CN112477462B - Non-online digital proofing method for aluminum aerosol cans - Google Patents

Abstract

The invention discloses an off-line digital proofing method for an aluminum aerosol can, which comprises the following steps: creating a tank type library for determining the tank type; outputting an aluminum can digital proofing draft by using digital proofing equipment for determining image-text and color; the digital proofing draft of the aluminum can comprises the following steps: configuring digital proofing equipment; configuring a digital proofing system for digital proofing equipment; establishing an aluminum can printing digital proofing technical standard in a digital proofing system; selecting an aluminum material plate, and printing and outputting an aluminum can digital proofing draft by using digital proofing equipment according to the aluminum can printing digital proofing technical standard. The invention decomposes the proofing into the tank-type proofing and the pattern-text and color proofing, meets the requirement of a customer on the signing content (tank type + pattern-text), does not need to occupy an aluminum tank production line, has the characteristics of high output speed, simple working procedure and low proofing cost, and has great economic benefit and social value.

Description

Non-online digital proofing method for aluminum aerosol cans

[ technical field ] A method for producing a semiconductor device

The application relates to the technical field of printing, in particular to a digital proofing method for an off-line aluminum aerosol can.

[ background of the invention ]

Before the production of the aluminum aerosol can, a draft is provided for a customer to sign, and the content of the sign comprises a can pattern and a pattern (including color). The existing aluminum aerosol can proofing is a production line online proofing method, specifically, the online proofing method utilizes a full-automatic aluminum can production line to realize the forming and printing from a raw material aluminum block to an aluminum can, but the online proofing method has the defects of multiple steps, high cost, long treatment period, occupation of the production line and influence on the production scheduling and production efficiency of a company.

[ summary of the invention ]

The invention provides a non-online digital proofing method for an aluminum aerosol can, which is improved aiming at the problems that the traditional production line is adopted for proofing the aluminum aerosol can, the working procedures are multiple, the cost is high, the treatment period is long, the production line is occupied, and the production scheduling and the production efficiency of a company are influenced, and the method comprises the following steps:

s1: creating a tank type library for determining the tank type;

s2: the method for outputting the aluminum can digital proofing draft by using the digital proofing equipment is used for determining the image, text and color, and specifically comprises the following steps:

s21: configuring digital proofing equipment;

s22: configuring a digital proofing system for digital proofing equipment;

s23: establishing an aluminum can printing digital proofing technical standard in a digital proofing system;

s24: selecting an aluminum material plate, and printing and outputting an aluminum can digital proofing draft by using digital proofing equipment according to the aluminum can printing digital proofing technical standard.

As an improvement of the non-online digital proofing method for the aluminum aerosol cans, the digital proofing equipment in the step S21 needs to meet the following requirements that the printing function of aluminum materials is achieved; the ink saturation of the equipment is high, and the color gamut is wide; has fine ink drop imaging technology and supports high-resolution proofing.

As an improvement of the non-online digital proofing method for the aluminum aerosol cans, the digital proofing system in the step S22 needs to meet the following requirements that a digital printing device can be started; the color management function is provided, the aluminum material printing color profile ICC and the aluminum can printing color profile ICC can be manufactured, and the mapping from the aluminum can printing color to the digital proofing color is realized; a spot color library can be created, spot color matching calculation and correction can be carried out, and accurate simulation of digital proofing colors on the spot colors of aluminum can printing is realized; the spectrophotometer can be identified, and online measurement and setting are realized.

As an improvement of the above non-online digital proofing method for aluminum aerosol cans, step S23 includes the following steps:

s231: in a digital proofing system, an aluminum material linear file matched with an aluminum material by a digital proofing device and an aluminum material printing color characteristic file ICC are created;

s232: carrying out four-color simulation of aluminum can printing in a digital proofing system;

s233: and (4) carrying out spot color simulation of aluminum can printing in a digital proofing system.

As an improvement of the non-online digital proofing method for the aluminum aerosol can, step S232 includes the following steps:

s2321: collecting color information of an aluminum can printing standard plate;

s2322: in a digital proofing system, creating an aluminum can printing color profile ICC;

s2323: in a digital proofing system, the data conversion between an aluminum can printing color profile ICC and an aluminum material printing color profile ICC is implemented by utilizing a color management function, so that absolute color comparison is carried out, and the four-color simulation of aluminum can printing is realized.

As an improvement of the non-online digital proofing method for the aluminum aerosol can, step S233 includes the following steps:

s2331: in a digital proofing system, creating a special color library;

s2332: the digital proofing system performs spot color matching calculation and correction based on the aluminum linear file, updates the printing data corresponding to the spot color library, and realizes spot simulation of spot color of aluminum can printing.

As an improvement of the above non-online digital proofing method for aluminum aerosol cans, step S233 further includes step S2333: and measuring an aluminum can printing spot color channel step ruler, drawing a tone copying curve, and realizing spot color dot printing simulation through a curve loading function or directly adjusting spot color tones.

As an improvement of the non-online digital proofing method for aluminum aerosol cans, the spot color library in step S2331 may be a PANTONE spot color library or a custom spot color library.

As an improvement of the non-online aluminum aerosol can digital proofing method, a spectrophotometer is configured for establishing a custom special color library, and the spectrophotometer needs to meet the following requirements: the color of the aluminum-based material can be accurately measured; and the digital proofing system is connected to realize online measurement and setting.

As an improvement of the non-online aluminum aerosol can digital proofing method, in step S24, the flat aluminum plate needs to be printed with white ink and gloss oil.

Compared with the prior art, the invention has the following advantages:

the invention provides a digital proofing method for an off-line aluminum aerosol can, which decomposes proofing into can-shaped proofing and pattern and color proofing. The tank type proofing method is characterized in that the characteristics of low updating speed and few types of tank types are utilized, the tank type of an enterprise is directly used for tank type proofing or an equal-proportion model is established by using three-dimensional software for tank type proofing and proofing, and the proofing method is low in cost and high in speed; and the pattern-text and color proofing utilizes digital proofing equipment which establishes the technical standard of aluminum can printing digital proofing to print and output the aluminum can digital proofing draft for pattern-text and color proofing, and the proofing mode has high efficiency, low cost and high output speed. In conclusion, the non-online digital proofing method for the aluminum aerosol cans meets the requirements of customers on the proofing contents (can type + image-text), does not need to occupy an aluminum can production line, and has the characteristics of high output speed, simple working procedures and low proofing cost, and has great economic benefit and social value.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings used in the description of the embodiments will be briefly introduced below.

Fig. 1 is a flowchart of outputting a digital proofing draft of an aluminum can by using a digital proofing device in the non-online digital proofing method for an aluminum aerosol can.

[ detailed description ] embodiments

In order to make the technical problems, technical solutions and advantageous effects solved by the present application more clear and obvious, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

As can be seen from the flow chart of the off-line digital proofing method for aluminum aerosol cans shown in fig. 1, the method includes the following steps:

s1: and creating a tank type library for determining the tank type, wherein the tank type library is composed of a plurality of aluminum tanks with different shapes and sizes. The aluminum can be in a real form or a virtual form. Wherein the aluminum tank in the form of a real object is an existing enterprise tank type; the aluminum pot in the virtual form is a three-dimensional software which establishes an equal proportion model according to the conventional size, specifically, the bottom diameter of the aluminum pot in the virtual form can be phi 22mm or phi 25mm or phi 28mm or phi 35mm or phi 38mm or phi 40mm or phi 45mm or phi 50mm or phi 53mm or phi 59mm or phi 66m, and the height and the shape can be drawn according to the actual requirement.

S2: the method for outputting the aluminum can digital proofing draft by using the digital proofing equipment is used for determining the image, text and color, and specifically comprises the following steps:

s21: configuring a digital proofing device, wherein in order to accurately simulate the printing effect of the aluminum can, the digital proofing device in the step S21 needs to meet the following requirements of having the printing function of the aluminum material; the ink saturation of the equipment is high, and the color gamut is wide; has fine ink drop imaging technology and supports high-resolution proofing. Wherein, the digital proofing equipment needs to be provided with white ink, CMYK and glazing 6-color channel ink;

s22: configuring a digital proofing system for digital proofing equipment, wherein the digital proofing system meets the following requirements that the digital printing equipment can be started; the color management function is provided, the aluminum material printing color profile ICC and the aluminum can printing color profile ICC can be manufactured, and the mapping from the aluminum can printing color to the digital proofing color is realized; a spot color library can be created, spot color matching calculation and correction can be carried out, and accurate simulation of digital proofing colors on the spot colors of aluminum can printing is realized; the spectrophotometer can be identified, and online measurement and setting are realized;

s23: establishing an aluminum can printing digital proofing technical standard in a digital proofing system;

specifically, step S23 includes the steps of:

s231: in a digital proofing system, an aluminum material linear file matched with an aluminum material by a digital proofing device and an aluminum material printing color characteristic file ICC are created;

s232: carrying out four-color simulation of aluminum can printing in a digital proofing system;

specifically, step S232 further includes the following steps:

s2321: collecting color information of an aluminum can printing standard plate;

s2322: in a digital proofing system, creating an aluminum can printing color profile ICC;

s2323: in a digital proofing system, the data conversion between an aluminum can printing color profile ICC and an aluminum material printing color profile ICC is implemented by utilizing a color management function, so that absolute color comparison is carried out, and the four-color simulation of aluminum can printing is realized.

S233: carrying out special color simulation of aluminum can printing in a digital proofing system;

specifically, step S233 includes the following steps:

s2331: creating a special color library in a digital proofing system, wherein the special color library can be a PANTONE special color library or a custom special color library; when the special color library is the PANTONE special color, directly calling the PANTONE special color library; when the special color library is a user-defined special color library, a spectrophotometer is required to be configured for establishing the user-defined special color library, and the spectrophotometer is required to meet the following requirements: the color of the aluminum-based material can be accurately measured; connecting to a digital proofing system to realize online measurement and setting;

s2332: the digital proofing system performs spot color matching calculation and correction based on the aluminum linear file, updates the printing data corresponding to the spot color library, and realizes spot simulation of spot color of aluminum can printing.

When the product relates to spot color dot printing, spot color dot printing simulation needs to be performed, specifically, a step S2333 is added after the step S2332, and the specific operations are as follows: and measuring an aluminum can printing spot color channel step ruler, drawing a tone copying curve, and realizing spot color dot printing simulation through a curve loading function or directly adjusting spot color tones.

S24: selecting an aluminum material plate, and printing and outputting an aluminum can digital proofing draft by using digital proofing equipment according to the aluminum can printing digital proofing technical standard, wherein the color difference between the plane aluminum plate and the aluminum can is small, and the plane aluminum plate can be printed with white ink and gloss oil according to the needs of customers.

In conclusion, the off-line digital proofing method for the aluminum aerosol cans, provided by the invention, decomposes the proofing into can-shaped proofing and graphic, text and color proofing. The tank type proofing method is characterized in that the characteristics of low updating speed and few types of tank types are utilized, the tank type of an enterprise is directly used for tank type proofing or an equal-proportion model is established by using three-dimensional software for tank type proofing and proofing, and the proofing method is low in cost and high in speed; and the pattern-text and color proofing utilizes digital proofing equipment which establishes the technical standard of aluminum can printing digital proofing to print and output the aluminum can digital proofing draft for pattern-text and color proofing, and the proofing mode has high efficiency, low cost and high output speed. In conclusion, the non-online digital proofing method for the aluminum aerosol cans meets the requirements of customers on the proofing contents (can type + image-text), does not need to occupy an aluminum can production line, and has the characteristics of high output speed, simple working procedures and low proofing cost, and has great economic benefit and social value.

It should be understood that the terms "first", "second", etc. are used herein to describe various information, but the information should not be limited to these terms, and these terms are only used to distinguish one type of information from another. For example, "first" information may also be referred to as "second" information, and similarly, "second" information may also be referred to as "first" information, without departing from the scope of the present application. Furthermore, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application.

The foregoing is illustrative of one or more embodiments provided in connection with the detailed description and is not intended to limit the disclosure to the particular forms disclosed. Similar or identical methods, structures, etc. as used herein, or several technical inferences or substitutions made on the concept of the present application should be considered as the scope of the present application.

Claims (8)

1. The non-online digital proofing method for the aluminum aerosol cans is characterized by comprising the following steps of:

s1: creating a tank type library for determining the tank type;

s2: the method for outputting the aluminum can digital proofing draft by using the digital proofing equipment is used for determining the image, text and color, and specifically comprises the following steps:

s21: configuring digital proofing equipment;

s22: configuring a digital proofing system for digital proofing equipment;

the digital proofing system in step S22 is required to satisfy the requirement that the digital printing apparatus can be started; the color management function is provided, the aluminum material printing color profile ICC and the aluminum can printing color profile ICC can be manufactured, and the mapping from the aluminum can printing color to the digital proofing color is realized; a spot color library can be created, spot color matching calculation and correction can be carried out, and accurate simulation of digital proofing colors on the spot colors of aluminum can printing is realized; the spectrophotometer can be identified, and online measurement and setting are realized;

s23: establishing an aluminum can printing digital proofing technical standard in a digital proofing system;

step S23 includes the following steps:

s231: in a digital proofing system, an aluminum material linear file matched with an aluminum material by a digital proofing device and an aluminum material printing color characteristic file ICC are created;

s232: carrying out four-color simulation of aluminum can printing in a digital proofing system;

s233: spot color simulation for aluminum can printing in digital proofing system

S24: selecting an aluminum material plate, and printing and outputting an aluminum can digital proofing draft by using digital proofing equipment according to the aluminum can printing digital proofing technical standard.

2. The off-line digital proofing method for aluminum aerosol cans according to claim 1, wherein the digital proofing device in step S21 is required to have the function of printing aluminum material; the ink saturation of the equipment is high, and the color gamut is wide; has fine ink drop imaging technology and supports high-resolution proofing.

3. The off-line digital proofing method for aluminum aerosol cans according to claim 1, wherein the step S232 comprises the steps of:

s2321: collecting color information of an aluminum can printing standard plate;

s2322: in a digital proofing system, creating an aluminum can printing color profile ICC;

s2323: in a digital proofing system, the data conversion between an aluminum can printing color profile ICC and an aluminum material printing color profile ICC is implemented by utilizing a color management function, so that absolute color comparison is carried out, and the four-color simulation of aluminum can printing is realized.

4. The off-line digital proofing method for aluminum aerosol cans according to claim 1, wherein the step S233 comprises the steps of:

s2331: in a digital proofing system, creating a special color library;

s2332: the digital proofing system performs spot color matching calculation and correction based on the aluminum linear file, updates the printing data corresponding to the spot color library, and realizes spot simulation of spot color of aluminum can printing.

5. The off-line digital proofing method for aluminum aerosol cans as claimed in claim 4, wherein the step S233 further comprises the step S2333: and measuring an aluminum can printing spot color channel step ruler, drawing a tone copying curve, and realizing spot color dot printing simulation through a curve loading function or directly adjusting spot color tones.

6. The off-line digital proofing method for aluminum aerosol cans as claimed in claim 1, wherein the spot color library in step S2331 is a PANTONE spot color library or a custom spot color library.

7. The off-line digital proofing method for aluminum aerosol cans according to claim 1, wherein a spectrophotometer is configured for establishing the custom proprietary color library, the spectrophotometer being required to satisfy the following requirements: the color of the aluminum-based material can be accurately measured; and the digital proofing system is connected to realize online measurement and setting.

8. The off-line digital proofing method for aluminum aerosol cans according to claim 1, wherein the flat aluminum plate is printed with white ink and gloss oil in step S24.

Images