An antimicrobial agent atomization treatment device

By filtering air impurities through a filter screen and absorbent cotton, and stirring the antibacterial agent solution with a servo motor, the atomizer atomizes and directs the airflow for penetration, the problem of uneven antibacterial agent treatment is solved, improving the antibacterial effect of the fabric and the operability of the equipment.

CN224378481UActive Publication Date: 2026-06-19CHANGXING HONGFENG PRINTING & DYEING

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHANGXING HONGFENG PRINTING & DYEING
Filing Date
2025-07-11
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing antibacterial agent atomization treatment devices lack effective control over the treatment environment, causing impurities and moisture in the air to enter the antibacterial agent, affecting its effectiveness. Furthermore, the antibacterial agent solution is prone to stratification or uneven concentration, resulting in uneven treatment and failure to fully penetrate into the fabric fibers.

Method used

The system uses a filter screen and absorbent cotton to filter impurities and moisture from the air. The antibacterial agent solution is stirred by a spiral stirring rod driven by a servo motor. The solution is atomized into tiny particles by an atomizer and then evenly penetrated into the fabric fibers by a directional airflow. Combined with a meshing gear structure, the fabric is stretched evenly.

Benefits of technology

It ensures clean air, prevents solution stratification and uneven concentration, achieves uniform penetration and full contact of antibacterial agents, improves the antibacterial treatment effect of fabrics, and the equipment is easy to operate and maintain.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224378481U_ABST
    Figure CN224378481U_ABST
Patent Text Reader

Abstract

The utility model discloses an antibacterial agent atomization processing device belongs to textile technical field, it includes processing box, the inside center of processing box is equipped with the tensile structure, the tensile structure includes six stretchers, six the stretchers are respectively arranged two as a group in the upper and lower, three groups the stretchers are arranged respectively in the inside two sides of processing box upper and the inside center of processing box lower, six the stretchers end part respectively penetrates the inside wall of processing box front and rear wall and reaches the front end and rear end of processing box, and the end part all is fixedly connected with first gear, in addition, the utility model discloses, through the filtration of the large particle impurity, tiny impurity and moisture in air, ensure that the air that enters the processing box is relatively clean, and, through the stirring antibacterial agent solution, prevent solution stratification or concentration uneven, simultaneously, can let antibacterial agent atomization particle even permeate to the fabric fiber with atomization or gaseous form, has improved antibacterial agent and the contact evenness and fullness of fabric.
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Description

Technical Field

[0001] This utility model belongs to the field of textile technology, specifically an antibacterial agent atomization treatment device. Background Technology

[0002] Antimicrobial agents are chemical substances that can inhibit or kill bacteria, fungi, and other microorganisms. In fabric treatment, antimicrobial agents are used to impart antimicrobial properties to fabrics, thereby improving the hygiene standards and durability of products. Common antimicrobial agents include silver ions, copper ions, and organosilicon quaternary ammonium salts. Devices that convert antimicrobial agent solutions into tiny droplets are also used. Common types of atomizers include ultrasonic atomizers, compressed air atomizers, and high-pressure nozzle atomizers.

[0003] Existing antibacterial agent atomization treatment devices have the following main shortcomings:

[0004] The existing antibacterial agent atomization treatment devices lack effective control over the treatment environment, which allows impurities and moisture in the air to enter the antibacterial agent, affecting its effectiveness. Furthermore, the antibacterial agent solution may be layered or uneven in concentration, resulting in inconsistent treatment effects and an inability to achieve uniform distribution of the antibacterial agent on the fabric, leading to unsatisfactory treatment results. At the same time, the antibacterial agent may not be able to fully penetrate into the fabric fibers, affecting the antibacterial effect. Utility Model Content

[0005] To overcome the above-mentioned defects, this utility model provides an antibacterial agent atomization treatment device, which solves the problems in the prior art.

[0006] To achieve the above objectives, the present invention provides the following technical solution: an antibacterial agent atomization treatment device, comprising: a treatment box, wherein a stretching structure is provided at the center of the interior of the treatment box;

[0007] The tensioning structure includes six tensioning rods, which are arranged in pairs, one above the other. The three groups of tensioning rods are respectively located on the upper sides of the inside of the processing box and on the lower side of the center of the processing box. The two ends of the six tensioning rods pass through the front inner wall and the rear inner wall of the processing box and extend to the front and rear ends of the processing box, respectively, and each end is fixedly connected to a first gear.

[0008] The processing box has a feeding and discharging structure at the lower center of both sides of the side wall, an antibacterial agent atomization structure at the front and rear center of the end face of the processing box, and an antibacterial agent atomization spraying structure at the upper center of the rear end face of the processing box.

[0009] As a further embodiment of this utility model: the two feeding and discharging structures include four connecting plates, which are respectively arranged at the front and rear ends of the lower side walls of the processing box. The two rear connecting plates are each provided with a first servo motor at the center of their rear end faces. The output ends of the two first servo motors pass through the rear end faces of the two rear connecting plates and extend to the front end faces of the two rear connecting plates, and each end is fixedly connected to a material roller.

[0010] As a further embodiment of this utility model: the two antibacterial agent atomization treatment structures include two air inlet frames, which are respectively located at the front and rear of the center of the upper end face of the treatment box. Two lifting boxes are arranged vertically at the upper center of each of the two air inlet frames, and a filter screen is provided at the center of the upper center of each of the two lifting boxes.

[0011] As a further embodiment of this utility model: the antibacterial agent atomizing spraying structure includes an antibacterial agent flow box, which is located at the upper center of the rear end face of the processing box. A second servo motor is provided at the center of the upper end face of the antibacterial agent flow box. The output end of the second servo motor passes through the upper end face of the antibacterial agent flow box and extends into the interior of the antibacterial agent flow box, and a spiral stirring rod is fixedly connected to its end.

[0012] As a further embodiment of this utility model: atomizers are provided on both sides of the center of the lower inner wall of the antibacterial agent flow box, and a delivery pipe is provided at the output end of each of the two atomizers. The output ends of the two delivery pipes pass through the rear inner wall of the antibacterial agent flow box and the rear end face of the treatment box to the interior of the treatment box. Multiple atomizing nozzles are arranged in a front-to-back pattern on the lower side of the center of one side wall of each of the two delivery pipes. A water inlet is provided on one side of the center of the upper end face of the antibacterial agent flow box.

[0013] As a further embodiment of this utility model: absorbent cotton is provided at the center of the interior of the two lower-positioned carrying boxes, and a fan is provided at the center of the interior of the two air inlet frames. One end of each of the four carrying boxes passes through the inner side wall of the two air inlet frames and extends to one side wall of the two carrying boxes.

[0014] As a further embodiment of this utility model: threaded holes are provided at the center of the front end face and the center of the rear end face of the six tension rods, and limit blocks are rotatably connected to the center of the six threaded holes. The three sets of first gears are all meshed with each other.

[0015] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0016] 1. This utility model utilizes a layered filter screen and absorbent cotton within the air inlet frame to filter large particles, small impurities, and moisture from the air, ensuring relatively clean air entering the treatment chamber. Furthermore, a second servo motor drives a spiral stirring rod to agitate the antibacterial agent solution, preventing stratification or uneven concentration. Simultaneously, an atomizer outputs the solution through a delivery pipe, and the antibacterial agent is atomized into fine particles via an atomizing nozzle. A fan generates airflow within the treatment chamber, creating a directional airflow that allows the atomized antibacterial agent particles to penetrate evenly into the fabric fibers in atomized or gaseous form. This improves the uniformity and sufficiency of contact between the antibacterial agent and the fabric, thereby enhancing the antibacterial treatment effect on the fabric.

[0017] 2. This utility model uses a three-set intermeshing first gear structure to connect six tension rods. When one tension rod rotates, it drives the other tension rods to rotate synchronously through the first gear transmission, thereby stretching the fabric. Threaded holes are provided at the ends of the tension rods, and they are connected to the limit blocks by screws. During the stretching process, the relative position of the tension rod and the first gear is kept fixed, ensuring that the two intermeshing first gears can evenly distribute the force on the fabric, avoiding damage to the fabric due to uneven stretching. Furthermore, when the equipment needs to be disassembled and adjusted, the operation is more convenient and quick, improving the efficiency and operability of equipment maintenance. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of the present invention. Figure 1 ;

[0019] Figure 2 This is a schematic diagram of the overall structure of the present invention. Figure 2 ;

[0020] Figure 3 This is a side sectional view of the present invention.

[0021] Figure 4 This is a three-dimensional split-structure diagram of the stretching structure of this utility model.

[0022] In the diagram: 1. Processing box; 2. Feeding and discharging structure; 201. Connecting plate; 202. First servo motor; 203. Material roller; 3. Tensioning structure; 301. Tensioning rod; 302. First gear; 303. Limiting block; 304. Threaded hole; 4. Antibacterial agent atomization treatment structure; 401. Air inlet frame; 402. Lifting box; 403. Filter screen; 404. Absorbent cotton; 405. Fan; 5. Antibacterial agent atomization spraying structure; 501. Antibacterial agent flow box; 502. Second servo motor; 503. Spiral stirring rod; 504. Atomizer; 505. Conveying pipe; 506. Atomizing nozzle. Detailed Implementation

[0023] The technical solution of this patent will be further described in detail below with reference to specific embodiments.

[0024] like Figures 1-4 As shown, this utility model provides a technical solution:

[0025] An antibacterial agent atomization treatment device, comprising:

[0026] The processing box 1 has a tension structure 3 at its center. The tension structure 3 includes six tension rods 301, which are arranged in pairs, one above the other. The three sets of tension rods 301 are located on the upper sides and lower center of the processing box 1, respectively. The two ends of the six tension rods 301 pass through the front and rear inner walls of the processing box 1 and lead to the front and rear ends of the processing box 1, respectively. Each end is fixedly connected to a first gear 302. The center of the front and rear faces of the six tension rods 301 are provided with threaded holes 304. The center of each of the six threaded holes 304 is screwed to a limit block 303. The three sets of first gears 302 are meshed with each other.

[0027] With three sets of meshing first gears 302, when one tension rod 301 rotates, the other meshing tension rods 301 will rotate synchronously, causing the limiting block 303 to rotate as well. The limiting block 303 is threadedly connected to the threaded hole 304, ensuring that the relative position of the tension rod 301 and the first gear 302 is fixed. This also facilitates disassembly and adjustment when needed, making it convenient for stretching the fabric. The two meshing first gears 302 ensure that the fabric is stretched evenly during the stretching process.

[0028] The two sides of the processing box 1 are equipped with feeding and discharging structures 2 at the lower center of each side wall. Each feeding and discharging structure 2 includes four connecting plates 201. The four connecting plates 201 are respectively located at the front and rear ends of the lower side walls of the processing box 1. The two rear connecting plates 201 are equipped with a first servo motor 202 at the center of their rear end faces. The output ends of the two first servo motors 202 pass through the rear end faces of the two rear connecting plates 201 and extend to the front end faces of the two rear connecting plates 201. The ends of the two first servo motors 202 are fixedly connected to material rollers 203. By starting the two first servo motors 202, the two material rollers 203 are driven to rotate. The rotation of the material rollers 203 can control the material to enter and exit the processing box 1. The material enters from the feed port on one side of the processing box 1 and exits from the discharge port on the other side, thereby realizing the transfer and exchange of materials inside and outside the processing box 1.

[0029] The treatment box 1 has antibacterial agent atomization structures 4 located at the front and rear of the center of its end face. Each antibacterial agent atomization structure 4 includes two air inlet frames 401, located at the front and rear of the center of the upper end face of the treatment box 1, respectively. Inside each air inlet frame 401, two vertically arranged carrying boxes 402 are positioned at the upper center. The upper carrying boxes 402 have filters 403 at their center, while the lower carrying boxes 402 have absorbent cotton 404 at their center. A fan 405 is located inside each air inlet frame 401. One end of each of the four carrying boxes 402 passes through an inner wall of one of the two air inlet frames 401 and leads to the two carrying boxes 402. 2. On one side wall, by starting the fan 405, air is drawn into the air intake frame 401. After the air enters, it passes through the filter screen 403 in the upper box 402, which can filter out large particulate impurities in the air. Then it flows through the absorbent cotton 404 in the lower box 402, which absorbs small impurities and moisture in the air, making the air entering the treatment box 1 relatively clean. The wind generated by the fan 405 forms a directional airflow in the treatment box 1. Under the action of the airflow, the antibacterial agent atomized particles sprayed from the antibacterial agent atomizing spray structure 5 can penetrate evenly into the fabric fibers in atomized or gaseous form, thereby achieving antibacterial treatment of the fabric.

[0030] An antibacterial agent atomizing spraying structure 5 is provided at the upper center of the rear end face of the treatment box 1. The antibacterial agent atomizing spraying structure 5 includes an antibacterial agent flow box 501, which is located at the upper center of the rear end face of the treatment box 1. A second servo motor 502 is provided at the center of the upper end face of the antibacterial agent flow box 501. The output end of the second servo motor 502 passes through the upper end face of the antibacterial agent flow box 501 and leads to the interior of the antibacterial agent flow box 501. A spiral stirring rod 503 is fixedly connected to the end of the second servo motor 502. Atomizers 504 are provided at both sides of the lower inner wall of the antibacterial agent flow box 501. The output ends of the two atomizers 504 are provided with conveying pipes 505. The output ends of the two conveying pipes 505 pass through the rear inner wall of the antibacterial agent flow box 501 and lead to the interior of the treatment box 1. Multiple atomizing nozzles 506 are arranged in a front-to-back pattern at the lower center of one side wall of the two conveying pipes 505. A water inlet is provided at one side of the center of the upper end face of the antibacterial agent flow box 501.

[0031] When antibacterial agent atomization spraying is required, the second servo motor 502 is started to drive the spiral stirring rod 503 to rotate. The spiral stirring rod 503 rotates inside the antibacterial agent flow box 501, which can stir the antibacterial agent solution entering the antibacterial agent flow box 501 evenly, preventing the antibacterial agent from stratifying or having uneven concentration. Furthermore, by starting the atomizer 504, the antibacterial agent solution in the antibacterial agent flow box 501 is output through the delivery pipe 505, and the antibacterial agent is atomized into tiny particles through the atomizing nozzle 506 at the output end of the delivery pipe 505. These tiny antibacterial agent particles come into full contact with the purified air and the processed materials in the treatment box 1, realizing the atomization treatment process of the antibacterial agent and achieving the expected treatment effect. At the same time, the antibacterial agent solution or cleaning water can be replenished through the water inlet to realize the continuous supply of antibacterial agent in the device or the cleaning and maintenance of the device.

[0032] The working principle of this utility model is as follows: When it is necessary to perform antibacterial agent atomization treatment on the fabric, the two first servo motors 202 are started to drive the two material rollers 203 to rotate. The rotating material rollers 203 control the material to enter and exit the processing box 1. The material can be pushed in from the feed port on one side of the processing box 1 by the rotation of the material rollers 203, and then discharged from the discharge port on the other side. In this way, the transfer and exchange of materials inside and outside the processing box 1 are realized.

[0033] When the fabric enters the processing box 1 and passes through the stretching rods 301, when one stretching rod 301 rotates, it drives the other stretching rod 301 to rotate synchronously through the meshing first gear 302. Since the center of the front and rear end faces of the stretching rod 301 is provided with a threaded hole 304, and the threaded hole 304 is screwed to the limiting block 303, the limiting block 303 rotates when the stretching rod 301 rotates. The function of the limiting block 303 is to ensure that the relative position of the stretching rod 301 and the first gear 302 is fixed. During the fabric stretching operation, the two meshing first gears 302 make the fabric evenly stressed, ensuring that the fabric is stretched evenly. In addition, when disassembly and adjustment are required, it is convenient to disassemble and separate the stretching rod 301 and the first gear 302.

[0034] When the antibacterial agent is sprayed, the second servo motor 502 drives the spiral stirring rod 503 to rotate inside the antibacterial agent flow box 501, stirring the antibacterial agent solution inside the flow box 501 evenly and preventing uneven concentrations such as stratification. Simultaneously, the atomizer 504 is activated, outputting the antibacterial agent solution from the flow box 501 through the delivery pipe 505. At the output end of the delivery pipe 505, the antibacterial agent is atomized into fine particles by the atomizing nozzle 506. During spraying, the fan 405 is activated, drawing air in from the air inlet frame 401. The air first passes through the filter screen 403 in the upper lifting box 402, which intercepts and filters large particles of impurities in the air. Then the air... The air flows through the absorbent cotton 404 in the lower box 402, which absorbs tiny impurities and moisture from the air. The clean air then enters the treatment chamber 1, and the airflow generated by the fan 405 forms a directional airflow within the treatment chamber 1. This directional airflow facilitates the uniform penetration of the antibacterial agent atomized particles sprayed by the subsequent antibacterial agent atomization spraying structure 5 into the fabric fibers in atomized or gaseous form, ultimately achieving antibacterial treatment of the fabric. These tiny antibacterial agent particles come into full contact with the purified air and the treated material within the treatment chamber 1, completing the atomization treatment of the antibacterial agent. In addition, the water inlet can replenish the antibacterial agent solution for continuous atomization treatment or inject cleaning water during device cleaning and maintenance.

[0035] Furthermore, the control method of this utility model is controlled by a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art. The power supply is also common knowledge in the art. Since this utility model is used to protect mechanical devices, the control method and circuit connection will not be explained in detail.

[0036] The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.

Claims

1. An antibacterial agent atomization treatment device, characterized in that, include: Processing box (1), wherein a tension structure (3) is provided at the center of the interior of the processing box (1); The tension structure (3) includes six tension rods (301). The six tension rods (301) are arranged in pairs, one above the other. The three groups of tension rods (301) are respectively located on the upper sides of the inside of the processing box (1) and the lower center of the inside of the processing box (1). The two ends of the six tension rods (301) pass through the front inner wall and the rear inner wall of the processing box (1) respectively, and are connected to the front end and the rear end of the processing box (1). The ends are all fixedly connected to the first gear (302). The processing box (1) has a feeding and discharging structure (2) located at the lower center of both sides of its side walls. The processing box (1) has an antibacterial agent atomizing treatment structure (4) located at the front and rear center of its end face. The processing box (1) has an antibacterial agent atomizing spraying structure (5) located at the upper center of its rear end face.

2. The antibacterial agent atomization treatment device according to claim 1, characterized in that: The two feeding and discharging structures (2) include four connecting plates (201). The four connecting plates (201) are respectively located at the front and rear ends of the lower side walls of the processing box (1). The rear two connecting plates (201) are each provided with a first servo motor (202) at the center of the rear end face. The output ends of the two first servo motors (202) pass through the rear end face of the two rear connecting plates (201) and extend to the front end face of the two rear connecting plates (201), and the ends are fixedly connected to material rollers (203).

3. The antibacterial agent atomization treatment device according to claim 1, characterized in that: The two antibacterial agent atomization treatment structures (4) include two air inlet frames (401). The two air inlet frames (401) are respectively located at the front and rear of the center of the upper end face of the treatment box (1). Two lifting boxes (402) are arranged vertically at the upper center of the two air inlet frames (401). A filter screen (403) is provided at the center of the upper center of the two lifting boxes (402).

4. The antibacterial agent atomization treatment device according to claim 1, characterized in that: The antibacterial agent atomizing spraying structure (5) includes an antibacterial agent flow box (501). The antibacterial agent flow box (501) is located at the upper center of the rear end face of the processing box (1). A second servo motor (502) is provided at the center of the upper end face of the antibacterial agent flow box (501). The output end of the second servo motor (502) passes through the upper end face of the antibacterial agent flow box (501) and extends into the interior of the antibacterial agent flow box (501). A spiral stirring rod (503) is fixedly connected to the end of the motor.

5. The antibacterial agent atomization treatment device according to claim 4, characterized in that: The antibacterial agent flow box (501) is equipped with atomizers (504) on both sides of the lower inner wall center. The output ends of the two atomizers (504) are equipped with delivery pipes (505). The output ends of the two delivery pipes (505) pass through the rear inner wall of the antibacterial agent flow box (501) and the rear end face of the treatment box (1) to the interior of the treatment box (1). Multiple atomizing nozzles (506) are arranged in a front-to-back pattern on one side of the center of the two delivery pipes (505). The antibacterial agent flow box (501) is equipped with a water inlet on one side of the center of the upper end face.

6. The antibacterial agent atomization treatment device according to claim 3, characterized in that: The two lower-positioned carrying boxes (402) are each provided with absorbent cotton (404) at their center, and the two air inlet frames (401) are each provided with a fan (405) at their center. One end of each of the four carrying boxes (402) passes through an inner wall of one of the two air inlet frames (401) and leads to a side wall of one of the two carrying boxes (402).

7. The antibacterial agent atomization treatment device according to claim 1, characterized in that: Each of the six tension rods (301) has a threaded hole (304) at the center of its front end face and the center of its rear end face. Each of the six threaded holes (304) has a limit block (303) rotatably connected to its interior center. The three sets of first gears (302) are all meshed with each other.