A reaction kettle for processing rabeprazole sulfide

By installing a rotating structure and a limiting locking design on the reactor, the problem of inconvenient installation of traditional reactors is solved, enabling quick adjustment of the support rod angle and height, enhancing the stability and flexibility of the equipment, facilitating the connection of the reactor lid and pipelines, and improving operating efficiency.

CN224308409UActive Publication Date: 2026-06-02LANZHOU HONGYU TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
LANZHOU HONGYU TECH CO LTD
Filing Date
2025-07-09
Publication Date
2026-06-02

AI Technical Summary

Technical Problem

Traditional reactors are prone to tilting during installation due to uneven ground, making operation cumbersome, inflexible, and difficult to adjust in height and connect pipes to the reactor lid.

Method used

By installing a rotating structure on the reactor body and utilizing the interlocking design of the limiting rod and the limiting block, the tilt angle of the support rod can be quickly adjusted to enhance the stability of the reactor body. The height can also be adjusted by the telescopic rod and bolt structure for easy fixation.

Benefits of technology

It enables rapid installation and height adjustment of the reactor, improves the stability and flexibility of the equipment, facilitates the connection of the reactor lid and pipelines, and enhances operational efficiency.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224308409U_ABST
    Figure CN224308409U_ABST
Patent Text Reader

Abstract

This utility model relates to the field of reaction vessel technology, specifically a reaction vessel for processing rabeprazole sulfide. It includes a reaction vessel body, with three mounting seats fixedly connected to the outer wall of the reaction vessel body. A rotating shaft is fixedly connected to each mounting seat, and a support rod is rotatably connected to the rotating shaft. An attachment lug is fixedly connected to each support rod, and a limit rod is slidably connected to the attachment lug. Two arc-shaped grooves are provided on each mounting seat, and a limit block is fixedly connected to the outer side of each mounting seat. The end of the limit rod engages with a hole in the limit block. First, the reaction vessel body is installed in a designated position, and the end of the limit rod is no longer engaged with the hole in the limit block. Then, the support rod is rotated around the rotating shaft to change its angle. When the support rod rotates to a suitable angle, the end of the limit rod engages with another hole in the limit block, effectively limiting the support rod and quickly adjusting its tilt angle, thus enhancing the overall stability of the reaction vessel body.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to a reaction vessel, specifically a reaction vessel for processing rabeprazole sulfide, and belongs to the field of reaction vessel technology. Background Technology

[0002] Rabeprazole sulfide is an organic compound and an intermediate of rabeprazole, a raw material used to treat acid-related diseases. In its production process, a reaction vessel is often used to provide reaction space, promote material mixing, and ensure the safe conduct of the reaction, so as to meet various requirements for the processing of rabeprazole sulfide.

[0003] However, traditional reactors are often installed on iron frames via support lugs on the outer wall or fixed to the ground via support legs. Since the support legs are usually fixed directly to the outer wall of the reactor via lugs, the equipment is prone to tilting when the ground is uneven. This usually requires adjusting the installation position or leveling the ground, which is cumbersome and inflexible. It is also inconvenient to adjust the overall height of the reactor and to connect pipes on the reactor lid, resulting in poor flexibility. Utility Model Content

[0004] The purpose of this invention is to provide a reaction vessel for processing rabeprazole sulfide in order to solve the above-mentioned problems. By pulling out the limiting rod, the limiting rod connected to the support rod is no longer locked between itself and the hole on the limiting block, allowing for quick adjustment of the tilt angle of the support rod. This enables height adjustment and improves the overall stability of the reaction vessel.

[0005] This utility model achieves the above-mentioned objective through the following technical solution: a reaction vessel for processing rabeprazole sulfide, comprising a reaction vessel body, a rotating structure mounted on the reaction vessel body, the rotating structure including a mounting base, three mounting bases fixedly connected to the outer wall of the reaction vessel body, a rotating shaft fixedly connected to the mounting base, a support rod rotatably connected to the rotating shaft, an attachment lug fixedly connected to the support rod, a limit rod slidably connected to the attachment lug, two arc-shaped grooves opened on the mounting base, a limit rod provided between the two arc-shaped grooves, a limit block fixedly connected to the outer side of the mounting base, and the end of the limit rod engaging with a hole opened on the limit block.

[0006] Preferably, a knob is fixedly connected to one end of the limiting rod away from the limiting block, a retaining ring is slidably connected to the limiting rod, and a tension spring is fixedly connected between the retaining ring and the knob.

[0007] Preferably, one side of the retaining ring abuts against the inner wall of the mounting base, and the other side of the retaining ring abuts against the outer wall of the support rod.

[0008] Preferably, the three mounting bases are arranged in a circular array, and the limiting block has an arc-shaped structure.

[0009] Preferably, the tension spring passes through one of the arc-shaped grooves, and the support rod is fitted with a support structure.

[0010] Preferably, the support structure includes a telescopic rod, the telescopic rod is slidably connected inside the support rod, a first bolt is fixedly connected to the bottom of the support rod, and multiple limiting holes are opened on the telescopic rod, with the first bolt passing through one of the limiting holes.

[0011] Preferably, the bottom of the telescopic rod is fixedly connected to a base plate by a second bolt, and the base plate has a "T" shaped structure.

[0012] Preferably, the reactor body is equipped with an installation structure, the installation structure including a reactor cover, the reactor cover being fixedly connected to the reactor body, the reactor cover being fixedly connected to a feed inlet, the bottom of the reactor body being fixedly connected to a discharge port, and the reactor cover being fitted with a stirring structure.

[0013] Preferably, the stirring structure includes a support, a support is fixedly connected to the center of the vessel lid, a shaft seal is fixedly connected inside the support, a stirring shaft is rotatably connected to the center of the shaft seal, a motor is fixedly connected to the top of the support, the output shaft of the motor is fixedly connected to the stirring shaft via a coupling, and a stirring rod is fixedly connected to the bottom of the stirring shaft.

[0014] The beneficial effects of this utility model are as follows: a rotating structure is installed on the reactor body, three mounting seats are fixedly connected to the outer wall of the reactor body, a rotating shaft is fixedly connected to the mounting seat, a support rod is rotatably connected to the rotating shaft, an attached lug is fixedly connected to the support rod, a limit rod is slidably connected to the attached lug, two arc-shaped grooves are opened on the mounting seat, a limit rod is provided between the two arc-shaped grooves, a limit block is fixedly connected to the outer side of the mounting seat, and the end of the limit rod is engaged with the hole opened on the limit block. First, install the reactor body in the designated position. Simply adjust the tilt angle of the support rods on the three mounting bases according to the flatness of the ground or the ideal installation height of the reactor body. The end of the limiting rod is no longer engaged with the hole on the limiting block. Then, rotate the support rod around the pivot to move the angle. At the same time, the support rod drives the lug to rotate, and the lug drives the limiting rod to move along the arc groove. When the support rod rotates to the appropriate angle, the end of the limiting rod engages with another hole on the limiting block. At this time, the support rod can be effectively limited, and the tilt angle of the support rod can be quickly adjusted, which enhances the overall stability of the reactor body. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0016] Figure 2 for Figure 1 The diagram shown is an enlarged view of the structure of part A.

[0017] Figure 3 This is a schematic diagram of the connection structure between the lid and the support of this utility model;

[0018] Figure 4 for Figure 3 The diagram shown is an enlarged view of the structure of section B.

[0019] Figure 5 This is a schematic diagram of the connection structure between the stirring rod and the stirring shaft of this utility model.

[0020] In the diagram: 1. Reactor body; 2. Mounting structure; 201. Reactor cover; 202. Feed inlet; 203. Discharge outlet; 3. Stirring structure; 301. Support; 302. Motor; 303. Shaft seal; 304. Stirring shaft; 305. Coupling; 306. Stirring rod; 4. Rotating structure; 401. Mounting base; 402. Rotating shaft; 403. Support rod; 404. Lug; 405. Limiting block; 406. Limiting rod; 407. Knob; 408. Retaining ring; 409. Tension spring; 410. Arc groove; 5. Supporting structure; 501. Telescopic rod; 502. Limiting hole; 503. First bolt; 504. Second bolt; 505. Base plate. Detailed Implementation

[0021] 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.

[0022] Please see Figure 1-5As shown, a reaction vessel for processing rabeprazole sulfide includes a reaction vessel body 1. A rotating structure 4 is mounted on the reaction vessel body 1. The rotating structure 4 includes a mounting base 401. Three mounting bases 401 are fixedly connected to the outer wall of the reaction vessel body 1. A rotating shaft 402 is fixedly connected to the mounting base 401. A support rod 403 is rotatably connected to the rotating shaft 402. An attachment lug 404 is fixedly connected to the support rod 403. A limit rod 406 is slidably connected to the attachment lug 404. The mounting base 401 has two arc-shaped grooves 410. A limit rod 406 is provided between the two arc-shaped grooves 410. A limiting block 405 is fixedly connected to the outer side of the support rod 403. The end of the limiting rod 406 engages with a hole in the limiting block 405. A knob 407 is fixedly connected to the end of the limiting rod 406 facing away from the limiting block 405. A retaining ring 408 is slidably connected to the limiting rod 406. A tension spring 409 is fixedly connected between the retaining ring 408 and the knob 407. One side of the retaining ring 408 abuts against the inner wall of the mounting base 401, and the other side of the retaining ring 408 abuts against the outer wall of the support rod 403. The three mounting bases 401 are arranged in a circular array. The limiting block 405 has an arc-shaped structure, and the tension spring 409 passes through one of the arcs. The groove 410 has a support structure 5 fitted on the support rod 403. First, the reactor body 1 is installed in the designated position. The tilt angle of the support rod 403 on the three mounting seats 401 is adjusted according to the flatness of the ground or the ideal installation height of the reactor body 1. By pulling the knob 407 outward, the knob 407 stretches the tension spring 409, which in turn drives the limiting rod 406 to slide outward along the inner wall of the lug 404 and the retaining ring 408 until the end of the limiting rod 406 is no longer engaged with the hole on the limiting block 405. At this time, the support rod 403 is rotated around the rotating shaft 402 to move the angle, and the support rod 403 drives the lug 405 to move outward. 04. Rotation causes the lug 404 to move the limiting rod 406 along the arc groove 410. When the support rod 403 rotates to a suitable angle, the knob 407 is released, and the limiting rod 406 slides back to its initial position under the reset action of the tension spring 409 until the end of the limiting rod 406 engages with another hole on the limiting block 405. At this point, the support rod 403 can be effectively limited, and the tilt angle of the support rod 403 can be quickly adjusted. This not only enhances the overall stability of the reactor body 1, but also facilitates the adjustment of the height of the reactor cover 201 and the feed inlet 202, making it easy to connect pipes and add raw materials, with high flexibility.

[0023] As a technical optimization of this utility model, the support structure 5 includes a telescopic rod 501. The telescopic rod 501 is slidably connected inside the support rod 403. A first bolt 503 is fixedly connected to the bottom of the support rod 403. The telescopic rod 501 has multiple limiting holes 502. The first bolt 503 passes through one of the limiting holes 502. The bottom of the telescopic rod 501 is fixedly connected to a base plate 505 by a second bolt 504. The base plate 505 has a "T" shape. After adjusting the tilt angle of the three support rods 403 in sequence, the first bolt 503 can be removed so that it is no longer engaged with the limiting hole 502 on the telescopic rod 501. Then, the length of the telescopic rod 501 extending outward can be adjusted, which is highly flexible. At the same time, by loosening the nut on the second bolt 504, the base plate 505 at the bottom of the telescopic rod 501 can be rotated so that the base plate 505 is completely horizontal with the ground, which facilitates the overall fixation of the reactor body 1 and improves stability.

[0024] As a technical optimization of this utility model, an installation structure 2 is installed on the reactor body 1. The installation structure 2 includes a reactor cover 201. The reactor cover 201 is fixedly connected to the reactor body 1. A feed inlet 202 is fixedly connected to the reactor cover 201. A discharge port 203 is fixedly connected to the bottom of the reactor body 1. A stirring structure 3 is fitted on the reactor cover 201. After the reactor body 1 is fully installed, production raw materials can be added into the reactor body 1 through the feed inlet 202 on the reactor cover 201, and the finished product can be discharged out through the discharge port 203 at the bottom of the reactor body 1.

[0025] As a technical optimization of this utility model, the stirring structure 3 includes a support 301. The support 301 is fixedly connected to the center of the vessel cover 201. A shaft seal 303 is fixedly connected inside the support 301. A stirring shaft 304 is rotatably connected to the center of the shaft seal 303. A motor 302 is fixedly connected to the top of the support 301. The output shaft of the motor 302 is fixedly connected to the stirring shaft 304 through a coupling 305. A stirring rod 306 is fixedly connected to the bottom of the stirring shaft 304. When the power supply of the motor 302 on the support 301 is connected, the output shaft of the motor 302 drives the stirring shaft 304 at the bottom to rotate through the coupling 305. Since the shaft seal 303 is provided at the connection between the stirring shaft 304 and the vessel cover 201, the sealing of the inside of the reactor body 1 is effectively guaranteed. The stirring shaft 304 can drive the stirring rod 306 at the bottom to mix and stir the raw materials inside the reactor body 1, resulting in high operating efficiency.

[0026] In use, the reactor body 1 is first installed in the designated position. The tilt angle of the support rods 403 on the three mounting bases 401 is adjusted according to the flatness of the ground or the ideal installation height of the reactor body 1. By pulling the knob 407 outwards, the knob 407 stretches the tension spring 409, simultaneously causing the limiting rod 406 to slide outwards along the inner wall of the lug 404 and the retaining ring 408 until the end of the limiting rod 406 is no longer engaged with the hole in the limiting block 405. Then, the support rod 403 is rotated around the rotating shaft 402 to change its angle. Simultaneously, the support rod 403... 3. The lug 404 rotates, causing the limiting rod 406 to move along the arc groove 410. Once the support rod 403 rotates to the appropriate angle, the knob 407 is released, and under the reset action of the tension spring 409, the limiting rod 406 slides back to its initial position until the end of the limiting rod 406 engages with another hole on the limiting block 405. This effectively limits the support rod 403 and quickly adjusts its tilt angle, enhancing the overall stability of the reactor body 1 and facilitating the adjustment of the reactor lid 201 and the feed inlet 202. The height facilitates the connection of pipelines and the addition of production raw materials, offering high flexibility. After adjusting the tilt angles of the three support rods 403 in sequence, the first bolt 503 can be removed to prevent it from engaging with the limiting hole 502 on the telescopic rod 501. Then, the outward extension length of the telescopic rod 501 can be adjusted, providing high flexibility. Simultaneously, by loosening the nut on the second bolt 504, the bottom plate 505 of the telescopic rod 501 can be rotated to make the bottom plate 505 completely horizontal with the ground, facilitating the overall fixation of the reactor body 1 and improving stability. After the overall installation of the reactor body 1 is completed... Raw materials can be added into the reactor body 1 through the feed inlet 202 on the lid 201, while finished products can be discharged out through the discharge outlet 203 at the bottom of the reactor body 1. The power supply of the motor 302 on the support 301 is connected, and the output shaft of the motor 302 drives the bottom stirring shaft 304 to rotate through the coupling 305. Since the connection between the stirring shaft 304 and the lid 201 is equipped with a shaft seal 303, the sealing of the reactor body 1 is effectively guaranteed. The stirring shaft 304 can drive the stirring rod 306 at the bottom to mix and stir the raw materials inside the reactor body 1, resulting in high operating efficiency.

[0027] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0028] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A reaction vessel for processing rabeprazole sulfide, comprising a reaction vessel body (1), characterized in that: A rotating structure (4) is installed on the reactor body (1). The rotating structure (4) includes a mounting base (401). Three mounting bases (401) are fixedly connected to the outer wall of the reactor body (1). A rotating shaft (402) is fixedly connected to the mounting base (401). A support rod (403) is rotatably connected to the rotating shaft (402). An attachment lug (404) is fixedly connected to the support rod (403). A limiting rod (406) is slidably connected to the attachment lug (404). Two arc-shaped grooves (410) are opened on the mounting base (401). A limiting rod (406) is provided between the two arc-shaped grooves (410). A limiting block (405) is fixedly connected to the outer side of the mounting base (401). The end of the limiting rod (406) is engaged with the hole opened on the limiting block (405).

2. The reaction vessel for processing rabeprazole sulfide according to claim 1, characterized in that: A knob (407) is fixedly connected to one end of the limiting rod (406) away from the limiting block (405). A retaining ring (408) is slidably connected to the limiting rod (406). A tension spring (409) is fixedly connected between the retaining ring (408) and the knob (407).

3. The reaction vessel for processing rabeprazole sulfide according to claim 2, characterized in that: One side of the retaining ring (408) abuts against the inner wall of the mounting base (401), and the other side of the retaining ring (408) abuts against the outer wall of the support rod (403).

4. The reaction vessel for processing rabeprazole sulfide according to claim 1, characterized in that: The three mounting bases (401) are arranged in a circular array, and the limiting block (405) has an arc-shaped structure.

5. The reaction vessel for processing rabeprazole sulfide according to claim 2, characterized in that: The tension spring (409) passes through one of the arc-shaped grooves (410), and the support rod (403) is fitted with a support structure (5).

6. The reaction vessel for processing rabeprazole sulfide according to claim 5, characterized in that: The support structure (5) includes a telescopic rod (501), and the telescopic rod (501) is slidably connected inside the support rod (403). A first bolt (503) is fixedly connected to the bottom of the support rod (403). Multiple limiting holes (502) are opened on the telescopic rod (501), and the first bolt (503) passes through one of the limiting holes (502).

7. The reaction vessel for processing rabeprazole sulfide according to claim 6, characterized in that: The bottom of the telescopic rod (501) is fixedly connected to a base plate (505) by a second bolt (504), and the base plate (505) has a "T" shaped structure.

8. The reaction vessel for processing rabeprazole sulfide according to claim 1, characterized in that: The reactor body (1) is equipped with an installation structure (2), which includes a lid (201). The lid (201) is fixedly connected to the reactor body (1), and a feed inlet (202) is fixedly connected to the lid (201). A discharge port (203) is fixedly connected to the bottom of the reactor body (1). A stirring structure (3) is fitted on the lid (201).

9. The reaction vessel for processing rabeprazole sulfide according to claim 8, characterized in that: The stirring structure (3) includes a support (301), the support (301) is fixedly connected to the center of the lid (201), a shaft seal (303) is fixedly connected inside the support (301), a stirring shaft (304) is rotatably connected to the center of the shaft seal (303), a motor (302) is fixedly connected to the top of the support (301), the output shaft of the motor (302) is fixedly connected to the stirring shaft (304) through a coupling (305), and a stirring rod (306) is fixedly connected to the bottom of the stirring shaft (304).