CN110668671A - Quick dewatering device of mud - Google Patents

Abstract

The invention discloses a sludge rapid dehydration device, which comprises a working box and a working cavity in the working box, wherein a fixed plate is arranged in the working cavity in a sliding manner, a dehydration box is rotatably arranged on the upper end surface of the fixed plate, the peripheral surface of the dehydration box is provided with fine dehydration holes, an annular chain is fixedly arranged on the outer end wall of the bottom of the dehydration box, a dehydration cavity is arranged in the dehydration box, and a moisture sensor is fixedly arranged on the bottom wall of the dehydration cavity. And the use loss of the equipment is also reduced.

Description

Quick dewatering device of mud

Technical Field

The invention relates to the field of sludge dewatering equipment, in particular to a rapid sludge dewatering device.

Background

In the process of sludge treatment, some sludge contains a certain amount of moisture, so that the sludge appears in the form of turbid liquid, the recycling of the sludge is influenced, at the moment, the sludge is usually dewatered, filter residues are formed after the dewatering treatment, and the filter residues can be used as filler for recycling.

Disclosure of Invention

The invention aims to provide a quick sludge dewatering device, which overcomes the problems.

The invention is realized by the following technical scheme.

A sludge rapid dehydration device comprises a working box and a working chamber in the working box, wherein a fixed plate is arranged in the working chamber in a sliding manner, a dehydration box is arranged on the upper end face of the fixed plate in a rotating manner, the peripheral surface of the dehydration box is provided with fine dehydration holes, an annular chain is fixedly arranged on the outer end wall of the bottom of the dehydration box, a dehydration chamber is arranged in the dehydration box, a moisture sensor is fixedly arranged on the bottom wall of the dehydration chamber, a first chute is arranged at the bottom of the dehydration box, the first chute is arranged in a bilateral symmetry manner, a first sliding block is arranged in the first chute in a sliding manner, the first sliding block is connected with the first chute through a first spring, a moving rod is fixedly arranged on the upper end face of the first sliding block, a first belt wheel and a second belt wheel positioned on the lower side of the first belt wheel are fixedly arranged on the moving rod, a sliding block positioned, the sliding block is connected with the top wall of the working cavity through a second spring, a cavity is arranged in the sliding block, the cavity is opened downwards, a first rotating shaft is arranged in the cavity in a rotating mode, the first rotating shaft extends downwards into the dewatering cavity, a first gear, a first cam and a second cam are sequentially and fixedly arranged on the first rotating shaft from top to bottom, an annular cavity is arranged on the outer end wall of the dewatering box, a sensor is fixedly arranged on the inner wall of the annular cavity, the sensor is arranged in an annular mode, third springs are fixedly arranged on the upper cavity wall and the lower cavity wall of the annular cavity, and the opposite end faces of the third springs are connected with an;

the lower end surface of the fixed plate is fixedly provided with a chain, the chain is connected with the bottom wall of the working cavity through a fourth spring, the bottom wall of the working cavity is fixedly provided with a fixed rod positioned on the left side of the fixed plate, the fixed rods are symmetrically arranged in the front and back direction, the upper end surface of the fixed rod is fixedly provided with a collecting box, a collecting cavity is arranged in the collecting box, the upper end of the working box is fixedly provided with a feeding box, a feeding cavity is arranged in the feeding box, the feeding cavity is upwards opened, the right end of the feeding box is provided with a discharge hole, a sliding cavity positioned on the lower side of the discharge hole is arranged in the feeding box, a sliding clamping block is arranged in the sliding cavity in a sliding mode, the sliding clamping block is connected with the sliding cavity through a fifth spring, a second sliding chute positioned on the upper side of the discharge hole is arranged in the, the top of the second sliding chute is fixedly provided with an electromagnet, and the electromagnet is connected with the sliding plate through a sixth spring;

when sludge to be dehydrated enters the dehydration cavity, the dehydration box rotates to dehydrate the sludge in the dehydration cavity, the first rotating shaft rotates to drive the moving rod to relatively slide in the dehydration cavity, so that the sludge in the dehydration cavity is prevented from being solidified, the dehydration efficiency is not influenced, after dehydration is completed, the dehydration box moves leftwards to the upper side of the collection cavity, the dehydration box is rotated, and the sludge after dehydration in the dehydration box enters the collection cavity to be collected.

Further, a third chute is arranged at the bottom of the working box, a second slider is arranged in the third chute in a sliding manner, the second slider is connected with the third chute through a seventh spring, the second slider is connected with the sliding clamping block through a second pull rope, a rotating cavity is arranged in the second slider, a second rotating shaft is arranged in the rotating cavity in a rotating manner, the second rotating shaft extends upwards into the working cavity, a second gear is fixedly arranged on the second rotating shaft, a first bevel gear positioned on the upper side of the second gear is fixedly arranged on the second rotating shaft, a third rotating shaft positioned on the lower side of the first bevel gear is rotatably arranged on the rear end face of the working cavity, a second bevel gear is fixedly arranged on the third rotating shaft, a fourth rotating shaft positioned on the right side of the third rotating shaft is rotatably arranged on the rear end face of the working cavity, and the fourth rotating shaft is in transmission connection with the third rotating shaft through a first belt pulley, and a rotating gear is fixedly arranged on the fourth rotating shaft and is meshed with the chain.

Further, the bottom wall of the left side of the working cavity is fixedly provided with a motor, the upper end face of the motor is in power connection with a power shaft, and the power shaft is in transmission connection with the second rotating shaft through a second belt pulley.

Further, the working chamber bottom wall rotates and is equipped with and is located the transmission pivot on second pivot right side, the third gear has set firmly in the transmission pivot, the working chamber bottom wall rotates and is equipped with and is located the fifth pivot on transmission pivot right side, the fifth pivot with the transmission pivot is passed through third belt pulley transmission and is connected, the fourth gear has set firmly in the fifth pivot, the fifth pivot top has set firmly the fifth gear, the working chamber roof rotates and is equipped with and is located the left sixth pivot of fifth pivot, set firmly in the sixth pivot with fifth gear engagement's sixth gear, sixth pivot bottom has set firmly the seventh gear.

Further, the left cavity wall of the working cavity rotates to be provided with a seventh rotating shaft, an eighth gear is fixedly arranged on the seventh rotating shaft, a threaded rod is fixedly arranged on the right end face of the seventh rotating shaft, a threaded sleeve is connected to the outer side of the threaded rod through threads, a rotating block is fixedly arranged on the right end face of the threaded sleeve, a fourth sliding groove is formed in the upper end of the threaded sleeve, an annular groove located on the right side of the fourth sliding groove is formed in the threaded sleeve, a third sliding block is arranged in the fourth sliding groove in a sliding mode, a fifth sliding groove located on the upper side of the threaded sleeve is formed in the top of the working box, a fourth sliding block is arranged in the fifth sliding groove in a sliding mode, the fourth sliding block is connected with the fifth sliding groove through an eighth spring, and the fourth sliding.

Further, the wall of the left chamber of the working chamber is provided with an eighth rotating shaft located on the lower side of the seventh rotating shaft in a rotating manner, a ninth gear meshed with the eighth gear is fixedly arranged on the eighth rotating shaft, a third bevel gear is fixedly arranged at the right end of the eighth rotating shaft, a tenth gear located on the right side of the eighth rotating shaft is rotatably arranged on the wall of the rear chamber of the working chamber, a fourth bevel gear meshed with the third bevel gear is fixedly arranged on the tenth gear, a ninth rotating shaft located on the lower side of the tenth gear is rotatably arranged on the wall of the rear chamber of the working chamber, a fifth bevel gear is fixedly arranged on the ninth rotating shaft, and the ninth rotating shaft is in transmission connection with the tenth gear through a fourth belt pulley.

Further, the second belt pulley is an elastic belt pulley.

The invention has the beneficial effects that: the sludge dewatering equipment improves the working efficiency of the traditional sludge dewatering equipment, the traditional sludge dewatering equipment dewaters sludge in a drying mode, and the dewatered sludge is solidified in the inner wall of the equipment.

Drawings

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

FIG. 1 is a schematic view of the overall structure of a rapid sludge dewatering device according to the present invention;

FIG. 2 is a schematic view of the structure at A in FIG. 1;

FIG. 3 is a schematic view of the structure at B in FIG. 1;

FIG. 4 is a schematic view of the structure of FIG. 1 at C;

fig. 5 is a schematic structural diagram at D in fig. 1.

Detailed Description

The present invention will be further described with reference to the following description and examples, which include but are not limited to the following examples.

As shown in fig. 1-5, a sludge rapid dewatering device comprises a working chamber 10 and a working chamber 11 in the working chamber 10, wherein a fixed plate 52 is slidably disposed in the working chamber 11, a dewatering box 48 is rotatably disposed on an upper end surface of the fixed plate 52, fine dewatering holes are formed on a peripheral surface of the dewatering box 48, an annular chain 39 is fixedly disposed on an outer end wall of a bottom of the dewatering box 48, a dewatering chamber 49 is disposed in the dewatering box 48, a moisture sensor 40 is fixedly disposed on a bottom wall of the dewatering chamber 49, a first sliding chute 47 is disposed at a bottom of the dewatering box 48, the first sliding chute 47 is symmetrically disposed left and right, a first sliding block 46 is slidably disposed in the first sliding chute 47, the first sliding block 46 is connected with the first sliding chute 47 through a first spring 45, a moving rod 51 is fixedly disposed on an upper end surface of the first sliding block 46, a first belt pulley 50 and a second belt pulley 44 located on a lower side of the first belt pulley 50 are fixedly disposed on the, a sliding block 95 positioned on the upper side of the moisture sensor 40 is slidably arranged in the working cavity 11, the sliding block 95 is connected with the top wall of the working cavity 11 through a second spring 32, a cavity 96 is arranged in the sliding block 95, the cavity 96 is opened downwards, a first rotating shaft 42 is rotatably arranged in the cavity 96, the first rotating shaft 42 extends downwards into the dewatering cavity 49, a first gear 30, a first cam 43 and a second cam 41 are sequentially and fixedly arranged on the first rotating shaft 42 from top to bottom, an annular cavity 81 is arranged on the outer end wall of the dewatering box 48, a sensor 84 is fixedly arranged on the inner wall of the annular cavity 81, the sensor 84 is annularly arranged, a third spring 82 is fixedly arranged on the upper cavity wall and the lower cavity wall of the annular cavity 81, and the opposite end surface of the third spring 82 is connected with an annular fixing plate;

the lower end surface of the fixed plate 52 is fixedly provided with a chain 53, the chain 53 is connected with the bottom wall of the working chamber 11 through a fourth spring 55, the bottom wall of the working chamber 11 is fixedly provided with a fixed rod 60 positioned at the left side of the fixed plate 52, the fixed rod 60 is symmetrically arranged in front and back, the upper end surface of the fixed rod 60 is fixedly provided with a collecting box 76, a collecting chamber 74 is arranged in the collecting box 76, the upper end of the working chamber 10 is fixedly provided with a feeding box 28, a feeding chamber 29 is arranged in the feeding box 28, the feeding chamber 29 is upwardly opened, the right end of the feeding box 28 is provided with a discharge hole 92, a sliding chamber 90 positioned at the lower side of the discharge hole 92 is arranged in the feeding box 28, a sliding fixture block 91 is arranged in the sliding chamber 90 in a sliding manner, the sliding fixture block 91 is connected with the sliding chamber 90 through a fifth spring 87, and a, a sliding plate 89 is arranged in the second sliding chute 88 in a sliding manner, the sliding plate 89 is made of metal, the sliding plate 89 is connected with the sliding block 95 through a first pull rope 31, an electromagnet 86 is fixedly arranged at the top of the second sliding chute 88, and the electromagnet 86 is connected with the sliding plate 89 through a sixth spring 85;

when sludge to be dehydrated enters the dehydration cavity 49, the dehydration box 48 rotates to dehydrate the sludge in the dehydration cavity 49, the first rotating shaft 42 rotates to drive the moving rod 51 to relatively slide in the dehydration cavity 49, so that the sludge consolidation in the dehydration cavity 49 is avoided, the dehydration efficiency is influenced, after dehydration is completed, the dehydration box 48 moves leftwards to the upper side of the collection cavity 74, the dehydration box 48 is rotated, and the sludge in the dehydration box 48 after dehydration is completed enters the collection cavity 74 to be collected.

Beneficially, a third sliding groove 67 is disposed at the bottom of the working box 10, a second sliding block 78 is slidably disposed in the third sliding groove 67, the second sliding block 78 is connected to the third sliding groove 67 through a seventh spring 66, the second sliding block 78 is connected to the sliding block 91 through a second pull rope 80, a rotating cavity 79 is disposed in the second sliding block 78, a second rotating shaft 62 is rotatably disposed in the rotating cavity 79, the second rotating shaft 62 extends upward into the working cavity 11, a second gear 65 is fixedly disposed on the second rotating shaft 62, a first bevel gear 73 located on the upper side of the second gear 65 is fixedly disposed on the second rotating shaft 62, a third rotating shaft 63 located on the lower side of the first bevel gear 73 is rotatably disposed on the rear end surface of the working cavity 11, a third rotating shaft 64 is fixedly disposed on the third rotating shaft 63, a fourth rotating shaft 56 located on the right side of the third rotating shaft 63 is rotatably disposed on the rear end surface of the working cavity 11, the fourth rotating shaft 56 is in transmission connection with the third rotating shaft 63 through a first belt pulley 59, a rotating gear 57 is fixedly arranged on the fourth rotating shaft 56, and the rotating gear 57 is meshed with the chain 53.

Advantageously, a motor 68 is fixedly arranged on the bottom wall of the left side of the working cavity 11, a power shaft 70 is dynamically connected to the upper end surface of the motor 68, and the power shaft 70 is in transmission connection with the second rotating shaft 62 through a second belt pulley 69.

Beneficially, the bottom wall of the working chamber 11 is rotatably provided with a transmission rotating shaft 58 located on the right side of the second rotating shaft 62, the transmission rotating shaft 58 is fixedly provided with a third gear 61, the bottom wall of the working chamber 11 is rotatably provided with a fifth rotating shaft 37 located on the right side of the transmission rotating shaft 58, the fifth rotating shaft 37 is in transmission connection with the transmission rotating shaft 58 through a third belt pulley 54, the fifth rotating shaft 37 is fixedly provided with a fourth gear 38, the top of the fifth rotating shaft 37 is fixedly provided with a fifth gear 36, the top wall of the working chamber 11 is rotatably provided with a sixth rotating shaft 34 located on the left side of the fifth rotating shaft 37, the sixth rotating shaft 34 is fixedly provided with a sixth gear 33 engaged with the fifth gear 36, and the bottom of the sixth rotating shaft 34 is fixedly provided with a seventh gear 35.

Beneficially, a seventh rotating shaft 16 is rotatably disposed on a left cavity wall of the working cavity 11, an eighth gear 17 is fixedly disposed on the seventh rotating shaft 16, a threaded rod 18 is fixedly disposed on a right end face of the seventh rotating shaft 16, a threaded sleeve 19 is threadedly connected to an outer side of the threaded rod 18, a rotating block 22 is fixedly disposed on a right end face of the threaded sleeve 19, a fourth sliding groove 20 is disposed at an upper end of the threaded sleeve 19, an annular groove 23 located on a right side of the fourth sliding groove 20 is disposed on the threaded sleeve 19, a third sliding block 21 is slidably disposed in the fourth sliding groove 20, a fifth sliding groove 27 located on an upper side of the threaded sleeve 19 is disposed at a top of the working box 10, a fourth sliding block 26 is slidably disposed in the fifth sliding groove 27, the fourth sliding block 26 is connected with the fifth sliding groove 27 through an eighth spring 25, and the fourth sliding block 26 is fixedly connected with the third sliding block 21.

Advantageously, an eighth rotating shaft 13 is rotatably disposed on the left cavity wall of the working cavity 11 and located below the seventh rotating shaft 16, a ninth gear 12 engaged with the eighth gear 17 is fixedly disposed on the eighth rotating shaft 13, a third bevel gear 15 is fixedly disposed at the right end of the eighth rotating shaft 13, a tenth gear 14 located on the right side of the eighth rotating shaft 13 is rotatably disposed on the rear cavity wall of the working cavity 11, a fourth bevel gear 77 engaged with the third bevel gear 15 is fixedly disposed on the tenth gear 14, a ninth rotating shaft 71 located below the tenth gear 14 is rotatably disposed on the rear cavity wall of the working cavity 11, a fifth bevel gear 72 is fixedly disposed on the ninth rotating shaft 71, and the ninth rotating shaft 71 and the tenth gear 14 are in transmission connection through a fourth belt pulley 75.

Advantageously, said second pulley 69 is an elastic pulley.

Sequence of mechanical actions of the whole device:

the initial state of the invention is as follows: the electromagnet 86 is powered off, the sliding plate 89 extrudes the sliding clamping block 91 to close the feeding cavity 29, the first pull rope 31 is in a tensioned state, the sliding block 95 is retracted, the second pull rope 80 is in a relaxed state, the seventh spring 66 is in a relaxed state, the first bevel gear 73 and the fifth bevel gear 72 are in a meshed state, the fourth spring 55 is in a compressed state, the rotating block 22 and the annular cavity 81 are in the same horizontal position, and the third sliding block 21 is positioned in the fourth sliding groove 20;

1. the electromagnet 86 is electrified, the electromagnet 86 is electrified to attract the sliding plate 89 to move upwards, the feeding cavity 29 is opened, the sliding plate 89 moves upwards to enable the first pull rope 31 to be loosened, the first pull rope 31 is loosened to enable the second spring 32 to be reset, the second spring 32 is reset to enable the sliding block 95 to move downwards until the first gear 30 and the seventh gear 35 are in a meshed state;

2. sludge to be dehydrated enters the dehydration cavity 49 through the discharge hole 92, when the sludge completely enters the dehydration cavity 49, the fifth spring 87 is reset to enable the sliding fixture block 91 to move upwards, the sliding fixture block 91 moves upwards to tension the second pull rope 80, the second pull rope 80 is tensioned to enable the second slide block 78 to move rightwards, the second slide block 78 moves rightwards to drive the second rotating shaft 62 to move rightwards, and the first bevel gear 73 and the second bevel gear 64, and the second gear 65 and the third gear 61 are in a meshed state;

3. starting the motor 68, wherein the motor 68 rotates to drive the power shaft 70 to rotate, because the power shaft 70 is in transmission connection with the second rotating shaft 62 through the second belt pulley 69, the power shaft 70 rotates to drive the second rotating shaft 62 to rotate, the second rotating shaft 62 rotates to drive the first bevel gear 73 to rotate, the first bevel gear 73 rotates to drive the second bevel gear 64 to rotate, the second bevel gear 64 rotates to drive the third rotating shaft 63 to rotate, because the third rotating shaft 63 is in transmission connection with the fourth rotating shaft 56 through the first belt pulley 59, the third rotating shaft 63 rotates to drive the fourth rotating shaft 56 to rotate, the fourth rotating shaft 56 rotates to drive the rotating gear 57 to rotate, the rotating gear 57 rotates to drive the chain 53 to move upwards, the chain 53 moves upwards to drive the fixing plate 52 to move upwards, and the fixing plate 52 moves upwards to drive the dewatering box 48 to move upwards until the annular chain 39 and the fourth;

4. the second rotating shaft 62 rotates to drive the second gear 65 to rotate, the second gear 65 rotates to drive the third gear 61 to rotate, the third gear 61 rotates to drive the transmission rotating shaft 58 to rotate, the transmission rotating shaft 58 rotates to drive the fifth rotating shaft 37 to rotate as the transmission rotating shaft 58 is in transmission connection with the fifth rotating shaft 37 through the third belt pulley 54, the transmission rotating shaft 58 rotates to drive the fifth rotating shaft 37 to rotate, the fifth rotating shaft 37 rotates to drive the fourth gear 38 to rotate, the fourth gear 38 rotates to drive the annular chain 39 to rotate, the annular chain 39 rotates to drive the dewatering box 48 to rotate, and the dewatering box 48 rotates to dewater sludge in the dewatering cavity 49;

5. the fifth rotating shaft 37 rotates to drive the fifth gear 36 to rotate, the fifth gear 36 rotates to drive the sixth gear 33 to rotate, the sixth gear 33 rotates to drive the sixth rotating shaft 34 to rotate, the sixth rotating shaft 34 rotates to drive the seventh gear 35 to rotate, the seventh gear 35 rotates to drive the first gear 30 to rotate, the first gear 30 rotates to drive the first rotating shaft 42 to rotate, the first rotating shaft 42 rotates to drive the first cam 43 and the second cam 41 to rotate, the first cam 43 and the second cam 41 rotate to enable the first sliding block 46 to relatively slide in the first sliding chute 47, and the sludge in the dewatering cavity 49 is continuously oscillated by the first belt pulley 50 and the second belt pulley 44 to prevent the sludge from being solidified and influence the dewatering efficiency;

6. after the dehydration is finished, the moisture sensor 40 sends an electric signal to cut off the electromagnet 86, the electromagnet 86 is cut off to reset the sixth spring 85, the sixth spring 85 is reset to enable the sliding plate 89 to move downwards to press the sliding clamping block 91, the sliding plate 89 moves downwards to tension the first pulling rope 31, the first pulling rope 31 is tensioned to enable the sliding block 95 to move upwards, the sliding block 95 moves upwards to enable the first gear 30 and the seventh gear 35 to be disengaged, and the first rotating shaft 42 is retracted;

7. the sliding fixture block 91 is extruded to enable the second pull rope 80 to be loosened, the second pull rope 80 is loosened to enable the seventh spring 66 to be reset, the seventh spring 66 is reset to drive the second slide block 78 to move leftwards, the second slide block 78 moves leftwards to drive the second rotating shaft 62 to move leftwards, and the first bevel gear 73 is meshed with the fifth bevel gear 72;

8. the chain 53 drives the fixing plate 52 to move downwards to the initial position under the action of the fourth spring 55;

9. the first bevel gear 73 rotates to drive the fifth bevel gear 72 to rotate, the fifth bevel gear 72 rotates to drive the ninth rotating shaft 71 to rotate, the ninth rotating shaft 71 and the tenth gear 14 are in transmission connection through a fourth belt pulley 75, the ninth rotating shaft 71 rotates to drive the tenth gear 14 to rotate, the tenth gear 14 rotates to drive the fourth bevel gear 77 to rotate, the fourth bevel gear 77 is meshed with the third bevel gear 15, the fourth bevel gear 77 rotates to drive the third bevel gear 15 to rotate, the third bevel gear 15 rotates to drive the eighth rotating shaft 13 to rotate, the eighth rotating shaft 13 rotates to drive the ninth gear 12 to rotate, the ninth gear 12 is meshed with the eighth gear 17, the ninth gear 12 rotates to drive the eighth gear 17 to rotate, the eighth gear 17 rotates to drive the seventh rotating shaft 16 to rotate, the seventh rotating shaft 16 rotates to drive the threaded rod 18 to rotate, the threaded rod 18 rotates to drive the threaded sleeve 19 to move rightwards under the action of the third slider 21, the screw sleeve 19 moves rightwards to enable the rotating block 22 to be clamped into the annular cavity 81 and fixed with the dewatering box 48 through the annular fixing plate 83;

10. when the rotating block 22 presses the sensor 84, the motor 68 is started to rotate reversely, so that the rotating block 22 drives the dewatering box 48 to move leftwards, when the third slide block 21 slides into the annular groove 23, the dewatering box 48 is positioned at the upper side of the collecting box 76, the fourth slide block 26 presses the eighth spring 25, the threaded rod 18 rotates to drive the threaded sleeve 19 to rotate the threaded sleeve 19 to drive the rotating block 22 to rotate, the rotating block 22 rotates to drive the dewatering box 48 to rotate, sludge in the dewatering cavity 49 is poured into the collecting cavity 74, and the collection of the sludge is completed.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a quick dewatering device of mud, including the work box and the working chamber in the work box, the slip is equipped with fixed plate, its characterized in that in the working chamber: the upper end face of the fixed plate is rotatably provided with a dewatering box, the peripheral surface of the dewatering box is provided with fine dewatering holes, the outer end wall of the bottom of the dewatering box is fixedly provided with an annular chain, a dewatering cavity is arranged in the dewatering box, the bottom wall of the dewatering cavity is fixedly provided with a moisture sensor, the bottom of the dewatering box is provided with a first chute, the first chute is arranged in bilateral symmetry, a first slide block is arranged in the first chute in a sliding manner, the first slide block is connected with the first chute through a first spring, the upper end face of the first slide block is fixedly provided with a moving rod, a first belt wheel and a second belt wheel are fixedly arranged on the moving rod, the second belt wheel is positioned on the lower side of the first belt wheel, a slide block positioned on the upper side of the moisture sensor is arranged in the working cavity in a sliding manner, the slide block is connected with the top wall of, a first rotating shaft is rotatably arranged in the cavity, the first rotating shaft extends downwards into the dewatering cavity, a first gear, a first cam and a second cam are fixedly arranged on the first rotating shaft from top to bottom in sequence, an annular cavity is formed in the outer end wall of the dewatering box, a sensor is fixedly arranged on the inner wall in the annular cavity, the sensor is annularly arranged, third springs are fixedly arranged on the upper cavity wall and the lower cavity wall of the annular cavity, and the opposite end faces of the third springs are connected with an annular fixing plate;

the lower end surface of the fixed plate is fixedly provided with a chain, the chain is connected with the bottom wall of the working cavity through a fourth spring, the bottom wall of the working cavity is fixedly provided with a fixed rod positioned on the left side of the fixed plate, the fixed rods are symmetrically arranged in the front and back direction, the upper end surface of the fixed rod is fixedly provided with a collecting box, a collecting cavity is arranged in the collecting box, the upper end of the working box is fixedly provided with a feeding box, a feeding cavity is arranged in the feeding box, the feeding cavity is upwards opened, the right end of the feeding box is provided with a discharge hole, a sliding cavity positioned on the lower side of the discharge hole is arranged in the feeding box, a sliding clamping block is arranged in the sliding cavity in a sliding mode, the sliding clamping block is connected with the sliding cavity through a fifth spring, a second sliding chute positioned on the upper side of the discharge hole is arranged in the, the top of the second sliding chute is fixedly provided with an electromagnet, and the electromagnet is connected with the sliding plate through a sixth spring;

when sludge to be dehydrated enters the dehydration cavity, the dehydration box rotates to dehydrate the sludge in the dehydration cavity, the first rotating shaft rotates to drive the moving rod to relatively slide in the dehydration cavity, so that the sludge in the dehydration cavity is prevented from being solidified, the dehydration efficiency is not influenced, after dehydration is completed, the dehydration box moves leftwards to the upper side of the collection cavity, the dehydration box is rotated, and the sludge after dehydration in the dehydration box enters the collection cavity to be collected.

2. The rapid sludge dewatering device of claim 1, wherein: a third chute is arranged at the bottom of the working tank, a second sliding block is arranged in the third chute in a sliding manner, the second sliding block is connected with the third chute through a seventh spring, the second sliding block is connected with the sliding clamping block through a second pull rope, a rotating cavity is arranged in the second sliding block, a second rotating shaft is arranged in the rotating cavity in a rotating manner, the second rotating shaft extends upwards into the working cavity, a second gear is fixedly arranged on the second rotating shaft, a first bevel gear positioned on the upper side of the second gear is fixedly arranged on the second rotating shaft, a third rotating shaft positioned on the lower side of the first bevel gear is rotatably arranged on the rear end face of the working cavity, a second bevel gear is fixedly arranged on the third rotating shaft, a fourth rotating shaft positioned on the right side of the third rotating shaft is rotatably arranged on the rear end face of the working cavity, and the fourth rotating shaft is in transmission connection with the third rotating shaft through a first belt pulley, and a rotating gear is fixedly arranged on the fourth rotating shaft and is meshed with the chain.

3. The rapid sludge dewatering device of claim 2, wherein: the bottom wall of the left side of the working cavity is fixedly provided with a motor, the upper end face of the motor is in power connection with a power shaft, and the power shaft is in transmission connection with the second rotating shaft through a second belt pulley.

4. The rapid sludge dewatering device of claim 1, wherein: the working chamber bottom wall rotates and is equipped with and is located the transmission pivot on second pivot right side, the third gear has set firmly in the transmission pivot, the working chamber bottom wall rotates and is equipped with and is located the fifth pivot on transmission pivot right side, the fifth pivot with the transmission pivot is passed through third belt pulley transmission and is connected, the fourth gear has set firmly in the fifth pivot, the fifth pivot top has set firmly the fifth gear, the working chamber roof rotates and is equipped with and is located the left sixth pivot of fifth pivot, set firmly in the sixth pivot with fifth gear engagement's sixth gear, sixth pivot bottom has set firmly the seventh gear.

5. The rapid sludge dewatering device of claim 1, wherein: the working chamber left side chamber wall rotates and is equipped with the seventh pivot, the eighth gear has set firmly in the seventh pivot, seventh pivot right-hand member face has set firmly the threaded rod, threaded rod outside threaded connection has the threaded sleeve, threaded sleeve right-hand member face has set firmly rotatory piece, the threaded sleeve upper end is equipped with the fourth spout, be equipped with on the threaded sleeve and be located the ring channel on fourth spout right side, it is equipped with the third slider to slide in the fourth spout, the work box top is equipped with and is located the fifth spout of threaded sleeve upside, it is equipped with the fourth slider to slide in the fifth spout, the fourth slider with the fifth spout passes through eighth spring coupling, the fourth slider with the third slider passes through slide bar fixed connection.

6. The rapid sludge dewatering device of claim 5, wherein: the working chamber left side chamber wall rotates and is equipped with and is located the eighth pivot of seventh pivot downside, set firmly in the eighth pivot with eighth gear engagement's ninth gear, eighth pivot right-hand member has set firmly third bevel gear, the working chamber back cavity wall rotates and is equipped with and is located the tenth gear on eighth pivot right side, set firmly on the tenth gear with third bevel gear engagement's fourth bevel gear, the working chamber back cavity wall rotates and is equipped with and is located the ninth pivot of tenth gear downside, set firmly fifth bevel gear in the ninth pivot, the ninth pivot with the tenth gear passes through fourth belt pulley transmission and connects.

7. The rapid sludge dewatering device of claim 3, wherein: the second belt pulley is an elastic belt pulley.

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