CN221344442U - Microbial inoculum adding equipment for bio-organic fertilizer production - Google Patents

Abstract

The utility model relates to the technical field of fertilizer production and processing, in particular to microbial inoculum adding equipment for bio-organic fertilizer production, which comprises a conveying box and a feed hopper arranged on the conveying box, wherein the feed hopper is fixedly connected with the conveying box through a connecting cylinder, and mounting brackets are symmetrically arranged at the bottom of the conveying box.

Description

Microbial inoculum adding equipment for bio-organic fertilizer production

Technical Field

The utility model relates to the technical field of fertilizer production and processing, in particular to microbial inoculum adding equipment for bio-organic fertilizer production.

Background

In the production and processing process of the bio-organic fertilizer, continuously conveying materials by a belt conveyor, and continuously adding solid microbial inoculum into the materials by using screw conveying equipment arranged at one side of the belt conveyor; because solid thalli are easy to block a feed inlet after being tightly extruded, emptying conditions of spiral conveying equipment occur, so that the adding proportion of the microbial inoculum is out of balance, and the fermentation effect of the organic fertilizer is affected;

Reference is made to patent reference document with the application number of 'CN2023204583. X', and the name of 'a microbial inoculum adding device for production and processing of biological organic fertilizer', which comprises a frame, a screw conveyor arranged on the frame, and a hopper arranged on a feed inlet of the screw conveyor, wherein solid thalli tightly extruded at the feed inlet are vibrated and dispersed in the document in a vibration mode, but the solid thalli tightly extruded can be a ready-made blocky material, the solid thalli cannot be completely vibrated and crushed in a vibration mode, and the screw conveyor cannot uniformly send blocky solid thalli into the organic fertilizer, so that the microbial inoculum is unevenly proportioned, and the quality of the organic fertilizer is affected.

Therefore, we design a microbial inoculum adding device for bio-organic fertilizer production.

Disclosure of utility model

The utility model aims to solve the problem that in the prior art, extruded and blocked thalli cannot be completely vibrated and crushed, so that the thalli cannot be uniformly fed into an organic fertilizer by screw conveying equipment, and provides a microbial inoculum adding equipment for producing a biological organic fertilizer.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

The utility model provides a microbial inoculum interpolation equipment for bio-organic fertilizer production, includes the delivery casing and sets up the feeder hopper on the delivery casing, the feeder hopper passes through connecting cylinder and delivery casing fixed connection, the bottom symmetry of delivery casing is equipped with the installing support, be equipped with the stirring subassembly that stirs solid thallus in the feeder hopper, be equipped with a plurality of rotating plates that are used for stirring the solid thallus of jam at the connecting cylinder in the connecting cylinder.

Preferably, the spiral blade is rotationally connected to the conveying box, a second spur gear is rotationally connected to the side wall of the conveying box, and the spiral blade and the second spur gear are coaxially fixed.

Preferably, a plurality of rotating plates are rotatably connected with the connecting cylinder through rotating rods, first straight gears are coaxially fixed on the rotating rods, and the first straight gears are meshed with the second straight gears through belts.

Preferably, a motor is arranged on one side of the conveying box, the motor is fixedly connected with the conveying box through a connecting frame, and the output end of the motor is coaxially fixed with the second spur gear.

Preferably, a fixing frame is fixedly connected to the feeding hopper, and the stirring assembly is rotationally connected with the fixing frame.

Preferably, a first bevel gear is coaxially fixed on the stirring assembly, a second bevel gear is coaxially fixed on the rotating rod, and the first bevel gear is meshed with the second bevel gear.

The beneficial effects of the utility model are as follows:

1. according to the utility model, the solid thalli is stirred to rotate by the rotating stirring assembly, so that the solid thalli is prevented from being tightly extruded in the feed hopper to influence the solid thalli transportation, and the solid thalli blocked in the connecting cylinder is crushed by the rotating plate, so that the solid thalli can be conveniently and uniformly transported by the spiral blade.

2. According to the utility model, the second spur gear drives the first spur gear to synchronously rotate through the belt, so that the helical blade and the rotating plate synchronously rotate, and the second bevel gear drives the meshed first bevel gear to rotate, so that the rotating plate and the stirring assembly synchronously rotate, and the helical blade, the rotating plate and the stirring assembly can be simultaneously driven to rotate by only one driving force, so that the use cost is saved.

Drawings

FIG. 1 is a schematic structural diagram of a microbial inoculum adding device for bio-organic fertilizer production;

FIG. 2 is a sectional view of the structure of the microbial inoculum adding device for producing the bio-organic fertilizer;

FIG. 3 is a partial sectional view of a microbial inoculum adding apparatus for bio-organic fertilizer production according to the present utility model;

Fig. 4 is an enlarged view at a in fig. 3.

In the figure: 1. a delivery box; 2. a feed hopper; 3. a fixing frame; 4. a stirring assembly; 5. a belt; 6. a connecting cylinder; 7. a mounting bracket; 8. a connecting frame; 9. a motor; 10. a helical blade; 11. a rotating plate; 12. a first straight gear; 13. a second spur gear; 14. a rotating lever; 15. a first bevel gear; 16. and a second bevel gear.

Detailed Description

Referring to fig. 1-4, a microbial inoculum adding device for bio-organic fertilizer production comprises a conveying box 1 and a feed hopper 2 arranged on the conveying box 1, wherein the feed hopper 2 is fixedly connected with the conveying box 1 through a connecting cylinder 6, mounting brackets 7 are symmetrically arranged at the bottom of the conveying box 1, and the conveying box 1 is fixed on a material conveying device through the mounting brackets 7, so that thalli can be conveniently added into materials; the stirring assembly 4 for stirring the solid thalli is arranged in the feed hopper 2, the stirring assembly 4 comprises a rotating shaft and a plurality of stirring rods with different lengths, and when the stirring assembly is used, the rotating shaft is rotated to drive the stirring rods to rotate, so that the solid thalli in the feed hopper 2 is stirred to rotate, and the solid thalli is prevented from being completely and tightly extruded in the feed hopper 2 to influence the solid thalli transportation; a plurality of rotating plates 11 for crushing solid thalli blocked in the connecting cylinder 6 are arranged in the connecting cylinder 6, and the lengths of the rotating plates 11 are different, so that the rotating plates 11 can rotate in the connecting cylinder 6 with a circular cross section.

Referring to fig. 2, a spiral blade 10 is rotatably connected to the transport box 1, a second spur gear 13 is rotatably connected to a side wall of the transport box 1, the spiral blade 10 and the second spur gear 13 are coaxially fixed, and the spiral blade 10 is driven to rotate by rotating the second spur gear 13.

Referring to fig. 3, a plurality of rotating plates 11 are rotatably connected with a connecting cylinder 6 through a rotating rod 14, a first spur gear 12 is coaxially fixed on the rotating rod 14, the first spur gear 12 is meshed with a second spur gear 13 through a belt 5, the second spur gear 13 rotates during use, the second spur gear 13 rotates through the belt 5 to drive the first spur gear 12 to rotate, the rotating rod 14 and a plurality of rotating plates 11 arranged on the fixed rod 14 are driven by the rotating first spur gear 12 to rotate, and solid thalli blocked in the connecting cylinder 6 are crushed by the rotating plates 11, so that the solid thalli can be conveyed uniformly by the helical blades 10.

Referring to fig. 1, a motor 9 is disposed on one side of the conveying box 1, the motor 9 is fixedly connected with the conveying box 1 through a connecting frame 8, an output end of the motor 9 is coaxially fixed with a second spur gear 13, the motor 9 is started to drive the second spur gear 13 to rotate, it is to be noted that specific model specifications of the motor 9 need to be determined according to actual specifications of the device, and a specific model selection calculation method adopts the prior art in the field, so that detailed description is omitted.

Referring to fig. 2 and 4, the fixed frame 3 is fixedly connected to the feed hopper 2, the stirring assembly 4 is rotationally connected to the fixed frame 3, the first bevel gear 15 is coaxially fixed to the stirring assembly 4, the second bevel gear 16 is coaxially fixed to the rotating rod 14, the first bevel gear 15 is meshed with the second bevel gear 16, the rotating second bevel gear 16 can drive the first bevel gear 15 to rotate, the rotating rod 14 drives the second bevel gear 16 to rotate during use, the rotating second bevel gear 16 drives the meshed first bevel gear 15 to rotate, and then the stirring assembly 4 coaxially fixed to the first bevel gear 15 is driven to rotate, so that solid thalli are prevented from being completely and tightly extruded in the feed hopper 2 to affect solid thalli transportation.

The working principle of the utility model is as follows:

The motor 9 is started to drive the second spur gear 13 and the helical blades 10 to rotate, the second spur gear 13 which rotates drives the first spur gear 12 to rotate through the belt 5, the first rotary gear 12 drives the rotary rod 14 and the rotary plates 11 arranged on the fixed rod 14 to rotate, the rotary plates 11 stir the solid thalli blocked in the connecting barrel 6, the rotary rod 14 drives the second bevel gear 16 to rotate, the second bevel gear 16 which rotates drives the meshed first bevel gear 15 to rotate, and then the stirring assembly 4 which is coaxially fixed with the first bevel gear 15 is driven to rotate, so that solid thalli is prevented from being completely and tightly extruded in the feed hopper 2 to influence solid thalli transportation.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a microbial inoculum interpolation equipment for bio-organic fertilizer production, includes delivery casing (1) and sets up feeder hopper (2) on delivery casing (1), its characterized in that, feeder hopper (2) are through connecting cylinder (6) and delivery casing (1) fixed connection, the bottom symmetry of delivery casing (1) is equipped with installing support (7), be equipped with stirring subassembly (4) that agitate solid thallus in feeder hopper (2), be equipped with a plurality of rotating plates (11) that are used for stirring the solid thallus of jam at connecting cylinder (6) in connecting cylinder (6).

2. The microbial inoculum adding device for bio-organic fertilizer production according to claim 1, wherein the conveying box (1) is rotationally connected with a spiral blade (10), a second spur gear (13) is rotationally connected to the side wall of the conveying box (1), and the spiral blade (10) and the second spur gear (13) are coaxially fixed.

3. The microbial inoculum adding apparatus for bio-organic fertilizer production according to claim 2, wherein a plurality of the rotating plates (11) are rotatably connected with the connecting cylinder (6) through rotating rods (14), first straight gears (12) are coaxially fixed on the rotating rods (14), and the first straight gears (12) are meshed with second straight gears (13) through the belt (5).

4. The microbial inoculum adding device for bio-organic fertilizer production according to claim 3, wherein a motor (9) is arranged on one side of the conveying box (1), the motor (9) is fixedly connected with the conveying box (1) through a connecting frame (8), and the output end of the motor (9) is coaxially fixed with a second spur gear (13).

5. The microbial inoculum adding device for bio-organic fertilizer production according to claim 4, wherein the fixing frame (3) is fixedly connected to the feed hopper (2), and the stirring assembly (4) is rotationally connected with the fixing frame (3).

6. The microbial inoculum adding apparatus for bio-organic fertilizer production according to claim 5, wherein a first bevel gear (15) is coaxially fixed on the stirring assembly (4), a second bevel gear (16) is coaxially fixed on the rotating rod (14), and the first bevel gear (15) is meshed with the second bevel gear (16).