KR20170089137A - apparatus for dehydration of a laver - Google Patents

Abstract

The present invention relates to a device for dehydrating laver. The device comprises: a dehydrating unit including a fixing case fixed at the top of a frame, a dehydrating container rotated in the fixing case and having a dehydrating hole for moving seawater dehydrated from laver to the fixing case, and a guide unit rotated in the dehydrating container and moving the dehydrated laver to the top thereof; a driving unit including a first shaft having a hollow part and having one side coupled with the bottom end of the dehydrating container, a second shaft inserted into the hollow part of the first shaft and having one side coupled with the guide unit, and a decelerator coupled with the first shaft and the second shaft and changing a rotation speed of the guide unit by rotating the second shaft; a first electrical power unit for rotating the dehydrating container and the guide unit by rotating the first shaft; and a second electrical power unit for driving the decelerator, and relatively changing a rotation speed of the guide unit and the dehydrating container by rotating the second shaft.

Description

[0001] The present invention relates to a dehydration apparatus for dehydration,

The present invention relates to a dehydration apparatus for a defrosted fleshy body.

Generally, Haitai's manufacturing process is to collect fresh seaweed from the sea, store it in seawater along with seawater, collect the freshness of the seawater, and remove foreign matter by separating and removing seaweed A dewatering step of removing salinity from the debris-removed leaves and a cutting step of washing the dewatered dehydrated leaves and cutting the seedlings to an appropriate length. The dried shredded leaves are dried in the form of a thin paper sheet Drying process.

At this time, the dehydrating apparatus of the shredded fleshy body is limited in the amount of dehydrating at one time according to the size of the loading box and the dehydrating tub (see Utility Model Document 1). Therefore, the operator has to store a certain amount of defrosted leaves directly in the loading box and collect the dehydrated defrosted leaves to move to the next process. As a result, not only a lot of time is required but also productivity is low.

(Utility model document 1) KR20-1987-0014149 a

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art as described above, and it is an object of the present invention to provide a dehydrating apparatus for a defrosting poultry having improved working time and productivity.

A dewatering apparatus for a defrosting lure according to the present invention comprises a fixed case fixed to an upper portion of a frame, a dehydrating tub having a dehydrating hole formed therein in which seawater dehydrated from the dehydrating lobe rotates inside the fixed case, A dehydrating part including a guide part which rotates inside the dehydrating tub and moves the dehydrated deodorized bobbins upward; A first shaft inserted into the hollow of the first shaft, a second shaft inserted into the hollow of the first shaft, one side of which is engaged with the guide portion, and a second shaft inserted into the hollow of the first shaft, A driving unit coupled to the shaft and configured to rotate the second shaft to change the rotational speed of the guide unit; A first power unit rotating the first shaft to rotate the dehydration guide unit; And a second power unit that drives the speed reducer and relatively rotates the guide unit and the dehydration cylinder by rotating the second shaft.

The dewatering unit may further include: a cover provided with a bleed port through which the bleed leaf is inserted into the guide unit from the upper portion of the fixed case; Wherein the upper end of the fixing case has a discharge port for discharging the dehydrated shredded bodily waste to the outside; And the lower end of the fixed case has a seawater discharge port for discharging the seawater to the outside.

And a feed member which is formed in a hollow shape and communicates with the bottom portion of the feed port to feed the cut-off piece into the guide portion, wherein the guide portion rotates in the same direction of the dehydration and passing, And moves to the release port.

The first power unit includes a first pulley coupled to the first shaft and the speed reducer, a first pulley receiving the power from the outside and rotating the first shaft and the speed reducer, And a first motor disposed in the frame and connected to the first pulley by a belt to transmit a rotational force, the second power section including a second pulley for rotating the second shaft while driving the speed reducer; And a second motor disposed in the frame and connected to the second pulley by a belt to transmit rotational force.

Further, the dehydrator may include a cylinder; A plurality of dewatering holes formed on an outer circumferential surface of the cylinder, and a first fastening portion for fastening an upper end of the first shaft and a lower portion of the dehydrating tub.

A plurality of vertically extended posts extending from a lower portion of the guide portion upward; A wing portion extending from the lower portion to the upper portion and surrounding the outer circumferential surface of the post adjacent to the post, the upper portion of the guide portion being open at the center thereof, And a guide cover formed thereon.

And a second fastening portion for fastening the upper end of the second shaft and the lower portion of the guide portion, wherein the height of the center portion and the rim portion are different from each other with respect to a height from the lower portion to the upper portion of the second fastening portion, And the central portion of the second fastening portion is formed to be higher than the peripheral portion of the second fastening portion.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

The defrost dehydrator according to various embodiments of the present invention provides a defrost dehydrator capable of continuous dehydration of the defrost leaves and improved working time and productivity.

Also, the first shaft, the second shaft, and the speed reducer are formed on the concentric shaft, thereby adjusting the speed of the second power section to facilitate relative speed control of the dewatering guide section.

The present invention also provides a defrost dewatering device for minimizing power loss by driving a dewatering and deflection guide portion using a first shaft, a second shaft, and a speed reducer.

1 is a perspective view of a dehydrator of a defrosted hull according to an embodiment of the present invention;
Fig. 2 is a sectional view of Fig. 1; Fig.
3 is a perspective view of a dehydrator according to the present invention.
4 is a perspective view of a guide according to the present invention;
5 is a cross-sectional enlarged view of a dehydrating section according to the present invention.
6 is a cross-sectional enlarged view of a driving unit according to the present invention;
Figure 7 is a plan view of Figure 1;
Fig. 8 to Fig. 10 are views showing an operation example of the dewatering device shown in Fig. 1; Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages, and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. Also, the terms "one side,"" first, ""first,"" second, "and the like are used to distinguish one element from another, no. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of related arts which may unnecessarily obscure the gist of the present invention will be omitted

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a perspective view of a dewatering apparatus according to an embodiment of the present invention, Fig. 2 is a sectional view of Fig. 1, Fig. 3 is a perspective view of a dewatering apparatus according to the present invention, FIG. 5 is a sectional enlarged view of the dewatering unit according to the present invention, FIG. 6 is an enlarged sectional view of the driving unit according to the present invention, FIG. 7 is a plan view of FIG. 1 and FIGS. to be.

Referring to FIGS. 1 to 5, a dehydrator 10 for a defrost deck according to an embodiment of the present invention includes a frame 100 formed by connecting a plurality of horizontal frames 110 and vertical frames 130; A fixed case 210 fixed to the upper part of the frame 100 and seawater 30 dehydrated from the defrosted flesh 20 rotating inside the fixed case 210 to move to the fixed case 210 A dewatering unit 230 including a dewatering hole 231 formed therein and a guide unit 250 rotating inside the dewatering drum 230 to move the dehydrated dewatering bowl 20 upward, ); The first shaft 310 is hollow and has a concentric shaft inserted into the first shaft 310. One end of the first shaft 310 is connected to the guide portion 250 The second shaft 330 is fixed to the first shaft 310 and is fastened to the first shaft 310 and the second shaft 330. The second shaft 330 is fixed to the first shaft 310, A driving unit 300 including a speed reducer 350 for reducing the rotational speed of the guide unit 250; A first power unit 400 coupled to an outer circumferential surface of the first shaft 310 and rotating the first shaft 310 to rotate the dehydrator 230 and the guide unit 250; And a second power unit 500 that rotates the speed reducer 300 to change the rotation speed of the guide unit 250.

Referring to FIG. 2, the frame 110 includes a plurality of horizontal bars 110 and vertical bars 30 connected to each other. The frame 110 provides a space in which the dewatering unit 200, the driving unit 300, the first power unit 400, and the second power unit 500 are disposed.

1 to 5, the dewatering unit 200 includes a fixed case 210 fixed to the upper portion of the frame 110, a dewatering unit 210 rotating in the fixed case 210, And a guide part 250 which rotates inside the dewatering drum 230 and the dewatering drum 230 in which the dewatering drum 21 is moved upward do.

The dewatering unit 200 includes a lid 270 and a top end portion of the fixed case 210 on which the unloading port 271 is formed such that the unloading lid 20 is inserted into the guide unit 250 from above the fixed case 210, A discharge port 211 for discharging the dehydrated off-shredder 21 to the outside; And the lower end of the fixed case 210 have a seawater discharge port 213 for discharging seawater to the outside.

1, 2 and 5, the fixed case 210 is fixed to the upper portion of the frame 110, and protects the dehydration tub 230 and the guide unit 250 from external impacts. The fixed case 210 is formed with a lid 270 capable of opening and closing the upper portion thereof.

The lid 270 is formed at the center thereof with a thawing inlet 271 into which the defrosted lobes 20 can be inserted. At this time, it is appropriate that the unloading port 271 is formed as a circular groove in the center of the lid 270. In addition, a throwing member 273 is disposed inside the throwing hole 271.

The insertion member 273 is hollow and guides the defrosting flesh body 20 to the lower portion of the guide portion 250. Further, the feeding member 273 feeds the defrosted flesh body from the outside and supplies it to the guide portion during the process. That is, one side of the insertion member 273 is fixed to the lid and is connected to the release port 271, and the other side of the insertion member 273 inserts the defrosted lid 20 into the guide part 250.

The input member 273 is preferably formed in a cylindrical shape. This is not intended to limit the input member 273 to a cylindrical shape.

1 or 2, the upper end of the fixed case 210 is formed with a discharge port 211 for discharging the dehydrated defoliation flesh body 21 to the outside. At this time, the drain port 211 is disposed on the upper part of the drain tank 230, and the drain port 211 is formed between the drain tank 230 and the lid 270.

Then, the discharge port 211 serves as a passage for discharging the discharged debris 21 to the outside. That is, when the dehydrator 230 and the guide 250 are driven, the dehydrated debris leaves 21 which have moved upward are discharged to the outside.

The lower end of the fixed case 210 is formed with a seawater discharge port 213 for discharging seawater to the outside. At least one seawater discharge port 213 is formed, and seawater accumulated in the interior of the stationary case 210 is discharged to the outside. The size of the seawater discharge port 213 is variously formed according to the dehydration speed and the amount of seawater of the defrost flesh 20.

3 or 5, the dewatering drum 230 is formed in a cylindrical shape, and a space in which the defrosting lure 20 is disposed is formed, and a dewatering hole 231 is formed on the outer circumferential surface.

At this time, the dehydrating tub 230 is inserted and disposed inside the fixed case 210. The dewatering cylinder 230 is spaced apart from the lower portion of the fixed case 210 and is coupled to the first shaft 310 and rotated when driven. The upper portion of the dehydrating tub 230 is open and the lower portion of the dehydrating tub 230 is formed with a first through groove 233 through which the first coupling portion 235 is fastened.

A plurality of dewatering holes 231 are formed around the dewatering container 230. At this time, a plurality of dewatering holes 231 are formed along the circumference at predetermined intervals. The dehydrating hole 231 serves as a passage through which the seawater of the deflocculant flesh body 20 flows out to the outside when dewatering. That is, the dewatering hole 231 serves as a passage for the seawater to flow into the fixed case 210 when the guide unit 250 and the dewatering tank 230 are driven. At this time, the mesh 237 is disposed on the inner peripheral surface of the dehydrating tub 230. The mesh 237 is disposed on the inner circumferential surface of the dehydrating tub 230 and is formed to be denser than the dehydrating hole 231. At this time, the mesh 237 prevents the defrosted fleece 20 from being released to the outside of the dehydrating tub 231 during rotation.

In addition, a first through-hole 233 is formed in the lower portion of the dehydrating tub 230. The first fastening portion 235 is fastened to the first through-hole 233. The upper part of the first fastening part 235 is fastened to the first through hole 233 and the lower part is fastened to the first shaft 310. That is, the first fastening part 235 fastens the first shaft 310 and the dehydrating tub 230.

Referring to FIG. 4 or 5, the guide unit 250 is inserted and disposed in the dehydrating tub 230. The guide part 250 is spaced apart from the lower part of the dewatering container 230 and rotates about the concentric axis of the fixed case 210 when driven. That is, the guide portion 250 and the first shaft 310 are driven on the concentric axis. Then, the guide part 250 rotates in the same direction as the dewatering drum 230, and moves the dehydrated dewatering lure 21 to the dewatering outlet 211.

The guide part 250 is fixed while surrounding the outer periphery of the post 251 and the post 251 adjacent to the post 251 and extends upward from the lower part of the guide part 250, And an elongated wing portion 253. The upper part of the guide part 250 is provided with a guide lid 254 for preventing separation of the defrosting lure 20 and a lower part of the guide part 250 is formed with a second through groove 255 to which the second fastening part 257 is fastened Is formed. At this time, the guide lid 254 is fixed to the upper part of the post 251, and the insertion member 273 is inserted. The guide cover 254 prevents the defoliating flecks 20 from being separated upward when driven.

It is preferable that the second through-hole 255 is formed at the center of the guide portion 250. Then, the second coupling part 257 connects the second shaft 330 and the guide part 250, respectively. The lower part of the second fastening part 257 is inserted and fastened to the second shaft 330 and the upper part of the second fastening part 257 is fastened to the second through hole 255. In addition, the second fastening portions 257 are formed to have different heights at the center and the circumference. At this time, the center of the second fastening part 257 is formed higher than the circumference. That is, when the defrosting body 20 is inserted from the outside, the outer circumferential surface of the second fastening part 257 spreads the defrosting body 20 to the wing part 253 when driven.

Referring to FIG. 5, a support portion 252 to be fastened to the lower portion of the guide portion 250 is formed. The receiving portion 252 is formed so as to spread upward. This allows the catching portion 252 to prevent the breakable feces 20 from being released into the drainage receptacle 230 when the catching feces 20 is inserted.

The posts 251 are disposed apart from the center of the second through grooves 255 and uniformly disposed around the second through grooves 255. At this time, the post 251 is suitably formed as a cylinder. Here, the post 251 reduces the contact area of the defrosting flesh body 20 to prevent entanglement in the guide part 250. And the post 251 supports the wing portion 253.

4 or 5, the wing 253 is formed by connecting the post 251 and the neighboring post 251 and surrounding the post 251 adjacent to the post 251. That is, the wing portion 253 is fixed to the outer circumferential surface of the post 251 adjacent to the post 251 and extends upward while connecting the post 251 and the adjacent post 251. At this time, the wing portion 253 is formed so as to gradually extend upward when the posts 251 and the adjacent posts 251 are connected. That is, the wing portion 253 is formed so as to ascend upward in the form of a screw in the transverse section with reference to the guide portion 250.

Then, the wing portion 253 moves to the release port 211 due to the rotational force of the defrosting post 21 which is dehydrated when the guide portion 250 is driven. That is, the wing portion 253 serves as a guiding means for moving the dehydrated bobbin body 21 dehydrated due to the rotational force upward along the thread.

Referring to FIG. 5, the driving unit 300 is fixed to the fixed case 210 and drives the dehydrating tub 230 and the guide unit 250. The driving unit 300 includes a first shaft 310 coupled to a lower end of the dewatering cylinder 230, a second shaft 330 coupled to a lower end of the guide unit 250, a first shaft 310 coupled to the second shaft 330, And a speed reducer (350) fastened to the shaft (330).

One side of the first shaft 310 is fastened to the lower end of the center of the dewatering cylinder 230, and the other side is fastened to the reducer 350. That is, one side of the first shaft 310 is fastened to the first fastening portion 235, and the other side of the first shaft 310 is fastened to the first power portion 400.

The first shaft 310 is hollow and the second shaft 330 is inserted into the first shaft 310. That is, the first shaft 310 and the second shaft 330 are formed to have a concentric axis. At this time, when the first shaft 310 rotates, the reducer 350 and the second shaft 330 also rotate in the same direction. That is, when the first shaft 310 rotates, the dewatering drum 230 and the guide unit 250 are rotated.

The second shaft 330 is hollowly inserted into the first shaft 310 and has the same concentric axis. One side of the second shaft 330 is fastened to the lower center of the guide part 250 and the other side of the second shaft 330 fastens the speed reducer 350.

That is, the second shaft 330 is inserted into and fixed to the second coupling part 257, and rotates the guide part 250 at the time of driving. The second shaft 330 rotates inside the first shaft 310 and transmits the rotational speed of the speed reducer 350 to the guide unit 250 during driving.

One side of the speed reducer 350 is coupled to the first shaft 310 and the second shaft 330 and the other side of the speed reducer 350 is coupled to a second pulley 510 to be described later. The speed reducer 350 has the same center on the first shaft 310 and the second shaft 330.

At this time, the speed reducer 350 preferably uses a speed reducer. This is because the speed reducer 350 relatively adjusts the number of revolutions of the first shaft 310 and the second shaft 330. Then, the decelerator 350 decelerates the rotational speed of the second shaft 330 to adjust the relative rotational speed of the dehydrator 230 and the guide unit 250. In contrast, the speed reducer 350 drives the second shaft 330 at a high speed to adjust the relative rotation speed of the dewatering drum 230 and the guide unit 250.

At this time, the speed reducer 350 adjusts the relative speed of the dewatering drum 230 and the guide unit 250 by adjusting the speed of the second power unit, which will be described later, by fastening the second shaft 330. The speed reducer 350 is connected to the first shaft 310 and the second shaft 330 to drive the dewatering drum 230 and the guide unit 250 so that the structure is simple and the power loss is minimized .

Referring to FIG. 6 or 8, the first power unit 400 is coupled to the first shaft 310 and the speed reducer 350, and receives the power to drive the first shaft 310. The second shaft 330 and the speed reducer 350 are simultaneously rotated. The first power unit 400 includes a first pulley 410 fastened to the first shaft 310 and a speed reducer 350 and a first motor 450 disposed to the frame 100.

The first pulley 410 rotates the first shaft 310 using the first belt 430. At this time, the first pulley 410 rotates the first shaft 310, the reducer 350, and the second shaft 330. That is, the first pulley 410 rotates the dewatering tub 230 and the guide unit 250 in the same direction. The first motor 450 is disposed on one side of the frame 100. The third pulley 470 is disposed on the axis of the first motor 450 and the third pulley 470 is disposed on the first belt 430 . That is, the first motor 450 rotates the third pulley 470 and the first belt 430 to drive the first pulley 410.

Referring to FIG. 6 or FIG. 8, the second power unit 500 receives the power and rotates the second shaft 330. The second power unit 500 includes a second pulley 510 fastened to the speed reducer 350 and a second motor 550 disposed on the frame 100. At this time, the second power unit 500 rotates the second pulley 510 connected to the speed reducer 350.

The second pulley 510 rotates the reducer 350 using the second belt 530. That is, the second pulley 510 rotates the second shaft 330 using the driving force of the second motor 550. At this time, the speed reducer 350 decelerates the driving force of the second motor 550 and transmits it to the second shaft 330. That is, the second pulley 510 adjusts the speed using the speed reducer 350.

At this time, the second motor 550 is disposed on the other side of the frame 100, the fourth pulley 570 is disposed on the axis of the second motor 550, and the fourth pulley 570 is disposed on the second belt 530 . That is, the second motor 550 rotates the fourth pulley 570 and the second belt 530 to drive the second pulley 510. Then, the second pulley 510 rotates to drive the speed reducer 350.

8 to 10, the same components as those of the dehydrating apparatus according to the first embodiment will be omitted, and a method of operating the dehydrating apparatus according to the present invention will be described. Injecting the deionized water into the dehydrating tub 230 and the guide 250 through the inlet 271; b) driving the dewatering cylinder (230) and the guide unit (250) by driving the first power unit (400); c) adjusting the speed of the guide unit 250 by driving the second power unit 500; And d) discharging the dehydrated bleached flesh body 21 to the relief outlet 211 through the guide portion 250.

8, a) the defrosting feces 20 is injected into the dewatering tub 230 and the guide 250 through the defrosting inlet 271.

b) When the first power unit 400 is driven, the dehydrator 230 and the guide unit 250 are simultaneously driven. That is, when the first motor 450 is driven, the first shaft 310, the second shaft 330, and the speed reducer 350 simultaneously rotate.

Then, the dewatering tube 231 connected to the first shaft 310 and the guide part 250 rotate in the same direction. At this time, the sea water of the defrosting feces 20 moves to the fixed case 210 due to the rotational force of the dehydration tub 231 and the guide unit 250. The seawater is discharged to the outside through the seawater outlet 213.

c) When the second power unit 500 is driven, the relative speed between the guide unit 250 and the dehydration cylinder 231 is adjusted. That is, when the second motor 550 is driven, the speed reducer 350 decelerates or increases the rotation speed of the second shaft 330. Then, the speed reducer 350 adjusts the relative rotation speed of the guide portion 250 and the dewatering tube 231. This is to increase the dehydration efficiency of the defrosted flesh body 20 by generating a speed difference between the dehydration cylinder 230 and the guide part 250.

d) The dewatered defrosting feces 21 is discharged to the discharge port 211 through the guide part 250. At this time, the dehydrated shredded flesh body 21 moves to the discharge port 211 along the wing portion 253 of the guide portion 250.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

10: Dehydrator device 100: Frame
110: Horizontal frame 130: Vertical frame
200: dehydrating part 210: fixed case
211: Haitai discharge port 213: Seawater discharge port
230: dehydrator 231: dehydrator
233: first through groove 235: first fastening part
250: guide portion 251: post
252: receiving portion 253: wing portion
254: Guide cover 255: Second through groove
257: second fastening part 270: cover
271: Haitai injection port 273: input member
300: driving part 310: first shaft
330: second shaft 350: speed reducer
400: first power section 410: first pulley
430: first belt 450: first motor
470: Third pulley 500: Second power unit
510: second pulley 530: second belt
550: second motor 570: fourth pulley
20: Dehydrated Leaves 21: Dehydrated Dehydrated Leaves

Claims (12)

A dewatering container having a dewatering hole formed therein, the dewatering hole being rotated in the fixing case, the dehydrated water from the dehydrating lid being moved to the fixing case, and a dewatering container rotating in the dewatering container, A dehydrating part including a guide part for moving the defrosted garbage body upward;
A first shaft inserted into the hollow of the first shaft, a second shaft inserted into the hollow of the first shaft, one side of which is engaged with the guide portion, and a second shaft inserted into the hollow of the first shaft, A driving unit coupled to the shaft and configured to rotate the second shaft to change the rotational speed of the guide unit;
A first power unit rotating the first shaft to rotate the dehydration guide unit; And
And a second power unit for driving the speed reducer and rotating the second shaft to relatively change a rotation speed of the guide unit and the dewatering tank.
The method according to claim 1,
The dewatering unit includes:
A cover provided with a disengagement input port through which the breaker body is inserted into the guide portion from the upper portion of the fixed case;
Wherein the upper end of the fixing case has a discharge port for discharging the dehydrated shredded bodily waste to the outside; And
And a lower end of the fixed case further comprises a seawater discharge port for discharging the seawater to the outside.
The method of claim 2,
And a feeding member formed in a hollow shape and communicating with the lower portion of the feeding port for introducing the defrosting post into the guide portion.
The method of claim 2,
Wherein the guide portion is rotated in the same direction as the dehydration and passing, and the dehydrated shredded flesh is moved to the deodorizing outlet.
The method according to claim 1,
The first power section
A first pulley coupled to the first shaft and the speed reducer, respectively, for receiving power from the outside and rotating the first shaft and the speed reducer; And
And a first motor disposed in the frame and connected to the first pulley by a belt to transmit a rotational force.
The method according to claim 1,
The second power section
A second pulley for rotating the second shaft while driving the speed reducer; And
And a second motor disposed in the frame and connected to the second pulley by a belt to transmit a rotational force.
The method according to claim 1,
The dehydrating tub
cylinder;
And a plurality of dewatering holes are formed on the outer circumferential surface of the cylinder.
The method of claim 7,
And a first fastening portion for fastening the upper end of the first shaft and the lower portion of the dehydrating tub.
The method according to claim 1,
A post extending vertically from a lower portion of the guide portion and formed vertically;
A wing portion which is fixed while surrounding the outer circumferential surfaces of the plurality of posts and extends in the upper direction from the lower portion while surrounding the outer circumferential surface of the posts adjacent to the posts.
And a guide cover disposed at an upper portion of the guide portion and having an upper portion opened at a center thereof.
The method of claim 9,
And a second fastening portion for fastening the upper end of the second shaft and the lower portion of the guide portion.
The method of claim 10,
Wherein a height of a center portion and an edge portion of the second fastening portion are different from each other with respect to a height from a lower portion to an upper portion of the second fastening portion.
The method of claim 11,
Wherein the central portion of the second fastening portion is formed to be higher than the peripheral portion of the second fastening portion.

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