Intelligent fog gun water drop recovery device

The intelligent mist cannon dripping water recovery device solves the problems of nozzle dripping and low-temperature freezing, realizes water resource recovery and efficient operation of the equipment, and improves the environmental performance and service life of the equipment.

CN224442511UActive Publication Date: 2026-07-03SHANDONG YU RUN ENVIRONMENTAL PROTECTION MACHINERY EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG YU RUN ENVIRONMENTAL PROTECTION MACHINERY EQUIP CO LTD
Filing Date
2025-07-28
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Water dripping from the mist cannon nozzles after operation leaves residue, affecting performance and safety. Furthermore, it is prone to freezing in low-temperature environments, shortening equipment lifespan and increasing maintenance costs.

Method used

Design an intelligent mist cannon drip water recovery device, including a water collection hood and a solenoid valve system. It uses gas to purge and drain residual water to prevent the nozzles and pipes from freezing. The nozzles are evenly distributed around the circumference, and the water collection hood is designed with an incline to prevent bumps. The water resources are recovered to the water tank for recycling.

Benefits of technology

It effectively prevents nozzle dripping, improves equipment adaptability and lifespan, reduces maintenance costs, ensures operational safety and environmental performance, and enhances usage efficiency.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model is suitable for the technical field of mist gun nozzle drip water recovery device, provides an intelligent mist gun drip water recovery device, including the air cylinder, the end of air cylinder is fixed with the spray ring, is installed with the nozzle on the spray ring, the end of air cylinder lower side is fixed with the water collecting cover, the lower part of spray ring is connected with the front water pipe, and the front water pipe is connected with the rear water pipe through the check valve, and the other end of rear water pipe is connected with water pump, the front water pipe still is connected with the front water return pipe through the branch pipe, and is installed with electromagnetic valve two on the branch pipe, and one end of front water return pipe is connected with the lower part of water collecting cover, and the other end of front water return pipe is connected with the rear water return pipe through electromagnetic valve one, and the water outlet of rear water return pipe is placed in the water tank, the front water return pipe is connected with the air inlet pipe still, and is installed with electromagnetic valve three on the air inlet pipe. The utility model has the advantages of water saving, reasonable structure, anti -bumping, anti -frost damage, guarantee operation safety and high degree of automation, effectively improves the practicality and maintenance convenience of equipment.
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Description

Technical Field

[0001] This utility model belongs to the technical field of mist cannon nozzle drip water recovery device, and in particular relates to an intelligent mist cannon drip water recovery device. Background Technology

[0002] In recent years, with the continuous advancement and implementation of environmental protection efforts, society has placed higher demands on the overall performance of fog cannon equipment, especially in terms of protecting human health and the environment. Therefore, in the research and development and performance improvement of fog cannons, we should actively address these challenges and continuously optimize and innovate.

[0003] Currently, dust suppression fog cannons possess advantages such as long range, wide coverage, flexible operation, and high degree of automation. They can effectively control dust concentration, improve the working environment, and prevent industrial accidents, playing a vital role in promoting safe production and maintaining environmental sanitation. Therefore, their applications are wide-ranging, covering scenarios with severe dust pollution such as steel smelters, coal logistics parks, open-pit mining, blasting dust control, enclosed unloading areas, port truck unloading, dump truck dust control, large-scale loading operations, coastal port loading and unloading, coal and ore transshipment, and bulk material handling. They are also widely used in construction and demolition, construction waste or slag transportation, localized dust control in mechanical operations, and heavy vehicle road dust control. Furthermore, fog cannons can also be used for dust suppression, humidification, cooling, and disinfection operations in airports, highways, stations, docks, public places, stadiums, and high-temperature environments.

[0004] To achieve more efficient and stable operation of fog cannons in various dust control scenarios and better adapt to diverse dust suppression environments, it is necessary to optimize and upgrade their performance in multiple aspects, with particular emphasis on improving the design of the nozzle structure. As a key component of the fog cannon, the performance of the nozzle directly affects the overall performance and maintenance costs.

[0005] 1) Prevent water dripping from the nozzle: Currently, after the fog cannon finishes operation, residual water often appears at the nozzle, which not only affects the normal use of materials in the dust suppression area, but may also cause safety hazards such as slippery ground;

[0006] 2) Extend service life: Prolonged dripping of water from the nozzle can easily lead to rust, which in turn affects the service life of the spray ring, increasing the frequency and cost of equipment maintenance;

[0007] 3) Adaptable to low-temperature environments: When used outdoors in environments below zero degrees Celsius, water dripping from the nozzles may freeze, thus affecting the normal start-up of the equipment and the spraying effect;

[0008] 4) Reduce air duct corrosion: Water dripping from the nozzles can also cause dampness inside the air duct, which may lead to rust over time and shorten the service life of the entire machine;

[0009] 5) Responding to energy conservation and emission reduction policies: Under the national policy of vigorously advocating energy conservation and emission reduction, extending the service life of fog cannons and other key components helps to save resources and improve work efficiency;

[0010] 6) Enhance product market competitiveness: In the development of the real economy, keeping up with market demand and improving product diversity and practicality are the core driving forces for the sustainable development of enterprises and important factors that promote the continuous emergence of new and practical products.

[0011] In conclusion, systematically optimizing the design of fog cannon nozzles and related structures can not only significantly improve the applicability and stability of the equipment in various complex environments, but also help reduce operation and maintenance costs, extend equipment life, further meet the development needs of environmental protection and energy conservation, and help enterprises occupy a more advantageous position in fierce market competition.

[0012] Therefore, in view of the above situation, there is an urgent need to develop an intelligent mist cannon drip water recovery device to overcome the shortcomings in current practical applications. Utility Model Content

[0013] The purpose of this invention is to provide an intelligent mist cannon dripping water recovery device, which aims to solve the problems mentioned in the background art.

[0014] This utility model is implemented as follows: an intelligent mist cannon dripping water recovery device includes a blower duct, a spray ring fixed to one end of the blower duct, a nozzle mounted on the spray ring, and a water collection cover fixed to the lower side of the end of the blower duct; a front water pipe is connected to the lower part of the spray ring, the front water pipe is connected to a rear water pipe through a check valve, and the other end of the rear water pipe is connected to a water pump; the front water pipe is also connected to a front return water pipe through a branch pipe, and a second solenoid valve is mounted on the branch pipe; one end of the front return water pipe is connected to the lower part of the water collection cover, and the other end of the front return water pipe is connected to the rear return water pipe through a first solenoid valve; the water outlet of the rear return water pipe is placed in a water tank; an air inlet pipe is also connected to the front return water pipe, and a third solenoid valve is mounted on the air inlet pipe.

[0015] In a further technical solution, the nozzles are evenly distributed circumferentially on the spray ring.

[0016] In a further technical solution, the lower part of the water collection hood is inclined to the side away from the air duct.

[0017] A further technical solution is that the inner bottom of the water collection hood is inclined downward at the end near the air duct.

[0018] In a further technical solution, the solenoid valve three is used to control the gas from the air intake pipe to enter the spray ring and the water collection shroud, and to discharge the internal residual water.

[0019] The intelligent mist cannon dripping water recovery device provided by this utility model has the following beneficial effects:

[0020] This invention effectively collects water dripping from mist cannon nozzles and recycles it in a water tank, responding to the national water conservation policy and improving environmental performance. The water collection cover has a reasonable structure and is easy to install, preventing damage to the nozzles from impacts due to being too close to the ground. In cold environments, the system uses a three-way solenoid valve to control the gas purging of the pipeline, emptying residual water and preventing freezing damage to the nozzles and pipelines, thus improving the equipment's adaptability and service life. It also prevents dripping water from damaging materials on site, ensuring a clean and safe work area. Overall, the system is easy to operate, highly automated, reduces maintenance costs, and improves efficiency.

[0021] In summary, this utility model has the advantages of water conservation and environmental protection, reasonable structure, impact resistance, frost resistance, ensuring operational safety and high degree of automation, effectively improving the practicality and ease of maintenance of the equipment. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the intelligent fog cannon drip water recovery device provided in an embodiment of the present invention.

[0023] In the diagram: 1-Air duct, 2-Spray ring, 3-Spray head, 4-Water collection cover, 5-Inlet water pipe, 6-Check valve, 7-Rear inlet water pipe, 8-Solenoid valve 2, 9-Inlet water pipe, 10-Solenoid valve 1, 11-Solenoid valve 3, 12-Air inlet pipe, 13-Rear water pipe. Detailed Implementation

[0024] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.

[0025] The specific implementation of this utility model will be described in detail below with reference to specific embodiments.

[0026] like Figure 1 As shown, an intelligent fog cannon drip water recovery device is provided in one embodiment of the present utility model, including a wind duct 1, a spray ring 2 fixed at the end of the wind duct 1, a nozzle 3 installed on the spray ring 2, and a water collection cover 4 fixed at the lower side of the end of the wind duct 1.

[0027] The lower part of the spray ring 2 is connected to the inlet water pipe 5, which is connected to the rear inlet water pipe 7 through the check valve 6. The other end of the rear inlet water pipe 7 is connected to the water pump (not shown) through a flange.

[0028] The inlet water pipe 5 is also connected to the inlet water pipe 9 via a branch pipe. A solenoid valve 8 is installed on the branch pipe. One end of the inlet water pipe 9 is connected to the lower part of the water collection cover 4. The other end of the inlet water pipe 9 is connected to the outlet water pipe 13 via a solenoid valve 10. The outlet of the outlet water pipe 13 is placed inside the water tank (not shown).

[0029] The front return water pipe 9 is also connected to an air inlet pipe 12, on which a solenoid valve 3 11 is installed. By closing solenoid valve 1 10 and opening solenoid valve 2 8 and solenoid valve 3 11, gas can enter the spray ring 2 and water collection hood 4, discharging residual water inside and preventing damage to the nozzle 3 and pipes due to freezing. This significantly improves the environmental adaptability and service life of the equipment.

[0030] All connections can be threaded and tightened in place, ensuring tight pipe connections and secure installation to guarantee overall reliability.

[0031] Preferably, the nozzles 3 are evenly distributed around the spray ring 2; the lower part of the water collection cover 4 is inclined to the side away from the air duct 1, and the inner bottom of the water collection cover 4 is inclined downward at the end closer to the air duct 1 to ensure the reliability of water collection.

[0032] The above embodiments of this utility model provide an intelligent mist cannon dripping water recovery device, which can effectively collect water dripping from the mist cannon nozzle 3 and recycle it in a water tank. This not only responds to the national call for water conservation but also improves the environmental performance of the equipment. The water collection cover 4 has a reasonable structural design, is easy to install, and can effectively prevent the bottom nozzle 3 from being damaged by collision due to being too close to the ground. When used in cold outdoor environments, the solenoid valve 311 controls the gas to enter the water inlet pipe and spray ring 2 to discharge the residual water inside, preventing the nozzle 3 and pipe from being damaged by freezing, which significantly improves the environmental adaptability and service life of the equipment. At the same time, the device can also effectively prevent dripping water from damaging materials on site, ensuring the cleanliness and safety of the work area. The overall operation is convenient, with a high degree of automation, reducing maintenance costs and improving efficiency.

[0033] The technical features of the above embodiments can be combined in any way. For the sake of brevity, not all possible combinations of the technical features in the above embodiments are described. However, as long as there is no contradiction in the combination of these technical features, they should be considered to be within the scope of this specification.

[0034] The embodiments described above are merely illustrative of several implementations of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.

Claims

1. A smart fog gun water droplet recovery device comprising a wind tube (1), characterized in that, A spray ring (2) is fixed to the end of the air duct (1), a nozzle (3) is installed on the spray ring (2), and a water collection cover (4) is fixed to the lower side of the end of the air duct (1). The lower part of the spray ring (2) is connected to the inlet water pipe (5), the inlet water pipe (5) is connected to the rear inlet water pipe (7) through the check valve (6), and the other end of the rear inlet water pipe (7) is connected to the water pump. The forward water pipe (5) is also connected to the forward return water pipe (9) through a branch pipe. A second solenoid valve (8) is installed on the branch pipe. One end of the forward return water pipe (9) is connected to the lower part of the water collection cover (4). The other end of the forward return water pipe (9) is connected to the rear return water pipe (13) through a first solenoid valve (10). The blow-out port of the rear return water pipe (13) is placed inside the water tank. The front return water pipe (9) is also connected to an air inlet pipe (12), and a solenoid valve (11) is installed on the air inlet pipe (12).

2. The intelligent fog gun water drop recovery device according to claim 1, characterized in that, The nozzles (3) are evenly distributed around the spray ring (2).

3. The intelligent fog gun water drop recovery device according to claim 1, characterized in that, The lower part of the water collection cover (4) is inclined to the side away from the air duct (1).

4. The intelligent fog gun water recovery device according to claim 3, wherein, The bottom of the water collection cover (4) is inclined downward at the end near the air duct (1).

5. The intelligent fog gun water recovery device according to any one of claims 1-4, wherein, The solenoid valve three (11) is used to control the gas from the air inlet pipe (12) to enter the spray ring (2) and the water collection hood (4) and discharge the internal residual water.