TW201503961A - Rice hulling device - Google Patents

Abstract

A rice hulling device of the invention comprises a pair of rubber rollers 4 and 5 on a base section 24, wherein one of the pair of rubber rollers 4 and 5 is supported at both ends by fixed bearings 23 to act as a fixed roller, and the other is supported at both ends by moving bearings 22 to act as a movable roller. On one of each of the fixed bearings 22 and the moving bearings 23, seat sections 25 and 35 are provided which can slide in a direction away from the ends of the support shafts that support the rubber rollers 4 and 5, and these seat sections can be turned to a position that does not interfere with the movement in the axial direction of the rubber rollers 4 and 5.

Description

Stripping machine

The present invention relates to a husking machine, and more particularly to a husking machine which is excellent in husking treatment ability.

In the case of a processing machine for cereals such as rice, a threshing machine is known, and the chaff is detached from the grain to become brown rice. In the case of the threshing method of the threshing machine, a rubber roll type is known in which a pair of rubber rolls are disposed to face each other with a gap therebetween, so that the pair of rubber rolls are mutually different from each other at a peripheral speed. Rotating in the opposite direction, the grain is supplied to the roll gap, and the threshing shell is performed by the circumferential speed difference between the rolls and the shear breaking force.

The rubber roll type threshing machine is a rubber roll which is formed by fixing a rubber ring to a core made of cast iron. According to JISB9124 of the Japanese Industrial Standard, the shape and size of the rubber roll are in the range of 153 to 254 mm in diameter and 63.0 to 152.4 mm in width. Further, if such a JIS-standard general-purpose rubber roll is used, the rubber roll size determines the brown rice discharge capacity of the threshing machine. For example, in the case of a 3-inch type threshing machine using a 3-inch rubber roll, the brown rice discharge capacity is approximately 0.8 metric tons/h, and if it is a 10-inch type husking machine using a 10-inch rubber roll, The capacity of brown rice is approximately 5 metric tons per hour.

Thus, the brown rice discharge capacity of the rubber roll type husking machine is determined according to the diameter of the rubber roll, but it is also known that a technique is used to combine the general rubber rolls to further increase the brown rice discharge capacity to be higher than the ordinary husking machine. . For example, Patent Document 1 provides a threshing machine which is formed by laminating two 10 inch rubber rolls in the axial direction to form a long rubber roll, and has a pair of the strip rubber rolls. , and the ability to discharge brown rice is doubled from the conventional 10-inch stripping machine.

However, in the threshing machine described in Patent Document 1, since the rubber roll is formed in a long shape, the support shaft of the rubber roll is also elongated, and at least two workers must be replaced by rubber rolls. The roll replacement operation becomes a problem of heavy weight. Further, when the rubber roll is removed from the long support shaft, the bearing fixed to the support shaft side must be taken out, which has a problem of greatly consuming work time. [Prior Art Literature] [Patent Literature]

[Patent Document 1]: China Utility Model Bulletin No. 2420058

[The problem that the invention wants to solve]

The problem to be solved by the present invention is that the rubber roll replacement work of the threshing machine becomes heavy and the operation time is greatly consumed. [The way to solve the problem]

The threshing machine of the present invention has a pair of rubber rolls on the base portion, and one of the pair of rubber rolls is supported as a fixed roll on both sides by a fixed bearing to move the bearing to support the other side on the both sides. As a moving roll, each rubber roll is rotationally driven at mutually different peripheral speeds and in opposite directions to each other. On the other hand, the moving bearing has a roll opening and closing mechanism capable of adjusting the width of the roll gap, which is characterized in that the double side support The fixed bearing and the double-sided supported moving bearing are respectively provided with a seat portion which is slidable away from the axial end of the support shaft supporting the rubber roller, and is rotatable to avoid the rubber The position at which the rolls create interference.

The groating machine can be provided in each of the seat portions provided with the fixed bearing and the moving bearing, and is provided with a sliding shaft coupled to the base portion such that the fixed bearing and the moving bearing are away from the axial end of the supporting shaft Slide and rotate to a position that avoids interference with the rubber roll.

The stripping machine can form a support shaft that supports the rubber roll into an elongated shape, and a plurality of rubber rolls are axially coupled in the axial direction of the elongated support shaft to form a long rubber roll, and The base portion has a pair of the elongated rubber rolls.

The threshing machine can have a guide chute above the pair of rubber rolls, and can manually change the down position or the inclination angle, and feed the raw material into a gap of the pair of rubber rolls in a strip shape.

The threshing machine can flow the raw material grain into a strip shape having the same width as the width of the rubber roll and flow down from the guide chute.

The groating machine can form the roll opening and closing mechanism by: a roll opening and closing link rotatably provided via the seat on the base portion; and a fulcrum disposed on the roll opening and closing a lower end of the rod; a bearing portion disposed at an intermediate portion of the roll opening and closing link; a roll opening and closing support shaft disposed at an upper end of the roll opening and closing link; and a roll opening and closing cylinder coupled to the roll opening and closing support shaft.

The stripping machine can axially connect the small diameter pulley and the large diameter pulley to the rear end portions of the pair of rubber roller supporting shafts, and can change the peripheral speed of each rubber roller, so that the rubber roller originally rotating at a low speed becomes a high speed. The rubber roller that originally rotated at a high speed became a low speed. [Effects of the Invention]

According to the threshing machine of the present invention, if the rubber roll continues to wear and reaches the replacement period, first, the operator steps on the working step of the husking machine, and moves the seat portion of the moving bearing and the seat portion of the fixed bearing to the axial direction. slide. The seat portion of the moving bearing and the seat portion of the fixed bearing are respectively provided with a sliding shaft coupled to the base portion, and the seat portion of the moving bearing and the seat portion of the fixed bearing are moved away from the axial end of the support shaft of the rubber roller, The bearing portion is pulled out from the support shaft of the rubber roll. Next, the seat portion of the moving bearing is rotated clockwise around the sliding shaft, and the seat portion of the fixed bearing is rotated counterclockwise. Thereby, there is no member that interferes with the rubber roll in the axial direction, and the rubber roll replacement operation becomes extremely easy.

In the husking machine, a sliding shaft coupled to the base portion is provided in each of the fixed bearing and the movable bearing, so that the fixed bearing and the moving bearing are away from the support shaft. When the direction of the shaft end slides and is rotated to avoid interference with the axial movement of the rubber roller, the bearing portion can be pulled out from the support shaft of the rubber roller by an inexpensive and easy configuration, and the axial direction of the rubber roller can be avoided. The action produces interference.

In the husking machine, the support shaft supporting the rubber roll is formed into a long shape, and a plurality of rubber rolls are axially coupled to the axial direction of the elongated support shaft to form a long rubber roll. When the rubber roller is removed from the long-shaped support shaft, it is not necessary to take out the bearing fixed to the support shaft side, and the rubber roller replacement operation becomes a simple operation, and the work requires one person. Moreover, the work of removing the rubber roll from the support shaft is also simple, and the work time can be greatly shortened.

In the husking machine, when there is a guide chute that can manually change the downflow position or the inclination angle and supply the raw material in a strip shape to the gap between the pair of rubber rolls, During the sliding on the guide chute, the posture of the raw material grain is adjusted so that the longitudinal direction of the raw material grain is parallel to the sliding direction of the raw material grain, and almost all the time when it falls to the gap between the pair of rubber rolls Raw material grains are lined up in the long-side direction to reduce the generation of broken rice. When the raw material grain at this time is supplied from the guide chute in a strip shape having the same width as the width of the rubber roll which is connected in the axial direction, the processing ability of the threshing shell is further improved.

In the groating machine, a roll opening and closing mechanism is formed by: a roll opening and closing link erected so as to be rotatable by a seat portion on a base portion; and a fulcrum disposed at a lower end of the roll opening and closing link a bearing portion is disposed at an intermediate portion of the roll opening and closing link; a roll opening and closing support shaft is disposed at an upper end of the roll opening and closing link; and a roll opening and closing cylinder is coupled to the roll opening and closing support shaft; and if so, even if, for example, is formed In the case of a long rubber roll, the difference in the width adjustment of the axial roll gap can be eliminated, and the gap can be maintained constant in any part of the roll.

In the husking machine, the small diameter pulley and the large diameter pulley are respectively coupled to the rear end portions of the pair of rubber roller support shafts, and the peripheral speeds of the respective rubber rolls are changed to respectively rotate the rubber originally rotated at a low speed. The roll becomes a high speed, and the rubber roll which is originally rotated at a high speed becomes a low speed, that is, when the rubber roll continues to wear to a certain extent, the rubber roll which is originally rotated at a low speed becomes a high speed by changing the peripheral speed, respectively, and is rotated at a high speed. The rubber roll becomes a low speed, that is, the abrasion of the rubber roll can be equalized and the replacement period of the rubber roll is delayed.

[Preferred form of implementing the invention]

The form in which the present invention is carried out will be described below with reference to the drawings. Fig. 1 is a perspective view showing the entire structure of the threshing machine of the present invention, Fig. 2 is a front view of the threshing machine, and Fig. 3 is a schematic longitudinal sectional view showing the internal structure of the threshing machine.

(Embedded structure of the husking machine) As shown in Figs. 1 to 3, the main part of the husking machine 1 is composed of the following: the air selection unit 3, which is located in the body supported by the plurality of pillars 2 The inner air-selecting passage carries out the air-selection of the shelled rice; the threshing shell portion 6 is composed of a pair of rubber rolls 4 and 5, and is placed above the air-selecting portion 3, so that one is subjected to the fixed bearing Supported, the other is supported by a moving bearing that is freely movable in the far and near direction with respect to the fixed bearing, and rotates at mutually different circumferential speeds in opposite directions; the raw material supply portion 7 is placed on the threshing shell Above the portion 6, the raw material grain is stored, and the raw grain is supplied to the threshing portion 6, and the suction pipe 8 is provided on the side of the air-selecting portion 3 and the threshing portion 6, by the wind Foreign matter, inclusions, and the like having a small specific gravity such as a chaff that is air-selected in the air-selecting portion 3 are removed by suction.

(Structure of Raw Material Supply Portion) As shown in Fig. 3, the raw material supply unit 7 is provided with a supply tank 9 for storing raw material grains fed from the raw material supply port 9a in the upper portion of the supply tank 9, which is supplied. The intermediate portion of the tank 9 is provided with a shutter 10 for feeding raw material grains stored in the supply tank 9 into the machine. The opening and closing of the shutter 10 is controlled by the switching control of the air compressor cylinder 11 provided on the side of the supply tank 9. A flow regulating valve 12 is provided at a lower portion of the gate 10. As shown in FIG. 2, the opening degree of the flow regulating valve 12 can be adjusted by rotating the adjustment knob 13. Agitating roller 14 that is rotated by a suitable zone mechanism is provided below the flow regulating valve 12 as a conveying mechanism for conveying the raw material grain to the guiding chute as will be described later. Further, even if bridging of the raw material grain occurs between the flow rate adjusting valve 12 and the duct 15, the bridge can be broken by the rotation of the stirring roll 14, and the raw material grain can be conveyed downward. The component symbol 16 indicates a supply pipe, and the raw material grain dropped from the agitation roll 14 is supplied to a guide chute which will be described later.

Below the front end of the supply duct 16, a guide chute 17 for feeding the raw material grains dropped from the agitation roll 14 to the rubber rolls 4, 5 of the threshing shell portion 6 is provided at a predetermined inclination angle. The guide rail 17 is held by the slide frame 18, and the upper end of the slide frame 18 is mounted to be rotatable about the support shaft 19. The lower end of the slide frame 18 is fitted to the adjustment rod 20, The grip 21 is rotated to adjust the inclination of the guide chute 17. The width of the guide chute 17 is almost equal to the width of the pair of rubber rolls 4, 5. In addition, as long as the line connecting the guide chute 17 and the line connecting the central axes of rotation of the pair of rubber rolls 4 and 5 are substantially perpendicular, the raw material grains are rotated by a pair of rubber rolls. 4, 5 bounces the situation that the posture of the raw material is disordered, and the effect of suppressing the generation of the granules is reduced.

(Structure of the threshing shell portion) As shown in Fig. 3 to Fig. 6, the threshing shell portion 6 is configured such that the moving bearing 22 supports the rubber roller 4 on one side to rotate freely and far (in Fig. 2, the drawing) In the left-right direction, in the direction of the arrow T in Fig. 6, the fixed bearing 23 supports the rubber roller 5 on the other side, and each of the rubber rolls rotates in different directions from each other at different circumferential speeds. As shown in Fig. 6, the moving bearing 22 is composed of a member that opens and closes the link 26 so as to be erectable via a seat portion 25 on the base portion 24, and a support shaft 27 is provided on the roller. The lower end of the opening and closing link 26; the bearing portion 28 is provided at an intermediate portion of the roll opening and closing link 26; and the roll opening and closing mechanism 29 is provided at an upper end of the roll opening and closing link 26. Further, the roll opening and closing mechanism 29 is configured by a roll opening and closing support shaft 30 at the upper end of the roll opening and closing link 26, and a roll opening and closing cylinder 31 connected to the roll opening and closing support shaft 30. Further, the bearing portion 28 (the front side bearing portion 28a and the rear side bearing portion 28b) of the moving bearing 22 supports the elongated rubber roll supporting shaft 32 from both sides. Further, in the long rubber roll supporting shaft 32, two rubber rolls 4a and 4b are axially connected to the intermediate portion, and the small diameter pulley 33 and the large diameter pulley 34 are axially coupled to the rear end portion, and can be rotationally driven by the belt.

On the other hand, as shown in FIG. 6, the fixed bearing 23 is constituted by a bearing portion 36 which is erected by the seat portion 35 on the base portion 24. Further, the bearing portions of the fixed bearing 23, that is, the front side bearing portion 36a and the rear side bearing portion 36b support the long rubber roll supporting shaft 37 on both sides. Further, in the same manner as described above, the rubber roller support shaft 37 is configured such that two rubber rolls 5a and 5b are axially connected to the intermediate portion, and a large diameter pulley 38 and a small diameter pulley 39 are axially coupled to the rear end portion and rotatable by the belt. drive.

As shown in Fig. 3, a funnel-shaped valley duct 40, 41 is provided in the lower portion of the casing 6a of the threshing shell portion 6. Further, below the collecting ducts 40, 41, along the entire width of the rubber rolls 4, 5, there is provided a collision plate 42 which is located directly under the rubber rolls 4, 5 to cause the knocking of the falling rice to collide and to alleviate the flushing. Further, a suction port 43 is provided in the upper portion of the casing 6a, and dust or the like raised by the threshing process is sucked, and is connected to the suction pipe 8 via the suction pipe 44.

(Structure of the air-selecting portion) As shown in Fig. 3, the inside of the casing 3a of the air-selecting portion 3 is constituted by a downflow duct 45 for allowing the unpacking falling rice from the threshing shell portion 3 to flow down; The air-selecting passage 46 is configured to perform air-selection of the unpacked falling rice flowing down the down-flow duct 45; the equalizer 47 is disposed in the down-flow duct 45 for widening the width of the flow path of the unpacking and falling rice of the down-flow duct 45; A plurality of rectifying plates 48a, 48b are disposed in the air-selecting passage 46, so that the brown rice in the unpacking falling rice is vertically dropped without being sucked to the side of the air-selecting passage 46; the fine-discharge passage 49 is to be shelled. The mixed particles of the fine brown rice and the unhulled grain of the selected rice are discharged to the outside of the machine; and the chaff discharge passage 50 delivers the chaff and other inclusions in the unpacked rice to the suction pump 8 .

As shown in FIG. 5, the sizing unit 47 provided in the downflow duct 45 is formed by arranging a plurality of partition plates 47b to 47i on a wide fan-shaped slide plate 47a. shape. By means of the homogenizer 47, the width of the flow path can be broadened to, for example, approximately two times. Further, as shown in FIG. 3, the boutique discharge passage 49 is provided with a secondary air inlet 49a covered by a metal mesh, and has a structure in which the air separation capability of the air selection passage 46 is not lowered. Furthermore, the chamfer collision plate 51 is provided at the corner of the path of the chaff discharge passage 50 so that the frame does not wear due to the conflict of the chaff floating on the air passage 46.

(Structure of the suction filter tube) The suction filter tube 8 is formed by the suction duct 52 of the configuration in which the air flows longitudinally. A suction fan (not shown) is connected to the downstream side of the suction duct 52, and foreign matter or inclusions having a small specific gravity such as a chaff are sucked and removed by the wind.

(Structure of Rotation Drive Portion of Threshing Shell Portion) Next, the rotation drive portion of the threshing shell portion 6 will be described with reference to Fig. 4 . A drive motor 52 for rotational driving is attached to one side of the frame body 6a of the threshing shell portion 6, and the rubber rolls 4, 5 are rotationally driven by the rotational force of the drive motor 52. More specifically, the motor pulley 53 that is coupled to the motor shaft 52a of the drive motor 52 and the intermediate pulley 54 that is adjacent to the drive motor 52 are wound with a V-belt 55 that will be driven from the drive motor 52. The rotational force is first relayed by the intermediate pulley 54, and then the rotational force is transmitted to the respective portions. That is, the intermediate pulley 54, the large diameter pulley 34 that is axially coupled to the support shaft 32 of the rubber roller 4, and the small diameter pulley 39 that is axially coupled to the support shaft 37 of the rubber roller 5 are wound around the tension pulley 55. The belt 56 can thereby rotate the rubber rolls 4, 5 in different directions at mutually different peripheral speeds. The component symbol 61 is a pneumatic cylinder that exhibits the tension of the tension pulley 55.

On the other hand, the intermediate pulley 54 is also axially coupled to the intermediate pulley 57 of a small diameter on the same shaft. This is provided to rotationally drive the agitation roll 14, and the V-belt 59 is wound between the intermediate pulley 57 and the agitating pulley 58, so that the agitation roll 14 can be constantly rotated. Further, the component symbol 60 is a tension pulley that displays the V-belt 59. Further, as shown in FIG. 7, between the small diameter pulley 33 that is axially coupled to the support shaft 32 of the rubber roll 4, and the large diameter pulley 38 that is axially coupled to the support shaft 37 of the rubber roll 5, the tension pulley 55 is used. When the V-belt 56 is wound, the peripheral speed can be changed. Contrary to Fig. 4, the rubber roll 4 is rotated at a high speed, and the rubber roll 5 is rotated at a low speed.

(Moving Structure of Bearing) Next, the movement structure of the above bearing will be described with reference to Figs. 8A and 8B. 8A and 8B are schematic perspective views of the rubber roll removed from the rubber roll support shaft. As shown in FIG. 6, when the threshing shell portion 6 is driven, the seat portion 25 forming the moving bearing 22 and the seat portion 35 forming the fixed bearing 23 are fixed to the base portion 24 by bolts or the like. On the other hand, when the roller of the threshing shell portion 6 is replaced, if the bolt or the like is removed, the seat portions 25 and 35 can be moved away from the axial ends of the support shafts 32 and 37 by the slide shafts 62 and 63 (refer to Arrow (1) of Fig. 8A). When the seat portions 25 and 35 are moved and the bearing portions 28 and 36 are removed from the support shafts 32 and 37, the moving bearing 22 and the fixed bearing 23 can be rotated about the slide shafts 62 and 63 (refer to FIG. 8A). Arrow (2)).

(Removing and Attaching Method of Rubber Roller) As described above, the moving bearing 22 and the fixed bearing 23 are prevented from supporting the shafts 32, 37, and the rubber rolls 4, 5 do not interfere in the axial direction, as shown in Fig. 8B, loosened and fixed When the bolts or the like are used, the rubber rolls 4, 5 can be easily removed from the support shafts 32, 37.

(Operation) The action of the threshing machine 1 of the present invention in the above configuration will be described below. When the power source is turned on and the starter switch (not shown) is turned on to drive the drive motor 52, the rotational force of the motor pulley 53 is transmitted to the intermediate pulley 54 via the V-belt 55, and the rotational force is transmitted from the intermediate pulley 54 via the V-type. The belt 56 is transmitted to the large diameter pulley 34 and the small diameter pulley 39. Thereby, the pair of rubber rolls 4 and 5 rotate in the opposite direction to each other and have a speed difference in the peripheral speed. Moreover, the rotation force is transmitted from the small-diameter intermediate pulley 57 to the stirring pulley 58 via the V-belt 59, and the stirring roller 14 is rotated.

Further, when the air compressor cylinder 11 is actuated to open the shutter 10 and the flow rate adjusting valve 12 is adjusted, the raw material grain stored in the supply tank 9 is transferred to the lower side by the rotation of the stirring roller 14. The raw material grain reaching the supply pipe 16 falls into a belt shape on the guide chute 17, and during the sliding on the guide chute 17, the posture is adjusted so that the longitudinal direction of the raw material grain is parallel to the sliding direction of the raw material grain. At the point of time when the gap between the pair of rubber rolls 4 and 5 is dropped, almost all of the raw material grains are lined up in the longitudinal direction. At this time, the raw material grain is supplied in a strip shape having the same width as the width of the rubber rolls 4a and 4b connected to each other in the axial direction or the widths of 5a and 5b.

The guiding chute 17 adjusts the length and the inclination so that the raw material grain slides on the guiding chute 17 and is supplied to the rubber rolls 4 and 5 to accelerate to a speed close to the natural falling, and the supply speed of the raw material grain is adjusted. It becomes approximately 3 m/sec to 5 m/sec. The raw material grains are supplied to the rubber rolls 4 and 5 in a strip shape and a thin layer by the guide chutes 17. As a result, the rubber rolls 4 and 5 function uniformly in each of the raw material grains, and the shelling action is equalized and the shelling is efficiently performed. In particular, since the queuing action of the raw material grain in the longitudinal direction is made more reliable, the guide surface of the guide chute 17 may not be provided with a strip-shaped groove (not shown).

The following three kinds of mixed particles are produced by the raw material grains in the gap between the rubber rolls 4 and 5: brown rice, chaff, and unhulled grains which are removed from the chaff. Then, the mixed particles collide with the collision plate 42 of the air-selecting portion 3, and the chaff adhered to the brown rice is separated by the impact force at this time. Next, the mixed particles flow down the downflow pipe 45 and widen the flow path width by the homogenizer 47 to reach the air selection passage 46. In the air-selecting passage 46, in the case of the mixed particles, the foreign matter such as the chaff and the inclusions having a small specific gravity is sucked obliquely upward, and on the other hand, the brown rice having a larger specific gravity and the grain collide with the rectifying plate 48. And down to the boutique discharge channel 49 below. Further, the foreign matter such as the chaff and the inclusions having a small specific gravity is deflected in the direction in which the chaff collision plate 51 is deflected, and reaches the chaff discharge passage 50, and is discharged to the outside through the suction pipe 8. On the other hand, the brown rice and the grain having a large specific gravity are taken out from the discharge port 49b of the boutique discharge passage 49 to the outside, and supplied to a swaying sorting machine (not shown) to separate the brown rice from the grain.

The husking action is carried out as described above, but the rubber rolls 4, 5 are worn at all times as they are used, and in particular, the rubber rolls 5 on the fixed side which are rotated at a high speed are worn faster. Therefore, when the rubber rolls 4 and 5 are worn to a certain extent, if the peripheral speed of each rubber roll is changed, the rubber roll 4 is rotated at a low speed to become a high speed, and the rubber roll 5 rotating at a high speed becomes a low speed, that is, the rubber can be made. The wear of the rolls 4, 5 is equal and the replacement period of the rubber rolls is delayed. In the method of changing the peripheral speed, the configuration of the V-belt 56 shown in Fig. 4 can be changed to the configuration of the V-belt 57 shown in Fig. 7.

When the rubber rolls 4 and 5 continue to wear and reach the replacement period, the rubber rolls 4 and 5 are replaced as follows. First, the worker steps on the work step 64 (see FIG. 1) of the husking machine 1, and moves the seat portion 25 that forms the moving bearing 22 and the seat portion 35 that forms the fixed bearing 23 in the axial direction. In other words, the seat portion 25 and the seat portion 35 are provided with slide shafts 62 and 63 that are coupled to the base portion 24, respectively, and the operator moves the seat portions 25 and 35 away from the axial ends of the support shafts 32 and 37 (refer to FIG. 8A). The arrow (1)) pulls out the bearing portions 28, 36 from the support shafts 32, 37. Next, the operator rotates the moving bearing 22 clockwise around the slide shafts 62 and 63, and rotates the fixed bearing 23 counterclockwise (see an arrow (2) of FIG. 8A). Thereby, there is no member which interferes with the rubber rolls 4 and 5 in the axial direction, and the replacement of the rubber roll becomes easy. In this state, when the operator opens the front door 6b of the threshing shell portion 6 shown in FIG. 1, the rubber rolls 4 and 5 are exposed while the moving bearing 22 and the fixed bearing 23 are avoided.

Further, as shown in FIG. 8B, the worker sequentially removes the rubber rolls 5a and 5b that are axially coupled to the support shaft 37, and secondarily removes the rubber rolls 4a and 4b that are axially coupled to the support shaft 32 in order. After removing the rubber rolls 4 and 5, the operator can install the new rubber rolls in the reverse order.

According to the above operation sequence, the rubber roll replacement operation becomes a simple operation, and the number of employees required for the operation is also sufficient. Moreover, the operation of removing the rubber roll from the support shaft is simple, and the work time can be greatly shortened.

As described above, when the rubber rolls 4 and 5 are worn and reach the replacement period, first, the worker steps on the work step 64 of the husking machine, and moves the seat portion 25 of the moving bearing 22 and the seat portion 35 of the fixed bearing 23. The bearing portions 28, 36 are pulled out from the support shafts 32, 37 of the rubber rolls 4, 5 by sliding in the axial direction. Next, the seat portion 25 of the moving bearing 22 is rotated clockwise around the slide shafts 62 and 63, and the seat portion 35 of the fixed bearing 23 is rotated counterclockwise. Thereby, there is no member which interferes with the rubber rolls 3 and 4 in the axial direction, and the rubber roll replacement work becomes extremely easy.

[Industrial Applicability] The present invention can be applied to a rubber roll type stripping machine or the like.

1‧‧‧Removing shell machine
2‧‧‧ pillar
3‧‧‧Winding Department
3a‧‧‧ frame
4, 4a, 4b‧‧‧ rubber rolls
5, 5a, 5b‧‧‧ rubber rolls
6‧‧‧Debarding
6a‧‧‧ frame
6b‧‧‧ front door
7‧‧‧Material Supply Department
8‧‧‧Sucker
9‧‧‧ Feed tank
9a‧‧‧Material supply port
10‧‧‧ gate
11‧‧‧Air compressor cylinder
12‧‧‧Flow Regulator
13‧‧‧ adjustment knob
14‧‧‧Stirring rolls
15‧‧‧ Pipes
16‧‧‧Supply pipeline
17‧‧‧ Guided slide
18‧‧‧Slide frame
19‧‧‧ Support shaft
20‧‧‧Adjustment rod
21‧‧‧ grip
22‧‧‧Moving bearings
23‧‧‧Fixed bearings
24‧‧‧ base
25‧‧‧
26‧‧‧ Roller opening and closing connecting rod
27‧‧‧ Support shaft
28‧‧‧ Bearing Department
28a‧‧‧Front side bearing
28b‧‧‧Back side bearing
29‧‧‧ Roller opening and closing mechanism
30‧‧‧ Roller opening and closing shaft
31‧‧‧ Roller opening and closing cylinder
32‧‧‧Rubber roll support shaft
33‧‧‧Small diameter pulley
34‧‧‧ Large diameter pulley
35‧‧‧s
36‧‧‧ Bearing Department
36a‧‧‧Front side bearing
36b‧‧‧Back side bearing
37‧‧‧Rubber roll support shaft
38‧‧‧ Large diameter pulley
39‧‧‧Small diameter pulley
40, 41‧‧ ‧ Valley Valley Pipeline
42‧‧‧ collision plate
43‧‧ ‧ suction port
44‧‧‧Sucking tube
45‧‧‧Lower pipeline
46‧‧‧Wind selection channel
47‧‧‧Sequencer
47a‧‧‧slip board
47b~47i‧‧‧ partition board
48, 48a, 48b‧‧‧ rectifying plates
49‧‧‧ Boutique discharge channel
49a‧‧‧ secondary air inlet
49b‧‧‧Export
50‧‧‧ chaff drain
51‧‧‧ chaff impact board
52‧‧‧Drive motor
52a‧‧‧Motor shaft
53‧‧‧Motor pulley
54‧‧‧Intermediate pulley
55‧‧‧V belt
56‧‧‧V belt
57‧‧‧Intermediate pulley
58‧‧‧Agitating pulley
59‧‧‧V belt
60‧‧‧Tension pulley
61‧‧‧Tension pulley
62‧‧‧Sliding shaft
63‧‧‧Sliding shaft
64‧‧‧ steps

Fig. 1 is a perspective view showing the entirety of the threshing machine of the present invention. Figure 2 is a front elevational view of the threshing machine of the present invention. Fig. 3 is a schematic longitudinal cross-sectional view showing the internal structure of the threshing machine of the present invention. Figure 4 is a rear elevational view showing the configuration of the belt of the threshing shell. Fig. 5 is a perspective view showing the configuration of a homogenizer provided in a downflow duct of the air selection section. Fig. 6 is a schematic perspective view showing a bearing portion of a rubber roll support shaft of a threshing shell portion. Figure 7 is a rear elevational view of another embodiment showing the configuration of the belt of the threshing shell. Fig. 8A is a schematic perspective view showing the procedure when the rubber roll is removed from the rubber roll support shaft. Fig. 8B is a schematic perspective view showing the procedure when the rubber roller is removed from the rubber roller support shaft.

1‧‧‧Removing shell machine

2‧‧‧ pillar

3‧‧‧Winding Department

6‧‧‧Debarding

6b‧‧‧ front door

7‧‧‧Material Supply Department

8‧‧‧Sucker

9a‧‧‧Material supply port

21‧‧‧ grip

22‧‧‧Moving bearings

23‧‧‧Fixed bearings

24‧‧‧ base

25‧‧‧

35‧‧‧s

49a‧‧‧ secondary air inlet

49b‧‧‧Export

52‧‧‧Drive motor

52a‧‧‧Motor shaft

62‧‧‧Sliding shaft

63‧‧‧Sliding shaft

64‧‧‧ steps

Claims (7)

A threshing machine having a pair of rubber rolls on a base portion, which supports one of the pair of rubber rolls as a fixed roll by a fixed bearing, and supports the other side with a moving bearing a rubber roller is used as a moving roller, so that each rubber roller is rotationally driven at different circumferential speeds and in opposite directions to each other. On the other hand, the moving bearing has a roll opening and closing mechanism capable of adjusting the width of the roll gap, which is characterized in that the double The side-supported fixed bearing and the double-sided supported moving bearing are respectively provided with a seat portion which is slidable away from the axial end of the support shaft supporting the rubber roller, and is rotatable to avoid The rubber roller creates a position of interference. The groating machine of claim 1, wherein each of the fixed bearing and the movable bearing is provided with a sliding shaft coupled to the base portion such that the fixed bearing and the moving bearing Slides away from the axial end of the support shaft and rotates to a position that avoids interference with the rubber roller. The groating machine of claim 1 or 2, wherein the support shaft supporting the rubber roll is formed in an elongated shape, and a plurality of rubber rolls are axially coupled to the axial direction of the elongated support shaft. A rubber roll formed into a long strip shape and having a pair of elongated rubber rolls on the base portion. The groating machine of claim 1 or 2, wherein the pair of rubber rolls have a guide chute, the flow position or the inclination angle can be manually changed, and the raw material is supplied in a strip shape. The gap between the pair of rubber rolls. The husking machine according to the fourth aspect of the invention, wherein the raw material grain is formed into a strip shape having the same width as the width of the rubber roll, and flows down from the guide chute. The groating machine of claim 1 or 2, wherein the roll opening and closing mechanism is formed by a member that opens and closes a roll so as to be erectable via the seat on the base portion. a support shaft disposed at a lower end of the roll opening and closing link; a bearing portion disposed at an intermediate portion of the roll opening and closing link; a roll opening and closing support shaft disposed at an upper end of the roll opening and closing link; and a cylinder for opening and closing the roll, and The roll opening and closing support shafts are coupled. The groating machine of claim 1 or 2, wherein the pair of rubber roller support shafts are respectively axially connected with a small diameter pulley and a large diameter pulley, and the circumferential speed of each rubber roller can be changed. The rubber roll that was originally rotated at a low speed became a high speed, and the rubber roll that originally rotated at a high speed became a low speed.