Degradation agent treatment device for environmental pollution treatment
By combining gas-coordination components and air-blowing components, the problems of low mixing efficiency and high safety risks in traditional degradation agent treatment devices are solved, achieving efficient and safe pollutant treatment, especially in the treatment of flammable and explosive substances, ensuring controllable and safe reaction conditions.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHENGDU JINGRUILIN ENVIRONMENTAL PROTECTION ENG CO LTD
- Filing Date
- 2025-06-10
- Publication Date
- 2026-06-23
AI Technical Summary
Traditional degradation agent treatment devices have low mixing efficiency, difficult-to-control reaction conditions, and high safety risks. In particular, they pose an oxidation explosion risk when treating flammable and explosive pollutants, and lack inert gas protection and leakage monitoring mechanisms.
By employing gas-co-processing components and air-blowing components, combined with static mixing and dynamic stirring modes, and utilizing steam and nitrogen for synergistic heating to create an inert environment, the reaction parameters are precisely controlled by a controller, and nitrogen leak detection and safety valves are set up to ensure the safe and efficient conduct of the reaction.
It significantly improves reaction efficiency, ensures reaction safety, avoids the risk of oxidative explosion, and achieves efficient and stable treatment of pollutants in complex environments.
Smart Images

Figure CN224388769U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of environmental pollution control technology, specifically to a degradation agent treatment device for environmental pollution treatment. Background Technology
[0002] In the field of environmental pollution control, degradation agent treatment technology plays a key role in soil remediation, industrial wastewater purification and air pollution control as a crucial means of rendering pollutants harmless and reducing their volume.
[0003] In the field of environmental pollution control, traditional degradation agent treatment devices often face problems such as low mixing efficiency, difficulty in controlling reaction conditions, and high safety risks. On the one hand, some devices adopt a single mixing method, such as relying solely on static mixing or simple stirring, resulting in insufficient contact between the degradation agent and pollutants and low reaction efficiency. On the other hand, the lack of precise control over parameters such as temperature, pressure, and gas composition during the reaction process can easily lead to incomplete reactions or safety hazards caused by pressure imbalances. In addition, most existing equipment does not have inert gas protection and leakage monitoring mechanisms, posing a risk of oxidation and explosion when treating flammable and explosive pollutants. This makes it difficult to meet the demand for efficient and safe treatment of pollutants in complex environments. Therefore, we need to propose a degradation agent treatment device for environmental pollution control. Utility Model Content
[0004] The purpose of this invention is to provide a degradation agent treatment device for environmental pollution treatment, so as to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a degradation agent treatment device for environmental pollution treatment, comprising a tank and a mounting plate, wherein the tank is mounted on the surface of the mounting plate;
[0006] The surface of the mounting plate is equipped with a gas-coordination component for filling the tank with gas.
[0007] A power assembly for providing power is installed on the outside of the tank, and one end of the power assembly extends into the inside of the tank.
[0008] The tank is equipped with a blower assembly for spraying gas into the pipe, and one end of the blower assembly is connected to the inner wall of the tank.
[0009] Preferably, the gas coordinating component includes a steam generator, a nitrogen tank, and a first static mixer. The steam generator and the nitrogen tank are mounted on the surface of a bottom mounting plate. A water pump and a water tank are mounted on the surface of the mounting plate, and the pump's pumping end is connected to one end of the water tank.
[0010] Preferably, the water outlet of the water pump is connected to the water inlet of the steam generator, the steam outlet of the steam generator is connected to the air inlet of the first static mixer, the air inlet of the nitrogen tank is connected to the air inlet of the first static mixer, a nitrogen leak detector and a one-way valve are installed on the pipeline connecting the nitrogen tank and the first static mixer, and the air outlet of the first static mixer is connected to a first air outlet pipe.
[0011] Preferably, the power assembly includes a motor, a fixed plate, a pulley assembly, and a rotating shaft. The motor is mounted on the outside of the tank via the fixed plate. The pulley assembly connects the output end of the motor to the rotating shaft. The rotating shaft extends downward to the bottom of the tank. A stirring fan is mounted on the surface of the rotating shaft.
[0012] Preferably, the blowing assembly includes a spray head, which is installed inside the tank. An annular hole is provided on the upper side wall of the tank. The end of the first air outlet pipe away from the first static mixer is connected to the annular hole of the tank. The spray head is evenly distributed around the inner wall of the annular hole.
[0013] Preferably, a second static mixer is installed on the top of the tank, the surface of the second static mixer is provided with a feed inlet, and the top of the second static mixer is connected to an exhaust pipe.
[0014] Preferably, a pressure detector is mounted on the top of the second static mixer, and a controller is mounted on the surface of the mounting plate, the controller being electrically connected to the pressure detector.
[0015] Compared with the prior art, the beneficial effects of this utility model are:
[0016] This invention achieves both efficiency and safety enhancements through the combination of gas synergy components, air blowing components, and power components. It adopts a composite mode of "static mixing and dynamic stirring" to greatly improve reaction efficiency. Steam and nitrogen provide synergistic heating and create an inert environment to avoid oxidation. The intelligent system precisely controls reaction parameters to prevent pressure imbalance, providing an efficient, stable, and safe solution for pollutant treatment in complex environments. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the structure of this utility model;
[0018] Figure 2 This is a schematic diagram of the cross-sectional structure of the tank body of this utility model;
[0019] Figure 3 This is a schematic diagram of the blower assembly structure of this utility model;
[0020] Figure 4 This is a schematic diagram of the gas synergistic component structure of this utility model.
[0021] In the diagram: 1. Tank body; 2. Mounting plate; 3. Steam generator; 4. Nitrogen tank; 5. First static mixer; 6. Water pump; 7. Water tank; 8. Nitrogen leak detector; 9. One-way valve; 10. First outlet pipe; 11. Motor; 12. Fixing plate; 13. Pulley assembly; 14. Shaft; 15. Agitator fan; 16. Spray head; 17. Annular orifice; 18. Second static mixer; 19. Feed inlet; 20. Pressure detector; 21. Controller; 22. Exhaust pipe. Detailed Implementation
[0022] 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.
[0023] Please see Figures 1-4 This utility model provides a technical solution: an environmental pollution treatment device for degrading agents, including a tank 1 and a mounting plate 2. The tank 1 is mounted on the surface of the mounting plate 2. The tank 1 is used to provide space for the degradation reaction. Its hollow internal structure accommodates the substance to be treated and the degrading agent to react chemically. The mounting plate 2 is used to support and fix the tank 1 and other components, and provides a stable installation foundation for the equipment through bolt connection.
[0024] The surface of mounting plate 2 is equipped with a gas-coordination assembly for filling the tank 1 with gas. This assembly includes a steam generator 3, a nitrogen tank 4, and a first static mixer 5. The steam generator 3 and nitrogen tank 4 are mounted on the surface of the bottom mounting plate 2. The steam generator 3 heats water supplied from the water tank 7 to produce high-temperature steam, providing heat for the degradation reaction and promoting material flow. The nitrogen tank 4 stores nitrogen and supplies it to the first static mixer 5 via pipeline, acting as an inert protective gas to prevent oxidation and maintain pressure within the tank. The surface of mounting plate 2 is also equipped with a water pump 6 and a water tank 7. The pump's suction end is connected to one end of the water tank 7. The water pump 6 delivers water from the water tank 7 to the steam generator 3, where centrifugal force generated by the impeller rotation provides the power for water delivery. The water tank 7 stores water for the steam generator 3, providing a continuous and stable water supply for steam generation.
[0025] The outlet of the water pump 6 is connected to the inlet of the steam generator 3, and the outlet of the steam generator 3 is connected to the inlet of the first static mixer 5. The first static mixer 5 fully mixes the steam generated by the steam generator 3 with the nitrogen output from the nitrogen tank 4. The two gases are evenly distributed through the internal spiral blades. The inlet of the nitrogen tank 4 is connected to the inlet of the first static mixer 5. A nitrogen leak detector 8 and a one-way valve 9 are installed on the pipeline connecting the nitrogen tank 4 and the first static mixer 5. The nitrogen leak detector 8 monitors the sealing of the nitrogen pipeline in real time, detects changes in nitrogen concentration through an electrochemical sensor and issues an alarm. The one-way valve 9 ensures that nitrogen can only flow in one direction. The valve flap automatically opens or closes under fluid pressure to prevent backflow. The outlet of the first static mixer 5 is connected to a first outlet pipe 10. The first outlet pipe 10 transports the mixed steam and nitrogen to the annular hole 17 of the tank body 1, which serves as a gas transmission channel connecting the first static mixer 5 and the tank body 1.
[0026] A power assembly for providing power is installed on the outside of the tank body 1. One end of the power assembly extends into the interior of the tank body 1. The power assembly includes a motor 11, a fixing plate 12, a pulley set 13, and a rotating shaft 14. The motor 11 is mounted on the outside of the tank body 1 via the fixing plate 12. The motor 11 provides rotational power to the power assembly, converting electrical energy into mechanical energy to drive the pulley set 13 to rotate. The fixing plate 12 is used to fix the motor 11, and the motor 11 is securely mounted on the outside of the tank body 1 by bolts. The pulley set 13 is connected to the output shaft of the motor 11. The output end is connected to the rotating shaft 14. The pulley assembly 13 transmits the power of the motor 11 to the rotating shaft 14. The power transmission is achieved through the friction between the belt and the pulley. The rotating shaft 14 extends downward to the bottom of the tank 1. A stirring fan 15 is installed on the surface of the rotating shaft 14. The rotating shaft 14 transmits the rotational power of the pulley assembly 13 to the stirring fan 15. As a transmission component, it drives the stirring fan 15 to rotate inside the tank 1. The stirring fan 15 rotates under the drive of the rotating shaft 14. The blades agitate the substances inside the tank to promote full contact and mixing between the degradation agent and the substances to be treated.
[0027] The tank 1 is equipped with a blower assembly for spraying gas into the pipe. One end of the blower assembly is connected to the inner wall of the tank 1. The blower assembly includes a spray head 16, which is installed inside the tank 1. The spray head 16 sprays the mixed gas in the annular orifice 17 evenly into the tank 1. The gas is dispersed in a mist by the nozzle structure. The annular orifice 17 is provided on the upper side wall of the tank 1. The annular orifice 17 serves as a channel for gas to enter the tank 1. The gas is evenly distributed around the inner wall of the tank 1 by the surrounding design. The end of the first gas outlet pipe 10 away from the first static mixer 5 is connected to the annular orifice 17 of the tank 1. The spray head 16 is evenly distributed around the inner wall of the annular orifice 17.
[0028] A second static mixer 18 is installed on the top of the tank 1. An inlet 19 is installed on the surface of the second static mixer 18. The second static mixer 18 further mixes the degradation agent input into the inlet 19 with the rising gas in the tank. The static mixing element enhances the contact reaction between substances. The inlet 19 is used to input the degradation agent, serving as the inlet channel for the external degradation agent to enter the second static mixer 18. The top of the second static mixer 18 is connected to an exhaust pipe 22, which discharges the gas after the reaction in the tank. It serves as an exhaust gas discharge channel to maintain gas flow and pressure balance in the tank. The second static mixer 18 is installed on the top of the tank 1, and its top is connected to the exhaust pipe 22. To prevent the gas sprayed from the spray head 16 from escaping directly from the exhaust pipe 22, the spray head 16 sprays towards the material layer and forms at least a 180-degree circumferential misalignment with the exhaust pipe 22. At the same time, the low density characteristics of the mixture of high-temperature steam and nitrogen, combined with the pressure gradient of 0.02-0.05 MPa in the tank, guide the gas to flow upward to ensure that it fully participates in the reaction before being discharged.
[0029] A pressure detector 20 is installed on the top of the second static mixer 18. The pressure detector 20 monitors the pressure inside the tank in real time and converts the pressure signal into an electrical signal through a pressure sensor, which is then transmitted to the controller 21.
[0030] The surface of the mounting plate 2 is equipped with a controller 21, which is electrically connected to the pressure detector 20. The controller 21 receives the pressure signal of the tank 1 transmitted by the pressure detector 20 in real time and compares the received pressure signal with the preset pressure range. If the pressure is lower than the lower limit of the preset range, the controller 21 controls the water pump 6 to increase the water supply, so that the steam generator 3 produces more steam and opens the valve of the nitrogen tank 4 to supplement the gas. If the pressure is higher than the upper limit of the preset range, the controller 21 closes the valve of the nitrogen tank 4 and controls the induced draft fan to speed up the exhaust speed of the exhaust pipe 22 to reduce the pressure inside the tank. During this process, the controller 21 adjusts the speed of the motor 11 according to the pressure change and controls the speed of the stirring fan 15 through the pulley group 13 and the rotating shaft 14 to promote the reaction of the substances inside the tank. When the pressure returns to the normal range, the controller 21 maintains the current operating status of each component and continuously monitors the pressure to achieve closed-loop control.
[0031] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A degradation agent treatment device for environmental pollution treatment, comprising a tank (1) and a mounting plate (2), characterized in that: The tank (1) is mounted on the surface of the mounting plate (2); The surface of the mounting plate (2) is equipped with a gas-coordinating component for filling the tank (1) with gas; A power assembly for providing power is installed on the outside of the tank (1), and one end of the power assembly extends into the inside of the tank (1); The tank (1) is equipped with a blower assembly for spraying gas into the pipe, and one end of the blower assembly is connected to the inner wall of the tank (1).
2. The degradation agent treatment device for environmental pollution treatment according to claim 1, characterized in that: The gas coordinating component includes a steam generator (3), a nitrogen tank (4), and a first static mixer (5). The steam generator (3) and the nitrogen tank (4) are mounted on the surface of a bottom mounting plate (2). A water pump (6) and a water tank (7) are mounted on the surface of the mounting plate (2). The pumping end of the water pump (6) is connected to one end of the water tank (7).
3. The degradation agent treatment device for environmental pollution treatment according to claim 2, characterized in that: The outlet of the water pump (6) is connected to the inlet of the steam generator (3), the outlet of the steam generator (3) is connected to the inlet of the first static mixer (5), the inlet of the nitrogen tank (4) is connected to the inlet of the first static mixer (5), a nitrogen leak detector (8) and a one-way valve (9) are installed on the pipeline connecting the nitrogen tank (4) and the first static mixer (5), and the outlet of the first static mixer (5) is connected to the first outlet pipe (10).
4. The degradation agent treatment device for environmental pollution treatment according to claim 3, characterized in that: The power assembly includes a motor (11), a fixing plate (12), a pulley assembly (13), and a rotating shaft (14). The motor (11) is mounted on the outside of the tank (1) via the fixing plate (12). The pulley assembly (13) connects the output end of the motor (11) to the rotating shaft (14). The rotating shaft (14) extends downward to the bottom of the tank (1). A stirring fan (15) is mounted on the surface of the rotating shaft (14).
5. The degradation agent treatment device for environmental pollution treatment according to claim 4, characterized in that: The blowing assembly includes a spray head (16), which is installed inside the tank (1). An annular hole (17) is provided on the upper side wall of the tank (1). The end of the first air outlet pipe (10) away from the first static mixer (5) is connected to the annular hole (17) of the tank (1). The spray head (16) is evenly distributed around the inner wall of the annular hole (17).
6. The degradation agent treatment device for environmental pollution treatment according to claim 5, characterized in that: The top of the tank (1) is equipped with a second static mixer (18), the surface of the second static mixer (18) is equipped with a feed port (19), and the top of the second static mixer (18) is connected to an exhaust pipe (22).
7. The degradation agent treatment device for environmental pollution treatment according to claim 6, characterized in that: A pressure detector (20) is mounted on the top of the second static mixer (18), and a controller (21) is mounted on the surface of the mounting plate (2), which is electrically connected to the pressure detector (20).