CN110640868A - Production and preparation method of building ceramic tile - Google Patents

Abstract

The invention relates to a production and preparation method of a building ceramic tile, which mainly comprises the following steps of preparing a ceramic tile raw material, performing ball milling operation, removing iron by filtering, mixing slurry, drying the slurry, forming, processing, drying and the like. The invention can solve the following problems existing in the production and manufacturing process of the existing ceramic tile, a, the ceramic tile raw materials are uniformly placed in the traditional pouring tool, the slurry is easy to solidify after being placed for a long time, the pouring operation in the flow line production operation consumes long time, the slurry in the pouring tool has different solidification degrees, the quality of the poured slurry is uneven, and the overall quality of the ceramic tile is influenced. b. Traditional filling tool can't fill the load of thick liquids according to the big or small control of ceramic tile mould, fills and leads to the thick liquids not enough or thick liquids excessive in the operation easily, and the thick liquids is not enough to lead to the ceramic tile quality to reach the requirement, and the thick liquids is excessive to cause the waste of material.

Description

Production and preparation method of building ceramic tile

Technical Field

The invention relates to the technical field of ceramic tile manufacturing, in particular to a production and preparation method of a building ceramic tile.

Background

The ceramic tile is made up by using refractory metal oxide and semimetal oxide and adopting several processes of ceramic tile raw material preparation, ball-milling operation, iron-removing filtration and iron-removing, slurry mixing, slurry drying, forming and drying treatment, etc. so as to form an acid-resisting and alkali-resisting ceramic or stone material for building or decorative material, so-called ceramic tile. The raw materials are mostly mixed by clay, quartz sand and the like.

However, the following problems of the existing ceramic tiles in the production and manufacturing process are that a, ceramic tile raw materials are uniformly placed in a traditional pouring tool, slurry is placed for a long time and is easy to solidify, the pouring operation in the flow line production operation consumes long time, the solidification degree of the slurry in the pouring tool is different, the quality of the poured slurry is uneven, and the overall quality of the ceramic tiles is affected. b. Traditional filling tool can't fill the load of thick liquids according to the big or small control of ceramic tile mould, fills and leads to the thick liquids not enough or thick liquids excessive in the operation easily, and the thick liquids is not enough to lead to the ceramic tile quality to reach the requirement, and the thick liquids is excessive to cause the waste of material.

Regarding the technical problems existing in the manufacturing process of ceramic tiles, persons skilled in the relevant art have made suitable improvements after research and study, for example, patent No. 2017114773032, a quicksand texture vitrified ceramic tile preparation device, can produce products with different color systems, however, there is a need to solve the above-mentioned problems existing in the manufacturing process of ceramic tiles.

Disclosure of Invention

In order to solve the problems, the invention provides a method for producing and preparing building tiles, which can solve the problems in the manufacturing process of the tiles mentioned above.

In order to achieve the purpose, the invention adopts the following technical scheme to realize the purpose: a production and preparation method of building tiles mainly comprises the following production and preparation steps:

step one, preparing a ceramic tile raw material, mixing prepared mud, stone sand, stone powder and auxiliary materials together and uniformly stirring;

step two, ball milling operation, namely putting the raw materials prepared in the step one into a ball mill for grinding, and screening the ground raw materials to obtain raw material powder;

step three, performing iron removal filtration, namely preparing a filtration screen, fixing an iron removal rod in the screen, putting the raw material powder obtained in the step two into the screen, controlling the screen to perform shaking screening on the raw material powder, adsorbing iron impurities in the raw material powder by the iron removal rod, and repeatedly screening the raw material powder for three to five times;

step four, mixing slurry, namely putting the raw materials treated in the step three into a corrosion removing pool, injecting water into the corrosion removing pool, stirring, standing for 3-5 hours, and fishing out the slurry precipitated at the bottom of the corrosion removing pool;

drying the slurry, namely conveying the slurry fished out in the step four into a drying tower, evaporating water in the slurry through the drying tower, and reducing the water content of the slurry to obtain granular slurry;

step six, forming processing, namely putting the granular slurry and the ingredients obtained in the step five into a pouring device, and pouring the slurry into a tile mould through the pouring device;

seventhly, drying, namely heating and drying the ceramic tile mold in the sixth step, and taking out the formed slurry from the mold to obtain the ceramic tile;

the first to seventh steps need the matching operation of the ball mill, the screen, the drying tower and the special filling equipment, the filling equipment comprises a filling frame, the upper end of the filling frame is provided with a feeding hole, the lower end of the filling frame is provided with a discharging hole, a stirring mechanism is arranged in the filling frame, and the lower end of the stirring mechanism is provided with a quantity control mechanism;

the stirring mechanism comprises a stirring motor which is arranged at the upper end of the filling frame through a motor base, an output shaft of the stirring motor is connected with a stirring shaft, the lower end of the stirring shaft is connected to the discharging plate, the stirring shaft is of a hollow structure, a lifting rack is fixedly arranged on the inner wall of the stirring shaft, lifting grooves are uniformly formed in the inner wall of the stirring shaft along the circumferential direction of the inner wall, stirring branch chains are uniformly arranged on the lifting rack from top to bottom, the upper end of each stirring branch chain is arranged on an annular cylinder, and the annular cylinder is sleeved on;

the quantity control mechanism comprises a quantity control ring arranged at the lower end of the discharge plate, a quantity control motor is arranged on the inner wall of the quantity control ring through a motor base, a rotary bevel gear is arranged on an output shaft of the quantity control motor, quantity control branched chains are uniformly arranged on the rotary bevel gear along the circumferential direction of the rotary bevel gear, and a pressing branched chain is arranged at the lower end of the rotary bevel gear.

The stirring branch chain comprises a rotating shaft arranged on the annular cylinder through a bearing, the rotating shaft is positioned in the lifting groove, a lifting gear is arranged on the rotating shaft, the lifting gear is meshed with the lifting rack, and fishbone stirring frames are symmetrically arranged at two ends of the rotating shaft.

The annular cylinder is provided with an annular groove, a lifting telescopic rod is arranged between the annular groove and the inner wall of the filling frame in a sliding fit mode, a support rod is arranged on the annular cylinder, the upper end of the support rod supports against the driving ring, and the driving ring is arranged on the inner wall of the filling frame.

Be provided with the guide annular frame on the play flitch, the diameter of guide annular frame is from up reducing gradually down, and the upper end of guide annular frame supports and leans on annular cylinder, and the cover is equipped with the guide piece on the lower extreme inner wall of filling the frame, has evenly seted up the discharge gate along its circumference on the play flitch.

The quantity control branched chain comprises a quantity control frame arranged at the lower end of the discharge plate, a quantity control roller is arranged between the inner walls of the quantity control frame through a bearing, a material conveying groove is formed in the quantity control roller, the quantity control roller penetrates through a quantity control ring through the bearing, a driven bevel gear is arranged on the quantity control roller, and the driven bevel gear is meshed with the rotating bevel gear.

The pressing branched chain comprises a pressing groove which is uniformly formed in the inner wall of the measuring control ring, a pressing frame is installed in the pressing groove through a reset spring rod, a rotary column is arranged at the lower end of the rotary bevel gear, a closed ring groove is formed in the outer wall of the rotary column, a linkage rod is arranged on the closed ring groove in a sliding mode, and the linkage rod is fixed on the pressing frame.

The invention has the beneficial effects that:

1. the invention can solve the following problems existing in the production and manufacturing process of the existing ceramic tile, a, the ceramic tile raw materials are uniformly placed in the traditional pouring tool, the slurry is easy to solidify after being placed for a long time, the pouring operation in the flow line production operation consumes long time, the slurry in the pouring tool has different solidification degrees, the quality of the poured slurry is uneven, and the overall quality of the ceramic tile is influenced. b. Traditional filling tool can't fill the load of thick liquids according to the big or small control of ceramic tile mould, fills and leads to the thick liquids not enough or thick liquids excessive in the operation easily, and the thick liquids is not enough to lead to the ceramic tile quality to reach the requirement, and the thick liquids is excessive to cause the waste of material. The pouring equipment designed in the invention can completely solve the problems in operation, improve the uniformity of the quality of the manufactured ceramic tile and achieve unexpected effects.

2. The stirring mechanism designed by the invention can control the fishbone stirring frame to carry out rotary stirring operation through the driving of the stirring motor in operation, controls the fishbone stirring frame to carry out vertical reciprocating vibration type stirring operation through the mutual matching between the lifting rack and the lifting gear while stirring and rotating, controls the fishbone stirring frame to carry out rotary turnover while rotating and vertically vibrating to match, ensures that slurry in a pouring frame can be fully and uniformly stirred, and ensures that the quality of a manufactured ceramic tile is uniform

3. The quantity control mechanism designed by the invention can accurately control the conveying of the slurry according to the size of the ceramic tile mould in operation, the quantity control motor works to drive the quantity control roller to rotate in a gear transmission mode so as to convey the slurry, and the conveyed slurry is pushed by pressing the branched chain, so that the accuracy of slurry filling is ensured.

Drawings

The invention is further illustrated with reference to the following figures and examples.

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

FIG. 2 is a plan view of the perfusion apparatus of the present invention;

FIG. 3 is a schematic view of the structure of the spin column of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 3, a method for producing and preparing a building tile mainly comprises the following production steps:

step one, preparing a ceramic tile raw material, mixing prepared mud, stone sand, stone powder and auxiliary materials together and uniformly stirring;

step two, ball milling operation, namely putting the raw materials prepared in the step one into a ball mill for grinding, and screening the ground raw materials to obtain raw material powder;

step three, performing iron removal filtration, namely preparing a filtration screen, fixing an iron removal rod in the screen, putting the raw material powder obtained in the step two into the screen, controlling the screen to perform shaking screening on the raw material powder, adsorbing iron impurities in the raw material powder by the iron removal rod, and repeatedly screening the raw material powder for three to five times;

step four, mixing slurry, namely putting the raw materials treated in the step three into a corrosion removing pool, injecting water into the corrosion removing pool, stirring, standing for 3-5 hours, and fishing out the slurry precipitated at the bottom of the corrosion removing pool;

drying the slurry, namely conveying the slurry fished out in the step four into a drying tower, evaporating water in the slurry through the drying tower, and reducing the water content of the slurry to obtain granular slurry;

step six, forming processing, namely putting the granular slurry and the ingredients obtained in the step five into a pouring device, and pouring the slurry into a tile mould through the pouring device;

seventhly, drying, namely heating and drying the ceramic tile mold in the sixth step, and taking out the formed slurry from the mold to obtain the ceramic tile;

in the first to seventh steps, the ball mill, the screen, the drying tower and the special filling equipment are required to be operated in a matched mode, the filling equipment comprises a filling frame 1, a feeding hole is formed in the upper end of the filling frame 1, a discharging hole is formed in the lower end of the filling frame 1, a stirring mechanism 2 is arranged in the filling frame 1, and a quantity control mechanism 3 is arranged at the lower end of the stirring mechanism 2;

the stirring mechanism 2 comprises a stirring motor 21 which is arranged at the upper end of the filling frame 1 through a motor base, a stirring shaft 22 is connected onto an output shaft of the stirring motor 21, the lower end of the stirring shaft 22 is connected onto a discharge plate 23, the stirring shaft 22 is of a hollow structure, a lifting rack 24 is fixedly arranged on the inner wall of the stirring shaft 22, lifting grooves are uniformly formed in the inner wall of the stirring shaft 22 along the circumferential direction of the inner wall, stirring branch chains 25 are uniformly arranged on the lifting rack 24 from top to bottom, the upper ends of the stirring branch chains 25 are arranged on an annular cylinder 26, and the annular cylinder 26 is slidably sleeved on;

the stirring branch chain 25 comprises a rotating shaft 251 arranged on the annular cylinder 26 through a bearing, the rotating shaft 251 is positioned in the lifting groove, a lifting gear 252 is arranged on the rotating shaft 251, the lifting gear 252 is meshed on the lifting rack 24, and fishbone stirring frames 253 are symmetrically arranged at two ends of the rotating shaft 251.

An annular groove 261 is formed in the annular cylinder 26, a lifting telescopic rod 262 is arranged between the annular groove 261 and the inner wall of the perfusion frame 1 in a sliding fit mode, an abutting rod 263 is arranged on the annular cylinder 26, the upper end of the abutting rod 263 abuts against a driving ring 264, and the driving ring 264 is installed on the inner wall of the perfusion frame 1.

Be provided with guide annular frame 231 on ejection of compact board 23, guide annular frame 231's diameter is from up reducing gradually down, and guide annular frame 231's upper end supports and leans on annular cylinder 26, and the cover is equipped with guide block 232 on the lower extreme inner wall of pouring frame 1, has evenly seted up the discharge gate along its circumference on ejection of compact board 23.

In the operation, put into the frame 1 that fills through the feed inlet with the material inside, agitator motor 21 begins work and drives the (mixing) shaft 22 and rotate, the (mixing) shaft 22 drives fishbone stirring frame 253 on the annular section of thick bamboo 26 at rotatory in-process and stirs the operation to the thick liquids that fills in the frame 1 inside, annular section of thick bamboo 26 carries out the oscilaltion operation through the change of the position between support pole 263 and the drive ring 264 in rotating the operation, annular section of thick bamboo 26 drives fishbone stirring frame 253 through the cooperation between elevating gear 252 and the lifting rack 24 and rotates in the operation, accomplish the action of spiral upset thick liquids when carrying out the stirring of level and vertical rotation to thick liquids in the operation, ensure to carry out abundant homogeneous mixing stirring operation to thick liquids.

The quantity control mechanism 3 comprises a quantity control ring 31 arranged at the lower end of the discharging plate 23, a quantity control motor 32 is arranged on the inner wall of the quantity control ring 31 through a motor base, a rotary bevel gear 33 is arranged on an output shaft of the quantity control motor 32, quantity control branched chains 34 are uniformly arranged on the rotary bevel gear 33 along the circumferential direction of the rotary bevel gear, and a pressing branched chain 35 is arranged at the lower end of the rotary bevel gear 33.

The quantity control branched chain 34 comprises a quantity control frame 341 arranged at the lower end of the discharge plate 23, a quantity control roller 342 is arranged between the inner walls of the quantity control frame 341 through a bearing, a material conveying groove is formed in the quantity control roller 342, the quantity control roller 342 penetrates through the quantity control ring 31 through the bearing, a driven bevel gear 343 is arranged on the quantity control roller 342, the driven bevel gear 343 is meshed with the rotating bevel gear 33, the quantity control roller 342 plays a role in sealing a discharge hole in operation, after the material conveying groove in the quantity control roller 342 moves to a proper working position, slurry falls into the conveying groove, and the slurry is conveyed quantitatively through rotation of the quantity control roller 342.

The pressing branched chain 35 comprises pressing grooves uniformly formed in the inner wall of the volume control ring 31, a pressing frame 352 is installed in each pressing groove through a reset spring rod 351, a rotating column 353 is arranged at the lower end of the rotating bevel gear 33, a closed ring groove is formed in the outer wall of each rotating column 353, a linkage rod 354 is arranged on each closed ring groove in a sliding mode, and the linkage rods 354 are fixed on the pressing frames 352.

The control motor 32 works to drive the control roller 342 to rotate in a gear transmission mode to quantitatively convey the slurry, so that the accurate control of the material conveying according to the sizes of the ceramic tile molds of different specifications is ensured, the conveyed slurry flows downwards along the inner wall of the pouring frame 1, the rotating bevel gear 33 drives the synchronous rotating column 353 to rotate, and the pressing frame 352 is controlled by the rotating column 353 to extrude the slurry out of the pouring frame 1 through the change of the position between the rotating column 353 and the linkage rod 354.

In the operation of the pouring equipment, the slurry is poured into the pouring frame 1, the stirring mechanism 2 is used for stirring the slurry in the pouring operation, and the quantity control mechanism 3 is used for controlling the slurry to be accurately poured into the ceramic tile mould.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. A production and preparation method of building tiles is characterized by comprising the following steps: the method mainly comprises the following production steps:

step one, preparing a ceramic tile raw material, mixing prepared mud, stone sand, stone powder and auxiliary materials together and uniformly stirring;

step two, ball milling operation, namely putting the raw materials prepared in the step one into a ball mill for grinding, and screening the ground raw materials to obtain raw material powder;

step three, performing iron removal filtration, namely preparing a filtration screen, fixing an iron removal rod in the screen, putting the raw material powder obtained in the step two into the screen, controlling the screen to perform shaking screening on the raw material powder, adsorbing iron impurities in the raw material powder by the iron removal rod, and repeatedly screening the raw material powder for three to five times;

step four, mixing slurry, namely putting the raw materials treated in the step three into a corrosion removing pool, injecting water into the corrosion removing pool, stirring, standing for 3-5 hours, and fishing out the slurry precipitated at the bottom of the corrosion removing pool;

drying the slurry, namely conveying the slurry fished out in the step four into a drying tower, evaporating water in the slurry through the drying tower, and reducing the water content of the slurry to obtain granular slurry;

step six, forming processing, namely putting the granular slurry and the ingredients obtained in the step five into a pouring device, and pouring the slurry into a tile mould through the pouring device;

seventhly, drying, namely heating and drying the ceramic tile mold in the sixth step, and taking out the formed slurry from the mold to obtain the ceramic tile;

the first to seventh steps need the matching operation of the ball mill, the screen, the drying tower and the special pouring equipment, the pouring equipment comprises a pouring frame (1), the upper end of the pouring frame (1) is provided with a feeding hole, the lower end of the pouring frame (1) is provided with a discharging hole, a stirring mechanism (2) is arranged in the pouring frame (1), and the lower end of the stirring mechanism (2) is provided with a quantity control mechanism (3);

the stirring mechanism (2) comprises a stirring motor (21) which is arranged at the upper end of the filling frame (1) through a motor base, a stirring shaft (22) is connected onto an output shaft of the stirring motor (21), the lower end of the stirring shaft (22) is connected onto a discharge plate (23), the stirring shaft (22) is of a hollow structure, a lifting rack (24) is fixedly arranged on the inner wall of the stirring shaft (22), lifting grooves are uniformly formed in the inner wall of the stirring shaft (22) along the circumferential direction of the stirring shaft, stirring branched chains (25) are uniformly arranged on the lifting rack (24) from top to bottom, the upper end of each stirring branched chain (25) is arranged on an annular cylinder (26), and the annular cylinder (26) is slidably sleeved on the stirring;

the quantity control mechanism (3) comprises a quantity control ring (31) arranged at the lower end of the discharge plate (23), a quantity control motor (32) is arranged on the inner wall of the quantity control ring (31) through a motor base, a rotary bevel gear (33) is arranged on an output shaft of the quantity control motor (32), quantity control branched chains (34) are uniformly arranged on the rotary bevel gear (33) along the circumferential direction of the rotary bevel gear, and a pressing branched chain (35) is arranged at the lower end of the rotary bevel gear (33).

2. The method for producing and preparing a building tile according to claim 1, wherein: the stirring branch chain (25) comprises a rotating shaft (251) arranged on the annular cylinder (26) through a bearing, the rotating shaft (251) is positioned in the lifting groove, a lifting gear (252) is arranged on the rotating shaft (251), the lifting gear (252) is meshed with the lifting rack (24), and fishbone stirring frames (253) are symmetrically arranged at two ends of the rotating shaft (251).

3. The method for producing and preparing a building tile according to claim 1, wherein: the annular cylinder (26) is provided with an annular groove (261), a lifting telescopic rod (262) is arranged between the annular groove (261) and the inner wall of the perfusion frame (1) in a sliding fit mode, the annular cylinder (26) is provided with a leaning rod (263), the upper end of the leaning rod (263) leans against the driving ring (264), and the driving ring (264) is installed on the inner wall of the perfusion frame (1).

4. The method for producing and preparing a building tile according to claim 1, wherein: go out to be provided with on flitch (23) and guide annular frame (231), the diameter of guide annular frame (231) is from up reducing gradually down, and the upper end of guide annular frame (231) supports and leans on annular cylinder (26), and the cover is equipped with guide block (232) on the lower extreme inner wall of pouring frame (1), goes up along its circumference on the flitch (23) and has evenly seted up the discharge gate.

5. The method for producing and preparing a building tile according to claim 1, wherein: the quantity control branched chain (34) comprises a quantity control frame (341) arranged at the lower end of the discharging plate (23), a quantity control roller (342) is arranged between the inner walls of the quantity control frame (341) through a bearing, a material conveying groove is formed in the quantity control roller (342), the quantity control roller (342) penetrates through the quantity control ring (31) through the bearing, a driven bevel gear (343) is arranged on the quantity control roller (342), and the driven bevel gear (343) is meshed with the rotating bevel gear (33).

6. The method for producing and preparing a building tile according to claim 1, wherein: the pressing branched chain (35) comprises pressing grooves which are uniformly formed in the inner wall of the volume control ring (31), a pressing frame (352) is installed in the pressing grooves through a reset spring rod (351), a rotating column (353) is arranged at the lower end of the rotating bevel gear (33), a closed ring groove is formed in the outer wall of the rotating column (353), a linkage rod (354) is arranged on the closed ring groove in a sliding mode, and the linkage rod (354) is fixed on the pressing frame (352).

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