A nanocoating plasma spray device

By designing an automatic storage component, the problem of manually storing material plates in existing devices has been solved, realizing the automatic storage of the substrate after spraying and improving processing efficiency.

CN224467889UActive Publication Date: 2026-07-07NEI MENG GU BAO GANG LV JIN SHENG TAI JIAN SHE YOU XIAN ZE REN GONG SI

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NEI MENG GU BAO GANG LV JIN SHENG TAI JIAN SHE YOU XIAN ZE REN GONG SI
Filing Date
2025-07-28
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing nano-coating processing equipment cannot automatically store the coated plates, resulting in manual operation that consumes manpower and affects coating efficiency.

Method used

A nano-coating plasma spraying device was designed, comprising legs, support frame, drive roller, belt, spraying assembly and storage assembly. The sprayed substrate is transported to the stacking rack by the drive roller and belt driven by the motor, and the stacking rack is used to achieve automatic storage.

Benefits of technology

It enables automatic storage of the coated substrate, saving manpower and improving the efficiency of board processing.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of substrate surface treatment technology, and more particularly to a nano-coating plasma spraying device. This utility model provides a nano-coating plasma spraying device that can store sprayed substrates, saving manpower and improving the efficiency of sheet material processing. A nano-coating plasma spraying device includes legs, a support frame, and baffles. The legs have two sections, front and rear, with the support frame connected between them in the middle. Baffles are connected to the upper parts of each leg. This utility model uses a second motor to drive a transmission roller and belt to rotate and transport the sprayed substrate to the right, causing the substrate to move to the right onto the partition block of a stacking rack. Subsequently, the stacking rack moves downwards under gravity to allow the next sprayed substrate to be moved onto the stacking rack, achieving the effect of storing sprayed substrates, saving manpower, and improving the efficiency of sheet material processing.
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Description

Technical Field

[0001] This utility model relates to the field of substrate surface treatment technology, and in particular to a nano-coating plasma spraying device. Background Technology

[0002] Nanocoating technology offers significant advantages in improving substrate surface properties, such as enhanced wear resistance, corrosion resistance, and thermal stability. Plasma spraying is a commonly used method for preparing nanocoatings, which involves melting a powder substrate with a high-temperature, high-speed plasma jet and spraying it onto the substrate surface to form a coating. The following is a design overview of a nanocoating plasma spraying apparatus.

[0003] A health nano-coating processing device, disclosed in CN217432049U, includes a support frame and a material plate. Rollers are rotatably mounted at both ends of the support frame, and a conveyor belt is positioned between the rollers. Horizontal plates are spaced along the conveyor belt, on which the material plate can be placed. A first motor is mounted on the support frame, and its output is connected to the rollers. A connecting frame is located at the top of the support frame, and a receiving box is located on one side of the connecting frame. An air extraction fan is mounted on the receiving box, and a spring tube with a suction port is located at the bottom of the receiving box. A cleaning component is rotatably mounted on the connecting frame and connected to the suction port. A storage box containing nano-liquid is located on the side of the connecting frame opposite the receiving box. A second motor is mounted on the storage box, and a pipe is located at the bottom of the storage box, with a spray head at the bottom of the pipe. This invention, by incorporating a cleaning component, wipes away residual touch marks and impurities on the material plate, resulting in a clean and aesthetically pleasing surface after the nano-liquid is sprayed onto the material plate. However, this device cannot store the coated material plate after it has been coated. After the material plate is coated, it needs to be removed and stored manually, which consumes manpower and affects the efficiency of nano-coating.

[0004] Therefore, a nano-coating plasma spraying device has now been developed that can store the sprayed substrate, saving manpower and improving the efficiency of board processing. Utility Model Content

[0005] To overcome the shortcomings of existing nano-coating processing devices, which cannot store the coated substrate and require manual removal after coating, thus wasting manpower and affecting the efficiency of nano-coating, this invention provides a nano-coating plasma spraying device that can store the coated substrate, saving manpower and improving the processing efficiency of the substrate.

[0006] The technical solution of this utility model is: a nano-coating plasma spraying device, including legs, a support frame, baffles, belts, transmission rollers, a second motor, a spraying component, and a storage component. The legs are front and rear, and the support frame is connected between the middle of the legs. Baffles are connected to the upper part of each leg. Two transmission rollers are rotatably connected between the baffles. A belt is wound between the transmission rollers. The front leg is connected to the upper left front side of the front leg. The output shaft of the second motor is connected to the transmission roller on the left side. The support frame is equipped with a spraying component capable of spraying nano-coatings. A storage component capable of storing the sprayed substrate is provided between the legs.

[0007] Furthermore, the spraying assembly includes a first motor, a worm gear, a connecting frame, a worm wheel, and a plasma spray gun. The first motor is connected to the inner side of the upper front part of the support frame. The worm gear is connected to the output shaft of the first motor. The worm gear is rotatably connected to the support frame. The connecting frame is connected to the worm gear. The plasma spray gun is rotatably connected to the connecting frame. The worm wheel is connected to the plasma spray gun. The worm wheel meshes with the worm gear.

[0008] Furthermore, the first motor, the second motor, and the processor are electrically connected via a control module.

[0009] Furthermore, the storage components include a base plate, elastic elements, a sliding plate, and a stacking rack. The base plate is connected between the right sides of the legs, and the sliding plate is slidably connected to the base plate. The legs are all slidably connected to the sliding plate. Multiple elastic elements are connected between the sliding plate and the base plate, and the stacking rack is snapped onto the upper side of the sliding plate.

[0010] Furthermore, the elastic element is a spring.

[0011] Furthermore, the stacking rack is equipped with multiple partitions at both the front and rear.

[0012] The beneficial effects are: by starting the second motor, the transmission roller and belt are driven to rotate and transport the coated substrate to the right, so that the substrate moves to the right onto the partition block of the stacking rack. Then the stacking rack moves downward under the action of gravity, so that the next coated substrate can be moved onto the stacking rack. This achieves the effect of storing the coated substrate, saving manpower and improving the efficiency of board processing. Attached Figure Description

[0013] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0014] Figure 2 This is a three-dimensional structural cross-sectional view of the structural legs, support frame, and other components of this utility model.

[0015] Figure 3 This is a three-dimensional structural diagram of the stacking rack, sliding plate, and other components of this utility model.

[0016] Figure 4 This is a three-dimensional structural diagram of the worm gear, worm wheel, and other components of this utility model.

[0017] In the attached diagram, the following are the reference numerals: 1-support leg, 2-support frame, 3-baffle, 4-belt, 5-drive roller, 6-first motor, 7-worm gear, 8-connecting frame, 9-worm wheel, 10-plasma spray gun, 11-base plate, 12-spring, 13-sliding plate, 14-stacking rack, 15-second motor. Detailed Implementation

[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0019] A nano-coating plasma spraying device, such as Figures 1-4 As shown, it includes support legs 1, support frame 2, baffles 3, belts 4, transmission rollers 5, a second motor 15, a spraying assembly, and a storage assembly. The support legs 1 have two legs, front and rear, and the support frame 2 is connected between the middle of the support legs 1. The upper part of each support leg 1 is connected to a baffle 3. The left and right transmission rollers 5 are rotatably connected between the baffles 3. The belt 4 is wound between the transmission rollers 5. The upper left front of the front support leg 1 is connected to the second motor 15. The output shaft of the second motor 15 is connected to the transmission roller 5 on the left. The support frame 2 is equipped with a spraying assembly, and the support legs 1 are equipped with a storage assembly.

[0020] like Figures 1-4 As shown, the spraying assembly includes a first motor 6, a worm gear 7, a connecting frame 8, a worm wheel 9, and a plasma spray gun 10. The first motor 6 is connected to the inner side of the upper front part of the support frame 2. The first motor 6, the second motor 15, and the processor are electrically connected through a control module. The worm gear 7 is connected to the output shaft of the first motor 6. The worm gear 7 is rotatably connected to the support frame 2. The connecting frame 8 is connected to the worm gear 7. The plasma spray gun 10 is rotatably connected to the connecting frame 8. The worm wheel 9 is connected to the plasma spray gun 10. The worm wheel 9 meshes with the worm gear 7.

[0021] like Figures 1-3 As shown, the storage assembly includes a base plate 11, elastic elements, a sliding plate 13, and a stacking rack 14. The base plate 11 is connected between the right sides of the support legs 1. The sliding plate 13 is slidably connected to the base plate 11. All support legs 1 are slidably connected to the sliding plate 13. Four elastic elements, which are springs 12, are connected between the sliding plate 13 and the base plate 11. The stacking rack 14 is snapped onto the upper side of the sliding plate 13. The stacking rack 14 has five partition blocks at both the front and rear to facilitate the separation of the base.

[0022] When using this utility model, first place the support leg 1 in the substrate surface treatment area, then place the substrate to be coated with nano-coating on the belt 4. The processor starts the first motor 6 through the control module, drives the worm gear 7 to rotate, causing the connecting frame 8 to rotate, which in turn drives the plasma spray gun 10 to swing left and right. While the worm gear 7 rotates, it meshes with the worm wheel 9, causing the plasma spray gun 10 to swing back and forth, and then the plasma spray gun 10 sprays the material onto the substrate surface to form a nano-coating.

[0023] After the coating is completed, the processor starts the second motor 15 through the control module, which drives the transmission roller 5 and belt 4 to rotate and transport the coated substrate to the right. This causes the substrate to move to the right onto the partition block of the stacking rack 14. Then, the stacking rack 14 moves downward under the action of gravity, the sliding plate 13 moves downward, and the spring 12 is compressed and contracted, so that the next coated substrate can move onto the stacking rack 14. This allows the coated substrate to be stored, saving manpower and improving the efficiency of board processing. When the stacking rack 14 is full, it can be removed from the sliding plate 13 for replacement.

[0024] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the scope of the claims.

Claims

1. A nano-coating plasma spraying device, characterized in that: It includes a support leg (1), a support frame (2), a baffle (3), a belt (4), a transmission roller (5), a second motor (15), a spraying assembly, and a storage assembly. The support leg (1) has two legs, front and back. The support frame (2) is connected between the middle of the support leg (1). The baffle (3) is connected to the upper part of the support leg (1). The left and right transmission rollers (5) are rotatably connected between the baffles (3). The belt (4) is wound between the transmission rollers (5). The second motor (15) is connected to the upper left front side of the front support leg (1). The output shaft of the second motor (15) is connected to the transmission roller (5) on the left side. The support frame (2) is equipped with a spraying assembly that can spray nano-coating. The support leg (1) is equipped with a storage assembly that can store the sprayed substrate.

2. The nano-coating plasma spraying device according to claim 1, characterized in that: The spraying assembly includes a first motor (6), a worm (7), a connecting frame (8), a worm wheel (9), and a plasma spray gun (10). The first motor (6) is connected to the inner side of the upper front part of the support frame (2). The worm (7) is connected to the output shaft of the first motor (6). The worm (7) is rotatably connected to the support frame (2). The connecting frame (8) is connected to the worm (7). The plasma spray gun (10) is rotatably connected to the connecting frame (8). The worm wheel (9) is connected to the plasma spray gun (10). The worm wheel (9) meshes with the worm (7).

3. The nano-coating plasma spraying device according to claim 2, characterized in that: The first motor (6), the second motor (15), and the processor are electrically connected through the control module.

4. The nano-coating plasma spraying device according to claim 1, characterized in that: The storage components include a base plate (11), elastic elements, a sliding plate (13), and a stacking rack (14). The base plate (11) is connected between the right sides of the legs (1). The sliding plate (13) is slidably connected to the base plate (11). The legs (1) are all slidably connected to the sliding plate (13). Multiple elastic elements are connected between the sliding plate (13) and the base plate (11). The stacking rack (14) is snapped onto the upper side of the sliding plate (13).

5. The nano-coating plasma spraying device according to claim 4, characterized in that: The elastic element is a spring (12).

6. The nano-coating plasma spraying device according to claim 4, characterized in that: The stacking rack (14) has multiple partition blocks at both the front and back.