Automotive interior anti-fingerprint coating ion plating equipment

By setting up a rotating device and a high vacuum environment in the coating machine, the problem of uneven coating caused by uneven heating of the interior substrate is solved, and uniform heating and high-quality coating of the interior substrate are achieved.

CN224430697UActive Publication Date: 2026-06-30烟台海心新材料科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
烟台海心新材料科技有限公司
Filing Date
2025-05-28
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In the prior art, uneven coating occurs in automotive interior substrates due to uneven heating during the coating process.

Method used

A rotating device is used to drive the interior substrate to rotate, and combined with a heating source and a high vacuum environment, a high-energy positive ion deposition film is formed through the arc discharge of the cathode and anode, ensuring uniform heating of the substrate.

Benefits of technology

It achieves uniform heating of the interior substrate, avoids uneven coating, and improves coating quality.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224430697U_ABST
    Figure CN224430697U_ABST
Patent Text Reader

Abstract

This utility model provides an ion plating processing equipment for anti-fingerprint coating of automotive interior materials, relating to the field of anti-fingerprint film processing technology. The utility model includes a plating machine, which is placed on the ground to provide overall support. A cover plate is rotatably connected to one side of the plating machine via a hinge, covering the plating chamber. A heating source is installed in the plating chamber. A control box is located outside the plating machine, and its surface has several buttons, some of which control the plating machine and the heating source. A rotating device is located inside the plating chamber, rotating the interior substrate within it. The rotating device includes a motor. This utility model achieves the effect of rotating the interior substrate through the rotating device, ensuring uniform heating and preventing uneven heating that could lead to uneven coating.
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Description

Technical Field

[0001] This utility model relates to the field of anti-fingerprint film processing technology, and in particular to coating processing equipment. Background Technology

[0002] Anti-fingerprint films are mainly used in automotive coatings. The coating surface can reduce the adhesion of fingerprints and various stains, prevent the screen from being contaminated by fingerprints or other stains and reduce visibility, and the stains that have already adhered can also be easily removed.

[0003] In existing technologies, when coating automotive interiors, the coating machine uses resistance heating to raise the temperature of the coating chamber to the required range to ensure the thermodynamic conditions necessary for film growth. However, the location of the resistance heating source is fixed, which leads to uneven heating of the interior substrate inside the coating chamber, resulting in uneven coating of the interior substrate. Utility Model Content

[0004] This utility model proposes an ion plating equipment for anti-fingerprint coating of automotive interiors to overcome the shortcomings of existing technologies.

[0005] To achieve the above objectives, this utility model adopts the following technical solution: an automotive interior anti-fingerprint coating ion plating processing equipment, including a coating machine, which is placed on the ground to provide overall support. A cover plate is rotatably connected to one side of the coating machine via a hinge, wherein the cover plate can cover the coating chamber of the coating machine. A heating source is installed in the coating chamber of the coating machine. A control box is located on the outside of the coating machine, and the surface of the control box is provided with several buttons, some of which can control the coating machine and the heating source. A rotating device is located inside the coating chamber of the coating machine, wherein the rotating device can rotate the interior substrate in the coating chamber.

[0006] The effect achieved by the above components is as follows: When coating the interior substrate, the operator places the interior substrate into the coating chamber of the coating machine. Then, the operator rotates the cover plate to cover the coating chamber. The operator operates the coating machine and the heating source through the control box. The heating source heats the interior substrate inside the coating chamber. At the same time, the rotating device drives the interior substrate to rotate, so that the interior substrate can be heated evenly. Finally, a high vacuum environment is formed between the cathode target and the anode inside the coating machine, triggering the electrode starter to separate the cathode and the anode, forming a stable arc discharge. Local atoms of the target are ionized into high-energy positive ions. These positive ions are deposited on the surface of the substrate to form a film layer.

[0007] Preferably, the rotating device includes a motor, which is mounted on the top of the coating machine. The motor is fixedly connected to a rotating shaft via a reducer. The rotating shaft is located inside the coating chamber of the coating machine. A support plate is fixedly connected to the arc surface of the rotating shaft. The cross-section of the support plate is cross-shaped. Four mounting plates are rotatably connected to one side of the support plate. Two mounting holes are opened on the surface of the mounting plate. An auxiliary device is provided inside the mounting hole. The auxiliary device can be detachably installed on the interior substrate.

[0008] The effect achieved by the above components is as follows: When the coating machine is working, the operator turns on the motor, and the motor drives the rotating shaft to rotate through the reducer. The rotating shaft rotates the support plate and the mounting plate. The interior substrate inside the mounting hole of the mounting plate rotates, so that the heating source can heat the interior substrate evenly. The rotating device achieves the effect of rotating the interior substrate, so that the interior substrate can be heated evenly, avoiding uneven heating of the interior substrate, which would lead to uneven coating.

[0009] Preferably, a gear is fixedly connected to one end of the mounting plate, and a gear ring is fixedly connected inside the coating chamber of the coating machine, wherein the gear and the gear ring mesh with each other.

[0010] The effect achieved by the above components is as follows: when the mounting plate rotates around the rotating shaft, the gear on the mounting plate moves inside the gear ring, and the gear ring rotates with the gear and the mounting plate, so that the position between the interior substrate on the mounting plate and the rotating shaft changes continuously, thereby improving the heat uniformity of the interior substrate.

[0011] Preferably, a triangular plate is fixedly connected to the upper surface of the support plate, wherein one inclined side of the triangular plate is fixedly connected to the rotating shaft.

[0012] The effect achieved by the above components is that the stability between the rotating shaft and the support plate is improved by setting the triangular plate, thus preventing the support plate from shaking.

[0013] Preferably, a bearing is provided at one end of the rotating shaft, wherein the outer ring of the bearing is fixedly connected to the coating chamber of the coating machine, and the inner ring of the bearing is fixedly connected to the rotating shaft.

[0014] The effect achieved by the above components is to improve the stability of the shaft rotation by setting bearings, and to prevent the shaft from shaking.

[0015] Preferably, the auxiliary device includes a cylinder, which is installed on the inner wall of the mounting hole of the mounting plate, wherein a base plate is fixedly connected to the inner wall of the other side of the mounting hole, and a clamping plate is fixedly connected to the output end of the cylinder.

[0016] The aforementioned components achieve the following effect: When it is necessary to install the interior substrate, the worker first places the interior substrate on the base plate, then opens the cylinder, and the cylinder moves the clamping plate. Finally, the clamping plate and the base plate together squeeze the interior substrate, achieving the effect of fixing the interior substrate. The auxiliary device achieves the effect of fixing the interior substrate, and at the same time, it facilitates the disassembly of the interior substrate after the coating is completed, bringing convenience to the workers.

[0017] Preferably, the cylinder is electrically connected to some of the buttons on the surface of the control box.

[0018] The effect achieved by the above components is that when the cylinder needs to be operated, the operator can operate the cylinder through the buttons on the control box, which brings convenience to the operator.

[0019] Preferably, a rubber pad is fixedly connected to the upper surface of the base plate, wherein the size of the rubber pad is adapted to the size of the base plate.

[0020] The effect achieved by the above-mentioned components is that the rubber pads protect the interior substrate, preventing the plywood and floorboards from damaging the interior substrate.

[0021] In summary, the beneficial effects of this utility model are as follows:

[0022] When coating interior substrates, workers place the substrates into the coating chamber of the coating machine. Then, they rotate the cover to cover the coating chamber and operate the coating machine and heating source through the control box. The heating source heats the interior substrates inside the coating chamber, while the rotating device drives the substrates to rotate, ensuring uniform heating. Finally, a high vacuum environment is formed between the cathode target and the anode inside the coating machine, triggering the electrode starter to separate the cathode and anode, forming a stable arc discharge. Local atoms of the target are ionized into high-energy positive ions, which are deposited on the surface of the substrate to form a film. Attached Figure Description

[0023] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0024] Figure 2 This is a three-dimensional structural diagram of the rotating device of this utility model;

[0025] Figure 3 This is a three-dimensional structural diagram of the mounting plate of this utility model;

[0026] Figure 4 This utility model Figure 3 Enlarged view of point A.

[0027] Legend: 1. Coating machine; 2. Heating source; 3. Control box; 4. Rotating device; 41. Motor; 42. Support plate; 43. Mounting plate; 44. Mounting hole; 45. Rotating shaft; 46. Gear; 47. Gear ring; 48. Bearing; 49. Triangular plate; 5. Auxiliary device; 51. Cylinder; 52. Clamping plate; 53. Base plate; 54. Rubber pad. Detailed Implementation

[0028] Reference Figure 1-4 As shown, this embodiment discloses an ion plating processing equipment for anti-fingerprint coating of automotive interior materials, including a coating machine 1, which is placed on the ground to provide support for the whole. A cover plate is rotatably connected to one side of the coating machine 1 via a hinge, wherein the cover plate can cover the coating chamber of the coating machine 1; a heating source 2 and a control box 3, wherein the heating source 2 is installed in the coating chamber of the coating machine 1, and the control box 3 is located on the outside of the coating machine 1. The surface of the control box 3 is provided with several buttons, some of which can control the coating machine 1 and the heating source 2; and a rotating device 4, which is located inside the coating chamber of the coating machine 1, wherein the rotating device 4 can rotate the interior substrate in the coating chamber. When coating the interior substrate, the operator places the interior substrate into the coating chamber of the coating machine 1. Then, the operator rotates the cover plate to cover the coating chamber. The operator operates the coating machine 1 and the heating source 2 through the control box 3. The heating source 2 heats the interior substrate inside the coating chamber. At the same time, the rotating device 4 drives the interior substrate to rotate, so that the interior substrate can be heated evenly. Finally, a high vacuum environment is formed between the cathode target and the anode inside the coating machine 1, triggering the electrode starter to separate the cathode and the anode, forming a stable arc discharge. Local atoms of the target are ionized into high-energy positive ions. These positive ions are deposited on the surface of the substrate to form a film layer.

[0029] Reference Figure 1-4 As shown, the rotating device 4 includes a motor 41, which is mounted on top of the coating machine 1. The motor 41 is fixedly connected to a rotating shaft 45 via a reducer. The rotating shaft 45 is located inside the coating chamber of the coating machine 1. A support plate 42 is fixedly connected to the arc surface of the rotating shaft 45. The support plate 42 has a cross-section in the shape of a cross. Four mounting plates 43 are rotatably connected to one side of the support plate 42. Two mounting holes 44 are formed on the surface of each mounting plate 43. An auxiliary device 5 is installed inside each mounting hole 44, allowing for the detachable installation of the interior trim substrate. When the coating machine 1 is operating, the operator turns on the motor 41. The motor 41 drives the rotating shaft 45 to rotate via the reducer. The rotating shaft 45 rotates the support plate 42 and the mounting plates 43, causing the interior trim substrate inside the mounting holes 44 of the mounting plates 43 to rotate. This allows the heating source 2 to heat the interior trim substrate evenly. The rotating device 4 achieves the effect of rotating the interior trim substrate, ensuring even heating and preventing uneven heating that could lead to uneven coating.

[0030] Reference Figure 1-4 As shown, a gear 46 is fixedly connected to one end of the mounting plate 43, and a gear ring 47 is fixedly connected inside the coating chamber of the coating machine 1, wherein the gear 46 and the gear ring 47 mesh with each other. When the mounting plate 43 rotates around the rotating shaft 45, the gear 46 on the mounting plate 43 moves inside the gear ring 47, and the gear ring 47 rotates the gear 46 and the mounting plate 43, causing the position between the interior substrate on the mounting plate 43 and the rotating shaft 45 to change continuously, thereby improving the heat uniformity of the interior substrate. A triangular plate 49 is fixedly connected to the upper surface of the support plate 42, wherein one inclined side of the triangular plate 49 is fixedly connected to the rotating shaft 45. By setting the triangular plate 49, the stability between the rotating shaft 45 and the support plate 42 is improved, and the support plate 42 is prevented from shaking. A bearing 48 is provided at one end of the rotating shaft 45, wherein the outer ring of the bearing 48 is fixedly connected to the coating chamber of the coating machine 1, and the inner ring of the bearing 48 is fixedly connected to the rotating shaft 45. By setting bearing 48, the stability of the rotation of shaft 45 is improved, and the shaking of shaft 45 is prevented.

[0031] Reference Figure 1-4 As shown, the auxiliary device 5 includes a cylinder 51, which is installed on the inner wall of the mounting hole 44 of the mounting plate 43. A base plate 53 is fixedly connected to the inner wall of the other side of the mounting hole 44, and a clamping plate 52 is fixedly connected to the output end of the cylinder 51. When the interior trim substrate needs to be installed, the worker first places the interior trim substrate on the base plate 53, then opens the cylinder 51. The cylinder 51 moves the clamping plate 52, and finally, the clamping plate 52 and the base plate 53 together press the interior trim substrate, achieving the effect of fixing the interior trim substrate. The auxiliary device 5 achieves the effect of fixing the interior trim substrate and facilitates the disassembly of the interior trim substrate after the coating is completed, providing convenience for the workers.

[0032] Reference Figure 1-4 As shown, cylinder 51 is electrically connected to some buttons on the surface of control box 3. When cylinder 51 needs to be operated, the operator can operate it through the buttons on control box 3, which is convenient for the operator. A rubber pad 54 is fixedly connected to the upper surface of base plate 53, and the size of rubber pad 54 is adapted to the size of base plate 53. By setting rubber pad 54, the interior trim substrate is protected, preventing the clamping plate 52 and base plate 53 from damaging the interior trim substrate.

[0033] Working principle: When coating the interior substrate, the operator places the substrate into the coating chamber of the coating machine 1. The operator then rotates the cover plate to cover the coating chamber. The operator controls the coating machine 1 and the heating source 2 via the control box 3. The heating source 2 heats the interior substrate inside the coating chamber. The operator turns on the motor 41, which drives the rotating shaft 45 to rotate via a reducer. The bearing 48 at one end of the rotating shaft 45 improves the stability of its rotation. The rotating shaft 45 rotates along with the support plate 42 and the mounting plate 43. The interior substrate inside the mounting hole 44 of the mounting plate 43 rotates around the rotating shaft 45. The gear 46 on the mounting plate 43 moves inside the gear ring 47. The gear ring 47 rotates, carrying the gear 46 and the mounting plate 43, causing the position of the interior substrate on the mounting plate 43 and the rotating shaft 45 to change continuously. This allows the heating source 2 to heat the interior substrate evenly. Finally, a high vacuum environment is formed between the cathode target and the anode inside the coating machine 1, triggering the electrode starter to separate the cathode and the anode, forming a stable arc discharge. Local atoms of the target are ionized into high-energy positive ions. These positive ions are deposited on the surface of the substrate to form a film. The rotating device 4 achieves the effect of rotating the interior substrate, allowing it to be heated evenly and avoiding uneven heating of the interior substrate, which would lead to uneven coating.

[0034] When it is necessary to install the interior substrate, the staff first places the interior substrate on the base plate 53, and then opens the cylinder 51 by pressing the button on the control box 3. The cylinder 51 moves the clamping plate 52, and finally the clamping plate 52 and the base plate 53 together use the rubber pad 54 to squeeze the interior substrate, thereby achieving the effect of fixing the interior substrate. The auxiliary device 5 achieves the effect of fixing the interior substrate, and at the same time facilitates the disassembly of the interior substrate after the coating is completed, which brings convenience to the staff.

Claims

1. An ion plating equipment for anti-fingerprint coating on automotive interior surfaces, characterized in that: The coating machine (1) is placed on the ground to provide support for the whole. A cover plate is rotatably connected to one side of the coating machine (1) by a hinge, wherein the cover plate can cover the coating chamber of the coating machine (1). A heating source (2) and a control box (3) are provided. The heating source (2) is installed in the coating chamber of the coating machine (1). The control box (3) is located on the outside of the coating machine (1). The surface of the control box (3) is provided with several buttons, some of which can control the coating machine (1) and the heating source (2). A rotating device (4) is installed inside the coating chamber of the coating machine (1), wherein the rotating device (4) can rotate the interior substrate in the coating chamber.

2. The automotive interior anti-fingerprint coating ion plating equipment according to claim 1, characterized in that: The rotating device (4) includes a motor (41), which is installed on the top of the coating machine (1). The motor (41) is fixedly connected to a rotating shaft (45) by means of a reducer. The rotating shaft (45) is located inside the coating chamber of the coating machine (1). A support plate (42) is fixedly connected to the arc surface of the rotating shaft (45). The cross section of the support plate (42) is in the shape of a cross. Four mounting plates (43) are rotatably connected to one side of the support plate (42). Two mounting holes (44) are opened on the surface of the mounting plate (43). An auxiliary device (5) is provided inside the mounting hole (44). The auxiliary device (5) can be detachably installed on the interior substrate.

3. The automotive interior anti-fingerprint coating ion plating equipment according to claim 2, characterized in that: A gear (46) is fixedly connected to one end of the mounting plate (43), and a gear ring (47) is fixedly connected inside the coating chamber of the coating machine (1), wherein the gear (46) and the gear ring (47) mesh with each other.

4. The automotive interior anti-fingerprint coating ion plating equipment according to claim 2, characterized in that: A triangular plate (49) is fixedly connected to the upper surface of the support plate (42), wherein one inclined side of the triangular plate (49) is fixedly connected to the rotating shaft (45).

5. The automotive interior anti-fingerprint coating ion plating equipment according to claim 2, characterized in that: One end of the rotating shaft (45) is provided with a bearing (48), wherein the outer ring of the bearing (48) is fixedly connected to the coating chamber of the coating machine (1), and the inner ring of the bearing (48) is fixedly connected to the rotating shaft (45).

6. The automotive interior anti-fingerprint coating ion plating equipment according to claim 2, characterized in that: The auxiliary device (5) includes a cylinder (51), which is installed on the inner wall of the mounting hole (44) of the mounting plate (43), wherein a base plate (53) is fixedly connected to the inner wall of the other side of the mounting hole (44), and a clamping plate (52) is fixedly connected to the output end of the cylinder (51).

7. The automotive interior anti-fingerprint coating ion plating equipment according to claim 6, characterized in that: The cylinder (51) is electrically connected to some of the buttons on the surface of the control box (3).

8. The automotive interior anti-fingerprint coating ion plating equipment according to claim 6, characterized in that: A rubber pad (54) is fixedly connected to the upper surface of the base plate (53), wherein the size of the rubber pad (54) is adapted to the size of the base plate (53).