CN111168815B

CN111168815B - Full-digital decorative ceramic polished tile with antifouling and anti-skid functions and production method thereof

Info

Publication number: CN111168815B
Application number: CN202010145868.6A
Authority: CN
Inventors: 夏昌奎; 赵明; 余剑峰; 余爱民; 甄燕萍; 樊叶利; 余昌江; 李华云
Original assignee: Deqing Nabel Ceramic Co ltd; Jiujiang Nabel Ceramic Co ltd; Hangzhou Nabel Ceramic Co ltd
Current assignee: Deqing Nabel Ceramic Co ltd; Jiujiang Nabel Ceramic Co ltd; Hangzhou Nabel Ceramic Co ltd
Priority date: 2020-03-05
Filing date: 2020-03-05
Publication date: 2021-08-31
Anticipated expiration: 2040-03-05
Also published as: CN111168815A

Abstract

The invention discloses a full-digital decorative ceramic polished tile with antifouling and anti-skid functions and a production method thereof, wherein the production method comprises the following steps: a) preparing a bottom material and a surface material of the polished tile body according to a conventional method; b) distributing by adopting a high-precision digital colorful distributing system and a distributing process; c) pressing and molding the polished ceramic tile blank; d) adopting symbol marking equipment to mark the texture of the polished tile blank; e) drying the blank; f) carrying out symbol mark identification on the dried polished tile green body by using equipment for identifying the symbol mark so as to identify the texture of the polished tile green body; g) spraying penetrating ink; h) drying again; i) firing; j) edging; k) polishing; l) coating multi-component nano anti-skid liquid with an anti-fouling function; the fully digital decorative ceramic polished tile with antifouling and antiskid functions is prepared. The invention realizes the perfect connection of the surface texture of the green body and the texture of the entire cloth, improves the anti-skid effect of the polished ceramic tile and solves the technical problem that the ceramic tile is anti-skid but not anti-fouling.

Description

Full-digital decorative ceramic polished tile with antifouling and anti-skid functions and production method thereof

Technical Field

The invention relates to a production method of polished porcelain tiles, in particular to a fully-digitalized decorative polished porcelain tile with antifouling and anti-skid functions and a production method thereof.

Background

The natural stone is influenced by long-term geological motion and climate change and is mixed with associated minerals with other colors, so that high-end, natural and rich decorative effects are formed, shapes such as lines, pits and patches are covered on texture patterns, and materials with various colors such as white, dark red and the like and transparent materials are included, so that the natural stone is favored by people as a high-grade decorative material. However, the radioactive minerals associated with some natural stones may cause radioactive damage to human health; the natural stone affected by geological action and weathering has more defects such as impurities, cracks and the like, and poor service performance, and needs to be waxed and the like in daily use, but the natural stone has the characteristics of natural pores and the like after a long time and can generate diseases such as alkali resistance or color spots and the like due to the permeation of other substances outside. In addition, the natural stone is used as an unrenewable resource, is expensive and is difficult to enter common families; the transitional exploitation of natural stones not only causes the exhaustion of rare and rare stone resources, but also seriously damages the natural ecological environment.

Therefore, in recent years, the natural stone texture imitating ceramic tiles gradually become a new favorite in the market, however, the existing natural stone texture imitating ceramic tiles still have defects on decoration textures, chinese patent CN201910066018.4 discloses a whole body unglazed marble ceramic tile and a manufacturing method thereof, the whole body textures of the ceramic tile are endowed in a way of combining multi-tube free cloth with drying and blank polishing, but in order to protect the surface textures, a transparent wear-resistant protective material is also needed to be added after ink-jet decoration, and the randomness of the textures is easily too large due to the multi-tube free cloth, so that the blank textures and the ink-jet textures are difficult to be completely matched, and after the drying and blank polishing process is used, due to different polishing depths, the presented textures are also different, so that the increase of the drying and blank polishing process brings great difficulty to texture control. Chinese patent CN201811600656.1 discloses a method and a device for preparing marble ceramic tiles with overall texture, the method comprises the steps of scanning selected natural marble stones to obtain a large-amplitude design drawing, manufacturing a grating of blank material pushing and distributing according to the design drawing, pushing the material by using the grating of the design drawing texture to form blank texture, and realizing ink-jet printing of patterns by using the same design drawing, so that the blank texture and the design drawing are combined to form the final overall texture, but multicolor blank powder is mixed by a hopper before entering the grating, so that the blank is formed, the distribution of blank powder with different colors is random, and the natural transition of the blank surface texture in the aspects of shape and color is difficult to ensure.

Ceramic tiles have many advantages of being economical, practical, attractive, easy to clean and the like, and are becoming the main ground decoration materials gradually. The overall visual effect of decoration is too much pursued, so that the major potential safety hazard problem is brought to the surfaces of most ceramic floor tile products because the surfaces are too smooth, and the anti-skid performance of the ceramic tiles is more and more emphasized. However, when the problem of skid resistance of the ceramic tile is solved, the antifouling performance of the ceramic tile is poor, and the preparation of the ceramic tile with the skid resistance and the antifouling function becomes a current technical problem on the premise of ensuring the excellent decorative effect.

Disclosure of Invention

The invention provides a production method of a fully digitalized decorative ceramic polished tile with an antifouling and antiskid function, aiming at solving the problems that in the prior art, after the surface of a ceramic tile needs to be grooved, trimmed or chamfered, the decoration effect is reduced due to the fact that the surface texture of the ceramic tile is inconsistent with the color or texture of a blank body, and the aesthetic feeling is affected, really realizing the natural transition of the surface texture of the blank body in the aspects of shape and color, and endowing the ceramic tile with an antiskid function and excellent antifouling performance.

The invention also aims to provide the fully digitalized decorative ceramic polished tile with the antifouling and anti-skid functions, which is produced by the method.

In order to realize the first invention purpose, the technical scheme adopted by the invention is as follows: the production method of the full-digital decorative ceramic polished tile with antifouling and antiskid functions comprises the following steps:

a) preparing a bottom material and a surface material of the polished tile body according to a conventional method for later use;

b) distributing by adopting a high-precision digital colorful distribution system and a distribution process, forming a ceramic polished tile green body powder material layer with required thickness, and sending the ceramic polished tile green body powder material layer into a press die cavity;

c) pressing and forming a ceramic polished tile blank: pressing a powder material layer of the polished tile green body into a polished tile green body under the pressure of 30-50 MPa;

d) sign marking the texture of the polished ceramic tile blank pressed and formed in the step c) by using sign marking equipment;

e) drying the blank: drying the polished ceramic tile blank marked in the step d) in a drying kiln at 100-300 ℃;

f) carrying out symbol mark identification on the green ceramic polished tile body dried in the step e) by using equipment for identifying symbol marks, and further identifying the texture of the green ceramic polished and rotated body;

g) and (3) spraying penetrating ink: the penetrating ink-jet printer performs jet printing on the corresponding surface pattern texture on the surface of the polished tile body in a contraposition mode according to the texture of the polished tile body identified in the step f), wherein the thickness of the ink-jet layer is 0.3-1 mm;

h) and (3) drying again: drying the ceramic polished tile body subjected to ink jet in the step g) in a drying kiln at 100-300 ℃;

i) and (3) firing: placing the ceramic polished tile blank dried again in the step h) in a roller kiln, and sintering once by using a conventional ceramic polished tile sintering temperature system, a conventional ceramic polished tile sintering pressure system and a conventional atmosphere system, wherein the sintering temperature is 1150-1250 ℃, and the sintering period is 50-160 min, so as to obtain a semi-finished ceramic polished tile product;

j) edging: carrying out edge grinding treatment on the semi-finished polished ceramic tile prepared in the step i) by using conventional edge grinding processing equipment to prepare a fully-digital decorative semi-finished polished ceramic tile;

k) polishing: polishing the semi-finished polished ceramic tile prepared in the step j) to prepare a fully-digital decorative semi-finished polished ceramic tile;

l) coating a multi-component nano anti-slip liquid with an anti-fouling function: and (c) coating the multi-component nano anti-skid liquid with the antifouling function on the surface of the semi-finished product of the fully digitalized decorative ceramic polished tile prepared in the step k) to prepare the fully digitalized decorative ceramic polished tile with the antifouling and anti-skid functions.

In the above steps, the conventional control means in the prior art is adopted, unless otherwise specified.

In order to accomplish the second invention, the fully digital decorative porcelain polished tile with antifouling and antiskid functions, which is produced according to the steps, is adopted.

The high-precision digital colorful material distribution system in the step b) comprises a computer hardware control system, a computer software control system and a high-precision digital colorful material distribution device; the computer hardware control system provides an operating environment of the computer software control system; after the computer software control system inputs the digitized pattern, the high-precision digitized colorful cloth device is driven by control software to complete cloth distribution; the high-precision digital colorful material distribution device comprises a rack, a first transmission belt positioned on the rack, a material distribution system above the starting end along the movement direction of the first transmission belt, a baffle plate at the front end of the material distribution system along the movement direction of the first transmission belt, a material supplementing device at the front end of the baffle plate, a backing material distribution system at the front end of the material supplementing device, and a backing material supplementing device at the front end of the backing material distribution system; the fabric distributing system comprises a second transmission belt and fabric distributing equipment; the fabric distributing equipment comprises a hopper and a sub-conveying belt; the hopper is characterized in that the part in contact with the sub-conveying belt is a liftable metal barrier strip feed opening array controlled by a control software-driven electromagnetic valve; the front ends of the second transmission belts in the motion direction of the sub-transmission belts of each fabric distribution device are respectively provided with a laser detection self-feedback distribution automatic compensation device; the backing material distribution system comprises a third transmission belt and backing material distribution equipment, the structure of the device is the same as that of the backing material distribution system, only the backing material is distributed, and the movement directions of the third transmission belt and the sub-transmission belts of the backing material distribution system are opposite to the movement direction of the first transmission belt; the moving direction of the second transmission belt and the sub-transmission belt of the fabric distributing system is the same as the moving direction of the first transmission belt; and the front ends of the third transmission belts in the motion direction of the sub-transmission belts of each backing material distribution device are respectively provided with a laser detection self-feedback distribution automatic compensation device.

Furthermore, the fabric distributing device of the fabric distributing system comprises a first distributing device, a second distributing device, a third distributing device and a fourth distributing device which are arranged at the starting end along the moving direction of the first transmission belt; the backing material distributing device of the backing material distributing system comprises an eighth distributing device, a seventh distributing device, a sixth distributing device and a fifth distributing device which are arranged at the starting end along the moving direction of the first conveying belt.

Furthermore, the liftable metal barrier strip feed opening array is formed by combining a plurality of independently controlled metal barrier strips.

Furthermore, the number of the metal barrier strips of the liftable metal barrier strip feed opening array is 60-400.

Furthermore, the opening and closing state of the liftable metal barrier strip feed opening array is continuous.

Furthermore, the opening and closing states of the liftable metal barrier strip feed opening array are closing, 1/4 opening, 1/2 opening, 3/4 opening and full opening.

Furthermore, the opening and closing state of the liftable metal barrier strip feed opening array is closed and fully opened.

Furthermore, laser detection self-feedback cloth automatic compensation device monitors the thickness of the blanking layer of each cloth device in advance according to the thickness of the required material layer, feeds back the material layer position with insufficient height, conducts information to the subsequent cloth device needing cloth, and enables the subsequent cloth device to adjust the blanking amount of the material layer position with insufficient height.

The cloth process adopting the high-precision digital colorful cloth system in the step b) is realized by the following mode: when the machine works, a computer software control system inputs digital patterns, the high-precision digital colorful material distribution device is driven to work through control software, material distribution equipment in a material distribution system sequentially discharges materials to form a material layer on a second transmission belt, a backing material distribution system is consistent with the material distribution process of the material distribution system, the starting working time of the backing material distribution system is later than the initial working time of the material distribution system, the material distribution equipment in the backing material distribution system sequentially discharges materials to form a backing material layer on a third transmission belt, the material layer and the backing material layer sequentially fall onto the first transmission belt, the backing material layer falls onto the material layer of the first transmission belt to form a blank powder layer with full texture, and then the blank powder layer with full texture is sent into a die cavity of a press through the first transmission belt to be molded in a back pressure mode; the moving direction of the second transmission belt is the same as that of the first transmission belt; the third transmission belt moves in the direction opposite to the first transmission belt; the front ends of the material distribution devices of the surface material distribution system and the bottom material distribution system are respectively provided with a laser detection self-feedback material distribution automatic compensation device which respectively monitors the heights of the surface material layer and the bottom material layer and feeds information back to the next surface material or bottom material distribution device, and the next surface material or bottom material distribution device adjusts the blanking amount of the material layer with insufficient height of the surface material or bottom material layer according to the fed information.

Further, the cloth process of the high-precision digital multicolor cloth system adopted in the step b) is realized in the following way, when the cloth process works, a computer software control system inputs digital patterns, the high-precision digital multicolor cloth device is driven to work through control software, a fabric cloth system of the high-precision digital multicolor cloth device is sequentially distributed with a first cloth device, a second cloth device, a third cloth device and a fourth cloth device at the starting end along the movement direction of a first transmission belt, and a backing material cloth system of the high-precision digital multicolor cloth device is sequentially distributed with an eighth cloth device, a seventh cloth device, a sixth cloth device and a fifth cloth device at the starting end along the movement direction of the first transmission belt; the hopper of a first material distribution device of the high-precision digital colorful material distribution device starts to feed materials, the thickness and the texture of a material layer which is distributed on a distribution transmission belt of the first material distribution device are controlled by a liftable metal barrier strip feed opening array, the material layer falls onto a second transmission belt, the second transmission belt transmits the material layer to the lower part of a second material distribution device, in the motion process, a laser detection self-feedback material distribution automatic compensation device monitors the height of the material layer which is distributed on the first material distribution device and feeds back the information to the second material distribution device, the second material distribution device adjusts the feed height of the liftable metal barrier strip feed opening array according to the information which is fed back by the laser detection self-feedback material distribution automatic compensation device, powder is distributed on the distribution transmission belt of the second material distribution device by a certain texture to form the thickness of the material layer, and the material layer falls onto the material layer which is distributed on the first material distribution device, the second transmission belt conveys the material layer to the lower part of a third material distribution device to work consistently with the first and the second material distribution devices, the third material distribution device drops the powder material to the upper part of the material layer fed by the first and the second material distribution devices according to the information fed by the laser detection self-feedback material distribution automatic compensation device on the second transmission belt and the front end of the second material distribution device, the second transmission belt conveys the material layer to the lower part of a fourth material distribution device to work consistently with the first, the second and the third material distribution devices, the fourth material distribution device drops the powder material to the upper part of the material layer fed by the first, the second and the third material distribution devices on the second transmission belt and the laser detection self-feedback material distribution automatic compensation device on the front end of the third material distribution device according to the information fed by the laser detection self-feedback material distribution automatic compensation device on the second transmission belt and the sub-transmission belt of the fourth material distribution device, then, the material layer falls onto a first transmission belt through a baffle plate by a laser detection self-feedback cloth automatic compensation device, the material layer is transmitted to the lower part of a material supplementing device by the first transmission belt, and the material supplementing device supplements the material layer on the first transmission belt according to the information fed back by the laser detection self-feedback cloth automatic compensation device at the front end of a fourth material distribution device on a second transmission belt, so that the material layer is formed; the backing material distribution system and the surface material distribution system have the same distribution process, the movement directions of the third transmission belt and the sub-transmission belt of the backing material distribution system are opposite to the movement direction of the first transmission belt, the starting working time of the backing material distribution system is slightly later than the starting working time of the surface material distribution system, when a first distribution device of the surface material distribution system forms a material layer on the second transmission belt, a fifth distribution device of the backing material distribution system starts to discharge materials, the sub-transmission belt of the eighth distribution device drops backing material powder onto the material layers discharged by the fifth, sixth and seventh distribution devices through the same distribution process as the surface material distribution system, then the backing material layer passes through a laser detection self-feedback distribution automatic compensation device at the front end of the eighth distribution device and falls onto the surface material layer of the first transmission belt to form a blank powder material layer with through textures, and then the first transmission belt transmits the blank powder material layer with the through textures to the bottom material supplement device, and the backing material supplementing device performs backing material supplementing on the full-body texture green body powder material layer on the first conveying belt according to the information fed back by the self-feedback material distribution automatic compensation device for laser detection at the front end of the eighth material distribution device on the third conveying belt to form a final full-body texture green body powder material layer, and then sends the full-body texture green body powder material layer into a press die cavity through the first conveying belt for back pressure forming.

Furthermore, the liftable metal barrier strip feed opening arrays at the lower ends of the hoppers in the fabric distribution system and the bottom material distribution system are lifted under the control of control software, and are matched with each other in the direction perpendicular to the movement direction of the first transmission belt to form an opening and closing feeding array.

Furthermore, the opening and closing state of the liftable metal barrier strip feed opening array is continuous, namely the opening and closing state is not limited to the closing state and the opening state, and the opening and closing state can be expanded to various states, such as the continuous state control of closing, 1/4 opening, 1/2 opening, 3/4 opening, full opening and the like, so that the size of the feed opening is controllable. The size of the opening diameter of the feed opening is matched with the opening and closing time, so that on one hand, the shortage part of the cloth layer in the previous process can be compensated; on the other hand, various thick and thin line textures can be flexibly realized. The traditional blanking mode only has two states of full opening and closing, the lines formed by the blanking opening cloth in the full opening state are thick, the details of the texture lines formed by the powder are weakened, and the texture fidelity is reduced; and the material can not be discharged in the closed state. Therefore, the traditional blanking mode has single realization of line texture, and is difficult to present rich texture with natural variation and alternate thickness of natural stone. The invention provides a plurality of choices for texture decoration through redesigning the array of the feed openings controlled by the powder distribution electromagnetic valve, such as thick lines in the texture, and the feed openings controlled by the electromagnetic valve can be selected to be in a fully open state. The fine lines in the grains can select the feed opening controlled by the electromagnetic valve to be in an 1/4 opening state, and the opening diameter of the feed opening controlled by the electromagnetic valve is reasonably regulated and controlled by the digital distributing machine to be switched randomly through the setting of a program, so that the working efficiency of the equipment is improved, and the 'real through' green bricks with fine and vivid grains can be prepared.

Further, the second conveying belt and the third conveying belt move at the same speed, but are higher than the first conveying belt.

Further, the second transmission belt and the third transmission belt have the same moving speed which is 3 times of the moving speed of the first transmission belt.

Furthermore, the feed inlets of the fabric material supplementing device and the bottom material supplementing device are connected with powder, and the feed inlet is funnel-shaped.

Furthermore, the feed openings of the fabric feeding device and the backing material feeding device comprise baffles, and the opening and closing size can be controlled to control the feeding amount.

Furthermore, the material supplementing device and the base material supplementing device can move along the moving direction of the first conveying belt and in the direction perpendicular to the moving direction of the first conveying belt, namely, the materials can be supplemented flexibly in the whole plane range parallel to the material layer according to the requirement.

Further, the powder filled in the hoppers of the backing material distribution device and the surface material distribution device can be single color powder of a single formula or powder mixed by multiple formulas and colors.

The symbol marking equipment in the step d) consists of a laser sensor, a spray gun, an ink box filled with ink, a network receiver, a control circuit and an operation display screen.

The working process of the symbol marking device in the step d) is as follows: when the conveying bearing conveys the blanks to the laser sensor, the sensor senses that the blanks reach the identification area, the light signals are converted into electric signals, the working current of the spray gun is started, and then the spray gun sprays the markers on the side faces of the blanks, and each blank is required to be guaranteed to have a unique mark symbol. The network receiver ensures that the equipment is in a networking state, the network is utilized to transmit the working instruction marked by the equipment to the identification mark symbol device, and the identification mark symbol device commands the ink-jet printer to spray and print the patterns which are the same as the texture of the blank body through the identification marker, and ensures that the ink-jet printing texture is completely overlapped with the texture of the blank body without dislocation between the ink-jet texture and the texture of the blank body.

The equipment for recognizing the symbol mark in the step f) consists of a laser sensor, a network receiver, a control circuit and an operation display screen.

The working process of the device for recognizing the symbol mark in the step f) is as follows: by identifying the markers on the side surface of the blank body, each marker corresponds to an ink-jet printing file, when the marked blank body is conveyed to a laser sensor identification area of identification marking equipment by a conveying bearing, a laser optical signal is converted into an electric signal, an identification device issues an instruction to an ink-jet machine, the ink-jet machine sprays and prints patterns consistent with the texture of the blank body, the ink-jet printing texture is completely overlapped with the texture of the blank body, and the dislocation between the ink-jet texture and the texture of the blank body does not exist, so that the full-automatic accurate alignment of the texture of the blank body and the ink-jet texture is realized.

The marks have one-to-one correspondence with the textures of the blank, and the equipment for identifying the marks can transmit instructions to spray different patterns to an ink-jet printer according to the difference of the marks, so that the overall texture of the blank from top to bottom is finally realized.

Further, in the step d), the symbol marking device marks the edge of the polished tile blank formed in the step b).

Further, the symbol marked by the symbol marking device in the step d) is a single independent symbol which can be identified, such as 1, 2, 3 … …; or a, b, c … …. The mark marked by the traditional marking equipment is an identification texture formed by a plurality of marks together, for example, a dot-shaped mark, and a marked whole body texture is a 3 rd pattern, and is marked as 3 points (a.cndot.) on the edge of a blank, but once the blank is rubbed during the conveying process, or 1 or half of the points are shielded by dust impurities, the equipment marked by the identification mark cannot identify or identifies wrongly. The invention can mark and identify single independent symbol, the number of independent symbols can be single or multiple by improving the symbol marking device and the device technology for identifying symbol mark.

Further, the number of the symbols marked on the edge of the single blank by the symbol marking device in the step d) is 3-6.

Further, a step of spreading ceramic surface slurry by polishing the ceramic tiles is added between the step e) and the step f), and a step of drying is added after the ceramic surface slurry of the polished ceramic tiles is spread.

Further, the multi-component nano anti-slip liquid with the antifouling function in the step l) comprises two or more of a component A, a component B and a component C;

further, the component A of the step l) is nano organic silica sol;

further, the chemical components of the component B and the component C in the step l) are the same in type;

further, the chemical components of the component B and the component C in the step l) comprise organic acid or inorganic acid, surfactant, drier, solvent and the like;

further, the multicomponent nano anti-skid fluid with the antifouling function in the step l) is characterized in that the organic acid or inorganic acid is selected from one or more of sulfamic acid, glycolic acid, ethylenediamine tetraacetic acid, benzoic acid, acetic acid and diluted phosphoric acid;

further, the multicomponent nano-antislip liquid with the antifouling function in the step l) is characterized in that the drier is selected from one or more of caprylate, abietate and linoleate;

further, the multi-component nano anti-slip liquid with the antifouling function in the step l) is characterized in that the anti-slip liquid of the component B comprises the following raw materials in percentage by weight: 5 to 35 percent of organic acid or inorganic acid, 1 to 5 percent of surfactant, 0.1 to 2 percent of drier and the balance of solvent.

Further, the multi-component nano anti-slip liquid with the antifouling function in the step l) is characterized in that the anti-slip liquid of the component C comprises the following raw materials in percentage by weight: 5 to 40 percent of organic acid or inorganic acid, 6 to 10 percent of surfactant, 0.1 to 2 percent of drier and the balance of solvent. The component A with the antifouling effect, namely the nano organic silica sol, is coated to fill the cavities on the surface of the fully digitalized decorative polished ceramic tile, so that the antifouling effect of the polished ceramic tile is improved. The chemical components of the component B and the component C are the same in type, and have content difference, so that the component B and the component C ensure that the ceramic tile has excellent antifouling and antiskid properties no matter in a dry state or a wet state. The principle is that the content and the type of organic acid or inorganic acid are adjusted to control the damage degree of acidic substances to silicate structures, nano-scale concave holes are left on the surfaces of ceramic tiles after the acidic substances corrode the ceramic tiles, nano-uneven structures are formed on the surfaces of the ceramic tiles after the anti-slip liquid is dried, when a person walks on the ceramic tiles in a wet state, the nano-scale concave holes can form mechanical biting force with a vamp under pressure, and the uneven concave structures can generate negative pressure with a contact surface under pressure to form suction. Under the synergistic effect of the two structures, the anti-skid effect of the brick surface is greatly improved, the nano-scale uneven surface hollow structure is formed after the anti-skid liquid is dried, and most of stains or dust are in the micron level, so that the stains or dust are difficult to enter the cavity of the nano-scale uneven surface hollow structure, and the antifouling performance of the brick surface is ensured. The surfactant adjusts the wetting angle of the anti-skid liquid on the surface of the ceramic tile, so that the anti-skid liquid can be spread on the surface of the ceramic tile. The drying speed of the anti-skid liquid can be adjusted by adding the drier, for example, Chinese patent CN109678561, a nano hydrogel anti-skid and anti-fouling material, a preparation method and application thereof, the patent indicates that the ceramic tile coated with the anti-skid liquid needs to be dried at a high temperature of 100-190 ℃, the anti-skid liquid prepared by the invention does not need a high-temperature drying process link, and the waste of energy is avoided.

The nanometer anti-slip liquid of the component B and the nanometer anti-slip liquid of the component C have chemical content difference, so that the component C forms more nanometer concave holes on the surface of the ceramic tile, the surface roughness of the ceramic tile is improved, gaps among layers of the microstructure of the formed polymer film are larger, the absorption of water on the surface of the ceramic tile is facilitated, and finally the nanometer anti-slip liquid of the component C has better antifouling and anti-slip performances when meeting water, and is compared with the component B.

The fully-digitalized decorative ceramic polished tile with antifouling and antiskid functions, prepared by the invention, has a wet static friction coefficient of more than 0.71, a dry static friction coefficient of more than 0.75 and pollution resistance of more than 4 or 4.

The invention has the following beneficial effects: the continuous through texture is realized by accurately positioning, fixing points and quantitatively distributing powder with various compositions and colors, and the penetrating ink-jet pattern is accurately aligned and jet-printed on the surface of the blank by combining a symbol marking-symbol marking identification process to form the through texture from top to bottom and from the surface to the inside, so that the perfect connection of the surface texture of the blank and the texture of the through cloth is really realized, and the problems that in the decoration process, after the groove drawing, the trimming or the chamfering is needed on the surface of the ceramic tile, the decoration effect is reduced and the aesthetic feeling is influenced due to the inconsistency between the surface texture of the ceramic tile and the color or the texture of the blank are solved. The multi-component nano anti-skid liquid ensures the anti-skid and anti-fouling performance of the ceramic tile on the premise of high glossiness, and solves the technical problem that the anti-skid and anti-fouling performance of the ceramic tile are difficult to be compatible.

The fully-digital decorative porcelain polishing with the antifouling and antiskid functions and the preparation method thereof are simple and easy to implement, and have good decoration and excellent antifouling and antiskid functions.

Drawings

FIG. 1 is a process flow chart of the production of the fully digitalized decorative tile with anti-fouling and anti-skid functions of the present invention.

Fig. 2 is a schematic diagram of the blank marked by the symbol marking device, wherein the number of the marked symbols is 6, and the marked symbols mean that a 3 rd texture pattern is adopted.

FIG. 3 is a diagram of the full-digital high-precision decoration effect formed after the identification symbol is marked and ink is injected by contraposition permeation.

Fig. 4 is a structural diagram of the components of the high-precision digital multicolor fabric system of the invention.

FIG. 5 is a schematic view of a high-precision digital multicolor distributing device according to the present invention.

Fig. 6 is a schematic diagram of a liftable metal barrier strip feed opening array controlled by a control software-driven solenoid valve.

In FIG. 3, A is the texture of the surface of the blank formed after the ink is injected by the contraposition permeation, and B is the texture of the whole body formed by the high-precision digital multicolor cloth system.

In FIG. 5, 1-the gantry; 2-a first conveyor belt; 3-fabric material distribution system; 4-a second conveyor belt; 5-fabric distributing equipment; 6-a fabric hopper; 6-1-a metal barrier strip feed opening array capable of being lifted; 7, distributing a fabric material system by a transmission belt; 8-laser detection self-feedback cloth automatic compensation device; 9-baffle plate; 10-fabric feeding device; 11-bed charge distribution system; 12-third conveyor belt; 13-bed charge distribution equipment; 14-bottom material hopper; 15-a backing material distributing system is divided into a conveying belt; 16-primer feeding device, and the arrow indicates the belt advancing direction.

In FIG. 6, 6-1-an array of liftable metal barrier strip feed openings; and 7, distributing the fabric material system by a transmission belt.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

As shown in fig. 1 to 6, the present invention is realized by the following steps:

the high-precision digital colorful cloth system comprises a computer hardware control system, a computer software control system and a high-precision digital colorful cloth device; the computer hardware control system provides an operating environment of the computer software control system; after the computer software control system inputs the digitized pattern, the high-precision digitized colorful cloth device is driven by control software to complete cloth distribution; the high-precision digital colorful material distribution device comprises a rack 1, a first transmission belt 2 positioned on the rack, a material distribution system 3 above the starting end along the movement direction of the first transmission belt 2, a baffle 9 at the front end of the material distribution system 3 along the movement direction of the first transmission belt 2, a material supplementing device 10 at the front end of the baffle 9, a backing material distribution system 11 at the front end of the material supplementing device 10, and a backing material supplementing device 16 at the front end of the backing material distribution system 11; the fabric distributing system 3 comprises a second transmission belt 4 and fabric distributing equipment 5; the fabric distributing device 5 comprises a hopper 6 and a sub-conveying belt 7; the contact part of the hopper 6 and the sub-conveying belt 7 is a liftable metal barrier strip feed opening array 6-1 controlled by a control software-driven electromagnetic valve; the front ends of the second transmission belts 4 in the motion direction of the sub-transmission belts 7 of each fabric distribution device 5 are respectively provided with a laser detection self-feedback distribution automatic compensation device 8; the backing material distribution system 11 comprises a third transmission belt 12 and a backing material distribution device 13, the device structure of the backing material distribution system 11 is the same as that of the backing material distribution system 3, only backing materials are distributed, and the moving directions of the third transmission belt 12 and a sub-transmission belt 15 of the backing material distribution system 11 are opposite to the moving direction of the first transmission belt 2; the moving directions of the second transmission belt 4 and the sub-transmission belt 7 of the fabric distribution system 3 are the same as the moving direction of the first transmission belt 2; and the front ends of the third conveying belts 12 in the motion direction of the sub-conveying belts 15 of each backing material distribution device 13 are respectively provided with a laser detection self-feedback distribution automatic compensation device 8.

Laser detection self-feedback cloth automatic compensation device monitors the bed thickness of unloading of every cloth equipment according to required bed thickness in advance, feeds back the bed position of the material of not enough height, with information conduction to the follow-up cloth equipment that needs the cloth, make follow-up cloth equipment carry out the unloading volume adjustment to the bed position of the material of not enough height, the adjustment mode is through control software drive solenoid valve control liftable metal blend stop feed opening array, make liftable metal blend stop feed opening array rise, increase the unloading volume to compensate the vacancy of the not enough height of preceding cloth bed of material.

The fabric distributing device of the fabric distributing system comprises a first distributing device, a second distributing device, a third distributing device and a fourth distributing device which are arranged at the starting end along the movement direction of the first transmission belt; the backing material distributing device of the backing material distributing system comprises an eighth distributing device, a seventh distributing device, a sixth distributing device and a fifth distributing device which are arranged at the starting end along the moving direction of the first conveying belt.

The working process is as follows: when the automatic material distribution device works, a computer software control system inputs digital patterns, the high-precision digital colorful material distribution device is driven to work through control software, a first material distribution device hopper 6 of a material distribution device 5 in a material distribution system 3 of the high-precision digital colorful material distribution device starts to feed materials, the thickness and the texture of a material layer laid on a first material distribution device distribution transmission belt 7 are controlled through a liftable metal barrier strip feed opening array 6-1, the material layer falls onto a second transmission belt 4, the material layer is conveyed to the lower part of a second material distribution device by the second transmission belt 4, in the movement process, a laser detection self-feedback material distribution automatic compensation device 8 monitors the height of the material layer fed by the first material distribution device and feeds information back to the second material distribution device, and the second material distribution device feeds back the information according to the laser detection self-feedback material distribution automatic compensation device 8, the blanking height of the blanking opening array 6-1 of the liftable metal barrier strip is adjusted, powder is spread on a second distribution equipment distribution belt in certain texture, the thickness of a material layer is formed, the material layer falls on the material layer distributed by a first distribution equipment, the second distribution equipment 4 conveys the material layer to the lower part of a third distribution equipment, the work of the third distribution equipment is consistent with that of the first distribution equipment and the second distribution equipment, the blanking of the third distribution equipment is carried out according to the information fed back by a laser detection self-feedback distribution automatic compensation device 8 at the front end of the second distribution equipment on the second conveying belt 4, the powder falls on the blanking layers of the first distribution equipment and the second distribution equipment through the distribution conveying belt of the third distribution equipment, the material layer is conveyed to the lower part of the fourth distribution equipment by the second conveying belt 4 and is consistent with the work of the first distribution equipment, the second distribution equipment and the third distribution equipment, the fourth distribution equipment is according to the second conveying belt 4, the laser detection of third cloth equipment front end is from the information unloading of feedback cloth automatic compensation arrangement 8, fall the powder to second transmission belt 4 through the branch transmission belt of fourth cloth equipment on first, second, third cloth equipment blanking layer, later, the bed of material passes through laser detection from feedback cloth automatic compensation arrangement 8, fall to first transmission belt 2 through baffle 9 on, first transmission belt carries the bed of material to surface fabric feed supplement device 10 below, surface fabric feed supplement device 10 is according to the laser detection of fourth cloth equipment front end on second transmission belt 4 from the information that feedback cloth automatic compensation arrangement 8 feedbacks, the surface fabric bed of material on first transmission belt 2 carries out the feed supplement, thereby form the surface fabric bed of material.

The work time of the backing material distribution system 11 is slightly later than the work time of the fabric distribution system 3, when the first material distribution device of the fabric distribution system 3 forms a material layer on the second transmission belt 4, the fifth material distribution device hopper 14 of the backing material distribution system 11 starts to feed, the material distribution process of the backing material distribution system 11 is consistent with the material distribution process of the fabric distribution system 3, the movement direction of the third transmission belt 12 and the sub-transmission belt 15 of the backing material distribution system 11 is opposite to the movement direction of the first transmission belt 2, the sub-transmission belt of the eighth material distribution device drops the backing material powder onto the material layers fed by the fifth, sixth and seventh material distribution devices through the material distribution process same with the fabric distribution system 3, and then the backing material layer passes through the laser detection self-feedback material distribution automatic compensation device 8 at the front end of the eighth material distribution device and drops onto the fabric layer of the first transmission belt 2, the blank powder material layer with the full body texture is formed and is then transmitted to the lower part of a backing material supplementing device 16 through a first transmission belt 2, the backing material supplementing device 16 performs backing material supplementing on the full body texture blank powder material layer on the first transmission belt 2 according to information fed back by a self-feedback material distribution automatic compensation device 8 detected by laser at the front end of eighth material distribution equipment on a third transmission belt 12, a final full body texture blank powder material layer is formed, and then the full body texture blank powder material layer is sent into a press die cavity through the first transmission belt to be subjected to back pressure forming.

The liftable metal barrier strip lower opening array 6-1 is controlled by a control software-driven electromagnetic valve, the opening and closing state is continuous, the liftable metal barrier strip lower opening array 6-1 comprises 180 metal barrier strips in the direction perpendicular to the first transmission belt 2, the opening and closing state adopts the closing, 1/4 opening, 1/2 opening, 3/4 opening and full opening states which are unevenly distributed, and diversified textures such as thick lines, patches, pockmarks and the like are realized.

The second transmission belt 4 and the third transmission belt 12 move at the same speed which is 3 times of the speed of the first transmission belt 2.

d) marking the green body formed by pressing in the step c) with symbols by using symbol marking equipment, wherein the number of the marked symbols is 6, and the symbol pattern is '3';

e) drying the blank: drying the ceramic polished tile green body marked in the step d) in a drying kiln at the temperature of 100-300 ℃;

f) applying porcelain facing slurry;

g) drying after the ceramic surface slurry is applied, and drying the ceramic polished tile green body subjected to the ceramic surface slurry application in the step f) in a drying kiln at the temperature of 100-300 ℃;

h) identifying the blank texture of the blank dried again in the step g) by using equipment for identifying the mark symbol;

i) and (3) spraying penetrating ink: b, the penetrating ink-jet printer performs jet printing on the corresponding surface pattern texture on the surface of the blank in a contraposition mode according to the blank texture identified in the step h), wherein the thickness of the ink-jet layer is 0.3-1 mm;

j) and (3) drying again: drying the ceramic polished tile body subjected to ink jet in the step i) in a drying kiln at 100-300 ℃;

k) and (3) firing: placing the ceramic polished tile green body dried for the third time in the step j) into a roller kiln, and sintering once by using a conventional ceramic polished tile sintering temperature system, a conventional ceramic polished tile sintering pressure system and a conventional atmosphere system, wherein the sintering temperature is 1150-1250 ℃, and the sintering period is 50-160 min, so as to obtain a ceramic polished tile semi-finished product;

l) edging: performing edge grinding treatment on the semi-finished polished ceramic tile prepared in the step k) by using conventional edge grinding processing equipment to prepare a fully-digital decorative semi-finished polished ceramic tile;

m) polishing: polishing the fully-digital decorative ceramic polished tile semi-finished product prepared in the step l) to prepare a fully-digital decorative ceramic polished tile semi-finished product;

n) coating multi-component nano anti-skid liquid with an anti-fouling function: respectively coating the A component nanometer anti-slip liquid and the B component nanometer anti-slip liquid with the antifouling function on the surface of the fully digitalized decorative ceramic polished tile semi-finished product prepared in the step m) to prepare the fully digitalized decorative ceramic polished tile with the antifouling and anti-slip functions.

The fully digitalized polished decorative porcelain tile with the antifouling and antiskid functions, prepared by the embodiment, has a wet static friction coefficient of 0.71, a dry static friction coefficient of 0.76 and a pollution resistance of 4 grades.

The above embodiments are only for illustrating the technical solutions of the present invention and not for limiting the same, although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those of ordinary skill in the art. Modifications to the embodiments of the invention or equivalent substitutions of parts of the technical features can be made without departing from the spirit of the technical solution of the invention, which is to be covered by the technical solution of the invention.

Claims

1. A production method of a full-digital decorative ceramic polished tile with antifouling and antiskid functions is characterized by comprising the following steps:

f) carrying out symbol mark identification on the green ceramic polished tile body dried in the step e) by using equipment for identifying symbol marks, and further identifying the texture of the green ceramic polished tile body;

l) coating a multi-component nano anti-slip liquid with an anti-fouling function: coating the multi-component nano anti-skid liquid with the antifouling function on the surface of the semi-finished product of the fully digitalized decorative ceramic polished tile prepared in the step k) to prepare the fully digitalized decorative ceramic polished tile with the antifouling and anti-skid functions;

the high-precision digital colorful material distribution system in the step b) comprises a computer hardware control system, a computer software control system and a high-precision digital colorful material distribution device; the computer hardware control system provides an operating environment of the computer software control system; after the computer software control system inputs the digitized pattern, the high-precision digitized colorful cloth device is driven by control software to complete cloth distribution; the high-precision digital colorful material distribution device comprises a rack, a first transmission belt positioned on the rack, a material distribution system above the starting end along the movement direction of the first transmission belt, a baffle plate at the front end of the material distribution system along the movement direction of the first transmission belt, a material supplementing device at the front end of the baffle plate, a backing material distribution system at the front end of the material supplementing device, and a backing material supplementing device at the front end of the backing material distribution system; the fabric distributing system comprises a second transmission belt and fabric distributing equipment; the fabric distributing equipment comprises a hopper and a sub-conveying belt; the hopper is characterized in that the part in contact with the sub-conveying belt is a liftable metal barrier strip feed opening array controlled by a control software-driven electromagnetic valve; the front ends of the second transmission belts in the motion direction of the sub-transmission belts of each fabric distribution device are respectively provided with a laser detection self-feedback distribution automatic compensation device; the backing material distribution system comprises a third transmission belt and backing material distribution equipment, the structure of the device is the same as that of the backing material distribution system, only the backing material is distributed, and the third transmission belt and the backing material distribution system divide the movement direction of the transmission belt and are opposite to the movement direction of the first transmission belt; the moving direction of the second transmission belt and the sub-transmission belt of the fabric distributing system is the same as the moving direction of the first transmission belt; laser detection self-feedback cloth automatic compensation devices are arranged on the third transmission belts and at the front ends of the third transmission belts in the movement direction of the sub-transmission belts of each backing material distribution device;

the material distribution process of the high-precision digital colorful material distribution system in the step b) is as follows: when the machine works, a computer software control system inputs digital patterns, the high-precision digital colorful material distribution device is driven to work through control software, material distribution equipment in a material distribution system sequentially discharges materials to form a material layer on a second transmission belt, a backing material distribution system is consistent with the material distribution process of the material distribution system, the starting working time of the backing material distribution system is later than the initial working time of the material distribution system, the material distribution equipment in the backing material distribution system sequentially discharges materials to form a backing material layer on a third transmission belt, the material layer and the backing material layer sequentially fall onto the first transmission belt, the backing material layer falls onto the material layer of the first transmission belt to form a blank powder layer with full texture, and then the blank powder layer with full texture is sent into a die cavity of a press through the first transmission belt to be molded in a back pressure mode; the moving direction of the second transmission belt is the same as that of the first transmission belt; the third transmission belt moves in the direction opposite to the first transmission belt; the front ends of the material distribution devices of the surface material distribution system and the bottom material distribution system are respectively provided with a laser detection self-feedback material distribution automatic compensation device which respectively monitors the heights of the surface material layer and the bottom material layer and feeds information back to the next surface material or bottom material distribution device, and the next surface material or bottom material distribution device adjusts the blanking amount of the material layer with insufficient height of the surface material or bottom material layer according to the fed information.

2. The method for producing the fully digitalized decorative polished tile with anti-fouling and anti-skid functions as claimed in claim 1, wherein the liftable metal barrier strip feed opening array is formed by combining a plurality of independently controlled metal barrier strips.

3. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: the number of the metal barrier strips of the liftable metal barrier strip feed opening array is 60-400.

4. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: the opening and closing state of the liftable metal barrier strip feed opening array is continuous.

5. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 4, wherein: the opening and closing states of the liftable metal barrier strip feed opening array are closing, 1/4 opening, 1/2 opening, 3/4 opening and full opening.

6. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 5, wherein: the opening and closing state of the liftable metal barrier strip feed opening array is closing and full opening.

7. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: the laser detection self-feedback cloth automatic compensation device monitors the thickness of a blanking layer of each cloth device in advance according to the required thickness of the material layer, feeds back the position of the material layer with insufficient height, transmits information to the subsequent cloth device needing cloth, and enables the subsequent cloth device to adjust the blanking amount of the material layer with insufficient height.

8. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: the fabric distributing system is characterized in that a first distributing device, a second distributing device, a third distributing device and a fourth distributing device are sequentially distributed at the starting end along the moving direction of the first transmission belt, and an eighth distributing device, a seventh distributing device, a sixth distributing device and a fifth distributing device are sequentially distributed at the starting end along the moving direction of the first transmission belt.

9. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 8, wherein: the material distribution process of the high-precision digital colorful material distribution system in the step b) is as follows: when the high-precision digital colorful material distribution device works, a computer software control system inputs digital patterns, the high-precision digital colorful material distribution device is driven to work through control software, a fabric material distribution system of the high-precision digital colorful material distribution device is sequentially provided with a first material distribution device, a second material distribution device, a third material distribution device and a fourth material distribution device at the starting end along the movement direction of a first transmission belt, and a backing material distribution system of the high-precision digital colorful material distribution device is sequentially provided with an eighth material distribution device, a seventh material distribution device, a sixth material distribution device and a fifth material distribution device at the starting end along the movement direction of the first transmission belt; the hopper of a first distributing device of a high-precision digital colorful distributing device starts to feed, the thickness and the texture of a material layer which is spread on a distribution transmission belt of the first distributing device are controlled by a liftable metal barrier strip feed opening array, the material layer falls onto a second transmission belt, the material layer is conveyed to the lower part of the second distributing device by the second transmission belt, in the motion process, a laser detection self-feedback distributing automatic compensation device at the front end of the first distributing device monitors the height of the material layer which is fed by the first distributing device and feeds back the information to the second distributing device, the second distributing device adjusts the feed height of the liftable metal barrier strip feed opening array according to the information which is fed back by the laser detection self-feedback distributing automatic compensation device, powder is spread on the distribution transmission belt of the second distributing device by a certain texture to form the thickness of the material layer, and the material layer falls onto the material layer which is distributed by the first distributing device, the second transmission belt conveys the material layer to the position below a third material distribution device, then the third material distribution device and a fourth material distribution device sequentially perform blanking according to the same working process, then the material layer passes through a laser detection self-feedback material distribution automatic compensation device at the front end of the fourth material distribution device and falls onto the first transmission belt through a baffle, the first transmission belt conveys the material layer to the position below a material supplementing device, and the material supplementing device supplements the material for the material layer on the first transmission belt according to the information fed back by the laser detection self-feedback material distribution automatic compensation device at the front end of the fourth material distribution device, so that the material layer is formed; the backing material distribution system and the surface material distribution system have the same distribution process, the motion directions of the third transmission belt and the sub-transmission belt of the backing material distribution system are opposite to the motion direction of the first transmission belt, the starting working time of the backing material distribution system is slightly later than the starting working time of the surface material distribution system, when a first distribution device of the surface material distribution system forms a material layer on the second transmission belt, a fifth distribution device of the backing material distribution system starts to discharge materials, the sub-transmission belt of the eighth distribution device drops backing material powder onto the material layers discharged by the fifth, sixth and seventh distribution devices through the same distribution process as the surface material distribution system, and then the backing material layer passes through a laser detection self-feedback distribution automatic compensation device at the front end of the eighth distribution device and falls onto the surface material layer of the first transmission belt to form a blank powder layer with through textures, and then is transmitted to the lower part of the backing material device through the first transmission belt, and the backing material supplementing device performs backing material supplementing on the full-body texture green body powder material layer on the first conveying belt according to the information fed back by the self-feedback material distribution automatic compensation device for laser detection at the front end of the eighth material distribution device on the third conveying belt to form a final full-body texture green body powder material layer, and then sends the full-body texture green body powder material layer into a press die cavity through the first conveying belt for back pressure forming.

10. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the lower end of the hopper in the fabric distribution system and the bottom material distribution system is provided with a liftable metal barrier strip feed opening array which is controlled by control software to lift.

11. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 10, wherein: the liftable metal barrier strip feed opening array is an array for opening and closing feed formed by mutually matching a plurality of metal barrier strips in a direction vertical to the motion direction of the first transmission belt.

12. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the number of the metal barrier strips of the liftable metal barrier strip feed opening array is 60-400.

13. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the opening and closing state of the liftable metal barrier strip feed opening array is continuous.

14. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 13, wherein: the opening and closing states of the liftable metal barrier strip feed opening array are closing, 1/4 opening, 1/2 opening, 3/4 opening and full opening.

15. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 14, wherein: the opening and closing state of the liftable metal barrier strip feed opening array is closing and full opening.

16. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the second conveying belt and the third conveying belt move at the same speed but are higher than the first conveying belt.

17. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 16, wherein: the second transmission belt and the third transmission belt have the same movement speed which is 3 times of the movement speed of the first transmission belt.

18. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the material supplementing device for the fabric and the material supplementing device for the bottom material are funnel-shaped.

19. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the feed openings of the fabric material supplementing device and the bottom material supplementing device comprise baffles.

20. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 9, wherein: the surface material supplementing device and the bottom material supplementing device move in the whole plane range parallel to the material layer to supplement materials.

21. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: and c) the symbol marking equipment consists of a laser sensor, a spray gun, an ink box filled with ink, a network receiver, a control circuit and an operation display screen.

22. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: the equipment for identifying the symbol mark in the step e) consists of a laser sensor, a network receiver, a control circuit and an operation display screen.

23. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: and the symbol marking equipment in the step c) marks the edge of the polished tile blank formed in the step b).

24. The method for producing the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 23, wherein: the symbol marked by the symbol marking device in the step c) is a single independent symbol which can be identified.

25. The production method of the fully digitalized decorative tile with antifouling and anti-skid functions as claimed in claim 1, wherein: and a step of applying ceramic surface slurry of polished ceramic tiles is added between the step e) and the step f), and a step of drying is added after the ceramic surface slurry of polished ceramic tiles is applied.

26. The method for producing the fully digitalized decorative tile with antifouling and anti-slip functions according to claim 1, wherein the multi-component nano anti-slip liquid with antifouling function of step l) comprises two or more of a component A, a component B and a component C.

27. The method for producing the fully digitalized decorative tile with anti-fouling and anti-slip functions as claimed in claim 26, wherein the component A is nano organic silica sol.

28. The method for producing the fully digitalized decorative tile with anti-fouling and anti-slip functions as claimed in claim 26, wherein the chemical components of the B component and the C component are the same.

29. The method for producing the fully digitalized decorative tile with anti-fouling and anti-slip functions as claimed in claim 28, wherein the chemical components of the component B and the component C are organic or inorganic acids, surfactants, driers and solvents.

30. The method for producing the fully digitalized decorative tile with anti-fouling and anti-slip functions as claimed in claim 29, wherein the organic or inorganic acid is selected from one or more of sulfamic acid, glycolic acid, ethylenediaminetetraacetic acid, benzoic acid, acetic acid, and diluted phosphoric acid.

31. The method for producing fully digitalized decorative tile with anti-fouling and anti-slip functions as claimed in claim 29, wherein said drier is selected from one or more of caprylate, abietate and linoleate.

32. The method for producing the fully digitalized decorative tile with anti-fouling and anti-skid functions as claimed in claim 29, wherein the component B comprises the following raw materials in percentage by weight: 5 to 35 percent of organic acid or inorganic acid, 1 to 5 percent of surfactant, 0.1 to 2 percent of drier and the balance of solvent.

33. The method for producing the fully digitalized decorative tile with anti-fouling and anti-skid functions as claimed in claim 29, wherein the component C comprises the following raw materials in percentage by weight: 5 to 40 percent of organic acid or inorganic acid, 6 to 10 percent of surfactant, 0.1 to 2 percent of drier and the balance of solvent.

34. The fully digitalized decorative ceramic tile with antifouling and anti-skid functions, produced by the method for producing the fully digitalized decorative ceramic tile with antifouling and anti-skid functions of any one of claims 1 to 33.