A reaction kettle with automatic metering function of chemical material drop adding

Abstract

The utility model discloses a kind of reaction kettle with chemical material droping automatic metering function, it is related to chemical material reaction kettle technical field.The utility model includes base, reaction vessel, sealing cover and sliding plate, the top four corners of base are respectively fixed with sliding rod frame, and the top of sliding rod frame is equipped with two groups of jack, and the outside of four groups of sliding rod frame is slid with sliding plate, and the inside of jack is inserted with limit plug rod, and is tightly clamped with sliding plate, the side of sliding plate is inserted with two groups of limit pin, and is respectively inserted with two groups of limit plug rod, the top of reaction vessel is clamped with sealing cover, and rotating shaft is rotatably arranged in the inside of sealing cover, and the inside one end of sealing cover is provided with burette, the utility model can be better uniform speed droping function to the chemical material in the inside of reaction vessel, simultaneously, reaction vessel is conveniently disassembled, and the inside material of reaction vessel can also be observed and poured out for use quickly.

Description

Technical Field

[0001] This utility model relates to the field of chemical material reaction vessel technology, specifically a reaction vessel with automatic metering function for chemical material dripping. Background Technology

[0002] Chemical reaction vessels are crucial equipment in chemical production. They provide a suitable environment for various chemical reactions. Inside the reaction vessel, different chemical materials are fully mixed and come into contact, reacting according to a preset reaction path to generate the target product. Their stable operation ensures the high efficiency and safety of chemical production and is widely used in many industries such as pharmaceuticals, pesticides, and dyes.

[0003] However, traditional chemical reaction vessels are inconvenient to place or remove. They are usually fixed in place to transport materials inside, which are then discharged through the outlet at the bottom of the vessel. This method is not convenient for observing the degree of mixing of materials inside the vessel, and it is also not convenient for quickly removing or placing the reaction vessels. Utility Model Content

[0004] Based on this, the purpose of this utility model is to provide a reaction vessel with an automatic metering function for adding chemical materials. It can provide a better uniform dripping function for the chemical materials inside the reaction vessel, and at the same time, it can be easily disassembled, allowing for quick observation and emptying of the materials inside the reaction vessel.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a reaction vessel with automatic metering function for chemical material dripping, comprising a base, a reaction vessel, a sealing cover, and a sliding plate. Sliding rods are fixed at the four corners of the top of the base, and two sets of insertion holes are provided on the top of the sliding rods. Sliding plates slide on the outer sides of the four sets of sliding rods, and limiting rods are inserted into the insertion holes and abutted against the sliding plates. Two sets of limiting pins are inserted into one side of the sliding plates and are respectively inserted into the two sets of limiting rods. A sealing cover is secured to the top of the reaction vessel, and a rotating shaft is rotatably provided inside the sealing cover. A burette is provided at one end of the inner side of the sealing cover.

[0006] By adopting the above technical solution, the sliding rod frame is used to provide a limiting sliding function for the sliding plate, the insertion hole provides a supporting function for the sliding plate through cooperation with the limiting insertion rod, the limiting pin provides a limiting function for the limiting insertion rod to prevent it from falling off during use, the sealing cover provides a sealing function for the reactor vessel and a protection function for the chemical materials inside it, the rotating shaft is used to drive the stirring blades at the bottom to stir the chemical materials inside the reactor vessel, and the burette is used to automatically feed special chemical materials at a uniform speed and quantity.

[0007] Furthermore, a stabilizing pad is fixed to the bottom of the base, and a placement platform is fixed to the top of the base. The top of the placement platform is limited and engaged with the slots at the bottom of the reactor vessel by a number of sets of locking blocks.

[0008] By adopting the above technical solution, a stabilizing pad is fixed at the bottom of the base. This design significantly enhances the stability of the entire reactor system. A placement platform is fixed at the top of the base, and the top of the placement platform is limited and engaged with the slot at the bottom of the reactor vessel by several sets of locking blocks. This design not only makes the installation and disassembly of the reactor vessel more convenient, but also ensures the positional stability of the reactor vessel during the reaction process.

[0009] Furthermore, a drive motor is provided in the middle of the sliding plate, and a connector is installed at the output end of the drive motor. The bottom of the connector has a cross-sectional "+" shaped structure. The drive motor is electrically connected to an external power source through the control center.

[0010] By adopting the above technical solution, a drive motor is set in the middle of the sliding plate. This design allows the drive motor to directly drive the connector to rotate. The "+" shaped structure also helps to enhance the torque transmission capability of the connector, enabling the drive motor to drive the rotating shaft and stirring blades to rotate more effectively, thereby improving the stirring effect and reaction efficiency. The drive motor is electrically connected to an external power source through the control center. This design allows the start, stop, and speed adjustment of the drive motor to be remotely or automatically controlled through the control center.

[0011] Furthermore, the top of the rotating shaft is fitted with a cross-shaped groove structure, which is adapted to engage with the connector.

[0012] By adopting the above technical solution, a cross-shaped groove structure is provided on the top of the rotating shaft. This design makes the connection between the rotating shaft and the connector more stable and precise.

[0013] Furthermore, a stirring blade is fixed to the bottom of the rotating shaft, and the bottom of the stirring blade is locked to the inner bottom of the reactor vessel by a locking block.

[0014] By adopting the above technical solution, a stirring blade is fixed at the bottom of the rotating shaft. This design allows the stirring blade to be directly driven by the rotating shaft to rotate, thereby realizing the stirring of the material inside the reactor vessel.

[0015] Furthermore, an observation window is provided on the outside of the reactor vessel.

[0016] By adopting the above technical solution, an observation window is provided on the outside of the reactor vessel. This design allows the operator to directly observe the reaction inside the reactor vessel without frequently opening the sealing cap or performing other complex operations.

[0017] In summary, the present invention has the following main advantages:

[0018] 1. This utility model, by setting up insertion holes, sliding plates, limiting rods, and limiting pins, allows the sliding plates to slide stably up and down via four sets of sliding rod frames. When two sets of limiting rods are inserted into the insertion holes at the top of the sliding rod frames in pairs, they can provide a limiting function for the sliding plates. Each set of sliding rod frames has two sets of insertion holes at the top, thereby controlling the lifting height of the sliding plates. The limiting pins pass through the sliding plates to limit the limiting rods, thereby preventing the limiting rods from slipping during use. By adjusting the sliding plates to two different heights, the drive motor output connector can be disassembled and engaged with the rotating shaft, allowing the stirring blades to rotate inside the reactor vessel.

[0019] 2. This utility model, by setting up a burette, an observation window, and a placement platform, allows the reactor dish to be stably connected to the top of the placement platform via a slot at the bottom. When the connector and the rotating shaft are detached, the reactor dish can be quickly disassembled and installed on the placement platform. At the same time, the observation window on the outside of the reactor dish allows for real-time observation of the interior of the reactor dish. Furthermore, the burette allows for automatic and uniform dripping of materials into the interior of the reactor dish. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall front view of the present invention;

[0021] Figure 2 This is a bottom view of the structure of the connector and rotating shaft of this utility model in a split state;

[0022] Figure 3 This is a schematic diagram of the overall cross-sectional structure of this utility model;

[0023] Figure 4 This is a schematic diagram of the overall structure of this utility model in a disassembled state.

[0024] In the diagram: 1. Base; 2. Stabilizing pad; 3. Placement platform; 4. Sliding rod frame; 5. Insertion hole; 6. Sliding plate; 7. Drive motor; 8. Connector; 9. Limiting rod; 10. Limiting pin; 11. Reacting vessel; 12. Observation window; 13. Sealing cap; 14. Burette; 15. Rotating shaft; 16. Stirring blade. Detailed Implementation

[0025] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain the present invention, and should not be construed as limiting the present invention.

[0026] In this embodiment:

[0027] A reaction vessel with automatic metering function for chemical material dispensing, such as Figures 1-4 As shown, the reactor includes a base 1, a reactor dish 11, a sealing cap 13, and a sliding plate 6. Sliding rods 4 are fixed at the four corners of the top of the base 1, and two sets of insertion holes 5 are opened on the top of the sliding rods 4. Sliding plates 6 slide on the outside of the four sets of sliding rods 4, and limiting rods 9 are inserted into the insertion holes 5 and are tightly engaged with the sliding plates 6. Two sets of limiting pins 10 are inserted into one side of the sliding plates 6 and are respectively engaged with the two sets of limiting rods 9. The top of the reactor dish 11 is secured with a sealing cap 13, and a rotating shaft 15 is rotatably provided inside the sealing cap 13. A burette 14 is provided on one end of the inner side of the sealing cap 13.

[0028] The sliding rod bracket 4, fixed at the four corners of the top of the base 1, and the interlocking holes 5 and limiting rods 9 on the top of the sliding rod bracket 4, enable the stable sliding and height adjustment of the sliding plate 6. This allows the sliding plate 6 to be flexibly adjusted as needed. The interlocking design of the limiting pin 10 and the limiting rod 9 further enhances the stability of the sliding plate 6 after adjustment. In addition, the locking design of the sealing cover 13 and the reactor vessel 11, as well as the rotating shaft 15 and the burette 14 inside the sealing cover 13, not only ensure the sealing of the reaction environment, but also realize the automatic addition and precise metering of materials, thereby improving the efficiency and accuracy of the chemical reaction.

[0029] See Figure 1 , Figure 2 , Figure 3 and Figure 4 A stabilizing pad 2 is fixed to the bottom of the base 1, and a placement platform 3 is fixed to the top of the base 1. The top of the placement platform 3 is limited and engaged with the slot at the bottom of the reactor vessel 11 by several sets of locking blocks.

[0030] The base 1 has a stabilizing pad 2 fixed at its bottom to reduce the interference that may occur to the reaction process due to external vibration or uneven ground. The base 1 has a placement platform 3 fixed at its top, and the top of the placement platform 3 is locked in place with the slot at the bottom of the reactor vessel 11 by several sets of locking blocks, which prevents the reaction effect from being affected or safety hazards from the shaking or displacement of the reactor vessel 11. The drive motor 7 is electrically connected to an external power source through the control center, which not only improves the convenience and flexibility of operation, but also enables the reactor system to better adapt to the needs of different chemical reactions and achieve a more precise and controllable reaction process.

[0031] See Figure 1 , Figure 2 , Figure 3 and Figure 4A drive motor 7 is provided in the middle of the sliding plate 6, and a connector 8 is installed at the output end of the drive motor 7. The bottom of the connector 8 is provided with a cross-shaped structure. The drive motor 7 is electrically connected to an external power source through the control center.

[0032] The output end of the drive motor 7 is equipped with a connector 8, and the bottom of the connector 8 is designed with a cross-section in the shape of a cross. This special design enables the connector 8 to provide better alignment and stability when connected to components such as the rotating shaft 15, reducing vibration or wear caused by inaccurate connection.

[0033] See Figure 3 and Figure 4 The top of the rotating shaft 15 is fitted with a cross-shaped groove structure, which is compatible with and engages with the connector 8.

[0034] Since the bottom of the connector 8 also has a cross-shaped structure, the rotating shaft 15 and the connector 8 can fit together perfectly, ensuring smooth and stable power transmission.

[0035] See Figure 3 and Figure 4 A stirring blade 16 is fixed to the bottom of the rotating shaft 15, and the bottom of the stirring blade 16 is limited and locked to the inner bottom of the reactor vessel 11 by a locking block.

[0036] The bottom of the stirring blade 16 is locked to the inner bottom of the reactor vessel 11 by a locking block. This design not only ensures the stability of the stirring blade 16 during rotation, but also prevents the stirring blade 16 from being displaced or deformed due to centrifugal force or material impact.

[0037] See Figure 1 , Figure 2 , Figure 3 and Figure 4 An observation window 12 is provided on the outside of the reactor vessel 11;

[0038] In this invention, an observation window 12 is provided on the outside of the reactor dish 11, which not only improves the convenience of operation, but also reduces the pollution or error that may be introduced due to frequent opening of the reactor dish 11, thereby ensuring the purity and accuracy of the reaction.

[0039] The implementation principle of this embodiment is as follows: First, the base 1 is stably placed in the designated position by the stabilizing pad 2 at the bottom. Then, the material to be mixed is placed inside the reactor dish 11. The sealing cap 13 is used to lock and seal the top of the reactor dish 11. The bottom groove of the reactor dish 11 is locked and installed with the locking block on the top of the placement platform 3. Then, the material to be added is placed inside the burette 14, and the adjusting knob on the burette 14 is rotated to allow the burette 14 to slowly and uniformly add the material inside to the reactor dish 11. The locking and limiting of the limiting rod 9 is released by pulling the limiting pin 10 out of the sliding plate 6. Then, the two sets of limiting rods 9 are pulled out from the insertion hole 5 on the upper side of the top of the sliding rod frame 4. After releasing the support limit on the sliding plate 6, the sliding plate 6 can be lowered, allowing the connector 8 of the drive motor 7 to engage with the rotating shaft 15 in the middle of the sealing cover 13. Once the rotating shaft 15 and the connector 8 are connected, the limiting rod 9 can be inserted into the lower hole 5 at the top of the sliding rod frame 4 to provide support for the sliding plate 6. The limiting pin 10 limits the limiting rod 9. Finally, the drive motor 7 can be turned on through the control center, allowing the drive motor 7 to drive the rotating shaft 15 to rotate through the connector 8. This causes the rotating shaft 15 to drive the bottom stirring blade 16 to stir the material inside the reactor vessel 11. During the stirring process, the inside of the reactor vessel 11 can be observed in real time through the observation window 12.

[0040] Although embodiments of the present invention have been shown and described, these specific embodiments are merely explanations of the present invention and are not intended to limit the invention. The specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. After reading this specification, those skilled in the art may make modifications, substitutions, and variations to the embodiments as needed without departing from the principles and spirit of the present invention, provided that such modifications, substitutions, and variations are within the scope of the claims of the present invention and are protected by patent law.

Claims

1. A reaction vessel with automatic metering function for chemical material dispensing, characterized in that: Includes a base (1), a reactor vessel (11), a sealing cap (13), and a sliding plate (6); The base (1) has four sliding rods (4) fixed at the top corners, and two sets of insertion holes (5) are opened at the top of the sliding rods (4). Sliding plates (6) slide on the outside of the four sets of sliding rods (4), and limiting rods (9) are inserted into the insertion holes (5) and are tightly engaged with the sliding plates (6). Two sets of limiting pins (10) are inserted into one side of the sliding plates (6) and are respectively engaged with the two sets of limiting rods (9). The top of the reactor vessel (11) is secured with a sealing cap (13), and a rotating shaft (15) is rotatably provided inside the sealing cap (13). A burette (14) is provided at one end of the inner side of the sealing cap (13).

2. The reaction vessel with automatic metering function for chemical material dispensing according to claim 1, characterized in that: The bottom of the base (1) is fixed with a stabilizing pad (2), and the top of the base (1) is fixed with a placement platform (3). The top of the placement platform (3) is limited and engaged with the slot at the bottom of the reactor vessel (11) by several sets of locking blocks.

3. The reaction vessel with automatic metering function for chemical material dispensing according to claim 1, characterized in that: A drive motor (7) is provided in the middle of the sliding plate (6), and a connector (8) is installed at the output end of the drive motor (7). The bottom of the connector (8) is provided with a cross-shaped structure. The drive motor (7) is electrically connected to an external power source through the control center.

4. The reaction vessel with automatic metering function for chemical material dispensing according to claim 1, characterized in that: The top of the rotating shaft (15) is fitted with a cross-shaped groove structure, which is adapted to engage with the connector (8).

5. The reaction vessel with automatic metering function for chemical material dispensing according to claim 1, characterized in that: The bottom of the rotating shaft (15) is fixed with a stirring blade (16), and the bottom of the stirring blade (16) is locked to the inner bottom of the reactor vessel (11) by a locking block.

6. The reaction vessel with automatic metering function for chemical material dispensing according to claim 1, characterized in that: An observation window (12) is provided on the outside of the reactor vessel (11).

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