CN115466033A

CN115466033A - A mud hydroextractor for sewage treatment

Info

Publication number: CN115466033A
Application number: CN202211418254.6A
Authority: CN
Inventors: 孙中岩; 孙启祥; 孙法虎; 马驰
Original assignee: Zaozhuang Jindiyuan Environmental Protection Equipment Co ltd
Current assignee: Zaozhuang Jindiyuan Environmental Protection Equipment Co ltd
Priority date: 2022-11-14
Filing date: 2022-11-14
Publication date: 2022-12-13
Anticipated expiration: 2042-11-14
Also published as: CN115466033B

Abstract

The invention discloses a slurry dehydrator for sewage treatment, and relates to the technical field of sewage treatment. The mud dewatering machine for sewage treatment comprises a base plate, wherein a first conveying mechanism and a second conveying mechanism are arranged on the base plate, the first conveying mechanism and the second conveying mechanism are respectively provided with a first conveying belt and a second conveying belt, the second conveying mechanism is located above the first conveying mechanism, and the mud dewatering machine further comprises a gap mechanism which is arranged on the first conveying belt and used for carrying out gap conveying on mud and a dewatering mechanism which is arranged on the second conveying belt and used for carrying out extrusion dewatering on mud. This kind of a mud hydroextractor for sewage treatment through clearance mechanism's setting, under the effect of dehydration mechanism, will quantify place the mud of placing on the frame stir and dewater, under the continuous transmission effect of first conveyer belt, realize the transmission of the reciprocating nature that does not shut down to carry out the processing of continuous high efficiency to mud, improved the efficiency of handling mud.

Description

A mud hydroextractor for sewage treatment

Technical Field

The invention relates to the technical field of sewage treatment, in particular to a slurry dehydrator for sewage treatment.

Background

The sludge that produces among the sewage treatment process is relevant with its technology of selecting for use, and traditional AO, A2O, activated sludge method etc. belong to biological treatment process, rely on the reproduction of microorganism, form biomembrane, and the biomembrane degrades the pollutant in the sewage, and the biomembrane all has life cycle, just like people's skin, can molt and drop, also has some granule impurity that are difficult to decompose in the sewage in addition, will have sludge settling in accumulating daily life sewage treatment equipment.

In order to ensure that the sewage treatment equipment can stably operate and reduce the influence on subsequent water quality treatment, the slurry in the sewage treatment tank needs to be treated, and because the slurry contains a large amount of water, after the slurry is taken out from the sewage treatment tank, the slurry needs to be dewatered, and the existing dewaterer can be generally divided into a horizontal spiral filtering centrifuge and a horizontal spiral sedimentation centrifuge.

The existing dehydrator is used for dehydrating the sludge, a large amount of sludge is poured into the machine body, so that the dehydration of the sludge by the dehydrator is insufficient, the reduction of the sludge is greatly reduced, and the transportation cost of the sludge is increased.

Disclosure of Invention

The invention aims to provide a slurry dehydrator for sewage treatment, which solves the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a slurry dehydrator for sewage treatment comprises a bottom plate, wherein a first conveying mechanism and a second conveying mechanism are arranged on the bottom plate, the first conveying mechanism and the second conveying mechanism are respectively provided with a first conveying belt and a second conveying belt, the second conveying mechanism is positioned above the first conveying mechanism, and the slurry dehydrator also comprises a gap mechanism arranged on the first conveying belt and used for carrying out gap conveying on slurry and a dehydrating mechanism arranged on the second conveying belt and used for extruding and dehydrating the slurry;

the clearance mechanism comprises a plurality of placing frames fixedly connected to a first conveying belt, each placing frame is provided with a plurality of water permeable holes, each water permeable hole penetrates through the arrangement of the first conveying belt, an L-shaped rod is arranged on the bottom plate, a feed inlet is formed in one end, located above the first conveying belt, of the L-shaped rod, a collecting box is arranged on the bottom plate, and the collecting box is located below the first conveying belt.

Preferably, the dewatering mechanism is including setting up a plurality of control boxes on the second conveyer belt, each a plurality of sliding trays, each have been seted up to one side that the control box is close to first conveyer belt sliding tray is connected with first mounting panel, each the lateral wall and each first mounting panel magnetism of sliding tray link to each other, each the one end that the control box was kept away from to first mounting panel is equipped with the dehydration board, be equipped with on the installation pole of second conveying mechanism and be used for carrying out the first actuating mechanism of driven to each control box.

Preferably, the first driving mechanism comprises a driving plate fixedly connected to the side wall of the mounting rod, an inclined plane is formed on one side, close to the operation box, of the driving plate, a driving rod is arranged on the operation box, and the driving rod slides on the inclined plane.

Preferably, each be equipped with the moving mechanism who is used for carrying out lateral shifting to each first mounting panel in the control box, moving mechanism includes sliding block of sliding connection on two inner walls that the control box is relative, two be equipped with the slide bar that two mutual symmetries set up between the sliding block, the one end sliding connection that first mounting panel is located the control box inside is on two slide bars, be equipped with a plurality of semi-circular sand grips on the first mounting panel, each semi-circular sand grip slides on the lateral wall of sliding tray.

Preferably, each be equipped with on the control box and be convenient for two sliding blocks and carry out gliding slip subassembly, the slip subassembly is including seting up the T type groove on the control box inner wall, sliding connection has T type piece on the T type groove, the one end of T type piece is connected with the sliding block.

Preferably, be equipped with on the second conveyer belt and be used for carrying out the first telescopic machanism that stretches out and draws back to each control box, first telescopic machanism includes two first fixed pipes of fixed connection on the second conveyer belt, two sliding connection has first dead lever, two on the first fixed pipe the one end and the control box of first dead lever are connected, two the diapire of first fixed pipe is equipped with first spring, two the other end of first spring is connected with first dead lever.

Preferably, each be equipped with the second telescopic machanism that is used for stretching out and drawing back two sliding blocks on the control box, the second telescopic machanism includes the fixed pipe of second of fixed connection on the control box lateral wall, sliding connection has the second dead lever on the fixed pipe of second, the one end of second dead lever is connected with the sliding block, the diapire of the fixed pipe of second is equipped with the second spring, the other end of second spring is connected with the second dead lever.

Preferably, be equipped with the vibrations mechanism that is used for carrying out vibrations to first conveyer belt on second conveying mechanism's the installation pole, vibrations mechanism includes the second mounting panel of fixed connection on the installation pole lateral wall, sliding connection has two T type poles that mutual symmetry set up, two on the second mounting panel sliding connection has the third mounting panel on the T type pole lateral wall, one side that the third mounting panel is close to first conveyer belt is equipped with a plurality of vibrations poles, two the cover is equipped with third spring, two on the T type pole the both ends of third spring are connected with third mounting panel and second mounting panel respectively.

Preferably, be equipped with on second conveying mechanism's the installation pole and be used for carrying out driven second actuating mechanism to the third mounting panel, second actuating mechanism includes the fourth mounting panel of fixed connection on the installation pole lateral wall, it is connected with the dwang to rotate on the fourth mounting panel, the one end that the dwang is close to first conveyer belt is equipped with the turning block, be equipped with a plurality of semi-circular archs on the turning block, each semi-circular arch slides on the lateral wall of third mounting panel.

Preferably, the lateral wall of dwang is equipped with first rolling disc, be equipped with the second rolling disc in the axis of rotation of second conveying mechanism, be connected through the conveyer belt between second rolling disc and the first rolling disc.

Compared with the prior art, the invention has the beneficial effects that:

(1) This kind of a mud hydroextractor for sewage treatment through clearance mechanism's setting, under the effect of dehydration mechanism, will quantify place the mud of placing on the frame stir and dewater, under the continuous transmission effect of first conveyer belt, realize the transmission of the reciprocating of not shutting down to carry out the processing of continuous high efficiency to mud, improved the efficiency of handling mud.

(2) This kind of a mud hydroextractor for sewage treatment through the setting of vibrations mechanism, under the rotation effect of second conveyer belt, makes a plurality of semi-circular archs on the turning block drive vibrations pole clearance nature to first conveyer belt to will be attached to and shake falling in the mud of placing the frame bottom, the mud after avoiding the dehydration will place the dehydration hole jam of frame below, has influenced the dewatering effect of mud.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view showing the structure of a dewatering mechanism according to the present invention;

FIG. 3 is a schematic view showing the internal structure of the dehydration mechanism of the present invention;

FIG. 4 is an enlarged view of FIG. 1 at A;

FIG. 5 is an enlarged view of FIG. 2 at B;

fig. 6 is an enlarged view of fig. 3 at C.

In the figure: 101. a base plate; 102. a first conveyor belt; 103. a second conveyor belt; 2. a gap mechanism; 201. placing a frame; 202. water permeable holes; 203. an L-shaped rod; 204. a feed inlet; 205. a collection box; 3. a dewatering mechanism; 301. an operation box; 302. a first mounting plate; 303. a dewatering plate; 304. a sliding groove; 4. a first drive mechanism; 401. a drive plate; 402. a bevel; 403. a drive rod; 5. a moving mechanism; 501. a slider; 502. a slide bar; 503. semicircular convex strips; 6. a first telescoping mechanism; 601. a first stationary tube; 602. a first fixing lever; 603. a first spring; 7. a second telescoping mechanism; 701. a second stationary tube; 702. a second fixing bar; 8. a vibration mechanism; 801. a second mounting plate; 802. a T-shaped rod; 803. a third mounting plate; 804. a vibration rod; 805. a third spring; 9. a second drive mechanism; 901. a fourth mounting plate; 902. rotating the rod; 903. rotating the block; 904. a semicircular bulge; 905. a first rotating disk; 906. a second rotating disk; 907. and (4) a conveyor belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: a mud dehydrator for sewage treatment comprises a bottom plate 101, wherein a first conveying mechanism and a second conveying mechanism are arranged on the bottom plate 101, the first conveying mechanism and the second conveying mechanism are respectively provided with a first conveying belt 102 and a second conveying belt 103, the first conveying belt 102 and the second conveying belt 103 rotate at the same frequency, the second conveying mechanism is positioned above the first conveying mechanism, the mud dehydrator further comprises a gap mechanism 2 arranged on the first conveying belt 102 and used for carrying out gap conveying on mud and a dehydrating mechanism 3 arranged on the second conveying belt 103 and used for extruding and dehydrating the mud;

the clearance mechanism 2 comprises a plurality of placing frames 201 fixedly connected to the first conveying belt 102, a plurality of water permeable holes 202 are formed in each placing frame 201, each water permeable hole 202 penetrates through the first conveying belt 102, an L-shaped rod 203 is arranged on the bottom plate 101, a feed inlet 204 is formed in one end, located above the first conveying belt 102, of the L-shaped rod 203, a collecting box 205 is arranged on the bottom plate 101, the collecting box 205 is located below the first conveying belt 102, and through the setting of the clearance mechanism 2, mud falls into the placing frames 201 in clearance, the amount of the mud on each placing frame 201 is certain, and therefore the mud can be fully dewatered.

Referring to fig. 2, 3, 5, and 6, the dewatering mechanism 3 includes a plurality of operation boxes 301 disposed on the second conveyor belt 103, a plurality of sliding grooves 304 are disposed on one side of each operation box 301 close to the first conveyor belt 102, a first mounting plate 302 is slidably connected to each sliding groove 304, a side wall of each sliding groove 304 is magnetically connected to each first mounting plate 302, a dewatering plate 303 is disposed on one end of each first mounting plate 302 away from the operation box 301, a first driving mechanism 4 for driving each operation box 301 is disposed on a mounting rod of the second conveyor mechanism, and water inside the slurry is separated from the slurry through the arrangement of the dewatering mechanism 3.

Referring to fig. 2 and fig. 5, the first driving mechanism 4 includes a driving plate 401 fixedly connected to a side wall of the mounting rod, an inclined plane 402 is formed on one side of the driving plate 401 close to the operation box 301, a driving rod 403 is arranged on the operation box 301, and the driving rod 403 slides on the inclined plane 402, so that the operation box 301 is pushed to move close to the first conveying belt 102 continuously through the arrangement of the first driving mechanism 4.

Referring to fig. 3 and 6, a moving mechanism 5 for moving each first mounting plate 302 in the operation box 301 in a transverse direction is provided in each operation box 301, the moving mechanism 5 includes sliding blocks 501 slidably connected to two inner walls of the operation box 301 opposite to each other, two sliding rods 502 symmetrically arranged with respect to each other are provided between the two sliding blocks 501, one end of the first mounting plate 302 located inside the operation box 301 is slidably connected to the two sliding rods 502, a plurality of semicircular protruding strips 503 are provided on the first mounting plate 302, each semicircular protruding strip 503 slides on a side wall of the sliding groove 304, and by the arrangement of the moving mechanism 5, during the continuous movement of the operation box 301, the plurality of semicircular protruding strips 503 on the first mounting plate 302 continuously generate a mutual acting force with the sliding groove 304, so as to push the dewatering plate 303 to move in the slurry in the transverse direction continuously, stir the slurry, and separate moisture inside the slurry from the slurry.

Referring to fig. 3 and 6, each operation box 301 is provided with a sliding assembly for facilitating sliding of two sliding blocks 501, the sliding assembly includes a T-shaped groove formed on an inner wall of the operation box 301, the T-shaped groove is connected with a T-shaped block in a sliding manner, one end of the T-shaped block is connected with the sliding block 501, and guiding and limiting effects are provided for movement of the sliding block 501 through the arrangement of the sliding assembly.

Referring to fig. 2 and 5, the second conveyor belt 103 is provided with a first telescopic mechanism 6 for extending and retracting each operation box 301, the first telescopic mechanism 6 includes two first fixed pipes 601 fixedly connected to the second conveyor belt 103, the two first fixed pipes 601 are slidably connected with first fixed rods 602, one ends of the two first fixed rods 602 are connected with the operation box 301, the bottom walls of the two first fixed pipes 601 are provided with first springs 603, and the other ends of the two first springs 603 are connected with the first fixed rods 602, by the arrangement of the first telescopic mechanism 6, the operation box 301 is conveniently and continuously moved downward during extrusion and the operation box 301 is driven to reset when not being extruded under stress.

Referring to fig. 3 and 6, each operation box 301 is provided with a second telescopic mechanism 7 for extending and retracting the two sliding blocks 501, the second telescopic mechanism 7 includes a second fixing pipe 701 fixedly connected to the side wall of the operation box 301, the second fixing pipe 701 is slidably connected with a second fixing rod 702, one end of the second fixing rod 702 is connected with the sliding block 501, the bottom wall of the second fixing pipe 701 is provided with a second spring, the other end of the second spring is connected with the second fixing rod 702, and the dewatering plate 303 can move upwards continuously when being stressed due to the arrangement of the second telescopic mechanism 7.

Referring to fig. 1 and 4, a vibration mechanism 8 for vibrating the first conveyor belt 102 is disposed on the mounting rod of the second conveyor mechanism, the vibration mechanism 8 includes a second mounting plate 801 fixedly connected to a side wall of the mounting rod, two T-shaped rods 802 symmetrically disposed with each other are slidably connected to the second mounting plate 801, a third mounting plate 803 is slidably connected to a side wall of the two T-shaped rods 802, a plurality of vibration rods 804 are disposed on a side of the third mounting plate 803 close to the first conveyor belt 102, third springs 805 are sleeved on the two T-shaped rods 802, two ends of the two third springs 805 are respectively connected to the third mounting plate 803 and the second mounting plate 801, and through the rotation of the vibration mechanism 8, under the rotation of the second conveyor belt 103, the plurality of semicircular protrusions 904 on the rotating block 903 drive the vibration rods 804 to vibrate the first conveyor belt 102 in an intermittent manner, thereby dropping the mud attached to the bottom of the frame 201, avoiding the mud from blocking the water permeable holes 202 below the frame 201 after dewatering, and affecting the dewatering effect of the mud.

Referring to fig. 1 and 4, a second driving mechanism 9 for driving the third mounting plate 803 is disposed on the mounting rod of the second conveying mechanism, the second driving mechanism 9 includes a fourth mounting plate 901 fixedly connected to a side wall of the mounting rod, a rotating rod 902 is rotatably connected to the fourth mounting plate 901, a rotating block 903 is disposed at one end of the rotating rod 902 close to the first conveying belt 102, a plurality of semicircular protrusions 904 are disposed on the rotating block 903, each semicircular protrusion 904 slides on a side wall of the third mounting plate 803, and the second driving mechanism 9 is disposed, so as to drive the vibration rod 804 to vibrate the first conveying belt 102 in a clearance manner.

Referring to fig. 1 and 4, a first rotating disk 905 is disposed on a side wall of the rotating rod 902, a second rotating disk 906 is disposed on a rotating shaft of the second conveying mechanism, the second rotating disk 906 is connected with the first rotating disk 905 through a conveyor belt 907, and the rotating rod 902 is driven to rotate by power of the second conveyor belt 103 through the arrangement of the conveyor belt 907, so that power cost is saved.

The working principle is as follows: when the device is used, firstly, slurry is fed from the feed inlet 204, falls on the placing frames 201 on the first conveying belt 102 under the action of the gravity of the slurry, and continuously moves along with the placing frames 201 in the transmission of the first conveying belt 102, so that the slurry falls on the placing frames 201 at intervals, the amount of the slurry on each placing frame 201 is constant, and the slurry is conveniently and fully dewatered;

when the mud on the placing frame 201 is brought to the lower part of the second conveyor belt 103 by the first conveyor belt 102, the operation box 301 is driven by the second conveyor belt 103 to move continuously, when the driving rod 403 on the operation box 301 is abutted against one side of the driving plate 401, the dewatering plate 303 on the operation box 301 is driven to be continuously close to the mud on the placing frame 201 under the interaction force of the inclined surface 402, at the moment, the first spring 603 is stressed and deformed to form elastic force, when the dewatering plate 303 is abutted against the mud, the dewatering plate 303 is pushed to move upwards, in the process that the dewatering plate 303 moves upwards, the semicircular convex strips 503 on the first mounting plate 302 are abutted against the side walls of the sliding groove 304, under the guide action of the interaction force and the sliding assembly, the dewatering plate 303 is pushed to move transversely in the mud, the operation box 301 is pushed to be continuously close to the mud as the inclined surface 402 extrudes the driving rod 403 continuously, and the operation box 301 is pushed to move continuously, and during the continuous movement of the operation box 301, the semicircular convex strips 503 on the interaction force of the sliding groove 304 and the dewatering plate 303 are pushed to stir the mud to be separated from the inside of the mud;

with the continuous movement of the first conveyor belt 102, when the driving rod 403 is located below the driving plate 401, the dewatering plate 303 will not move upwards any more, and instead squeeze and dewater the slurry, the squeezing of the slurry will keep a distance to facilitate sufficient squeezing of the moisture in the slurry, with the rotation of the first conveyor belt 102, when the placement frame 201 does not move below the second conveyor belt 103, the operation box 301 resets under the elastic force of the first spring 603, the dewatering plate 303 extends outwards from the inside of the operation box 301 under the elastic force of the second spring to facilitate next use, with the continuous transmission of the first conveyor belt 102, the placement frame 201 will be driven to pass below the feeding port 204 continuously, so as to achieve continuous and efficient transmission of the reciprocating property without machine halt, and when the placement frame 201 is moved to a turning position by the first conveyor belt 102, the dewatering plate will fall into the collection box 205 under the gravity of the slurry, so as to facilitate centralized processing;

in the process of rotating the second conveying belt 103, the first rotating disc 905 is driven to rotate through the conveying belt 907, in the process of rotating the first rotating disc 905, the rotating block 903 on one end of the rotating bar 902 is driven to rotate, in the process of rotating the rotating block 903, the semicircular bulge 904 on the rotating block 903 is driven to slide on the third mounting plate 803, so that the vibration bar 804 on the third mounting plate 803 is pushed to knock on the surface of the first conveying belt 102, the first conveying belt 102 is caused to vibrate, when the semicircular bulge 904 crosses the third mounting plate 803, under the elastic force of the third spring 805, the vibration bar 804 is driven to move away from the first conveying belt 102, along with the continuous rotation of the first rotating bar 902, the plurality of semicircular bulges on the rotating block 903 drive the vibration bar 804 to vibrate the first conveying belt 102 in a clearance mode, mud attached to the bottom of the placing frame 201 is vibrated, the blockage of the water permeable holes 202 below the placing frame 201 is avoided, and the dehydration effect of the mud is influenced.

Claims

1. A mud dehydrator for wastewater treatment comprising:

the conveying device comprises a base plate (101), wherein a first conveying mechanism and a second conveying mechanism are arranged on the base plate (101), the first conveying mechanism and the second conveying mechanism are respectively provided with a first conveying belt (102) and a second conveying belt (103), and the second conveying mechanism is positioned above the first conveying mechanism;

it is characterized by also comprising:

a gap mechanism (2) arranged on the first conveying belt (102) and used for conveying slurry in a gap mode;

a dewatering mechanism (3) arranged on the second conveyor belt (103) and used for squeezing and dewatering the slurry;

the clearance mechanism (2) comprises a plurality of placing frames (201) fixedly connected to the first conveying belt (102), each placing frame (201) is provided with a plurality of water permeable holes (202), each water permeable hole (202) penetrates through the first conveying belt (102), an L-shaped rod (203) is arranged on the bottom plate (101), a feeding hole (204) is formed in one end, located above the first conveying belt (102), of the L-shaped rod (203), a collecting box (205) is arranged on the bottom plate (101), and the collecting box (205) is located below the first conveying belt (102).

2. The mud dehydrator for wastewater treatment of claim 1, wherein: dewatering mechanism (3) are including setting up a plurality of control boxes (301) on second conveyer belt (103), each a plurality of sliding tray (304) have been seted up, each to one side that control box (301) are close to first conveyer belt (102) sliding tray (304) go up sliding connection has first mounting panel (302), each the lateral wall and each first mounting panel (302) magnetism of sliding tray (304) link to each other, each the one end that control box (301) were kept away from in first mounting panel (302) is equipped with dehydration board (303), be equipped with on second conveying mechanism's the installation pole and be used for carrying out the first actuating mechanism (4) of driven to each control box (301).

3. The mud dehydrator for sewage treatment according to claim 2, wherein: the first driving mechanism (4) comprises a driving plate (401) fixedly connected to the side wall of the mounting rod, an inclined plane (402) is formed in one side, close to the operation box (301), of the driving plate (401), a driving rod (403) is arranged on the operation box (301), and the driving rod (403) slides on the inclined plane (402).

4. The mud dehydrator for wastewater treatment of claim 2, wherein: each be equipped with in control box (301) and be used for carrying out lateral shifting's moving mechanism (5) to each first mounting panel (302), moving mechanism (5) are including sliding block (501) of sliding connection on two relative inner walls of control box (301), two be equipped with slide bar (502) that two mutual symmetries set up between slide block (501), first mounting panel (302) are located the inside one end sliding connection of control box (301) on two slide bar (502), be equipped with a plurality of semi-circular sand grip (503) on first mounting panel (302), each semi-circular sand grip (503) slide on the lateral wall of sliding tray (304).

5. The mud dehydrator for sewage treatment according to claim 4, wherein: each be equipped with on control box (301) and be convenient for two sliding blocks (501) and carry out gliding slip subassembly, the slip subassembly is including seting up the T type groove on control box (301) inner wall, sliding connection has T type piece on the T type groove, the one end of T type piece is connected with sliding block (501).

6. The mud dehydrator for wastewater treatment of claim 2, wherein: be equipped with on second conveyer belt (103) and be used for carrying out first telescopic machanism (6) that stretch out and draw back to each control box (301), first telescopic machanism (6) are including two first fixed pipes (601) of fixed connection on second conveyer belt (103), two sliding connection has first dead lever (602) on first fixed pipe (601), two the one end of first dead lever (602) is connected with control box (301), two the diapire of first fixed pipe (601) is equipped with first spring (603), two the other end of first spring (603) is connected with first dead lever (602).

7. The mud dehydrator for sewage treatment according to claim 4, wherein: each be equipped with on control box (301) and be used for carrying out the second telescopic machanism (7) that stretch out and draw back to two sliding blocks (501), second telescopic machanism (7) are including fixed pipe (701) of second of fixed connection on control box (301) lateral wall, sliding connection has second dead lever (702) on the fixed pipe (701) of second, the one end of second dead lever (702) is connected with sliding block (501), the diapire of the fixed pipe (701) of second is equipped with the second spring, the other end of second spring is connected with second dead lever (702).

8. The mud dehydrator for wastewater treatment of claim 1, wherein: be equipped with on second conveying mechanism's the installation pole and be used for carrying out vibrations vibration mechanism (8) to first conveyer belt (102), vibration mechanism (8) include second mounting panel (801) of fixed connection on the installation pole lateral wall, sliding connection has T type pole (802) that two mutual symmetries set up on second mounting panel (801), two sliding connection has third mounting panel (803) on T type pole (802) lateral wall, one side that third mounting panel (803) are close to first conveyer belt (102) is equipped with a plurality of vibrations pole (804), two the cover is equipped with third spring (805), two on T type pole (802) the both ends of third spring (805) are connected with third mounting panel (803) and second mounting panel (801) respectively.

9. The mud dehydrator for wastewater treatment of claim 8, wherein: be equipped with on second conveying mechanism's the installation pole and be used for carrying out driven second actuating mechanism (9) to third mounting panel (803), second actuating mechanism (9) include fourth mounting panel (901) of fixed connection on the installation pole lateral wall, it is connected with dwang (902) to rotate on fourth mounting panel (901), the one end that dwang (902) are close to first conveyer belt (102) is equipped with turning block (903), be equipped with a plurality of semi-circular archs (904) on turning block (903), each semi-circular archs (904) slide on the lateral wall of third mounting panel (803).

10. The mud dehydrator for sewage treatment of claim 9, wherein: and a first rotating disc (905) is arranged on the side wall of the rotating rod (902), a second rotating disc (906) is arranged on the rotating shaft of the second conveying mechanism, and the second rotating disc (906) is connected with the first rotating disc (905) through a conveying belt (907).