A new vibrating screen for nematodes and fungi killing machine

By introducing a dispersing and concentrating mechanism into the vibrating screen of the insect and mold extermination machine, the problem of blind spots in extermination caused by material accumulation is solved, achieving uniform extermination on the material surface, improving the inactivation efficiency of insect eggs and mold spores, and ensuring the safety and quality of materials.

CN224405700UActive Publication Date: 2026-06-26YIXING XINTUO INTELLIGENT EQUIP MFG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
YIXING XINTUO INTELLIGENT EQUIP MFG CO LTD
Filing Date
2025-07-09
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

During the screening process, the vibrating screen of existing insect and mold extermination machines may cause local accumulation due to differences in material particle size, humidity, or shape characteristics, forming blind spots for extermination. This makes it impossible to effectively inactivate internal insect eggs and mold spores, leading to the re-reproduction of organisms during subsequent storage or processing.

Method used

A novel vibrating screen is designed, employing a dispersing mechanism and a concentrating mechanism. Through the combined motion of the dispersing plate and the cleaning brush, the material is dispersed and the edge material is swept towards the center, ensuring that the disinfection agent can fully cover the material surface and avoid accumulation.

Benefits of technology

It improves disinfection efficiency, ensures uniform disinfection of material surfaces, avoids blind spots in disinfection, reduces the residue of insect eggs and mold spores, and ensures the safety and quality of stored materials.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a novel vibrating screen for insect and mould killing machine belongs to vibrating screen technical field, and its technical scheme main points are: including support frame vibration plate, wherein, be provided with dispersion mechanism on the vibration plate, be used for dispersing the material on the vibration plate, the dispersion mechanism is provided with the centralized mechanism symmetrically, is used for the material of vibrator edge to the sweep of vibrator center area, effect is thereby solved the killing factor in background art and cannot penetrate thick material layer or accumulation area, lead to internal insect egg, mould spore or deep -layer pollution has not been inactivated, and the problem that the residual organism can reproduce in subsequent storage or processing possibly.
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Description

Technical Field

[0001] This utility model belongs to the field of vibrating screen technology, and in particular, it is a new type of vibrating screen for insect and mold extermination machines. Background Technology

[0002] A vibrating screen is a device that uses mechanical vibration to screen, classify, or remove impurities from materials. It utilizes the excitation force generated by vibration to cause materials to jump, roll, or slide on the screen surface, thereby achieving the separation of particles of different sizes. Its core function is to discharge particles that meet the specifications through the screen holes according to the size difference of the material particles, while particles that do not pass through are discharged from the other end of the screen surface, thus achieving the purpose of screening or grading.

[0003] The new type of vibrating screen for insect and mold control is a screening device designed to efficiently remove insects, mold clumps and impurities from materials. By optimizing vibration parameters, screen surface structure or material properties, it can achieve rapid grading and synergistic treatment of perishable materials such as grains, feed, and Chinese medicinal materials. Its core objective is to reduce the residue of harmful organisms such as insect eggs and mold spores during the screening process, ensuring the safety and quality of material storage.

[0004] Because of differences in particle size, humidity, or shape characteristics (such as particle adhesion or fiber entanglement), materials on the screen surface may form local accumulations or uneven layers of material, which may prevent disinfection agents such as ultraviolet light and ozone from penetrating, creating "disinfection blind spots". In this case, disinfection agents may not be able to penetrate the thick material layer or accumulation area, resulting in the failure to inactivate insect eggs, mold spores, or deep contamination inside. The remaining organisms may reproduce again during subsequent storage or processing.

[0005] The purpose of this invention is to provide a novel vibrating screen for insect and mold extermination machines, in order to solve the problems mentioned in the background art. Utility Model Content

[0006] The purpose of this invention is to provide a novel vibrating screen for insect and mold extermination machines, in order to solve the problems mentioned in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution: a novel vibrating screen for an insect and mold extermination machine, comprising a support frame and a vibrating plate;

[0008] The vibrating plate is equipped with a dispersing mechanism for dispersing the material on the vibrating plate.

[0009] The dispersing mechanism is symmetrically equipped with a concentrating mechanism, which is used to sweep the material at the edge of the vibrator toward the central area of ​​the vibrator.

[0010] Preferably, the support frame has multiple telescopic rods symmetrically connected inside, and the telescopic end of each telescopic rod is connected to a vibrating plate. The vibrating plate is connected to each telescopic end by a spring. The lower end of the vibrating plate is symmetrically connected to a vibrator, which facilitates shaking the material on the vibrating plate and moving it forward.

[0011] Preferably, one end of the vibrating plate is connected to an inclined discharge plate, and multiple disinfection lamps are equidistantly connected at the upper end of the support frame to facilitate disinfection of the material on the vibrating plate.

[0012] Preferably, the dispersing mechanism includes a slide rail, a slider, a motor, a screw, a dispersing plate, a gear A, and a rack A. The vibrating plate is symmetrically provided with slide rails, and sliders are slidably connected in both slide rails. A dispersing plate is rotatably connected between the two sliders. One end of the dispersing plate is connected to gear A. The vibrating plate is connected to rack A, and gear A and rack A mesh with each other. One end of the vibrating plate is connected to the motor. The end of the screw away from the motor extends into the slide rail near the motor and passes through the slider in the slide rail, which facilitates the dispersion of material on the vibrating plate.

[0013] Preferably, the concentrating mechanism includes a connecting plate, a rotating shaft, gear B, a cleaning brush, and a rack B. Both sliders are connected to the connecting plate, both connecting plates are rotatably connected to the rotating shaft, and both rotating shafts are connected to gear B. Racks B are symmetrically connected to both sides of the vibrating plate. The two gears B mesh with their corresponding racks B. The lower ends of both rotating shafts are connected to the cleaning brushes, and the cleaning ends of both cleaning brushes are in contact with the vibrating plate, facilitating the sweeping of material from the edge of the vibrating plate towards the center area of ​​the vibrator.

[0014] Compared with the prior art, the present invention has the following beneficial effects:

[0015] This invention utilizes a dispersion mechanism mounted on a vibrating plate. A starting motor causes a connected screw to rotate within a slide rail. As the screw rotates, a connected slider moves laterally within the slide rail. This movement of the slider causes a connected dispersion plate to move synchronously. Simultaneously, the movement of the dispersion plate causes another connected slider to move within a different slide rail. Furthermore, the movement of the dispersion plate causes a connected gear A to move synchronously. Gear A rolls on rack A and rotates. This rotation of gear A causes the connected dispersion plate to rotate. The simultaneously moving and rotating dispersion plate disperses the material on the vibrating plate, thus solving the problem in the prior art where the disinfection agent cannot penetrate thick material layers or accumulated areas, resulting in the inactivation of internal insect eggs, mold spores, or deep contamination, and the potential for residual organisms to re-infect during subsequent storage or processing.

[0016] This invention utilizes a centralized mechanism mounted on two sliders. When the two sliders move, the connected connecting plate moves, which in turn moves the connected rotating shaft. This movement of the shaft causes the connected gear B to move, which in turn rolls and rotates on its corresponding rack B. This rotation of the gear B causes the connected rotating shaft to rotate, which in turn causes the connected cleaning brushes to rotate. The two cleaning brushes, moving and rotating simultaneously, sweep material from the edge of the vibrating plate to its center. This combined motion effectively sweeps the dispersed material from the edge of the vibrating plate towards the center, preventing material accumulation in dead corners and creating a uniformly concentrated disinfection target area, thereby improving disinfection efficiency. Attached Figure Description

[0017] To more clearly illustrate the specific embodiments of this utility model or the technical solutions in the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a cross-sectional structural diagram of the support frame in this utility model;

[0020] Figure 3 This is a schematic diagram of the structure of the vibrating plate in this utility model;

[0021] Figure 4 This utility model Figure 3 A structural schematic diagram of the enlarged view at point A in the middle;

[0022] Figure 5 This is a schematic diagram of the slider in this utility model.

[0023] Explanation of reference numerals in the attached figures:

[0024] In the picture:

[0025] 1. Support frame; 2. Vibrating plate; 3. Telescopic rod; 4. Spring; 5. Vibrator; 6. Discharge plate; 7. Dispersion mechanism; 701. Slide rail; 702. Slider; 703. Motor; 704. Screw; 705. Dispersion plate; 706. Gear A; 707. Rack A; 8. Concentrating mechanism; 801. Connecting plate; 802. Rotating shaft; 803. Gear B; 804. Cleaning brush; 805. Rack B; 9. Disinfection lamp. Detailed Implementation

[0026] In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. However, it will be apparent to those skilled in the art that the present invention can be practiced without one or more of these details. In other instances, certain technical features well-known in the art have not been described in order to avoid confusion with the present invention.

[0027] Unless otherwise defined, the directions mentioned herein, such as up, down, left, right, front, back, inside, and outside, are based on the directions shown in the figures of this utility model, and are explained here together.

[0028] The connection method can be any existing method, such as bonding, welding, or bolting, depending on the actual needs.

[0029] Please see Figures 1 to 5 As shown, this utility model provides a novel vibrating screen for a pest and mold control machine, including a support frame 1 and a vibrating plate 2. Multiple telescopic rods 3 are symmetrically connected within the support frame 1 to facilitate the vibration of the vibrating plate 2. The telescopic end of each telescopic rod 3 is connected to the vibrating plate 2, which is used to place and vibrate the material. The vibrating plate 2 is connected to each telescopic end by a spring 4, which is used to vibrate the vibrating plate 2. A vibrator 5 is symmetrically connected to the lower end of the vibrating plate 2 to vibrate the vibrating plate 2 and move the material towards the conveying plate. One end of the vibrating plate 2 is connected to an inclined discharge plate 6, which is used to convey the disinfected material to the next step. Multiple disinfection lamps 9 are equidistantly connected to the upper end of the support frame 1 to disinfect the material on the vibrating plate 2.

[0030] The vibrating plate 2 is equipped with a dispersing mechanism 7, which disperses the material on the vibrating plate 2. This mechanism activates the motor 703, causing the connected screw 704 to rotate within the slide rail 701. When the screw 704 rotates, the connected slider 702 moves laterally within the slide rail 701. As the slider 702 moves, the connected dispersing plate 705 moves synchronously. When the dispersing plate 705 moves, it causes another connected slider 702 to move within another slide rail 701. Simultaneously, when the dispersing plate 705... When moving, the connected gear A706 will move synchronously. At this time, the gear A706 will roll on the rack A707 and rotate. When the gear A706 rotates, the connected dispersing plate 705 will rotate. The dispersing plate 705, which moves and rotates at the same time, will disperse the material on the vibrating plate 2. The shearing force generated by the rotation of the dispersing plate 705 can effectively break up the material clumps, ensuring that individual particles or microorganisms are fully exposed to the disinfection environment, thereby improving the disinfection efficiency of the material.

[0031] The dispersing mechanism 7 includes a slide rail 701, a slider 702, a motor 703, a screw 704, a dispersing plate 705, a gear A706, and a rack A707. The vibrating plate 2 has symmetrically arranged slide rails 701 for facilitating stable sliding of the slider 702. Slider 702s are slidably connected within each of the two slide rails 701 for facilitating transmission of the dispersing plate 705. The dispersing plate 705 is rotatably connected between the two sliders 702, allowing the material on the vibrating plate 2 to be dispersed by the simultaneous movement and rotation of the dispersing plate 705. One end of the dispersing plate 705 is connected to the gear A706 for... The dispersing plate 705 is now rotated. The vibrating plate 2 is connected to a rack A707, which is used to make the gear A706 roll on the rack A707, thereby making the gear A706 rotate. The gear A706 and the rack A707 mesh with each other. One end of the vibrating plate 2 is connected to a motor 703, which is used to control the rotation of the screw 704. The output end of the motor 703 is connected to the screw 704, which is used to control the lateral reciprocating movement of the slider 702. The end of the screw 704 away from the motor 703 extends into the slide rail 701 near the motor and passes through the slider 702 in the slide rail.

[0032] The dispersing mechanism 7 is symmetrically equipped with a concentrating mechanism 8, which is used to sweep the material at the edge of the vibrator 5 towards the center area of ​​the vibrator 5. When the two sliders 702 move, the connected connecting plate 801 moves. When the two connecting plates 801 move, the connected rotating shaft 802 moves. When the two rotating shafts 802 move, the connected gears B803 move. At this time, the two gears B803 will roll and rotate on the corresponding racks B805. When the two gears B803 rotate, the connected rotating shaft 802 will rotate. When the two rotating shafts 802 rotate, the connected cleaning brushes 804 will rotate. At this time, the two cleaning brushes 804, which move and rotate at the same time, will sweep the material at the edge of the vibrating plate 2 towards the center of the vibrating plate 2. This can effectively make the cleaning brushes 804 continuously sweep the dispersed material at the edge of the vibrating plate 2 towards the center through compound motion, avoiding the accumulation of material in the dead corner of the equipment, forming a uniform and concentrated disinfection target area, thereby improving the disinfection efficiency.

[0033] The concentrating mechanism 8 includes a connecting plate 801, a rotating shaft 802, a gear B803, a cleaning brush 804, and a rack B805. Both sliders 702 are connected to the connecting plate 801, and both connecting plates 801 are rotatably connected to the rotating shaft 802, which is used to realize the rotation of the cleaning brush 804. Both rotating shafts 802 are connected to the gear B803, which is used to control the rotation of the rotating shaft 802. The two sides of the vibrating plate 2 are symmetrically connected to the racks B805, which are used to realize the rotation of the gears B803 by rolling on the racks B805. The two gears B803 mesh with the corresponding racks B805. The lower ends of both rotating shafts 802 are connected to the cleaning brushes 804, which are used to sweep the material on the edge of the vibrating plate 2 to the center area of ​​the vibrator 5 by rotating the cleaning brushes 804. The cleaning ends of both cleaning brushes 804 are in contact with the vibrating plate 2.

[0034] Working principle: When it is necessary to disperse the material on the vibrating plate 2, the motor 703 is started first to make the connected screw 704 rotate in the slide rail 701. When the screw 704 rotates, the connected slider 702 will move laterally in the slide rail 701. When the slider 702 moves, the connected dispersing plate 705 will move synchronously. When the dispersing plate 705 moves, the other connected slider 702 will move in another slide rail 701. At the same time, when the dispersing plate 705 moves, the connected gear A706 will move synchronously. At this time, the gear A706 will roll on the rack A707 and rotate. When the gear A706 rotates, the connected dispersing plate 705 will rotate. At this time, the dispersing plate 705, which moves and rotates at the same time, will disperse the material on the vibrating plate 2.

[0035] When the two sliders 702 move, the connected connecting plate 801 moves. When the two connecting plates 801 move, the connected rotating shaft 802 moves. When the two rotating shafts 802 move, the connected gears B803 move. At this time, the two gears B803 will roll and rotate on the corresponding racks B805. When the two gears B803 rotate, the connected rotating shaft 802 will rotate. When the two rotating shafts 802 rotate, the connected cleaning brushes 804 will rotate. At this time, the two cleaning brushes 804, which move and rotate at the same time, will sweep the material on the edge of the vibrating plate 2 to the center of the vibrating plate 2.

[0036] It should be noted that, in this document, relational terms such as "one" and "two" are used merely to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, the phrase "comprising an element defined as..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.

[0037] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is limited by the appended claims and their equivalents.

Claims

1. A new vibrating screen for a worm grubs killing machine characterized in that: Includes support frame (1) and vibrating plate (2); The vibrating plate (2) is provided with a dispersing mechanism (7) for dispersing the material on the vibrating plate (2); The dispersing mechanism (7) is symmetrically provided with a concentrating mechanism (8) for sweeping the material at the edge of the vibrator (5) toward the central area of ​​the vibrator (5).

2. A novel vibrating screen for a metamitron killing machine as claimed in claim 1, wherein: The support frame (1) has multiple telescopic rods (3) symmetrically connected inside. The telescopic end of each telescopic rod (3) is connected to a vibrating plate (2). The vibrating plate (2) is connected to each telescopic end by a spring (4). The lower end of the vibrating plate (2) is symmetrically connected to a vibrator (5).

3. A novel vibrating screen for a metamitron killing machine as claimed in claim 2, wherein: One end of the vibrating plate (2) is connected to an inclined discharge plate (6), and multiple disinfection lamps (9) are connected at equal intervals on the upper end of the support frame (1).

4. A novel vibrating screen for a metamitron killing machine as claimed in claim 3, wherein: The dispersing mechanism (7) includes a slide rail (701), a slider (702), a motor (703), a screw (704), a dispersing plate (705), a gear A (706), and a rack A (707). The vibrating plate (2) is symmetrically provided with slide rails (701). Sliders (702) are slidably connected in both slide rails (701). A dispersing plate (705) is rotatably connected between the two sliders (702). A gear A (706) is connected to one end of the dispersing plate (705). A rack A (707) is connected to the vibrating plate (2). The gear A (706) and the rack A (707) mesh with each other. A motor (703) is connected to one end of the vibrating plate (2). A screw (704) is connected to the output end of the motor (703). The end of the screw (704) away from the motor (703) extends into the slide rail (701) near the motor and passes through the slider (702) in the slide rail.

5. A novel vibrating screen for an insect and mold control machine according to claim 4, characterized in that: The central mechanism (8) includes a connecting plate (801), a rotating shaft (802), a gear B (803), a cleaning brush (804), and a rack B (805). Both sliders (702) are connected to the connecting plate (801), and both connecting plates (801) are rotatably connected to the rotating shaft (802). Both rotating shafts (802) are connected to the gear B (803). The two sides of the vibrating plate (2) are symmetrically connected to the racks B (805). The two gears B (803) mesh with the corresponding racks B (805). The lower ends of both rotating shafts (802) are connected to the cleaning brushes (804), and the cleaning ends of both cleaning brushes (804) are in contact with the vibrating plate (2).