KR102195944B1 - Exhaust gas controlled coating and deposition system - Google Patents

Abstract

The present invention relates to an exhaust device-controlled coating and deposition system. According to the present invention, the exhaust device-controlled coating and deposition system comprises: a spindle conveyor driving device; a first coating line having a first ionizer, a first spray unit, and a first dryer; a deposition line; a second coating line having a second ionizer, a second spray unit, and a second dryer; reliability test equipment; an exhaust device; and an intelligent coating and deposition control device. According to the present invention, the reliability of a product can be improved.

Description

Exhaust control type coating and deposition system {EXHAUST GAS CONTROLLED COATING AND DEPOSITION SYSTEM}

The present application relates to an exhaust controlled coating and deposition system.

Cosmetic containers are manufactured in various shapes capable of accommodating cosmetics in internal accommodation spaces such as cylinders and square pillars, and are manufactured in various sizes according to usages such as portable, sample, or capacity.

These cosmetic containers are painted in various colors according to the nature and design of the cosmetics to improve aesthetics and prevent scratches (gloss). At this time, in general, a cosmetic container is mounted on a spindle conveyor in which a rotating spindle is formed at regular intervals, first passes through an ionizing booth, etc. to remove static electricity and foreign substances on the surface, and is primarily directed toward the rotating product. After passing through a coating booth spraying the UV coating liquid, passing through a drying booth to be dried through a drying device, metal is deposited using an evaporator. After the deposition process, a coating process is performed again to prevent abrasion of the product surface and give a color or gloss effect.

Conventionally, a uniform coating and deposition process has been performed regardless of the shape and size of cosmetics, and even when the shape and size of cosmetics are considered, the setting of each equipment while the operator directly manages the line performing each process. There was an inconvenience of having to manipulate the state.

In addition, since defect inspection is performed after all processes are performed, there is a problem in that even products with potential for improvement during the process often become defective products as a result, thereby increasing the defect rate.

The technology behind the present application is disclosed in Korean Patent Application Publication No. 10-1650866.

The present application is to solve the problems of the prior art described above, and an object of the present invention is to provide an exhaust system controlled coating and deposition system capable of performing a suitable coating process or the like according to the shape and size of the product.

The present application is to solve the problems of the prior art described above, and it is possible to prevent an intermediate defective product (or a temporary defective product) with a possibility of improvement before the coating and deposition process is completed, eventually becoming defective after the process is completed. It is an object to provide an exhaust system controlled coating and deposition system.

The present application is to solve the problems of the prior art described above, and an object of the present invention is to provide an exhaust system controlled coating and deposition system for discharging exhaust gas generated during the coating and painting process of a cosmetic container.

However, the technical problem to be achieved by the embodiments of the present application is not limited to the technical problems as described above, and other technical problems may exist.

As a technical means for achieving the above technical problem, as an exhaust system controlled coating and deposition system according to an embodiment of the present application, a spindle that rotates a jig coupled to a spindle conveyor and drives a spindle conveyor to move along an extended line Conveyor driving device, a first ionizer to remove foreign substances from the product coupled to the jig, a first spray unit to base-coat the product by spraying paint toward the product, and a first dryer to dry the base-coated product The provided first coating line, a deposition line equipped with an evaporator that performs a vacuum deposition process on a product bonded to the jig by inserting the jig bar on which the jig is mounted, a second deposition line that removes foreign matter from the product bonded to the jig A second coating line provided with an ionizer, a second spray unit for top-coating the product by spraying paint toward the product, and a second dryer for drying the top-coated product, the first coating line, the deposition line, and Reliability testing equipment for testing the reliability of a product on which a process corresponding to at least one of the second coating lines has been performed, the first ionizer and the first spray unit, the second ionizer and the second spray unit, The operation of the spindle conveyor driving device and the first coating line based on product information and product information and a measurement result measured by the reliability test equipment and an exhaust device installed oppositely to inhale harmful gas and exhaust gas through a purification device. And an intelligent coating and deposition control device for controlling at least one operation of devices provided in the deposition line and the second coating line, wherein the intelligent coating and deposition control device comprises the It is possible to control for controlling the drive of the exhaust system.

In addition, the exhaust device includes a suction duct and a suction fan, performs a primary filter through a preprocessor, and exhausts the gas through a purification device that adsorbs the coating liquid, and the intelligent coating and deposition control device includes the Driving of the exhaust device may be controlled in consideration of a control signal for an operation of at least one of devices provided in the first coating line, the deposition line, and the second coating line.

In addition, the intelligent coating and deposition control device adjusts at least one of a spindle rotation speed and a movement speed of the spindle conveyor based on the size information of the product among the product information, but the spindle rotation as the size of the product increases. The spindle conveyor drive may be controlled to increase the speed or decrease the moving speed.

In addition, the spray unit includes a plurality of sprays provided spaced apart at predetermined intervals along the longitudinal direction of the spindle conveyor, and the intelligent coating and deposition control device includes the product information based on the shape information of the product. The spraying angle of the spray unit may be adjusted, and the spray units may be controlled so that the spray angles of the plurality of sprays are differently adjusted for each group by grouping the plurality of sprays according to a preset range for the length of the product.

In addition, the reliability test equipment measures the thickness of the coating film on the product on which the base coating process of the first coating line has been performed, and the intelligent coating and deposition control device is based on the measurement result received from the reliability test equipment. , When the coating film thickness falls within the first reference range, the second spray unit is controlled to increase the spraying speed of the second spray unit, and when the coating film thickness falls within the second reference range, the base coating of the first coating line The spindle conveyor driving device may be controlled to repeat the base coating process of the first coating line once more for the product on which the process has been performed.

In addition, the reliability test equipment measures the degree of wear of the coating film on the product on which the top coating process of the second coating line has been performed, and the intelligent coating and deposition control device is based on the measurement result received from the reliability test equipment. , When the degree of wear of the coating film is within a predetermined range of defects, the spindle conveyor driving device may be controlled to move to a defect inspection line for a product on which the top coating process of the second coating line has been performed.

In addition, the reliability testing equipment, when it is determined by the intelligent coating and deposition control device to be within a preset normal range, the coating film wear resistance is further measured for the product on which the top coating process of the second coating line has been performed, and , The intelligent coating and deposition control device controls the spindle conveyor driving device to move to the packaging line when the coating film wear resistance is within a preset normal range, based on the measurement result received from the reliability testing equipment, and the coating film wear resistance is in advance. In the case of a set defect range, the spindle conveyor driving device may be controlled to move to a defect inspection line.

In addition, the reliability testing equipment further comprises a UV irradiation meter for measuring the UV irradiation amount of the first dryer and the second dryer, the intelligent coating and deposition control device, the measurement result received from the UV irradiation meter Based on this, the UV irradiation amount of the first dryer and the second dryer may be adjusted, or the moving speed of the spindle conveyor may be adjusted.

In addition, the intelligent coating and deposition control device, when the UV irradiation amount is less than a preset UV irradiation amount in connection with the product information of the product, the first dryer and the second dryer to increase the UV irradiation amount. Controls the spindle conveyor driving device to reduce the movement speed of the spindle conveyor to control the 1 dryer and the second dryer, or to reduce the movement speed of the spindle conveyor, and the UV irradiation amount is associated with the product information of the product and is relatively In many cases, the first dryer and the second dryer may be controlled to reduce the UV irradiation amount of the first dryer and the second dryer, or the spindle conveyor driving device may be controlled to increase the moving speed of the spindle conveyor. I can.

In addition, the intelligent coating and deposition apparatus, the receiving unit for receiving the product information and the measurement result measured by the reliability test equipment; A database unit for storing the product information and reference information on the measurement result; A determination unit for determining by comparing the product information and the measurement result with the reference information; And a control unit for controlling an operation of the spindle conveyor driving device and at least one of devices provided in the first coating line, the deposition line, and the second coating line based on the comparison and determination result. I can.

The above-described problem solving means are merely exemplary and should not be construed as limiting the present application. In addition to the above-described exemplary embodiments, additional embodiments may exist in the drawings and detailed description of the invention.

According to the above-described problem solving means of the present application, by controlling the operation of various devices provided in the spindle conveyor, the coating line, and the deposition line based on the size information or shape information of the product, a coating process suitable therefor according to the shape and size of the product There is an effect that can be achieved.

According to the above-described problem solving means of the present application, by controlling the operation of various devices provided in the spindle conveyor, the coating line, and the deposition line based on the result of measuring the reliability of the finished product, the reliability or defect rate of the product There is an effect of improving.

However, the effect obtainable in the present application is not limited to the effects as described above, and other effects may exist.

1 is a schematic configuration diagram of an exhaust system controlled coating and deposition system according to an embodiment of the present application.
2 is a block diagram illustrating a schematic configuration of an exhaust system controlled coating and deposition system according to an embodiment of the present disclosure.
3 is a schematic diagram showing a coating line of an exhaust system controlled coating and deposition system according to an embodiment of the present disclosure.
4 is a schematic diagram illustrating various examples in which the spraying angle of the spray unit of the exhaust system controlled coating and deposition system is adjusted according to an exemplary embodiment of the present disclosure.
5 is a view showing the flow of a process performed by the exhaust control type coating and deposition system according to an embodiment of the present application.
6 is a schematic block diagram of an intelligent coating and deposition control device of an exhaust system controlled coating and deposition system according to an embodiment of the present disclosure.

Hereinafter, exemplary embodiments of the present application will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present application. However, the present application may be implemented in various different forms and is not limited to the embodiments described herein. In addition, in the drawings, parts not related to the description are omitted in order to clearly describe the present application, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the present specification, when a part is said to be "connected" with another part, it is not only "directly connected", but also "electrically connected" or "indirectly connected" with another element interposed therebetween. "Including the case.

Throughout this specification, when a member is positioned "on", "upper", "upper", "under", "lower", and "lower" of another member, this means that a member is located on another member. It includes not only the case where they are in contact but also the case where another member exists between the two members.

Throughout the specification of the present application, when a certain part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

The present application relates to a system for performing a coating and deposition process as a painting operation on various primary molded metal and non-metal products, and may be applied to a cosmetic container as an example. At this time, the cosmetic container includes a container body having a space in which the cosmetics are accommodated, and a cap that can be separated and combined with the body, and is combined with the body to block the opened part of the body from the outside. It is desirable to understand it as a concept.

In addition, since techniques and various facilities commonly performed in the art can be applied to the coating process and deposition process of the present application, detailed descriptions of specific methods of performing each process and specific operations of various facilities performing the same will be omitted. To

In addition, it goes without saying that detailed processes may be added or omitted as necessary in the coating process and the deposition process performed by the present application.

1 is a schematic configuration diagram of an exhaust system controlled coating and deposition system 1 according to an embodiment of the present application, and shows a schematic configuration of an exhaust system controlled coating and deposition system 1 according to an embodiment of the present application It is a block diagram for betting.

1 and 2, the exhaust system controlled coating and deposition system 1 according to an embodiment of the present application includes a first coating line 20, a deposition line 30, and a second coating line 40 do. In addition, referring to FIG. 1, the first coating line 20 and the second coating line 40 each include an ionizing booth, a spray booth, an exhaust device, and a drying booth, and the products undergoing coating and deposition processes are It can be moved to the ionizing booth, spray booth, and drying booth through the spindle conveyor (C). Here, each booth may mean a space that is divided or conceptually divided due to physical partitions, and different processes (detailed processes) may be performed in each booth.

Referring to FIG. 2, an exhaust system controlled coating and deposition system 1 according to an embodiment of the present disclosure includes a spindle conveyor driving device 10. The spindle conveyor driving device 10 rotates the jig coupled to the spindle conveyor C and moves the spindle along the extended line (eg, the first coating line 20, the second coating line 40, etc.). It is possible to drive the conveyor (C).

More specifically, the spindle conveyor driving apparatus 10 may drive the spindle conveyor C so that a jig coupled (mounted) to the spindle and a product coupled to the jig rotate by rotating the spindle provided at predetermined intervals. Here, the spindle provided at a predetermined interval may be referred to differently as a spindle line.

In addition, the spindle conveyor driving device 10 is a line (for example, the first coating line 20, the second coating line (for example, the first coating line 20) and the second coating line ( 40) It is possible to drive the spindle conveyor (C) to move the spindle line along).

On the other hand, the operation of the spindle conveyor driving device 10 may be controlled by the intelligent coating and deposition control device 60 to be described later, but a more detailed description in this regard will be described later.

Referring to FIG. 1, the spindle conveyor C and the spindle conveyor driving device 10 may be provided for the first coating line 20 and the second coating line 40, respectively. In addition, the spindle conveyor C may be provided to sequentially pass through an ionizing booth, a spray booth, and a drying booth provided in the first coating line 20 and the second coating line 40. In this case, the product coupled to the spindle conveyor C first goes through an ionizing step in an ionizing booth, then a coating step in a spray booth, and then a drying step in a drying booth.

Meanwhile, referring to FIG. 2, a first ionizer 210, a first spray unit 220, a first dryer 230, and a first exhaust device 240 may be provided in the first coating line 20. have. In addition, a second ionizer 410, a second spray unit 420, a second dryer 430, and a second exhaust device 440 may be provided in the second coating line 40.

The first ionizer 210 and the second ionizer 420 remove foreign substances from the product coupled to the jig. The first ionizer 210 and the second ionizer 420 may be provided in the ionizing booth of the first coating line 20 and the ionizing booth of the second coating line 40, respectively.

The first ionizer 210 and the second ionizer 420 may mean a plurality of ionizer guns. A plurality of ionizer guns may be provided on one side of the spindle conveyor C passing through the ionizing booth at predetermined intervals along the traveling direction of the conveyor. A plurality of ioni guns are coupled to the spindle conveyor (C) to inject ionized air at high pressure toward the rotating product (P), whereby static electricity and foreign matter on the surface of the product (P) can be removed. .

In addition, the first spray unit 220 sprays the paint toward the product coupled to the jig to base coating the product, and the second spray unit 420 sprays the paint toward the product coupled to the jig. It is Top Coating. The first spray unit 220 and the second spray unit 420 may be provided in the spray booth of the first coating line 20 and the spray booth of the second coating line 40, respectively.

According to an exemplary embodiment of the present disclosure, a first exhaust device 240 may be provided in an area facing each other at a position where the first ionizer 210 and the first spray unit 220 are installed. In addition, a second exhaust device 420 may be provided in an area opposite to the second ionizer 410 and the second spray unit 420 at the installed position.

The first exhaust device 240 and the second exhaust device 420 may be devices including a suction fan in a suction duct. The first exhaust device 240 and the second exhaust device 420 may suck air in which foreign substances including dust and charged particles floating and flying by a plurality of ionizers are sprayed.

Meanwhile, FIG. 3 is a schematic diagram showing a coating line of the exhaust system controlled coating and deposition system 1 according to an exemplary embodiment of the present disclosure. More specifically, FIG. 3 is a view showing a part of a spray booth of an exhaust system controlled coating and deposition system 1 according to an embodiment of the present disclosure.

Referring to FIG. 3, the spray unit (the first spray unit 220 and the second spray unit 420) includes a plurality of sprays spaced apart at predetermined intervals along the length direction of the spindle conveyor C. I can. Here, the longitudinal direction of the spindle conveyor C may mean a direction in which the spindle conveyor C travels. In other words, a plurality of sprays may be provided on one side of the spindle conveyor C passing through the spray booth at predetermined intervals along the traveling direction of the conveyor. Meanwhile, a plurality of sprays may be provided in the form of, for example, a spray gun, but are not limited thereto, and may be provided in various forms.

A plurality of sprays (spray guns) are coupled to the spindle conveyor (C) to spray paint such as UV coating liquid toward the rotating product (P), whereby the paint can be coated on the surface of the product (P). . In this case, the plurality of sprays included in the first spray unit 220 may spray paint for the base coating, and the plurality of sprays included in the second spray unit 420 may spray paint for the top coating. have. Here, the paint for the base coating and the paint for the top coating can be selected according to each role (function) and product information (including customer's requirements or orders for products) among paints commonly used in the field. I can.

On the other hand, although not shown in FIG. 3, the first spray unit 220 and the second spray unit 420 have a vertical direction (a height direction or 12 o'clock-6 o'clock direction) of the injection ports of a plurality of sprays (spray guns). ) Or a driving device that can be adjusted in a horizontal direction (length direction or 9 o'clock-3 o'clock direction). The spraying angle of a plurality of sprays (spray guns) may be adjusted by such a driving device, and the driving device may be controlled by an intelligent coating and deposition control system 60 to be described later.

In addition, an exhaust device 70 may be provided in a direction opposite to the installation position of the plurality of sprays (spray guns). The exhaust device 70 may include a suction duct provided with a suction fan. The exhaust device 70 may inhale harmful substances (eg, harmful gases such as toluene) injected from a plurality of sprays (spray guns).

According to another embodiment of the present application, an exhaust device 70 including a collecting device (not shown) having a collecting unit in a direction opposite to the installation position of the plurality of spray guns in the area where the coating line proceeds may be provided. . Collection device (not shown) It may be to collect and collect the excess coating liquid scattered without being applied to the cosmetic container so that it can be reused. As an example, the collection device (not shown) may include a collection unit (not shown) for collecting coating liquid or paint sucked into the suction passage between the inlet of the suction duct and the suction fan. As another example, the collecting part (not shown) may have a structure in which a plurality of beads are rotatably formed on fixing pins arranged at regular intervals, but the present invention is not limited thereto.

In addition, the first dryer 230 dries the base-coated product, and the second dryer 430 dries the top-coated product. The first dryer 230 and the second dryer 430 may be provided in a drying booth of the first coating line 20 and a drying booth of the second coating line 40, respectively.

The drying booth may include an IR drying booth (IR Oven Room) equipped with an infrared dryer (eg, IR Oven) and a UV drying booth (UV Ramp Room) equipped with an ultraviolet dryer (eg, UV Ramp). have. That is, the product (P) coupled to the spindle conveyor (C) passes through the IR drying booth and the UV drying booth as the spindle conveyor (C) is driven, thereby being irradiated with infrared rays and ultraviolet rays, and thus drying can be performed. have.

Meanwhile, referring to FIG. 1, one or more evaporators may be provided in the deposition line 30. In the evaporator, a jig bar equipped with a jig is inserted to perform a vacuum deposition process on a product bonded to the jig.

In addition, the deposition line 30 may be provided between the first coating line 20 and the second coating line 40 in a process sequence (flow). That is, the jig to which all the processes of the first coating line 20 are combined is detached (separated) from the spindle line of the first coating line 20, and a plurality of jig is mounted (coupled) on the jig bar at a predetermined interval. In addition, a plurality of jig bars may be introduced into the evaporator, and as the evaporator is driven, a vacuum deposition process may be performed on a product coupled to the jig. After the vacuum deposition process is completed, the jig (a jig in which the product having completed the vacuum deposition process is bonded) can be detached (separated) from the jig bar and mounted (coupled) to the spindle line of the second coating line 40 , All processes of the second coating line 40 may be performed on the product coupled to the jig mounted on the spindle line of the second coating line 40.

Meanwhile, various jigs, jig bars, evaporators, and vacuum deposition techniques commonly used in the art may be applied to parts and devices such as jigs, jig bars, evaporators, and the like, and vacuum deposition techniques, and thus a more detailed description thereof will be omitted.

In addition, referring to FIG. 2 (not shown in FIG. 1 ), the exhaust system controlled coating and deposition system 1 according to an embodiment of the present disclosure may include a reliability test equipment 50. The reliability testing equipment 50 may test the reliability of a product on which a process corresponding to at least one of the first coating line 20, the deposition line 30, and the second coating line 40 has been performed.

Meanwhile, as described above, a first coating process corresponding to the first coating line 20, a deposition process corresponding to the deposition line 30, and a second coating process corresponding to the second coating line 40 are sequentially performed. Considering the progress, for example, testing the reliability of a product on which a process corresponding to the first coating line 20 is performed means that only the first coating process is performed, and the deposition process and the second coating process are performed. It means testing the reliability of the product in its pre-war state. In addition, testing the reliability of the product in which the process corresponding to the second coating line 40 has been performed means testing the reliability of the product in which the first coating process, the deposition process, and the second coating process have all been performed. Can mean that.

In addition, the reliability test equipment 50 may be, for example, a device for measuring the thickness of a coating film, a device for measuring the wear degree of the coating film, a device for measuring the wear resistance of the coating film, etc., but is not limited thereto, and It is desirable to understand it as a concept that includes a wide range of other measuring devices such as measuring instruments and sensors.

Meanwhile, the measurement result measured by the reliability test equipment 50 may be collected by the intelligent coating and deposition control device 60 to be described later.

1 and 2, an exhaust system controlled coating and deposition system 1 according to an embodiment of the present disclosure includes an intelligent coating and deposition control device 60. The intelligent coating and deposition control device 60 is based on the product information and the measurement result measured by the reliability test equipment 50, the operation of the spindle conveyor drive device 10, the first coating line 20, the deposition line ( 30) and at least one of the devices provided in the second coating line 40 may be controlled. Here, the devices provided in the first coating line 20, the deposition line 30, and the second coating line 40 may refer to the ionizer, spray (part), dryer, evaporator, etc. described above, but are limited thereto. It does not become.

In addition, the intelligent coating and deposition control device 60 is installed to face the first ionizer 210 and the first spray unit 220 and the second ionizer 240 and the second spray unit 420 It is possible to control the driving of the exhaust device 70 that sucks in and discharges gas through the purification device. The intelligent coating and deposition control device 60 may control the driving of the exhaust device 70 based on a preset amount of exhaust air. For example, the amount of air exhaust is set differently according to the type of the hood provided, and the intelligent coating and deposition control device 60 may set the amount of air exhaust in consideration of the type of the installed hood. Product information refers to information about a product that an orderer or customer has ordered (or requested) for coating and deposition. Product information may include product size information and shape information. The product shape information may include product length information. Here, the length (height) of the product may mean the direction of the rotation axis of the spindle when the product is coupled to the jig and then the jig is coupled (mounted) to the spindle. Referring to FIG. 3, the direction of the rotation axis of the spindle may be a vertical direction of the traveling direction of the spindle conveyor C.

Further, the shape information of the product may include overall shape information such as, for example, a square cylinder (rectangular column), a hexagonal cylinder (hexagonal column), and a cylinder (cylindrical shape).

The size information of the product may mean the width of a cross-sectional area cut in a direction perpendicular to the length direction of the product, or the distance from the rotation axis to the farthest part (point) of the product when the product is coupled to the jig and spindle. Referring to FIG. 3, for example, when the product P is cylindrical (cylindrical), the size information of the product P is the area of a circle with a cross-sectional area cut in a direction perpendicular to the length direction of the product P. It can mean the radius of a circle. That is, as the area of the circle increases or the radius of the circle increases, the size of the product increases. Also, as the size of the product increases, the time it takes for the product to rotate once increases.

Meanwhile, FIG. 6 is a schematic block diagram of an intelligent coating and deposition control apparatus 60 of an exhaust system controlled coating and deposition system 1 according to an exemplary embodiment of the present disclosure.

Referring to FIG. 6, the intelligent coating and deposition control apparatus 60 according to an embodiment of the present disclosure may include a receiving unit 610, a database unit 620, a determination unit 630, and a control unit 640.

The receiving unit 610 may receive product information and a measurement result measured by the reliability testing equipment 50. More specifically, product information may be input through an external user terminal (not shown), or information stored in an external user terminal (not shown) may be received through the receiving unit 610 of the intelligent coating and deposition control device 60 .

That is, the intelligent coating and deposition control device 60 may be connected to an external user terminal (not shown) and the reliability testing equipment 50 through a network to transmit and receive information such as product information and measurement results.

A network refers to a connection structure that enables information exchange between nodes such as terminals and servers, and examples of such networks include 3GPP (3rd Generation Partnership Project) networks, LTE (Long Term Evolution) networks, and 5G networks. Network, WIMAX (World Interoperability for Microwave Access) network, Internet, LAN (Local Area Network), Wireless LAN (Wireless Local Area Network), WAN (Wide Area Network), PAN (Personal Area Network), wifi network, Examples include, but are not limited to, a Bluetooth network, a satellite broadcasting network, an analog broadcasting network, and a Digital Multimedia Broadcasting (DMB) network. In addition, the user terminal (not shown) is, for example, a smart phone (Smartphone), a smart pad (SmartPad), a tablet PC, and PCS (Personal Communication System), GSM (Global System for Mobile communication), PDC (Personal Digital Cellular) , PHS (Personal Handyphone System), PDA (Personal Digital Assistant), IMT (International Mobile Telecommunication)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W-Code Division Multiple Access), Wibro (Wireless Broadband) Internet) may include all kinds of wireless communication devices such as terminals and wired communication devices such as desktop computers and smart TVs.

In addition, the intelligent coating and deposition control device 60 is at least one of the operation of the spindle conveyor drive device 10 and the devices provided in the first coating line 20, the deposition line 30, and the second coating line 40. A control signal for controlling one operation may be generated and transmitted to various devices including the spindle conveyor driving device 10 based on the network.

The database unit 620 may store product information and reference information on a measurement result measured by the reliability testing equipment 50. Here, the reference information is the operation of the spindle conveyor driving device 10 set in advance for the product information and the measurement result, or various types provided in the first coating line 20, the deposition line 30, and the second coating line 40. It may mean information about the operation of at least one of the devices.

More specifically, the reference information for product information may include information on a rotation speed or a moving speed of the spindle conveyor driving apparatus 10 set in advance according to the size information of the product. In addition, the reference information for product information may include information on grouping and spray angles of spray units (or a plurality of sprays) set in advance according to the shape information of the product.

In addition, the reference information for the measurement result measured by the reliability test equipment 50 is a reference range preset for measurement items (eg, thickness of the coating film, abrasion of the coating film, abrasion resistance of the coating film, etc.), the normal range and the defect. It may include at least one of the ranges.

Alternatively, the reference information on the measurement result measured by the reliability testing equipment 50 may include a reference measurement value (measurement value) preset in connection with product information for a measurement item (eg, UV irradiation, etc.) .

The determination unit 630 may determine product information and a measurement result measured by the reliability testing equipment 50 by comparing it with reference information. Specifically, it may be determined whether the product information received by the receiving unit 610 matches the product information of the reference information. In addition, it is determined whether the measurement result measured by the reliability testing equipment 50 received by the receiving unit 610 falls within a reference range, a normal range, or a defective range of the reference information, or the measurement result is a preset reference measurement value. You can determine whether it is greater or less, or more or less.

The control unit 640 determines the operation of the spindle conveyor driving device 10 and the first coating line 20, the deposition line 30, and the second coating line 40 based on the result of comparison and determination by the comparison unit 630. It is possible to control the operation of at least one of the devices provided in the.

Specifically, the control unit 640 includes the operation of the spindle conveyor driving apparatus 10 set in advance or the first coating line 20, the deposition line 30 and the reference information corresponding to the product information received by the receiving unit 610. The operation of the spindle conveyor driving device 10 or the first coating line 20, the deposition line 30, and the second coating line 20, the operation of the spindle conveyor driving device 10, to correspond to information on the operation of at least one of various devices provided in the second coating line 40. It is possible to control the operation of at least one of various devices provided in the coating line 40.

In addition, the control unit 640 may determine whether the measurement result measured by the reliability testing equipment 50 received by the receiving unit 610 falls within the reference range, the normal range, or the defective range. The operation or operation of at least one of various devices provided in the first coating line 20, the deposition line 30, and the second coating line 40 may be controlled differently.

In addition, the control unit 640 drives the spindle conveyor according to whether the measurement result measured by the reliability testing equipment 50 received by the receiving unit 610 is greater than (more) or less than (less) a preset reference measurement value. The operation of the device 10 or at least one of various devices provided in the first coating line 20, the deposition line 30, and the second coating line 40 may be controlled differently.

In addition, the control unit 640 may control the driving of the exhaust device 70 based on driving information of various devices provided in the first coating line 20, the deposition line 30, and the second coating line 40. have. In addition, the control unit 640 considers driving information of various devices provided in the first coating line 20, the deposition line 30, and the second coating line 40, and changes the driving method of the exhaust device 70. can do. For example, the driving method may include, but is not limited to, a driving time of the exhaust device 70, a pattern, a speed, a rotation speed of a suction fan, and a control wind speed of the hood.

It will be described in more detail below with respect to the control of the exhaust system control type coating and deposition system 1 of the intelligent coating and deposition control device 60 outlined above.

The intelligent coating and deposition control device 60 may adjust at least one of a spindle rotation speed and a movement speed of the spindle conveyor C based on product size information among product information. In this case, as the size of the product increases, the spindle conveyor driving device 10 may be controlled to increase the spindle rotation speed or decrease the moving speed.

For example, when the product is cylindrical (cylindrical), the size information of the product may be a radius. At this time, it can be seen that the larger the radius, the larger the size of the product. As the size of the product increases, the time it takes to rotate one round, that is, the time it takes to apply the paint to the entire product surface, increases. Accordingly, when the moving speed of the spindle conveyor C and the spraying speed of the paint (injection amount per unit time) are the same, the rotational speed of the spindle needs to increase as the size of the product increases.

That is, by increasing the spindle rotation speed as the size of the product increases, there is an effect that the paint can be applied the same number of times over the entire product surface regardless of the size of the product.

On the other hand, even if the paint is applied to the entire surface of the product the same number of times, the thickness of the coating film may be relatively thin as the size of the product increases if the spraying speed (the amount of spraying per unit time) of the paint is the same. The intelligent coating and deposition control device 60 reduces the moving speed of the spindle conveyor C, thereby increasing the time for spraying (applying) the paint to the same area of the product surface, thereby securing the desired thickness of the coating film. .

Therefore, the exhaust system-controlled coating and deposition system 1 according to an embodiment of the present application can automatically adjust the equipment so as to have a thickness of a coating film suitable for the size of the product in the coating process, and is uniform regardless of the size of the product. There is an effect of securing the coating film thickness.

In addition, the intelligent coating and deposition control device 60 may adjust the spray angles of the spray units 220 and 420 based on product shape information among product information. In this case, by grouping a plurality of sprays according to a preset range for the length of the product, the spray units 220 and 420 may be controlled to differently adjust the spray angles of the plurality of sprays for each group.

As described above, the shape information of the product may include length information of the product. In addition, information about grouping of the spray units 220 and 420 (or a plurality of sprays) and information about spray angles may be preset as reference information according to the length information of the product.

4 is a schematic diagram illustrating various examples in which spraying angles of the spray units 220 and 420 of the exhaust system-controlled coating and deposition system 1 are adjusted according to an embodiment of the present disclosure.

Referring to Figure 4 (a), for example, when the length of a product is more than a preset range, a plurality of sprays are grouped by three, and three spray angles are sprayed toward the area where the total length of the product is divided into three. Is set, and can be adjusted to have different spray angles for each group. That is, it can be understood that the spraying angle is changed for every three sprays, and the spraying angle can be alternately changed to three preset spraying angles.

As another example, referring to (b) of FIG. 4, when the length of the product is greater than or equal to a preset range, a plurality of sprays are grouped by three, and three spray angles are sprayed toward the area where the total length of the product is divided into three. Is set, and three sprays belonging to one group may be adjusted to each have the set three spray angles. That is, continuous sprays have different spraying angles, but can be adjusted to repeatedly have the same spraying angle for every three sprays.

Meanwhile, in the case of FIG. 4B, the number of grouped sprays and the number of preset spray angles may be the same.

On the other hand, in the above, a case in which a plurality of sprays are grouped by three and have three spray angles is illustrated, but the number of sprays grouped according to the length of the product and the number of preset spray angles are not limited thereto. It can be different.

For example, when the length of the product is greater than or equal to the first range (0.5 to 10 cm), two spray angles may be preset so that a plurality of sprays are respectively sprayed toward an area where the length of the product is divided into two, and the first range In the case of more than the second range (10 to 20 cm), three spray angles may be preset so that a plurality of sprays are respectively sprayed toward the area where the entire length of the product is divided into 3 parts.

According to the exemplary embodiment of the present disclosure, the intelligent coating and deposition control device 60 may control the driving of the exhaust device 70 based on the grouping and injection amount of the spray unit (or a plurality of sprays). For example, the intelligent coating and deposition control device 60 generates a first control signal to control the driving of the exhaust device 70 when the amount of injection sprayed from the spray unit (or a plurality of sprays) is more than a preset range. I can. On the other hand, the intelligent coating and deposition control device 60 can control the driving of the exhaust device 70 by generating a second control signal when the amount of injection sprayed from the spray unit (or a plurality of sprays) is less than a preset range. . As an example, the first control signal may have a higher rotational speed of the suction fan than the second control signal.

Meanwhile, the intelligent coating and deposition control device 60 compares the size information and shape information of the product received through the receiving unit 610 with reference information stored in the database unit 620 through the determination unit 630, and product information Based on the information on the operation of the spindle conveyor driving device 10 corresponding to (stored in association with product information) and the information on the operation of the spray units 220 and 420, the control unit 640 is the spindle conveyor driving device 10 ) And the operation of the spray units 220 and 420 can be controlled.

In addition, as described above, the intelligent coating and deposition control device 60 is based on the measurement result measured by the reliability testing equipment 50, the operation of the spindle conveyor driving device 10 and the first coating line 20, It is possible to control the operation of at least one of devices (eg, ionizer, spray (part), dryer, etc.) provided in the deposition line 30 and the second coating line 40.

The reliability test equipment 50 may measure the thickness of the coating film on the product on which the base coating process of the first coating line 20 has been performed. The reliability test equipment 50 measures the thickness of the coating film on the product that has passed through the spray booth of the first coating line 20 or the product that has passed through the drying booth of the first coating line 20. I can.

The intelligent coating and deposition control device 60 increases the spraying speed of the second spray unit 420 when the coating film thickness falls within the first reference range based on the measurement result received from the reliability test equipment 50. The second spray unit 420 may be controlled. In addition, the intelligent coating and deposition control device 60 performs the base coating process of the first coating line 20 on the product on which the process of the first coating line 20 is performed when the coating film thickness falls within the second reference range. The spindle conveyor drive device 10 can be controlled to repeat once more.

Here, the first reference range and the second reference range may be understood as concepts included in the aforementioned reference range. Also, the second reference range may be preset to be equal to or greater than the first reference range. For example, the first reference range may be 0.5 to 1 mm, and the second reference range may be preset to 1 to 1.5 mm. Also, the first reference range and the second reference range may be set differently according to product information in consideration of the coating thickness information and the error range of the product information.

5 is a view showing the flow of a process performed by the exhaust control type coating and deposition system according to an embodiment of the present application.

Referring to FIG. 5, the entire coating and deposition process performed by the exhaust system controlled coating and deposition system 1 according to an embodiment of the present disclosure is a first coating process and a deposition line corresponding to the first coating line 20. It can be seen that the deposition process corresponding to 30 and the second coating process corresponding to the second coating line 40 are sequentially performed.

That is, after the first coating process is performed first, the deposition process is performed, and then the second coating process is performed.

In consideration of this, the first reference range of the preset coating film thickness includes an error range of a level that can be adjusted to the desired coating film thickness only by the second coating process, and the second reference range includes both the first coating process and the second coating process. It can be understood to include an error range of a level that can be adjusted to a desired coating thickness by using.

In other words, the first reference range includes a fine error range capable of obtaining a desired coating film thickness by partially increasing the coating film thickness when performing the second coating process, and the second reference range requires the first coating process more. It can be understood to include a relatively large error range of the state.

Therefore, the intelligent coating and deposition control device 60 increases the spraying speed (spraying amount per unit time) of the second spraying unit 420 performing the second coating process when the coating film thickness falls within the first reference range. By performing the coating thicker, the desired thickness of the coating film can be met.

In addition, the intelligent coating and deposition control device 60 controls the spindle conveyor driving device 10 to repeat the first coating process once more when the coating film thickness falls within the second reference range, thereby measuring the coating film thickness again. In this case, it is possible to block the possibility of a defective product in advance by making it fall within the first reference range or a desired film thickness (coating film thickness range). (For reference, the desired coating thickness (coating thickness range) after performing the first coating process and the desired coating thickness (coating thickness range) after performing the second coating process mean different thicknesses.)

On the other hand, whether the coating film thickness falls within the first reference range or the second reference range can be determined by the determination unit 630 of the intelligent coating and deposition control device 60, and the spindle conveyor is driven based on the determination result. The operation of the device 10 or the second spray unit 420 may be controlled by the controller 640 of the intelligent coating and deposition control device 60.

In addition, the reliability testing equipment 50 may further include a UV irradiation meter measuring the UV irradiation amount of the first dryer 230 and the second dryer 430. Such a UV irradiation meter, for example, is provided in each of the drying booths of the first coating line and the second coating line in the UV Ramp Room to measure the amount of UV irradiation in the UV drying booth.

The intelligent coating and deposition control device 60 adjusts the UV irradiation amount of the first dryer 230 and the second dryer 430 based on the measurement result received from the UV irradiation meter, or the moving speed of the spindle conveyor C. Can be adjusted.

More specifically, the intelligent coating and deposition control device 60, when the UV irradiation amount is less than the preset UV irradiation amount in connection with the product information of the product P, the first dryer 230 and the second dryer 430 The first dryer 230 and the second dryer 430 may be controlled to increase the amount of UV irradiation, or the spindle conveyor driving device 10 may be controlled to reduce the moving speed of the spindle conveyor C.

In addition, when the UV irradiation amount is relatively large compared to the preset UV irradiation amount in connection with the product information of the product P, the first dryer to reduce the UV irradiation amount of the first dryer 230 and the second dryer 430 ( 230) and the second dryer 430 may be controlled, or the spindle conveyor driving apparatus 10 may be controlled to increase the moving speed of the spindle conveyor C.

For example, in the size information of the product information, the amount of UV irradiation required may increase as the size of the product increases. That is, as the size of the product increases, the preset UV irradiation amount may increase, and the preset UV irradiation amount in connection with such product information may also be understood as a concept included in the reference information described above.

The intelligent coating and deposition control device 60 increases the amount of UV irradiation per unit time of the first dryer 230 and the second dryer 430 in order to increase the amount of UV irradiation, or decreases the moving speed of the spindle conveyor C. By increasing the UV irradiation time, it is possible to increase the UV irradiation amount. Since a method of reducing the UV irradiation dose can be understood in the opposite direction, a detailed description will be omitted.

In other words, the intelligent coating and deposition control device 60 receives the UV irradiation amount measured from the UV irradiation meter through the receiving unit 610, and is linked to the product information as reference information stored in the database unit 620 and a preset UV irradiation amount The measured UV irradiation amount is compared with the determination unit 630, and the increase or decrease of the UV irradiation amount of the first dryer 230 and the second dryer 430 through the control unit 640 or of the spindle conveyor driving device 10 Movement speed can be adjusted.

In addition, the reliability testing equipment 50 may measure the degree of wear of the coating film on the product on which the top coating process of the second coating line 40 has been performed. Here, as an example of the reliability test equipment for measuring the degree of wear of the coating film, there is a rubbing tester.

The intelligent coating and deposition control device 60 is a product in which the top coating process of the second coating line 40 has been performed when the coating film wear degree is within a preset defective range based on the measurement result received from the reliability testing equipment 50 It is possible to control the spindle conveyor drive device 10 to move to the defect inspection line for. Here, the preset defect range can be understood as a concept included in the above-described reference information.

When the second coating line 40, that is, the wear of the coating film measured for the product completed up to the top coating process, falls within the defective range, the intelligent coating and deposition control device 60 moves the product to the defect inspection line to remove the defective product. Immediately separate and inspect, collect defective products together so that the cause of the defect can be identified. As a result, it is possible to prevent a phenomenon in which defective products are mixed into a normal product, and to further improve the quality of the next product through feedback of the identified cause of the defect.

In addition, when the wear degree of the coating film is determined to be within a preset normal range by the intelligent coating and deposition control device 60, the reliability testing equipment 50 is applied to the product on which the top coating process of the second coating line 40 is performed. The wear resistance can be further measured. Here, as an example of the reliability test equipment for measuring the wear resistance of the coating film, there is an RCA tester.

The intelligent coating and deposition control device 60 may control the spindle conveyor drive device 10 to move to the packaging line when the coating film wear resistance is within a preset normal range, based on the measurement result received from the reliability testing equipment 50. have. In addition, when the measured wear resistance of the coating film is within a preset defect range, the spindle conveyor driving device 10 may be controlled to move to the defect inspection line.

In other words, the receiving unit 610 receives the measurement result of measuring the wear resistance of the coating film for the product on which the top coating process of the second coating line 40 has been performed, and the determination unit 630 receives the coating film wear resistance in a preset normal range or It is determined whether it falls within the defective range, and the control unit 640 controls the spindle conveyor driving device 10 to move to the packaging line when the coating film wear resistance is within a preset normal range, and if the coating film wear resistance is within the preset defective range, it is defective. The spindle conveyor drive device 10 can be controlled to move to the inspection line. Here, the preset normal range and defective range can be understood as concepts included in the above-described reference information.

That is, only products with both coating wear and wear resistance in the normal range are moved to the packaging line, and even if the coating wear resistance is in the normal range, if the coating wear resistance is in the defective range, it is finally determined as a defective product and moves to the defect inspection line.

Referring to FIG. 5, in the intelligent coating and deposition control system according to an embodiment of the present application, a product in which all processes of the first coating line, the deposition line, and the second coating line are performed by the reliability test equipment 50. The degree of wear of the coating film and the degree of wear resistance of the coating film are measured, and based on the measurement result, the process is carried out by moving to a defect inspection line or a packaging line.

According to an embodiment of the present application, the quality and reliability of the product can be further improved by further measuring not only the wear resistance of the coating film, but also the wear resistance of the coating film, and the step-by-step reliability measurement process and the separation of defective products and genuine products are automated. Accuracy also increases.

According to one embodiment of the present application, the exhaust device 70 is installed to face the first ionizer 210 and the first spray unit 220 and the second ionizer 410 and the second spray unit 430 You can inhale harmful gas and exhaust the gas through a purification device. In addition, the exhaust device 70 may be driven by receiving a control signal generated based on a preset amount of air exhaust from the intelligent coating and deposition control device 60.

In addition, the exhaust device 70 may include a suction duct equipped with a suction fan. Further, the exhaust device 70 may perform a primary filter through a preprocessor. For example, the primary filter may be a UV filter. Also, the primary filter may be a bag filter. The bag filter may include a filter material, a support, a dust removal device, a dust hopper, a cell, a blower, and the like. In addition, the exhaust device 70 may exhaust gas (air) through an exhaust fan through an air purifier equipped with an adsorption tower for adsorbing the coating liquid.

For example, the exhaust device 70 may be provided on each of the first coating line and the second coating line. The exhaust device 70 may include a first exhaust device 240 provided in the first coating line and a second exhaust device 440 provided in the second coating line. In this case, the intelligent coating and deposition control device 60 may control the driving of the first exhaust device 240 in consideration of a control signal for controlling the operation of at least one of the devices provided in the first coating line. Meanwhile, the intelligent coating and deposition control device 60 may control the driving of the second exhaust device 440 in consideration of a control signal for controlling the operation of at least one of the devices provided in the second coating line. In other words, the intelligent coating and deposition control device 60 may control driving of a plurality of exhaust devices in consideration of the conditions of the coating line.

In addition, the exhaust and processing order of the exhaust device 70 may be performed in the order of a hood, a duct, a pre-processor (bag filter), an air purifier, an exhaust fan, and an exhaust, but is not limited thereto.

Meanwhile, the exhaust device 70 may include a plurality of sensors. The plurality of sensors can sense state information of components (components) included in the exhaust device 70. In addition, the plurality of sensors may sense the state information of the adsorption tower provided in the air purification device. The intelligent coating and deposition control device 60 may control the driving of the exhaust device 70 in consideration of a plurality of state information collected from a plurality of sensors included in the exhaust device 70. In addition, the intelligent coating and deposition control apparatus 60 may compare preset state information with collected state information, and provide an alarm message to a user terminal (not shown) when there is an abnormality between the preset state and the comparison result. .

In addition, the environmental information collection unit (not shown) may collect status information inside the ionizing booth, the spray booth, and the drying booth. The intelligent coating and deposition control device 60 may control the driving of the exhaust device 70 in consideration of state information inside a plurality of booths. For example, the environmental information collection unit (not shown) may collect information such as detection amount of harmful gas, temperature, humidity, amount of dust, and oxygen inside a plurality of booths. The intelligent coating and deposition control device 60 may control the driving of the exhaust device 70 in consideration of status information inside a plurality of booths collected by the environmental information collection unit (not shown).

The foregoing description of the present application is for illustrative purposes only, and those of ordinary skill in the art to which the present application pertains will be able to understand that it is possible to easily transform it into other specific forms without changing the technical spirit or essential features of the present application. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope of the present application is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present application.

1: Exhaust control type coating and deposition control system
10: spindle conveyor drive device
20: first coating line
30: evaporation line
40: second coating line
50: reliability testing equipment
60: intelligent coating and deposition control device
70: exhaust system

Claims (10)

As an exhaust system controlled coating and deposition system,
A spindle conveyor driving device for rotating the jig coupled to the spindle conveyor and driving the spindle conveyor to move along the extended line;
A first ionizer provided with a first ionizer to remove foreign matter from the product bonded to the jig, a first spray unit to base-coat the product by spraying paint toward the product, and a first dryer to dry the base-coated product Coating line;
A deposition line equipped with a vapor deposition device for performing a vacuum deposition process on a product bonded to the jig by inserting the jig bar on which the jig is mounted;
A second ionizer that removes foreign matter from the product bonded to the jig, a second spray unit that sprays paint toward the product to top coat the product, and a second dryer that dries the top-coated product. Coating line;
A reliability testing equipment for testing reliability of a product on which a process corresponding to at least one of the first coating line, the deposition line, and the second coating line has been performed;
An exhaust device installed to face the first ionizer and the first spray unit and the second ionizer and the second spray unit to inhale harmful gas and exhaust the gas through a purification device; And
Based on product information and measurement results measured by the reliability testing equipment, the operation of the spindle conveyor driving device and at least one operation of devices provided in the first coating line, the deposition line, and the second coating line Including an intelligent coating and deposition control device to control,
The reliability test equipment,
Measuring the coating film thickness of the product on which the base coating process of the first coating line was performed,
The intelligent coating and deposition control device,
Controls the driving of the exhaust system based on a preset amount of exhaust air, and increases the spraying speed of the second spray unit when the coating thickness falls within the first reference range based on the measurement result received from the reliability test equipment. So that the second spray part is controlled so that the base coating process of the first coating line is repeated once more for the product on which the base coating process of the first coating line has been performed when the thickness of the coating film falls within the second reference range. Controlling the spindle conveyor drive device, exhaust system controlled coating and deposition system. The method of claim 1,
The exhaust device,
Comprising a suction duct equipped with a suction fan, performing a primary filter through a preprocessor, and exhausting the gas through a purification device for adsorbing the coating liquid,
The intelligent coating and deposition control device,
To control the driving of the exhaust device in consideration of a control signal of an operation of at least one of devices provided in the first coating line, the deposition line, and the second coating line. The method of claim 1,
The intelligent coating and deposition control device,
Adjusting at least one of a spindle rotation speed and a moving speed of the spindle conveyor based on product size information among the product information,
Controlling the spindle conveyor drive device to increase the spindle rotation speed or decrease the moving speed as the size of the product increases. The method of claim 1,
The spray part,
It includes a plurality of sprays provided to be spaced apart at a predetermined interval along the longitudinal direction of the spindle conveyor,
The intelligent coating and deposition control device,
Adjust the spraying angle of the spray part based on the shape information of the product among the product information,
By grouping the plurality of sprays according to a preset range for the length of the product, the spray unit is controlled to differently adjust the spray angles of the plurality of sprays for each group. delete The method of claim 1,
The reliability test equipment,
Measure the wear of the coating film for the product on which the top coating process of the second coating line was performed,
The intelligent coating and deposition control device,
Based on the measurement result received from the reliability testing equipment, when the wear degree of the coating film is within a preset defective range, the spindle conveyor driving device is configured to move to a defect inspection line for the product on which the top coating process of the second coating line is performed Controlling an exhaust controlled coating and deposition system. The method of claim 6,
The reliability test equipment,
When it is determined by the intelligent coating and deposition control device to be within a preset normal range, the coating layer wear resistance is further measured for the product on which the top coating process of the second coating line has been performed,
The intelligent coating and deposition control device,
Based on the measurement result received from the reliability test equipment, the spindle conveyor driving device is controlled to move to the packaging line when the coating film wear resistance is within a preset normal range, and moves to the defect inspection line when the coating film wear resistance is within a preset defect range. Controlling the spindle conveyor drive device to be controlled, an exhaust controlled coating and deposition system. The method of claim 1,
The reliability test equipment,
Further comprising a UV irradiation dose meter for measuring the UV irradiation amount of the first dryer and the second dryer,
The intelligent coating and deposition control device,
Based on the measurement result received from the UV irradiation meter, to adjust the UV irradiation amount of the first dryer and the second dryer, or to control the moving speed of the spindle conveyor, the exhaust system controlled coating and deposition system. The method of claim 8,
The intelligent coating and deposition control device,
When the UV irradiation amount is less than a preset UV irradiation amount in connection with the product information of the product, controlling the first dryer and the second dryer to increase the UV irradiation amount of the first dryer and the second dryer, or Controlling the spindle conveyor driving device to reduce the moving speed of the spindle conveyor,
When the UV irradiation amount is relatively larger than the preset UV irradiation amount in connection with the product information of the product, the first dryer and the second dryer are controlled to reduce the UV irradiation amount of the first dryer and the second dryer. Or, to control the spindle conveyor drive device to increase the moving speed of the spindle conveyor, the exhaust system controlled coating and deposition system. The method of claim 1,
The intelligent coating and deposition device,
A receiving unit for receiving the product information and a measurement result measured by the reliability test equipment;
A database unit for storing the product information and reference information on the measurement result;
A determination unit for determining by comparing the product information and the measurement result with the reference information; And
A control unit for controlling an operation of the spindle conveyor driving device and at least one of devices provided on the first coating line, the deposition line, and the second coating line based on the comparison and determination result,
Including,
The control unit,
To control for controlling the driving of the exhaust device based on a preset amount of exhaust air, an exhaust device controlled coating and deposition system.

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