CN220507618U - High-moisture material drying production line - Google Patents

Abstract

The utility model relates to the technical field of material drying, and discloses a high-moisture material drying production line, which comprises a drying roller, a mechanical dehydrator and a screw conveyor, wherein the screw conveyor is arranged between a feeding end of the drying roller and a discharging end of the mechanical dehydrator.

Description

High-moisture material drying production line

Technical Field

The utility model relates to the technical field of material drying, in particular to a high-moisture material drying production line.

Background

The material drying is a process of heating and drying materials to volatilize moisture in the materials, so that the materials reach the specified drying requirement, and the material drying can be realized in various modes, such as direct heating, indirect heating, radiation heating and the like.

We have therefore proposed a high moisture material drying line in order to solve the problems set out above.

Disclosure of Invention

The utility model aims to solve the problems that the existing material drying is generally adopted, the material to be dried is directly put into drying equipment for drying, but the drying mode is not ideal in drying effect when dealing with high-moisture material (the material with the water content of more than or equal to 80 percent), the material is required to be repeatedly dried, and the drying efficiency is low and the cost is high.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the high-moisture material drying production line comprises a drying roller, a mechanical dehydrator and a screw conveyer, wherein the screw conveyer is arranged between the feeding end of the drying roller and the discharging end of the mechanical dehydrator, the mechanical dehydrator comprises a cylindrical dehydration tank and a rectangular dehydration tank which are mutually communicated, a helical blade shaft is arranged in the cylindrical dehydration tank, a motor case is arranged at one end of the cylindrical dehydration tank, a driving motor connected with the helical blade shaft is fixedly arranged in the motor case, a baffle plate is fixedly arranged at the position, close to the cylindrical dehydration tank, of the rectangular dehydration tank, a partition plate is arranged in the cylindrical dehydration tank, the inner cavity of the cylindrical dehydration tank is divided into a dehydration cavity and a mechanism cavity by the partition plate, a first bevel gear is fixedly arranged on the helical blade shaft, a transmission shaft is rotatably connected to the side wall of the mechanism cavity, a second bevel gear meshed with the first bevel gear is fixedly sleeved at one end of the transmission shaft, two first central shafts are fixedly sleeved at positions, close to the bottom parts, a second transmission shaft is fixedly sleeved on the rectangular dehydration tank, a second transmission shaft is fixedly sleeved at the first central shaft, a second transmission shaft is fixedly sleeved at the position, a second transmission shaft is in the first transmission shaft is fixedly connected with a transmission belt, a second transmission shaft is fixedly sleeved at the second transmission shaft is in the first transmission shaft is fixedly connected with a transmission shaft, a transmission shaft is fixedly sleeved at the second transmission shaft is fixedly and is in a transmission shaft is sleeved at one end, a second transmission shaft is fixedly connected with a transmission shaft is fixedly at a transmission shaft is sleeved with a transmission shaft, and a transmission belt is fixedly and is sleeved at a transmission shaft is respectively, and a transmission position is fixedly and at a transmission position, and is fixedly and a transmission center, and is sleeved with a transmission station and at a transmission station and a transmission station. The novel rotary drum type dewatering box is characterized in that a transmission gear assembly is arranged in the mechanism box, a feed inlet is formed in the upper surface of the mechanism box, a discharge outlet is formed in the lower surface of the rectangular dewatering box, a first filtering hole is formed in the inner bottom wall of the cylindrical dewatering box, a second filtering hole is formed in the inner bottom wall of the rectangular dewatering box, and a third filtering hole is formed in the material conveying belt.

Further, the transmission gear assembly comprises a plurality of first gears and a plurality of second gears, the first gears are fixedly sleeved on the second central shaft, each second gear is arranged between two adjacent first gears, the first gears are meshed with the second gears, rotating columns are fixedly sleeved at the central positions of the second gears, and the rotating columns are connected with the inner wall of the mechanism box in a rotating mode.

Further, the pitch of the helical blades of the helical blade shaft is sequentially reduced from the first bevel gear to the baffle plate.

Further, the third driving wheel, the fourth driving wheel and the second driving belt are in crossed belt driving.

Further, the bottoms of the cylinder dewatering box and the rectangular dewatering box are set to be liquid collecting boxes, liquid outlet pipes are arranged at the bottoms of the liquid collecting boxes, and rotary valves are arranged on the liquid outlet pipes.

Further, an observation window is arranged on the side face of the liquid collecting box.

Further, the bottom of the liquid collecting box is arranged to be of a bucket-pouring structure.

The utility model has the beneficial effects that: through being provided with stoving cylinder, mechanical dehydrator and screw conveyer, be provided with helical blade axle in the drum dehydration box of mechanical dehydrator, preliminary extrusion with moisture when carrying out the propelling movement to the material, through being provided with swager roller and material conveyer belt in the rectangle dehydration box, carry out the secondary extrusion with moisture when carrying to the material through the cooperation of swager roller and material conveyer belt, thereby accomplish dehydration work, then the material is exported screw conveyer and is imported stoving cylinder and carry out drying treatment, the stoving mode of combining the cylinder stoving through mechanical dehydration has improved stoving effect greatly, drying efficiency has been improved and the cost is reduced.

Drawings

FIG. 1 is a schematic diagram of a high moisture material drying line according to the present utility model;

FIG. 2 is a schematic diagram of the front view structure of a mechanical dehydrator of the high-moisture material drying production line of the present utility model;

FIG. 3 is a schematic diagram of a side view of a mechanical dehydrator of a high moisture material drying line according to the present utility model;

FIG. 4 is a schematic cross-sectional view of a mechanical dehydrator of the high moisture material drying line of the present utility model;

FIG. 5 is a schematic view of a first partial cross-sectional structure of the high moisture material drying line of the present utility model;

fig. 6 is a schematic diagram of a second partial cross-sectional structure of the high moisture material drying line of the present utility model.

Name corresponding to each label in the figure:

1. a drying roller; 2. a mechanical dehydrator; 100. a screw conveyor; 3. a cylinder dewatering box; 301. a dewatering cavity; 302. a mechanism cavity; 303. a first filter aperture; 4. rectangular dewatering boxes; 41. a second filter aperture; 5. a helical blade shaft; 6. a motor case; 7. a baffle; 8. a partition plate; 9. a first bevel gear; 10. a transmission shaft; 11. a second bevel gear; 12. a first driving wheel; 13. a first central axis; 14. a driving roller; 15. a material conveyor belt; 151. a third filter aperture; 16. a second central axis; 17. a material pressing roller; 18. a second driving wheel; 19. a third driving wheel; 20. a fourth driving wheel; 21. a first drive belt; 22. a second drive belt; 23. a mechanism box; 24. a feed inlet; 25. a discharge port; 26. a first gear; 27. a second gear; 28. rotating the column; 29. a liquid collecting box; 30. a liquid outlet pipe; 31. a rotary valve; 32. and an observation window.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which are derived by a person skilled in the art based on the embodiments of the utility model, fall within the scope of protection of the utility model.

Embodiments of the utility model:

example 1

As shown in fig. 1-6, the utility model provides a high-moisture material drying production line, which comprises a drying roller 1, a mechanical dehydrator 2 and a screw conveyer 100, wherein the screw conveyer 100 is arranged between a feeding end of the drying roller 1 and a discharging end of the mechanical dehydrator 2, the mechanical dehydrator 2 comprises a cylinder dehydration tank 3 and a rectangular dehydration tank 4 which are mutually communicated, a helical blade shaft 5 is arranged in the cylinder dehydration tank 3, one end of the cylinder dehydration tank 3 is provided with a motor box 6, a driving motor connected with the helical blade shaft 5 is fixed in the motor box 6, a baffle 7 is fixed in the rectangular dehydration tank 4 near the cylinder dehydration tank 3, a division plate 8 is arranged in the cylinder dehydration tank 3, an inner cavity of the cylinder dehydration tank 3 is divided into a dehydration cavity 301 and a mechanism cavity 302 by the division plate 8, a first bevel gear 9 is fixed on the helical blade shaft 5, a transmission shaft 10 is rotationally connected on a side wall of the mechanism cavity 302, a second bevel gear 11 meshed with the first bevel gear 9 is fixed at one end of the transmission shaft 10, a first transmission wheel 12 is fixedly sleeved at the position of the transmission shaft 10 close to the other end, two first central shafts 13 are arranged at the position of the rectangular dehydration tank 4 close to the bottom, transmission rollers 14 are sleeved on the first central shafts 13, material conveying belts 15 are arranged on the two transmission rollers 14, a plurality of second central shafts 16 are arranged in the rectangular dehydration tank 4, material pressing rollers 17 contacted with the material conveying belts 15 are sleeved on the second central shafts 16, a second transmission wheel 18 and a third transmission wheel 19 are fixedly sleeved at the position of one second central shaft 16 close to one end, a fourth transmission wheel 20 is fixedly sleeved at the position of one first central shaft 13 close to one end, a first transmission belt 21 is arranged on the first transmission wheel 12 and the second transmission wheel 18, the third transmission wheel 19 and the fourth transmission wheel 20 are provided with a second transmission belt 22, the side surface of the rectangular dehydration tank 4 is provided with a mechanism box 23, the mechanism box 23 is internally provided with a transmission gear assembly, the upper surface of the mechanism box 23 is provided with a feed inlet 24, the lower surface of the rectangular dehydration tank 4 is provided with a discharge outlet 25, the inner bottom wall of the cylindrical dehydration tank 3 is provided with a first filtering hole 303, the inner bottom wall of the rectangular dehydration tank 4 is provided with a second filtering hole 41, the material conveyer 15 is provided with a third filtering hole 151, the helical blade spacing of the helical blade shaft 5 is sequentially reduced from the first bevel gear 9 to the baffle 7, high-moisture materials can be led in through the feed inlet 24 and a driving motor is started, the helical blade shaft 5 is driven to rotate, the high-moisture materials are pushed and initially removed, then the materials are sent into the rectangular dehydration tank 4 and fall on the material conveyer 15, and simultaneously the material conveyer belt 25 is pressed and discharged through the first bevel gear 11, the transmission shaft 12, the second bevel gear 18, the first transmission belt 21, the second transmission shaft 16, the second transmission shaft 18, the third transmission shaft 19, the third transmission shaft 13 and the fourth transmission shaft 13 are matched with the material conveyer 20, and the material is discharged through the second bevel gear 20, and the material conveyer is simultaneously conveyed through the second bevel gear 20, and the material conveyer roller is discharged through the second bevel gear 20, and the material conveyer roller is further rotated, and the material conveyer roller is discharged, and the material is finally, and the material is discharged.

Example two

As shown in fig. 6, on the basis of the first embodiment of the present utility model: the transmission gear assembly comprises a plurality of first gears 26 and a plurality of second gears 27, the first gears 26 are fixedly sleeved on the second central shaft 16, each second gear 27 is arranged between two adjacent first gears 26, the first gears 26 are meshed with the second gears 27, the center positions of the second gears 27 are fixedly sleeved with rotating columns 28, the rotating columns 28 are rotationally connected with the inner wall of the mechanism box 23, and through the arrangement, the material pressing rollers 17 can all rotate towards one direction.

Example III

As shown in fig. 1 to 4, on the basis of the first embodiment of the present utility model: through such arrangement, the pressing roller 17 and the material conveyer belt 15 can rotate in opposite directions, the materials can be extruded, dehydrated and conveyed better, the bottoms of the cylindrical dewatering tank 3 and the rectangular dewatering tank 4 are arranged to be liquid collecting tanks 29, the bottoms of the liquid collecting tanks 29 are provided with liquid outlet pipes 30, the liquid outlet pipes 30 are provided with rotary valves 31, the collected liquid can be collected intensively, the side surfaces of the liquid collecting tanks 29 are provided with observation windows 32, the reserves of the liquid in the liquid collecting tanks 29 can be checked through the observation windows 32, the bottoms of the liquid collecting tanks 29 are arranged to be of a pouring structure, and the liquid can be guided out conveniently through such arrangement.

Claims (7)

1. High moisture material stoving production line, its characterized in that: including stoving cylinder (1), mechanical dehydrator (2) and screw conveyer (100), screw conveyer (100) set up between the pan feeding end of stoving cylinder (1) and the discharge end of mechanical dehydrator (2), mechanical dehydrator (2) are including drum dehydration case (3) and rectangle dehydration case (4) of intercommunication each other, be provided with helical blade axle (5) in drum dehydration case (3), just drum dehydration case (3) one end is provided with motor case (6), motor case (6) internal fixation has the driving motor who is connected with helical blade axle (5), be close to drum dehydration case (3) in rectangle dehydration case (4) position is fixed with baffle (7), just be provided with division board (8) in drum dehydration case (3), drum dehydration case (3) inner chamber is divided into dehydration chamber (301) and mechanism chamber (302) through division board (8), be fixed with first bevel gear (9) on the helical blade axle (5), be connected with transmission shaft (10) on the mechanism chamber (302) lateral wall rotation, be close to drum dehydration case (4) position is fixed with baffle (8) and is connected with second bevel gear (10) and is fixed with the second bevel gear (12) of the other end that is cup joints mutually, two first central shafts (13) are arranged at positions, close to the bottom, in the rectangular dewatering box (4), driving rollers (14) are sleeved on the first central shafts (13), material conveying belts (15) are arranged on the two driving rollers (14), a plurality of second central shafts (16) are arranged in the rectangular dewatering box (4), pressing rollers (17) in contact with the material conveying belts (15) are sleeved on the second central shafts (16), a second driving wheel (18) and a third driving wheel (19) are fixedly sleeved at positions, close to one end, of the second central shafts (16), a fourth driving wheel (20) is fixedly sleeved at positions, close to one end, of the first central shafts (13), a first driving belt (21) is arranged on the first driving wheel (12) and the second driving wheel (18), a second driving belt (22) is arranged on the third driving wheel (19) and the fourth driving wheel (20), a mechanism box (23) is arranged on the side face of the rectangular dewatering box (4), a second driving wheel (18) and a filter drum (25) are arranged in the mechanism box (23), a discharging hole (303) is formed in the bottom surface of the dewatering box (4), the inner bottom wall of the rectangular dewatering box (4) is provided with a second filtering hole (41), and the material conveying belt (15) is provided with a third filtering hole (151).

2. The high moisture material drying line of claim 1, wherein: the transmission gear assembly comprises a plurality of first gears (26) and a plurality of second gears (27), the first gears (26) are fixedly sleeved on a second central shaft (16), each second gear (27) is arranged between two adjacent first gears (26), the first gears (26) are meshed with the second gears (27), rotating columns (28) are fixedly sleeved at the central positions of the second gears (27), and the rotating columns (28) are rotationally connected with the inner wall of the mechanism box (23).

3. The high moisture material drying line of claim 1, wherein: the pitch of the helical blades of the helical blade shaft (5) is sequentially reduced from the first bevel gear (9) to the baffle (7).

4. The high moisture material drying line of claim 1, wherein: the third driving wheel (19), the fourth driving wheel (20) and the second driving belt (22) are in crossed belt driving.

5. The high moisture material drying line of claim 1, wherein: the bottoms of the cylinder dewatering box (3) and the rectangular dewatering box (4) are provided with a liquid collecting box (29), a liquid outlet pipe (30) is arranged at the bottom of the liquid collecting box (29), and a rotary valve (31) is arranged on the liquid outlet pipe (30).

6. The high moisture material drying line of claim 5, wherein: an observation window (32) is arranged on the side face of the liquid collecting box (29).

7. The high moisture material drying line of claim 5, wherein: the bottom of the liquid collecting box (29) is provided with a bucket reversing structure.