CN219313782U - Cryolite conveyer - Google Patents

Abstract

The utility model provides a cryolite conveying device, which belongs to the technical field of material conveying, and comprises a bottom plate and a bracket arranged on the bottom plate, wherein a feed bin is arranged on the bracket through a hinge, a rotating shaft is arranged in the feed bin, a spiral blade is arranged on the rotating shaft corresponding to the feed bin, a motor frame is arranged at the end part of the feed bin, a first motor is arranged on the motor frame, an output shaft of the first motor is connected with the end part of the rotating shaft, a feed inlet is arranged on the feed bin, a feed assembly is arranged corresponding to the feed inlet, a telescopic mechanism is arranged on the bottom plate through a hinge seat, the other end of the telescopic mechanism is connected with the feed bin through a hinge seat, and a feed guide pipe is arranged at the other end of the feed bin; according to the utility model, cryolite can be sent into the feed inlet of the flash evaporation drying system at a constant speed, and the inclination angle of the feed bin can be adjusted according to the height of the feed inlet of the flash evaporation drying system.

Description

Cryolite conveyer

Technical Field

The utility model relates to the technical field of material conveying equipment, in particular to a cryolite conveying device.

Background

After centrifugal dehydration is carried out on materials obtained by the cryolite acid method production process, the overall water content of the materials is still high, the dried powder can be obtained after flash evaporation and drying, a large amount of materials cannot be added at one time when the flash evaporation and drying system is used for drying the materials, a small amount of materials are required to be continuously conveyed, thus operators are required to be equipped to continuously control the adding amount of the materials, and a conveying device capable of conveying cryolite into the feeding port of the flash evaporation and drying system at a constant speed is needed because the feeding port of the flash evaporation and drying system is high.

Disclosure of Invention

In view of the above, the utility model provides a cryolite conveying device, which can convey cryolite into a feed inlet of a flash drying system at a constant speed, and can adjust the inclination angle of a feed bin according to the height of the feed inlet of the flash drying system.

In order to solve the technical problems, the utility model provides a cryolite conveying device, which comprises a bottom plate and a support arranged on the bottom plate, wherein a feed bin is arranged on the support through hinging, the feed bin can rotate on the support, a rotating shaft is arranged in the feed bin, the rotating shaft can rotate in the feed bin, a spiral blade is arranged on the rotating shaft corresponding to the feed bin, the rotating shaft can drive the spiral blade to rotate, a motor frame is arranged at the end part of the feed bin, a first motor is arranged on the motor frame and provides support for the first motor, an output shaft of the first motor is connected with the end part of the rotating shaft, an output shaft of the first motor can drive the rotating shaft to rotate, a feed inlet is arranged on the feed bin, a feed assembly is arranged corresponding to the feed inlet, cryolite can enter the feed bin through the feed assembly, a telescopic mechanism is arranged on the bottom plate, the other end of the telescopic mechanism is connected with the feed bin through a hinging seat, and a material guide pipe is arranged at the other end of the feed bin. Namely, the telescopic mechanism can drive the feeding bin to rotate on the bracket.

The feeding assembly comprises a positioning frame arranged on the bottom plate, a discharging hopper is arranged on the positioning frame, the positioning frame provides support for the discharging hopper, and the end part of the discharging hopper is connected with the feeding port through a discharging pipe; i.e. cryolite can enter the blanking pipe through the blanking hopper and then enter the feeding bin through the blanking pipe.

Preferably, the blanking pipe is a corrugated hose; the blanking pipe can deform when the feeding bin rotates, and the blanking pipe is arranged to be a corrugated hose, so that the blanking pipe can still be normally used after deformation.

The telescopic mechanism comprises a fixed block, a sliding groove is arranged in the fixed block, the sliding groove is vertically arranged on the fixed block, a movable block is arranged in the sliding groove in a sliding manner, the movable block can slide in the sliding groove, a threaded rod is arranged in the sliding groove, the threaded rod can rotate in the sliding groove, a threaded hole is formed in the movable block corresponding to the threaded rod, the threaded rod penetrates through the threaded hole to be connected with the movable block, the threaded rod can drive the movable block to move up and down in a cavity, the cavity is arranged on the fixed block corresponding to the sliding groove, a second motor is arranged in the cavity, and an output shaft of the second motor is connected with the end part of the threaded rod; i.e. the second motor is operated to drive the threaded rod to rotate.

Preferably, the cross section of the chute is of a polygonal structure; namely, the movable block can not rotate in the chute when lifting.

The hinge seat comprises a positioning block arranged on the base, the positioning block is of a concave structure, bearings are arranged at two ends of the positioning block, a rotating rod is arranged between the two bearings, and two ends of the telescopic mechanism are connected with the rotating rod; namely, two ends of the telescopic mechanism can be rotationally connected with the bottom plate and the feeding bin through the hinging seat.

In summary, compared with the prior art, the present application includes at least one of the following beneficial technical effects:

1. placing cryolite into the feeding subassembly, then the cryolite can be through in the feeding subassembly gets into the feed bin, then control first motor work just can make the cryolite by the propelling movement at uniform velocity to the passage department to the cryolite just can get into in the flash distillation drying system.

2. The feed inlet height of flash drying system that different producer used is all inconsistent, uses this device, and flexible through telescopic machanism can make the pay-off storehouse rotatory on the support to just can make the position of passage obtain adjusting, thereby just can make the device send into flash drying system's feed inlet with cryolite in.

Drawings

FIG. 1 is a schematic view of a cryolite conveyor according to the present utility model;

FIG. 2 is a schematic structural view of a cross-sectional view of the present utility model;

fig. 3 is a schematic structural view of the telescopic mechanism of the present utility model.

Reference numerals illustrate:

100. a bottom plate; 101. a bracket; 102. feeding a storage bin; 103. a rotating shaft; 104. a helical blade; 105. a motor frame; 106. a first motor; 107. a feed inlet; 108. a material guiding pipe;

200. a feed assembly; 201. a positioning frame; 202. discharging a hopper; 203. discharging pipes;

300. a telescoping mechanism; 301. a fixed block; 302. a chute; 303. a movable block; 304. a threaded rod; 305. a threaded hole; 306. a chamber; 307. a second motor;

400. a hinge base; 401. a positioning block; 402. and (5) rotating the rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to fig. 1 to 3 of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which are obtained by a person skilled in the art based on the described embodiments of the utility model, fall within the scope of protection of the utility model.

As shown in fig. 1-3: the embodiment provides a cryolite conveying device, which comprises a bottom plate 100 and a bracket 101 arranged on the bottom plate 100, wherein the bracket 101 is provided with a feed bin 102 through hinging, the feed bin 102 can rotate on the bracket 101, a rotating shaft 103 is arranged in the feed bin 102, the rotating shaft 103 can rotate in the feed bin 102, a spiral blade 104 is arranged on the rotating shaft 103 corresponding to the feed bin 102, the rotating shaft 103 can drive the spiral blade 104 to rotate, cryolite in the feed bin 102 can be pushed, the end part of the feed bin 102 is provided with a motor frame 105, the motor frame 105 is provided with a first motor 106, the motor frame 105 provides support for the first motor 106, an output shaft of the first motor 106 is connected with the end part of the rotating shaft 103, an output shaft of the first motor 106 can drive the rotating shaft 103 to rotate, a feed inlet 107 is arranged on the feed bin 102, a feed assembly 200 is arranged corresponding to the feed inlet 107, the cryolite can enter the feed bin 102 through the feed assembly 200, the bottom plate 100 is provided with a telescopic mechanism 300 through a hinging seat 400, the other end of the telescopic mechanism 300 is connected with the feed bin 102 through the hinging seat 400, and the other end of the feed bin 102 is provided with a guide pipe 108; cryolite can be sent into the feed inlet 107 of flash drying system at a constant speed to can adjust the inclination of feed bin 102 according to the height of the feed inlet 107 of flash drying system.

Put into feeding subassembly 200 with the cryolite, the cryolite can get into through feeding subassembly 200 and send in bin 102, then control first motor 106 work, the output shaft of first motor 106 can drive pivot 103 and rotate in feeding bin 102, pivot 103 rotates just can drive helical blade 104 and rotate, thereby helical blade 104 just can push the cryolite in feeding bin 102, thereby just can will push the cryolite to the passage 108 in, thereby the cryolite just can get into flash drying system's feed inlet 107 through passage 108 in.

The feed assembly 200 is shown in figure 2,

the feeding assembly 200 comprises a positioning frame 201 arranged on the bottom plate 100, a discharging hopper 202 is arranged on the positioning frame 201, and the end part of the discharging hopper 202 is connected with the feeding port 107 through a discharging pipe 203. The material is led into the blanking hopper 202, cryolite can enter the blanking pipe 203, then cryolite can enter the feeding bin 102 through the blanking pipe 203, the blanking pipe 203 is a corrugated hose, namely, the blanking pipe 203 can deform when the feeding bin 102 rotates, and the blanking pipe 203 is arranged into the corrugated hose, so that the blanking pipe 203 can still be normally used after the blanking pipe 203 deforms.

The telescoping mechanism 300 is shown in figure 3,

the telescopic mechanism 300 comprises a fixed block 301, a sliding groove 302 is arranged in the fixed block 301, the sliding groove 302 is vertically arranged on the fixed block 301, a movable block 303 is arranged in the sliding groove 302 in a sliding mode, the movable block 303 can move up and down in the sliding groove 302, a threaded rod 304 is arranged in the sliding groove 302, a threaded hole 305 is formed in the movable block 303 corresponding to the threaded rod 304, the threaded rod 304 is vertically arranged at the bottom of the movable block 303, the threaded rod 304 is connected with the movable block 303 through the threaded hole 305, the movable block 303 can be driven to move up and down in the sliding groove 302 by rotating the threaded rod 304, a cavity 306 is formed in the fixed block 301 corresponding to the sliding groove 302, a second motor 307 is arranged in the cavity 306, and an output shaft of the second motor 307 is connected with the end portion of the threaded rod 304. Namely, the second motor 307 is controlled to work, the output shaft of the second motor 307 can drive the threaded rod 304 to rotate in the chute 302, the threaded rod 304 rotates to drive the movable block 303 to move up and down in the chute 302, the movable block 303 moves up and down to push the feed bin 102 to rotate on the bracket 101 through the hinge seat 400, so that the position of the feed guide pipe 108 can be adjusted, and the device can send cryolite into the feed inlet 107 of the flash drying system.

The cross section of the chute 302 is polygonal in structure. The cross section of the movable block 303 is also polygonal, and the threaded rod 304 does not rotate together with the movable block 303 when rotating.

The hinge base 400 is shown in figure 3,

the hinge seat 400 comprises a positioning block 401 arranged on the base, the positioning block 401 is of a concave structure, bearings are arranged at two ends of the positioning block 401, a rotating rod 402 is arranged between the two bearings, the rotating rod 402 can rotate between the two bearings, and two ends of the telescopic mechanism 300 are connected with the rotating rod 402. The rotating rod 402 can drive the end part of the telescopic mechanism 300 to rotate, so that the end part of the telescopic mechanism 300 can be rotationally connected with the positioning block 401 through the rotating rod 402, and further, the two ends of the telescopic mechanism 300 can be respectively rotationally connected with the bottom plate 100 and the feed bin 102 through the hinging seat 400.

Furthermore, it should be noted that, in the description of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those skilled in the art according to the specific circumstances.

While the foregoing is directed to the preferred embodiments of the present utility model, it will be appreciated by those skilled in the art that various modifications and adaptations can be made without departing from the principles of the present utility model, and such modifications and adaptations are intended to be comprehended within the scope of the present utility model.

Claims (6)

1. Cryolite conveyer, its characterized in that: including support (101) that set up on bottom plate (100) and bottom plate (100), set up feed bin (102) through articulated on support (101), set up pivot (103) in feed bin (102), correspond feed bin (102) on pivot (103) and set up helical blade (104), feed bin (102) tip sets up motor frame (105), set up first motor (106) on motor frame (105), the output shaft of first motor (106) is connected with pivot (103) tip, set up feed inlet (107) on feed bin (102), set up feed assembly (200) corresponding feed inlet (107), set up telescopic machanism (300) on bottom plate (100) through articulated seat (400), the telescopic machanism (300) other end is connected with feed bin (102) through articulated seat (400), the feed bin (102) other end sets up feed conduit (108).

2. A cryolite delivery apparatus as defined in claim 1, wherein: the feeding assembly (200) comprises a locating frame (201) arranged on the bottom plate (100), a discharging hopper (202) is arranged on the locating frame (201), and the end part of the discharging hopper (202) is connected with the feeding port (107) through a discharging pipe (203).

3. A cryolite delivery apparatus as defined in claim 2, wherein: the blanking pipe (203) is a corrugated hose.

4. A cryolite delivery apparatus as defined in claim 1, wherein: the telescopic mechanism (300) comprises a fixed block (301) arranged on a hinge seat (400), a sliding groove (302) is formed in the fixed block (301), a movable block (303) is arranged in the sliding groove (302) in a sliding mode, a threaded rod (304) is arranged in the sliding groove (302), a threaded hole (305) is formed in the movable block (303) corresponding to the threaded rod (304), the threaded rod (304) penetrates through the threaded hole (305) to be connected with the movable block (303), a cavity (306) is formed in the fixed block (301) corresponding to the sliding groove (302), a second motor (307) is arranged in the cavity (306), and an output shaft of the second motor (307) is connected with the end portion of the threaded rod (304).

5. A cryolite delivery apparatus as defined in claim 4, wherein: the cross section of the sliding groove (302) is of a polygonal structure.

6. A cryolite delivery apparatus as defined in claim 1, wherein: the hinge seat (400) comprises a positioning block (401) arranged on the base, the positioning block (401) is of a concave structure, bearings are arranged at two ends of the positioning block (401), a rotating rod (402) is arranged between the two bearings, and two ends of the telescopic mechanism (300) are connected with the rotating rod (402).

Images