CN111115632B - Activated carbon production and processing equipment - Google Patents

Abstract

The invention relates to the technical field of activated carbon processing equipment, in particular to activated carbon production and processing equipment. This device is provided with the processing board in four different apertures, actuating mechanism utilizes the processing board in four different apertures to process out not unidimensional active carbon through the clamp plate, drive the clamp plate at actuating mechanism and carry out the up-and-down motion in-process, two connecting rods of accessible drive the push pedal group of both sides respectively with the raw materials active carbon in the active carbon bin progressively in the circulation propulsion device, and then realize the volume production of not unidimensional active carbon, the active carbon after the processing is discharged by four output channel, and collect by different collection device, and then realize when the not unidimensional active carbon of volume production, can not take place blocking phenomenon because of once only dropping into too much active carbon, also can not drop into raw materials active carbon in the device frequently because of dropping into too little.

Description

Activated carbon production and processing equipment

Technical Field

The invention relates to the technical field of activated carbon processing equipment, in particular to activated carbon production and processing equipment.

Background

For example, the utility model discloses a No. CN 207142837U's an active carbon production processing environmental protection equipment, including support frame and fastener, install the fixed plate on the support frame, the top of support frame is fixed with the bearing frame, the bearing frame is connected with the main shaft, the disc is installed to the one end of main shaft, the connecting rod is installed in the outside of disc, the one end of fixed rod is fixed with the bolt seat, be connected with the double-screw bolt on the bolt seat, be equipped with the processing case on the support frame, the top of processing case is fixed with the fixed bolster, the motor is installed on the top of fixed bolster, the motor is connected with electric telescopic handle. The utility model discloses, through being equipped with first perforated plate, second perforated plate, third perforated plate and fourth perforated plate around the disc respectively, the aperture size differs on four perforated plates, selects the perforated plate in different apertures according to the user's demand to process out corresponding active carbon, make active carbon processing equipment application scope wider. The device can only process and produce the active carbon of a size singly in the production process of the active carbon, if want to produce the active carbon of other sizes and need change different orifice plates and use, and can't the active carbon of different sizes of volume production simultaneously with this kind of method, the active carbon of the multiple size of volume production more accords with the production and processing demand of reality, and the device is when carrying out active carbon processing, once only fills raw materials active carbon into the processing case, and if load too much, then easily takes place the jam phenomenon, too little then need frequently load the raw materials and carry out the processing of active carbon.

Disclosure of Invention

The invention aims to provide activated carbon production and processing equipment which can simultaneously process activated carbon with various sizes, can gradually and automatically convey raw material activated carbon into a device in the processing process, cannot generate a blocking phenomenon due to the fact that too much activated carbon is added at one time, and cannot frequently add the raw material activated carbon into the device due to too little input.

The purpose of the invention is realized by the following technical scheme:

an active carbon production and processing device comprises a processing box, a supporting frame, a driving mechanism and pressing plates, wherein the supporting frame is fixedly connected to the upper end of the processing box, the middle part of the driving mechanism is provided with the driving mechanism, the four pressing plates are respectively and fixedly connected to four corners of the lower part of the driving mechanism, the active carbon production and processing device also comprises a sub-processing box, four processing plates, a pushing plate group, a connecting rod, an active carbon storage box and an output channel, the sub-processing box is provided with four sub-processing boxes, the four sub-processing boxes are uniformly connected in the processing box, an inner processing plate is fixedly connected in each sub-processing box, when the active carbon production and processing device works, the four pressing plates are respectively and slidably connected in the four sub-processing boxes, the outer ends of the four processing boxes are fixedly connected with the active carbon storage box, the connecting rod is provided with two connecting rods, the inner, the push pedal group is provided with two, and the inner of two push pedal groups rotates respectively to be connected in the outer end of two connecting rods, and sliding connection is in two activated carbon bin lower parts that are located the left respectively at the both ends of one of them push pedal group, and sliding connection is in two activated carbon bin lower parts that are located the right respectively at the both ends of another push pedal group, and the equal fixedly connected with output channel of lower extreme of four sub-processing casees

As a further optimization of the technical scheme, the activated carbon production and processing equipment provided by the invention is characterized in that four processing cavities are arranged in the processing box, the lower end of the processing box is fixedly connected with the device supporting frame, the front, rear, left and right inner walls of each processing cavity are provided with the mounting groove I, and the four sub-processing boxes are respectively and fixedly connected in the four processing cavities.

As the technical scheme is further optimized, the middle parts of four outer wall surfaces of the sub-processing box are fixedly connected with mounting plates I, the middle parts of four inner wall surfaces of the sub-processing box are respectively provided with mounting grooves II, the four mounting plates I are respectively connected in the four corresponding mounting grooves I in a sliding mode, and the four processing plates are respectively and fixedly connected in the four sub-processing boxes.

According to the activated carbon production processing equipment, a plurality of processing holes are uniformly formed in the processing plate, the three adjacent wall surfaces of the processing plate are fixedly connected with the mounting plate II, the other wall surface of the processing plate is fixedly connected with the mounting plate III, the three mounting plates II and the mounting plate III are respectively connected in the four mounting grooves II in a sliding mode, and the mounting plate III is located on the outer side.

According to the activated carbon production and processing equipment, threaded holes I are formed in the middle of the four sides of the upper end of the sub-processing box, threaded holes II are formed in the upper end of the mounting plate II corresponding to the threaded holes II, and the same bolt penetrates through the corresponding threaded holes I and the corresponding threaded holes II.

As a further optimization of the technical scheme, the processing holes on the four processing plates are different in size.

As a further optimization of the technical scheme, the lower parts of the left and right ends of the support frame are provided with holes, the driving mechanism comprises a telescopic rod connecting plate and a pressing rod, the upper end of the telescopic rod is fixedly connected with the middle part of the support frame, the lower end of the telescopic rod is fixedly connected with the connecting plate, the four corners of the lower surface of the connecting plate are fixedly connected with the pressing rod, the middle part of the upper end of the pressing plate is provided with a connecting sleeve, the lower end of the pressing rod is fixedly connected in the corresponding connecting sleeve, the inner ends of the two pushing plate groups are respectively connected in the two holes in a sliding manner, and the inner ends of the two connecting rods are respectively connected to the.

As a further optimization of the technical scheme, the active carbon production and processing equipment comprises a T-shaped connecting plate, L-shaped connecting rods and a push plate, wherein the inner end of the T-shaped connecting plate is rotatably connected to the outer end of the corresponding connecting rod, two ends of a transverse plate of the T-shaped connecting plate are respectively and fixedly connected with the two L-shaped connecting rods, the inner ends of the two T-shaped push plates are respectively and fixedly connected with the push plate, and the push plates are slidably connected into the lower ends of the corresponding active carbon storage boxes.

As a further optimization of the technical scheme, the activated carbon production and processing equipment comprises two side walls, a landslide, a storage box and a slide-in hole, wherein the landslide is fixedly connected between the two side walls, the storage box is fixedly connected to the outer ends of the two side walls, a slide-in hole is formed between the lower end of the storage box and the outer end of the landslide, the push plate is slidably connected into the corresponding slide-in hole, the lower surface of the push plate is slidably connected to the surface of the landslide, and an activated carbon plate is stored in the storage box.

As a further optimization of the technical scheme, the lower end of the output channel is provided with the material conveying pipe, and the joint of the material conveying pipe and the output channel is provided with the inclined sliding surface.

The active carbon production and processing equipment has the beneficial effects that:

this device is provided with the processing board in four different apertures, actuating mechanism utilizes the processing board in four different apertures to process out not unidimensional active carbon through the clamp plate, drive the clamp plate at actuating mechanism and carry out the up-and-down motion in-process, two connecting rods of accessible drive the push pedal group of both sides respectively with the raw materials active carbon in the active carbon bin progressively in the circulation propulsion device, and then realize the volume production of not unidimensional active carbon, the active carbon after the processing is discharged by four output channel, and collect by different collection device, and then realize when the not unidimensional active carbon of volume production, can not take place blocking phenomenon because of once only dropping into too much active carbon, also can not drop into raw materials active carbon in the device frequently because of dropping into too little.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the overall structure of an activated carbon production and processing apparatus according to the present invention;

FIG. 2 is a schematic overall fragmentary structure of the present invention;

FIG. 3 is a first schematic view of the construction of the processing box of the present invention;

FIG. 4 is a second schematic structural view of the processing box of the present invention;

FIG. 5 is a schematic view of the construction of the sub-fab of the present invention;

FIG. 6 is a schematic structural view of a tooling plate of the present invention;

FIG. 7 is a schematic structural view of the support frame and drive mechanism of the present invention;

FIG. 8 is a schematic structural view of a platen of the present invention;

FIG. 9 is a schematic structural view of a thrust plate assembly and a connecting rod of the present invention;

FIG. 10 is a first schematic view of the activated carbon storage bin of the present invention;

FIG. 11 is a second schematic structural view of the activated carbon storage bin of the present invention;

fig. 12 is a schematic diagram of the structure of the output channel of the present invention.

In the figure: a processing box 1; a processing cavity 1-1; 1-2 of a support frame; mounting grooves I1-3; a sub-processing box 2; the mounting plate I2-1; mounting groove II 2-2; 2-3 of a threaded hole; processing the plate 3; machining a hole 3-1; mounting plate II 3-2; a threaded hole II 3-3; a support frame 4; 4-1 of a hole; a drive mechanism 5; 5-1 of a telescopic rod; a connecting plate 5-2; 5-3 of a pressure lever; a pressing plate 6; 6-1 of a connecting sleeve; a push plate group 7; a T-shaped connecting plate 7-1; an L-shaped connecting rod 7-2; 7-3 of a push plate; a connecting rod 8; an activated carbon storage tank 9; side wall 9-1; landslide 9-2; a storage tank 9-3; sliding into hole 9-4; an output channel 10; 10-1 of a material conveying pipe; and (4) a sloping slide surface 10-2.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

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.

In the description of the present invention, it is to be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "circumferential", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In the present invention, unless otherwise expressly specified or limited, the terms "disposed," "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected or detachably connected; may be a mechanical connection; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The first embodiment is as follows:

the following description of the embodiment with reference to fig. 1-12 shows an activated carbon production and processing apparatus, which comprises a processing box 1, a supporting frame 4, a driving mechanism 5 and four pressing plates 6, wherein the supporting frame 4 is fixedly connected to the upper end of the processing box 1, the driving mechanism 5 is arranged in the middle of the driving mechanism 5, the four pressing plates 6 are respectively and fixedly connected to four corners of the lower part of the driving mechanism 5, the activated carbon production and processing apparatus further comprises a sub-processing box 2, a processing plate 3, a pushing plate group 7, a connecting rod 8, an activated carbon storage box 9 and an output channel 10, the sub-processing box 2 is provided with four, the four sub-processing boxes 2 are uniformly connected in the processing box 1, the inner processing plate 3 is fixedly connected in each sub-processing box 2, during operation, the four pressing plates 6 are respectively and slidably connected in the four sub-processing boxes 2, the outer ends of the four processing boxes 1 are fixedly connected with the activated carbon storage box, connecting rod 8 is provided with two, and the inner of two connecting rods 8 rotates respectively to be connected both ends about actuating mechanism 5, push away board group 7 is provided with two, and the inner of two push away board groups 7 rotates respectively to be connected in the outer end of two connecting rods 8, and sliding connection is in two left active carbon bin 9 lower parts of lieing in respectively at the both ends of one of them push away board group 7, and sliding connection is in two active carbon bin 9 lower parts of lieing in the right side respectively at the both ends of another push away board group 7, and the equal fixedly connected with delivery channel 10 of lower extreme of four sub-processing case 2.

This device is provided with the processing board 3 in four different apertures, actuating mechanism 5 utilizes the processing board 3 in four different apertures to process the active carbon of unidimensional through clamp plate 6, drive clamp plate 6 at actuating mechanism 5 and carry out the up-and-down motion in-process, two connecting rods 8 of accessible drive the push pedal group 7 of both sides respectively with the raw materials active carbon in the active carbon bin 9 progressively in the circulation propulsion unit, and then realize the volume production of unidimensional active carbon, the active carbon after the processing is discharged by four delivery channel 10, and collect by the collection device of difference, and then realize in the active carbon of volume production unidimensional, can not take place blocking phenomenon because of once only throwing into too much active carbon, also can not throw into the raw materials active carbon in the device frequently because of throwing into too little.

The second embodiment is as follows:

the following describes the present embodiment with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, four processing chambers 1-1 are disposed in the processing box 1, the lower end of the processing chamber is fixedly connected with a device supporting frame 1-2, the front, rear, left and right inner walls of each processing chamber 1-1 are provided with mounting grooves i 1-3, and four sub processing boxes 2 are respectively and fixedly connected in the four processing chambers 1-1.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 12, and the second embodiment is further described in the present embodiment, the mounting plates i 2-1 are fixedly connected to the middle portions of the four outer wall surfaces of the sub processing box 2, the mounting grooves ii 2-2 are respectively arranged on the middle portions of the four inner wall surfaces of the sub processing box, the four mounting plates i 2-1 are respectively slidably connected to the corresponding four mounting grooves i 1-3, and the four processing plates 3 are respectively fixedly connected to the four sub processing boxes 2.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 12, wherein a plurality of processing holes 3-1 are uniformly formed in the processing plate 3, mounting plates ii 3-2 are fixedly connected to three adjacent wall surfaces of the processing plate 3, a mounting plate iii 3-4 is fixedly connected to the other wall surface, the three mounting plates ii 3-2 and the mounting plates iii 3-4 are respectively slidably connected to the four mounting grooves ii 2-2, and the mounting plates iii 3-4 are located outside.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 12, the threaded holes i 2-3 are formed in the middle of the four sides of the upper end of the sub processing box 2, the threaded holes ii 3-3 are formed in the upper end of the mounting plate ii 3-2 corresponding to the threaded holes ii 3-3, and the same bolt penetrates through the corresponding threaded holes i 2-3 and the corresponding threaded holes ii 3-3.

The sixth specific implementation mode:

the present embodiment will be described with reference to fig. 1 to 12, and the present embodiment will further describe a fourth embodiment in which the size of the machining holes 3-1 in the four machining plates 3 is different from each other.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1 to 12, which further describes the first embodiment, the lower portions of the left and right ends of the support frame 4 are provided with holes 4-1, the driving mechanism 5 includes a telescopic rod 5-1, a connecting plate 5-2 and a pressing rod 5-3, the upper end of the telescopic rod 5-1 is fixedly connected to the middle portion of the support frame 4, the lower end of the telescopic rod 5-1 is fixedly connected to the connecting plate 5-2, the four corners of the lower surface of the connecting plate 5-2 are fixedly connected to the pressing rod 5-3, the middle portion of the upper end of the pressing plate 6 is provided with a connecting sleeve 6-1, the lower end of the pressing rod 5-3 is fixedly connected to the corresponding connecting sleeve 6-1, the inner ends of the two pushing plate groups 7 are respectively slidably, the inner ends of the two connecting rods 8 are respectively and rotatably connected to the left end and the right end of the connecting plate 5-2.

The specific implementation mode is eight:

the following describes the present embodiment with reference to fig. 1 to 12, and the seventh embodiment is further described in the present embodiment, where the push plate group 7 includes a T-shaped connecting plate 7-1, L-shaped connecting rods 7-2 and push plates 7-3, the inner ends of the T-shaped connecting plate 7-1 are rotatably connected to the outer ends of corresponding connecting rods 8, two ends of a transverse plate of the T-shaped connecting plate 7-1 are respectively and fixedly connected with the two L-shaped connecting rods 7-2, the inner ends of the two T-shaped push plates 7-3 are both fixedly connected with the push plates 7-3, and the push plates 7-3 are slidably connected in the lower ends of corresponding activated carbon storage boxes 9.

The specific implementation method nine:

this embodiment will be described with reference to fig. 1 to 12, and this embodiment will further describe embodiment eight, the activated carbon storage box 9 comprises a side wall 9-1, a landslide 9-2, a storage box 9-3 and a slide-in hole 9-4, two side walls 9-1 are arranged, a landslide 9-2 is fixedly connected between the two side walls 9-1, the storage box 9-3 is fixedly connected with the outer ends of the two side walls 9-1, the lower end of the storage box 9-3 and the outer end of the landslide 9-2 form a sliding hole 9-4, the push plate 7-3 is connected in a corresponding sliding-in hole 9-4 in a sliding mode, the lower surface of the push plate 7-3 is connected on the surface of the landslide 9-2 in a sliding mode, and an activated carbon plate is stored in the storage box 9-3.

The detailed implementation mode is ten:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, a feed delivery pipe 10-1 is disposed at the lower end of the output channel 10, an inclined sliding surface 10-2 is disposed at the joint of the feed delivery pipe 10-1 and the output channel 10, and the inclined sliding surface 10-2 facilitates the output of activated carbon from the feed delivery pipe 10-1.

The invention relates to an active carbon production and processing device, which has the working principle that:

when the device is used for producing and processing activated carbon with different sizes, in an initial state, the telescopic rod 5-1 is in an extension state, namely the four press plates 6 are respectively positioned in the four sub-processing boxes 2, and the push plate 7-3 is positioned at the outermost end of the sliding hole 9-4.

When the device is used, a sufficient amount of raw activated carbon is first put into the storage tank 9-3.

After the operation is finished, the processing work of the active carbon can be started, the telescopic rod 5-1 is started, the telescopic rod 5-1 can be an electric telescopic rod and can be connected with a relay, and then reciprocating expansion and contraction are realized, so that the continuous active carbon processing is carried out.

After the telescopic rod 5-1 is electrified, the telescopic rod 5-1 is contracted, the connecting plate 5-2 moves upwards along with the telescopic rod 5-1, the four pressing plates 6 are further gradually separated from the four sub-processing boxes 2 respectively, the two connecting rods 8 move upwards along with the connecting plate 5-2 while the connecting plate 5-2 moves upwards, inward rotation with the axis of the connecting end of the connecting plate 5-2 as a central line is generated, inward horizontal movement is generated at the lower ends of the two connecting rods 8, the two connecting rods 8 respectively drive the two T-shaped connecting plates 7-1 to move inwards, and the pushing plates 7-3 slide inwards along the sliding holes 9-4, so that raw material activated carbon at the bottommost layer is pushed out and enters the corresponding sub-processing boxes 2 through the sliding slopes 9-2.

After the movement is finished, the telescopic rods 5-1 extend, so that the pressing plates 6 gradually enter the corresponding sub processing boxes 2, raw activated carbon is extruded downwards, activated carbon with different sizes is processed through the processing plates 3, the processed activated carbon is output through the output channels 10 through the material conveying pipes 10-1, the lower ends of the material conveying pipes 10-1 can be provided with collecting devices, and the output activated carbon is collected by the collecting devices. At the same time, each push plate 7-3 also returns to the outermost end of each slide-in hole 9-4, which is again in the most initial state.

The reciprocating motion can realize the mass production of the activated carbon with different sizes, and simultaneously can not cause the blocking phenomenon because of the excessive activated carbon input at one time, and can not frequently input the raw material activated carbon into the device because of the small input.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides an active carbon production processing equipment, is including processing case (1), support frame (4), actuating mechanism (5) and clamp plate (6), support frame (4) fixed connection be in the upper end of processing case (1), the middle part of support frame (4) is provided with actuating mechanism (5), clamp plate (6) are provided with four, and four clamp plates (6) are fixed connection respectively in four corners department of actuating mechanism (5) lower part, its characterized in that: the activated carbon production and processing equipment further comprises sub processing boxes (2), processing plates (3), a push plate group (7), connecting rods (8), an activated carbon storage box (9) and an output channel (10), wherein the sub processing boxes (2) are provided with four, the four sub processing boxes (2) are uniformly connected in the processing boxes (1), the processing plates (3) are fixedly connected in each sub processing box (2), during work, the four press plates (6) are respectively connected in the four sub processing boxes (2) in a sliding manner, the outer ends of the four processing boxes (1) are fixedly connected with the activated carbon storage box (9), the connecting rods (8) are provided with two, the inner ends of the two connecting rods (8) are respectively connected with the left end and the right end of the driving mechanism (5) in a rotating manner, the push plate group (7) is provided with two, the inner ends of the two push plate groups (7) are respectively connected with the outer ends of the two connecting rods (8) in a rotating, two ends of one of the pushing plate groups (7) are respectively connected to the lower parts of the two activated carbon storage boxes (9) on the left side in a sliding mode, two ends of the other pushing plate group (7) are respectively connected to the lower parts of the two activated carbon storage boxes (9) on the right side in a sliding mode, and the lower ends of the four sub-processing boxes (2) are respectively fixedly connected with an output channel (10).

2. The activated carbon production and processing equipment of claim 1, wherein: four processing cavities (1-1) are arranged in the processing box (1), the lower end of the processing box is fixedly connected with a device supporting frame (1-2), the front inner wall, the rear inner wall, the left inner wall and the right inner wall of each processing cavity (1-1) are respectively provided with a mounting groove I (1-3), and the four sub processing boxes (2) are respectively and fixedly connected in the four processing cavities (1-1).

3. The activated carbon production and processing equipment of claim 2, wherein: four outer wall surface middle parts of the sub-processing box (2) are fixedly connected with mounting plates I (2-1), four inner wall surface middle parts of the sub-processing box are provided with mounting grooves II (2-2), the four mounting plates I (2-1) are respectively in sliding connection in the corresponding four mounting grooves I (1-3), and the four processing plates (3) are respectively and fixedly connected in the four sub-processing boxes (2).

4. The activated carbon production and processing equipment of claim 3, wherein: evenly be provided with a plurality of process holes (3-1) on process plate (3), equal fixedly connected with mounting panel II (3-2) on the adjacent three wall of process plate (3), fixedly connected with mounting panel III (3-4) on another wall, three mounting panel II (3-2) and mounting panel III (3-4) sliding connection are respectively in four mounting groove II (2-2), mounting panel III (3-4) are located the process plate (3) outside.

5. The activated carbon production and processing equipment of claim 4, wherein: the middle parts of four sides of the upper end of the sub-processing box (2) are provided with threaded holes I (2-3), the upper end of the mounting plate II (3-2) is provided with threaded holes II (3-3) corresponding to the threaded holes I (2-3), and the corresponding threaded holes I (2-3) and the corresponding threaded holes II (3-3) are internally provided with the same bolt in a penetrating mode.

6. The activated carbon production and processing equipment of claim 4, wherein: the sizes of the processing holes (3-1) on the four processing plates (3) are different.

7. The activated carbon production and processing equipment of claim 1, wherein: the lower parts of the left end and the right end of the support frame (4) are respectively provided with a hole (4-1), the driving mechanism (5) comprises a telescopic rod (5-1), a connecting plate (5-2) and a pressure rod (5-3), the upper end of the telescopic rod (5-1) is fixedly connected with the middle part of the support frame (4), the lower end of the telescopic rod (5-1) is fixedly connected with the connecting plate (5-2), the four corners of the lower surface of the connecting plate (5-2) are respectively fixedly connected with the pressure rod (5-3), the middle part of the upper end of the pressure plate (6) is provided with a connecting sleeve (6-1), the lower end of the pressure rod (5-3) is fixedly connected in the corresponding connecting sleeve (6-1), the inner ends of the two push plate groups (7) are respectively connected, the inner ends of the two connecting rods (8) are respectively and rotatably connected to the left end and the right end of the connecting plate (5-2).

8. The activated carbon production and processing equipment of claim 7, wherein: the push plate group (7) comprises a T-shaped connecting plate (7-1), L-shaped connecting rods (7-2) and push plates (7-3), the inner ends of the T-shaped connecting plate (7-1) are rotatably connected to the outer ends of corresponding connecting rods (8), two ends of a transverse plate of the T-shaped connecting plate (7-1) are fixedly connected with the two L-shaped connecting rods (7-2) respectively, the inner ends of the two T-shaped push plates (7-3) are fixedly connected with the push plates (7-3), and the push plates (7-3) are slidably connected into the lower ends of corresponding activated carbon storage boxes (9).

9. The activated carbon production and processing equipment of claim 8, wherein: the active carbon storage box (9) comprises a side wall (9-1), a landslide (9-2), a storage box (9-3) and a sliding hole (9-4), two side walls (9-1) are arranged, a landslide (9-2) is fixedly connected between the two side walls (9-1), the storage box (9-3) is fixedly connected with the outer ends of the two side walls (9-1), the lower end of the storage tank (9-3) and the outer end of the landslide (9-2) form a sliding hole (9-4), the push plate (7-3) is connected in the corresponding slide-in hole (9-4) in a sliding mode, the lower surface of the push plate (7-3) is connected on the surface of the landslide (9-2) in a sliding mode, and the storage box (9-3) is internally provided with an activated carbon plate.

10. The activated carbon production and processing equipment of claim 1, wherein: the lower end of the output channel (10) is provided with a material conveying pipe (10-1), and the joint of the material conveying pipe (10-1) and the output channel (10) is provided with an inclined sliding surface (10-2).

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