Ink fragrance agent mixing and stirring device

By designing a V-shaped guide channel and staggered stirring rod assembly, combined with a distribution plate and stirring components, the problem of uneven mixing of the ink fragrance inoculant was solved, achieving efficient inoculant production.

CN224474953UActive Publication Date: 2026-07-10中霖丰源(周口)生物科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
中霖丰源(周口)生物科技有限公司
Filing Date
2025-06-20
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

The existing ink-fragrant microbial inoculant is not mixed evenly during production, resulting in low mixing efficiency and affecting production efficiency.

Method used

The premixing process employs a V-shaped guide channel and staggered angle stirring rod assembly, combined with a distribution plate and stirring components. The drive assembly rotates the shaft to achieve premixing and further mixing of the raw materials for the ink fragrance microbial agent.

Benefits of technology

It improves the premixing and mixing efficiency of raw materials for ink-scented microbial agents, increases the production efficiency of the agents, and avoids the sedimentation of raw materials.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224474953U_ABST
    Figure CN224474953U_ABST
Patent Text Reader

Abstract

This utility model discloses a mixing and stirring device for ink fragrance microbial agents, including a reaction vessel, a vessel lid, a stirring assembly, a driving assembly, and a feeding assembly. In this mixing and stirring device, different ink fragrance microbial agent raw materials flow inward from both outer ends of a V-shaped guide channel, premixing them in the feeding pipe. Simultaneously, the driving assembly is activated, driving the stirring rod assembly to rotate. The rotation of multiple stirring rods at staggered angles premixes the different ink fragrance microbial agent raw materials, improving the premixing efficiency. The premixed ink fragrance microbial agent raw materials fall onto a distribution plate and flow downward through the distribution holes on the plate. The distribution plate and distribution holes ensure that the premixed ink fragrance microbial agent raw materials are distributed at various locations, further improving the mixing effect and efficiency, thereby increasing the production efficiency of the ink fragrance microbial agent.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of microbial agent production technology, specifically to a mixing and stirring device for ink-scented microbial agent. Background Technology

[0002] Ink-scented microbial inoculant refers to a live microbial preparation made by industrially propagating target microorganisms and then using porous materials as adsorbents to adsorb the fermentation broth of the microorganisms. This inoculant is used for seed dressing or root dipping, and has direct or indirect effects such as improving soil, restoring soil fertility, preventing soil-borne diseases, maintaining the balance of the rhizosphere microbial community, and degrading toxic substances. In the production process of the microbial inoculant, after inoculating the microbial culture medium with seedlings, the mixture is stirred and kept at a suitable temperature and with adequate oxygen to allow the microorganisms to continuously multiply.

[0003] However, existing ink fragrance microbial agents are mostly mixed manually or solely by mixing components during production, resulting in uneven mixing of different ink fragrance microbial agent raw materials and low mixing efficiency, which reduces the production efficiency of microbial agents. To address this, we propose an ink fragrance agent mixing and stirring device. Utility Model Content

[0004] The technical problem this invention aims to solve is to overcome existing defects and provide a mixing and stirring device for ink-scented microbial agents. In use, different ink-scented microbial agent raw materials are fed from the first and second feed cylinders to the V-shaped guide grooves of the V-shaped plate inside the reactor. The different raw materials flow inward from the outer ends of the V-shaped guide grooves and are pre-mixed in the feed pipe. Simultaneously, the drive assembly is activated, driving the second rotating shaft to rotate. The rotation of the second rotating shaft drives the stirring rod assembly to rotate. The use of multiple stirring rods at staggered angles pre-mixes the different ink-scented microbial agent raw materials, thereby improving the mixing of different... The premixing efficiency of the ink fragrance microbial agent raw materials is improved by having the premixed raw materials fall onto the distribution plate and flow down through the distribution holes on the distribution plate. Under the action of the distribution plate and the distribution holes, the premixed ink fragrance microbial agent raw materials are placed at various positions to further improve the mixing effect and mixing efficiency of the ink fragrance microbial agent raw materials, thereby improving the production efficiency of the ink fragrance microbial agent. When the second rotating shaft rotates, it drives the first rotating shaft to rotate, and the first rotating shaft rotates, it drives the stirring component to rotate, thereby completing the mixing and stirring of the ink fragrance microbial agent, which can effectively solve the problems in the background technology.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a mixing and stirring device for ink-scented fungicide, comprising a reaction vessel, a vessel cover, a stirring assembly, a driving assembly, and a feeding assembly;

[0006] The reactor has a first feed cylinder and a second feed cylinder installed on both sides of its upper surface, symmetrically arranged. A V-shaped plate is installed above the interior of the reactor, with a lower center and higher ends. A V-shaped guide groove is formed within the V-shaped plate, and a discharge pipe is connected to the lower center of the guide groove. A reactor lid is connected to the upper surface of the reactor. A second rotating shaft is rotatably mounted in the center of the lid, and a first rotating shaft is fixedly mounted at the lower end of the second rotating shaft. The lower part of the second rotating shaft is located inside the discharge pipe. A flow divider is rotatably mounted on the upper part of the first rotating shaft. The flow divider is shaped like a suction cup, with a higher center and lower edges. The outer end is fixedly connected to the inner wall of the reactor. Multiple flow distribution holes are evenly opened on the flow distribution plate. Multiple stirring rod groups are evenly installed on the second rotating shaft along the axial direction. The stirring rod group includes multiple stirring rods rotatably installed on the outer surface of the second rotating shaft. The multiple stirring rod groups are arranged at a fixed angle in a staggered manner along the circumferential direction. The first feed cylinder and the second feed cylinder are respectively located directly above the corresponding ends of the two ends of the V-shaped guide groove. A stirring assembly is provided at the lower part of the first rotating shaft. A driving assembly is installed on the upper surface of the reactor. The driving assembly is connected to the upper end of the second rotating shaft. A feeding assembly is installed on the lower surface of the reactor. Four support legs are evenly installed on the lower surface of the reactor.

[0007] Furthermore, the stirring assembly includes multiple inclined blade stirring paddles evenly installed axially in the middle of the first rotating shaft. Each inclined blade stirring paddle assembly includes multiple inclined blade stirring paddles evenly installed on the outer surface of the first rotating shaft. An anchor-type stirring paddle is installed at the lower part of the first rotating shaft. The inclined blade stirring paddles are used to mix and stir different ink-scented microbial inoculant raw materials, while the anchor-type stirring paddle effectively prevents the inoculant raw materials from settling.

[0008] Furthermore, the feeding assembly includes a discharge pipe installed on the lower surface of the reactor, and a control valve is installed on the discharge pipe. The discharge of the mixed microbial agent raw material is controlled by the control valve and the discharge pipe.

[0009] Furthermore, the drive assembly includes a motor bracket mounted on the upper surface of the vessel lid, on which a motor is mounted. The output shaft of the motor is connected to the upper end of a second rotating shaft via a coupling, and the input end of the motor is electrically connected to the output end of an external controller. The external controller controls the motor's operation, which in turn drives the second rotating shaft to rotate, thus electrically completing the rotation of the second rotating shaft.

[0010] Compared with the prior art, the beneficial effects of this utility model are as follows: In use, this ink-fragrant microbial agent mixing and stirring device feeds different ink-fragrant microbial agent raw materials from the first and second feed cylinders to the V-shaped guide grooves of the V-shaped plate inside the reactor. The different ink-fragrant microbial agent raw materials flow inward from both outer ends of the V-shaped guide grooves, premixing in the feed pipe. Simultaneously, the drive assembly is activated, driving the second rotating shaft to rotate. The rotation of the second rotating shaft drives the stirring rod assembly to rotate. The rotation of multiple stirring rod assemblies at staggered angles premixes the different ink-fragrant microbial agent raw materials. To improve the premixing efficiency of different ink fragrance microbial agent raw materials, the premixed ink fragrance microbial agent raw materials fall onto the distribution plate and flow down through the distribution holes on the distribution plate. Under the action of the distribution plate and the distribution holes, the premixed ink fragrance microbial agent raw materials fall into various positions, so as to further improve the mixing effect and mixing efficiency of the ink fragrance microbial agent raw materials, thereby improving the production efficiency of ink fragrance microbial agent. When the second rotating shaft rotates, it drives the first rotating shaft to rotate, and the first rotating shaft rotates to drive the stirring component to rotate, thereby completing the mixing and stirring work of ink fragrance microbial agent. Attached Figure Description

[0011] Figure 1 This is a schematic diagram of the structure of this utility model;

[0012] Figure 2 This is a cross-sectional structural diagram of the present invention.

[0013] In the diagram: 1 Reactor, 2 First feed cylinder, 3 Motor, 4 Motor bracket, 5 Second feed cylinder, 6 Support leg, 7 V-shaped plate, 8 Stirring rod, 9 Diverter plate, 10 Inclined blade stirrer, 11 First rotating shaft, 12 Second rotating shaft, 13 V-shaped guide groove, 14 Discharge pipe, 15 Diverter hole, 16 Anchor stirrer, 17 Control valve, 18 Discharge pipe. Detailed Implementation

[0014] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0015] Please see Figure 1-2 This embodiment provides a technical solution: a mixing and stirring device for ink-scented fungicide, including a reaction vessel 1, a vessel cover, a stirring assembly, a driving assembly, and a feeding assembly;

[0016] A first feed cylinder 2 and a second feed cylinder 5 are installed on both sides of the upper surface of the reactor 1. The first feed cylinder 2 and the second feed cylinder 5 are symmetrically arranged. A V-shaped plate 7 is installed on the upper part of the interior of the reactor 1. The V-shaped plate 7 is low in the middle and high at both ends. A V-shaped guide groove 13 is opened in the V-shaped plate 7. A feed pipe 14 is connected to the lower side of the middle of the V-shaped guide groove 13. A reactor cover is connected to the upper surface of the reactor 1. A second rotating shaft 12 is rotatably installed in the middle of the reactor cover. A first rotating shaft 11 is fixedly installed at the lower end of the second rotating shaft 12. The lower part of the second rotating shaft 12 is located inside the feed pipe 14. A flow divider 9 is rotatably installed on the upper part of the first rotating shaft 11. The flow divider 9 is shaped like a suction cup. The flow divider 9 is high in the middle and low at the edges. The outer end is fixedly connected to the inner wall of the reactor 1. Multiple diversion holes 15 are evenly opened on the diversion plate 9. Multiple stirring rod groups are evenly installed on the second rotating shaft 12 along the axial direction. The stirring rod group includes multiple stirring rods 8 rotatably installed on the outer surface of the second rotating shaft 12. The multiple stirring rod groups are arranged at a fixed angle in a staggered manner along the circumferential direction. The first feed cylinder 2 and the second feed cylinder 5 are respectively located directly above the corresponding ends of the two ends of the V-shaped guide groove 13. The lower part of the first rotating shaft 11 is provided with a stirring assembly. The upper surface of the reactor 1 is equipped with a drive assembly. The drive assembly is connected to the upper end of the second rotating shaft 12. The lower surface of the reactor 1 is connected to a feeding assembly. Four support legs 6 are evenly installed on the lower surface of the reactor 1.

[0017] In use, different ink-fragrant microbial inoculant raw materials are fed from the first feed cylinder 2 and the second feed cylinder 5 to the V-shaped guide groove 13 of the V-shaped plate 7 inside the reactor 1. The different ink-fragrant microbial inoculant raw materials flow inward from both outer ends of the V-shaped guide groove 13 and are premixed in the feed pipe 14. Simultaneously, the drive assembly is activated, driving the second rotating shaft 12 to rotate. The rotation of the second rotating shaft 12 drives the stirring rod assembly to rotate. The rotation of multiple stirring rod assemblies at staggered angles premixes the different ink-fragrant microbial inoculant raw materials, thereby improving the mixing of the different ink-fragrant microbial inoculant raw materials. The premixing efficiency is achieved by the premixed ink fragrance microbial agent raw material falling onto the distribution plate 9 and flowing down through the distribution holes 15 on the distribution plate 9. Under the action of the distribution plate 9 and the distribution holes 15, the premixed ink fragrance microbial agent raw material falls into various positions, thereby further improving the mixing effect and mixing efficiency of the ink fragrance microbial agent raw material, and thus improving the production efficiency of the ink fragrance microbial agent. When the second rotating shaft 12 rotates, it drives the first rotating shaft 11 to rotate, and the first rotating shaft 11 rotates, which drives the stirring component to rotate, thereby completing the mixing and stirring work of the ink fragrance microbial agent.

[0018] The mixing assembly includes multiple inclined blade agitators evenly installed axially in the middle of the first rotating shaft 11. Each inclined blade agitator includes multiple inclined blade agitators 10 evenly installed on the outer surface of the first rotating shaft 11. An anchor-type agitator 16 is installed at the lower part of the first rotating shaft 11. The inclined blade agitators 10 are used to mix and stir different ink-fragrant microbial inoculant raw materials, while the anchor-type agitator 16 effectively prevents the inoculant raw materials from settling.

[0019] The feeding assembly includes a discharge pipe 18 installed on the lower surface of the reactor 1, and a control valve 17 is installed on the discharge pipe 18. The discharge of the mixed microbial agent raw material is controlled by the control valve 17 and the discharge pipe 18.

[0020] The drive assembly includes a motor bracket 4 mounted on the upper surface of the vessel lid, on which a motor 3 is mounted. The output shaft of the motor 3 is connected to the upper end of the second rotating shaft 12 via a coupling, and the input end of the motor 3 is electrically connected to the output end of an external controller. The external controller controls the operation of the motor 3, which drives the second rotating shaft 12 to rotate, thereby completing the rotation of the second rotating shaft 12 electrically.

[0021] The working principle of the ink fragrance microbial agent mixing and stirring device provided by this utility model is as follows: During use, different ink fragrance microbial agent raw materials are fed from the first feed cylinder 2 and the second feed cylinder 5 to the V-shaped guide groove 13 of the V-shaped plate 7 inside the reaction vessel 1. The different ink fragrance microbial agent raw materials flow inward from both outer ends of the V-shaped guide groove 13, pre-mixing within the feed pipe 14. Simultaneously, the drive assembly is activated, driving the second rotating shaft 12 to rotate. The rotation of the second rotating shaft 12 drives the stirring rod assembly to rotate. The rotation of multiple stirring rod assemblies at staggered angles pre-mixes the different ink fragrance microbial agent raw materials, thereby improving... To improve the premixing efficiency of different ink-fragrant microbial agent raw materials, the premixed raw materials fall onto the distribution plate 9 and flow down through the distribution holes 15 on the distribution plate 9. Under the action of the distribution plate 9 and the distribution holes 15, the premixed raw materials are distributed at various locations, further enhancing the mixing effect and efficiency of the ink-fragrant microbial agent raw materials, thereby increasing the production efficiency of the ink-fragrant microbial agent. When the second rotating shaft 12 rotates, it drives the first rotating shaft 11 to rotate, which in turn drives the stirring assembly to rotate, thus completing the mixing and stirring of the ink-fragrant microbial agent. An inclined blade stirring paddle 10 is used for mixing and stirring different ink-fragrant microbial agent raw materials, and an anchor-type stirring paddle 16 effectively prevents the raw materials from settling. The discharge of the mixed raw materials is controlled by the control valve 17 and the discharge pipe 18. An external controller controls the operation of the motor 3, which drives the second rotating shaft 12 to rotate, thus electrically completing the rotation of the second rotating shaft 12.

[0022] It is worth noting that in this embodiment, the core chip of the external controller is an STC microcontroller, specifically the STC15W204S. Motor 3 can be freely configured according to the actual application scenario; it can be a JE series single-phase servo motor manufactured by Beijing Mitsubishi Electric (China) Co., Ltd. The external controller controls the operation of motor 3 using methods commonly used in existing technologies.

[0023] The above are merely embodiments of this utility model and do not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the description and drawings of this utility model, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.

Claims

1. A mixing and stirring device for ink-scented fungicide, characterized in that: Includes a reaction vessel (1), a vessel cover, a stirring assembly, a driving assembly, and a feeding assembly; The reactor (1) has a first feed cylinder (2) and a second feed cylinder (5) installed on both sides of its upper surface. The first feed cylinder (2) and the second feed cylinder (5) are symmetrically arranged. A V-shaped plate (7) is installed on the upper part of the reactor (1). The V-shaped plate (7) is low in the middle and high at both ends. A V-shaped guide groove (13) is opened in the V-shaped plate (7). A feed pipe (14) is connected to the lower part of the middle of the V-shaped guide groove (13). The reactor (1) is connected to a reactor cover. A second rotating shaft (12) is rotatably installed in the middle of the reactor cover. A first rotating shaft (11) is fixedly installed at the lower end of the second rotating shaft (12). The lower part of the second rotating shaft (12) is located in the feed pipe (14). A diverter plate (9) is rotatably installed on the upper part of the first rotating shaft (11). The diverter plate (9) is in the shape of a suction cup. The diverter plate (9) is high in the middle and high at both ends. The outer end of the diversion plate (9) is fixedly connected to the inner wall of the reactor (1). The diversion plate (9) is evenly provided with multiple diversion holes (15). Multiple stirring rod groups are evenly installed on the second rotating shaft (12) along the axial direction. The stirring rod group includes multiple stirring rods (8) that are rotatably installed on the outer surface of the second rotating shaft (12). The multiple stirring rod groups are arranged at fixed angles in a staggered manner along the circumferential direction. The first feed cylinder (2) and the second feed cylinder (5) are respectively located directly above one end of the V-shaped guide groove (13). The lower part of the first rotating shaft (11) is provided with a stirring assembly. The upper surface of the reactor (1) is provided with a driving assembly. The driving assembly is connected to the upper end of the second rotating shaft (12). The lower surface of the reactor (1) is connected to a feeding assembly. The lower surface of the reactor (1) is evenly provided with four support legs (6).

2. The ink-scented fungicide mixing and stirring device according to claim 1, characterized in that: The stirring assembly includes a plurality of oblique blade stirring paddles uniformly installed along the axial direction in the middle of the first rotating shaft (11). The oblique blade stirring paddles include a plurality of oblique blade stirring paddles (10) uniformly installed on the outer surface of the first rotating shaft (11). An anchor stirring paddle (16) is installed at the lower part of the first rotating shaft (11).

3. The ink-scented fungicide mixing and stirring device according to claim 1, characterized in that: The feeding assembly includes a discharge pipe (18) installed on the lower surface of the reactor (1), and a control valve (17) is installed on the discharge pipe (18).

4. The ink-scented fungicide mixing and stirring device according to claim 1, characterized in that: The drive assembly includes a motor bracket (4) mounted on the upper surface of the vessel lid, on which a motor (3) is mounted. The output shaft of the motor (3) is connected to the upper end of a second rotating shaft (12) via a coupling. The input end of the motor (3) is electrically connected to the output end of an external controller.