CN111546679B

CN111546679B - Enzyme ball manufacturing device for agricultural production

Info

Publication number: CN111546679B
Application number: CN202010281096.9A
Authority: CN
Inventors: 熊雪凤
Original assignee: Hunan Yaofang Biotechnology Co ltd
Current assignee: Hunan Yaofang Biotechnology Co ltd
Priority date: 2020-04-10
Filing date: 2020-04-10
Publication date: 2023-01-03
Anticipated expiration: 2040-04-10
Also published as: CN111546679A

Abstract

The invention discloses a ferment ball manufacturing device for agricultural production, relates to the technical field of agricultural production, and solves the problems that the size and the weight of each ferment ball produced by the conventional ferment ball are different, the manual ferment ball pinching operation is troublesome, the labor capacity of workers is large, and the efficiency of the manual ferment ball pinching operation of the workers is low; the upper part of the left side of the bracket main body is fixedly connected with a group of stirrers; the front end surface of the driving motor is hinged with a group of connecting rods; the inner side of the rear part of the bracket main body is axially connected with a group of middle driving shafts and a group of material distributing transmission shafts; the upper left side of the rear part of the bracket main body is axially connected with a group of material distribution driving shafts. The device convenient operation that uses simply can realize the quick suppression of ferment ball, divides the material effectual simultaneously, and the big or small quality that can guarantee the ferment ball of production is even, has reduced manual operation, has alleviateed workman's intensity of labour, improves work efficiency.

Description

Enzyme ball manufacturing device for agricultural production

Technical Field

The invention relates to the technical field of agricultural production, in particular to a ferment ball manufacturing device for agricultural production.

Background

The enzyme balls can increase soil microorganisms for paddy or farmland crops, improve soil, purify sewage and eliminate garbage and the like, are generally prepared by mixing and kneading brown sugar, fertile soil, wheat bran, environment-friendly enzyme, pyroligneous and other various materials into balls, when the enzyme balls are prepared, workers need to put quantitative brown sugar, fertile soil, wheat bran, environment-friendly enzyme, pyroligneous and other various materials on the ground firstly, when the workers put quantitative brown sugar, fertile soil, wheat bran, environment-friendly enzyme, pyroligneous and other various materials on the ground, the workers need to use tools to mix the various materials on the ground, after the workers use the tools to mix the various materials on the ground completely, the workers need to grasp the quantitative mixture with both hands, and then the workers need to knead the mixed materials in the hands into balls with both hands.

Based on the above, in the existing enzyme ball production, the mixed material amount grabbed by both hands of a worker each time is different, so that the size and the weight of each enzyme ball are different, the manual enzyme ball pinching operation is troublesome, the labor capacity of the worker is large, and the efficiency of manually pinching the enzyme balls by the worker is low; therefore, the existing requirements are not met, and the enzyme ball making device for agricultural production is provided for the same.

Disclosure of Invention

The invention aims to provide a ferment ball manufacturing device for agricultural production, which solves the problems that in the prior ferment ball production, the mixed material amount grabbed by both hands of a worker each time is different, the size and the weight of each ferment ball are different, the manual ferment ball pinching operation is troublesome, the labor amount of the worker is large, and the efficiency of manually pinching the ferment balls by the worker is low.

In order to achieve the purpose, the invention provides the following technical scheme: a ferment ball making device for agricultural production comprises a bracket main body; the upper part of the left side of the bracket main body is fixedly connected with a group of stirrers; a group of conveying mechanisms are arranged at the lower part of the bracket main body; the upper part of the left side of the bracket main body is axially connected with a group of distributing discs; the front end face above the bracket main body is connected with a group of extrusion blocks in a sliding manner; a group of driving motors is fixedly connected above the rear end face of the bracket main body; the front end face of the driving motor is hinged with a group of connecting rods; the lower part of the connecting rod is hinged with the top of the extrusion block; the inner side of the rear part of the bracket main body is axially connected with a group of middle driving shafts and a group of material distributing transmission shafts; the upper left side of the rear part of the bracket main body is axially connected with a group of material distribution driving shafts.

Preferably, the extrusion block is further provided with extrusion guide sliding chutes, a group of extrusion guide sliding chutes are arranged on the left side and the right side of the extrusion block, and the extrusion block is in sliding connection with the support main body through the extrusion guide sliding chutes.

Preferably, the driving motor further comprises a flywheel, a group of flywheels is coaxially and fixedly connected to the front end face of the driving motor, the connecting rod is eccentrically hinged to the front end face of the flywheel, and a crank-slider mechanism is formed among the connecting rod, the flywheel, the extrusion block and the support body.

Preferably, the driving motor further comprises a driving pulley, a group of driving pulleys are coaxially and fixedly connected to a rotating shaft of the driving motor, the intermediate driving shaft further comprises a driving driven pulley, a group of synchronous transmission belts are wound on the outer sides of the driving pulley and the driving driven pulley together, and a synchronous transmission belt transmission mechanism is formed between the driving pulley and the driving driven pulley together.

Preferably, the intermediate driving shaft further comprises a driving gear, a group of driving gears is coaxially and fixedly connected to the front end face of the intermediate driving shaft, the driving gear is an incomplete gear, the conveying mechanism further comprises a conveying driven gear, the conveying mechanism is a conveying belt structure, a group of conveying driven gears is coaxially and fixedly connected to the rear end face of the driving shaft of the conveying mechanism, and the conveying driven gear and the driving gear are meshed to form an incomplete gear transmission mechanism.

Preferably, the distributing transmission shaft further comprises a distributing driven gear, the front end face of the distributing transmission shaft is coaxially and fixedly connected with a group of distributing driven gears, and the distributing driven gears and the driving gear are meshed to form an incomplete gear transmission mechanism together.

Preferably, the material distributing transmission shaft further comprises a material distributing driving pulley, the rear end face of the material distributing transmission shaft is coaxially and fixedly connected with a group of material distributing driving pulleys, the material distributing driving shaft further comprises a material distributing driven pulley, the rear end face of the material distributing driving shaft is coaxially and fixedly connected with a group of material distributing driven pulleys, and a group of synchronous transmission belts are wound on the outer sides of the material distributing driven pulleys and the material distributing driving pulleys together to form a synchronous transmission belt transmission mechanism.

Preferably, the material distributing driving shaft further comprises a material distributing driving bevel gear, the front end face of the material distributing driving shaft is coaxially and fixedly connected with a group of material distributing driving bevel gears, the material distributing disc further comprises a material distributing driven bevel gear, a group of material distributing driven bevel gears are arranged on the outer side of the lower portion of the material distributing disc, and the material distributing driving bevel gear and the material distributing driven bevel gears are meshed to form a bevel gear transmission mechanism together.

Preferably, the material distribution disc further comprises material distribution holes, four groups of the material distribution holes are uniformly distributed in the circumferential array on the material distribution disc, the support main body further comprises a material disc mounting seat, a feed inlet and a discharge port, the upper end face of the support main body is provided with an upper material disc mounting seat and a lower material disc mounting seat, the upper material disc mounting seat is provided with a group of the feed inlet, the top of the feed inlet is connected with the stirring machine, and the lower material disc mounting seat is provided with a group of the discharge port.

Preferably, the conveying mechanism further comprises an extrusion die, a plurality of groups of extrusion dies are uniformly arranged on the outer side of the conveying mechanism, and the extrusion dies and the extrusion blocks are of spherical structures.

Compared with the prior art, the invention has the beneficial effects that:

the device has realized the intermittent type nature rotation of conveying mechanism and the intermittent type nature rotation of branch charging tray through incomplete gear drive mechanism, the completion is fed and is divided the material action automatically, realized the extrusion to the ferment through slider-crank mechanism simultaneously, it is globular with fertilizer extrusion, the device only can realize dividing the material to fertilizer through driving motor's rotation, the extrusion, action such as feed, easy operation is simple to use, can realize the quick suppression of ferment ball, divide simultaneously that the material is effectual, the size quality that can guarantee the ferment ball of production is even, manual operation has been reduced, the labor intensity of workers has been alleviateed, and the work efficiency is improved.

Drawings

FIG. 1 is a schematic side view of the present invention;

FIG. 2 is a schematic side view of the extrusion block mounting shaft of the present invention;

FIG. 3 is a schematic side view of the transmission mechanism of the present invention;

FIG. 4 is a rear axial side view of the transmission mechanism of the present invention;

FIG. 5 is a schematic side view of the transmission shaft of the conveying mechanism of the present invention;

FIG. 6 is a schematic side view of the distribution plate transmission shaft of the present invention;

FIG. 7 is a schematic axial side view of the stent body of the present invention;

FIG. 8 is a schematic view of the structure of the distribution plate on the shaft side;

FIG. 9 is a schematic isometric cross-sectional view of an extrusion block of the present invention;

FIG. 10 is a schematic isometric sectional view of the dispensing pan of the present invention;

in the figure: 1. a stent body; 101. a tray mounting base; 102. a feed inlet; 103. a discharge port; 2. a blender; 3. a conveying mechanism; 301. a conveying driven gear; 302. extruding the die; 4. distributing disks; 401. a material distributing hole; 402. distributing a material by using a driven bevel gear; 5. extruding the block; 501. extruding the guide chute; 6. a drive motor; 601. driving a driving pulley; 602. a flywheel; 7. a connecting rod; 8. an intermediate drive shaft; 801. driving the driven pulley; 802. a driving gear; 9. a material distribution transmission shaft; 901. a material-distributing driven gear; 902. a material distribution driving belt wheel; 10. a material-distributing drive shaft; 1001. a material-distributing driven belt wheel; 1002. divide material initiative bevel gear.

Detailed Description

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.

Referring to fig. 1 to 10, an embodiment of the present invention includes: a ferment ball making device for agricultural production comprises a support main body 1, wherein a stirrer 2 is installed at the upper part of the left side of the support main body 1, a conveying mechanism 3 is arranged at the lower part of the support main body 1, the upper part of the left side of the support main body 1 is connected with a material distribution disc 4 through an axial property, an extrusion block 5 is arranged at the front side of the top of the support main body 1 in a sliding mode, the extrusion block 5 further comprises an extrusion guide sliding groove 501, extrusion guide sliding grooves 501 are formed in the left side and the right side of the extrusion block 5, the extrusion block 5 is arranged on the support main body 1 in a sliding mode through the extrusion guide sliding grooves 501, and the extrusion block 5 is guided through the extrusion guide sliding grooves 501 in use; the upper part of the rear side of the bracket main body 1 is provided with a driving motor 6 through a bolt, the driving motor 6 also comprises a driving belt pulley 601 and a flywheel 602, the driving belt pulley 601 is arranged on the output shaft of the driving motor 6 through a flat key, the flywheel 602 is connected on the output shaft of the driving motor 6 through a flat key, the eccentric position of the front side of the flywheel 602 is hinged with a connecting rod 7, the bottom end of the connecting rod 7 is hinged with the top of the extrusion block 5, the connecting rod 7, the flywheel 602, the extrusion block 5 and the bracket main body 1 jointly form a crank slide block mechanism, and the flywheel 602 rotates in use and realizes the up-and-down sliding of the extrusion block 5 through the crank slide block mechanism; the inner rear part of the bracket main body 1 is connected with an intermediate driving shaft 8 and a material distribution transmission shaft 9 through a shaft, the intermediate driving shaft 8 further comprises a driving driven pulley 801 and a driving gear 802, a synchronous transmission belt is wound between the driving pulley 601 and the driving driven pulley 801, a synchronous transmission belt transmission mechanism is formed between the driving pulley 601 and the driving driven pulley 801, the driving motor 6 drives the intermediate driving shaft 8 to rotate through the synchronous transmission belt transmission mechanism in use, the front end of the intermediate driving shaft 8 is connected with the driving gear 802 through a flat key, and the driving gear 802 is an incomplete gear; the conveying mechanism 3 further comprises a conveying driven gear 301 and an extrusion die 302, the conveying mechanism 3 is of a conveying belt structure, the rear end of a driving shaft of the conveying mechanism 3 is connected with the conveying driven gear 301 through a flat key, the conveying driven gear 301 is meshed with a driving gear 802 to form an incomplete gear transmission mechanism together, in use, an intermediate driving shaft 8 drives the conveying mechanism 3 to intermittently rotate through the incomplete gear transmission mechanism, the outer side of the conveying mechanism 3 is evenly connected with a plurality of extrusion dies 302 at intervals, the extrusion dies 302 and the extrusion block 5 are both of a spherical structure, and in use, enzyme particles are extruded into a spherical shape through the extrusion dies 302 and the extrusion block 5; the material distributing transmission shaft 9 also comprises a material distributing driven gear 901 and a material distributing driving pulley 902, the front end of the material distributing transmission shaft 9 is connected with the material distributing driven gear 901 through a flat key, the material distributing driven gear 901 and the driving gear 802 are meshed to form an incomplete gear transmission mechanism together, in use, the intermediate driving shaft 8 drives the material distributing transmission shaft 9 to intermittently rotate through the incomplete gear transmission mechanism, and the material distributing driving pulley 902 is installed at the rear end of the material distributing transmission shaft 9 through a flat key; a material distributing driving shaft 10 is axially connected to the upper left of the rear part of the bracket main body 1; the material-distributing driving shaft 10 further comprises a material-distributing driven pulley 1001 and a material-distributing driving bevel gear 1002, the rear end of the material-distributing driving shaft 10 is connected with the material-distributing driven pulley 1001 through a flat key, a synchronous transmission belt is wound between the material-distributing driven pulley 1001 and the material-distributing driving pulley 902 to jointly form a synchronous transmission belt transmission mechanism, in use, the material-distributing driving shaft 9 drives the material-distributing driving shaft 10 to intermittently rotate through the synchronous transmission belt transmission mechanism, and the front end of the material-distributing driving shaft 10 is connected with the material-distributing driving bevel gear 1002 through the flat key; the distributing disc 4 further comprises a distributing driven bevel gear 402, the top of the distributing disc 4 is provided with four distributing holes 401 at intervals uniformly around the circumferential direction, the bottom of the distributing disc 4 is provided with the distributing driven bevel gear 402, the distributing driving bevel gear 1002 and the distributing driven bevel gear 402 are meshed to form a bevel gear transmission mechanism together, in use, the distributing driving shaft 10 drives the distributing disc 4 to rotate through the bevel gear transmission mechanism, and the distributing disc 4 is ensured to rotate by ninety degrees each time; the support main body 1 is still including the charging tray mount pad 101, the upper left portion of support main body 1 front side is connected with two charging tray mount pads 101, two charging tray mount pads 101 are the top and bottom and set up, feed inlet 102 has been seted up on the charging tray mount pad 101 of top, feed inlet 102 is connected with mixer 2, the discharge gate 103 has been seted up on the charging tray mount pad 101 of below, in use the material in mixer 2 gets into branch material hole 401 through feed inlet 102 in, carry the discharge gate 103 discharge through the rotation of dividing charging tray 4 with the material.

The working principle is as follows: when the fertilizer distributor is used, the stirring machine 2 feeds stirred and mixed enzyme fertilizer into a material distribution hole 401 of a material distribution disc 4 through a feed inlet 102, a driving motor 6 drives a middle driving shaft 8 to rotate through a synchronous transmission belt transmission mechanism, the middle driving shaft 8 drives a conveying mechanism 3 and a material distribution transmission shaft 9 to rotate intermittently in a staggered mode through an incomplete gear, when teeth of a driving gear 802 are meshed with a conveying driven gear 301, the middle driving shaft 8 drives the conveying mechanism 3 to rotate, feeding of the material is achieved, when the teeth of the driving gear 802 are separated from the conveying driven gear 301, the conveying mechanism 3 stops, meanwhile, the teeth of the driving gear 802 are meshed with a material distribution driven gear 901, the material distribution transmission shaft 9 is driven to rotate, the material distribution transmission shaft 9 drives a material distribution driving shaft 10 to rotate through the synchronous transmission belt transmission mechanism, the material distribution driving shaft 10 drives the material distribution disc 4 to rotate for ninety degrees through a bevel gear transmission mechanism, the fertilizer in the material distribution hole 401 enters an extrusion die 302 below through a discharge outlet 103, meanwhile, the driving motor 6 drives an extrusion block 5 to slide up and down through a crank slider mechanism, the extrusion block 5 and the extrusion die 302 extrude the fertilizer into spherical fertilizer, and the extrusion die 302 roll out of the extrusion die 302 and collect the enzyme fertilizer when the extrusion die 302 rotates to the right side.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a ferment ball making devices for agricultural production which characterized in that: comprises a bracket main body (1); the upper part of the left side of the bracket main body (1) is fixedly connected with a group of stirrers (2); a group of conveying mechanisms (3) are arranged at the lower part of the bracket main body (1); the upper part of the left side of the bracket main body (1) is axially connected with a group of distributing discs (4); the front end face of the upper part of the bracket main body (1) is connected with a group of extrusion blocks (5) in a sliding way; a group of driving motors (6) is fixedly connected above the rear end face of the bracket main body (1); the front end face of the driving motor (6) is hinged with a group of connecting rods (7); the lower part of the connecting rod (7) is hinged with the top of the extrusion block (5); the inner side of the rear part of the bracket main body (1) is axially connected with a group of middle driving shafts (8) and a group of material distributing transmission shafts (9); a group of material distributing driving shafts (10) are axially connected to the upper left of the rear part of the bracket main body (1); the extrusion block (5) further comprises extrusion guide sliding chutes (501), a group of extrusion guide sliding chutes (501) are arranged on the left side and the right side of the extrusion block (5), and the extrusion block (5) is connected with the support main body (1) in a sliding mode through the extrusion guide sliding chutes (501); the driving motor (6) further comprises a flywheel (602), the front end face of the driving motor (6) is coaxially and fixedly connected with a group of flywheels (602), the connecting rod (7) is eccentrically hinged with the front end face of the flywheel (602), and a crank-slider mechanism is formed among the connecting rod (7), the flywheel (602), the extrusion block (5) and the bracket main body (1); the material distribution driving shaft (10) further comprises a material distribution driving bevel gear (1002), the front end face of the material distribution driving shaft (10) is coaxially and fixedly connected with a group of material distribution driving bevel gears (1002), the material distribution disc (4) further comprises a material distribution driven bevel gear (402), a group of material distribution driven bevel gears (402) are arranged on the outer side of the lower portion of the material distribution disc (4), and the material distribution driving bevel gear (1002) and the material distribution driven bevel gears (402) are meshed to form a bevel gear transmission mechanism; the material distribution disc (4) further comprises material distribution holes (401), four groups of the material distribution holes (401) are uniformly distributed on the material distribution disc (4) in a circumferential array mode, the support main body (1) further comprises a material disc mounting seat (101), a feeding hole (102) and a discharging hole (103), an upper group and a lower group of the material disc mounting seats (101) are arranged on the front end face of the support main body (1), a group of the feeding hole (102) is formed in the material disc mounting seat (101) in the upper portion, the top of the feeding hole (102) is connected with the stirring machine (2), and a group of the discharging hole (103) is formed in the material disc mounting seat (101) in the lower portion; the driving motor (6) further comprises a driving pulley (601), a group of driving pulleys (601) is coaxially and fixedly connected to a rotating shaft of the driving motor (6), the intermediate driving shaft (8) further comprises a driving driven pulley (801), a group of synchronous transmission belts are wound on the outer sides of the driving pulleys (601) and the driving driven pulley (801) together, and a synchronous transmission belt transmission mechanism is formed between the driving pulleys (601) and the driving driven pulley (801) together; the middle driving shaft (8) further comprises a driving gear (802), the front end face of the middle driving shaft (8) is coaxially and fixedly connected with a group of driving gears (802), the driving gears (802) are incomplete gears, the conveying mechanism (3) further comprises a conveying driven gear (301), the conveying mechanism (3) is a conveying belt structure, the rear end face of the driving shaft of the conveying mechanism (3) is coaxially and fixedly connected with a group of conveying driven gears (301), and the conveying driven gears (301) and the driving gears (802) are meshed to form an incomplete gear transmission mechanism; the material distributing transmission shaft (9) further comprises a material distributing driven gear (901), the front end face of the material distributing transmission shaft (9) is coaxially and fixedly connected with a group of material distributing driven gears (901), and the material distributing driven gears (901) and the driving gear (802) are meshed to form an incomplete gear transmission mechanism together; the material distributing transmission shaft (9) further comprises a material distributing driving pulley (902), the rear end face of the material distributing transmission shaft (9) is coaxially and fixedly connected with a group of the material distributing driving pulleys (902), the material distributing driving shaft (10) further comprises a material distributing driven pulley (1001), the rear end face of the material distributing driving shaft (10) is coaxially and fixedly connected with a group of the material distributing driven pulley (1001), and a group of synchronous transmission belts are wound on the outer sides of the material distributing driven pulley (1001) and the material distributing driving pulley (902) to jointly form a synchronous transmission belt transmission mechanism.

2. The apparatus for making ferment balls for agricultural production according to claim 1, wherein: conveying mechanism (3) are still including extrusion die (302), the outside of conveying mechanism (3) is evenly arranged and is provided with the multiunit extrusion die (302), extrusion die (302) with the inside of extrusion piece (5) is spherical structure.