KR101678768B1 - Screw-type low-speed solid-liquid separation apparatus - Google Patents

Abstract

More particularly, the present invention relates to a screw type low speed solid-liquid separator, and more particularly, to a screw type low speed solid-liquid separator having a base frame, a process water discharge portion, a case having a solid matter discharge portion and a plurality of dewatering holes, A cylindrical screen portion for separating and discharging the treated water and the solid from the raw water, a supply means for supplying the raw water including the solid material to the cylindrical screen portion, Transporting scraping means for transporting the solids discharged to the solids discharging portion as well as driving means for rotating the cylindrical screen portion and the supplying means at different rotational speeds.
According to the present invention as described above, the supplied raw water is rotated at low speed and separated into the treated water and the solid matter, and the solids hanging on the cylindrical screen are removed by the screw type scraping means, So that the dehydration rate of the solid can be improved.

Description

[0001] The present invention relates to a screw type low-speed solid-liquid separation apparatus,

The present invention relates to a solid-liquid separator, and more particularly, to a solid-liquid separator which separates treated water and solid matter from raw water to transfer and discharge the solid material, and scraping the dewatering hole of the cylindrical screen to facilitate separation and discharge of solid matter and treated water Speed low-solids liquid separator capable of improving the dewatering efficiency.

In general, since industrial wastewater and sewage, and swine manure contain solids such as sludge, the purification process can not be carried out properly without separating and removing the solids. Therefore, the solids .

As a conventional apparatus for performing a solid-liquid separation function prior to the purification process, a filtration cylinder is fixed inside a cylindrical body having an inlet at an upper portion thereof and an outlet for discharging a desorption filtrate in a state in which solids are removed, There is provided a pressurizing screw brush which is operated by a motor so as to be in close contact with the inner surface of the filtration cylinder and a sludge discharge port which is opened only at a predetermined pressure or more at the tip end of the screw brush of the filtration cylinder.

However, in such a conventional apparatus, when the screw is rotated by a screw brush, the wing pushes and discharges the solids attached to the inner surface of the filtration cylinder by scraping and pushing it forward, causing a large pressure to be applied to the filtration tube, And the solid matter is finely pulverized by the pressing force to escape from the filtration tube to lower the dehydration rate.

In addition, since solids are concentratively adhered only to the filtration cylinder close to the inflow part, there is a problem that the solids separation function of the filtration cylinder is rapidly deteriorated.

In order to solve this problem, a predetermined number of screw brushes for sludge are provided so as to be close to the inner surfaces of the plurality of filtering cylinders, as disclosed in Registration No. 10-0143165, so that the solid substances fixed on the inner surface of the filtering cylinder can be removed .

However, since the screw brush of the separating and removing device is rotated in the direction opposite to the filtration cylinder, a small amount of solids can be easily removed as the fixed solids are removed, but when the amount of solids is large, the solids can be removed between the brush and the filtration cylinder There is a problem that the brush or the filtration cylinder can be damaged by interfering with the rotation.

Particularly, since the driving gear and the driven gear for rotating the screw brush are located inside the filter cylinder, rust is generated by the dehydrated liquid, which shortens the service life.

Since the brush is a structure in which the object is easy to be seated, the separated and discharged solid matter is caught, which may lower the efficiency of separation and discharge.

In addition, when the brush is worn out, it is necessary to separate the components such as the filtration cylinder and the screw from the base frame, to separate the brush installed screw from the filtration cylinder, and to replace the brush again, A large amount of cost and a long working time are required to reduce the work efficiency.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for manufacturing a solid- A cylindrical screen portion for separating and discharging the treated water and the solid material, a supply means for supplying the raw water including the solid material to the cylindrical screen portion, a suction means provided on the supply means in the form of a screw to remove the solids placed on the inner surface of the cylindrical screen portion, Of course, there is provided a conveying scraping means for conveying to the solids discharging portion, and a driving means for rotating the cylindrical screen portion and the supplying means at mutually different rotational speeds, thereby rotating the supplied raw water at low speed, separating the treated water and the solid matter , The solid material caught on the cylindrical screen is removed by the screw-type transfer scraping means, Can be easily transferred to the output's objective is to provide a screw type low-speed solid-liquid separating apparatus which can improve the dehydration rate of the solids.

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a base frame; a case having a discharge space portion, a process water discharge portion, a solid material discharge portion, and a plurality of dewatering holes; A cylindrical screen portion for separating and discharging the treated water and the solid material, a supply means for supplying the raw water including the solid material to the cylindrical screen portion, a solid material disposed in the supply means for contacting the inner surface of the cylindrical screen portion, A transfer scraping means for transferring the cylindrical screen portion and the supply means to the solids discharging portion as well as a driving means for rotating the cylindrical screen portion and the supplying means at different rotational speeds.

Preferably, the supplying means includes: a discharge tube disposed inside the cylindrical screen portion and having a discharge hole for discharging raw water including solid matter along an outer periphery thereof; a discharge tube provided in communication with one end of the discharge tube for transferring raw water A rotary tube provided at the other end of the discharge tube so that the discharge tube is rotatably installed in the base frame together with the supply tube, a first tube connection part for detachably connecting the discharge tube and the supply tube, And a second pipe connection portion for detachably connecting the rotary pipe.

The first pipe connecting portion and the second pipe connecting portion may include a discharge flange formed at each end of the discharge pipe, a pipe flange formed respectively in the supply pipe and the rotary pipe to correspond to the discharge flange, And a pipe fixing member for detachably connecting the pipe flange.

The tube fixing member includes a tube fixing bolt penetrating the discharge flange and the tube flange, and a tube fixing nut fastened to the tube fixing bolt to fix the discharge flange and the tube flange.

The cylindrical screen unit includes a cylindrical screen having a plurality of dewatering holes, both ends of which are opened, a first screen rotating tube rotatably provided on the outer circumferential surface of the supply tube by a bearing, A second screen rotating tube provided rotatably, a first screen connecting portion for detachably connecting one end of the cylindrical screen to the first screen rotating tube, and a second screen rotating tube connected to the other end of the cylindrical screen in a detachable manner And a second screen connection part connected to the cylindrical screen, wherein the second screen connection part has a solid discharge port through which the dewatered solid is discharged from the cylindrical screen.

The first screen connecting portion may include a first cylindrical flange formed at one end of the cylindrical screen, a first screen flange formed at an end of the first screen rotating tube, a second screen flange formed at one end of the cylindrical screen, A first screen panel positioned between the first cylindrical flange and the first screen flange and a first screen securing member detachably connecting the first cylindrical flange and the first screen flange to the first screen panel, And the second screen connection portion includes a second cylindrical flange formed at the other end of the cylindrical screen, a second screen flange positioned outside the second screen rotating tube, and a second screen flange disposed at the other end of the cylindrical screen, A second screen panel positioned between the second cylindrical flange and the second screen flange and having a solids discharge port for discharging the dewatered solids and a second screen panel disposed between the second cylindrical flange and the second screen flange, But connected so as to be detachable, respectively a flange on the second screen panel, and a second screen member for detachable fixing to a second panel with a screen and the second screen rotary pipe, upon connection of the second screen flange.

The case has a partition wall for partitioning the treated water discharging part and the solids discharge part. A mounting hole for receiving the cylindrical screen is formed at a central part of the partition wall, and between the second cylindrical flange and the second screen panel And a second compartment flange positioned between the second screen panel and the second screen rotating tube, wherein the first compartment flange and the second compartment flange are located in a first portion of the second cylindrical flange, Diameter portion, and the partition wall is located between the partition wall and partition the treated water discharge portion and the solids discharge portion.

The first screen fixing member and the second screen fixing member are each composed of a bolt and a nut.

The conveying scraping means includes a conveying screw provided spirally along the outer circumferential surface of the discharge tube for conveying the solids toward the solids discharge portion and a conveying screw for scraping the inner circumferential surface of the cylindrical screen. And a scraper provided along the end portion.

Further, an auxiliary blade is further provided on the outer circumferential surface of the discharge tube so as to be positioned between the blade of the conveying screw, thereby separating and stirring the solid material conveyed along the conveying screw.

The auxiliary blade is formed at the same angle as the forming angle of the feed screw.

Further, the auxiliary blade is formed at an angle symmetrical to the blade forming angle of the conveying screw. A connection shaft provided in the base frame and rotated by the driving motor,

The driving unit may include a driving motor provided in the base frame, a first driving pulley installed and equally rotated so as to be parallel to the supply pipe, a second driving pulley mounted on the connecting shaft and rotated in the same manner, A first driven pulley provided on the supply pipe and equally rotated, a second driven pulley provided on the first screen rotating pipe and rotated in the same manner, a rotational force of the first drive pulley, A second transmitting portion for transmitting the rotational force of the second driving pulley to the second driven pulley to rotate the first screen rotating tube, and a second transmitting portion for rotating the first screen rotating tube, And a tension adjusting part for adjusting the tension of the first cut part and the second cut part.

As described above, according to the screw type low speed solid-liquid separator according to the present invention, the supplied raw water is rotated at low speed and separated into the treated water and the solid material, and the solid material caught on the cylindrical screen by the screw- The removal box is, of course, a very useful and effective invention that can be easily transferred to a solid discharge, thereby improving the dewatering rate for solids.

1 is a view showing a screw type low speed solid-liquid separator according to the present invention,
2 is an exploded view of a screw type low speed solid-liquid separator according to the present invention,
3 is a view showing a feeding means and a moving scraping means of a screw type low speed solid-liquid separator according to the present invention,
4 is a view showing a cylindrical screen unit of a screw type low speed solid-liquid separator according to the present invention,
5 is a view showing a first compartment flange and a second compartment flange of a cylindrical screen unit according to the present invention,
Figure 6 is a top view of the transport scraping means according to the invention,
FIG. 7 is a view showing one fixed embodiment of the transport scraping means according to the present invention,
8 is a view showing a driving means of a screw type low speed solid-liquid separator according to the present invention,
9 is a view showing a raw water regulating unit of a screw type low speed solid-liquid separator according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and various modifications are possible within the scope of the present invention.

FIG. 1 is a view showing a screw type low speed solid-liquid separator according to the present invention, FIG. 2 is an exploded view of a screw type low speed solid-liquid separator according to the present invention, 4 is a view showing a cylindrical screen portion of a screw type low-speed solid-liquid separation device according to the present invention, and Fig. 5 is a schematic view of a cylindrical screen portion according to the present invention FIG. 6 is a plan view of the conveying scraping means according to the present invention, and FIG. 7 is a perspective view of the conveying scraping means according to the present invention. FIG. 8 is a view showing the driving means of the screw type low speed solid-liquid separator according to the present invention, and FIG. 9 is a view showing the raw water adjusting portion of the screw type low- Fig.

As shown in the drawing, a screw type low speed solid-liquid separator 10 includes a base frame 100, a case 200, a cylindrical screen unit 300, a supply unit 400, a transport scraping unit 500, And driving means 600.

The case 200 is provided in the base frame 100 and includes a discharge space 202 for separating the process water and the solids from the process space, a process water discharge unit 212 for discharging the process water, A solid matter discharging portion 214 to be discharged is formed.

The cylindrical screen unit 300 has a plurality of dewatering holes 312 and is rotatably disposed in the discharge space 202 of the case 200 so that the treated water is discharged from the solid matter through the dewatering holes 312 by centrifugal force And a solids discharge port 357 for discharging the dewatered solids is formed to open in one direction.

The supply means 400 is rotatably provided in the base frame 100 through the cylindrical screen unit 300 and supplies the raw water including the solid material to the cylindrical screen unit 300.

The conveying scraper means 500 is provided so as to come in contact with the inner surface of the cylindrical screen portion in the form of a screw and removes solids placed in the dewatering hole 312 of the cylindrical screen portion 300 when the supply means 400 is rotated To the solids discharge unit 214, as shown in FIG.

The driving means 600 rotates the cylindrical screen portion 300 and the supplying means 400 at different rotational speeds.

3, the supply unit 400 includes a supply pipe 420, a rotary pipe 430, a first pipe connecting part 440, and a second pipe connecting part 450 do.

The discharge pipe 410 is located inside the cylindrical screen unit 300 and a discharge hole 412 for discharging raw water including solid matter along the periphery is formed.

The supply pipe 420 is provided to communicate with one end of the discharge pipe 410 to transfer the raw water.

The rotary pipe 430 is provided at the other end of the discharge pipe 410 so that the discharge pipe 410 is rotatably installed on the base frame 100 together with the supply pipe 420.

The first pipe connection part 440 connects the discharge pipe 410 and the supply pipe 420 in a detachable manner and the second pipe connection part 450 connects the discharge pipe 410 and the rotary pipe 430 in a detachable manner .

The first pipe connecting portion 440 and the second pipe connecting portion 450 are formed of the discharge flanges 442 and 452 and the pipe flanges 444 and 454 and the pipe fixing members 446 and 456.

The discharge flanges 442 and 452 are formed at both ends of the discharge pipe 410 and the pipe flanges 444 and 454 are connected to the discharge pipe 420 and the rotary pipe 430 so as to correspond to the discharge flanges 442 and 452, Respectively.

The pipe fixing members 446 and 456 are detachably connected to the discharge flanges 442 and 452 and the pipe flanges 444 and 454, respectively.

Here, the pipe fixing members 446 and 456 are composed of a pipe fixing bolt 460 and a pipe fixing nut 462. [

The pipe fixing bolts 460 are installed through the discharge flanges 442 and 452 and the pipe flanges 444 and 454 and the pipe fixing nuts 462 are fastened to the pipe fixing bolts 460 so that the discharge flanges 442, 452 and pipe flanges 444, 454, respectively.

Of course, it is a matter of course that a plurality of fixing holes are formed in each flange, and the tube fixing bolt 460 and the tube fixing nut 462 are fastened through the corresponding fixing holes.

4, the cylindrical screen unit 300 includes a cylindrical screen 310 and a first screen rotating tube 320, a second screen rotating tube 330, a first screen connecting unit 340, And a screen connection part 350.

The cylindrical screen 310 is formed with a plurality of dewatering holes 312 and both end portions are opened and the first screen rotating tube 320 is rotatably provided along the outer circumferential surface of the supply pipe 420 by a bearing.

The second screen rotating tube 330 is rotatably disposed along the outer circumferential surface of the rotary tube 430 by a bearing.

The first screen connection part 340 detachably connects one end of the cylindrical screen 310 and the first screen rotation pipe 320 while the second screen connection part 350 connects the other end of the cylindrical screen 310 and the second screen connection part 350. [ The two-screen rotary pipe 330 is connected detachably so that a solid outlet 352 through which the dewatered solid is discharged from the cylindrical screen 310 is formed.

The first screen connection portion 340 is composed of a first cylindrical flange 342 and a first screen flange 344, a first screen panel 346 and a first screen fixing member 348.

The first cylindrical flange 342 is formed at one end of the cylindrical screen 310 and the first screen flange 344 is formed at the end of the first screen rotating tube 320.

And the first screen panel 346 is positioned between the first cylindrical flange 342 and the first screen flange 344 to close an open end of the cylindrical screen 310.

The first screen fixing member 348 detachably connects the first cylindrical flange 342 and the first screen flange 344 to the first screen panel 346, respectively.

The second screen connection portion 350 is composed of a second cylindrical flange 352 and a second screen flange 354, a second screen panel 356 and a second screen fixing member 358.

The second cylindrical flange 352 is formed at the other end of the cylindrical screen 310 and the second screen flange 354 is located outside the second screen rotating tube 330.

The second screen panel 356 is positioned between the second cylindrical flange 352 and the second screen flange 354 to close the other open end of the cylindrical screen 310 so that the dewatered solids are discharged through the solids outlet (357) are formed.

The second screen fixing member 358 connects the second cylindrical flange 352 and the second screen flange 354 to the second screen panel 356 such that the second cylindrical flange 352 is detachably connected to the second screen flange 354, The second screen panel 360 is detached and attached to the second screen panel 356 together with the second screen rotating tube 330.

Here, the first screen fixing member 348 and the second screen fixing member 358 are composed of bolts and nuts, respectively.

Each of the flanges has a plurality of fixing holes formed therein. In each of the screen panels, a through hole corresponding to the fixing hole of the corresponding flange is formed, and the bolt and the nut are fastened through the corresponding fixing holes and through holes.

5, the case 200 is formed with a partition wall 216 for partitioning the treated water discharge portion 212 and the solids discharge portion 214, and the partition wall 216 has a central portion A mounting hole 217 for mounting the cylindrical screen 310 is formed.

Here, the first compartment flange 360 and the second compartment flange 370 are further provided.

The first compartment flange 360 is positioned between the second cylindrical flange 352 and the second screen panel 356 and the second compartment flange 370 is positioned between the second screen panel 356 and the second screen rotation pipe 330, respectively.

The first compartment flange 360 and the second compartment flange 370 are formed larger than the diameter of the second cylindrical flange 370 so that the partition wall 216 is positioned therebetween, And the cylindrical screen 310 is rotatably installed.

As shown in FIG. 6, the conveying scraping means 500 includes a conveying screw 510 and a scraper 520.

The conveying screw 510 is provided in a spiral shape along the outer circumferential surface of the discharge pipe 410 to convey the solids toward the solids discharge unit 214.

The scraper 520 is provided along the end of the conveying screw 510 to scrape the inner circumferential surface of the cylindrical screen 310.

The scraper 520 is made of an elastic material such as urethane or rubber. The scraper 520 is fitted to the end of the conveying screw 510 or is positioned along the end portion as shown in FIG. 7, As shown in Fig.

Of course, even when it is fitted to the end of the feed screw 510, it can be fixed by bolts and nuts.

Further, an auxiliary vane 530 is further provided on the outer circumferential surface of the discharge pipe 410 so as to be positioned between the edges of the transfer screw 510.

The auxiliary wings 530 are respectively positioned between the blades, and alternatively, they may be alternately installed, and it is a matter of course that a plurality of blades may be located between the blades.

The auxiliary vane 530 separates and agitates the solid material conveyed along the conveying screw 510 to improve the dewatering efficiency.

Here, the auxiliary vane 530 may be formed at an angle equal to the blade forming angle of the conveying screw 510, or may be formed at an angle symmetrical to the blade forming angle of the conveying screw 510.

An auxiliary wing 530 formed at an angle equal to the blade forming angle of the feed screw 510 and an auxiliary wing 530 formed at an angle symmetrical to the blade forming angle of the feed screw 510 may be alternately installed May be installed.

8, the driving means 600 includes a motor 610, a connecting shaft 620, a first driving pulley 630, a second driving pulley 640, a first driven pulley 650, A second driven pulley 660, a first transmitting portion 670, a second transmitting portion 680, and a tension adjusting portion 700.

The drive motor 610 is provided in the base frame 100 and the connection shaft 620 is provided in the base frame 100 so as to be parallel to the supply pipe 420 and is rotated by the drive motor 610.

The first driving pulley 630 is installed on the connecting shaft 620 and is rotated in the same manner. The second driving pulley 640 is installed on the connecting shaft 620 and is rotated in the same manner. Which is smaller than the pitch of the gear teeth.

The first driven pulley 650 is installed on the supply pipe 420 and rotated in the same manner and the second driven pulley 660 is installed on the first screen rotating pipe 320 and rotated in the same manner.

The first transmitting portion 670 transmits the rotating force of the first driving pulley 630 to the first driven pulley 650 to rotate the supply pipe 420 and the second transmitting portion 680 rotates the second driving pulley 640 to the second driven pulley 660 to rotate the first screen rotating tube 320.

The tension adjuster 700 is provided to adjust the tension of the first cut portion 670 and the second cut portion 680.

The tension controller 710 includes a tension moving frame 720, a tension fixing frame 730, and a position adjusting unit 740.

The tension roller 710 is provided in each of the first transmitting portion 670 and the second transmitting portion 680 and is formed as a pair to press each of the transmitting portions.

The tension moving frame 720 is provided at both ends of each tension roller 710, and is installed so that the tension roller 710 can rotate.

The tension fixing frames 730 are spaced apart from each other by a predetermined distance so that the tension moving frames 710 are interposed therebetween and are provided on the base frame 100.

Further, the position adjusting unit 740 is provided to move and fix the respective tension moving frames 710 in the tension fixing frame 730.

The position adjusting portion 740 includes a tension fixing hole 742 and a tensioning portion formed by a hole 744, a tension fixing bolt 746, and a tension fixing nut 748.

The tension fixing holes 742 are formed at the upper end and the lower end of the tension moving frame 710 so that the tension is fixed to the upper and lower ends of the tension fixing frame 730 such that the holes 744 correspond to the respective tensile fixing holes 742. [ Respectively, in the horizontal direction.

The tension fixing bolt 746 is provided with a tensile fixing hole 742 and a tension through the hole 744. The tension fixing nut 748 has a tension fixing hole 742 and a tension And is provided for fixing the tension moving frame 710 to the tension fixing frame 730 by being fastened to the fixing bolt 746.

Also, as shown in FIG. 9, a raw water control unit 800 for controlling the supply amount of raw water supplied to the supply pipe 410 of the supply means 400 is further provided.

The raw water regulating unit 800 includes a reservoir tank 810, a raw milk feed pipe 820, a raw water feed pipe 830, a raw water discharge pipe 840, and a flow rate regulator 850.

The raw water is temporarily stored in the reservoir tank 810 and the raw milk feed pipe 820 is provided for the raw water to be introduced into the reservoir tank 810.

The raw water discharge pipe 840 is provided to supply the raw water stored in the storage tank 810 to the supply pipe 410. The raw water discharge pipe 840 is connected to the raw water discharge pipe 840, do.

The flow control unit 850 controls the amount of raw water discharged through the raw water discharge pipe 840 by adjusting the amount of the raw water conveyed through the raw water transfer pipe 830 in the water storage tank 810.

It is preferable that the flow rate regulator 850 is formed as a regulating plate for regulating an amount of the liquid to be conveyed as it is moved in the vertical direction to regulate the open space.

10: screw type low speed solid-liquid separator 100: base frame
200: Case 300: Cylindrical screen part
310: cylindrical screen 320: first screen rotating tube
330: second screen rotating tube 340: first screen connecting part
350: second screen connection part 400: supply means
410: discharge pipe 420: supply pipe
430: Rotary tube 440: First tube connection
450: second tube connection part 500: transfer scraping means
510: Feed screw 520: Scraper
530: Auxiliary wing 600: Driving means
610: drive motor 620: connection shaft
630: first drive pulley 640: second drive pulley
650: first driven pulley 660: second driven pulley
670: first transmitting portion 680: second transmitting portion
700: tension adjusting portion

Claims (11)

A base frame;
A case having a discharge space portion, a process water discharge portion, and a solids discharge portion formed therein;
A cylindrical screen unit having a plurality of dewatering holes and rotatably provided in a discharge space portion of the case to separate and discharge the treated water and the solid matter from the raw water;
Supply means for supplying raw water including solids to the cylindrical screen portion;
A delivery scraping means provided on the supply means in a screw shape to contact the inner surface of the cylindrical screen portion to remove solids placed in the dewatering hole, and to transfer the solids to the solids discharge portion; And
And driving means for rotating the cylindrical screen portion and the supplying means at different rotational speeds,
Wherein the supplying means comprises:
A discharge tube located inside the cylindrical screen portion and having a discharge hole for discharging raw water including a solid material along an outer periphery;
A supply pipe communicating with one end of the discharge pipe to transfer the raw water;
A rotary pipe provided at the other end of the discharge pipe so as to be rotatable with the discharge pipe along with the supply pipe;
A first pipe connection part for detachably connecting the discharge pipe and the supply pipe; And
And a second pipe connection part for detachably connecting the discharge pipe and the rotary pipe,
The cylindrical screen unit includes:
A cylindrical screen in which a plurality of dewatering holes are formed and both ends thereof are opened;
A first screen rotating tube rotatably provided on an outer peripheral surface of the supply pipe by a bearing;
A second screen rotating tube rotatably provided on an outer peripheral surface of the rotary tube by a bearing;
A first screen connection part detachably connecting one end of the cylindrical screen to the first screen rotation pipe; And
And a second screen connection part connecting the other end of the cylindrical screen to the second screen rotation pipe such that the second screen rotation pipe is detachably attached thereto and a solids discharge port through which the dehydrated solids are discharged from the cylindrical screen,
Wherein the transferring scraping means comprises:
A conveyance screw provided spirally along the outer circumferential surface of the discharge tube for conveying the solids toward the solids discharge unit; And
And a scraper provided along the end of the conveying screw for scraping the inner circumferential surface of the cylindrical screen,
The first tube connecting part and the second tube connecting part are connected to each other,
A discharge flange formed at both ends of the discharge tube;
A pipe flange formed on the supply pipe and the rotary pipe respectively corresponding to the discharge flanges; And
And a pipe fixing member for detachably connecting the discharge flange and the pipe flange,
Wherein the first screen connection portion comprises:
A first cylindrical flange formed at one end of the cylindrical screen;
A first screen flange formed at an end of the first screen rotating tube;
A first screen panel positioned between the first cylindrical flange and the first screen flange to close an open end of the cylindrical screen; And
And a first screen fixing member detachably connecting the first cylindrical flange and the first screen flange to the first screen panel,
Wherein the second screen connection portion comprises:
A second cylindrical flange formed at the other end of the cylindrical screen;
A second screen flange positioned outside the second screen rotating tube;
A second screen panel positioned between the second cylindrical flange and the second screen flange to close the other open end of the cylindrical screen and having a solids discharge port for discharging dewatered solids; And
The second screen flange is connected to the second screen panel so that the second cylindrical flange and the second screen flange are detachably attached to each other. When the second screen flange is connected to the second screen flange, And a fixing member,
The first screen connection part and the second screen connection part are used to separate the supply pipe and the rotary pipe from the discharge pipe by using the first pipe connection part and the second pipe connection part in a state in which both ends of the cylindrical screen are opened, Only the discharge tube provided with the transfer scraping means can be pulled out from the cylindrical screen to replace the scraper,
And a raw water regulating unit for regulating a supply amount of the raw water supplied to the supply pipe of the supplying means. delete delete delete delete The method according to claim 1,
The case has a partition wall for partitioning the treated water discharging part and the solids discharging part. A mounting hole for receiving the cylindrical screen is formed at the center of the partition wall,
A first compartment flange positioned between the second cylindrical flange and the second screen panel; And
And a second compartment flange positioned between the second screen panel and the second screen rotation tube,
Wherein the first compartment flange and the second compartment flange are formed to be larger than the diameter of the second cylindrical flange and the partition wall is located between the first compartment flange and the second compartment flange to divide the process water discharge part and the solids discharge part. .
delete The method according to claim 1,
Further comprising an auxiliary vane on an outer circumferential surface of the discharge tube so as to be positioned between the blade of the conveying screw to separate and stir the solid material conveyed along the conveying screw.
9. The apparatus according to claim 8,
Wherein the screw is formed at an angle equal to a blade forming angle of the conveying screw.
9. The apparatus according to claim 8,
Wherein the screw is formed at an angle that is symmetrical to the blade forming angle of the conveying screw.
2. The apparatus according to claim 1,
A driving motor provided in the base frame;
A connection shaft provided on the base frame so as to be parallel to the supply pipe and rotated by the drive motor;
A first driving pulley installed on the connection shaft and rotated in the same manner;
A second drive pulley mounted on the connection shaft and rotated in the same manner, the second drive pulley having a pitch smaller than the gear teeth of the first drive pulley;
A first driven pulley installed in the supply pipe and rotated in the same manner;
A second driven pulley installed in the first screen rotating tube and rotated in the same manner;
A first transmission unit for transmitting the rotational force of the first drive pulley to the first driven pulley to rotate the supply pipe;
A second transmitting unit for transmitting the rotational force of the second driving pulley to the second driven pulley to rotate the first screen rotating pipe; And
And a tension adjusting unit for adjusting a tension of the first transmitting unit and the second transmitting unit.

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