A high-pressure micro-mist humidifying device for an optical fiber production workshop
By combining a high-pressure micro-mist device with a water treatment device, the problems of high energy consumption and unstable air supply environment of humidification equipment in the optical fiber production workshop have been solved. This has achieved low-energy humidification and cooling effects and stable air supply environment, and improved the service life and management convenience of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU STERLITE TONGGUANG FIBER
- Filing Date
- 2025-05-13
- Publication Date
- 2026-06-05
AI Technical Summary
The existing humidification equipment in optical fiber production workshops suffers from high energy consumption, low efficiency, and insufficient consideration of water quality and environmental changes, leading to unstable air supply environment and structural corrosion.
The system combines a high-pressure micro-mist device with a water treatment device. The high-pressure micro-mist device generates 1-15μm micro-mist particles for humidification. It is integrated with an air conditioning unit and a water distribution pipeline group for centralized management and protection. A water baffle is installed to prevent moisture erosion, and intelligent control is achieved through a humidity sensor.
It achieves low-energy humidification and cooling effects, ensures a stable air supply environment, improves the accuracy of humidity control and the service life of the equipment, reduces water dripping from the spray nozzles after shutdown, and facilitates maintenance and management.
Smart Images

Figure CN224327305U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of humidity control technology in production workshops, specifically to a high-pressure micro-mist humidification device for optical fiber production workshops. Background Technology
[0002] With the upgrading of optical fiber production technology, the cost of its production equipment is increasing, and the requirements for the production environment are also rising accordingly. To ensure the smooth operation of optical fiber production, it is necessary to control the temperature and humidity environment of the optical fiber production workshop. Controlling the ambient humidity is an important means of suppressing static electricity. Changes in humidity also affect the yield rate of the production process, the accuracy and lifespan of the production equipment, and the physical comfort of the workers.
[0003] Existing humidification methods for production workshops include electrode type, electric heating type, and high-pressure spray, etc. Electrode type and electric heating type humidification methods have the problem of extremely high power consumption, with high energy consumption and low efficiency; high-pressure spray saves power consumption, but the distance before the air outlet is long and water droplets are easily formed before the air is delivered, which affects the air delivery environment and requires high structural requirements for the air outlet section, which needs to be protected against moisture corrosion; in addition, existing humidification equipment does not adequately consider water quality and changes in the internal and external environment. Utility Model Content
[0004] Therefore, the technical problem to be solved by this utility model is to overcome the defects in structure and control in the prior art, thereby providing a high-pressure micro-mist humidification device for optical fiber production workshops.
[0005] The above-mentioned technical objective of this utility model is achieved through the following technical solution:
[0006] A high-pressure micro-mist humidification device for optical fiber production workshops includes a high-pressure micro-mist device, a water distribution pipeline group, multiple air conditioning units, and a water treatment device. The high-pressure micro-mist device is provided with a water inlet and a water outlet. The water inlet is connected to the water treatment device, and the water outlet is connected to the water distribution pipeline group. The water distribution pipeline group is provided with multiple connection ports connected to the air conditioning units. Each air conditioning unit includes an air conditioning shell, a heat exchanger, and a blower. The heat exchanger and the blower are arranged side by side in the air conditioning shell. A spraying device is provided on the side of the heat exchanger near the blower. The spraying device is connected to the connection port through a mist delivery pipe.
[0007] By adopting the above technical solution, a high-pressure micro-mist device is set up and connected to the air conditioning unit through a water distribution pipeline group, so as to adjust and control the ambient humidity at the same time as adjusting the ambient temperature, reduce the energy consumption of the air conditioning unit when cooling, avoid the use of electric heating humidification, and save energy and reduce costs; a water treatment device is set up at the front end of the high-pressure micro-mist device process to ensure the quality of atomized water and reduce possible impurities and pollutants.
[0008] The high-pressure micro-mist device uses a high-pressure plunger pump to increase the water pressure to 5-7 MPa, and then the pressurized water is atomized by a professional nozzle through a high-pressure resistant pipeline to produce micro-mist particles of 1-15 μm. These particles can quickly absorb heat from the air to complete vaporization and diffusion, thereby achieving the purpose of air humidification, cooling and energy saving.
[0009] Furthermore, the spraying device is installed on the side wall of the heat exchanger. The spraying device includes multiple parallel spray pipes connected to the mist delivery pipe at the same end. The multiple spray pipes are arranged in an array along the height direction of the heat exchanger and also along the length direction of the heat exchanger. Each spray pipe has multiple spray nozzles arranged in an array along its length direction. The axis of the spray nozzles is perpendicular to the axis of the spray pipe.
[0010] By adopting the above technical solution, spray pipes and spray nozzles are evenly arranged next to the heat exchanger. The overall layout is reasonable and also facilitates the subsequent air conditioning unit to output water mist to regulate humidity while adjusting the temperature.
[0011] Furthermore, each spray nozzle has a 0.15mm micropore at its center, and a filter is connected to the end of each spray nozzle away from the spray tube.
[0012] By adopting the above technical solution, the smaller micropores ensure a high-quality spray effect. A small filter is also provided in front of the spray nozzle to filter impurities and contaminants that may be generated during the operation of the plunger pump in the spray pipeline and high-pressure micro-mist device, thus ensuring the spray effect.
[0013] Furthermore, a baffle plate is provided between the heat exchanger and the blower. The baffle plate is abutted against the inner wall of the air conditioner housing around its perimeter. Water collection grooves are provided on both sides of the bottom of the baffle plate. The water collection grooves are perpendicular to the sides of the baffle plate. An inclined water guide plate is also provided between the baffle plate and the water collection grooves. The top of the water guide plate abuts against the side of the baffle plate and the bottom of the water guide plate abuts against the water collection grooves. A drain outlet is also provided at one end of the water collection grooves.
[0014] By adopting the above technical solution, a baffle plate is set in front of the air outlet section to collect and gather the water droplets formed, which avoids moisture from eroding the internal structure and ensures that the output mist is fine enough, thus ensuring a stable air supply environment and achieving a better mist delivery effect.
[0015] Furthermore, the air conditioner housing is provided with an air supply section and a return air section at both ends. The air supply section has an air supply port at the top, and the return air section has a return air port at the top. An air filter is also provided between the return air section and the heat exchanger.
[0016] By adopting the above technical solution, the indoor air and some fresh air drawn in the return air section are processed by air filters before being output, ensuring the cleanliness of the output air and improving the air conditioning effect.
[0017] Furthermore, a humidity sensor is also provided in the return air section, and the humidity sensor is connected to the high-pressure micro-mist device for signal control; an electrical control box is also provided on the outer wall of the air conditioner housing, and the electrical control box is connected to the high-pressure micro-mist device for signal control. The electrical control box is also connected to the high-pressure solenoid valve for signal control. The high-pressure solenoid valve is installed on the mist delivery pipe and controls the opening and closing of the mist delivery pipe.
[0018] By adopting the above technical solution, the humidity sensor in the return air section detects the humidity of the extracted air and adjusts the high-pressure micro-mist device to control the electrical control box, thereby operating the opening and closing of the high-pressure solenoid valve to control the on / off of the mist supply device, realizing intelligent control of the workshop environment humidity.
[0019] Furthermore, the high-pressure micro-mist device is also connected to the water distribution pipeline group for signal control. The water distribution pipeline group includes a water distribution body, a main water distribution pipe, two side water distribution branch pipes, and multiple intermediate water distribution branch pipes. The main water distribution pipe, the two side water distribution branch pipes, and the multiple intermediate water distribution branch pipes are all installed inside the water distribution body. The main water distribution pipe extends out of the water distribution body and connects to the outlet of the high-pressure micro-mist device. A pressure relief pipe is also connected to the main water distribution pipe, and a pressure relief valve is installed on the pressure relief pipe. The side water distribution branch pipes and the intermediate water distribution branch pipes are all connected to the other end of the main water distribution pipe. The intermediate water distribution branch pipes are all located between the two side water distribution branch pipes. The side water distribution branch pipes have three connection ports extending to the surface of the water distribution body, and the intermediate water distribution branch pipes have two connection ports extending to the surface of the water distribution body. Each connection port is equipped with a control valve that is connected to the high-pressure micro-mist device for signal control.
[0020] By adopting the above technical solution, a water distribution pipeline group is set up to connect the high-pressure micro-mist device and the spray device, which facilitates centralized management of the spray device's on / off state and also provides dual protection for the spray device and the high-pressure micro-mist device. The water distribution pipeline group directly releases pressure and drains water to reduce water dripping from the spray nozzles after shutdown. At the same time, the water distribution pipeline group provides unified monitoring of the connected pipelines, which facilitates troubleshooting and subsequent maintenance.
[0021] Furthermore, the top of the water treatment device is connected to a water source, and the water treatment device includes a coarse filter particle layer, an activated carbon layer, an ultrafiltration membrane layer and a reverse osmosis membrane layer arranged sequentially from top to bottom.
[0022] By adopting the above technical solution, a water treatment device is added before the high-pressure micro-mist device to treat the water source, reduce the generation of impurities in the water delivery pipeline, slow down the time of scale formation, improve the service life of the overall device, and also ensure the atomization cleaning effect.
[0023] In summary, the technical solution of this utility model has the following advantages:
[0024] 1. The high-pressure micro-mist humidification equipment for optical fiber production workshops provided by this utility model uses a high-pressure micro-mist device in conjunction with a spray device to generate a large number of fine mist droplets. Combined with an air conditioning unit, it can achieve reliable and stable humidification and cooling operation. This process has low energy consumption and can meet humidity control requirements.
[0025] 2. The high-pressure micro-mist humidification equipment for optical fiber production workshops provided by this utility model has a baffle plate set in front of the air outlet section to collect and converge the water droplets formed, which avoids moisture from corroding the internal structure and ensures that the output mist is fine enough, ensuring a stable air supply environment and achieving a good mist delivery effect.
[0026] 3. The high-pressure micro-mist humidification equipment for optical fiber production workshops provided by this utility model is equipped with a water treatment device to treat the water source and an air filter to treat the extracted air before output, ensuring cleanliness during use and improving the temperature and humidity adjustment effect.
[0027] 4. The high-pressure micro-mist humidification equipment for optical fiber production workshops provided by this utility model is equipped with a water distribution pipeline group connecting the high-pressure micro-mist device and the spray device, which facilitates centralized management of the spray device's on / off state and also provides dual protection for the spray device and the high-pressure micro-mist device. The water distribution pipeline group directly releases pressure and drains water to reduce water dripping from the spray nozzles after shutdown. At the same time, the water distribution pipeline group provides unified monitoring of the connected pipelines, which facilitates troubleshooting and subsequent maintenance. Attached Figure Description
[0028] To more clearly illustrate the specific embodiments of this utility model or the technical solutions in the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0029] Figure 1 This is a schematic diagram of the overall structure of a high-pressure micro-mist humidification device for an optical fiber production workshop, provided in one embodiment of the present invention.
[0030] Figure 2 This is a schematic diagram of the internal structure of an air conditioning unit provided in one embodiment of the present invention;
[0031] Figure 3 This is a cross-sectional view of a water distribution pipeline assembly provided in one embodiment of the present utility model;
[0032] Figure 4 This is a partial cross-sectional view of a water treatment device provided in one embodiment of the present invention.
[0033] Explanation of reference numerals in the attached figures:
[0034] 1. High-pressure micro-mist device; 11. Inlet; 12. Outlet; 2. Water distribution pipeline assembly; 21. Main water distribution unit; 211. Connection port; 2111. Control valve; 22. Main water distribution pipe; 221. Pressure relief pipe; 222. Pressure relief valve; 23. Side water distribution branch pipe; 24. Middle water distribution branch pipe; 3. Air conditioning unit; 31. Air conditioning casing; 311. Electrical control box; 32. Heat exchanger; 33. Blower; 34. Air supply section; 341. Air outlet 35. Return air section; 351. Return air vent; 352. Humidity sensor; 353. Air filter; 4. Water treatment device; 41. Coarse filtration layer; 42. Activated carbon layer; 43. Ultrafiltration membrane layer; 44. Reverse osmosis membrane layer; 5. Spray device; 51. Spray pipe; 511. Spray nozzle; 512. Filter nozzle; 6. Mist delivery pipe; 61. High-pressure solenoid valve; 7. Water baffle; 71. Water collection tank; 711. Drain outlet; 72. Water guide plate. Detailed Implementation
[0035] The present invention 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 only for explaining the present invention and are not intended to limit the present invention.
[0036] A high-pressure micro-mist humidification device for optical fiber production workshops, such as Figure 1 As shown, it includes a high-pressure micro-mist device 1, a water distribution pipeline group 2, multiple air conditioning units 3, and a water treatment device 4. The high-pressure micro-mist device 1 is provided with a water inlet 11 and a water outlet 12. The water inlet 11 is connected to the water treatment device 4, and the water outlet 12 is connected to the water distribution pipeline group 2. The water distribution pipeline group 2 is provided with multiple connection ports 211 to connect to different air conditioning units 3. The working principle of the air conditioning units 3 is the same as that in the prior art, so it will not be described again in this application.
[0037] The high-pressure micro-mist device 1 uses a high-pressure plunger pump to increase the water pressure to 5-7 MPa. When the micro-mist device is working, the water pressure is stable at 6-8 MPa. Then, the pressurized water is atomized by a professional nozzle through a high-pressure resistant pipeline to produce micro-mist particles of 1-15 μm. These particles can quickly absorb heat from the air to complete vaporization and diffusion, thereby achieving the purpose of air humidification, cooling, and energy saving.
[0038] like Figure 1 and Figure 4 As shown, the top of the water treatment device 4 is also connected to a water source. The water treatment device 4 includes a coarse filter particle layer 41, an activated carbon layer 42, an ultrafiltration membrane layer 43, and a reverse osmosis membrane layer 44 arranged sequentially from top to bottom. Adding the water treatment device 4 before the high-pressure micro-mist device 1 to treat the connected water source reduces the generation of impurities in the water delivery pipeline, slows down the time of scale formation, improves the service life of the overall device, and also ensures the atomization cleaning effect.
[0039] like Figure 1 and Figure 2 As shown, each air conditioning unit 3 includes an air conditioning housing 31, a heat exchanger 32, and a blower 33. The heat exchanger 32 and the blower 33 are arranged side by side inside the air conditioning housing 31. Each air conditioning housing 31 has a supply air section 34 and a return air section 35 at its left and right ends. The supply air section 34 is located at the end of the blower 33 away from the heat exchanger 32, and the return air section 35 is located at the end of the heat exchanger 32 away from the blower 33. The supply air section 34 has a supply air outlet 341 at its top, and the return air section 35 has a return air outlet 351 at its top. An air filter 353 is also provided between the return air section 35 and the heat exchanger 32. The indoor air and some fresh air drawn in by the return air section 35 are treated by the air filter 353 before being output, ensuring the cleanliness of the output air and improving the air conditioning effect.
[0040] like Figure 1 and Figure 2 As shown, a spray device 5 is installed on the side of the heat exchanger 32 near the blower 33. The spray device 5 is connected to the connection port 211 via a mist delivery pipe 6. The spray device 5 is installed on the side wall of the heat exchanger 32 and includes multiple parallel spray pipes 51 connected to the mist delivery pipe 6 at the same end. The spray pipes 51 are arranged in an array along the height direction of the heat exchanger 32 and also along the length direction of the heat exchanger 32. Each spray pipe 51 has multiple spray nozzles 511 arranged in an array along its length direction. The axis of the spray nozzles 511 is perpendicular to the axis of the spray pipes 51. A 0.15mm microhole is opened in the center of each spray nozzle 511. The 0.15mm microhole is precisely drilled by a drilling device. Each spray nozzle 511 is connected to a filter nozzle 512 at the end away from the spray pipe 51. The inner liner of the spray nozzle 511 is supported by copper material, and the flow rate of a single spray nozzle 511 is 2.76Kg / h. The spray pipes 51 and spray nozzles 511 are evenly arranged next to the heat exchanger 32. The overall layout is reasonable and facilitates the simultaneous output of water mist to regulate humidity when the air conditioning unit 3 adjusts the temperature. The small micro-holes ensure a high-quality spray effect. A small filter nozzle 512 is also provided in front of the spray nozzle 511 to filter impurities and contaminants that may be generated during the operation of the spray pipes 51 and the plunger pump in the high-pressure micro-mist device 1, ensuring the spray effect.
[0041] like Figure 1 and Figure 2As shown, a baffle plate 7 is also provided between the heat exchanger 32 and the blower 33. The baffle plate 7 is abutted against the inner wall of the air conditioner housing 31 on all four sides. Water collection troughs 71 are provided on both the left and right sides of the bottom of the baffle plate 7. The water collection troughs 71 are perpendicular to the sides of the baffle plate 7. An inclined water guide plate 72 is also provided between the baffle plate 7 and the water collection troughs 71. The top of the water guide plate 72 abuts against the side of the baffle plate 7 and the bottom abuts against the water collection troughs 71. A drain outlet 711 is also provided at the front end of the water collection troughs 71. The baffle plate 7 is set in front of the air outlet section to collect and gather the water droplets formed, so as to avoid moisture erosion of the internal structure and ensure that the output mist is fine enough, ensuring a stable air supply environment and achieving a good mist delivery effect.
[0042] like Figure 1 , Figure 2 and Figure 3 As shown, the water distribution pipeline group 2 includes a water distribution body 21, a main water distribution pipe 22, two side water distribution branch pipes 23, and multiple intermediate water distribution branch pipes 24. The main water distribution pipe 22, the two side water distribution branch pipes 23, and the multiple intermediate water distribution branch pipes 24 are all installed inside the water distribution body 21. The main water distribution pipe 22 extends out of the water distribution body 21 and is connected to the outlet 12 of the high-pressure micro-mist device 1. The upper and middle sections of the main water distribution pipe 22 are also connected to a pressure relief pipe 221. The pressure relief pipe 221 extends out of the water distribution body 21 and is equipped with a pressure relief valve 222. Pressure is directly released and water is drained at the water distribution pipeline group 2 to reduce the dripping of the spray nozzle 511 after shutdown. Both the side branch pipes 23 and the intermediate branch pipes 24 are connected to the other end of the main branch pipe 22. Multiple intermediate branch pipes 24 are positioned between two side branch pipes 23. Each side branch pipe 23 has three connection ports 211 extending to the surface of the main branch pipe 21. For example, the left side branch pipe 23 has connection ports 211 at the left, front, and bottom ends of the main branch pipe 21. The intermediate branch pipes 24 have two connection ports 211 extending to the surface of the main branch pipe 21. The connection ports 211 on the intermediate branch pipes 24 are located at the bottom and front ends of the main branch pipe 21. A branch pipe assembly 2 connects the high-pressure micro-mist device 1 and the spray device 5, facilitating centralized management of the spray device 5's operation. Simultaneously, the branch pipe assembly 2 provides unified monitoring of the connected pipes, facilitating troubleshooting and subsequent maintenance.
[0043] The main water distribution pipe 22, the two side water distribution branch pipes 23, and the multiple intermediate water distribution branch pipes 24 are all made of stainless steel and have a pressure resistance greater than 10 MPa to ensure the safe operation of the system.
[0044] like Figure 1 , Figure 2 and Figure 3As shown, a humidity sensor 352 is also installed in the return air section 35. The humidity sensor 352 is connected to the high-pressure micro-mist device 1 via signal control. An electrical control box 311 is also installed on the outer wall of the air conditioner housing 31. The electrical control box 311 is connected to the high-pressure micro-mist device 1 via signal control. The electrical control box 311 is also connected to the high-pressure solenoid valve 61 via signal control. The high-pressure solenoid valve 61 is installed on the mist delivery pipe 6 and controls the opening and closing of the mist delivery pipe 6. The high-pressure micro-mist device 1 is also connected to the water distribution pipeline group 2 via signal control. Each connection port 211 is equipped with a control valve 2111 that is connected to the high-pressure micro-mist device 1 via signal control. Humidity sensor 352 detects the humidity of the extracted air and transmits the humidity signal to high-pressure micro-mist device 1. High-pressure micro-mist device 1 is equipped with a set humidity condition to determine whether to activate the humidification function. If activated, it sends a signal to electrical control box 311 and the control valve 2111 of the corresponding water distribution pipe group 2 of the air conditioning unit 3. Electrical control box 311 controls the high-pressure solenoid valve 61 and control valve 2111 to open, thereby activating the spray device 5 to humidify the area where the air conditioning unit 3 is located. The high-pressure solenoid valve 61 and control valve 2111 control both ends of the mist delivery pipe 6, providing dual protection for the spray device 5 and ensuring spray safety.
[0045] The working principle and usage of the high-pressure micro-mist humidification equipment used in this optical fiber production workshop are as follows: Water treatment device 4, high-pressure micro-mist device 1, and spray device 5 are installed and connected in sequence via pipelines. A water baffle 7 is installed inside the air conditioner housing 31, and water collection troughs 71 and water guide plates 72 are installed on both sides of the bottom of the water baffle. A humidity sensor 352 is also installed in the return air section 35 of the air conditioning unit 3. When the air conditioning unit 3 is running, the high-pressure solenoid valve 61 and control valve 2111 are automatically opened or closed according to the humidity to start and close the spray device 5, thereby achieving the purpose of controlling the humidity of the corresponding area of each air conditioning unit 3.
[0046] The foregoing description illustrates and describes preferred embodiments of the present invention. As previously stated, it should be understood that the present invention is not limited to the forms disclosed herein and should not be construed as excluding other embodiments. It can be used in various other combinations, modifications, and environments, and can be altered within the scope of the inventive concept described herein through the foregoing teachings or related technical or knowledge. Any modifications and variations made by those skilled in the art that do not depart from the spirit and scope of the present invention should be within the protection scope of the appended claims.
Claims
1. A high-pressure micro-mist humidification device for optical fiber production workshops, characterized in that, The system includes a high-pressure misting device (1), a water distribution pipeline group (2), multiple air conditioning units (3), and a water treatment device (4). The high-pressure misting device (1) is provided with an inlet (11) and an outlet (12). The inlet (11) is connected to the water treatment device (4), and the outlet (12) is connected to the water distribution pipeline group (2). The water distribution pipeline group (2) is provided with multiple connection ports (211) connected to the air conditioning units (3). Each air conditioning unit (3) includes an air conditioning housing (31), a heat exchanger (32), and a blower (33). The heat exchanger (32) and the blower (33) are arranged side by side in the air conditioning housing (31). A spraying device (5) is provided on the side of the heat exchanger (32) near the blower (33). The spraying device (5) is connected to the connection port (211) through a mist delivery pipe (6).
2. The high-pressure micro-mist humidification equipment for optical fiber production workshops according to claim 1, characterized in that, The spray device (5) is installed on the side wall of the heat exchanger (32). The spray device (5) includes multiple parallel spray pipes (51) connected to the mist delivery pipe (6) at the same end. The multiple spray pipes (51) are arranged in an array along the height direction of the heat exchanger (32) and also along the length direction of the heat exchanger (32). Each spray pipe (51) has multiple spray nozzles (511) arranged in an array along its length direction. The axis of the spray nozzles (511) is perpendicular to the axis of the spray pipe (51).
3. The high-pressure micro-mist humidification equipment for optical fiber production workshops according to claim 2, characterized in that, The spray nozzle (511) has a 0.15mm microhole in the center, and each spray nozzle (511) is connected to a filter nozzle (512) at the end away from the spray tube (51).
4. The high-pressure micro-mist humidification equipment for optical fiber production workshops according to claim 3, characterized in that, A baffle plate (7) is also provided between the heat exchanger (32) and the blower (33). The baffle plate (7) is abutted against the inner wall of the air conditioner housing (31) around its perimeter. A water collection trough (71) is provided on both sides of the bottom of the baffle plate (7). The water collection trough (71) is perpendicular to the baffle plate (7). An inclined guide plate (72) is also provided between the baffle plate (7) and the water collection trough (71). The top of the guide plate (72) abuts against the side of the baffle plate (7) and the bottom abuts against the water collection trough (71). A drain outlet (711) is also provided at one end of the water collection trough (71).
5. A high-pressure micro-mist humidification device for optical fiber production workshops according to claim 4, characterized in that, The air conditioner housing (31) has an air supply section (34) and a return air section (35) at both ends. The air supply section (34) has an air supply port (341) at the top and the return air section (35) has a return air port (351) at the top. An air filter (353) is also provided between the return air section (35) and the heat exchanger (32).
6. A high-pressure micro-mist humidification device for an optical fiber production workshop according to claim 5, characterized in that, A humidity sensor (352) is also provided in the return air section (35), and the humidity sensor (352) is connected to the high-pressure micro-mist device (1) by signal control; an electrical control box (311) is also provided on the outer wall of the air conditioner housing (31), and the electrical control box (311) is connected to the high-pressure micro-mist device (1) by signal control. The electrical control box (311) is also connected to the high-pressure solenoid valve (61) by signal control. The high-pressure solenoid valve (61) is installed on the mist delivery pipe (6) and controls the opening and closing of the mist delivery pipe (6).
7. A high-pressure micro-mist humidification device for an optical fiber production workshop according to claim 6, characterized in that, The high-pressure micro-mist device (1) is also connected to the water distribution pipeline group (2) for signal control. The water distribution pipeline group (2) includes a water distribution body (21), a main water distribution pipe (22), two side water distribution branch pipes (23), and multiple intermediate water distribution branch pipes (24). The main water distribution pipe (22), the two side water distribution branch pipes (23), and the multiple intermediate water distribution branch pipes (24) are all installed inside the water distribution body (21). The main water distribution pipe (22) extends out of the water distribution body (21) and connects to the outlet (12) of the high-pressure micro-mist device (1). A pressure relief pipe (221) is also connected to the main water distribution pipe (22). 21) is equipped with a pressure relief valve (222). The side water distribution branch pipe (23) and the middle water distribution branch pipe (24) are both connected to the other end of the main water distribution pipe (22). The middle water distribution branch pipe (24) is set between the two side water distribution branch pipes (23). The side water distribution branch pipe (23) has three connection ports (211) extending to the surface of the water distribution body (21). The middle water distribution branch pipe (24) has two connection ports (211) extending to the surface of the water distribution body (21). Each connection port (211) is equipped with a control valve (2111) that is connected to the signal control of the high-pressure micro-mist device (1).
8. The high-pressure micro-mist humidification equipment for optical fiber production workshops according to claim 1, characterized in that, The water treatment device (4) includes a coarse filtration particle layer (41), an activated carbon layer (42), an ultrafiltration membrane layer (43), and a reverse osmosis membrane layer (44) arranged sequentially from top to bottom.