CN209937229U - Fine-grain through-body ceramic material distribution system - Google Patents

Abstract

The utility model discloses a distributing system of fine grain through body ceramics, which comprises a conveying carrier, and at least one group of pattern distributing device, a material supplementing device, at least one group of fine grain distributing device and a press are arranged along the conveying direction of the conveying carrier in sequence; the group of pattern distributing devices correspond to one pattern texture, wherein the pattern distributing devices pre-distribute the material to the conveying carrier based on the preset pattern texture so as to form at least one pattern texture on the conveying carrier; the material supplementing device distributes materials to the conveying carrier based on preset pattern textures, so that gaps among the pattern textures and a vacant region on the periphery of the pattern textures are filled in the conveying carrier to form a blank; the group of fine grain distributing devices correspond to a fine grain pattern, wherein each group of fine grain distributing devices separates and packs the blank on the conveying carrier based on the preset pattern texture so as to form the fine grain pattern on the blank; the press is arranged at the tail end of the conveying carrier and is used for pressing and forming the blank body with the fine grain pattern.

Description

Fine-grain through-body ceramic material distribution system

Technical Field

The utility model belongs to the technical field of the ceramic manufacture technique and specifically relates to a thin line general pottery's cloth system is related to.

Background

Marble has been popular with users as a high-grade decorative material because of its rich texture and noble decorative effect. However, marble is expensive and radioactive, and thus it is difficult to widely spread marble. Therefore, the surface texture marble-imitated ceramic tiles appear in the market and are popular with consumers, but the surface texture of the marble-imitated ceramic tiles has little change, and the texture effect of the surface layer of the product is inconsistent with the internal texture effect of the product; with the continuous development of the ceramic industry, the traditional marble-imitated ceramic tiles are commonly called as 'fake full-body ceramic tiles', and when people choose full-body ceramic tiles, people do not only need to ask for aesthetic feeling brought by the texture effect of the surface of the product, but also put forward a new requirement on the consistency of the texture effect of the interior and the surface of the product, and at the moment, the 'real full-body ceramic tiles' also gradually become the consumption direction pursued by consumers.

However, because the processing of the 'full body ceramic tile' has great difficulty, the stripe pattern of the 'full body ceramic tile' which is generally processed cannot achieve the expected bulk effect, the pattern stripes are rough, and meanwhile, the 'full body ceramic tile' is difficult to process and has abundant and various patterns.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a be not enough to prior art, the utility model aims to a ceramic pattern texture that enables to process is abundanter various, and the pattern is more exquisite, the fine lines whole body pottery's cloth system that the cloth accuracy is high.

In order to achieve the above purpose, the utility model provides a scheme does: a fine grain through body ceramic material distribution system comprises a conveying carrier, wherein at least one group of pattern material distribution devices, a material supplementing device, at least one group of fine grain material distribution devices and a press are sequentially arranged along the conveying direction of the conveying carrier; the group of pattern distributing devices correspond to one pattern texture, wherein the pattern distributing devices pre-distribute the material to the conveying carrier based on the preset pattern texture so as to form at least one pattern texture on the conveying carrier; the material supplementing device distributes materials to the conveying carrier based on preset pattern textures, so that gaps among the pattern textures and a vacant region on the periphery of the pattern textures are filled in the conveying carrier to form a blank; the group of the fine grain distributing devices correspond to a fine grain pattern, wherein each group of the fine grain distributing devices separates and packs the blanks on the conveying carrier based on the preset pattern texture so as to form the fine grain pattern on the blanks; the press is arranged at the tail end of the conveying carrier and is used for pressing and forming the blank body with the fine grain pattern.

Furthermore, the pattern distributing device comprises a wide distributing hopper, a distributing seat and a plurality of flashboard mechanisms arranged on the distributing seat, wherein the distributing hopper is fixedly arranged on the top surface of the distributing seat, and a powder outlet at the bottom of the distributing hopper is communicated with a pre-formed collecting cavity on the top surface of the distributing seat; a plurality of fine distribution holes which are arranged side by side are formed in the bottom surface of the distribution base, wherein any two adjacent fine distribution holes are abutted against each other, and the top end of each fine distribution hole is communicated with the bottom end of the material collection cavity; each fine material distribution hole corresponds to one flashboard mechanism to independently control the opening and closing of the fine material distribution hole, wherein each flashboard mechanism comprises a powder flashboard arranged at the fine material distribution hole and a driving unit driving the powder flashboard to horizontally reciprocate and translate, and the powder flashboard is driven to reciprocate and translate through the driving unit so as to shield or avoid the fine material distribution hole; any one of the fine distributing holes vertically corresponds to a distributing point right below the distributing seat, and all the distributing points are sequentially connected in series to form a connected straight line.

Further, a plurality of flashboard mechanism equally divide into two sets ofly to arrange the flashboard subassembly in slight cloth hole both sides, wherein, two sets of be equidistant staggered arrangement or arrange side by side between each flashboard mechanism of flashboard subassembly.

Further, a plurality of groups of fine grain distributing devices are included, wherein the plurality of groups of fine grain distributing devices are sequentially arranged along the conveying direction of the conveying carrier; and the multiple groups of fine grain distributing devices sequentially process fine grain patterns on the blank on the conveying carrier.

Further, any group of the fine grain distribution devices comprises a distribution head and a driving assembly, wherein the distribution head distributes the blank on the conveying carrier under the driving of the driving assembly to form a fine grain pattern.

Compared with the prior art, the utility model, carry out laying of pattern line through pattern distributing device, then supplement the vacancy part by the feed supplement device, carry out the microgroove processing by microgroove distributing device again, carry out the press forming by the press at last, through like this, can process the abundant "true entire body" of pattern line fast accurately, can carry out accurate processing according to required pattern line, the pattern line that processes out is fine and smooth, reaches better pleasing to the eye effect.

Drawings

Fig. 1 is a front view of a first embodiment of the present invention.

Fig. 2 is a front view of a second embodiment of the present invention.

Fig. 3 is a perspective view of the pattern distributing device of the present invention.

Fig. 4 is a first side view of the present invention.

Fig. 5 is a second side view of the present invention.

Fig. 6 is a schematic structural diagram of the shutter mechanism of the present invention.

Fig. 7 is a schematic view of the processing procedure of the present invention.

The device comprises a first conveying belt 1, a transition section 11, a second conveying belt 2, a pattern distributing device 3, a hopper 31, a powder outlet 311, a powder distributing seat 32, a material collecting cavity 321, a fine material distributing hole 322, a shutter mechanism 33, a connecting seat 333, a driving unit 332, a powder shutter 331, a sealing section 331a, a connecting section 331b, a material supplementing device 4, a fine grain distributing device 5, a press 6, a platform plate 7, pattern lines 8, fine grain patterns 9 and a blank 10.

Detailed Description

The invention will be further described with reference to the following specific embodiments:

referring to the attached drawings 1 to 7, the utility model relates to a thin-line through-body ceramic material distribution system.

The first embodiment is as follows:

referring to fig. 1 and fig. 3 to 7, the device includes a conveying carrier, a set of pattern distributing device 3, a material supplementing device 4, three sets of fine grain distributing device 5 and a press 6, wherein the conveying carrier is a first conveying belt 1 and a second conveying belt 2 (in actual use, the conveying carrier is used for carrying and transporting powder, but not limited to a conveying belt, other methods such as a carrier plate, etc. may also be used, and for easy understanding, the conveying belt is used in this embodiment); the tail end of the first conveyor belt 1 is a transition section 11 with a downward slope, and the transition section 11 extends to the head end of the second conveyor belt 2 so as to connect the first conveyor belt 1 and the second conveyor belt 2.

In this embodiment, the pattern distributing device 3 and the material supplementing device 4 are sequentially arranged along the conveying direction of the first conveying belt 1, wherein the pattern distributing device 3 pre-distributes the material on the first conveying belt 1 based on a preset pattern texture to form a specific pattern texture 8 on the first conveying belt 1, after the distribution of the pattern texture 8 is completed, the first conveying belt 1 conveys the powder material forming the pattern texture 8 to the material supplementing device 4, the material supplementing device 4 supplements the powder material forming the pattern texture 8 based on the preset pattern texture to fill the gap between the pattern textures 8 and the peripheral vacant region of the pattern texture 8 to form the green body 10, for example, the preset pattern texture is a color strip texture in an "S" shape at the middle section of the green brick, and when the pattern distributing device 3 distributes the material, the color powder material is distributed according to the shape of the color strip texture, after the material distribution is finished, the color strip-shaped grains are conveyed to the material supplementing device 4 by the first conveying belt 1, and the material supplementing device 4 correspondingly supplements the vacant parts on the two sides of the color strip-shaped grains so as to form a blank body 10 with the color strip-shaped pattern grains, wherein the whole body is a rectangular surface, and the middle section position of the rectangular surface is S-shaped.

In the present embodiment, specifically, the pattern distribution device 3 is disposed across above the first conveyor belt 1 by a preset bracket; the pattern distributing device 3 comprises a wide distributing hopper 31, a distributing seat 32 and a plurality of gate plate mechanisms 33 arranged on the distributing seat 32, wherein the distributing hopper 31 is fixedly arranged on the top surface of the distributing seat 32 through bolts, and the distributing hopper 31 is used for storing ceramic powder; the powder outlet 311 at the bottom of the distributing hopper 31 is communicated with a collecting cavity 321 preformed on the top surface of the distributing base 32, and the width of the collecting cavity 321 is the same as that of the powder outlet 311 at the bottom of the distributing hopper 31.

In this embodiment, a plurality of fine distribution holes 322 are formed in the bottom surface of the distribution base 32 and arranged side by side along the width direction of the first conveyor belt 1, wherein any two adjacent fine distribution holes 322 are abutted against each other, and the top end of each fine distribution hole 322 is communicated with the bottom end of the collection chamber 321, so that the ceramic powder pre-stored in the distribution hopper 31 is discharged from the powder outlet 311 and accumulated in the collection chamber 321, and the powder in the collection chamber 321 can be discharged from any one fine distribution hole 322 for distribution; in actual production, the width of the material distributing base 32 is slightly larger than or equal to the width of the actual material distributing carrier, so as to ensure that one material distributing point corresponds to any one transverse position on the material distributing carrier, for easy understanding, eighty four fine material distributing holes 322 arranged side by side are formed on the bottom surface of the material distributing base 32 of the present embodiment, that is, eighty four shutter mechanisms 33 are correspondingly disposed.

In the present embodiment, each fine distribution hole 322 corresponds to one shutter mechanism 33 to individually control the opening and closing of the fine distribution hole 322; next, each shutter mechanism 33 includes a connection seat 333, a powder shutter 331 and a driving unit 332, wherein the powder shutter 331 of the present embodiment is an "L" shaped plate-like structure, that is, the powder shutter 331 is composed of a sealing section 331a and a connection section 331b which are integrally formed; each of the powder shutter plates 331 corresponds to one of the fine distribution holes 322, and the powder shutter plate 331 is disposed at the fine distribution hole 322, that is, the sealing section 331a of the powder shutter plate 331 covers the bottom end of the fine distribution hole 322 in a shielding manner. In the present embodiment, in order to facilitate assembly, the plurality of driving units 332 share one connecting seat 333, and the plurality of driving units 332 are mounted on the connecting seat 333 in advance and then fixedly mounted on the cloth seat 32, so that the difficulty of assembly is optimized.

The driving unit 332 of this embodiment is a telescopic cylinder, and a telescopic end of the driving unit 332 (telescopic cylinder) is connected with the connecting section 331b of the powder shutter plate 331, so that the powder shutter plate 331 is driven to horizontally reciprocate by a telescopic action of the telescopic end of the driving unit 332, and the sealing section 331a of the powder shutter plate 331 shields or avoids the fine distribution hole 322, that is, when the sealing section 331a avoids the fine distribution hole 322, the fine distribution hole 322 is opened to perform a distribution action; when the sealing section 331a blocks the fine material distribution hole 322, the material distribution port is closed. The width of the sealing section 331a of this embodiment is slightly larger than the width of the material distribution port, so that the sealing section 331a completely covers the fine material distribution hole 322.

The flashboard mechanisms 33 of the present embodiment are equally divided into two groups of flashboard assemblies arranged on two sides of the material hole, wherein the flashboard mechanisms 33 of the two groups of flashboard assemblies are arranged at equal intervals in a staggered manner, that is, the powder flashboards 331 of the two groups of flashboard assemblies are arranged in a staggered manner, so that the position relationship of the flashboard assemblies on the distribution hopper 31 is optimized, the weight on two sides of the distribution seat 32 is balanced, and the problem that the flashboard mechanisms 33 are arranged on the distribution seat 32 and incline due to imbalance is avoided. Secondly, a plurality of flashboard mechanisms 3 of this application can also be located the homonymy and the condition of arranging side by side, can adopt the installation mode of deriving mutually according to the demand in actual production, belongs to conventional technical means to technical staff in the field, does not describe here any more.

In this embodiment, any one of the fine distribution holes 322 vertically corresponds to a distribution point on the first conveyor belt 1 directly below the distribution base 32, wherein all the distribution points are sequentially connected in series to form a continuous straight line, so as to ensure that when the first conveyor belt 1 passes through the distribution point directly below the distribution base 32, the opening and closing of the fine distribution hole 322 is independently controlled by the shutter mechanism 33 to enable the powder to fall to the corresponding position of the first conveyor belt 1, and thus the distribution action of the plurality of shutter mechanisms 33 and the fine distribution holes 322 enables the first conveyor belt 1 to form the required fine grain pattern 8; in addition, the material distribution point is consistent with the width of the first conveyor belt 1, so as to ensure that one material distribution point (i.e. one fine material distribution hole 322) corresponds to any one transverse position on the first conveyor belt 1, that is, the length of a continuous straight line formed by all the material distribution points is equal to the width of the first conveyor belt 1, so that the pattern material distribution device 3 can distribute materials at any position on the first conveyor belt 1.

In this embodiment, the pattern distributing device 3 has a structure with a plurality of fine distributing holes 322, so that the distributing accuracy is higher, the distributed patterns are more abundant, diversified and finer, and a better aesthetic effect is achieved; when the set pattern texture is composed of a plurality of pattern textures 8, the number of sets of pattern distributing devices 3 can be increased, one set of pattern distributing devices 3 corresponds to one pattern texture 8, for example, the required pattern texture is composed of an S-shaped red strip-shaped pattern texture 8 and a Z-shaped blue strip-shaped pattern texture 8, two sets of pattern distributing devices 3 can be sequentially set, and the two different pattern textures 8 are respectively and sequentially processed and distributed, so that the diversity of the pattern textures is greatly increased.

In the present embodiment, in particular, the feeding device 4 is also arranged above the first conveyor belt 1 across by a preset bracket; the material supplementing device 4 adopts a conventional gate plate type material distributing device which is a disclosed material distributing device, and belongs to a conventional technical means.

In this embodiment, the blank layer on which the material distribution is completed is conveyed to the second conveyor belt 2 through the transition section 11 of the first conveyor belt 1, wherein the three groups of fine grain material distribution devices 5 are sequentially arranged along the conveying direction of the second conveyor belt 2; each group of fine grain distribution devices 5 has the same structure, is arranged above the second conveying belt 2 in a crossing manner through a preset support, and comprises a distribution head and a driving assembly, wherein the distribution head is driven by the driving assembly to perform lifting, translation or rotary motion so as to separate a through groove on a blank 10 conveyed to the second conveying belt 2, and corresponding powder is filled into the through groove to form a corresponding fine grain pattern 9; specifically, referring to chinese patents with publication numbers CN207983659U and CN207983658U, a material distributing head of the fine grain material distributing device 5 is driven by a driving assembly to form a through groove matching with the set fine grain pattern on the blank 10 by a material sucking or scraping manner, and then the through groove is filled by filling corresponding powder, so as to form the required fine grain pattern 9 on the blank 10.

In this embodiment, each group of fine grain distribution devices 5 corresponds to one fine grain pattern 9, wherein the three groups of fine grain distribution devices 5 respectively distribute the blank 10 on the second conveyor belt 2 based on a predetermined pattern texture to form the fine grain pattern 9 on the blank 10, specifically, according to the effect requirement of the pattern texture, the powder and the working mode adopted by the three groups of fine grain distribution devices 5 may be the same or different, that is, one fine grain pattern 9 may be formed by processing the three groups of fine grain distribution devices 5 together, or the three groups of fine grain distribution devices 5 may be processed to form different fine grain patterns 9 respectively; for example, three strip-shaped linear grains with different colors need to be processed on the blank body 10, so that the three groups of fine grain distributing devices 5 can respectively distribute powder with different colors; by this, the pattern is more abundant and diversified.

In this embodiment, the tail end of the second conveyor belt 2 is connected with a platform plate 7, wherein the press 6 is disposed above the platform plate 7, and after the blank 10 on the second conveyor belt 2 is processed by the three groups of fine grain distributing devices 5 to form the fine grain pattern 9 on the blank 10, the second conveyor belt 2 conveys the blank 10 and the fine grain pattern 9 to the platform plate 7, and the blank 10 with the fine grain pattern 9 is pressed and molded by the press 6.

In this embodiment, the pattern texture to be processed is set by an input device such as a computer or a touch screen (the operator can directly draw the pattern texture), and after data processing is performed by a module with data processing capability such as a single chip microcomputer, a driving system such as a PLC control system drives an executing device such as the pattern distributing device 3, the material supplementing device 4, and the fine grain distributing device 5 to perform corresponding operations, so as to process the set pattern texture, and the degree of automation is high, and the specific principle can refer to chinese patent publication No. CN 102642242B.

Example two:

referring to fig. 2 to 7, the difference between this embodiment and the first embodiment is that the feeding device 4 has the same structure as the pattern distributing device 3, which improves the feeding accuracy and achieves better effect compared with the first embodiment.

The material distribution method of the fine grain through body ceramic material distribution system of the present application will be further described with reference to the above specific embodiments.

The distribution scheme of the fine-grained through-body ceramic in the embodiment comprises the following steps:

s1, controlling a sealing section 331a of a related powder gate 331 to avoid a corresponding fine distribution hole 322 (in an initial state, the fine distribution hole 322 is in a closed state) through a pattern distributing device 3 based on preset pattern textures, so that powder in a distributing hopper 31 flows out of the opened fine distribution hole 322 and falls onto a first conveying belt 1, and at the moment, the first conveying belt 1 synchronously moves to form one or more specific pattern textures 8 on the first conveying belt 1;

s2, after the distribution of the pattern grains 8 is finished, the first conveying belt 1 conveys powder forming the pattern grains 8 to the position below the material supplementing device 4;

s3, distributing the material on the first conveying belt 1 through the material supplementing device 4 based on preset pattern textures, so that gaps among the pattern textures 8 and a vacant region on the periphery of the pattern textures 8 are filled in the first conveying belt 1 to form a blank body 10;

s4, after the blank 10 is distributed, the first conveying belt 1 conveys the blank 10 to the second conveying belt 2;

s5, separating and filling the blank 10 on the second conveying belt 2 sequentially through the three groups of fine grain distributing devices 5 arranged on the second conveying belt 2 on the basis of preset pattern textures to form pattern textures 8 on the blank 10, wherein the distributing heads of the three groups of fine grain distributing devices 5 move, lift or rotate under the driving of the driving assembly to form corresponding fine line textures on the blank 10;

s6, after the fine grain pattern 9 is distributed, the combined body of the green body 10 and the fine grain pattern 9 is conveyed to the platform plate 7 by the second conveying belt 2, and the green body 10 and the fine grain pattern 9 are pressed into a green brick by the press 6.

In addition, it should be noted that the names of the parts and the like of the embodiments described in the present specification may be different, and all the equivalent or simple changes made according to the structure, the features and the principle of the present invention are included in the protection scope of the present invention. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims (5)

1. The utility model provides a thin line entire body pottery's cloth system, is including carrying the carrier, its characterized in that: at least one group of pattern distributing devices (3), a material supplementing device (4), at least one group of fine grain distributing devices (5) and a press (6) are sequentially arranged along the conveying direction of the conveying carrier; the group of pattern distributing devices correspond to one pattern texture (8), wherein the pattern distributing devices (3) pre-distribute the conveying carriers based on preset pattern textures so as to form at least one pattern texture (8) on the conveying carriers; the material supplementing device (4) distributes materials to the conveying carrier based on preset pattern textures, so that gaps among the pattern textures (8) and vacant areas on the periphery of the pattern textures (8) are filled in the conveying carrier to form a blank body (10); a group of the fine grain distributing devices (5) corresponds to a fine grain pattern (9), wherein each group of the fine grain distributing devices (5) distributes the blanks (10) on the conveying carrier based on the preset pattern texture so as to form at least one fine grain pattern (9) on the blanks (10); the press (6) is arranged at the tail end of the conveying carrier and is used for pressing and forming the blank (10) with the fine grain pattern (9).

2. The fine grain through-body ceramic distribution system of claim 1, wherein: the pattern distributing device (3) comprises a wide distributing hopper (31), a distributing seat (32) and a plurality of gate plate mechanisms (33) arranged on the distributing seat (32), wherein the distributing hopper (31) is fixedly arranged on the top surface of the distributing seat (32), and a powder outlet (311) at the bottom of the distributing hopper (31) is communicated with a material collecting cavity (321) preformed on the top surface of the distributing seat (32); a plurality of fine distribution holes (322) which are arranged side by side are formed in the bottom surface of the distribution seat (32), wherein any two adjacent fine distribution holes (322) are abutted against each other, and the top end of each fine distribution hole (322) is communicated with the bottom end of the collection cavity (321); each fine distribution hole (322) corresponds to one gate plate mechanism (33) to independently control the opening and closing of the fine distribution hole (322), wherein each gate plate mechanism (33) comprises a powder gate plate (331) arranged at the fine distribution hole (322) and a driving unit (332) driving the powder gate plate (331) to horizontally reciprocate and translate, and the powder gate plate (331) is driven to reciprocate and translate by the driving unit (332) to shield or avoid the fine distribution hole (322); any one of the fine material distribution holes (322) vertically corresponds to one material distribution point right below the material distribution seat (32), and all the material distribution points are sequentially connected in series to form a connected straight line.

3. The fine grain through-body ceramic distribution system of claim 2, wherein: a plurality of flashboard mechanism (33) equally divide into two sets and arrange the flashboard subassembly in tiny cloth hole (322) both sides, wherein, two sets of each flashboard mechanism (33) of flashboard subassembly are equidistant staggered arrangement or arrange side by side between.

4. The fine grain through-body ceramic distribution system of claim 1, wherein: comprises a plurality of groups of fine grain distributing devices (5), wherein the plurality of groups of fine grain distributing devices (5) are sequentially arranged along the conveying direction of the conveying carrier; and the multiple groups of fine grain distribution devices (5) are used for sequentially processing fine grain patterns (9) on the blank (10) on the conveying carrier.

5. The fine grain through-body ceramic distribution system of claim 4, wherein: any group of the fine grain distribution devices (5) comprises a distribution head and a driving assembly, wherein the distribution head separates and fills blanks (10) on the conveying carrier under the driving of the driving assembly to form a fine grain pattern (9).

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