rice supply portion, the rice supplied from the rice supply portion is prevented from staying with the rotation of the impeller portion , And is smoothly guided to pass through the rice passage portion. As a result, it is possible to smoothly guide the rice supplied from the rice feeder, without dispersing, in a state of being dispersed along the direction of the rotation axis.

Therefore, it is possible to collide the rice with the debris while keeping the rice as uniform as possible in the direction of the axis of rotation of the impeller, and it is possible to perform the operation efficiently.

In the present invention, it is preferable that the dispersed guide portion includes a rectifying guide path for guiding the rice to the outside in the radial direction in a rectified state in a state where the rice is divided for each rice passage portion.

According to this configuration, the rice separated for each rice passage portion is guided to the rectified state in the radially outward direction in the rectifying guide path without mixing the rice introduced from the respective rice guide portions. Therefore, In the dispersed state, it is directly transferred to the blade body in the radially outer side.

In the present invention, it is preferable that the dispersed guide portion is provided so that its radially outer end portion is located in the vicinity of the radially inward end portion of the blade body.

According to this configuration, since the dispersed guide portion and the blade body are brought into a close state, the rice guided in the dispersed state along the direction of the rotation axis by the dispersed guide portion can be directly transferred to the blade body, Can be prevented from being overlapped with each other.

In the present invention, it is preferable that a clearance for introducing rice is formed between the radially outer end of the rice feeder and the radially inner end of the dispersed guide.

According to this configuration, the rice feed section discharges the rice that is carried in from the outside to the outside in the radial direction, and the dispersion guide section guides the rice to receive and disperse the rice discharged from the rice supply section. At this time, the rice feed portion is in a fixed position, and the dispersed guide portion receives the rice while rotating. Since the clearance for introducing rice is formed, the rice can be smoothly conveyed from the fixed position rice feed portion toward the dispersed guide portion that is rotating, without staying.

In the present invention, it is preferable that the dispersed guide portion includes a plurality of partitioning bodies provided in a posture orthogonal to the rotary shaft center at a predetermined interval so as to form the rice passage portion, and a plurality of partitioning bodies arranged radially between the partitioning bodies And a slidably moving guide body which is integrally connected to the division forming body and is connected between the radially outer end of the rice feed part and the radially inner end of the sliding guide body, It is preferable that a radially outer end of the rice feeder and a radially inner end of the partition forming body are close to each other.

According to this configuration, in the region partitioned by the plurality of partition forming bodies that are orthogonal to the rotational axis, a plurality of rice passage portions are arranged in parallel in the direction of the rotational axis. Since the radially outward end of the rice feeder and the radially inward end of the segmented body are adjacent to each other after being dispersed once in the direction of the rotational axis through the plurality of rice passages, And is held at the corresponding rice passage portion without moving to the rice passage portion.

Since the clearance for introducing rice is formed between the rice feed section and the sliding guide body, the rice dispersed in the direction of the axis of rotation and guided to the respective rice passage sections is formed in the inside of the rice passage section, As shown in FIG. As a result, the rice is dispersed in the circumferential direction and guided sequentially outwardly in the radial direction from the plurality of sliding guide bodies.

Therefore, the rice is sequentially guided by the plurality of sliding guide members while being dispersed in the direction of the rotation axis, so that the rice can be guided toward the blade body without staying in the rice passage portion, Can be performed.

In the present invention, it is preferable that the rice feeder includes a cylindrical rice guide body, a rice inlet is formed at one end side of the rice guide body in the direction of the rotation axis, and a part of the rice guide body in the circumferential direction It is suitable if the rice puddle opening portion is formed.

According to this configuration, in the rice feed section, rice is carried from the rice inlet formed at one end side in the direction of the rotation axis of the cylindrical rice guide body having the cylindrical space. At this time, rice introduced from the outside is carried in a state of being diffused in the direction of the rotational axis in the cylindrical space. Then, the transferred rice is discharged radially outward from the rice discharging portion formed with an opening in a part of the circumference direction of the rice guide body.

Therefore, even if a large amount of rice is injected from the outside, the rice is discharged toward the impeller portion while being uniformly arranged in the direction of the rotation axis from the rice discharge portion, and the rice uniformization treatment in the direction of the rotation axis to the impeller portion is performed It becomes easy to do.

1 is a side view of an optional apparatus;
2 is a front view of an optional apparatus;
3 is a side view of the anatomical portion.
4 is an exploded perspective view of the hopper and the dispensing case;
5 is an exploded perspective view of the impeller portion;
6 is an exploded perspective view showing the state of installation of the blade body.
7 is an exploded perspective view of the dispersed guide.
8 is a longitudinal side view of an optional portion.
Fig. 9 is a longitudinal front view of an optional portion. Fig.
10 is a partial longitudinal side view showing the rice guide state of the rice guide block body.
11 is a side view showing a state in which the blade body and the rice guide block body are installed.
Fig. 12 is a longitudinal front view showing the installation state of the blade body and the rice guide block body. Fig.
Fig. 13 is a side view showing a dispersed guidance state of rice. Fig.
Fig. 14 is a front elevation view showing a distribution guiding state of rice. Fig.
Fig. 15 is a side view of an optional portion of another embodiment. Fig.
16 is a side view of a rice guide block body according to another embodiment;
17 is a front view of the rice guide block body of another embodiment.
Fig. 18 is a side view of an alternate embodiment of the present invention; Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of the saucer apparatus according to the present invention will be described with reference to the drawings. The saucer apparatus performs an arbitrary treatment of rice supplied from outside, that is, a disposal treatment for separating rice into rice husk and brown rice.

As shown in Figs. 1 and 2, the weaving machine according to the present invention comprises a hopper 2 for temporarily storing a rice M to be introduced from the outside, A lower guide portion 3 for guiding the rice M discharged downward from the hopper 2 downward and obliquely downward toward one side of the main body casing 1 and a guide portion 3 located outside the one side of the main body casing 1 A weft portion 4 for carrying out a weaving operation (removal processing) of rice discharged from the hopper 2 and guided down by the lower guide portion 3, an electric motor for driving located inside the body casing 1 (5) and the like.

The weft portion 4 includes an impeller portion 6 rotating at a high speed around a rotary axis X along the horizontal direction by the driving force of the electric motor 5, A rice feeder 7 for feeding rice, and a breather case 8 for covering them.

As shown in Figs. 1, 2 and 4, the desorption case 8 is formed in a substantially cylindrical shape having a circular shape when viewed from the side and having a predetermined width in the direction of the axis of rotation so as to cover the outer peripheral portion of the impeller portion 6 Respectively. The outer circumferential portion of the substantially cylindrical outer circumferential portion of the impeller portion 6 in the rejection case 8 is provided with a liner 9 as an outer delta portion for covering the outer circumferential portion of the impeller portion 6 on the inner surface side thereof . The liner 9 is formed in a strip shape using a soft material such as urethane. A conveying guide (not shown) for conveying a processed product (including brown rice, rice husks, untreated rice, etc.) after the picking is carried out by the blowing force generated by the rotation of the impeller portion 6, 8a are formed in a series. The lateral outer side portion 8b of the release case 8 is formed as a removable lid and is held in a closed state by a plurality of engagement holding openings 8c.

A cylindrical rice guide body 11 having a width corresponding to the width of the impeller portion 6 is provided in the rice supply portion 7 in the direction along the rotation axis X from a side of the rice supply portion 7 And is provided on the other side. A guide surface for guiding the rice conveyed to the outer peripheral portion of the rice feed portion 7 from one side in the direction along the rotation axis X to the other side is provided in the rice guide body 11. [

2, 4, and 5, the rice supply portion 7 is provided in a state of continuing to the lower side in the guiding direction of the lower guiding portion 3, and is connected to the rotary shaft center X of the impeller portion 6 And a cylindrical rice guide body 11 positioned on the same axis. The width of the rice guide body 11 in the direction of the axis of rotation corresponds to the width of the impeller portion 6 in the direction of the axis of rotation. The rice guide body (11) is provided with a rice inlet (12) at one end in the direction of the axis of rotation and the other end in the direction of the axis of rotation is closed at the side wall (10). The side wall portion 10 also serves as a bearing portion for rotatably supporting the drive shaft 41, which will be described later. A rice discharging portion 13 is formed by opening a part of a circumferential direction of the rice guide body 11. The rice discharging portion 13 has a wide width along the direction of the rotation axis and is opened at an angle of about 90 degrees along the circumferential direction (see FIG. 8).

The rice M guided down from the hopper 2 through the lower guide portion 3 passes through the rice inlet 12 and is guided into the inside of the rice guide body 11 as shown in Fig. And is connected to the lower guide portion 3 in a communicating manner. Therefore, the inner surface of the rice guide body 11 constitutes a guide surface for guiding the rice fed from one side in the direction of the rotation axis to the other side.

3, 8, and 9, the impeller portion 6 includes a plurality of blade bodies 14 extending radially outwardly from the radially inward side, a plurality of blade bodies 14 extending radially outwardly from the radial direction, ) Distributed along the direction of the rotational center axis and guiding the blades to a space between adjacent blade bodies.

The plurality of blade bodies 14 are formed by guiding the rice M supplied by the rice feeding section 7 in sliding directions on the sliding movement guide surface 16 extending in the radial direction, Outward.

As shown in Figs. 6, 8 and 10, each of the blade bodies 14 is provided with a main body portion 14a formed in a substantially U-shape by a plate-shaped metal material, and the width of the center of the main body portion 14a And a sliding guide surface 16 is formed on a wide surface. The back surface forming portion 14b for forming the back surface guide surface 17 on the opposite side of the sliding guide surface 16 is integrally formed with the main body portion 14a separately from the main body portion 14a forming the sliding guide surface 16, Respectively. An opening 14c is formed between the body portion 14a and the back surface forming portion 14b so as to be wider in the circumferential direction toward the outer side in the radial direction.

Shaped support plates 18 and 19 made of a synthetic resin material are provided on both sides of the blade body 14 in the direction of the axis of rotation and as shown in Figures 11 and 12, The left and right side surfaces 14d are bolted to the support plates 18 and 19, respectively.

5, 6, and 8, in a state in which each of the plurality of blade bodies 14 rotates integrally with the blade body 14 at a radially outer portion thereof, A rice guide block body 21 is provided as an inner sidewall portion having a collision surface 20 which is provided with a collision surface 20. Specifically, the impact surface 20 is inclined downward in the rotational direction toward the radially outer side with respect to the sliding guide surface 16.

The rice guide block body 21 is integrally formed by using a soft material made of urethane, which is a soft synthetic resin. The hardness of the rice guide block body 21 is set to a value lower than the hardness of the liner 9. If the hardness is too high, the risk of damage to the rice is increased. On the other hand, if the hardness is too low, there is a disadvantage that the detaching performance is deteriorated. Therefore, the hardness of the rice guide block body 21 is set to an appropriate value so as not to cause damage to the rice and reduce the detachment performance based on experiments and the like. Since the speed and angle when the rice hits the impact surface 20 are easier to manage than the liner 9, it is possible to maintain the removal performance even if the hardness is set to a little low.

As shown in Figs. 6, 11 and 12, the rice guide block body 21 is connected to the support plates 18 and 19 by two bolts 22 on both sides in the direction of the rotation axis. A metal female screw member 21 which covers the outer periphery of each bolt 22 and extends over the entire width of the rice guide block body 21 in the direction of the rotation center axis is used to securely bolt the rice guide block body 21 made of a soft material. (23). One end portion of the pair of female screw members 23 is integrally connected to the connecting portion 24 at one end in the direction of the axis of rotation and is connected to the insertion through hole 25 formed in the rice guide block body 21 And is inserted and inserted from the side.

10, the rice guide block body 21 has a state in which the base end portion 21a enters the opening 14c of the blade body 14 so as to extend in a radially outward direction of the blade body 14 Respectively. The rice guide block body (21) is provided with an extension portion (21b) extending from the proximal end portion (21a) toward the lower side in the radial direction toward the lower side in the rotational direction.

An impact surface 20 inclining downward in the rotational direction with respect to the sliding guide surface 16 of the blade body 14 in the radial direction is formed on the radially inner side of the extended portion 21b. In the impact surface 20, the rice which is slidably guided by the sliding guide surfaces 16 of the blade body 14 collides with each other, and the removal treatment is performed.

Between the sliding guide surface 16 of the blade body 14 and the impact surface 20 is formed a posture changing surface 26 curved so as to be positioned below the rotational direction in the radially outward direction. The posture change surface 26 guides the rice M guided outward in the radial direction from the sliding guide surface 16 to the impact surface 20 while changing the posture.

The attitude of the rice M to be slidably guided by the sliding guide surface 16 of the blade body 14 is changed to form the rice M as shown in Fig. The collision surface 20 is prevented from colliding with the most rigid portion of the end surface of the embryo, that is,

The landing surface 27 is formed in a position adjacent to the inside of the radial direction of the impact surface 20 of the rice guide block body 21 so as to be recessed with respect to the attitude changing surface 26. [ A step is formed in the circumferential direction between the arc surface 27 and the radially outer end of the posture changing surface 26 so that the rice guided by the posture changing surface 26 goes beyond the step to form the impact surface 20 So that the impact force against the impact surface 20 is increased.

The rice guide block body 21 is provided with a throwing operation surface 28 for throwing the processed product after colliding with the impact surface 20 toward the outer liner 9. [ The throwing action surface 28 is formed so as to follow the impact surface 20 and is inclined at an inclination angle larger than that of the impact surface 20 so as to be positioned below the rotational direction in the radially outward direction.

10, the processed material after colliding with the collision surface 20 is subjected to the thrusting action by the thighing action surface 28, so that the outer liner 9 can be prevented from falling off, Toward the liner 9 at an angle as close as possible to the tangential direction. As a result, when the processed product is discharged and collides against the liner 9, the impact force is lowered, and there is less possibility that the processed product is damaged, such as brown rice or rice blooms, the embryo part is missing,

As shown in Figs. 8 and 10, the rice guide block body 21 is overlapped with the blade body 14 adjacent to the lower side in the rotational direction along the rotational direction. Specifically, the lower end position L1 in the rotational direction of the extension portion 21b of the rice guide block body 21 is located at the rotational end upper end position (in the rotational direction) of the blade body 14 L2 in the rotational direction. That is, the rice guide block body 21 is provided in a state of overlapping in the rotating direction with respect to the blade body 14 adjacent to the lower side in the rotating direction, and the distance between the rice guide block body 21 and the blade body 14 Is set to be narrow. An outer guide surface 29 is formed at the radially outer end of the rice guide block body 21 so as to be substantially parallel to the inner circumferential surface of the liner 9.

Next, the distributed guide unit 15 will be described.

The dispersed guide portion 15 has a plurality of rice passage portions 36 arranged in parallel to each other in the direction of the axis of rotation and the rice passage portions 36 are arranged in the radial direction And has a lateral width allowing passage to the outside, and is provided so as to extend over the entire circumferential direction.

7, the dispersion guide section 15 includes a plurality of partition forming members 30 arranged in a posture orthogonal to the rotational axis with a predetermined interval along the rotational center axis direction, A plurality of sliding guide members 31 arranged radially with an interval therebetween and connecting members 32 and 33 connecting the sliding guide members 31 at both sides in the direction of the rotational axis are provided, Are integrally assembled and mounted. The partition forming member 30, the sliding guide member 31, and the connecting members 32 and 33 are formed of a metal material.

The partition forming member 30 is an annular plate, and slits 34 are formed along the radial direction at intervals in the circumferential direction. The sliding guide member 31 is formed of a rectangular plate extending in the radial and rotational axis directions and inserted into the slit 34 with respect to the plurality of partition forming members 30, And a sliding guide member 31 are assembled and mounted in a lattice shape.

At both lateral ends of the sliding guide member 31 in the direction of the rotation axis, a mounting portion 35 bent in a substantially L-shape is formed. The connecting members 32 and 33 on both sides are bolted to the mounting portions 35 of the plurality of sliding guide members 31 and are connected to the plurality of partition forming members 30, the plurality of sliding guide members 31, The connecting members 32 and 33 are integrally fixed to each other.

One rice passage portion 36 is formed in the region surrounded by the adjacent two partition forming members 30. [ The rice passage portion 36 has a lateral width allowing the passage of rice in the radial direction outward along the direction of the axis of rotation and is formed in a plurality of portions in a state of being arranged in the rotational axis direction. Specifically, the width of one rice passage portion 36 is set narrower than the width of the rice M in the long direction and wider than the width of the rice M in the short direction. The rice passage portion 36 is formed so as to extend over the entire circumferential direction. Therefore, the rice passage portion 36 is partitioned into a plurality of regions in the circumferential direction by the plurality of sliding guide members 31. [0054]

The distribution guide section 15 is a guide section for guiding the rice M having passed through each of the plurality of rice passage sections 36 to the outside in the radial direction in a state of being separated for each rice passage section 36, And a path Q is provided.

The partition forming member 30 and the sliding guide member 31 are positioned at a position close to the outer peripheral portion of the rice guide body 11 in the rice supply portion 7, And is formed wide in the radial direction from the radially inner end. The region surrounded by the partition forming member 30 and the sliding guide member 31 is located at a position nearer to the outer peripheral portion of the rice guide body 11 in the rice feeding section 7 than the diameter of the plurality of blade bodies 14 And the rectifying guide path Q is formed by the long path in the radial direction. In the state where the rice is divided for each rice passage portion 36, the rectifying guide passage Q is formed in a radially outward direction And has a function of guiding it to a rectified state.

13, the partition forming member 30 and the sliding guide member 31 of the dispersed guide portion 15 are arranged such that the radially outer end portions of the partition forming member 30 and the sliding guide member 31 respectively extend in the radial direction of the plurality of blade bodies 14 And is provided close to the inner end. A gap S for introducing rice is formed between the radially outer end of the rice feeder 7 and the radially inner end of the sliding guide member 31 in the dispersed guide 15. [ The radially outer end of the rice feeder 7 and the radially inner end of the partition forming member 30 are close to each other.

As shown in Figs. 5 and 7, of the pair of connecting members 32 and 33 for connecting and fixing the plurality of sliding guide members 31 to the opposite side (outer side) from the main body casing 1 The outer connecting member 32 is supported by the plurality of bolts 37 dispersed in the circumferential direction so that the outer supporting member 18 and the outer supporting member 18 located on the opposite side to the main casing 1 Is connected to the plate (18). A plurality of bolts 37 are welded and fixed to the outer connecting member 32 and inserted through the screw insertion through holes 38 formed in the outer support plate 18 and are inserted into the outer support plate 18 And is fastened and fixed from the outside to the nut 40 through the inserted external mounting plate 39. In this way, the dispersed guide portion 15 is integrally fixed to the outer support plate 18.

2 and 9, the liquid is supplied from the interior of the main body casing 1 through the lower guide portion 3 and the central portion of the rice supply portion 7 to the outer support plate 18 extending in the axial direction. Although not described in detail, the drive shaft 41 is rotatably supported by bearings at several points as required, and is connected to an electric motor 5 provided inside the main casing 1 in an interlocking manner.

5 and 9, the shaft connecting member 42 is connected to an end portion of the drive shaft 41 on the opposite side to the main body casing 1. The shaft connecting member 42 includes a boss portion 44 to be fitted to the insertion through hole 43 formed in the outer support plate 18 and a boss portion 44 which is inserted into the boss portion 44, (45).

The drive shaft 41 is fit-connected to the boss portion 44 so as to be able to transmit torque, and is prevented from being dislodged by a screw. The mounting portion 45 is connected to the outer support plate 18 by a plurality of bolts 46 dispersed in the circumferential direction. A plurality of bolts 46 are welded and fixed to the shaft connecting member 42 side so as to penetrate a screw insertion through hole 47 formed in the outer support plate 18 and to be inserted into the outer side of the outer support plate 18 And is fastened and fixed from the outside to the nut 48. The outer mounting plate 39, In this way, the drive shaft 41 and the outer support plate 18 are linked together.

As is apparent from the above description, the plurality of blade bodies 14, the plurality of rice guide block bodies 21, and the respective support plates 18, 19 are bolted together and integrally fixed, And the drive shaft 41 and the outer support plate 18 are interlocked and connected to each other. Therefore, the impeller portion 6 is integrally connected to the aforementioned members and is rotatably provided around the axis (= rotary axis X) of the drive shaft 41.

The rice M discharged from the rice discharging portion 13 in the rice supplying portion 7 is supplied between the radially outer end of the rice supplying portion 7 and the radially inner end of the dispersing guide 15. The rice M supplied between the radially outer end of the rice feed portion 7 and the radially inner end of the dispersed guide portion 15 is guided by the dispersed guide portion 15 being rotated when the impeller portion 6 rotates, Is guided outward in the radial direction in a state of being dispersed in the plurality of rice passage portions (36)

The rice guiding portion 3 guides the rice M introduced into the rice guide body 11 from the rice discharging portion 13 to the outside. At that time, one rice passage M is allowed to sequentially enter the one rice passage portion 36 in the direction of the axis of rotation. As described above, since the width along the direction of the rotation axis of the rice passage portion 36 is set to be regulated so as to be restricted by one row, the rice discharged from the rice discharge portion 13 is uniformly distributed in the direction of the rotation axis, To the plurality of rice passage portions 36 arranged in the direction of the rotation axis. And is dispersed in the direction of the rotation axis as described above. The division forming member 30 is rotated so that the lengthwise direction of the rice M is set to be in a posture along the radial direction of the rice feed portion 7 by the friction between the partition forming member 30 and the rice M. [ Can be aligned.

Since the radially outer end of the rice feeder 7 and the radially inner end of the partition forming member 30 are close to each other, After entering the passing portion 36, it is prevented from moving to the adjacent rice passage portion 36 in the direction of the axis of rotation.

Since the gap S for introducing rice is formed between the radially outer end of the rice feeder 7 and the radially inner end of the sliding guide member 31, 6 are dispersed in the circumferential direction through the clearance S between the rice supply portion 7 and the sliding guide member 31. As a result, The rice M is guided into the rice passage portion 36 in succession in one rice passage portion 36 in a circumferential direction. The rice M introduced into the rice passage portion 36 is guided by the radially provided sliding guide member 31 and radially outward due to the centrifugal force accompanying the rotation.

13 and 14, since the radially outer end of each of the partition forming member 30 and the sliding guide member 31 is close to the radially inner end of the blade body 14, The rice M guided along the radial direction of the inside of the passing portion 36 is guided to the blade body 14 in the rectified state toward the radially outward side of the blade body 14 without interfering with each other.

In the blade body 14, the rice M guided from the dispersed guide portion 15 is inherited as it is and is guided by sliding on the sliding guide surface 16 and guided by sliding, Outward. As shown in Fig. 10, the rice which is slidably guided by the sliding guide surface 16 is guided by the posture changing surface 26 formed at the radially outer end of the rice guide block body 21 Is guided toward the impact surface (20).

When the rice (M) impacts the impact surface (20), the impact is carried out by the impact to separate the rice (M) into rice husk and brown rice. However, some of the rice (M) may remain without being detached. The processed product including rice husks, brown rice and untreated rice is thrown toward the outer liner 9 by the throwing action surface 28 as the impeller portion 6 rotates, The removal processing is performed again.

The processed product after colliding with the outer liner 9 is conveyed to the outside of the sorting device (not shown) through the conveying guide portion 8a by the wind power generated by the rotation of the impeller portion 6 rotating at high speed Lt; / RTI > In the sorting apparatus, a sorting process is performed to separate the rice husk and the brown rice. In addition, since the detachability can be improved in the saucer apparatus having the above-described configuration, it is possible to omit a special sorting mechanism for sorting the brown rice and the untreated rice, which is required in the conventional saucer apparatus, in the sorting apparatus, It is possible to downsize and simplify the configuration.

The liner 9 and the blade member 14, which are large members in the above-described configuration, need to be replaced in the early stage. There is little possibility of wear on the rice guide block body 21, and the rice exchange guide block body 21 has only a high exchange frequency, which is advantageous in coping with low cost.

[Other Embodiments]

(1) In the above embodiment, the dispersion guide section 15 is provided with the rectification guide path Q for guiding the rice in the radially outward rectified state. However, instead of this configuration, the dispersion guide section 15 may be provided so as to be narrow in the radial direction and have a function of merely dispersing the rice in the direction of the rotation axis.

(2) In the above embodiment, the gap S for introducing rice is formed between the radially outer end of the rice feeder 7 and the radially inner end of the dispersed guide 15. However, It is also possible to adopt a configuration in which they are provided in a close state without forming gaps S for introduction.

(3) In the above embodiment, the rice passage portion 36 has a lateral width allowing the passage of one egg in the radial direction outward along the rotation axis direction. However, instead of this configuration, The portion 36 may have a transverse width that allows passage of rice seeds in the radial direction outward along the direction of the axis of rotation.

(4) In the above-described embodiment, the plurality of blade bodies 14 and the dispersed guide portion 15 are constituted by separate members, but they may be integrally formed.

(5) In the above embodiment, only the outer guide surface 29 is formed at the radially outer end of the rice guide block body 21 as the inner deck, but instead of this configuration, as described below, A protrusion that protrudes outward in the radial direction and that has a large width in the direction of the rotation axis may be formed.

An outer guide surface 29 is formed at the radially outer end of the rice guide block body 21 as an inner depressed portion and substantially parallel to the inner peripheral surface of the outer depressed portion and the outer guide surface 29 Protruding toward the outer side along the radial direction, may be formed from the uppermost position in the direction of rotation of the outer guide surface 29 in the radial direction. As shown in Figs. 16 and 17, the projections 51 are formed in a wide width over the entire width of the rice guide block body 21 in the direction of the axis of rotation.

18, the rear surface portion 50 extending from the base end portion 21a of the rice guide block body 21 to the outer guide surface 29 is formed as a flat surface, and not the outer guide surface 29, Protrusions 51 projecting in a direction substantially perpendicular to the back surface 50 may be formed from the end portions on the side of the outer guide surface 29 of the base 50. In this configuration, the projections 51 are formed not in the radially outward direction but in an inclined state located on the upper side in the rotational direction as they are located radially outward.

15 to 18, the projections 51 are not limited to be formed in a wide width over the entire width of the rotation axis direction of the rice guide block body 21, And it may be set to a range of only a part of the width of the rice guide block body 21 in the direction of the rotation axis.

(6) In the above embodiment, the step is formed between the impact surface 20 and the posture alteration surface 26. Instead of this configuration, as shown in Figs. 15 and 18, And the attitude change surface 26 may be formed in a series of succession.

(7) In the above embodiment, the rice feed section 7 is provided with the rice inlet 12 with one side opened in the direction of the rotation axis, and a part of the circumferential direction is opened, (11), but the present invention is not limited to this configuration. For example, as the rice guide body, there may be used a structure in which the discharge portion is opened from one side to the other side in the direction of the rotation axis, or a form in which a part of the region in the direction of the rotation axis is divided. can do.

(8) In the above-described embodiment, the rice guide block body 21 as the inner deck is provided on the outer side in the radial direction of the blade body 14, and the rice guide block body 21 is made of urethane which is a soft synthetic resin However, the rice guide block body 21 may be formed by using other kinds of soft materials such as rubber, for example. The inner guide portion (rice guide block body 21) Or may be omitted.

The present invention can be applied to an impeller-type saucer apparatus.

6: Impeller section
7: rice feeder
9:
11: rice guide body
12: Rice entrance
13: Rice discharge section
14:
15: Dispersion guide
30:
31: Sliding guide body
36: rice passage part
Q: Rectification guide path
S: Clearance

Claims (9)

A rice feeder for discharging the rice transferred from the outside to the outside in the radial direction,
The rice feeder is provided along the outer periphery of the rice feeder to receive the rice discharged from the rice feeder and rotates about the rotation axis located at the center of the rice feeder to guide the rice discharged from the rice feeder outward in the radial direction An impeller portion,
Wherein the impeller portion receives the rice guided by the impeller portion,
Wherein the rice supply portion has a width corresponding to the width of the impeller portion in the direction of the rotation axis,
Wherein a guide surface for guiding the rice carried from one side in the direction of the axis of rotation to the other side is provided on the outer periphery of the rice feed portion from the one side to the other side,
Wherein the impeller portion includes a plurality of blade bodies extending radially outwardly from an inner side in the radial direction and a plurality of blade bodies extending in a radial direction from the inner side in the radial direction, And a dispersion guide portion
Wherein the dispersion guiding portion includes a plurality of rice passage portions arranged in parallel in the direction of the rotation axis,
Wherein the rice passage portion has a lateral width allowing passage of one or more eggs of rice in the radial direction outward along the direction of the rotation axis and is provided so as to extend over the entire circumferential direction. The method according to claim 1,
Wherein the dispersion guiding portion includes a rectifying guide path for guiding the rice in a rectified state toward the radially outer side in a state where the rice is divided for each rice passage portion. The method according to claim 1,
And the dispersed guide portion is provided in a state in which its radially outer end is close to the radially inward end of the blade body. 3. The method of claim 2,
And the dispersed guide portion is provided in a state in which its radially outer end is close to the radially inward end of the blade body. 5. The method according to any one of claims 1 to 4,
Wherein a clearance for introducing rice is formed between the radially outer end of the rice feeder and the radially inner end of the dispersed guide. 6. The method of claim 5,
Wherein the dispersion guiding portion includes a plurality of partitioning bodies provided in a posture orthogonal to the rotary shaft center at a predetermined interval to form the rice passage portion and a plurality of radial sliding movement guides Wherein the partition forming body and the sliding movement guide body are integrally connected to each other,
A gap for introducing the rice is formed between the radially outer end of the rice feeder and the radially inner end of the sliding guide,
Wherein the radially outer end of the rice feeder and the radially inner end of the compartment are close to each other. 5. The method according to any one of claims 1 to 4,
Wherein the rice supply portion comprises a cylindrical rice guide body and a rice inlet is formed at one end side of the rice guide body in the direction of the rotation axis of the rice guide body and a portion of the circumference of the rice guide body is opened Wherein an outlet is formed. 6. The method of claim 5,
Wherein the rice supply portion comprises a cylindrical rice guide body and a rice inlet is formed at one end side of the rice guide body in the direction of the rotation axis of the rice guide body and a portion of the circumference of the rice guide body is opened Wherein an outlet is formed. The method according to claim 6,
Wherein the rice supply portion comprises a cylindrical rice guide body and a rice inlet is formed at one end side of the rice guide body in the direction of the rotation axis of the rice guide body and a portion of the circumference of the rice guide body is opened Wherein an outlet is formed.

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