CN112356608A - Method for making carved woodcut - Google Patents

Abstract

The invention relates to the field of handicraft manufacturing, in particular to a method for manufacturing a carved metal print. The method comprises the following steps: the method comprises the steps that a plurality of optional sample units are stored in advance, each sample unit at least comprises modeling element information, and the modeling elements are points, lines, surface models and combinations thereof in specific shapes or specific three-dimensional models and combinations thereof; selecting sample units, and arranging and combining the sample units into a to-be-processed picture template; and engraving the base material based on the picture template to be processed. The invention utilizes a plurality of sample units to form a template of the picture to be processed in a combined manner, and then carries out engraving processing on the base material, wherein the sample units comprise modeling element information which can be various modeling elements with specific styles loaded or stored in advance, so that the processed picture is vivid, rich in variation and unique in style.

Description

Method for making carved woodcut

Technical Field

The invention relates to the field of handicraft manufacturing, in particular to a method for manufacturing a carved metal print.

Background

The metal engraving print is an industrial art product formed by using metal foil as a carrier and adopting the technological methods of color printing, stamping, etching and the like.

In the conventional metal foil processing technology, a template for manufacturing the whole picture is usually designed in computer equipment, and then engraving processing is performed on the metal foil based on the template by using engraving equipment. However, the existing template design in the manufacturing process often adopts inherent lines and forms to outline patterns and pictures, and the overall style of the pictures is single, lacks novelty and change, and is difficult to adapt to the changing aesthetic requirements and technical needs.

Disclosure of Invention

The invention overcomes the defects and provides a method for manufacturing the carved metalwork with flexible design.

The technical scheme adopted by the invention for solving the technical problems is as follows: a method for manufacturing carved woodcut comprises the following steps:

the method comprises the steps of storing a plurality of candidate sample units in advance, wherein the sample units at least comprise modeling element information, and the modeling elements are in a mode of points, lines or planes with specific shapes or in a three-dimensional mode.

Selecting sample units, and arranging and combining the sample units into a to-be-processed picture template;

and engraving the base material based on the picture template to be processed.

Further, the sample unit may further include color information, where the color information includes at least one of hue information, saturation information, and brightness information; and performing a printing operation after engraving the substrate.

Further, the sample unit may further include at least one of engraving depth information and size information.

Furthermore, the sample unit may further include scale information for scaling the modeling elements by setting and adjusting the scale information.

Further, in the sample unit, the model element may be divided into a plurality of regions, and different saturation information or/and shading information may be set correspondingly.

Further, the modeling element information may be a variety of line modeling that simulates embroidery stitch, including but not limited to, aligning, cutting, pinching, splicing, rolling, locking, chaining, straight, coiling, scattering, trimming, random, mixing, carving, and combinations thereof.

Further, the modeling element information may be a plurality of solid models simulating a plurality of gem cutting modes, including but not limited to round diamond cutting, pear cutting, triangle cutting, oval cutting, heart cutting, olive cutting, pillow cutting, and combinations thereof.

Further, the step of selecting the sample units, arranging and combining the sample units into the to-be-processed picture template can be repeatedly performed.

Further, the step of engraving the substrate may adopt an intaglio or/and an embossing manner.

Further, the substrate may be a metal foil obtained by vacuum coating using a PET film.

The invention utilizes a plurality of sample units to form a template of the picture to be processed in a combined manner, and then carries out engraving processing on the base material, wherein the sample units comprise modeling element information which can be various modeling elements with specific styles loaded or stored in advance, so that the processed picture is vivid, rich in variation and unique in style. In addition, the sample units also correspondingly contain color information, printing processing is carried out after engraving processing is carried out, different modeling elements are combined with different colors, a richer picture effect is formed, and modeling characteristics and color characteristics in the picture template to be processed can be accurately corresponded.

Drawings

FIG. 1 is a flow chart of the present invention.

Detailed Description

Referring now to FIG. 1, a flow chart of the present invention is shown, and the following description of the present invention will be described in detail with reference to specific embodiments.

The first embodiment is as follows:

the embodiment is a preferred embodiment, and the method can be used for manufacturing the carved gold color print with the silk embroidery effect. The method of the embodiment is as follows:

step S01:

the method comprises the steps of loading and storing a plurality of candidate sample units in computer equipment in advance, wherein the sample units comprise modeling element information, hue information, saturation information, brightness information, carving depth information, size information and proportion information.

The modeling element information can be various line models simulating embroidery stitch, such as alignment needle, cutting needle, banquette needle, joint needle, needle roller, lock needle, chain needle, straight needle, disc needle, staggered needle, scattered needle, disordered needle, blending needle, scale needle and the like, and combinations of the same or different stitches. The dimensional information may include length, width, etc., simulating stitch length and thread thickness, respectively, of the stitch. The color information can be the hue, saturation and darkness of the simulated silk threads and embroidery threads. In one sample unit, the shading information may correspond to different regions in the current model element, and respectively have different shading degrees. For example, in a pattern element corresponding to the jersey, a plurality of light and shade areas are divided along the length direction of the jersey thread, and different shading parameters are correspondingly set respectively to simulate the shading change caused by the gloss of the silk thread.

Step 002:

and selecting the certain sample units one by one in sequence, and arranging and combining the sample units into the template of the picture to be processed.

For example, selecting sample units with modeling elements of needle rollers, dark ink colors, carving depths of 1mm, lengths of 5mm, widths of 0.2mm and the like, connecting the sample units one by one to form a line, and drawing a contour line of the mountain stone;

sequentially selecting sample units with molding elements of a needle, phthalocyanine (and cyanine, stone green and the like), carving depth of 0.1mm, length of 3mm, width of 0.2mm and the like, and tiling and filling the sample units on a template one by one to form a gradual change effect on a mountain;

and by analogy, the sample units of the various parameter information are arranged and combined into a complete landscape picture as a picture template to be processed.

In the step, an operator can manually select sample units in the equipment, and the selected samples are arranged one by one to form a complete picture; or selecting and arranging the sample units by using a set algorithm and rule through computer equipment to form a complete picture, for example, obtaining a line draft image in advance and marks of each specific area in the line draft image, selecting corresponding sample units based on colors or lines corresponding to the marks, and arranging and combining the complete picture in a set mode of tiling, interlacing, gradually changing and the like. The setting and adjustment of the proportion information can realize the scaling of the modeling elements so as to meet the requirements of different picture designs.

The above steps can be repeated to form a laminated effect consisting of a plurality of layers of modeling elements.

Step S03:

based on the model characteristics of the position line type, the size, the depth and the like in the picture completed in the step S02, an engraving instruction is generated, and the engraving device is made to perform engraving processing on the metal foil substrate in a concave engraving manner.

Based on the color characteristics of the screen completed in step S02, such as hue information, saturation information, and lightness information, at each position, a print command is generated to cause the printing device to print the engraved metal substrate.

Through the steps, the carving and printing operations are completed on the metal foil substrate in sequence, and the modeling elements of different embroidery stitch methods are combined with different colors, so that a picture with a silk embroidery effect can be formed on the metal foil. In particular, by utilizing modeling elements such as straight needles, disc needles, scattered needles, disorderly needles, blended needles, scale-carving needles and the like and mutual combination thereof, modeling elements of various embroidery methods such as disordered needle embroidery, flat needle embroidery and the like are simulated and then arranged to form a complete picture. In addition, when the metal foil substrate is engraved, the metal foil substrate can have a certain engraving depth, can naturally bring a certain light and shade effect, and can bring different texture effects due to different engraving depths. And, utilize the brightness parameter included in the said sample unit, give more abundant light and shade gradation in the printing process, the effect is more vivid.

The carving equipment can adopt existing equipment such as a laser carving machine and a numerical control metal carving and milling machine, or equipment devices possibly appearing in the future for metal foil stamping, carving, etching and the like.

The printing device may be an existing device such as a UV printer, or a device for metal foil painting, printing, etc. that may be present in the future.

Example two:

step S01:

the method comprises the steps of loading and storing a plurality of candidate sample units in computer equipment in advance, wherein the sample units comprise modeling element information, hue information, saturation information, brightness information, carving depth information, size information and proportion information.

The modeling element information can be various three-dimensional modeling simulating various gem cutting modes, such as round diamond cutting, pear cutting, triangle cutting, oval cutting, heart cutting, olive cutting, pillow cutting and the like, and combinations of the same or different three-dimensional modeling.

The color information may be the hue, saturation and darkness of the simulated gemstone. In a sample cell, different regions in the current style element may have different saturation and darkness, respectively. For example, in a modeling element corresponding to pear-shaped cutting, the luster and the fire effect of each different cutting surface of the gem are simulated by dividing a plurality of areas and correspondingly setting different saturation and darkness information respectively.

Steps S02 and S03 are substantially the same as those in the first embodiment, and are not repeated.

Through the steps, the metal foil substrate is carved in a convex carving or concave-convex combination mode in sequence, printing operation is carried out, a picture with a gem inlaying effect can be formed on the metal foil, modeling elements in different cutting modes are combined with different colors, and the picture is rich, fine and smooth and has aesthetic feeling.

The above embodiment may be simplified in that the sample cell in step S01 may include only modeling element information. The method is applied to carving the metal foil substrate without color matching scenes, such as carving pattern design of some gold bills and commemorative coins.

The substrate is a metal foil obtained by vacuum coating of a PET film, or a metal foil manufactured by physical means such as stamping, extending and the like, and can also be a plane, curved surface or polyhedral substrate made of various other materials.

The method can be operated in various equipment or devices with operation processing functions, such as PC computers, tablet computers, numerical control machine tool central control systems and the like.

The method for making the engraved engraving is described in detail, and the principle and the implementation mode of the invention are explained by applying specific examples, and the description of the examples is only used for helping to understand the method and the core idea of the invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (10)

1. The method for manufacturing the engraved engraving painting is characterized by comprising the following steps of:

the method comprises the steps that a plurality of alternative sample units are stored in advance, each sample unit at least comprises modeling element information, and the modeling elements are points, lines, surface models and combinations thereof in specific shapes or specific three-dimensional models and combinations thereof;

selecting sample units, and arranging and combining the sample units into a to-be-processed picture template;

and engraving the base material based on the picture template to be processed.

2. The method for making engraved engraving as claimed in claim 1, characterized in that: the sample unit further comprises color information, wherein the color information comprises at least one of hue information, saturation information and brightness information; and performing a printing operation after engraving the substrate.

3. The method for making engraved engraving as claimed in claim 2, characterized in that: in the sample unit, the modeling element is divided into a plurality of areas, and different saturation information or/and shading information is/are correspondingly set.

4. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: and selecting the sample units, arranging and combining the sample units into the template of the picture to be processed, and repeating the steps.

5. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the sample unit further includes at least one of engraving depth information and size information.

6. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the sample unit further comprises proportion information, and the modeling elements are zoomed by setting and adjusting the proportion information.

7. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the modeling element information is a plurality of line models simulating the stitch of embroidery thread, including but not limited to, aligning, cutting, pinching, splicing, rolling, locking, chaining, straight, coiling, scattering, random, messy, blending, carving and combination thereof.

8. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the modeling element information is a plurality of three-dimensional modeling simulating a plurality of gemstone cutting modes, including but not limited to round diamond cutting, pear cutting, triangle cutting, oval cutting, heart cutting, olive cutting, pillow cutting, and combinations thereof.

9. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the step of engraving the substrate adopts a concave engraving or/and convex engraving mode.

10. A method for making engraved engraving as claimed in claim 1, 2 or 3, characterized in that: the base material is a metal foil obtained by vacuum coating of a PET film.

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