A separation device for the purification of dichlofluanid

Abstract

The utility model provides a kind of separation device for purifying of trichex, it includes device body, the device body top end is equipped with mounting bracket, the mounting bracket top surface is equipped with drive cylinder, drive cylinder output end is fixed with vibration motor and passes through mounting bracket surface, the vibration motor output end is equipped with conical filter assembly, the conical filter assembly inside includes mounting plate and fixed ring, the vibration motor output end is fixed with mounting plate.This device uses conical filter assembly to match slope filter screen, the unique structure design increases filter area, it is convenient for separating liquid to pass through filter screen quickly, significantly improves filtering efficiency.After filtering is completed, drive cylinder can drive conical filter assembly to be lifted upwards, so that fixed ring is flush with the top of device body, without completely disassembling filter screen from device.At this time, vibration motor starts, and trichex crystal adhered on filter screen is vibrated to discharge, and crystal falls into collecting frame smoothly.

Description

Technical Field

[0001] This utility model relates to the field of hymexazol purification technology, and in particular to a separation device for hymexazol purification. Background Technology

[0002] As a new generation of pesticide fungicide, hymexazol can directly kill pathogens, promote plant growth, and promote the growth and development of crop roots, thereby improving the survival rate of crops.

[0003] Hymexazol is usually separated into solid and liquid components using separation equipment to separate the precipitated hymexazol crystals from the separation liquid.

[0004] Currently, traditional separation equipment includes a filter barrel, a filter screen, and a collection pipe. The collection pipe is located on the lower end face of the filter barrel, and the filter screen is clipped into the inside of the filter barrel. When the operator performs filtration, the separation liquid is poured into the filter barrel. The hymexazol crystals in the separation liquid are separated from the separation liquid by the filter screen. The separation liquid passes through the filter screen and enters the collection pipe of the filter barrel and is discharged from the filter barrel. After the hymexazol filtration is completed, the operator removes the filter screen from the filter barrel and collects the hymexazol on the filter screen.

[0005] Regarding the aforementioned technologies, the inventors believe that the following defects exist: after separation, the filter screen needs to be removed from the filter barrel, the hymexazol crystals on the filter screen need to be scraped off, and then the filter screen needs to be put back on the filter barrel for the next filtration. Removing the hymexazol crystals requires manpower and time, and the separation equipment cannot work again during the process of removing the filter screen, resulting in low efficiency.

[0006] Therefore, it is necessary to provide a separation device for the purification of hymexazol to solve the above-mentioned technical problems. Utility Model Content

[0007] This invention provides a separation device for the purification of hymexazol, which solves the problems in the background art.

[0008] To solve the above-mentioned technical problems, this utility model provides a separation device for the purification of hymexazol, comprising a device body, a mounting frame vertically fixedly mounted on the top of the device body, a drive cylinder vertically mounted centrally on the top surface of the mounting frame, the output end of the drive cylinder penetrating the surface of the mounting frame and fixedly connected to a vibration motor below, thereby driving the vibration motor to move vertically. A conical filter assembly is mounted on the output end of the vibration motor, the conical filter assembly including a mounting plate and a fixing ring. The output end of the vibration motor is fixedly connected to the mounting plate, so that the vibration of the vibration motor can be directly transmitted to the mounting plate. An inclined filter screen is tensioned between the mounting plate and the fixing ring. The fixing ring supports and positions the filter screen, and the outer diameter of the fixing ring is equal to the inner diameter of the device body, so that the fixing ring can be precisely embedded inside the device body, ensuring a tight fit between the conical filter assembly and the device body, preventing crystals from leaking out from the gaps. At the same time, multiple sets of inclined reinforcing rods are connected between the fixing ring and the mounting plate to enhance the connection strength and stability, ensuring structural stability during vibration. During operation, the drive cylinder moves the vibration motor and the conical filter assembly up and down, enabling the filter assembly to rise and fall within the device body. The vibration motor provides vibration power to the conical filter assembly, accelerating the separation process.

[0009] Preferably, a collection frame is tightly fitted and fixed to the outer surface of the device body. An inclined discharge plate is installed at the bottom of the collection frame. The inclined discharge plate is inclined and faces the discharge pipe installed through the surface of the collection frame. A valve is installed on the discharge pipe. When the hymexazol crystals separate and fall from the filter screen, the inclined discharge plate guides the crystals towards the discharge pipe using its own inclination angle. The operator can achieve efficient collection and discharge of the crystals by controlling the valve on the discharge pipe.

[0010] Preferably, the outer diameter of the fixing ring is equal to the inner diameter of the device body, so that the fixing ring is precisely fitted to the inside of the device body, ensuring the sealing of the crystal falling path during the filtration process and improving the collection efficiency.

[0011] Preferably, multiple sets of reinforcing rods are connected between the fixing ring and the mounting plate. One end of the reinforcing rod is securely connected to the mounting plate, and the other end is connected to the fixing ring. When the vibration motor is working, the stress generated by the vibration is effectively dispersed, preventing the mounting plate and the fixing ring from loosening due to vibration, and ensuring the reliability of the overall structure of the cone filter assembly.

[0012] Preferably, a conical discharge hopper is installed through the bottom of the device body, and a valve is installed at the outlet of the conical discharge hopper. During the separation process, the separated liquid that passes through the filter screen gathers at the bottom of the device body, and is discharged from the device body through the conical discharge hopper using its guiding characteristics. The valve can control the timing and speed of liquid discharge as needed to meet the separation requirements under different working conditions.

[0013] Preferably, the device body is equipped with multiple support legs at the bottom end, which are evenly distributed on the bottom surface of the device body to provide a stable support foundation for the device, ensure that the device remains balanced during operation, effectively resist the vibration generated when the vibration motor is working, and avoid the device shaking and affecting the separation effect.

[0014] Preferably, a controller is mounted on the outer surface of the device body. The controller is electrically connected to the drive cylinder, the vibration motor, and various valves via wiring. The operator can precisely control the lifting stroke of the drive cylinder, the start and stop of the vibration motor and the vibration frequency, as well as the opening and closing status of each valve through the controller, thereby achieving intelligent and precise control of the entire separation process.

[0015] Compared with related technologies, the separation device for purifying hymexazol provided by this utility model has the following beneficial effects:

[0016] Compared to existing technologies, this device employs a conical filter assembly paired with a sloping filter screen. This unique structural design increases the filtration area, facilitating rapid flow of the separated liquid through the filter screen and significantly improving filtration efficiency. After filtration, the drive cylinder lifts the conical filter assembly upwards, aligning the fixing ring with the top of the device body, eliminating the need to completely remove the filter screen. At this point, the vibration motor activates, vibrating and discharging the hymexazol crystals adhering to the filter screen, allowing them to fall smoothly into the collection frame. After discharging, the conical filter assembly descends back into the device body under the action of the drive cylinder to continue the next round of filtration. The entire process eliminates the need for repeated disassembly and reassembly of the filter screen, greatly reducing manual operation steps and labor intensity, while simultaneously achieving highly efficient cyclical operation of the device and significantly improving separation efficiency.

[0017] Compared to existing technologies, the tightly fitted collection frame on the outside of the device body, together with the internal inclined discharge plate, forms a highly efficient collection structure. After the hymexazol crystals separate and fall from the conical filter assembly, the inclined discharge plate guides the crystals to automatically converge at the discharge pipe using its tilt angle. Operators only need to open the valve on the discharge pipe to quickly and conveniently discharge the crystals from the collection frame. Compared to traditional devices, this design greatly simplifies the crystal collection and discharge process, reduces material residue, improves discharge efficiency, and makes the entire purification and separation process smoother and more efficient.

[0018] The parts of the device not covered herein are the same as or can be implemented using existing technologies. Attached Figure Description

[0019] Figure 1 A schematic diagram of the structure of a separation device for the purification of hymexazol provided by this utility model;

[0020] Figure 2A schematic diagram of the filter screen structure of a separation device for purifying hymexazol provided by this utility model;

[0021] Figure 3 A schematic diagram of the fixed ring structure of a separation device for the purification of hymexazol provided by this utility model;

[0022] Figure 4 A schematic diagram of the collection frame structure of a separation device for the purification of hymexazol provided by this utility model.

[0023] Numbering on the map:

[0024] 1. Device body; 2. Collection frame; 3. Support leg; 4. Conical discharge hopper; 5. Controller; 6. Conical filter assembly; 7. Vibration motor; 8. Mounting frame; 9. Drive cylinder; 10. Mounting plate; 11. Filter screen; 12. Fixing ring; 13. Reinforcing rod; 14. Discharge pipe; 15. Inclined drop plate. Detailed Implementation

[0025] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0026] Example 1

[0027] Please refer to the following: Figure 1-4A separation device for purifying hymexazol includes a device body 1. A vertically fixed mounting frame 8 is welded or bolted to the top of the device body 1. A drive cylinder 9 is centrally mounted on the top surface of the mounting frame 8 using bolts. The output end of the drive cylinder 9 passes through the surface of the mounting frame 8 and is fixedly connected to a vibration motor 7 via high-strength bolts, allowing the drive cylinder 9 to drive the vibration motor 7 to move vertically. The output end of the vibration motor 7 is fixed to a mounting plate 10 in a conical filter assembly 6 via a key connection or flange connection, enabling efficient transmission of vibration from the vibration motor 7 to the mounting plate 10. The conical filter assembly 6 includes a mounting plate 10 and a fixing ring 12. Multiple bolt holes are arranged in a ring between the mounting plate 10 and the fixing ring 12, and bolts are used to tension and fix a filter screen 11, forming an inclined filter surface, increasing the filtration area, and accelerating the filtration speed of the separated liquid. Simultaneously, multiple sets of inclined reinforcing rods 13 are welded between the fixing ring 12 and the mounting plate 10. The inclination angle is calculated mechanically to effectively disperse the stress generated by the vibration motor 7 during operation, enhancing the connection strength between the two. Furthermore, the outer diameter of the fixing ring 12 is precision machined to be equal to the inner diameter of the device body 1, forming a transition fit. This ensures that the fixing ring 12 is precisely embedded inside the device body 1, guaranteeing the stable installation of the conical filter assembly 6 and preventing the hymexazol crystals from leaking out through the gaps. During operation, the drive cylinder 9 drives the vibration motor 7 and the conical filter assembly 6 to move up and down, realizing the lifting and lowering of the filter assembly within the device body 1. The vibration motor 7 provides high-frequency vibration to the conical filter assembly 6, accelerating the separation process of the hymexazol crystals from the liquid, thereby achieving efficient and stable purification and separation.

[0028] Example 2

[0029] Please refer to the following: Figure 1-4 The outer surface of the device body 1 is tightly fitted and fixed to the collection frame 2 by welding or snap-fit ​​connection, ensuring a seamless connection between the collection frame 2 and the device body 1 and preventing crystal leakage. The bottom of the collection frame 2 is fitted with a sloping discharge plate 15 by welding or bolting. Its inclination angle is designed according to crystal flowability and collection requirements. One end faces a pre-drilled through hole on the surface of the collection frame 2. A discharge pipe 14 is installed through the through hole by welding or flange connection. A valve is installed on the discharge pipe 14 by threaded connection. The sloping discharge plate 15 and the bottom of the collection frame 2 form an inclined guiding channel, ensuring that the hymexazol crystals slide smoothly towards the discharge pipe 14 under gravity. The discharge pipe 14 and the outlet of the sloping discharge plate 15 are precisely aligned, ensuring smooth crystal entry into the discharge pipe 14. After the hymexazol crystals separate and fall from the filter screen 11, the inclined drop plate 15 guides the crystals to converge towards the discharge pipe 14. The operator can achieve efficient collection and rhythmic discharge of the crystals by controlling the valve on the discharge pipe 14 to open or close, simplifying the process, reducing manual intervention, and ensuring the continuity of the separation work.

[0030] Example 3

[0031] Please refer to the following: Figure 1-4 The outer diameter of the fixing ring 12 is precisely manufactured to be equal to the inner diameter of the device body 1 during processing. During installation, the two form a transition fit. This tight fit not only ensures the stability of the fixing ring 12 during installation, preventing it from shaking or shifting during device operation, but also effectively prevents the hymexazol crystals from leaking out of the gap between the fixing ring 12 and the device body 1 during the falling process, ensuring the integrity and accuracy of crystal collection, thereby improving collection efficiency.

[0032] Example 4

[0033] Please refer to the following: Figure 1-4 The fixing ring 12 and the mounting plate 10 are connected by welding. Multiple sets of reinforcing rods 13 are securely connected at one end to the edge of the mounting plate 10 and at the corresponding position on the fixing ring 12, arranged in a ring-shaped inclined distribution. Strict control of process parameters is maintained during welding to ensure welding quality. When the vibration motor 7 generates a large vibration force, the reinforcing rods 13 effectively disperse stress, evenly transmitting the vibration force to the mounting plate 10 and the fixing ring 12, preventing loosening or deformation due to excessive local stress. This ensures the reliability of the overall structure of the conical filter assembly 6 during vibration, guarantees the continuous and stable filtration function of the filter screen 11, and maintains the normal operation of the hymexazol purification and separation process.

[0034] Example 5

[0035] Please refer to the following: Figure 1-4 The bottom end of the device body 1 has a pre-drilled through hole matching the shape of the conical discharge hopper 4. The conical discharge hopper 4 is installed through the through hole by welding or flange connection, ensuring a tight connection and preventing leakage of the separated liquid. A valve is installed at the outlet of the conical discharge hopper 4 by threaded connection, and the installation position is convenient for operation. The special shape of the conical discharge hopper 4 gives it good flow guiding characteristics, which can smoothly guide the separated liquid at the bottom of the device body 1 to the outlet. The valve is tightly connected to the outlet of the conical discharge hopper 4, which can reliably control the discharge of the separated liquid. During the separation process, the separated liquid passing through the filter screen 11 gathers at the bottom of the device body 1. With the help of the flow guiding of the conical discharge hopper 4, it can be discharged quickly and smoothly. The operator controls the opening and closing of the valve and the opening degree to control the timing and speed of liquid discharge as needed, so as to meet the separation requirements under different working conditions.

[0036] Example 6

[0037] Please refer to the following: Figure 1-4Multiple support legs 3 are installed at the bottom of the device body 1, arranged at equal intervals, by welding or bolting. During installation, it is ensured that each support leg 3 is at the same height and perpendicular to the bottom surface of the device body 1. These equally spaced support legs 3 provide a stable foundation for the device, effectively dispersing the weight and vibration forces generated during operation. When the vibration motor 7 is working, the support legs 3 resist vibration impact, preventing the device from shaking or shifting, ensuring balanced operation, and guaranteeing a stable and accurate separation process, thereby improving separation efficiency and extending equipment lifespan.

[0038] Example 7

[0039] Please refer to the following: Figure 1-4 The controller 5 is mounted on the outer surface of the device body 1 using bolts or snap-fit ​​installation. The controller 5 is electrically connected to the drive cylinder 9, vibration motor 7, and various valves via wires. The wire connections use standardized plugs and sockets and are covered with protective sleeves. Through the controller 5's operating interface, the operator can precisely control the lifting stroke of the drive cylinder 9, adjust the position of the conical filter assembly 6 according to different separation requirements, control the start / stop and vibration frequency of the vibration motor 7 to optimize separation efficiency, and control the opening and closing status of various valves to achieve precise control over the discharge of the separated liquid and hymexazol crystals. Through the intelligent control of the controller 5, precise management of the entire separation process is achieved, improving the automation and efficiency of the separation work, and reducing manual operation errors and labor intensity.

[0040] It should be noted that the control circuit of controller 5 can be implemented by those skilled in the art through simple programming, and is common knowledge in the field. It is only used and not modified, so the control method and circuit connection will not be described in detail.

[0041] The working principle of the separation device for purifying hymexazol provided by this utility model is as follows:

[0042] When performing the purification and separation of hymexazol, the operator first pours the separation liquid containing hymexazol crystals into the main body 1 of the device. At this time, the drive cylinder 9 on the mounting frame 8 at the top of the main body 1 starts according to the preset program. Its output end passes through the mounting frame 8, driving the vibration motor 7 and the conical filter assembly 6 fixedly connected to it to move smoothly downward until the conical filter assembly 6 reaches the appropriate working position inside the main body 1.

[0043] Subsequently, the vibration motor 7 is activated, outputting high-frequency vibrations that drive the conical filter assembly 6 to produce a continuous and stable vibration effect. Under the action of vibration, the inclined filter screen 11 inside the conical filter assembly 6 accelerates the separation process of hymexazol crystals and liquid in the separation liquid. The separated liquid, relying on its own gravity and vibration impact, quickly passes through the filter screen 11 and is discharged through the conical discharge hopper 4 installed at the bottom of the device body 1. The valve installed at the outlet of the conical discharge hopper 4 can be flexibly controlled by the operator through the controller 5 on the outside of the device body 1, precisely adjusting the liquid discharge speed and flow rate to meet the separation requirements under different operating conditions.

[0044] The hymexazol crystals intercepted by the filter screen 11 gradually overcome their adhesion to the filter screen 11 and detach from it under the continuous vibration of the vibration motor 7. Because the outer diameter of the fixing ring 12 precisely matches the inner diameter of the device body 1, the crystals do not leak during their descent; instead, they fall directly along the inner wall of the device into the outer collection frame 2. The inclined drop plate 15 inside the collection frame 2, with its unique tilt angle design, automatically guides the falling crystals towards the discharge pipe 14. When the crystals accumulate to a certain amount in the collection frame 2, the operator opens the valve on the discharge pipe 14 via the controller 5. Under the influence of gravity, the crystals are smoothly discharged from the collection frame 2 through the discharge pipe 14, completing the crystal collection process.

[0045] Throughout the entire workflow, multiple support legs 3 evenly distributed at the bottom of the device body 1 provide stable and reliable support for the device, ensuring its stability during operation. Simultaneously, operators can monitor and precisely control the working status of the drive cylinder 9, vibration motor 7, and various valves in real time via the controller 5 installed on the outside of the device body 1, flexibly adjusting separation parameters to achieve fully automated and intelligent control of the hymexazol purification and separation process, thereby efficiently and accurately completing the hymexazol purification and separation task.

[0046] It should be noted that all components used in this application are standard parts that can be purchased from the market. The specific connection methods of each part adopt conventional methods such as bolts, rivets and welding that are mature in the prior art. The mechanical parts and electrical equipment adopt conventional models in the prior art. The circuit connection adopts conventional connection methods in the prior art. The electrical equipment is connected to an external safe power source. These will not be described in detail here.

[0047] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, 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 separation device for purifying hymexazol, comprising a device body (1), characterized in that, The device body (1) is equipped with a mounting frame (8) at the top. A drive cylinder (9) is mounted on the top surface of the mounting frame (8). A vibration motor (7) is fixed through the surface of the mounting frame (8) at the output end of the drive cylinder (9). A conical filter assembly (6) is mounted at the output end of the vibration motor (7). The conical filter assembly (6) includes a mounting plate (10) and a fixing ring (12). The output end of the vibration motor (7) is fixed to the mounting plate (10). A filter screen (11) is installed between the mounting plate (10) and the fixing ring (12).

2. The separation device for purifying hymexazol according to claim 1, characterized in that, A collection frame (2) is fixedly fitted onto the outer surface of the device body (1). An inclined material drop plate (15) is installed at the bottom inside the collection frame (2). A discharge pipe (14) is installed through the surface of the collection frame (2). A valve is installed on the discharge pipe (14).

3. The separation device for purifying hymexazol according to claim 1, characterized in that, The outer diameter of the fixing ring (12) is equal to the inner diameter of the device body (1).

4. The separation device for purifying hymexazol according to claim 1, characterized in that, A reinforcing rod (13) is connected between the fixing ring (12) and the mounting plate (10), and multiple sets of reinforcing rods (13) are installed.

5. The separation device for purifying hymexazol according to claim 1, characterized in that, A conical discharge hopper (4) is installed through the bottom of the device body (1), and a valve is installed at the outlet of the conical discharge hopper (4).

6. The separation device for purifying hymexazol according to claim 1, characterized in that, The device body (1) is equipped with a support leg (3) at the bottom end, and multiple support legs (3) are installed, and the multiple support legs (3) are distributed at equal distances on the bottom surface of the device body (1).

7. The separation device for purifying hymexazol according to claim 1, characterized in that, A controller (5) is installed on the outer surface of the device body (1).

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