CN118386358B - Quartz stone plate material distribution method and material distribution equipment thereof - Google Patents

Abstract

The invention discloses a quartz stone plate material distribution method and material distribution equipment thereof, and relates to the field of artificial quartz stone preparation devices, wherein the equipment comprises a mineral mixture receiving piece, only one set of material blocking templates, and a first material distribution mechanism and a second material distribution mechanism which are sequentially connected; the material blocking template is a box body with a top surface and a peripheral enclosing frame and is used for forming a limit between the second material distribution area and the first material distribution area, and a first mineral mixture accommodating cavity is arranged at the top of the material blocking template; the grid is arranged below the second distributing mechanism. The first material distributing mechanism can realize material distribution and compaction of the first mineral mixture, so that the first mineral mixture is more compact, and the problem of edge collapse is avoided; at the same time, the second mineral mixture is distributed in the area which is not occupied by the first mineral mixture through the trowelling piece and the grid, so that the problem of caking of the second mineral mixture is solved.

Description

Quartz stone plate material distribution method and material distribution equipment thereof

Technical Field

The invention relates to the field of artificial quartz stone preparation devices, in particular to a quartz stone plate material distribution method and material distribution equipment thereof.

Background

The artificial quartz stone is made of quartz sand powder as main raw material and unsaturated resin as adhesive, and is one environment-friendly decoration material without radioactive pollution and capable of being reused to replace natural marble. Referring to the prior patent document with publication number US9289923B1, in order to increase the decorative effect, the prior preparation method generally leaves texture grooves on the surface of a base material plate blank, and then uses texture equipment to distribute Shi Tianchong materials in the texture grooves of the artificial quartz stone, so that the surface of the artificial quartz stone can generate patterns similar to the texture of natural marble after molding.

Referring to the prior patent document with publication number US10105868B2, in the prior art, a first material distribution device and a second material distribution device are arranged on texture equipment, a first hollowed-out mold is arranged in the first material distribution device, and a second hollowed-out mold is arranged in the second material distribution device; the first hollow mold is complementary to the second hollow mold in pattern. When the cloth is carried out, firstly, the cloth is carried out through a first cloth device, and a first pattern is formed in a first hollow mould by the first granular mineral mixture; and then, distributing the second granular mineral mixture by a second distributing device, and forming a second pattern in the die by the second granular mineral mixture through a second hollow die. The two mixtures can form complementary stripes and grain patterns according to the first hollowed-out mold and the second hollowed-out mold according to the preset and complementary distribution patterns. However, when the hollowed-out dies are replaced, the hollowed-out dies on the first material distribution device and the second material distribution device are required to be replaced, and the hollowed-out dies on the first material distribution device and the second material distribution device are required to be ensured to be complementary to form corresponding stripes and grain patterns; if the hollowed-out dies on the first distributing device and the second distributing device are not complementary, corresponding stripes and grain patterns cannot be formed.

Disclosure of Invention

The invention aims to provide a material distribution method of quartz stone plates, which aims to solve the problem that the hollow-out dies are required to be replaced frequently when different products are produced by the texture equipment, and the problem that the production cost is high because two sets of hollow-out dies are required for each pattern. The invention aims to provide a material distribution device for quartz stone plates, so as to realize the material distribution method.

To achieve the purpose, the invention adopts the following technical scheme:

the invention provides a quartz stone distribution method, which comprises the following steps:

step one: performing first cloth; dividing the mineral mixture carrier into a first distribution area and a second distribution area, wherein the first distribution area and the second distribution area are used for respectively dispersing different mineral mixtures, and the first distribution area and the second distribution area are combined to form a complete mineral mixture carrier area;

Covering a material blocking template above the second material distribution area, wherein the material blocking template is a box body with a top surface and a peripheral enclosing frame, and the peripheral enclosing frame forms a limit between the second material distribution area and the first material distribution area; applying a first mineral mixture to the first material distribution area, filling the first material distribution area with the first mineral mixture, and covering the material blocking template with the first mineral mixture, wherein the height of the material blocking template is 10-20 mm lower than the thickness of the first mineral mixture;

step two: compacting the first mineral mixture;

step three: a second cloth; removing the material blocking template to form a second material distribution area; applying a second mineral mixture to the second distribution area to fill the second distribution area, the second mineral mixture forming a texture with the first mineral mixture due to the different composition;

step four: strickling the mineral mixture; and (3) scraping the second mineral mixture in the mineral mixture bearing piece, and filling up the texture grooves to obtain a plate blank.

The invention also provides a material distribution device of the quartz stone plate, which is applied to the quartz stone material distribution method and comprises a mineral mixture receiving piece, only one set of material blocking template, a grid, a first material distribution mechanism and a second material distribution mechanism; the first distributing mechanism and the second distributing mechanism are sequentially arranged along the conveying direction of the mineral mixture bearing piece;

The material blocking template is a box body with a top surface and a peripheral enclosing frame and is used for forming a limit between the second material distribution area and the first material distribution area, and a first mineral mixture accommodating cavity is arranged at the top of the material blocking template; the material blocking template is arranged on the mineral mixture receiving piece; the first distributing mechanism can move forwards or backwards along the conveying direction; the first distributing mechanism is used for distributing a first mineral mixture to the mineral mixture receiving piece, moving out a material blocking template and compacting the first mineral mixture;

The second distributing mechanism is used for distributing a second mineral mixture to the mineral mixture receiving piece; the second distributing mechanism is provided with a trowelling piece, the grid is arranged below the second distributing mechanism, and the trowelling piece is higher than or equal to the top surface of the first mineral mixture paved on the mineral mixture supporting piece; the trowelling piece scrapes the second mineral mixture distributed by the second distributing mechanism from the grid to the mineral mixture receiving piece and fills up the texture grooves.

In the material distribution equipment of the quartz stone plate, the material distribution equipment further comprises a transmission belt assembly, and the first material distribution mechanism and the second material distribution mechanism are arranged on the transmission belt assembly; the first distributing mechanism comprises a first rack, a first distributing device, a first moving assembly, a lifting assembly and a mould frame moving-out device;

The first material distribution device comprises a first conveying belt and a second conveying belt, the first conveying belt and the second conveying belt are respectively arranged on the first frame, and the discharge end of the first conveying belt is positioned above the feed end of the second conveying belt and is used for paving a first mineral mixture; the first rack is arranged on the conveyor belt assembly, and the first moving assembly is arranged on the first rack and is used for driving the first distributing device to reciprocate along the conveying direction;

The lifting assembly comprises a first lifting driving piece, a second lifting driving piece, a first lifting rod and a second lifting rod; the first lifting driving piece is arranged on one side of the conveying direction of the conveying belt assembly, and the second lifting driving piece is arranged on the other side of the conveying direction of the conveying belt assembly; the first lifting rod and the second lifting rod are respectively arranged along the conveying direction of the conveying belt assembly, the first lifting rod is connected with the driving end of the first lifting driving piece, and the second lifting rod is connected with the driving end of the second lifting driving piece; the width of the mineral mixture bearing piece is larger than the width of a conveying belt of the conveying belt assembly, and the distance between the first lifting rod and the second lifting rod is matched with the width of the mineral mixture bearing piece; the mould frame removing device is arranged on the first frame and is used for removing the material blocking mould plate out of the mineral mixture receiving piece perpendicular to the conveying direction.

In the material distribution equipment of the quartz stone plate, the second material distribution mechanism comprises a swinging unit and a mounting frame, and the mounting frame is arranged above the transmission belt assembly; the mounting frame is provided with an avoidance area, two ends of the swinging unit along the X-axis direction are respectively rotationally assembled in the avoidance area, the bottom of the swinging unit is provided with a swinging discharge hole, and the trowelling piece is arranged at two sides of the bottom of the swinging discharge hole along the X-axis direction; the grid is arranged between the transmission belt component and the discharge port of the swinging unit; the swinging unit swings reciprocally by taking the middle axis in the X-axis direction as a swinging axis to drive the trowelling piece to be far away from or close to the grid.

In the material distribution equipment of the quartz stone plate, the swinging unit comprises a receiving hopper and a swinging driving device, wherein the swinging driving device is arranged on the mounting frame, two ends of the receiving hopper are respectively assembled with the mounting frame in a rotating mode and are in transmission connection with the swinging driving device, and the receiving hopper rotates and swings by taking a connecting line of the connecting positions of the two ends of the receiving hopper as a shaft; the swing discharge hole is arranged at the bottom of the receiving hopper.

In the cloth equipment of quartz plate, second cloth mechanism still includes the second and removes the subassembly, the stiff end of second removes the subassembly and set up in the mounting bracket, and the drive end of second removes the subassembly sets up in one side of transmission band subassembly along the Y axle direction, is used for driving swing unit and mounting bracket carry out reciprocating motion along the Y axle direction.

In the material distribution equipment of the quartz stone plate, the grid is formed by combining a plurality of steel wires in parallel at intervals, and the steel wires are perpendicular to the conveying direction of the conveying belt assembly.

In the distributing equipment of the quartz stone plate, the material blocking template comprises a plurality of box bodies with irregular top surfaces, and the box bodies are arranged at intervals.

In the material distribution equipment of the quartz stone plate, the upstream end and the downstream end of the second material distribution area are respectively provided with a material baffle plate.

In the material distribution equipment of the quartz stone plate, the conveying belt assembly comprises a conveying belt rack, a conveying belt, a driving device, a driven roller and at least one driving roller; the driven roller is arranged at one end of the conveyor belt frame, the driving roller is arranged at the other end of the conveyor belt frame, the conveyor belt is sleeved on the outer sides of the driven roller and the driving roller, and the driving device is arranged at one side of the driving roller along the Y-axis direction and is in driving connection with the driving roller.

One technical scheme of the invention has the following beneficial effects:

The material distribution equipment of the quartz stone plate can change the texture pattern of the plate distributed by the first material distribution device by changing the material blocking template; the marbleized pattern of the quartz stone plate is changed more abundantly, the requirement of diversification of pattern patterns of the plate is met, and the operation of changing the pattern patterns is simple and portable. The first material distributing mechanism can realize material distribution and compaction of the first mineral mixture, so that the first mineral mixture is more compact, and the problem of edge collapse is avoided; meanwhile, through the cooperation of the trowelling piece and the grid, the second mineral mixture can be distributed in the area which is not occupied by the first mineral mixture, the problem that the second mineral mixture is agglomerated is solved, and therefore the situation that the second mineral mixture collides with the edges of the texture grooves to cause the texture grooves to collapse is avoided. In addition, each texture pattern of the product prepared by the material distribution equipment of the quartz stone plate does not need to be matched with two sets of complementary hollowed-out dies, so that the production cost is lower, and the types of the texture patterns are more various.

Drawings

Fig. 1 is a schematic structural view of a distributing apparatus (a first frame and a first conveyor are not shown) for quartz stone plates according to one embodiment of the present invention;

FIG. 2 is a schematic view of a first distributing mechanism according to one embodiment of the present invention;

FIG. 3 is a schematic view of a second distributing mechanism according to one embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

FIG. 5 is a schematic view of the structure of the receiving hopper in one embodiment of the invention;

FIG. 6 is a schematic cross-sectional view of a receiving hopper in one embodiment of the invention;

FIG. 7 is a schematic view showing the connection of the parts of the receiving hopper in one embodiment of the invention;

in the accompanying drawings: a conveyor belt assembly 1, a first distributing mechanism 2 and a second distributing mechanism 3;

a conveyor belt frame 11, a conveyor belt 12, a driving device 13, a driven roller 14, and a driving roller 15; the material blocking template 20, the first rack 21, the first material distributing device 22 and the first moving assembly 23; a lifting assembly 24; a vertical plate 25; a grid 30; a swing unit 31 and a mounting frame 32; a second moving assembly 33;

A mineral mixture receiving piece 101, a striker plate 102; swing the discharge port 300; a first conveyor belt 221 and a second conveyor belt 222; a second elevation driving member 242; trowelling member 302; a fixing frame 303; a receiving hopper 311 and a swing driving device 312; connecting the arc 320 and the limit stop 321;

a limit baffle 3110; a first semicircular plate 3111, a second semicircular plate 3112, a first connection plate 3113, a second connection plate 3114; a drive wheel 3115; driven wheel 3116;

A first inclined plate 3113a, a first vertical plate 3113b; second inclined plate 3114a, second vertical plate 3114b.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "top", "bottom", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, features defining "first", "second" may include one or more such features, either explicitly or implicitly, for distinguishing between the descriptive features, and not sequentially, and not lightly.

In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

The invention provides a quartz stone distribution method, which comprises the following steps:

Step one: performing first cloth; dividing the mineral mixture carrier 101 into a first distribution area and a second distribution area, wherein the first distribution area and the second distribution area are used for respectively distributing different mineral mixtures, and the areas of the mineral mixture carrier 101 are complete after combination;

Covering a material blocking template 20 above the second material distribution area, wherein the material blocking template 20 is a box body with a top surface and a peripheral enclosing frame, and the peripheral enclosing frame forms a limit between the second material distribution area and the first material distribution area; applying a first mineral mixture to the first distribution area, such that the first mineral mixture fills the first distribution area; the height of the material blocking template 20 is 10-20 mm lower than the thickness of the first mineral mixture;

step two: compacting the first mineral mixture;

step three: a second cloth; removing the material blocking template 20 to form a second material distribution area; applying a second mineral mixture to the second distribution area to fill the second distribution area, the second mineral mixture forming a texture with the first mineral mixture due to the different composition;

Step four: strickling the mineral mixture; the second mineral mixture in the mineral mixture receiver 101 is scraped off and the grain grooves are filled up to obtain a slab blank.

Referring to fig. 1 to 7, the present invention provides a material distribution device for a quartz stone plate, which is applied to the quartz stone material distribution method, and includes a mineral mixture receiving member 101, only one set of material blocking templates 20, a grid 30, a conveyor belt assembly 1, a first material distribution mechanism 2 and a second material distribution mechanism 3; the first material distributing mechanism 2 and the second material distributing mechanism 3 are sequentially arranged on the conveyor belt assembly 1 along the conveying direction of the conveyor belt assembly 1; the conveyor belt assembly 1 is used to transport the mineral mixture carrier 101 from its upstream end to its downstream end;

The material blocking template 20 is a box body with a top surface and a peripheral enclosing frame, and is used for forming a limit between the second material distribution area and the first material distribution area, and a first mineral mixture accommodating cavity is arranged at the top of the material blocking template 20; the material blocking template 20 is arranged on the mineral mixture receiving piece 101; the first distributing mechanism 2 can move forward or backward along the conveying direction; the first distributing mechanism 2 is used for distributing the first mineral mixture to the mineral mixture receiving piece 101, removing the material blocking template 20 and compacting the first mineral mixture;

The second distributing mechanism 3 is used for distributing a second mineral mixture to the mineral mixture receiving member 101; the second distributing mechanism 3 is provided with a trowelling piece 302, the grid 30 is arranged below the second distributing mechanism 3, and the trowelling piece 302 is higher than or equal to the top surface of the first mineral mixture paved on the mineral mixture supporting piece 101; the trowelling member 302 scrapes the second mineral mixture applied by the second distributing mechanism 3 from the mesh 30 to the mineral mixture receiving member 101, and fills up the texture grooves.

In the specific embodiment of the invention, a conveyor belt assembly 1 is arranged, a first distributing mechanism 2 and a second distributing mechanism 3 are arranged on the conveyor belt assembly 1, and a mineral mixture receiving piece 101 is conveyed through the conveyor belt assembly 1; the first distributing mechanism 2 can move forward or backward along the conveying direction of the conveyor belt assembly 1, and when the material is required to be distributed, the first distributing mechanism 2 moves to the material distribution area of the mineral mixture receiving member 101 for material distribution. In the distributing equipment of the quartz stone plate, only one set of material blocking templates 20 is arranged, and before the first material distribution, the material blocking templates 20 are placed in the mineral mixture receiving piece 101. The height of the material blocking template 20 is lower than the discharge hole of the first distributing device 22, and when the first distributing device 23 discharges the first mineral mixture, the first mineral mixture which is not blocked by the material blocking template 20 falls onto the mineral mixture receiving piece 101; while a portion of the first mineral mixture is blocked by the dam platen 20 and remains on the dam platen 20 such that the first mineral mixture of the mineral mixture receiver 101 forms texture grooves. The top of the material blocking template 20 is provided with a first mineral mixture accommodating cavity, and the height of the material blocking template 20 is 10-20 mm lower than the thickness of the first mineral mixture; when the material is distributed, part of the first mineral mixture is covered above the material blocking template 20; when the dam plate 20 is removed, the first mineral mixture spread on top of the dam plate 20 is prevented from falling off when removed. The first mineral mixture has viscosity, can be fixed into a stable shape after being compressed by the first distributing mechanism 2, and is not easy to collapse.

When the second distributing mechanism 3 discharges the second mineral mixture, part of the second mineral mixture directly falls into the texture groove through the grid 30; since the mesh 30 is higher than or equal to the top surface of the first mineral mixture laid on the mineral mixture receiver 101, the trowelling member 302 scrapes another portion of the second mineral mixture off the mesh 30 to the mineral mixture receiver 101 and fills up the texture grooves. A small amount of the second mineral mixture is laid on the surface of the first mineral mixture, and after pressing and curing, the side on the bottom surface of the mineral mixture holder 101 is the top surface of the quartz stone plate, and the side on which the first mineral mixture and the second mineral mixture are mixed is the bottom surface of the quartz stone plate. When scraped, small amounts of the first mineral mixture and the second mineral mixture may result, but the side where the first mineral mixture and the second mineral mixture are mixed is the bottom surface of the quartz stone plate, and does not affect the appearance of the quartz stone plate product. And the subsequent working procedures such as pressing and the like can be continued on the plate blank, so that gaps of texture grooves can be completely filled, and the occurrence of gaps on the surface of a final product is avoided. In one embodiment of the invention, the top surface of the first mineral mixture is 5mm different from the mesh 30.

By changing the material blocking template 20, the texture pattern of the plate material distributed by the first distribution device 22 can be changed; the marbleized pattern of the quartz stone plate is changed more abundantly, the requirement of diversification of pattern patterns of the plate is met, and the operation of changing the pattern patterns is simple and portable.

Meanwhile, through the cooperation of the trowelling piece 302 and the grid 30, the second mineral mixture can be distributed in the area which is not occupied by the first mineral mixture, so that the second mineral mixture is prevented from agglomerating and accumulating on the bottom surface of the quartz stone plate, the problem that the bottom surface of the quartz stone plate is defective or irregular is caused, and the first mineral mixture is pressed into a block shape, so that the situation that the second mineral mixture collides with the edges of the texture grooves and the texture grooves collapse is avoided when the second mineral mixture is distributed.

One side of the bottom surface of the mineral mixture holder 101 is the top surface of the quartz plate, and one side of the top surface of the mineral mixture holder 101 is the bottom surface of the quartz plate. Therefore, the second distributing mechanism 3 does not need to calculate the volume of the second mineral mixture accurately in advance when the second mineral mixture is distributed, and only needs to simply and quantitatively distribute the second mineral mixture and scrape the second mineral mixture. The redundant second mineral mixture is positioned on the bottom surface of the quartz stone plate, and the thickness of the quartz stone plate can be adjusted through subsequent procedures.

The mineral mixture receiving member 101 is specifically a mold frame for receiving the mineral mixture.

Specifically, the material distribution equipment further comprises a conveying belt assembly 1, and the first material distribution mechanism 2 and the second material distribution mechanism 3 are arranged on the conveying belt assembly 1; the first distributing mechanism 2 comprises a first rack 21, a first distributing device 22, a first moving assembly 23, a lifting assembly 24 and a mold frame removing device;

The first distributing device 22 comprises a first conveying belt 221 and a second conveying belt 222, the first conveying belt 221 and the second conveying belt 222 are respectively installed on the first frame 21, and the discharging end of the first conveying belt 221 is located above the feeding end of the second conveying belt 222 and is used for paving the first mineral mixture; the first frame 21 is erected on the conveyor belt assembly 1, and the first moving assembly 23 is arranged on the first frame 21 and is used for driving the first distributing device 22 to reciprocate along the conveying direction;

The lift assembly 24 includes a first lift drive, a second lift drive 242, a first lift bar, and a second lift bar; the first lifting driving piece is arranged on one side of the conveying direction of the conveying belt assembly 1, and the second lifting driving piece 242 is arranged on the other side of the conveying direction of the conveying belt assembly 1; the first lifting rod and the second lifting rod are respectively arranged along the conveying direction of the conveying belt assembly 1, the first lifting rod is connected with the driving end of the first lifting driving piece, and the second lifting rod is connected with the driving end of the second lifting driving piece 242; the width of the mineral mixture receiving piece 101 is larger than the width of the conveying belt assembly 1, and the distance between the first lifting rod and the second lifting rod is matched with the width of the mineral mixture receiving piece 101; the mould frame removing device is arranged on the first frame 21 and is used for removing the material blocking mould plate 20 from the mineral mixture receiving piece 101 perpendicular to the conveying direction.

The conveyor belt assembly 1 conveys the mineral mixture receiving piece 101, the mineral mixture receiving piece 101 passes through the first distributing device 22 and receives the first mineral mixture discharged by the first distributing device 22; subsequently, the mineral mixture receiving piece 101 is conveyed to a discharge hole of the second distributing mechanism 3 through the conveying belt assembly 1, and receives the second mineral mixture discharged by the second distributing mechanism 3; finally, the quartz stone plate with the imitation marble cracks can be prepared by the following procedures of pressing and the like after the quartz stone plate is conveyed out of the equipment through the conveying belt assembly 1.

The first mineral mixture is transported from the first conveyor belt 221 to the second conveyor belt 222 and from the second conveyor belt 222 to the mineral mixture carrier 101. The first frame 21 serves to connect the first conveyor 221, the second conveyor 222, the first moving assembly 23, and the mold frame removing device. The first moving assembly 23 moves the first conveyor belt 221 and the second conveyor belt 222 through the first frame 21. The first moving assembly 23 will drive the first conveyor belt 221 and the second conveyor belt 222 to move through the first frame 21. When the first mineral mixture needs to be compressed, the first lifting driving piece and the second lifting driving piece 242 are synchronously started, the driving end of the first lifting driving piece lifts the first lifting rod, and the driving end of the second lifting driving piece 242 lifts the second lifting rod, so that the first lifting rod and the second lifting rod extend out of two sides of the conveyor belt assembly 1; the distance between the first lifting rod and the second lifting rod is matched with the width of the mineral mixture supporting piece 101, the mineral mixture supporting piece 101 is lifted, the mineral mixture supporting piece 101 leaves the conveying belt assembly 1, the mineral mixture supporting piece 101 is close to the second conveying belt 222, the purpose of pressing the first mineral mixture is achieved, and therefore the problem that texture grooves collapse is avoided. Next, the driving end of the first lifting driving member drives the first lifting rod to reset, and the second lifting driving member 242 drives the second lifting rod to reset, so that the first lifting rod and the second lifting rod retract from two sides of the conveyor belt assembly 1, and the mineral mixture receiving member 101 is replaced back to the conveyor belt assembly 1.

In one embodiment of the present invention, the first elevation driving member includes a driving motor and two lifters, and the second elevation driving member 242 includes two lifters, and the first elevation driving member and the second elevation driving member 242 are combined into a synchronous lifter through a synchronous shaft to achieve synchronous elevation.

In one embodiment of the present invention, the mold frame removing device is not shown, specifically, the clamping lifting device is not shown, the top surface of the material blocking mold plate 20 is provided with a clamping piece for clamping, the clamping mechanism penetrates through the clamping piece clamped by the first mineral mixture, the mold frame removing device clamps the clamping piece of the material blocking mold plate 20 through the clamping mechanism, and then the clamping mechanism is moved upwards through the lifting device, so that the material blocking mold plate 20 is driven to move out of the mineral mixture receiving piece 101 perpendicular to the conveying direction. As a simple alternative, the mold frame removal device may be a robot.

The first moving assembly 23 and the second moving assembly 33 have the same structure, and reference is made to the existing moving device. The first moving assembly 23 comprises a rack, a driving motor, a moving frame, a driving gear and a driven gear, wherein the racks are arranged on two sides of the first frame 21, the driving gear is arranged on one side of the moving frame, and the driven gear is arranged on the other side of the moving frame; the driving gear is meshed with the rack on one side, the driven gear is meshed with the rack on the other side, the fixed end of the driving motor is arranged on the moving frame, the driving end of the driving motor is assembled with the driving gear in a driving mode, the driving gear is driven to rotate through the driving motor, and therefore the moving frame is driven to move along the direction of the rack. The first distributing device 22 is disposed on the corresponding moving frame.

Specifically, the second distributing mechanism 3 comprises a swinging unit 31 and a mounting frame 32, and the mounting frame 32 is erected above the conveyor belt assembly 1; the mounting frame 32 is provided with an avoidance area, two ends of the swinging unit 31 along the X-axis direction are respectively rotationally assembled in the avoidance area, the bottom of the swinging unit 31 is provided with a swinging discharge hole 300, and two sides of the bottom of the swinging discharge hole 300 along the X-axis direction are provided with trowelling pieces 302; the grid 30 is arranged between the conveyor belt assembly 1 and the discharge port of the swinging unit 31; the swinging unit 31 swings reciprocally with the central axis in the X-axis direction as a swinging axis, and drives the trowelling member 302 to be far away from or close to the grid 30.

When the swing unit 31 swings to one side with the center axis in the X-axis direction as the swing axis, the trowelling member 302 on one side is away from the grid 30, and at the same time, the trowelling member 302 on the other side is close to the grid 30; subsequently, the swinging unit 31 swings reversely with the center axis in the X-axis direction as the swing axis, the trowelling member 302 on one side approaching the grid 30 while the trowelling member 302 on the other side being away from the grid 30; the reciprocating motion is such that the trowelling member 302 periodically moves away from or toward the mesh 30, and the space between the trowelling member 302 and the mesh 30 gradually decreases from large to small and then increases from small to large. The mesh 30 is formed by combining a plurality of steel wires, has a plurality of hole structures, and after the mineral mixture in the swinging unit 31 is discharged from the swinging discharge port 300, the trowelling member 302 swings along with the swinging unit 31, so that the mineral mixture can be rolled, passes through the hole structures of the mesh 30, and falls into the mineral mixture receiving member.

By the cooperation of the trowelling member 302 of the swinging unit 31 and the grid 30, the mineral mixture is cut to be finer and looser, the mineral mixture is spread more uniformly, and the texture effect of the product is better after firing.

Applying second mineral mixtures with different colors to texture grooves at different positions through a second material distribution mechanism 3, and scraping by a trowelling piece 302 after the second mineral mixtures with one color are applied, so that the second mineral mixtures with the color enter the corresponding texture grooves, and the redundant second mineral mixtures are spread on the surface of the first mineral mixtures; since the side where the first mineral mixture and the second mineral mixture are mixed is the bottom surface of the quartz stone plate, the second mineral mixture is spread on the first mineral mixture and does not affect the actual appearance of the product.

The swinging unit 31 comprises a receiving hopper 311 and a swinging driving device 312, the swinging driving device 312 is arranged on the mounting frame 32, two ends of the receiving hopper 311 are respectively assembled with the mounting frame 32 in a rotating way and are in transmission connection with the swinging driving device 312, so that the receiving hopper 311 rotates and swings by taking a connecting line of the connecting positions of the two ends of the receiving hopper 311 as an axis; the swing discharging hole 300 is arranged at the bottom of the receiving hopper 311.

By adopting the structure, the connecting hopper 311 can rotate and swing by taking the connecting line at the connecting positions of the two ends as the shaft, so that the problem that the mineral mixture cannot be smoothly discharged from the connecting hopper 311 due to friction force and self adhesive force is avoided, and the mineral mixture can be discharged in time and falls into the texture groove. The swing driving device 312 may refer to an existing motor to drive the receiving hopper 311 to swing.

Specifically, the receiving hopper 311 includes a first semicircular plate 3111, a second semicircular plate 3112, a first connection plate 3113, and a second connection plate 3114;

The first connection plate 3113 and the second connection plate 3114 are arranged side by side, the outer sides of the first connection plate 3113 and the second connection plate 3114 are respectively provided with a fixing frame 303, one end of the fixing frame 303 is respectively connected with the inner side of the first semicircular plate 3111, and the other end of the fixing frame 303 is respectively connected with the inner side of the second semicircular plate 3112; the bottoms of the first semicircular plate 3111, the second semicircular plate 3112, the first connecting plate 3113 and the second connecting plate 3114 are matched to form a swinging discharge port 300; the trowelling member 302 is disposed at the bottom of the first connection plate 3113 or the second connection plate 3114;

the outer side of the first semicircular plate 3111 is provided with a driving wheel 3115, the driving wheel 3115 is in driving connection with the driving end of the swing driving device 312, the outer side of the second semicircular plate 3112 is provided with a driven wheel 3116, and the driven wheel 3116 is rotatably assembled on the mounting frame 32.

The receiving hopper 311 is in transmission connection with the driving end of the swing driving device 312 through a transmission wheel 3115, so that the swing action is realized. The structure is simple, and the receiving hopper 311 is stable and reliable in the swinging process. The first connection plate 3113 and the second connection plate 3114 are each provided with a fixing frame 303, and are fixed between the first semicircular plate 3111 and the second semicircular plate 3112 by the fixing frame 303 to form the swing discharge port 300.

Specifically, the first connection plate 3113 and the second connection plate 3114 are mirror-symmetrical with respect to a line connecting two ends of the receiving hopper 311 as a symmetry axis, the first connection plate 3113 includes a first inclined plate 3113a and a first vertical plate 3113b integrally formed, and the second connection plate 3114 includes a second inclined plate 3114a and a second vertical plate 3114b integrally formed; the outer sides of the first inclined plate 3113a, the first vertical plate 3113b, the second inclined plate 3114a and the second vertical plate 3114b are respectively provided with a fixing bracket 303; the first inclined plate 3113a is inclined to one side, the second inclined plate 3114a is inclined to the other side, and the first semicircular plate 3111, the second semicircular plate 3112, the first inclined plate 3113a and the second inclined plate 3114a cooperate to form a horn-shaped feed port;

The first and second risers 3113b, 3114b are each provided with a trowelling 302.

The first inclined plate 3113a and the first vertical plate 3113b are combined to form a first connection plate 3113, and the first inclined plate 3113a and the first vertical plate 3113b are connected to the inner side of the first semicircular plate 3111 and the inner side of the second semicircular plate 3112 by means of the fixing frame 303, thereby achieving fixation.

The second inclined plate 3114a and the second vertical plate 3114b are combined to form a second connection plate 3114, and the second inclined plate 3114a and the second vertical plate 3114b are connected to the inner side of the first semicircular plate 3111 and the inner side of the second semicircular plate 3112 through the fixing frame 303, thereby achieving fixation.

With the above configuration, the first inclined plate 3113a and the second inclined plate 3114a are inclined, and the feed ports are formed in a horn shape, so that the loading area of the receiving hopper 311 can be increased. The first inclined plate 3113a and the second inclined plate 3114a are inclined so that the mineral mixture can slide inside the receiving hopper 311, and the mineral mixture can be easily fed into the receiving hopper 311.

Specifically, the mounting frame 32 is provided with connecting arc plates 320 at two sides of the avoidance area along the X-axis direction, a limit stop 321 is provided at the outer side of the connecting arc plates 320, limit baffles 3110 are provided at two outer walls of the receiving hopper 311 at two sides of the X-axis direction, and the positions of the limit stop 321 and the limit baffles 3110 correspond.

With the above structure, when the receiving hopper 311 swings to a predetermined position to one side, the limit stopper 321 of the other side abuts against the corresponding limit baffle 3110; similarly, when the hopper 311 swings to the other side to a predetermined position, the limit stop 321 on the opposite side abuts against the corresponding limit baffle 3110. The limit stop 321 and the limit baffle 3110 can limit the swing amplitude of the receiving hopper 311, and prevent the receiving hopper 311 from being thrown out of the mineral mixture due to the overlarge swing amplitude.

The second distributing mechanism 3 further comprises a second moving assembly 33, wherein the fixed end of the second moving assembly 33 is arranged on the mounting frame 32, and the driving end of the second moving assembly 33 is arranged on one side of the conveying belt assembly 1 along the Y-axis direction and is used for driving the swinging unit 31 and the mounting frame 32 to reciprocate along the Y-axis direction.

In one embodiment of the present invention, the mesh 30 is formed by combining a plurality of steel wires side by side at intervals, and the steel wires are perpendicular to the conveying direction of the conveyor belt assembly 1.

As the trowelling member 302 passes, the second mineral mixture may be cut finer and looser, allowing the second mineral mixture to fill more easily and more evenly, allowing the second mineral mixture in the texture grooves to exhibit better texture after firing.

Specifically, the material blocking template 20 includes a plurality of boxes with irregular top surfaces, and the boxes are arranged at intervals.

In one embodiment of the invention, the box is irregularly shaped, and when the first distributing device 22 discharges the first mineral mixture, the first mineral mixture which is not blocked by the blocking template 20 falls onto the mineral mixture receiving piece 101; while a portion of the first mineral mixture is blocked by the cartridge and remains on the top surface of the cartridge, forming irregular texture grooves. After the second distributing mechanism 3 discharges the second mineral mixture, the grid 30 and the trowelling member 302 scrape the second mineral mixture into the texture groove, and a quartz stone plate with a marble-like texture can be formed through subsequent processes. The irregular shape includes a rectangle with wavy sides and a polygon with different side lengths.

Specifically, the upstream end and the downstream end of the upstream of the second distribution area are respectively provided with a striker plate 102. With the above structure, the trowelling member 302 can be prevented from scraping the second mineral mixture onto the conveyor belt assembly 1 by the dam 102, and the second mineral mixture is prevented from contaminating the conveyor belt assembly 1. Specifically, the two sides of the conveyor belt assembly 1 are respectively provided with a vertical plate 25, the vertical plates 25 are matched to form a template placing frame, and the material blocking template 20 is laid on the template placing frame.

In the specific embodiment, the material blocking template 20 is supported by a template holder, so as to achieve the purpose of being arranged above the conveyor belt assembly 1.

Specifically, the conveyor belt assembly 1 includes a conveyor belt frame 11, a conveyor belt 12, a driving device 13, a driven roller 14, and at least one driving roller 15; the driven roller 14 is arranged at one end of the conveyor belt frame 11, the driving roller 15 is arranged at the other end of the conveyor belt frame 11, the conveyor belt 12 is sleeved outside the driven roller 14 and the driving roller 15, and the driving device 13 is arranged at one side of the driving roller 15 along the Y-axis direction and is in driving connection with the driving roller 15.

The conveyor belt assembly 1 can refer to the existing conveyor belt assembly, and the driving device 13 drives the driving roller 15 to rotate, so that the conveyor belt 12 and the driven roller 14 are driven to rotate, the conveyor belt 12 can drive the mineral mixture bearing piece 101 to move, and the purpose of conveying the mineral mixture bearing piece 101 is achieved.

The technical principle of the present application is described above in connection with the specific embodiments. The description is made for the purpose of illustrating the general principles of the application and should not be taken in any way as limiting the scope of the application. Other embodiments of the application will occur to those skilled in the art from consideration of this specification without the exercise of inventive faculty, and such equivalent modifications and alternatives are intended to be included within the scope of the application as defined in the claims.

Claims (8)

1. The quartz stone material distribution method is characterized by being realized by quartz stone material distribution equipment, wherein the quartz stone material distribution equipment comprises a mineral mixture receiving piece (101), only one set of material blocking templates (20), a grid (30), a first material distribution mechanism (2) and a second material distribution mechanism (3); the first distributing mechanism (2) and the second distributing mechanism (3) are sequentially arranged along the conveying direction of the mineral mixture bearing piece (101);

the material blocking template (20) is a box body with a top surface and a peripheral enclosing frame and is used for forming a limit between a second material distribution area and a first material distribution area, and a first mineral mixture accommodating cavity is arranged at the top of the material blocking template (20); the material blocking template (20) is arranged on the mineral mixture receiving piece (101); the first distributing mechanism (2) can move forwards or backwards along the conveying direction; the first distributing mechanism (2) is used for distributing a first mineral mixture to the mineral mixture bearing piece (101), moving out a material blocking template (20) and compacting the first mineral mixture;

The second distributing mechanism (3) is used for distributing a second mineral mixture to the mineral mixture receiving piece (101); the second distributing mechanism (3) is provided with a trowelling piece (302), the grid (30) is arranged below the second distributing mechanism (3), and the trowelling piece (302) is higher than or equal to the top surface of the first mineral mixture paved on the mineral mixture supporting piece (101); the trowelling piece (302) scrapes the second mineral mixture distributed by the second distributing mechanism (3) from the grid (30) to the mineral mixture bearing piece (101) and fills up texture grooves;

The material distribution equipment further comprises a transmission belt assembly (1), and the first material distribution mechanism (2) and the second material distribution mechanism (3) are arranged on the transmission belt assembly (1); the second distributing mechanism (3) comprises a swinging unit (31) and a mounting frame (32), and the mounting frame (32) is arranged above the conveying belt assembly (1); the mounting frame (32) is provided with an avoidance area, two ends of the swinging unit (31) along the X-axis direction are respectively rotationally assembled in the avoidance area, the bottom of the swinging unit (31) is provided with a swinging discharge hole (300), and the trowelling piece (302) is arranged at two sides of the bottom of the swinging discharge hole (300) along the X-axis direction; the grid (30) is arranged between the conveying belt assembly (1) and the discharge port of the swinging unit (31); the swinging unit (31) swings reciprocally by taking the central axis in the X-axis direction as a swinging axis to drive the trowelling piece (302) to be far away from or close to the grid (30);

The quartz stone distribution method comprises the following steps:

step one: performing first cloth; dividing the mineral mixture carrier (101) into a first distribution area and a second distribution area, wherein the first distribution area and the second distribution area are used for respectively distributing different mineral mixtures, and the first distribution area and the second distribution area are combined to form a complete mineral mixture carrier (101);

Covering a material blocking template (20) above the second material distribution area, wherein the material blocking template (20) is a box body with a top surface and a peripheral enclosing frame, and the peripheral enclosing frame forms a limit between the second material distribution area and the first material distribution area; applying a first mineral mixture to the first material distribution area, filling the first material distribution area with the first mineral mixture, and covering the first mineral mixture on a material blocking template (20), wherein the height of the material blocking template (20) is 10-20 mm lower than the thickness of the first mineral mixture;

step two: compacting the first mineral mixture;

Step three: a second cloth; removing the material blocking template (20) to form a second material distribution area; applying a second mineral mixture to the second distribution area to fill the second distribution area, the second mineral mixture forming a texture with the first mineral mixture due to the different composition;

Step four: strickling the mineral mixture; scraping the second mineral mixture in the mineral mixture receptacle (101) and filling up the texture grooves; and taking one side of the bottom surface of the mineral mixture bearing piece (101) as the top surface of the quartz stone plate, and taking one side of the mixed first mineral mixture and second mineral mixture as the bottom surface of the quartz stone plate to obtain a plate blank.

2. A quartz stone distributing method according to claim 1, characterized in that the first distributing mechanism (2) comprises a first frame (21), a first distributing device (22), a first moving assembly (23), a lifting assembly (24) and a mould frame removing device;

the first material distribution device (22) comprises a first conveying belt (221) and a second conveying belt (222), the first conveying belt (221) and the second conveying belt (222) are respectively arranged on the first frame (21), and the discharge end of the first conveying belt (221) is positioned above the feed end of the second conveying belt (222) and used for paving a first mineral mixture; the first rack (21) is erected on the conveyor belt assembly (1), and the first moving assembly (23) is arranged on the first rack (21) and is used for driving the first distributing device (22) to reciprocate along the conveying direction;

The lifting assembly (24) includes a first lifting drive, a second lifting drive (242), a first lifting bar, and a second lifting bar; the first lifting driving piece is arranged on one side of the conveying direction of the conveying belt assembly (1), and the second lifting driving piece (242) is arranged on the other side of the conveying direction of the conveying belt assembly (1); the first lifting rod and the second lifting rod are respectively arranged along the conveying direction of the conveying belt assembly (1), the first lifting rod is connected with the driving end of the first lifting driving piece, and the second lifting rod is connected with the driving end of the second lifting driving piece (242); the width of the mineral mixture bearing piece (101) is larger than the width of the conveying belt assembly (1), and the distance between the first lifting rod and the second lifting rod is matched with the width of the mineral mixture bearing piece (101); the mould frame removing device is arranged on the first frame (21) and is used for removing the material blocking mould plate (20) from the mineral mixture bearing piece (101) perpendicular to the conveying direction.

3. The quartz stone distribution method according to claim 1, wherein the swinging unit (31) comprises a receiving hopper (311) and a swinging driving device (312), the swinging driving device (312) is arranged on the mounting frame (32), two ends of the receiving hopper (311) are respectively assembled with the mounting frame (32) in a rotating way and are in transmission connection with the swinging driving device (312), so that the receiving hopper (311) rotates and swings by taking a connecting line of two ends of the receiving hopper (311) as an axis; the swinging discharge hole (300) is arranged at the bottom of the receiving hopper (311).

4. The quartz stone distribution method according to claim 1, wherein the second distribution mechanism (3) further comprises a second moving assembly (33), a fixed end of the second moving assembly (33) is arranged on the mounting frame (32), and a driving end of the second moving assembly (33) is arranged on one side of the conveying belt assembly (1) along the Y-axis direction and is used for driving the swinging unit (31) and the mounting frame (32) to reciprocate along the Y-axis direction.

5. A quartz stone distribution method according to claim 2, characterized in that the grid (30) is formed by a plurality of steel wires which are arranged side by side at intervals, said wires being perpendicular to the conveying direction of the conveyor belt assembly (1).

6. The quartz stone distribution method according to claim 1, wherein the material blocking template (20) comprises a plurality of boxes with irregular top surfaces, and the boxes are arranged at intervals.

7. A quartz stone distribution method according to claim 1, characterized in that the upstream and downstream ends of the second distribution area are provided with a dam plate (102), respectively.

8. A quartz stone distribution method according to claim 1, characterized in that the conveyor belt assembly (1) comprises a conveyor belt frame (11), a conveyor belt (12), a driving device (13), a driven roller (14) and at least one driving roller (15); the driven roller (14) is arranged at one end of the conveyor belt frame (11), the driving roller (15) is arranged at the other end of the conveyor belt frame (11), the conveyor belt (12) is sleeved on the outer sides of the driven roller (14) and the driving roller (15), and the driving device (13) is arranged at one side of the driving roller (15) along the Y-axis direction and is in driving connection with the driving roller (15).