A gas continuous production reaction apparatus

By introducing flow direction and flow rate regulation mechanisms into the gas reaction device, continuous gas cooling is achieved, solving the problem of low gas cooling efficiency and improving cooling efficiency and the applicability of the device.

CN224358420UActive Publication Date: 2026-06-16CHONGQING TONGHUI GAS

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHONGQING TONGHUI GAS
Filing Date
2025-07-11
Publication Date
2026-06-16

AI Technical Summary

Technical Problem

Existing gas reaction devices have low gas cooling efficiency after production is completed, especially when the amount of reaction gas is large.

Method used

A reaction device for continuous gas production was designed. Through the flow direction adjustment mechanism and the flow rate adjustment mechanism, the drive component controls the rotation of the movable guide component, so that the gas enters different secondary cooling chambers for cooling. The gas flow rate is controlled by adjusting the alignment of the cooling discharge hole to improve the cooling efficiency.

Benefits of technology

It improves gas cooling efficiency, enhances the practicality of the device, and can adapt to different cooling needs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of reaction equipment of gas continuous production, belong to gas reaction device technical field, including first reaction tank body, first reaction tank body and second reaction tank body are communicated by connecting pipe;The inside bottom of second reaction tank body is fixedly installed with baffle;The upper region of second reaction tank body inside is located at the baffle and is set as transfer bin;The lower region of second reaction tank body inside is located at the baffle and is set as cooling bin;The middle part of baffle is provided with through-hole, so that transfer bin and cooling bin are communicated;The downside of baffle is provided with flow direction adjusting mechanism;Flow direction adjusting mechanism includes movable guide component and drive component.The utility model is continuously controlled movable guide component rotation by drive component, so that the through-hole of different secondary cooling bin intermittently with the middle part of baffle is communicated, so that the gas after production is continuously entered into different secondary cooling bin and is cooled.
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Description

Technical Field

[0001] This utility model relates to the technical field of gas reaction devices, specifically to a reaction device for continuous gas production. Background Technology

[0002] Gas reaction equipment is a core piece of equipment in the fields of chemical industry, environmental engineering, and energy conversion.

[0003] Chinese patent CN221656597U discloses a mixing reaction device for a gaseous chemical reaction, including a columnar reactor body with a reaction chamber inside. At least two reactant inlets communicating with the reaction chamber are located at the bottom of the reactor body, and a product outlet is located at the top of the reactor body. At least three mixing baffles are located in the reaction chamber above the reactant inlets, dividing the reaction chamber into multiple mixing reaction chambers from bottom to top. However, this device still has the following problems during use:

[0004] After the gas is produced, it needs to be cooled. However, the gas in this device can only be discharged through one outlet for cooling after production. When the amount of reactant gas is large, the cooling efficiency will be affected.

[0005] Based on this, the present invention designs a reaction device for continuous gas production to solve the above problems. Utility Model Content

[0006] In view of the above-mentioned shortcomings of the existing technology, the present invention provides a reaction device for continuous gas production.

[0007] To achieve the above objectives, this utility model provides the following technical solution:

[0008] A reaction apparatus for continuous gas production includes a first reaction tank, a flow direction regulating mechanism, a baffle, and a second reaction tank, wherein the first reaction tank and the second reaction tank are connected by a connecting pipe.

[0009] A baffle is fixedly installed at the bottom of the interior of the second reaction tank; the area above the baffle inside the second reaction tank is designated as a transfer chamber; the area below the baffle inside the second reaction tank is designated as a cooling chamber; a through hole is provided in the middle of the baffle to connect the transfer chamber and the cooling chamber.

[0010] A flow direction adjustment mechanism for controlling the flow direction of gas in the cooling chamber is provided on the lower side of the baffle; the flow direction adjustment mechanism includes a movable guide component for directional airflow in the internal space of the cooling chamber and a drive component for controlling the rotation of the movable guide component; the drive component is installed at the bottom of the second reaction tank, the movable guide component is connected to the drive component, and the movable guide component is connected to the interior of the second reaction tank.

[0011] Furthermore, it also includes a flow regulation mechanism. The bottom of the baffle is provided with a flow regulation mechanism for adjusting the gas outflow speed. The flow regulation mechanism includes a fixed cylinder, a rotating cylinder, a control component, and a self-locking component. The fixed cylinder is fixedly installed at the bottom of the baffle. The rotating cylinder is rotatably sleeved on the outer end of the fixed cylinder and is rotatably connected to the bottom of the baffle. The bottom of both the fixed cylinder and the bottom of the rotating cylinder extend through to the outer side of the bottom of the second reaction vessel. The bottom of the rotating cylinder is rotatably connected to the bottom of the second reaction vessel. The outer circumferential wall of the baffle is also fixedly connected to the inner wall of the second reaction vessel.

[0012] One part of the control assembly is installed at the bottom of the fixed cylinder, and the other part of the control assembly is connected to the rotating cylinder; a self-locking assembly for fixing the rotating cylinder is also installed at the bottom of the fixed cylinder.

[0013] The outer wall of the fixed cylinder has a first cooling discharge hole; the outer wall of the rotating cylinder has multiple first cooling discharge holes and second cooling discharge holes arranged alternately.

[0014] Multiple partition plates are fixedly installed between the inner bottom wall of the second reaction vessel and the bottom surface of the baffle. The ends of the partition plates are slidably connected to the outer side wall of the rotating cylinder. The multiple partition plates divide the cooling chamber area located between the inner wall of the second reaction vessel and the outer side wall of the rotating cylinder into multiple secondary cooling chambers of the same size. Each secondary cooling chamber has an air outlet on its inner bottom wall, and the outside of the air outlet is connected to the collection device.

[0015] Furthermore, the secondary cooling chamber is connected to the through hole in the middle of the baffle after being aligned with the first cooling discharge hole on the fixed cylinder and the first or second cooling discharge hole on the rotating cylinder.

[0016] Furthermore, the diameter of the second cooling discharge hole is smaller than that of the first cooling discharge hole.

[0017] Furthermore, the drive assembly includes a mounting bracket, a motor, and a drive gear. The mounting bracket is fixedly mounted on the bottom end of the fixed cylinder; the motor is fixedly mounted on the bottom of the mounting bracket; the drive gear is rotatably mounted on the top of the mounting bracket; and the output end of the motor is fixedly connected to the drive gear; the drive gear is connected to the movable guide assembly.

[0018] Furthermore, the movable guide assembly includes a V-shaped guide plate and a driven gear. The upper and lower ends of the V-shaped guide plate are rotatably connected to the top surface of the baffle and the inner bottom wall of the fixed cylinder, respectively. The driven gear is rotatably installed in the middle of the bottom end of the fixed cylinder. The driven gear is fixedly connected to the bottom corner of the V-shaped guide plate. The drive gear meshes with the driven gear.

[0019] Furthermore, the control assembly includes a first pusher cylinder and a pusher block. One end of the first pusher cylinder is hinged to the bottom edge of the second reaction vessel. The pusher block is fixedly connected to the bottom edge of the rotating cylinder. The output end of the first pusher cylinder is hinged to the pusher block.

[0020] Furthermore, the self-locking assembly includes a fixing plate, a locking pin, a second push cylinder, and a recovery assembly for controlling the reset of the locking pin. The fixing plate is fixedly installed at the bottom end of the fixing cylinder. A sliding groove is provided on the push block. The locking pin is slidably connected to the sliding groove. The two ends of the recovery assembly are respectively connected to the push block and the locking pin. The second push cylinder is fixedly installed at the front end of the push block, and the output end of the second push cylinder is in contact with the bottom of the locking pin.

[0021] Furthermore, the fixed plate is also provided with a movable groove; the top of the locking pin is inserted into the movable groove for a limit sliding connection; locking holes are provided on both the front and rear sides of the movable groove; the locking hole on the rear side is set as the first air outlet, and the locking hole on the front side is set as the second air outlet; the top of the locking pin can be inserted into the locking hole for connection.

[0022] Compared with the prior art, the advantages of this utility model are as follows:

[0023] 1. This utility model continuously controls the rotation of the movable guide component through the drive component, so that different secondary cooling chambers are intermittently connected to the through holes set in the middle of the baffle, so that the gas after production is completed continuously enters different secondary cooling chambers for cooling, thereby improving the cooling efficiency of the reaction gas.

[0024] 2. This utility model controls the gas discharge rate of the reaction gas by adjusting the alignment of the first cooling discharge hole on the rotating cylinder with the first cooling discharge hole or the second cooling discharge hole on the fixed cylinder, thereby further improving the practicality of the device. Attached Figure Description

[0025] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0026] Figure 1 This utility model relates to a three-dimensional reaction device for continuous gas production. Figure 1 ;

[0027] Figure 2 This is a front view of a reaction apparatus for continuous gas production according to this utility model;

[0028] Figure 3This utility model relates to a three-dimensional reaction device for continuous gas production. Figure 2 ;

[0029] Figure 4 for Figure 3 Enlarged view of point A in the middle;

[0030] Figure 5 For along Figure 2 A 3D diagram with a portion removed from the BB direction;

[0031] Figure 6 For along Figure 2 A three-dimensional image with a portion removed along the CC direction;

[0032] Figure 7 This is a partial 3D view of the self-locking component.

[0033] The labels in the diagram represent:

[0034] 1. First reaction vessel; 2. Flow direction adjustment mechanism; 21. Drive assembly; 211. Mounting bracket; 212. Motor; 213. Drive gear; 22. Movable guide assembly; 221. V-shaped guide plate; 222. Driven gear; 3. Flow adjustment mechanism; 31. Fixed cylinder; 32. Rotating cylinder; 33. Control assembly; 331. First push cylinder; 332. Push block; 34. Self-locking assembly; 341. Fixed plate; 342. Locking hole; 343. Locking pin; 344. Second push cylinder; 345. Locking spring; 346. Sliding groove; 347. Moving groove; 4. Baffle; 5. Second reaction vessel; 6. First cooling discharge hole; 7. Second cooling discharge hole. Detailed Implementation

[0035] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.

[0036] The terms "left," "right," "front," "back," "up," and "down" used in the following description refer to the orientation from the perspective of the front view.

[0037] In some embodiments, please refer to the accompanying drawings. Figures 1-7A reaction apparatus for continuous gas production includes a first reaction tank 1, a flow direction regulating mechanism 2, a flow rate regulating mechanism 3, a baffle 4, and a second reaction tank 5. The first reaction tank 1 and the second reaction tank 5 are connected by a connecting pipe. A baffle 4 is fixedly installed at the bottom of the interior of the second reaction tank 5. The area above the baffle 4 inside the second reaction tank 5 is designated as a transfer chamber. The area below the baffle 4 inside the second reaction tank 5 is designated as a cooling chamber. A through hole is provided in the middle of the baffle 4 to connect the transfer chamber and the cooling chamber.

[0038] A flow direction adjustment mechanism 2 for controlling the flow direction of gas in the cooling chamber is provided on the lower side of the baffle 4; the flow direction adjustment mechanism 2 includes a movable guide component 22 for directional airflow in the internal space of the cooling chamber and a drive component 21 for controlling the rotation of the movable guide component 22; the drive component 21 is installed at the bottom of the second reaction tank 5, the movable guide component 22 is connected to the drive component 21, and the movable guide component 22 is connected to the interior of the second reaction tank 5.

[0039] The bottom of the baffle 4 is provided with a flow regulating mechanism 3 for adjusting the gas outflow speed; the flow regulating mechanism 3 includes a fixed cylinder 31, a rotating cylinder 32, a control component 33, and a self-locking component 34; the fixed cylinder 31 is fixedly installed at the bottom of the baffle 4; the rotating cylinder 32 is rotatably sleeved on the outside of the fixed cylinder 31, and the rotating cylinder 32 is rotatably connected to the bottom of the baffle 4; the bottom of both the fixed cylinder 31 and the bottom of the rotating cylinder 32 extend through to the outside of the bottom of the second reaction tank 5, and the bottom of the rotating cylinder 32 is rotatably connected to the bottom of the second reaction tank 5; the outer circumferential wall of the baffle 4 is also fixedly connected to the inner wall of the second reaction tank 5; a part of the control component 33 is installed at the bottom of the fixed cylinder 31, and the other part of the control component 33 is connected to the rotating cylinder 32; the bottom of the fixed cylinder 31 is also equipped with a self-locking component 34 for fixing the rotating cylinder 32;

[0040] Preferably, the outer wall of the fixed cylinder 31 is provided with a plurality of first cooling discharge holes 6; the outer wall of the rotating cylinder 32 is provided with a plurality of first cooling discharge holes 6 and second cooling discharge holes 7 in an alternating manner; and the diameter of the second cooling discharge hole 7 is smaller than the diameter of the first cooling discharge hole 6.

[0041] Preferably, multiple partition plates are fixedly installed between the inner bottom wall of the second reaction tank 5 and the bottom surface of the baffle 4. The ends of the partition plates are slidably connected to the outer side wall of the rotating cylinder 32. The multiple partition plates divide the cooling chamber area located between the inner wall of the second reaction tank 5 and the outer side wall of the rotating cylinder 32 into multiple secondary cooling chambers of the same size. Each secondary cooling chamber has an air outlet on its inner bottom wall, and the outside of the air outlet is connected to the collection device. The secondary cooling chamber is connected to the through hole in the middle of the baffle 4 after being aligned with the first cooling discharge hole 6 on the fixed cylinder 31 and the first cooling discharge hole 6 or the second cooling discharge hole 7 on the rotating cylinder 32.

[0042] When this utility model is used, the gas that has been mixed and produced in the first reaction tank 1 is moved to the transfer chamber inside the second reaction tank 5 through the connecting pipe, and then flows from the transfer chamber to the cooling chamber through the through hole in the middle of the baffle 4.

[0043] Then, the drive assembly 21 is activated, and the drive assembly 21 controls the rotation of the movable guide assembly 22. At this time, the movable guide assembly 22 works, making one secondary cooling chamber connected to the through hole in the middle of the baffle 4, and blocking the channels between other secondary cooling chambers and the through holes in the middle of the baffle 4. After the reaction is completed, the gas enters the interior of the fixed cylinder 31 through the through hole in the middle of the baffle 4, and flows to the secondary cooling chamber connected to the through hole in the middle of the baffle 4 under the action of the movable guide assembly 22. Then, it is further cooled in the secondary cooling chamber, and finally discharged from the gas outlet at the bottom of the cooling chamber.

[0044] This invention continuously controls the rotation of the movable guide component 22 by the drive component 21, so that different secondary cooling chambers are intermittently connected to the through holes in the middle of the baffle 4, so that the gas after production is completed continuously enters the different secondary cooling chambers for cooling, thereby improving the cooling efficiency of the reaction gas.

[0045] Furthermore, in the initial state, the first cooling discharge hole 6 on the rotating cylinder 32 is aligned with the first cooling discharge hole 6 on the fixed cylinder 31. When it is necessary to accelerate the gas discharge speed of the reaction gas, the rotation lock of the rotating cylinder 32 is released by the self-locking component 34. Then, the rotating cylinder 32 is rotated by the control component 33, so that the second cooling discharge hole 7 on the rotating cylinder 32 is aligned with the first cooling discharge hole 6 on the fixed cylinder 31. At this time, since the diameter of the second cooling discharge hole 7 is smaller, the gas flow rate of the reaction gas entering the secondary cooling chamber will be increased, further improving the practicality of the device.

[0046] In some embodiments, such as Figures 1-7As shown, the drive assembly 21 includes a mounting bracket 211, a motor 212, and a drive gear 213. The mounting bracket 211 is fixedly mounted on the bottom end of the fixed cylinder 31; the motor 212 is fixedly mounted on the bottom of the mounting bracket 211; the drive gear 213 is rotatably mounted on the top of the mounting bracket 211; and the output end of the motor 212 is fixedly connected to the drive gear 213; the drive gear 213 is connected to the movable guide assembly 22.

[0047] In some embodiments, such as Figures 1-7 As shown, the movable guide assembly 22 includes a V-shaped guide plate 221 and a driven gear 222. The upper and lower ends of the V-shaped guide plate 221 are rotatably connected to the top surface of the baffle 4 and the inner bottom wall of the fixed cylinder 31, respectively. The driven gear 222 is rotatably installed in the middle of the bottom end of the fixed cylinder 31. The driven gear 222 is fixedly connected to the bottom corner of the V-shaped guide plate 221. The drive gear 213 is meshed with the driven gear 222.

[0048] In some embodiments, such as Figures 1-7 As shown, the control component 33 includes a first pusher cylinder 331 and a pusher block 332. One end of the first pusher cylinder 331 is hinged to the bottom edge of the second reaction vessel 5. The pusher block 332 is fixedly connected to the bottom edge of the rotating cylinder 32. The output end of the first pusher cylinder 331 is hinged to the pusher block 332.

[0049] In some embodiments, such as Figures 1-7 As shown, the self-locking assembly 34 includes a fixing plate 341, a locking pin 343, a second push cylinder 344, and a locking spring 345. The fixing plate 341 is fixedly installed at the bottom end of the fixing cylinder 31; a sliding groove 346 is provided on the push block 332; the locking pin 343 is slidably connected to the sliding groove 346; one end of the locking spring 345 is fixedly connected to the push block 332; and the other end of the locking spring 345 is fixedly connected to the top outer wall of the locking pin 343.

[0050] Preferably, the fixed plate 341 is also provided with a movable groove 347; the top of the locking pin 343 is inserted into the movable groove 347 for a limited sliding connection; locking holes 342 are provided on both the front and rear sides of the movable groove 347; the locking hole 342 on the rear side is set as the first air outlet, and the locking hole 342 on the front side is set as the second air outlet; the top of the locking pin 343 can be inserted into the locking hole 342 for insertion.

[0051] The second push cylinder 344 is fixedly installed at the front end of the push block 332, and the output end of the second push cylinder 344 is in contact with the bottom of the locking pin 343.

[0052] In this utility model, the gas after the mixing and production in the first reaction tank 1 is moved to the interior of the second reaction tank 5 through the connecting pipe, and then flows from the transfer chamber to the cooling chamber through the through hole in the middle of the baffle 4.

[0053] Then, motor 212 is started. Motor 212 drives drive gear 213 to rotate, which in turn drives driven gear 222 to rotate. Driven gear 222 rotates, which in turn drives V-shaped guide plate 221 to rotate. Driven gear 222 rotates, which connects one secondary cooling chamber with the through hole in the middle of baffle 4 and blocks the channels between other secondary cooling chambers and the through holes in the middle of baffle 4. At this time, after the reaction is completed, the gas enters the interior of fixed cylinder 31 through the through hole in the middle of baffle 4, and flows to the secondary cooling chamber through the first cooling discharge hole 6 set on fixed cylinder 31 and rotating cylinder 32. Then, it undergoes further cooling in the secondary cooling chamber and finally exits from the gas outlet at the bottom of the cooling chamber. By continuously driving V-shaped guide plate 221 to rotate by motor 212, different secondary cooling chambers are intermittently connected with the through holes in the middle of baffle 4, so that the gas after production continuously enters different secondary cooling chambers for cooling.

[0054] In the initial state, the first cooling discharge hole 6 on the rotating cylinder 32 is aligned with the first cooling discharge hole 6 on the fixed cylinder 31. At this time, the top of the locking pin 343 is inserted into the first gas outlet, and the locking spring 345 is in a stretched state. When it is necessary to accelerate the gas discharge speed of the reaction gas, the second push cylinder 344 pushes the locking pin 343 downward, and the restoring force of the locking spring 345 drives the locking pin 343 downward, so that the top of the locking pin 343 leaves the locking hole 342 of the first gas outlet.

[0055] Next, the first pusher cylinder 331 operates to push the pusher block 332 forward. At this time, the top of the locking pin 343 moves forward along the moving groove 347 until the locking pin 343 moves to the second gas outlet. At this time, the second pusher cylinder 344 drives the locking pin 343 to move upward, so that the top of the locking pin 343 is inserted into the locking hole 342 of the second gas outlet. At this time, the locking spring 345 is stretched. The second cooling discharge hole 7 provided on the rotating cylinder 32 is aligned with the first cooling discharge hole 6 provided on the fixed cylinder 31. Since the diameter of the second cooling discharge hole 7 is small, the gas flow rate of the reaction gas entering the secondary cooling chamber will be increased.

[0056] The above embodiments are only used to illustrate the technical solutions of this utility model, and are not intended to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions will not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.

Claims

1. A reaction apparatus for continuous gas production, comprising a first reaction tank (1), characterized in that: It also includes a flow direction adjustment mechanism (2), a baffle (4), and a second reaction tank (5), the first reaction tank (1) and the second reaction tank (5) being connected by a connecting pipe; A baffle (4) is fixedly installed at the bottom of the interior of the second reaction tank (5); the area above the baffle (4) inside the second reaction tank (5) is set as a transfer chamber; the area below the baffle (4) inside the second reaction tank (5) is set as a cooling chamber; a through hole is provided in the middle of the baffle (4) so ​​that the transfer chamber and the cooling chamber are connected. A flow direction adjustment mechanism (2) for controlling the flow direction of gas in the cooling chamber is provided on the lower side of the baffle (4); the flow direction adjustment mechanism (2) includes a movable guide component (22) for directional airflow in the internal space of the cooling chamber and a drive component (21) for controlling the rotation of the movable guide component (22); the drive component (21) is installed at the bottom of the second reaction tank (5), the movable guide component (22) is connected to the drive component (21), and the movable guide component (22) is connected to the interior of the second reaction tank (5).

2. The reaction equipment for continuous gas production according to claim 1, characterized in that, It also includes a flow regulating mechanism (3), and the bottom of the baffle (4) is provided with a flow regulating mechanism (3) for adjusting the gas outflow speed; the flow regulating mechanism (3) includes a fixed cylinder (31), a rotating cylinder (32), a control component (33) and a self-locking component (34); the fixed cylinder (31) is fixedly installed at the bottom of the baffle (4); the rotating cylinder (32) is rotatably sleeved on the outside of the fixed cylinder (31), and the rotating cylinder (32) is rotatably connected to the bottom of the baffle (4); the bottom of the fixed cylinder (31) and the bottom of the rotating cylinder (32) both extend through to the outside of the bottom of the second reaction tank (5), and the bottom of the rotating cylinder (32) is rotatably connected to the bottom of the second reaction tank (5); the outer circumferential wall of the baffle (4) is also fixedly connected to the inner wall of the second reaction tank (5); A portion of the control assembly (33) is installed at the bottom of the fixed cylinder (31), and another portion of the control assembly (33) is connected to the rotating cylinder (32); a self-locking assembly (34) for fixing the rotating cylinder (32) is also installed at the bottom of the fixed cylinder (31). The outer wall of the fixed cylinder (31) is provided with a plurality of first cooling discharge holes (6); the outer wall of the rotating cylinder (32) is provided with a plurality of first cooling discharge holes (6) and second cooling discharge holes (7) in an alternating manner. Multiple partition plates are fixedly installed between the inner bottom wall of the second reaction tank (5) and the bottom surface of the baffle (4). The ends of the partition plates are slidably connected to the outer side wall of the rotating cylinder (32). The multiple partition plates divide the cooling chamber area located between the inner wall of the second reaction tank (5) and the outer side wall of the rotating cylinder (32) into multiple secondary cooling chambers of the same size. Each secondary cooling chamber has an air outlet on its inner bottom wall, and the outside of the air outlet is connected to the collection device. Furthermore, the secondary cooling chamber is connected to the through hole in the middle of the baffle (4) after being aligned with the first cooling discharge hole (6) on the fixed cylinder (31) and the first cooling discharge hole (6) or the second cooling discharge hole (7) on the rotating cylinder (32).

3. The reaction equipment for continuous gas production according to claim 2, characterized in that, The diameter of the second cooling discharge hole (7) is smaller than that of the first cooling discharge hole (6).

4. The reaction equipment for continuous gas production according to claim 1, characterized in that, The drive assembly (21) includes a mounting bracket (211), a motor (212), and a drive gear (213). The mounting bracket (211) is fixedly mounted on the bottom end of the fixed cylinder (31); the motor (212) is fixedly mounted on the bottom of the mounting bracket (211); the drive gear (213) is rotatably mounted on the top of the mounting bracket (211); and the output end of the motor (212) is fixedly connected to the drive gear (213); the drive gear (213) is connected to the movable guide assembly (22).

5. The reaction equipment for continuous gas production according to claim 4, characterized in that, The active guide assembly (22) includes a V-shaped guide plate (221) and a driven gear (222). The upper and lower ends of the V-shaped guide plate (221) are rotatably connected to the top surface of the baffle (4) and the inner bottom wall of the fixed cylinder (31), respectively. The driven gear (222) is rotatably installed in the middle of the bottom end of the fixed cylinder (31). The driven gear (222) is fixedly connected to the bottom corner of the V-shaped guide plate (221). The drive gear (213) meshes with the driven gear (222).

6. The reaction equipment for continuous gas production according to claim 2, characterized in that, The control component (33) includes a first push cylinder (331) and a push block (332). One end of the first push cylinder (331) is hinged to the bottom edge of the second reaction vessel (5). The push block (332) is fixedly connected to the bottom edge of the rotating cylinder (32). The output end of the first push cylinder (331) is hinged to the push block (332).

7. The reaction equipment for continuous gas production according to claim 6, characterized in that, The self-locking assembly (34) includes a fixing plate (341), a locking pin (343), a second push cylinder (344), and a recovery assembly for controlling the reset of the locking pin (343). The fixing plate (341) is fixedly installed at the bottom end of the fixing cylinder (31). A sliding groove (346) is provided on the push block (332). The locking pin (343) is slidably connected to the sliding groove (346). The two ends of the recovery assembly are respectively connected to the push block (332) and the locking pin (343). The second push cylinder (344) is fixedly installed at the front end of the push block (332), and the output end of the second push cylinder (344) is in contact with the bottom of the locking pin (343).

8. The reaction equipment for continuous gas production according to claim 7, characterized in that, The fixed plate (341) is also provided with a movable groove (347); the top of the locking pin (343) is inserted into the movable groove (347) for a limited sliding connection; the movable groove (347) is provided with locking holes (342) on both the front and rear sides; the locking hole (342) on the rear side is set as the first air outlet, and the locking hole (342) on the front side is set as the second air outlet; the top of the locking pin (343) can be inserted into the locking hole (342) for connection.