Reactor with shock absorption and noise reduction functions

By introducing piston assemblies and rheostats into the reactor to regulate the flow rate and air velocity of the cooling medium, combined with a mechanical buffer structure, the problem of poor cooling effect of traditional reactors under different operating conditions is solved, and efficient and safe reactor operation is achieved.

CN122177637APending Publication Date: 2026-06-09WEIFANG CHENGJUN KUAIDIAN NEW ENERGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
WEIFANG CHENGJUN KUAIDIAN NEW ENERGY CO LTD
Filing Date
2026-01-29
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Traditional reactors have independent and non-dynamically adjustable shock absorption and heat dissipation systems, resulting in poor cooling performance under different operating conditions, increased resource waste or equipment failure risk, and higher equipment costs and space requirements.

Method used

A reactor with vibration and noise reduction functions was designed. The flow rate of perfluorohexanone liquid and the heat dissipation wind speed are adjusted by piston assembly and rheostat to achieve dynamic cooling response. Combined with mechanical buffer structure and intelligent adjustment cooling and fire extinguishing mechanism.

Benefits of technology

It enables precise cooling and fire suppression of reactors under abnormal operating conditions, reducing equipment damage, energy waste, simplifying equipment structure and reducing costs, and improving equipment safety and reliability.

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Abstract

This invention relates to the field of reactor technology, specifically to a reactor with vibration and noise reduction functions. It includes a distribution box with a cabinet door rotatably connected to its outer wall. A liquid storage tank is fixedly connected to the bottom of the inner wall of the distribution box, filled with perfluorohexanone liquid. When the reactor experiences abnormal high-temperature vibration, the noise reduction and vibration damping mechanism can reduce the reactor's vibration and noise, and trigger a cooling mechanism to increase the cooling effect on the reactor. A ventilation opening is provided on the outer wall of the distribution box, and an electric fan is fixedly installed inside the ventilation opening. When the reactor's vibration amplitude abnormally increases, the power of the water pump and fan is adjusted via a rheostat, simultaneously increasing the flow rate of the perfluorohexanone liquid and the cooling airflow, achieving precise cooling and fire suppression. This dynamic response mechanism overcomes the limitations of traditional fixed-parameter cooling methods, avoiding energy waste under normal operating conditions and rapidly improving cooling efficiency at abnormally high temperatures, significantly improving the safety and reliability of the equipment.
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Description

Technical Field

[0001] This invention relates to the field of reactor technology, specifically to a reactor with vibration reduction and noise reduction functions. Background Technology

[0002] In power systems, reactors are key equipment, and the vibration and heat generated during their operation are important factors affecting equipment stability and lifespan. As the capacity of power systems continues to increase, the vibration amplitude and heat generation of reactors during operation also increase. The vibration reduction and noise reduction and heat dissipation structures of traditional reactors are relatively independent. The vibration reduction device can only passively alleviate the vibration and cannot be dynamically adjusted according to the actual vibration situation. The heat dissipation system mostly adopts air cooling with a fixed wind speed or liquid cooling with a fixed flow rate, which is difficult to adapt to the heat dissipation requirements of reactors under different operating conditions.

[0003] Current reactor fire suppression and cooling solutions on the market often use pre-set parameters to control the flow rate of the cooling medium, such as the injection speed of perfluorohexanone or the speed of the cooling fan. These cannot be linked to the real-time vibration status of the reactor. When the reactor vibration amplitude is small, the cooling medium still runs at the preset high flow rate, resulting in wasted resources. When the vibration amplitude is large, the equipment is in abnormal operating conditions and heat generation increases, the cooling system cannot strengthen cooling in time, resulting in poor cooling and fire suppression effects. It may even cause equipment failure or fire due to heat accumulation. In addition, independent vibration damping, heat dissipation and fire suppression systems not only increase equipment costs and space occupation, but also have the problem of poor coordination between functional modules, making it difficult to achieve efficient and accurate protection of the reactor.

[0004] Therefore, developing a vibration reduction and noise reduction device that can intelligently adjust the flow rate of perfluorohexanone liquid and the cooling wind speed according to the actual vibration amplitude of the reactor has become an urgent need to improve the safety, reliability and economy of reactor operation, and is of great significance to ensuring the stable operation of the power system.

[0005] A search revealed prior art publication number CN111600225A, which discloses a vibration damping and noise reduction support for substations. The support includes a lower support plate and an upper support plate. The lower support plate includes a lower support plate base and a frustum-shaped load-bearing structure mounted on the base, with a circular boss at the bottom. The upper support plate includes an upper support plate base and a load-bearing structure connected to the base. At least one layer of rubber rings is disposed between the lower and upper support plates. When the rubber rings are multi-layered, a stiffening steel plate is provided between adjacent layers. The stiffening steel plate is a conical structure with circular openings of different diameters at the top and bottom. The bent portions of the rubber rings match the bent portions of the stiffening steel plates in structure, shape, and size. The rubber rings, stiffening steel plates, and the circular boss are concentrically arranged. This vibration damping and noise reduction support has a three-phase vibration damping function, effectively solving the problem of multiple points exceeding the standard for three-phase vibration in parallel reactors.

[0006] Therefore, based on the above search and combined with the existing methods, when the above solutions are used, they only achieve noise reduction and vibration reduction of the reactor by matching the structure, shape and size of the rubber ring bending. However, they cannot achieve cooling through the degree of vibration, which has limitations. Therefore, we propose a reactor with vibration reduction and noise reduction functions. Summary of the Invention

[0007] The purpose of this invention is to provide a reactor with vibration reduction and noise reduction functions to solve the problems mentioned in the background art.

[0008] To achieve the above objectives, the present invention provides the following technical solution:

[0009] A reactor with vibration and noise reduction functions includes a distribution box, an electrical cabinet door rotatably connected to the outer wall of the distribution box, a liquid storage tank fixedly connected to the bottom of the inner wall of the distribution box, the liquid storage tank being filled with perfluorohexanone liquid, a cooling mechanism fixedly installed at the upper end of the liquid storage tank, and a ceramic frame fixedly connected to the upper end of the liquid storage tank through two noise reduction and vibration reduction mechanisms.

[0010] A reactor is fixedly connected to the outer wall of the ceramic frame. When the reactor experiences abnormal high-temperature vibration, the noise reduction and vibration damping mechanism can reduce the noise and vibration of the reactor and trigger the cooling mechanism to increase the cooling effect on the reactor. A ventilation opening is provided on the outer wall of the distribution box, and an electric fan is fixedly installed inside the ventilation opening.

[0011] As a further aspect of this solution, the cooling mechanism includes two water pumps, the inlets of which are fixedly connected to the upper end of the liquid storage tank via pipes.

[0012] As a further aspect of this solution, a liquid storage box is fixedly connected between the outlets of the two water pumps via a pipe, and a heat dissipation pipe is fixedly connected to the upper end of the liquid storage box.

[0013] As a further aspect of this solution, the end of the heat dissipation pipe furthest from the liquid storage box is fixedly connected to the outer wall of the liquid storage tank.

[0014] As a further aspect of this solution, the noise reduction and vibration damping mechanism includes two first connecting round boxes, each of which has a first piston tube fixedly connected to its upper end. The inner wall of the first piston tube is slidably connected to a first piston block with a reset function, and the upper end of the first piston block is fixedly connected to a ceramic frame.

[0015] As a further aspect of this solution, a first piston plate is fixedly connected to the bottom of the first piston block, the first piston plate is slidably connected to the inner wall of the first connecting round box, a second piston tube is fixedly connected to the bottom of the first connecting round box, and a second piston block with a reset function is slidably connected to the inner wall of the second piston tube.

[0016] As a further aspect of this solution, a connecting block is fixedly connected to the bottom of the second piston block, and four reeling wheels with reset function are rotatably connected to the bottom of the first connecting round box. A miniature reeling wheel is fixedly connected between every two adjacent reeling wheels. A first pull rope is wound around the outer wall of each reeling wheel, and a belt rope is wound around the outer wall of the miniature reeling wheel. The free end of each belt rope is fixedly connected to the outer wall of the connecting block.

[0017] As a further aspect of this solution, a second connecting box is fixedly connected to the bottom of the first connecting box, a second piston plate is slidably connected to the inner wall of the second connecting box, and the second piston plate is fixedly connected to the top of the inner wall of the second connecting box by multiple second springs, and the free end of each of the first pull ropes is fixedly connected to the upper end of the second piston plate.

[0018] As a further aspect of this solution, the bottom of the second connecting round box is fixedly connected to a connecting air pipe, the outer wall of the connecting air pipe is fixedly connected to multiple air jet pipes, and the inner wall of the connecting air pipe is slidably connected to a movable ball, which is fixedly connected to the inner wall of the connecting air pipe by a fourth spring.

[0019] As a further aspect of this solution, a sleeve block is fixedly connected to the bottom of the movable ball via a connecting rod, and a rheostat is welded and fixed to the bottom of the connecting air pipe. The sleeve block is slidably connected to the outer wall of the rheostat. One of the rheostats is connected to two water pumps via a circuit, and the other rheostat is connected to a nearby electric fan via a circuit.

[0020] Beneficial effects

[0021] Compared with the prior art, the beneficial effects of the present invention are:

[0022] 1. When the vibration amplitude of the reactor increases abnormally, the power of the water pump and fan is adjusted by the rheostat to simultaneously increase the flow rate of perfluorohexanone liquid and the cooling wind speed, thereby achieving precise cooling and fire extinguishing. This dynamic response mechanism changes the limitations of the traditional fixed parameter cooling method, which not only avoids energy waste under normal working conditions, but also rapidly improves cooling efficiency at abnormal high temperatures, significantly improving the safety and reliability of the equipment.

[0023] 2. The piston assembly in the mechanical structure acts as a buffer and shock absorber during normal vibration, reducing the damage to the equipment. When abnormal vibration causes high temperature, it can also act as a switch to trigger intelligent adjustment, converting vibration energy into adjustment signals to achieve adaptive acceleration of the cooling system. This innovative design not only simplifies the equipment structure and reduces space occupation and cost, but also provides an integrated solution for the efficient and stable operation of the reactor. Attached Figure Description

[0024] Figure 1 This is a front view of a reactor with vibration damping and noise reduction functions;

[0025] Figure 2 This is a schematic diagram of the internal structure of a distribution box for a reactor with vibration and noise reduction functions.

[0026] Figure 3 This is a schematic diagram of the filter position structure of a reactor with vibration damping and noise reduction functions.

[0027] Figure 4 A schematic diagram of the location and structure of the liquid storage tank of a reactor with vibration damping and noise reduction functions;

[0028] Figure 5 This is a schematic diagram of the internal structure of the first connecting circular box of a reactor with vibration damping and noise reduction functions.

[0029] Figure 6 This is a schematic diagram of the position structure of the second piston plate of a reactor with vibration damping and noise reduction function.

[0030] Figure 7 for Figure 6 Enlarged view of point A in the middle;

[0031] Figure 8 A schematic diagram of the reel position structure of a reactor with vibration damping and noise reduction functions;

[0032] Figure 9 This is a schematic diagram of the internal structure of the connecting pipe of a reactor with vibration damping and noise reduction functions.

[0033] Figure 10This is a schematic diagram of the internal structure of a rubber ball in a reactor with vibration damping and noise reduction functions.

[0034] In the diagram: 1. Distribution box; 2. Cabinet door; 3. Reactor; 4. Ceramic frame; 5. Liquid storage tank; 6. Electric fan; 7. Filter screen; 8. Ventilation vent; 9. Water pump; 10. Liquid storage box; 12. Heat dissipation pipe; 14. First spring; 15. First piston block; 16. First piston tube; 17. Connecting column; 18. First piston plate; 19. First connecting round box;

[0035] 20. Second connecting round box; 21. Connecting air pipe; 22. Recycle reel; 23. First pull rope; 24. Second piston plate; 25. Second spring; 26. Second piston block; 27. Third spring; 28. Second piston tube; 29. ​​Belt rope; 30. Connecting block; 31. Miniature recycling wheel; 32. Moving ball; 33. Fourth spring;

[0036] 34. Jet nozzle; 35. Connecting rod; 36. Sleeve block; 37. Rheostat; 38. Chain; 39. Fifth spring; 40. Rubber ball; 41. Pressure relief pipe; 42. Third connecting box; 43. Nozzle; 101. Noise reduction and vibration damping mechanism; 201. Cooling mechanism. Detailed Implementation

[0037] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0038] Example 1: Please refer to Figure 1-4As shown, a reactor with vibration damping and noise reduction functions includes a distribution box 1. The outer wall of the distribution box 1 is rotatably connected to a cabinet door 2 via a pivot. A storage tank 5 is bolted to the bottom of the inner wall of the distribution box 1. The storage tank 5 is filled with perfluorohexanone liquid. Perfluorohexanone is a colorless and transparent liquid that evaporates rapidly during fire extinguishing, cooling through heat absorption during vaporization and interrupting the combustion chain reaction to extinguish the fire. It has good insulation properties, preventing secondary damage to precision circuits. A cooling mechanism 201 is fixedly installed at the upper end of the storage tank 5. The upper end of the box 5 is fixedly connected to a ceramic frame 4 via two noise reduction and vibration damping mechanisms 101. The outer wall of the ceramic frame 4 is fixedly connected to a reactor 3 via bolts. When the reactor 3 experiences abnormal high-temperature vibration, the noise reduction and vibration damping mechanism 101 can reduce the vibration and noise of the reactor 3 and trigger the cooling mechanism 201 to increase the cooling effect on the reactor 3. The outer wall of the distribution box 1 is provided with a ventilation opening 8. An electric fan 6 is fixedly installed inside the ventilation opening 8. A filter screen 7 is fixedly connected to the inner wall of the ventilation opening 8. The filter screen 7 can filter and remove dust from the air drawn in by the electric fan 6.

[0039] Example 2: Please refer to Figures 2-4 As shown, the cooling mechanism 201 includes two water pumps 9. The inlet of the water pump 9 is fixedly connected to the upper end of the liquid storage tank 5 through a pipe. The outlet of the two water pumps 9 is fixedly connected to the liquid storage box 10 through a pipe. The upper end of the liquid storage box 10 is fixedly connected to a heat dissipation pipe 12. The heat dissipation pipe 12 is made of copper. Copper has good corrosion resistance and high temperature resistance, as well as good thermal conductivity. The end of the heat dissipation pipe 12 away from the liquid storage box 10 is fixedly connected to the outer wall of the liquid storage tank 5.

[0040] Specifically, when the water pump 9 is started, the water pump 9 will draw perfluorohexanone liquid from the storage tank 5. The perfluorohexanone liquid will enter the storage box 10, then enter the heat dissipation pipe 12 through the storage box 10, and then flow back to the storage tank 5 through the heat dissipation pipe 12. This cycle continues. When the electric fan 6 rotates and blows air onto the outer wall of the heat dissipation pipe 12, the reactor 3 can be quickly cooled down by water.

[0041] Please see Figures 2-10As shown, the noise reduction and vibration damping mechanism 101 includes two first connecting round boxes 19. The upper end of each first connecting round box 19 is fixedly connected to a first piston tube 16. A first piston block 15 with a reset function is slidably connected to the inner wall of the first piston tube 16. The first piston block 15 and the inner wall of the first piston tube 16 are fixedly connected by a first spring 14. The upper end of the first piston block 15 is fixedly connected to a ceramic frame 4. The bottom of the first piston block 15 is fixedly connected to a first piston plate 18 via a connecting post 17. The outer wall of the connecting post 17 slidably passes through the interior of the first piston tube 16. The first piston plate 18 is slidably connected to the inner wall of the first connecting round box 19. A rubber ring is fixedly connected to the outer wall of the first piston plate 18. The rubber ring enhances the sealing between the first piston plate 18 and the inner wall of the first connecting round box 19. The bottom of the connecting round box 19 is fixedly connected to a second piston tube 28. The inner wall of the second piston tube 28 is slidably connected to a second piston block 26 with a reset function. The second piston block 26 and the bottom end of the inner wall of the second piston tube 28 are fixedly connected by a third spring 27. The bottom of the second piston block 26 is fixedly connected to a connecting block 30 through a connecting arm. The third spring 27 is sleeved on the outer wall of the connecting arm. The bottom of the first connecting round box 19 is rotatably connected to four recycle reel 22 with a reset function through a rotating shaft. Each recycle reel 22 is engaged with the bottom of the first connecting round box 19 through a first torsion spring. A miniature recycle reel 31 is fixedly connected between every two adjacent recycle reel 22. The outer wall of each recycle reel 22 is provided with multiple weight reduction ports, which are circumferentially distributed on the outer wall of the recycle reel 22.

[0042] Each recycling reel 22 has a first pull rope 23 wound around its outer wall, and a belt rope 29 wound around its outer wall. The free end of each belt rope 29 is fixedly connected to the outer wall of the connecting block 30. A second connecting box 20 is fixedly connected to the bottom of the first connecting box 19. A second piston plate 24 is slidably connected to the inner wall of the second connecting box 20. The second piston plate 24 and the top of the inner wall of the second connecting box 20 are fixedly connected by multiple second springs 25. The spring force coefficient of the first torsion spring is greater than that of the second spring 25. The first torsion spring is in a charged state. The multiple second springs 25 are circumferentially distributed between the second piston plate 24 and the second connecting box 20. The free end of each first pull rope 23 is fixedly connected to the upper end of the second piston plate 24. The outer wall of each first pull rope 23 slides through the interior of the second connecting box 20. A connecting air pipe 21 is fixedly connected to the bottom of the second connecting box 20 (please refer to...). Figure 5As shown), multiple jet pipes 34 are fixedly connected to the outer wall of the connecting air pipe 21. The multiple jet pipes 34 are circumferentially distributed on the outer wall of the connecting air pipe 21. A movable ball 32 is slidably connected to the inner wall of the connecting air pipe 21. The movable ball 32 is "spherical". The movable ball 32 is fixedly connected to the inner wall of the connecting air pipe 21 by a fourth spring 33. The fourth spring 33 is sleeved on the outer wall of the connecting rod 35. The outer wall of the connecting rod 35 slides through the inside of the connecting air pipe 21. A sleeve block 36 is fixedly connected to the bottom of the movable ball 32 through the connecting rod 35. A rheostat 37 is welded and fixed to the bottom of the connecting air pipe 21. The sleeve block 36 is slidably connected to the outer wall of the rheostat 37. One rheostat 37 is connected to two water pumps 9 through a circuit. The other rheostat 37 is connected to a nearby electric fan 6 through a circuit (not shown in the circuit diagram).

[0043] Specifically, when the moving ball 32 drives the sleeve 36 to move up and down on the outer wall of the rheostat 37 via the connecting rod 35, it will adjust the current to control the speed of the corresponding water pump 9, thereby accelerating the flow of perfluorohexanone liquid inside the heat dissipation tube 12 and increasing the cooling effect.

[0044] A rubber ball 40 is fixedly connected between the heat dissipation pipe 12 and the liquid storage tank 5 via a pipe. The rubber ball 40 is fixedly connected to the top of the distribution box 1 via a chain 38. The rubber ball 40 is made of rubber, which has good elasticity. A fifth spring 39 is fixedly connected inside the rubber ball 40. A pressure relief pipe 41 is fixedly connected to the bottom of the rubber ball 40. A pressure valve is fixedly installed inside the pressure relief pipe 41 (not shown in the figure). A third connecting round box 42 is fixedly connected to the bottom of the pressure relief pipe 41. Multiple nozzles 43 are fixedly connected to the bottom of the third connecting round box 42. The heat dissipation pipe 12 is fixedly connected to the upper end of the rubber ball 40 via a pipe. The upper end of the rubber ball 40 is also connected to the liquid storage tank 5 via a pipe.

[0045] Specifically, because a rubber ball 40 connects the heat dissipation pipe 12 and the liquid storage tank 5, the perfluorohexanone liquid inside the heat dissipation pipe 12 enters the rubber ball 40 at a constant speed, and then returns to the liquid storage tank 5 through the rubber ball 40. When the reactor 3 catches fire at high temperature, the water pump 9 will increase the flow rate of the perfluorohexanone liquid. Since the pipe between the rubber ball 40 and the liquid storage tank 5 is insufficient to support the current flow rate, the perfluorohexanone liquid will accumulate inside the rubber ball 40, causing the rubber ball 40 to expand. At this time, the reactor... 3. Due to abnormal vibration caused by high temperature, the distribution box 1 will also vibrate. The increased weight of the rubber ball 40 can enhance the overall stability of the distribution box 1 and also has a damping effect. When the rubber ball 40 expands to its limit, the pressure valve will be opened, and the perfluorohexanone liquid will enter the third connecting round box 42 and then be sprayed out through the nozzle 43. The perfluorohexanone liquid will fall evenly on the outer wall of the reactor 3. Since the perfluorohexanone liquid has flame retardant and insulating properties, it can effectively cool down and extinguish the fire, preventing the fire from starting.

[0046] The working principle of this invention is:

[0047] When in use, start the water pump 9. The water pump 9 will draw perfluorohexanone liquid from the storage tank 5. The perfluorohexanone liquid will enter the storage box 10, then enter the heat dissipation pipe 12 through the storage box 10, and then flow back to the storage tank 5 through the heat dissipation pipe 12. This cycle continues. When the electric fan 6 rotates and blows air onto the outer wall of the heat dissipation pipe 12, the reactor 3 can be quickly cooled by water.

[0048] When the reactor 3 is energized, it will vibrate, and the normal vibration amplitude of the reactor 3 is between 0.01 mm and 0.03 mm. When the reactor 3 vibrates, the reactor 3 will drive the first piston block 15 to move up and down through the ceramic frame 4. The first piston block 15 will drive the first piston plate 18 to move up and down in the inner wall of the first connecting round box 19 through the connecting column 17. The first piston plate 18 will compress the gas in the inner wall of the first connecting round box 19, which has the effect of buffering and shock absorption.

[0049] When reactor 3 experiences abnormal high temperature, its vibration amplitude increases significantly. The first spring 14 is compressed and accumulates elastic potential energy under the vibration. Subsequently, the elastic restoring force of the first spring 14 drives the first piston plate 18 to produce a larger up-and-down reciprocating motion. Since the internal volume of the first connecting round box 19 is much larger than that of the second piston tube 28 (the volume ratio between the two is 80:1), even if the first piston plate 18 has only a small displacement, it can quickly and efficiently compress the gas in the first connecting round box 19 and push it into the second piston tube 28, so that the second piston block 26 will move up and down in the inner wall of the second piston tube 28. The second piston block 26 will drive the connecting block 30 to move up and down. The connecting block 30 will also pull all the belt ropes 29. The belt ropes 29 will pull the micro recovery wheel 31 to rotate. The micro recovery wheel 31 will drive the connected recovery reel 22 to rotate. The recovery reel 22 will release the first pull rope 23.

[0050] At this time, the second piston plate 24 will move up and down under the action of the second spring 25. The second piston plate 24 will push the gas inside the second connecting round box 20 into the connecting air pipe 21. When the moving ball 32 drives the sleeve block 36 to move up and down on the outer wall of the rheostat 37 through the connecting rod 35, the current will be adjusted to control the speed of the corresponding water pump 9. The electric fan 6 will also accelerate to increase the air circulation inside the distribution box 1, so that the perfluorohexanone liquid will accelerate the flow inside the heat dissipation pipe 12 and increase the cooling effect.

[0051] When the temperature of reactor 3 decreases, the vertical range of the first piston block 15 decreases or disappears, and the vibration amplitude decreases, the reset torsion spring will drive the reel 22 to reset, the reel 22 will reset the first pull rope 23, the second piston plate 24 will reset inside the second connecting round box 20, at this time the sleeve block 36 will reset under the action of the fourth spring 33, and the power of water pump 9 and electric fan 6 will decrease.

[0052] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A reactor with vibration damping and noise reduction function, comprising a distribution box, characterized in that: The outer wall of the distribution box is rotatably connected to an electrical cabinet door, and the bottom of the inner wall of the distribution box is fixedly connected to a liquid storage tank. The liquid storage tank is filled with perfluorohexanone liquid, and a cooling mechanism is fixedly installed at the top of the liquid storage tank. The top of the liquid storage tank is fixedly connected to a ceramic frame through two noise reduction and vibration damping mechanisms. A reactor is fixedly connected to the outer wall of the ceramic frame. When the reactor experiences abnormal high-temperature vibration, the noise reduction and vibration damping mechanism can reduce the noise and vibration of the reactor and trigger the cooling mechanism to increase the cooling effect on the reactor. A ventilation opening is provided on the outer wall of the distribution box, and an electric fan is fixedly installed inside the ventilation opening.

2. A reactor with vibration damping and noise reduction function according to claim 1, characterized in that: The cooling mechanism includes two water pumps, and the inlet of each water pump is fixedly connected to the upper end of the liquid storage tank via a pipe.

3. A reactor with vibration damping and noise reduction function according to claim 2, characterized in that: A liquid storage box is fixedly connected between the outlets of the two water pumps via a pipe, and a heat dissipation pipe is fixedly connected to the upper end of the liquid storage box.

4. A reactor with vibration damping and noise reduction function according to claim 3, characterized in that: The end of the heat dissipation pipe furthest from the liquid storage box is fixedly connected to the outer wall of the liquid storage tank.

5. A reactor with vibration damping and noise reduction function according to claim 1, characterized in that: The noise reduction and vibration damping mechanism includes two first connecting round boxes. The upper end of each first connecting round box is fixedly connected to a first piston tube. The inner wall of the first piston tube is slidably connected to a first piston block with a reset function. The upper end of the first piston block is fixedly connected to a ceramic frame.

6. A reactor with vibration damping and noise reduction function according to claim 5, characterized in that: A first piston plate is fixedly connected to the bottom of the first piston block. The first piston plate is slidably connected to the inner wall of the first connecting round box. A second piston tube is fixedly connected to the bottom of the first connecting round box. A second piston block with a reset function is slidably connected to the inner wall of the second piston tube.

7. A reactor with vibration damping and noise reduction function according to claim 6, characterized in that: The bottom of the second piston block is fixedly connected to a connecting block, and the bottom of the first connecting round box is rotatably connected to four recycling reels with reset function. A miniature recycling reel is fixedly connected between every two adjacent recycling reels. A first pull rope is wound around the outer wall of each recycling reel, and a belt rope is wound around the outer wall of the miniature recycling reel. The free end of each belt rope is fixedly connected to the outer wall of the connecting block.

8. A reactor with vibration damping and noise reduction function according to claim 7, characterized in that: The bottom of the first connecting round box is fixedly connected to the second connecting round box, and the inner wall of the second connecting round box is slidably connected to the second piston plate. The second piston plate is fixedly connected to the top of the inner wall of the second connecting round box by multiple second springs, and the free end of each first pull rope is fixedly connected to the upper end of the second piston plate.

9. A reactor with vibration damping and noise reduction function according to claim 8, characterized in that: The bottom of the second connecting round box is fixedly connected to a connecting air pipe, the outer wall of the connecting air pipe is fixedly connected to multiple air jet pipes, and the inner wall of the connecting air pipe is slidably connected to a movable ball. The movable ball is fixedly connected to the inner wall of the connecting air pipe by a fourth spring.

10. A reactor with vibration damping and noise reduction function according to claim 9, characterized in that: The bottom of the movable ball is fixedly connected to a sleeve block via a connecting rod. A rheostat is welded and fixed to the bottom of the connecting air pipe. The sleeve block is slidably connected to the outer wall of the rheostat. One of the rheostats is connected to two water pumps via a circuit, and the other rheostat is connected to a nearby electric fan via a circuit.