CN117550772A - Sludge environment-friendly treatment device - Google Patents

Abstract

The application discloses a sludge environment-friendly treatment device relates to the technical field of sludge treatment. The application comprises the following steps: the device comprises a bearing frame, wherein a treatment cavity with an opening at the top is formed in the bearing frame and is used for placing sludge, a driving frame is horizontally and slidably arranged on the bearing frame, and a driving assembly used for driving the driving frame to move is arranged on the bearing frame; and the drying mechanism comprises a plurality of moving parts which are slidably arranged on the driving frame. This application removes this in-process from the processing chamber after entering into the processing chamber through moving the piece, can take out the large granule impurity of processing chamber through installing the clearance mechanism on moving the piece to can effectually reduce the impurity in the processing chamber mud, thereby indirect improvement follow-up mud makes corrugated paper's paper strength, and the inside large granule impurity of mud reduces the cooperation heating rod and has improved the mud drying effect and can prevent the phenomenon of putty appearing when follow-up environmental protection is handled.

Description

Sludge environment-friendly treatment device

Technical Field

The application relates to the technical field of sludge treatment, in particular to an environment-friendly sludge treatment device.

Background

At present, a large amount of wastewater and sludge are generated in the production process of many corrugated paper factories, wherein the sludge contains large-particle impurities such as paper fragments, sandy soil and the like. Traditional sludge treatment equipment is usually handled through carrying out the mode of heating drying to mud, then carries out further environmental protection treatment again, utilizes the mud that is through environmental protection treatment, remanufactures corrugated paper, however current sludge environmental protection treatment equipment is when carrying out the drying to mud, because the inside certain large granule impurity that contains of mud, do not clear away and influence the production quality of corrugated paper easily, and be unfavorable for the drying of mud to lead to the putty, not only, mud generally all is deposited in the bottom, when carrying out the drying to mud, and efficiency is comparatively low, needs to spend longer time when drying to mud.

Therefore, the invention provides a sludge environment-friendly treatment device.

Disclosure of Invention

The purpose of the present application is: in order to solve the problems in the background technology, the application provides a sludge environment-friendly treatment device.

The application specifically adopts the following technical scheme for realizing the purposes:

an environmental protection sludge treatment device, comprising:

the device comprises a bearing frame, wherein a treatment cavity with an opening at the top is formed in the bearing frame and is used for placing sludge, a driving frame is horizontally and slidably arranged on the bearing frame, and a driving assembly used for driving the driving frame to move is arranged on the bearing frame;

the drying mechanism comprises a plurality of moving parts which are slidably arranged on the driving frame, a heating rod is arranged on the moving parts, and a transmission assembly for driving the moving parts to vertically move towards the ring shape is arranged on the driving frame so that the moving parts sequentially move into the processing cavity;

and the cleaning mechanism is arranged on the moving part, and when the moving part moves out of the processing cavity, the large particle impurities in the processing cavity are taken out through the cleaning mechanism.

Further, the transmission assembly comprises synchronous belt assemblies arranged on the driving frame, the number of the synchronous belt assemblies is at least one, the synchronous belt assemblies comprise two transmission wheels arranged on the driving frame, the two transmission wheels are distributed up and down, one transmission wheel is located in the processing cavity, a transmission belt is synchronously connected between the two transmission wheels, a moving part is arranged on the transmission belt, the moving part is distributed in an equidistant array along the length direction of the transmission belt, and a gear motor for driving the uppermost transmission wheel to rotate is arranged on the driving frame.

Further, the moving member comprises a mounting frame connected with the driving belt, the mounting frame is provided with a stirring plate, and the heating rod is arranged on one side, far away from the driving belt, of the stirring plate.

Further, the clearing mechanism comprises a temporary storage groove arranged on one side of the stirring plate and used for fishing out large-particle impurities, a plurality of filter tanks are arranged inside the temporary storage groove in a penetrating mode, a storage box used for storing the large-particle impurities is arranged on one side of the bearing frame, and a guide assembly used for conveying the large-particle impurities in the temporary storage groove into the storage box is arranged on the driving frame.

Further, the guide assembly is including installing the semi-arc cover at drive frame top, semi-arc cover is concentric with the drive wheel of top, vertical structure has the inlet pipe that the bottom is the open-ended on the drive frame, and inlet pipe bottom is towards depositing the case top, semi-arc cover bottom has two uncovered, and one of them uncovered department intercommunication has the guide frame, the vertical through groove of having seted up of one side of guide frame towards the drive belt, guide frame one side and inlet pipe intercommunication, two guide plates are installed in guide frame bottom slope rotation, and two guide plates are towards the inlet pipe bottom, install the elasticity piece that resets on the semi-arc cover, make two guide plates involution shelter from guide frame bottom through the elasticity piece that resets.

Further, the elastic resetting piece comprises a connecting cylinder arranged on the semi-arc cover, a sliding rod is slidably arranged at the bottom end of the connecting cylinder, a convex plate is arranged at the free end of the sliding rod, linkage rods are symmetrically hinged to the convex plate, the free ends of the two linkage rods are respectively hinged to the two guide plates, and a collision spring is arranged between the sliding rod and the connecting cylinder.

Further, the stirring plate is vertically rotatably installed on the installation frame, and the shaking component acting on the stirring plate is installed on the driving frame, so that the stirring plate can shake in a reciprocating manner through the shaking component.

Further, the shake subassembly is including installing second deflector on the drive frame, the groove of forcing has been seted up to second deflector opposite side, forces the groove to be formed by a plurality of arc groove intercommunication, set up the triangular groove on the second deflector, the triangular groove on the second deflector is located forces the groove below, slidable mounting has the sliding block on the mounting bracket, install on the sliding block and be used for with force the tangential pole of forcing of groove slip, install the pin joint pole between sliding block and the stirring board, install the spring telescopic link between sliding block and the mounting bracket.

Further, the driving assembly comprises a driven rack horizontally arranged on the bearing frame, a transmission rod is horizontally and rotationally arranged on the driving frame, a transmission wheel above the driving rack is sleeved on the transmission rod, a belt pulley assembly is arranged between an output shaft of the speed reducing motor and the transmission rod, and a driving gear meshed with the driven rack is arranged on an output shaft of the speed reducing motor.

Further, a first guide plate is arranged on the driving frame, triangular grooves and forcing grooves are formed in the first guide plate, the triangular grooves in the first guide plate are located above the corresponding forcing grooves, the first guide plate is located below the guide plate, and the bottom end of the first guide plate is located in the processing cavity.

The beneficial effects of this application are as follows:

this application removes this in-process from the processing chamber after entering into the processing chamber through moving the piece, can take out the large granule impurity of processing chamber through installing the clearance mechanism on moving the piece to can effectually reduce the impurity in the processing chamber mud, thereby indirect improvement follow-up mud makes corrugated paper's paper strength, and the inside large granule impurity of mud reduces the cooperation heating rod and has improved the mud drying effect and can prevent the phenomenon of putty appearing when follow-up environmental protection is handled.

Drawings

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is an enlarged view of the structure of FIG. 1A of the present application;

FIG. 3 is a schematic view of another view of FIG. 1 of the present application;

FIG. 4 is a partial perspective cross-sectional view of FIG. 1 of the present application;

FIG. 5 is a further partial perspective cross-sectional view of FIG. 1 of the present application;

FIG. 6 is an enlarged view of the structure of FIG. 5B of the present application;

FIG. 7 is an exploded view of a portion of the construction of the present application;

FIG. 8 is an exploded view of yet another portion of the construction of the present application;

reference numerals: 1. a carrier; 2. a processing chamber; 3. a drive rack; 4. a drive assembly; 401. a driven rack; 402. a transmission rod; 403. a pulley assembly; 404. a drive gear; 5. a drying mechanism; 501. a moving member; 5011. a mounting frame; 5012. a stirring plate; 502. a heating rod; 503. a transmission assembly; 5031. a driving wheel; 5032. a transmission belt; 5033. a speed reducing motor; 6. a cleaning mechanism; 601. a temporary storage groove; 602. a filter tank; 603. a storage case; 7. a guide assembly; 701. a semi-arc shaped cover; 702. a feed pipe; 703. a guide frame; 704. a through groove; 705. a guide plate; 8. an elastic reset piece; 801. a connecting cylinder; 802. a slide bar; 803. a convex plate; 804. a linkage rod; 805. a contact spring; 9. a dithering assembly; 901. a first guide plate; 902. a second guide plate; 903. forcing the groove; 904. triangular grooves; 905. a sliding block; 906. forcing the rod; 907. a hinge rod; 908. a spring telescopic rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

As shown in fig. 1 to 8, an environment-friendly sludge treatment device according to an embodiment of the present application includes:

the sludge treatment device comprises a bearing frame 1, wherein a treatment cavity 2 with an opening at the top is formed in the bearing frame 1, the treatment cavity 2 is used for placing sludge, namely, the sludge to be dried is directly poured into the treatment cavity 2, a driving frame 3 is horizontally and slidably arranged on the bearing frame 1, and a driving assembly 4 for driving the driving frame 3 to move is arranged on the bearing frame 1;

the drying mechanism 5 comprises a plurality of moving parts 501 which are slidably arranged on the driving frame 3, a heating rod 502 is arranged on the moving parts 501, a transmission component 503 for driving the moving parts 501 to move vertically to the annular shape is arranged on the driving frame 3, so that the plurality of moving parts 501 sequentially move into the processing cavity 2, when the sludge inside the processing cavity 2 needs to be dried, the driving frame 3 horizontally reciprocates through the driving component 4 at the moment, the driving frame 3 indirectly drives the plurality of moving parts 501 arranged on the driving frame 3 to move during the movement, and then the plurality of moving parts 501 vertically circularly move through the transmission component 503, so that the plurality of moving parts 501 sequentially enter the processing cavity 2 to circulate, and as the heating rod 502 is arranged on the moving parts 501, the moving parts 501 can dry the sludge when moving into the processing cavity 2, and in the process, the driving frame 3 also horizontally reciprocates, so that the sludge at different positions in the processing cavity 2 can be dried, and the drying efficiency is improved;

the removing mechanism 6 is installed on the moving member 501, when the moving member 501 moves out of the processing cavity 2, the removing mechanism 6 is used for removing large particle impurities in the processing cavity 2, that is, in the process that the driving frame 3 and the moving member 501 move, the moving member 501 moves out of the processing cavity 2 after entering the processing cavity 2, and the removing mechanism 6 installed on the moving member 501 is used for removing the large particle impurities in the processing cavity 2, so that impurities in sludge in the processing cavity 2 can be effectively reduced, the paper strength of corrugated paper manufactured by follow-up sludge is indirectly improved, the drying effect of the sludge is improved, and the phenomenon of blocking during follow-up environment-friendly processing can be prevented.

As shown in fig. 1, fig. 4 and fig. 7, in some embodiments, the transmission assembly 503 includes at least one synchronous belt assembly mounted on the driving frame 3, the synchronous belt assembly includes two driving wheels 5031 mounted on the driving frame 3, the two driving wheels 5031 are distributed up and down, and one driving wheel 5031 is located in the processing cavity 2, a transmission belt 5032 is synchronously connected between the two driving wheels 5031, preferably, the driving wheels 5031 are existing sprockets, the transmission belt 5032 is an existing chain, the moving member 501 is mounted on the transmission belt 5032, that is, the moving member 501 is mounted on a chain link of the chain, preferably, the number of synchronous belt assemblies is two, the moving member 501 is distributed in an equidistant array along the length direction of the transmission belt 5032, and a speed reducing motor 5033 for driving the uppermost driving wheel 5031 to rotate is mounted on the driving frame 3, that is, when the speed reducing motor 5033 is started, the driving wheel 5031 located at the uppermost is rotated by the transmission belt 5031, and the corresponding driving wheel 5031 is rotated by the transmission belt 5032, so that the transmission belt 5031 is driven by the transmission belt 5032, the transmission belt 5032 is driven by the driving motor 5032, and the plurality of driving members 501 need to move in sequence, and the multiple driving members 501 need to move in the processing cavity 32.

As shown in fig. 1, 4 and 7, in some embodiments, the moving member 501 includes a mounting bracket 5011 connected with the driving belt 5032, the mounting bracket 5011 is provided with a stirring board 5012, the heating rod 502 is installed on one side of the stirring board 5012 far away from the driving belt 5032, the stirring board 5012 is rectangular plate-shaped, so that sludge inside the processing cavity 2 can be better stirred, and the heating rod 502 installed on the stirring board 5012 is matched, so that sludge deposited in the processing cavity 2 can be better heated, and the heating effect is further improved.

As shown in fig. 1, fig. 3 and fig. 7, in some embodiments, the cleaning mechanism 6 includes a temporary storage tank 601 provided on one side of the stirring plate 5012, which is used for taking out large particle impurities, a plurality of filter tanks 602 are provided inside the temporary storage tank 601, a storage tank 603 for storing large particle impurities is provided on one side of the carrier 1, a guide assembly 7 for conveying large particle impurities in the temporary storage tank 601 into the storage tank 603 is provided on the driving rack 3, that is, as the driving belt 5032 moves, one side of the stirring plate 5012 with the temporary storage tank 601 can enter into the processing cavity 2, when the stirring plate 5012 moves out of the processing cavity 2, the temporary storage tank 601 of the stirring plate 5012 is opened upwards, so that the temporary storage tank 601 has sludge salvaged from the processing cavity 2, because the filter tanks 602 are provided inside the temporary storage tank 601, and large particle impurities can flow out from the filter tanks 602, and the large particle impurities in the temporary storage tank 601 can be located in the temporary storage tank 601, the large particle impurities can be conveyed into the storage tank 603 by the guide assembly 7, so that the stirring plate 5012 can not enter into the processing cavity 2, and the processing speed of the processing cavity 2 is further improved.

As shown in fig. 1, 4 and 5, in some embodiments, the guiding assembly 7 includes a semi-arc cover 701 mounted on the top of the driving frame 3, the semi-arc cover 701 is concentric with the uppermost driving wheel 5031, the driving frame 3 is vertically configured with a feeding pipe 702 with an opening at the bottom, the bottom of the feeding pipe 702 faces the top of the storage box 603, that is, when the feeding pipe 702 has large particle impurities, the feeding pipe enters the storage box 603 due to the action of gravity, the bottom of the semi-arc cover 701 has two openings, one opening is communicated with a guiding frame 703, as shown in fig. 1, after the stirring plate 5012 enters the semi-arc cover 701 from the other opening, the stirring plate 5012 is turned over, so that the large particle impurities in the temporary storage groove 601 enter the guiding frame 703 due to the action of gravity, the guiding frame 703 vertically opens a through groove 704 towards one side of the driving belt 5032, the through groove 704 is used for enabling the installation frame 5011 to normally pass through the guide frame 703 without affecting the normal movement of the installation frame 5011, one side of the guide frame 703 is communicated with the feed pipe 702, two guide plates 705 are obliquely and rotatably arranged at the bottom of the guide frame 703, the bottommost ends of the two guide plates 705 face the feed pipe 702, that is, when large particle impurities fall into the guide frame 703, the large particle impurities fall onto the two guide plates 705 at the moment, so that the large particle impurities fall into the feed pipe 702 under the action of gravity, the semi-arc cover 701 is provided with an elastic reset piece 8, the two guide plates 705 are oppositely combined and blocked at the bottom of the guide frame 703 through the elastic reset piece 8, as shown in fig. 1, the driving belt 5032 moves clockwise, so that a stirring plate 5012 positioned in the semi-arc cover 701 contacts the two guide plates 705 when moving, and the large particle impurities on the stirring plate 5012 enter the feed pipe 702 along the guide plates 705, the stirring board 5012 can make two guide boards 705 rotate when contacting two guide boards 705 to make two guide boards 705 not shelter from the opening of guide frame 703 bottom, make stirring board 5012 can pass guide frame 703, it should be noted that there is a stirring board 5012 in half arc-shaped cover 701, only after stirring board 5012 shifts out from guide frame 703, the next stirring board 5012 can only enter into half arc-shaped cover 701 this moment, so there is certain interval between stirring board 5012 and stirring board 5012, so after stirring board 5012 passes the opening of guide frame 703 bottom, can make guide board 705 have enough time to rotate to reset through elastic reset piece 8, in this kind of mode shift the big granule impurity in the stirring board 5012 into deposit case 603, thereby can take out the big granule impurity in the stirring board 5012 in the course of stirring board 5012 removal, thereby need not repeatedly close gear motor 5033, further improvement efficiency of removing impurity.

As shown in fig. 1, fig. 4, fig. 5 and fig. 8, in some embodiments, the elastic restoring member 8 includes a connecting cylinder 801 installed on the semi-arc cover 701, a sliding rod 802 is slidably installed at the bottom end of the connecting cylinder 801, a convex plate 803 is configured at the free end of the sliding rod 802, a linkage rod 804 is symmetrically hinged on the convex plate 803, two free ends of the linkage rods 804 are respectively hinged on two guide plates 705, an interference spring 805 is installed between the sliding rod 802 and the connecting cylinder 801, when a stirring plate 5012 located in the guide frame 703 touches the guide plates 705, at this time, the guide plates 705 rotate to enable the linkage rod 804 to move, because one end of the linkage rod 804 is hinged on the convex plate 803, and the convex plate 803 is configured on the sliding rod 802, the guide plates can enable the sliding rod 802 to move when moving, and then the interference spring 805 is pulled, at this time, the two guide plates 705 can be separated from each other, and after the stirring plate 5012 is no longer contacted with the guide plates 705, at this time, the interference spring 805 can reset due to self elastic deformation, and then drive the free ends of the two guide plates 705 to mutually close to the bottom opening of the guide frame 703, so that the two guide plates 705 can be blocked by opening, and simultaneously, and when the two guide plates 705 can be kept open by opening and the other guide plate 705.

As shown in fig. 1 and 7, in some embodiments, the stirring board 5012 is vertically rotatably mounted on the mounting frame 5011, and the driving frame 3 is provided with a shaking component 9 acting on the stirring board 5012, and the stirring board 5012 is reciprocally shaken by the shaking component 9, that is, the stirring board 5012 is reciprocally rotated by a small extent during use by the shaking component 9, so that sludge adhering to the temporary storage tank 601 can be effectively reduced, and excessive sludge is prevented from entering the storage tank 603 along with large particle impurities.

As shown in fig. 1, 3 and 7, in some embodiments, the shaking component 9 includes a second guide plate 902 mounted on the driving frame 3, a forcing groove 903 is formed on opposite sides of the second guide plate 902, the forcing groove 903 is formed by a plurality of arc grooves, a triangular groove 904 is formed on the second guide plate 902, the triangular groove 904 on the second guide plate 902 is located below the forcing groove 903, a sliding block 905 is slidably mounted on the mounting frame 5011, a forcing rod 906 for sliding tangent to the forcing groove 903 is mounted on the sliding block 905, a hinge rod 907 is mounted between the sliding block 905 and the stirring plate 5012, a spring telescopic rod 908 is mounted between the sliding block 905 and the mounting frame 5011, in particular, the spring telescopic rod 908 includes a sleeve mounted on the mounting frame 5011, one end of the sleeve is slidably mounted with the sliding block 905, a spring is mounted between the sleeve and the sleeve, when the stirring plate 5012 is moved into the processing cavity 2, a sludge is provided in the stirring plate 5012, the stirring plate 905 is slidably moved out of the processing cavity 2, the stirring plate 907 is continuously moved along the hinge rod 905 after the sliding block 5012 is driven by the sliding block 907, and thus the stirring plate 905 is continuously moved into the stirring cavity 2, and the stirring rod 906 is continuously forced to be continuously moved along the hinge rod 905, and the reciprocating rod is continuously moved into the hollow groove 905 is continuously along the hinge rod 905, and the sliding rod is continuously forced into the inside the groove is continuously, and the sliding rod is forced into the groove 906, and the stirring rod is continuously, as the sliding rod is continuously, the sliding rod is pushed, and the rod is pushed, and is, when the rod is, and is mounted, and is pushed, and, in, and is mounted.

As shown in fig. 1 and 4, in some embodiments, the driving assembly 4 includes a driven rack 401 horizontally mounted on the carrier 1, a transmission rod 402 is horizontally and rotatably mounted on the driving frame 3, a driving wheel 5031 positioned above is sleeved on the transmission rod 402, a belt pulley assembly 403 is mounted between an output shaft of the speed reducing motor 5033 and the transmission rod 402, a driving gear 404 engaged with the driven rack 401 is mounted on an output shaft of the speed reducing motor 5033, that is, when the speed reducing motor 5033 is started, the rotation of the output shaft of the speed reducing motor 5033 drives the transmission rod 402 to rotate through the belt pulley assembly 403, a plurality of driving belts 5032 are moved because the driving wheel 5031 is sleeved on the transmission rod 402, and furthermore, the rotation of the output shaft of the speed reducing motor 5033 drives the driving gear 404 mounted on the output shaft because the driving gear 404 is engaged with the driven rack 401, therefore, when the driving gear 404 rotates, the driving gear 404 moves along the length direction of the driven rack 401, so as to realize the movement of the driving frame 3, the movement of the driving frame 3 and the movement of the driving belt 5032 can be realized only by controlling the speed reducing motor 5033 to rotate positively and negatively, and no additional electric driving is needed, and it is to be noted that the driving belt 5032 at this time reciprocates clockwise, that is, as shown in the figure, the stirring plate 5012 can only play a role in filtering large particles when the driving belt 5032 rotates clockwise, if the effect of filtering large particles by the stirring plate 5012 is further improved, the motor for driving the driving rod 402 to rotate can be independently arranged on the semi-arc cover 701, and then the belt pulley assembly 403 is detached, so that suitable modification can be performed according to the requirements of users and the amount of the sludge containing the large particles.

As shown in fig. 1, fig. 6 and fig. 7, in some embodiments, a first guide plate 901 is installed on the driving frame 3, a triangular groove 904 and a forcing groove 903 are formed on the first guide plate 901, the triangular groove 904 on the first guide plate 901 is located above the corresponding forcing groove 903, the first guide plate 901 is located below the guide plate 705, the bottom end of the first guide plate 901 is located in the processing cavity 2, when the stirring plate 5012 enters the processing cavity 2, the forcing rod 906 can enter the triangular groove 904 of the first guide plate 901 at this time, so that the stirring plate 5012 can shake repeatedly when located in the processing cavity 2, the stirring effect on sludge is effectively improved, besides, the efficiency of the stirring plate 5012 in salvaging large particles in the processing cavity 2 can be effectively improved by shaking the stirring plate 5012, and the impurity removing effect is improved.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The utility model provides a mud environmental protection processing apparatus which characterized in that includes:

the sludge treatment device comprises a bearing frame (1), wherein a treatment cavity (2) with an opening at the top is formed in the bearing frame (1), the treatment cavity (2) is used for placing sludge, a driving frame (3) is horizontally and slidably arranged on the bearing frame (1), and a driving assembly (4) for driving the driving frame (3) to move is arranged on the bearing frame (1);

the drying mechanism (5) comprises a plurality of moving parts (501) which are slidably arranged on a driving frame (3), a heating rod (502) is arranged on the moving parts (501), and a transmission assembly (503) for driving the moving parts (501) to vertically move towards the ring shape is arranged on the driving frame (3) so as to enable the plurality of moving parts (501) to sequentially move into the processing cavity (2);

and the cleaning mechanism (6) is arranged on the moving part (501), and when the moving part (501) moves out of the processing cavity (2), the large-particle impurities in the processing cavity (2) are taken out through the cleaning mechanism (6).

2. The sludge environment-friendly treatment device according to claim 1, wherein the transmission assembly (503) comprises synchronous belt assemblies arranged on the driving frame (3), the number of the synchronous belt assemblies is at least one, the synchronous belt assemblies comprise two transmission wheels (5031) arranged on the driving frame (3), the two transmission wheels (5031) are distributed up and down, one transmission wheel (5031) is arranged in the treatment cavity (2), a transmission belt (5032) is synchronously connected between the two transmission wheels (5031), the moving part (501) is arranged on the transmission belt (5032), the moving part (501) is distributed in an equidistant array along the length direction of the transmission belt (5032), and a speed reducing motor (5033) for driving the uppermost transmission wheel (5031) to rotate is arranged on the driving frame (3).

3. The sludge environment-friendly treatment device according to claim 2, wherein the moving member (501) comprises a mounting frame (5011) connected with the transmission belt (5032), the mounting frame (5011) is provided with a stirring plate (5012), and the heating rod (502) is arranged on one side of the stirring plate (5012) away from the transmission belt (5032).

4. A sludge environmental protection treatment device according to claim 3, characterized in that, the clearing mechanism (6) is including seting up temporary storage tank (601) in stirring board (5012) one side, and it is used for taking out big granule impurity, a plurality of filter tanks (602) have been seted up in the inside running through of temporary storage tank (601), storage case (603) that are used for depositing big granule impurity are installed to one side of bearing frame (1), install guide assembly (7) that are used for carrying big granule impurity in temporary storage tank (601) to in storage case (603) on driving frame (3).

5. The sludge environment-friendly treatment device according to claim 4, wherein the guide assembly (7) comprises a semi-arc cover (701) arranged at the top of the driving frame (3), the semi-arc cover (701) is concentric with the uppermost driving wheel (5031), a feeding pipe (702) with an opening at the bottom is vertically arranged on the driving frame (3), the bottom of the feeding pipe (702) faces the top of the storage box (603), two openings are formed in the bottom of the semi-arc cover (701), one opening is communicated with a guide frame (703), a through groove (704) is vertically formed in one side of the guide frame (703) facing the driving belt (5032), one side of the guide frame (703) is communicated with the feeding pipe (702), two guide plates (705) are obliquely and rotatably arranged at the bottom of the guide frame (703), an elastic reset piece (8) is arranged at the lowest end of the two guide plates (705) towards the feeding pipe (702), and the two guide plates (705) are enabled to be in closing and shielding the bottom of the guide frame (703) through the elastic reset piece (8).

6. The sludge environment-friendly treatment device according to claim 5, wherein the elastic reset piece (8) comprises a connecting cylinder (801) arranged on a semi-arc cover (701), a sliding rod (802) is slidably arranged at the bottom end of the connecting cylinder (801), a convex plate (803) is arranged at the free end of the sliding rod (802), a linkage rod (804) is symmetrically hinged on the convex plate (803), the free ends of the two linkage rods (804) are respectively hinged on two guide plates (705), and a collision spring (805) is arranged between the sliding rod (802) and the connecting cylinder (801).

7. The sludge environment-friendly treatment device according to claim 5, wherein the stirring plate (5012) is vertically rotatably mounted on a mounting frame (5011), and the driving frame (3) is provided with a shaking assembly (9) acting on the stirring plate (5012), and the stirring plate (5012) is reciprocally shaken by the shaking assembly (9).

8. The sludge environment-friendly treatment device according to claim 7, wherein the shaking assembly (9) comprises a second guide plate (902) installed on the driving frame (3), forcing grooves (903) are formed in opposite sides of the second guide plate (902), the forcing grooves (903) are formed by communicating a plurality of arc grooves, triangular grooves (904) are formed in the second guide plate (902), the triangular grooves (904) in the second guide plate (902) are located below the forcing grooves (903), a sliding block (905) is installed on the mounting frame (5011) in a sliding mode, a forcing rod (906) used for being tangent to the forcing grooves (903) in a sliding mode is installed on the sliding block (905), a hinging rod (907) is installed between the sliding block (905) and the stirring plate (5012), and a spring telescopic rod (908) is installed between the sliding block (905) and the mounting frame (5011).

9. The sludge environment-friendly treatment device according to claim 2, wherein the driving assembly (4) comprises a driven rack (401) horizontally mounted on the bearing frame (1), a transmission rod (402) is horizontally and rotationally mounted on the driving frame (3), a transmission wheel (5031) positioned above is sleeved on the transmission rod (402), a belt pulley assembly (403) is mounted between an output shaft of the gear motor (5033) and the transmission rod (402), and a driving gear (404) meshed with the driven rack (401) is mounted on an output shaft of the gear motor (5033).

10. The sludge environment-friendly treatment device according to claim 8, wherein the driving frame (3) is provided with a first guide plate (901), the first guide plate (901) is provided with triangular grooves (904) and forcing grooves (903), the triangular grooves (904) on the first guide plate (901) are positioned above the corresponding forcing grooves (903), the first guide plate (901) is positioned below the guide plate (705) and the bottom end of the first guide plate is positioned in the treatment cavity (2).