CN213050502U

CN213050502U - Biological granulator

Info

Publication number: CN213050502U
Application number: CN202021859176.XU
Authority: CN
Inventors: 侯维; 谭斌峰; 谭超武
Original assignee: Qingdao Ruizhisheng Biotechnology Co ltd
Current assignee: Qingdao Ruizhisheng Biotechnology Co ltd
Priority date: 2020-08-31
Filing date: 2020-08-31
Publication date: 2021-04-27
Anticipated expiration: 2030-08-31

Abstract

The utility model discloses a biological granulator relates to biotechnology technical field, including support, mount table, driving motor, drive reduction gear, drive shaft, cooling water circulating device, cooling water output tube, cooling water recovery pipe, air conditioning air compression device, air conditioning input tube, output rotary joint, hollow shaft, input rotary joint, staving, cold wind ring, squeeze roll, coolant liquid passageway, pelletization dish, ventilation pipe, louvre interface, installation cavity, spring, louvre, seal dish, louvre post. The utility model relates to a design through water-cooled squeeze roll and air-cooled pelletization dish makes the granulator at the in-process of working, and when the extrusion roll extrudeed the radiating hole post, the inside air conditioning of louvre just blows off in the twinkling of an eye because the pelletization dish is high-speed rotatory in the course of the work, and the squeeze roll can frequent extrusion radiating hole post make the pelletization dish reach the radiating effect of forced air cooling, and the inside water-cooling heat dissipation that passes through of squeeze roll simultaneously, the effectual problem of solving granulator mesh jam.

Description

Biological granulator

Technical Field

The utility model belongs to the technical field of biotechnology technology and specifically relates to a biological granulator.

Background

The granulator is at the in-process of work, and the material is extruded from the mesh of pelletization net circle, forms the strip granule and falls into and collect after the hopper, and this equipment drives the material roll owing to the rotation of extrusion pelletization dish at the pelletization in-process, and the material just takes place the friction with pelletization roller, extrusion pelletization dish and produces a large amount of heats, makes the material become to glue to block up the pelletization mesh.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, the utility model provides a biological granulator.

The utility model provides a technical scheme that its technical problem adopted is: a biological granulator comprises a support, a mounting platform, a driving motor, a driving reducer, a driving shaft, a cooling water circulating device, a cooling water output pipe, a cooling water recovery pipe, a cold air compression device, a cold air input pipe, an output rotary joint, a pipe shaft, an input rotary joint, a barrel body, a cold air ring, an extrusion roller, a cooling liquid channel, a granulating disc, a ventilating pipe, a heat dissipation hole interface, a mounting cavity, a spring, a heat dissipation hole, a sealing disc, a heat dissipation hole column, meshes and a discharge hole, wherein the support is respectively and rigidly mounted at four corner positions of the lower end surface of the mounting platform in 4 groups, the driving motor is rigidly mounted on the motor support, the driving reducer is fixed on a driving motor shell through the reducer support, the power input end of the driving reducer is rigidly connected to the power output shaft of the driving, the head end of the cooling water output pipe is arranged on the cooling water circulating device, the tail end of the cooling water output pipe is arranged at the right side end of the tubular shaft in a matching way through an input rotary joint, the head end of the cooling water recovery pipe is arranged on the cooling water circulating device, the tail end of the cooling water recovery pipe is arranged at the left side end of the tubular shaft in a matching way through an output rotary joint, the head end of the cooling air input pipe is rigidly arranged on the cooling air compressing device, the tail end of the cooling air input pipe is rigidly arranged on a cooling air ring, the barrel body is rigidly arranged on the upper end surface of the mounting table, the cooling air ring is arranged on the outer wall of the barrel body, the extrusion rollers are divided into 2 groups which are bilaterally symmetrical and rigidly and integrally arranged on the tubular shaft, the cooling liquid channels are uniformly distributed at the hollow part in the extrusion rollers in groups of 360-degree annular arrays in, the louvre interface divides 6 horizontal equipartitions of group to set up in singly organizing ventilation pipe lateral wall position, the installation cavity sets up in louvre interface upper end, spring rigidity is installed in the installation cavity bottom surface, the louvre sets up in the installation cavity upper end, seal the dish rigid mounting in the spring upper end, louvre post rigidity integral type is installed in sealing the dish up end, the mesh divides the multiunit equipartition to set up in pelletization dish, the discharge gate sets up in staving lower part lateral wall.

The discharge port is arranged at a position corresponding to the blanking disc which is arranged on the inner wall of the barrel body and is rigidly mounted on the driving shaft through the matching of the bearing.

The beneficial effects of the utility model are that, the utility model provides a design that the scheme passes through water-cooled squeeze roll and air-cooled pelletization dish makes the granulator at the in-process of working, when the cooling hole post was extruded to the squeeze roll, the inside air conditioning of louvre just blows off in the twinkling of an eye because the pelletization dish is high-speed rotatory in the course of the work, and the squeeze roll can frequent extrusion cooling hole post makes the pelletization dish reach the radiating effect of forced air cooling, and the inside water-cooling heat dissipation that passes through of squeeze roll simultaneously, the effectual problem of solving granulator mesh jam.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall internal mounting structure of the present invention;

FIG. 3 is a partial enlarged view of area A of the present invention;

fig. 4 is a top view of the overall structure of the granulating pan of the present invention.

In the figure, 1, a support, 2, a mounting table, 3, a driving motor, 4, a driving reducer, 5, a driving shaft, 6, a cooling water circulating device, 7, a cooling water output pipe, 8, a cooling water recovery pipe, 9, a cold air compressing device, 10, a cold air input pipe, 11, an output rotary joint, 12, a pipe shaft, 13, an input rotary joint, 14, a barrel body, 15, a cold air ring, 16, an extrusion roller, 17, a cooling liquid channel, 18, a granulating disc, 19, a ventilation pipe, 20, a heat dissipation hole interface, 21, a mounting cavity, 22, a spring, 23, a heat dissipation hole, 24, a sealing disc, 25, a heat dissipation hole column, 26, a mesh, 27 and a discharge hole are arranged.

Detailed Description

In order to more clearly illustrate the technical solution of the present invention, the following provides a further description of the present invention with reference to the accompanying drawings, and obviously, the following described drawings are only one embodiment of the present invention, and for those skilled in the art, other embodiments can be obtained according to the drawings and the embodiment without any creative work, and all belong to the protection scope of the present invention.

A biological granulator comprises a support 1, a mounting platform 2, a driving motor 3, a driving reducer 4, a driving shaft 5, a cooling water circulating device 6, a cooling water output pipe 7, a cooling water recovery pipe 8, a cooling air compressing device 9, a cooling air input pipe 10, an output rotary joint 11, a pipe shaft 12, an input rotary joint 13, a barrel body 14, a cooling air ring 15, a squeezing roller 16, a cooling liquid channel 17, a granulating disc 18, a ventilating pipe 19, a radiating hole interface 20, a mounting cavity 21, a spring 22, a radiating hole 23, a sealing disc 24, a radiating hole column 25, a mesh 26 and a discharge hole 27, wherein the support 1 is respectively and rigidly mounted at four corners of the lower end surface of the mounting platform 2 in 4 groups, the driving motor 3 is rigidly mounted on the motor support, the driving reducer 4 is fixed on the shell of the driving motor 3 through the reducer support, the power input end of the driving reducer 4 is rigidly connected, the head end of the driving shaft 5 is rigidly mounted at the power output end of the driving reducer 4, the head end of the cooling water output pipe 7 is mounted at the cooling water circulating device 6, the tail end of the cooling water output pipe 7 is mounted at the right side end of the tubular shaft 12 in a matching way through an input rotary joint 13, the head end of the cooling water recovery pipe 8 is mounted at the cooling water circulating device 6, the tail end of the cooling water recovery pipe 8 is mounted at the left side end of the tubular shaft 12 in a matching way through an output rotary joint 11, the head end of the cold air input pipe 10 is rigidly mounted at the cold air compressing device 9, the tail end of the cold air input pipe 10 is rigidly mounted at a cold air ring 15, the barrel body 14 is rigidly mounted at the upper end surface of the mounting table 2, the cold air ring 15 is arranged on the outer wall of the barrel body 14, the extrusion rollers 16 are symmetrically and, the cooling liquid passageway 17 communicates with each other with the internal channel connection of hollow shaft 12, pelletization dish 18 rigid mounting is at 5 terminal in the drive shaft, 360 annular array equipartitions of 6 groups of ventilation pipe 19 set up in pelletization dish 18 lateral walls, the horizontal equipartition of 6 groups of louvre interface 20 sets up in single group of ventilation pipe 19 lateral wall position, installation cavity 21 sets up in louvre interface 20 upper end, spring 22 rigid mounting is in installation cavity 21 bottom surface, louvre 23 sets up in installation cavity 21 upper end, seal the dish 24 rigid mounting in spring 22 upper end, the 24 rigid integrated types of louvre post 25 are installed in seal dish 24 up end, mesh 26 divides the multiunit equipartition to set up in pelletization dish 18, discharge gate 27 sets up in the 14 lower part lateral walls.

In detail, the discharge port 27 is disposed at a position corresponding to the height of the dropping tray which is arranged on the inner wall of the barrel 14 and rigidly mounted on the driving shaft 5 through a bearing fit.

The above embodiments are only exemplary embodiments of the present invention, and are not intended to limit the present invention, and the protection scope of the present invention is defined by the claims. Various modifications and equivalents of the invention can be made by those skilled in the art within the spirit and scope of the invention, and such modifications and equivalents should also be considered as falling within the scope of the invention.

Claims

1. The utility model provides a biological granulator, which comprises a bracket (1), mount table (2), driving motor (3), drive reduction gear (4), drive shaft (5), cooling water circulating device (6), cooling water output tube (7), cooling water recovery pipe (8), air conditioning air compression device (9), air conditioning input tube (10), output rotary joint (11), hollow shaft (12), input rotary joint (13), staving (14), cold wind ring (15), squeeze roll (16), coolant liquid passageway (17), pelletization dish (18), ventilation pipe (19), louvre interface (20), installation cavity (21), spring (22), louvre (23), seal dish (24), louvre post (25), mesh (26), discharge gate (27), its characterized in that: the support (1) is rigidly mounted at four corner positions of the lower end surface of the mounting table (2) in 4 groups respectively, the driving motor (3) is rigidly mounted on the motor support, the driving reducer (4) is fixed on the shell of the driving motor (3) through the reducer support, the power input end of the driving reducer (4) is rigidly connected to the power output shaft of the driving motor (3), the head end of the driving shaft (5) is rigidly mounted at the power output end of the driving reducer (4), the head end of the cooling water output pipe (7) is mounted on the cooling water circulating device (6), the tail end of the cooling water output pipe (7) is mounted at the right side end of the tubular shaft (12) through an input rotary joint (13) in a matching manner, the head end of the cooling water recovery pipe (8) is mounted on the cooling water circulating device (6), and the tail end of the cooling water recovery pipe (8) is mounted, the head end of the cold air input pipe (10) is rigidly mounted on the cold air compression device (9), the tail end of the cold air input pipe (10) is rigidly mounted on a cold air ring (15), the barrel body (14) is rigidly mounted on the upper end surface of the mounting table (2), the cold air ring (15) is arranged on the outer wall of the barrel body (14), the extrusion rollers (16) are divided into 2 groups and are rigidly mounted on the tubular shaft (12) in a bilateral symmetry mode, the cooling liquid channels (17) are divided into 6 groups and are uniformly distributed at the hollow part in the extrusion rollers (16), the cooling liquid channels (17) are communicated with the internal channel of the tubular shaft (12), the granulating disc (18) is rigidly mounted at the tail end of the driving shaft (5), the ventilating pipes (19) are divided into 6 groups and are uniformly distributed on the side wall of the granulating disc (18), and the heat dissipation hole interfaces (20) are divided into 6 groups and are uniformly distributed on, installation cavity (21) sets up in louvre interface (20) upper end, spring (22) rigid mounting is in installation cavity (21) bottom surface, louvre (23) set up in installation cavity (21) upper end, seal dish (24) rigid mounting in spring (22) upper end, the rigid integral type of louvre post (25) is installed and is sealed dish (24) up end, mesh (26) divide the multiunit equipartition to set up in pelletization dish (18), discharge gate (27) set up in staving (14) lower part lateral wall.

2. The biological granulator according to claim 1, characterized in that the discharge port (27) is provided at a position corresponding to the height of the inner wall of the barrel (14) and is provided with a blanking disc rigidly mounted on the driving shaft (5) through a bearing fit.