CN112959817A - Kitchen electric glass high-temperature printing device and technology thereof - Google Patents

Abstract

The invention discloses a kitchen electric glass high-temperature printing device and a process thereof, belonging to the glass field, the kitchen electric glass high-temperature printing device comprises a processing table, wherein a longitudinal slide rail is fixedly connected on the processing table, one end of the longitudinal slide rail is fixedly connected with a fixed plate, a movable plate is slidably connected on the longitudinal slide rail, transverse guide rails are fixedly connected on the fixed plate and the movable plate, a movable table is slidably connected on the transverse guide rails, a stepping motor is fixedly connected on the movable table, a mechanical clamp is fixedly connected on the power output end of the stepping motor, an electric slide rail is paved at the top end of the longitudinal slide rail, a sliding table is slidably connected on the electric slide rail, a rolling cylinder is rotatably connected on the sliding table, deformable images can be printed between double-layer glass, a plurality of images printed by color-changing coatings are covered on a basic image, and when the environment around the glass is changed to a dangerous state, corresponding warning images, the use is convenient to remind.

Description

Kitchen electric glass high-temperature printing device and technology thereof

Technical Field

The invention relates to the field of glass, in particular to a kitchen electric glass high-temperature printing device and a kitchen electric glass high-temperature printing process.

Background

Glass is an amorphous inorganic non-metallic material, and is generally prepared by using various inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash and the like) as main raw materials and adding a small amount of auxiliary raw materials.

Kitchen electric glass is mostly the glass of installing on electrical apparatus, electrical apparatus can release a large amount of heats at the during operation, traditional kitchen electric glass is mostly borosilicate glass, borosilicate glass heat conductivity and compressive strength effect are unsatisfactory, the heavy fragile of use, current kitchen electric glass is glued for scribbling glass and is connected electrical apparatus in the mode of being connected with electrical apparatus, when electrical apparatus trouble, glass panels and coil direct contact atress are uneven, fragile, factor of safety is lower. Present for kitchen electrical apparatus glass often can print the decorative pattern and decorate, and the decorative pattern style of printing on the present glass is single, watches from both sides and is a pattern, various environmental factor in the kitchen can influence the use of electrical apparatus, also take place internal failure in the electrical apparatus use, and do not have the detection and remind the function on present electrical apparatus, when the electrical apparatus trouble, be difficult for discovering the trouble reason.

Disclosure of Invention

1. Technical problem to be solved

The invention aims to provide a kitchen electric glass high-temperature printing device and a process thereof, which can realize that deformable images are printed between double layers of glass, and a plurality of images printed by color-changing coatings are covered on one basic image, so that when the surrounding environment of the glass is changed to a dangerous state, a corresponding warning image can be generated on the glass, and the kitchen electric glass high-temperature printing device and the process thereof are convenient to remind for use.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

The utility model provides a kitchen electricity glass high temperature printing device and technology, includes the processing platform, the processing bench is the vertical slide rail of fixedly connected with, the one end fixedly connected with fixed plate of vertical slide rail, sliding connection has the fly leaf on the vertical slide rail, equal fixedly connected with transverse guide on fixed plate and the fly leaf, sliding connection has the movable table on the transverse guide, fixedly connected with step motor on the movable table, fixedly connected with machinery presss from both sides on step motor's the power take off, electronic slide rail has been laid on the top of vertical slide rail, sliding connection has the slip table on the electronic slide rail, the slip table rotates and is connected with the rolling section of thick bamboo.

A kitchen electric glass high-temperature printing device and a process thereof comprise the following specific process flows:

s1, cutting the two glass sheets to obtain two glass sheets with the same size, and then stably clamping the glass sheets by using a pair of mechanical clamps;

s2, designing a pattern A and a pattern B, designing a printing track of a printing image, and obtaining a layer group A and a layer group B;

s3, then spraying a color image matched with the pattern A on one glass surface;

s4, manufacturing a screen template matched with the image layer group A and the image layer group B, and performing multi-layer screen printing on the glass on the other surface by using the color-changing paint;

s5, adhering electric heating sheets on the back of the transfer film, laying a lead among the electric heating sheets, and finally laying a modified paraffin film on the transfer film;

and S6, compounding the two pieces of glass at high temperature, and cooling to obtain the bidirectional glass.

Further, the modified paraffin film is prepared by mixing high-melting-point paraffin and cerate, and the ratio of the high-melting-point paraffin to the cerate is 7: 3, make to fill between the two-layer glass and have sticky parafilm, receive two glass boards of high temperature softening back class bonding at the parafilm, the disintegrating slag that produces when preventing glass damage splashes everywhere and causes the injury to personnel on every side.

Furthermore, waterproof paint with the same color as the pattern ground color is laid on the electric heating sheet and the paraffin film.

Furthermore, the electric lead comprises a carbon fiber wire, the electric heating piece is coated by the carbon fiber wire, and copper wires are laid in the carbon fiber wire, so that after the electric heating piece is heated, the area covered by the electric heating piece array is heated, and the designated area of the printed image is heated.

Further, the specific steps of the printing track design include: extracting pattern colors, setting each color as a layer, obtaining a first layer group, overlapping a pattern B with the pattern A, marking an overlapping area of the pattern B and the pattern A on each layer, setting the overlapping area corresponding to each color as a layer, obtaining a layer group B, setting the layer of each color in the layer group B corresponding to the layer of the same color in the first layer group, and deleting the overlapping area in the first layer to obtain the layer group A, so that one pattern is covered with another pattern, and the subsequent spraying work of the color-changing coating is facilitated.

Further, when the multi-layer screen printing in the step S4 is performed, the printing of the layer group a is completed by using a common paint, then the printing of the layer group B is completed by using a temperature change material, and the printing of the paints is performed in layers, so that the superposition of a plurality of paints is prevented, and the thickness of each point on the printed image is prevented from being inconsistent.

Furthermore, the multiple temperature-change coatings are in the same color after changing color, and the color changing point of the temperature-change coating is 60 ℃.

Furthermore, a plurality of electric heating pieces are arranged into a plurality of N x 2 array groups, the conducting wire is connected with sensors, each sensor is connected with one electric heating piece array group in series, and when the sensors feed back signals, the designated area on the glass can be heated, so that the temperature change coating material changes color after the printed image on the designated area on the glass is heated, and new patterns appear on the designated area on the glass.

Furthermore, an electric heating rod is fixedly connected in the rolling cylinder, and the rolling cylinder is made of heat-conducting ceramic.

Further, the thickness of parafilm is the same with electric heat piece thickness, makes two compound back electric heat pieces of glass can not outstanding with the parafilm, prevents to produce the space between two glass.

3. Advantageous effects

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

(1) this scheme can realize through printing deformable image between double glazing, cover a plurality ofly by the image of the coating printing of discolouing on a basic figure, can make glass go up to produce corresponding warning image when changing to dangerous state the environment around making glass, conveniently reminds the use.

(2) The modified paraffin film is prepared by mixing high-melting-point paraffin and cerate, wherein the ratio of the high-melting-point paraffin to the cerate is 7: 3, make to fill between the two-layer glass and have sticky parafilm, receive two glass boards of high temperature softening back class bonding at the parafilm, the disintegrating slag that produces when preventing glass damage splashes everywhere and causes the injury to personnel on every side.

(3) The electric lead comprises a carbon fiber wire, the carbon fiber wire coats the electric heating piece, and a copper wire is laid in the carbon fiber wire, so that after the electric heating piece generates heat, the area covered by the electric heating piece array generates heat, and the designated area of the printed image is heated.

(4) The specific steps of the printing track design comprise: extracting pattern colors, setting each color as a layer, obtaining a first layer group, overlapping a pattern B with the pattern A, marking an overlapping area of the pattern B and the pattern A on each layer, setting the overlapping area corresponding to each color as a layer, obtaining a layer group B, setting the layer of each color in the layer group B corresponding to the layer of the same color in the first layer group, and deleting the overlapping area in the first layer to obtain the layer group A, so that one pattern is covered with another pattern, and the subsequent spraying work of the color-changing coating is facilitated.

(5) And S4, when the multilayer screen printing is carried out in the step of S4, firstly using common paint to finish the printing of the layer group A, then using temperature-change material to finish the printing of the layer group B, and carrying out the printing of the paint layer by layer to prevent the superposition of various paints and prevent the thickness of each point on the printed image from being inconsistent.

(6) The plurality of electric heating pieces are arranged into a plurality of N x 2 array groups, the wires are connected with sensors, each sensor is connected with one electric heating piece array group in series, and when the sensors feed back signals, the designated area on the glass can be heated, so that after the printed image on the designated area on the glass is heated, the temperature change coating changes color, and new patterns appear on the designated area on the glass.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a process flow diagram of the present invention;

FIG. 3 is a schematic view of the structure of the bi-directional glass of the present invention;

FIG. 4 is an exploded view of the duplex glass of the present invention;

FIG. 5 is a cross-sectional view of the bi-directional glass of the present invention;

fig. 6 is a partial cross-sectional view of the bi-directional glass of the present invention.

The reference numbers in the figures illustrate:

1 processing table, 2 longitudinal slide rails, 3 fixed plates, 4 movable plates, 5 transverse guide rails, 6 movable tables, 7 stepping motors, 8 mechanical clamps, 9 electric slide rails, 10 sliding tables, 11 rolling cylinders, 12 carbon fiber wires, 13 modified paraffin layers, 14 wires and 15 electric heating sheets.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; the connection can be direct connection or indirect connection through an intermediate medium, and can be communication inside the model adapting element. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-3, a kitchen electric glass high-temperature printing device and a process thereof include a processing table 1, a longitudinal slide rail 2 is fixedly connected to the processing table 1, a fixed plate 3 is fixedly connected to one end of the longitudinal slide rail 2, a movable plate 4 is slidably connected to the longitudinal slide rail 2, transverse guide rails 5 are fixedly connected to the fixed plate 3 and the movable plate 4, a movable table 6 is slidably connected to the transverse guide rails 5, a stepping motor 7 is fixedly connected to the movable table 6, a mechanical clamp 8 is fixedly connected to a power output end of the stepping motor 7, an electric slide rail 9 is laid at the top end of the longitudinal slide rail 2, a sliding table 10 is slidably connected to the electric slide rail 9, a rolling cylinder 11 is rotatably connected to the sliding table 10, an electric heating rod is fixedly connected to the inside of the rolling cylinder 11.

A kitchen electric glass high-temperature printing device and a process thereof comprise the following specific process flows:

s1, cutting the two glass sheets to obtain two glass sheets with the same size, and then stably clamping the glass sheets by using a pair of mechanical clamps 8;

s2, designing a pattern A and a pattern B, designing a printing track of a printing image, and obtaining a layer group A and a layer group B, wherein the printing track design comprises the following specific steps: extracting pattern colors, setting each color as a layer, obtaining a first pattern layer group, overlapping a pattern B with the pattern A, marking an overlapping area of the pattern B and the pattern A on each layer, setting the overlapping area corresponding to each color as a layer, obtaining a pattern layer group B, setting the layer of each color in the pattern layer group B corresponding to the layer of the same color in the first layer group, deleting the overlapping area in the first layer, obtaining the pattern layer group A, covering one pattern with another pattern, and facilitating the subsequent spraying work of the color-changing coating;

s3, then spraying a color image matched with the pattern A on one glass surface;

s4, manufacturing a screen template matched with the image layer group A and the image layer group B, performing multi-layer screen printing on the glass on the other surface by using color-changing paint, wherein the color-changing paint is the same color after changing color, the color-changing point of the temperature-changing paint is 60 ℃, when the multi-layer screen printing in the step S4 is performed, firstly, the printing of the image layer group A is completed by using common paint, then, the printing of the image layer group B is completed by using temperature-changing materials, the printing of the paint is performed in a layering manner, the superposition of various paints is prevented, and the thickness of each point on a printed image is;

s5, adhering electric heating sheets 15 on the back surface of the transfer film, laying lead wires 14 among the electric heating sheets 15, and finally laying the modified paraffin film 13 on the transfer film;

and S6, compounding the two pieces of glass at high temperature, and cooling to obtain the bidirectional glass.

The modified paraffin film 13 is prepared by mixing high-melting-point paraffin and cerate, and the ratio of the high-melting-point paraffin to the cerate is 7: 3, make to fill between the two-layer glass and have sticky parafilm, receive two glass boards of high temperature softening back class bonding at the parafilm, the disintegrating slag that produces when preventing glass damage splashes everywhere and causes the injury to personnel on every side.

Please refer to the waterproof paint with the same pattern ground color laid on the electric heating sheet 15 and the paraffin film. The conductive wire 17 comprises a carbon fiber wire 12, the electric heating sheets 15 are coated by the carbon fiber wire 12, copper wires are laid in the carbon fiber wire 12, and after the electric heating sheets 15 generate heat, areas covered by the array of the electric heating sheets 15 all generate heat, so that the designated areas of the printed images are heated. The plurality of electric heating sheets 15 are arranged into a plurality of N x 2 array groups, the lead 14 is connected with a sensor, each array group is connected with a sensor, such as a temperature sensor, a smoke sensor, a gas component detection sensor and the like, each sensor is connected with one electric heating sheet 15 array group in series, when the sensor detects that the numerical value is abnormal or the detection value is higher than a set value, the sensor sends a feedback signal, when the sensor feeds back the signal, the designated area on the glass can be heated, so that after the printed image of the designated area on the glass is heated, the temperature-variable paint is changed in color, and new patterns appear in the designated area on the glass.

The scheme is that the image printed between double-layer glass is printed at normal temperature, the same image is displayed when the double-layer glass is viewed in two directions, the image of the scheme is printed for multiple times in a layering mode, the image covered on the basic image is processed in a layering mode according to the image overlapping area and the image color, the overlapping area of the basic image and the color-changing image is avoided during printing of the basic image, when the color-changing image is printed, the color-changing image is printed by using the coating which is not printed and has the same color as the color of the basic image overlapping area, compared with the existing color-changing image directly covered and printed on the basic image, the whole image of the flexible printed image obtained by the scheme is highly and completely unified, and the phenomenon that the ink on the glass is scattered due to the fact that the printed image is in a high-temperature extrusion state.

And the sensor connected with the electric heating sheet 15 in the double-layer glass sends a feedback signal, or when the surrounding environment is overheated, the color-changing coating combined with the basic image changes color, so that a warning image is displayed on the basic image, and the surrounding personnel can observe the abnormality in time after the user uses the warning image.

And the paraffin layer between a pair of glass boards softens gradually when the surrounding environment is overheated, and when glass damaged or broke because of high temperature, the glass disintegrating slag is by softening the adhesion of paraffin layer and sink into the paraffin layer that softens, and the disintegrating slag that produces when preventing glass from damaging splashes everywhere and causes the injury to personnel in the periphery.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims (10)

1. The kitchen electric glass high-temperature printing device and the process thereof comprise a processing table (1), and are characterized in that: fixedly connected with longitudinal slide rail (2) on processing platform (1), one end fixedly connected with fixed plate (3) of longitudinal slide rail (2), sliding connection has fly leaf (4) on longitudinal slide rail (2), equal fixedly connected with transverse guide (5) on fixed plate (3) and fly leaf (4), sliding connection has movable table (6) on transverse guide (5), fixedly connected with step motor (7) on movable table (6), fixedly connected with machinery presss from both sides (8) on the power take off of step motor (7), electronic slide rail (9) have been laid on the top of longitudinal slide rail (2), sliding connection has slip table (10) on electronic slide rail (9), slip table (10) rotate and are connected with rolling cylinder (11).

A kitchen electric glass high-temperature printing device and a process thereof comprise the following specific process flows:

s1, cutting the two glass sheets to obtain two glass sheets with the same size, and then stably clamping the glass sheets by using a pair of mechanical clamps (8);

s2, designing a pattern A and a pattern B, designing a printing track of a printing image, and obtaining a layer group A and a layer group B;

s3, then spraying a color image matched with the pattern A on one glass surface;

s4, manufacturing a screen template matched with the image layer group A and the image layer group B, and performing multi-layer screen printing on the glass on the other surface by using the color-changing paint;

s5, adhering electric heating sheets (15) on the back surface of the transfer film, laying lead wires (14) among the electric heating sheets (15), and finally laying a modified paraffin film (13) on the transfer film;

and S6, compounding the two pieces of glass at high temperature, and cooling to obtain the bidirectional glass.

2. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the modified paraffin film (13) is prepared by mixing high-melting-point paraffin and cerate, and the ratio of the high-melting-point paraffin to the cerate is 7: 3.

3. the kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: waterproof paint with the same pattern ground color is laid on the electric heating sheet (15) and the paraffin film.

4. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the electric lead (17) comprises a carbon fiber wire (16), the electric heating sheet (15) is coated by the carbon fiber wire (16), and a copper wire is laid in the carbon fiber wire (16).

5. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the specific steps of the printing track design include: extracting pattern colors, setting each color as a layer, obtaining a first pattern layer group, overlapping a pattern B with the pattern A, marking an overlapping area of the pattern B and the pattern A on each layer, setting the overlapping area corresponding to each color as a layer, obtaining a pattern layer group B, setting the layer of each color in the pattern layer group B corresponding to the layer of the same color in the first layer group, and deleting the overlapping area in the first layer to obtain the pattern layer group A.

6. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: in the step S4, when performing the multi-layer screen printing, the printing of the layer group a is completed by using a common paint, and then the printing of the layer group B is completed by using a temperature-change material.

7. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the multiple temperature-change coatings are same in color after changing color, and the color changing point of the temperature-change coatings is 60 ℃.

8. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the plurality of electric heating pieces (15) are arranged into a plurality of N x 2 array groups, the conducting wire (14) is connected with sensors, and each sensor is connected with one electric heating piece (15) array group in series.

9. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the electric heating rods are fixedly connected in the rolling cylinders (11), and the rolling cylinders (11) are made of heat-conducting ceramics.

10. The kitchen electric glass high-temperature printing device and the process thereof according to claim 1, wherein: the thickness of the paraffin film is the same as that of the electric heating piece (15).

Images