CN217454573U - Material distribution equipment for artificial board textures - Google Patents

Abstract

The distributing equipment for the texture of the artificial board comprises a stock bin assembly, a quantitative material scattering assembly and a distributing driving device; the bin assembly is provided with a discharge hole; the quantitative material spreading assemblies at least comprise two; the quantitative material scattering assemblies are arranged under the discharge port in the width direction; the material distribution driving device is used for independently driving each quantitative material scattering assembly, and the quantitative material scattering assemblies are driven by the material distribution driving device to enable the quantitative material scattering assemblies to seal the discharge port and stop material distribution or distribute powder material to a material distribution area right below the discharge port. The application discloses distribution equipment can be through removing the ration spills the material subassembly for the powder of feed bin subassembly can accurately spill and fall to on the different cloth region of powder carrier, thereby make the powder carrier can form different texture patterns.

Description

Material distribution equipment for artificial board textures

Technical Field

The utility model relates to a panel production technical field especially relates to a cloth equipment of artificial panel texture.

Background

The natural stone has natural and fine texture, clear layers, transparent color and strong stereoscopic impression, is always an ideal material for home decoration, has rich texture and color, and is always a product imitated by ceramics and artificial stones. Due to the limitation of the texture distribution mode of the prior quartz plate, the produced product has simple texture, single color and small change of style and variety, and can not meet the requirements of customers and markets.

SUMMERY OF THE UTILITY MODEL

To the problem that the background art provided, the utility model aims to provide a cloth equipment of artificial panel texture has solved the single problem of texture that current cloth equipment formed.

To achieve the purpose, the utility model adopts the following technical proposal:

the distributing equipment for the texture of the artificial board comprises a stock bin assembly, a quantitative material scattering assembly and a distributing driving device; the bin assembly is provided with a discharge hole; the quantitative material spreading assemblies at least comprise two; the quantitative material scattering assemblies are arranged under the discharge port in the width direction; the material distribution driving device is used for independently driving each quantitative material scattering assembly, and the quantitative material scattering assemblies are driven by the material distribution driving device to enable the quantitative material scattering assemblies to seal the discharge port and stop material distribution or distribute powder material to a material distribution area right below the discharge port.

Preferably, a transportation platform is arranged below the quantitative material spreading assembly along the length direction; the transportation platform is used for driving the cloth carrier to move under all the quantitative material scattering assemblies.

Preferably, the dosing spreading assembly comprises a bottom plate and a dosing plate; the bottom plate is provided with a material distribution hole; the quantitative plate is arranged between the discharge hole and the bottom plate, and the bottom surface of the quantitative plate is tightly attached to the top surface of the bottom plate; the quantitative plate is provided with a buffer hole; the quantitative plate is in transmission connection with the cloth driving device, and the cloth driving device can drive the quantitative plate to slide along the length direction relative to the bottom plate, so that the cache hole is communicated with the discharge hole or the cloth hole.

Preferably, the quantitative plate is provided with at least two buffer holes along the length direction, and the radial sizes of the buffer holes on the same quantitative plate are not completely equal.

Preferably, the discharge gate is equipped with the elasticity flange, the upside of elasticity flange with discharge gate fixed connection, the downside of elasticity flange with the installation of contradicting of the top surface of graduated flask.

Preferably, the top surface of the transportation platform is provided with a mounting support; the cloth driving device is a telescopic cylinder; the telescopic cylinder is installed on the installation support, and a telescopic driving end of the telescopic cylinder is in transmission connection with the quantitative plate.

Preferably, the mounting support further comprises a plurality of mounting holes, and the mounting holes are uniformly arranged at intervals along the length direction; the telescopic cylinder is connected with the mounting hole through a connecting piece, so that the telescopic cylinder is adjustably mounted on the mounting support.

Preferably, the bottom of the bin assembly is provided with a screw assembly, and the bin screw assembly comprises a rotary driving piece and a screw; the screw rod penetrates through the bottom of the storage bin along the width direction; the screw rod is in transmission connection with the rotary driving piece, so that the screw rod can rotate along the axis direction of the screw rod.

Preferably, the screw further comprises a plurality of stirring blades.

Preferably, the cloth feeding device further comprises a controller, and the controller is electrically connected with the cloth driving device.

Compared with the prior art, one of the technical schemes has the following beneficial effects:

the utility model provides a distribution equipment can be through removing the material subassembly is spilt to the ration for the powder of feed bin subassembly can spill accurately and fall to on the different cloth regions of powder carrier, thereby make the powder carrier can form different texture pattern.

Drawings

Fig. 1 is a front view of a material distribution apparatus according to an embodiment of the present invention;

fig. 2 is a top view of a material distribution apparatus according to an embodiment of the present invention;

FIG. 3 is a schematic view of a metering pad according to one embodiment of the present invention;

FIG. 4 is a schematic view of a screw assembly according to an embodiment of the present invention;

FIG. 5 is an enlarged partial view of the dashed circle A in FIG. 2;

fig. 6 is a schematic view of a screw according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to a number of technical features being indicated. Thus, features defined as "first", "second" and "third" may explicitly or implicitly include one or more of the features.

In a preferred embodiment of the present application, as shown in fig. 1 to 6, a distribution apparatus for artificial board texture includes a bin assembly 1, a quantitative spreading assembly 2, and a distribution driving device 3; the stock bin assembly 1 is provided with a discharge hole; the quantitative material spreading assembly 2 at least comprises two material spreading assemblies; the quantitative material scattering assemblies 2 are arranged under the discharge port in the width direction; the material distribution driving device 3 is used for independently driving each quantitative material scattering component 2, and the quantitative material scattering components 2 are driven by the material distribution driving device 3 to enable the quantitative material scattering components 2 to seal the discharge port and stop material distribution or distribute powder material to a material distribution area right below.

In this embodiment, the width direction is a front-rear direction, and the length direction is a left-right direction. The bin assembly 1 is used for containing powder forming textures; the silo assembly 1 discharges the powder through the discharge opening, so that the powder forms a texture on the cloth carrier 5. The powder discharged from the discharge port is scattered onto the cloth carrier 5 by the quantitative scattering member 2, thereby forming the texture. Specifically, at least two quantitative material scattering assemblies 2 are arranged below the discharge port for scattering materials, and the quantitative material scattering assemblies 2 are uniformly arranged at intervals in the front-back direction. Each quantitative spreading assembly 2 is separately connected with the cloth driving device 3 in a transmission way, so that each quantitative spreading assembly 2 can be separately moved along the left-right direction. This is done because the cloth carrier 5 is arranged below the dosing assembly 2 and the cloth carrier 5 is moved from right to left in this embodiment. Therefore, when the area of the cloth carrier 5 requiring distribution passes right below the quantitative material scattering assembly 2, the cloth driving device 3 drives the corresponding quantitative material scattering assembly 2 to move, so that the powder discharged from the discharge port is scattered on the cloth carrier 5 to form the area texture. When the distribution area moves out of the range of the quantitative material scattering assembly 2, the distribution driving device 3 drives the quantitative material scattering assembly 2 again, so that the quantitative material scattering assembly 2 seals the discharge port, and the powder stops scattering onto the distribution carrier 5. Similarly, when other cloth areas on the cloth carrier 5 pass through the quantitative material scattering assembly 2, the cloth driving device 3 can independently drive other corresponding quantitative material scattering assemblies 2 to move, and textures are formed on other cloth areas, so that a plurality of area textures are formed on the cloth carrier 5, and thus the plurality of area textures on the cloth carrier 5 can form an integral texture. Thus. The utility model provides a distribution equipment can be through removing material subassembly 2 is spilt to the ration for the powder of feed bin subassembly 1 can spill accurately to on the different cloth regions of powder carrier, thereby make the powder carrier can form different texture patterns.

Further, a transportation platform is arranged below the quantitative material scattering assembly 2 along the length direction; the transportation platform is used for driving the cloth carrier 5 to move under all the quantitative material scattering assemblies 2. This application passes through the transport platform drives cloth carrier 5 is in the ration spills the lower direction left branch removal of expecting subassembly 2, makes each cloth region can pass through on the cloth carrier 5 the ration spills expecting subassembly 2 under to can let the powder spill and form the texture on the cloth region.

Preferably, the dosing assembly 2 comprises a bottom plate 21 and a dosing plate 22; the bottom plate 21 is provided with a material distribution hole 210; the quantitative plate 22 is arranged between the discharge hole and the bottom plate 21, and the bottom surface of the quantitative plate 22 is tightly attached to the top surface of the bottom plate 21; the quantitative plate 22 is provided with a buffer hole 220; the quantitative plate 22 is in transmission connection with the cloth driving device 3, and the cloth driving device 3 can drive the quantitative plate 22 to slide along the length direction relative to the bottom plate 21, so that the buffer hole 220 is communicated with the discharge hole or the cloth hole 210. When the quantitative material spreading assembly 2 does not distribute the material, the buffer holes 220 on the quantitative plate 22 are communicated with the discharge port, so that the powder flows into the buffer holes 220 through the discharge port to be buffered. When the quantitative material spreading assembly 2 needs to distribute materials, the material distribution driving device 3 drives the quantitative plate 22 to move between the bottom plate 21 and the material outlet, so that the buffer holes 220 are communicated with the material outlet holes 210, and powder buffered in the buffer holes 220 passes through the material distribution holes 210 and is spread onto a material distribution area of the material distribution carrier 5, so as to form textures. The purpose of the arrangement is to limit the amount of powder scattered on the cloth carrier 5 through the buffer holes 220, so that the phenomenon that excessive powder is scattered on the cloth carrier 5 due to untimely driving of the cloth driving device 3 is avoided, thereby avoiding waste and saving production cost. Preferably, the top surface of the quantitative plate 22 is attached to the bottom surface of the discharge hole, and the bottom surface of the quantitative plate 22 is attached to the top surface of the bottom plate 21, so that the quantitative plate 22 can seal the buffer hole 220 to prevent powder from scattering when moving, and further, when the buffer hole 220 is communicated with the distribution hole 210, the quantitative plate 22 can seal the discharge hole to prevent the powder from being discharged from the discharge hole, thereby preventing powder waste.

More preferably, the metering plate 22 is provided with at least two buffer holes 220 along the length direction, and the radial sizes of the buffer holes 220 on the same metering plate 22 are not completely equal. In actual production, the cloth carrier 5 needs to form textures with different sizes, so that the diameters of the used powders are different. Therefore, the quantitative plate 22 is provided with different radial buffer holes 220, so that different buffer holes 220 are different in storage amount, different quantitative holes can be selected for buffer storage according to the diameter of the powder, and the application range is enlarged.

Further, the discharge gate is equipped with elasticity flange 11, the upside of elasticity flange 11 with discharge gate fixed connection, the downside of elasticity flange 11 with the installation is contradicted to the top surface of gage plate 22. The elastic flanges 11 are arranged to seal the left side and the right side of the discharge hole, so that powder leakage is avoided. Preferably, when the metering plate 22 moves the buffer hole 220 to be communicated with the material distribution hole 210 and the buffer hole 220 passes through the elastic rib 11, the buffer hole 220 is in elastic contact with the elastic rib 11, so as to reduce friction, so that the buffer hole 220 can easily pass through, thereby avoiding jamming.

In actual production and manufacturing of the cloth apparatus, the cloth driving device capable of driving the quantitative plate 22 to move horizontally is various, but in this embodiment, preferably, the cloth driving device 3 is a telescopic cylinder; the top surface of the transportation platform is provided with a mounting support 41; the telescopic cylinder is installed on the installation support 41, and a telescopic driving end of the telescopic cylinder is in transmission connection with the metering plate 22. Because telescopic cylinder drive is steady, and the transmission is accurate, so can control the accurate removal of calibration plate 22, ensure the accuracy of spilling the material.

Further, the mounting support 41 further includes a plurality of mounting holes 410, and the mounting holes 410 are uniformly arranged along the length direction at intervals; the telescopic cylinder is connected with the mounting hole 410 through a connecting member, so that the telescopic cylinder is adjustably mounted to the mounting bracket 41. Because the left end of the quantitative plate 22 is fixedly arranged on the telescopic cylinder, the telescopic cylinder is moved left and right, so that the discharge hole can be communicated with the buffer holes 220 with different apertures on the quantitative plate 22.

Furthermore, the bottom of the stock bin assembly 1 is provided with a screw assembly 12; the screw assembly 12 comprises a rotary drive 122 and a screw 121; the screw rod 121 is arranged along the width direction; the screw rod 121 is in transmission connection with the rotary driving member 122, so that the screw rod 121 can rotate along the axis direction thereof. After entering the stock bin assembly 1, the powder falls on the bottom of the stock bin assembly 1 under the action of gravity. However, the powder sometimes has an excessively large diameter and blocks the discharge port, so in this embodiment, a screw 121 is disposed at the bottom of the storage bin, and the screw 121 is connected to the rotary driving member 122 so as to rotate, thereby stirring the powder and preventing the powder from blocking the discharge port.

More preferably, the screw 121 further includes a plurality of stirring vanes 1211. In order to enable the screw 121 to stir the powder better, a plurality of stirring vanes 1211 are disposed on the screw 121 to ensure that the powder is in sufficient contact with the screw 121, thereby sufficiently stirring the powder. In this embodiment, the rotary driving member 122 is a driving motor.

Preferably, the cloth feeding device further comprises a controller, and the controller is electrically connected with the cloth driving device 3. In this embodiment, the controller is a PLC controller, and the PLC controller controls the work of the cloth driving device 3, so as to ensure that the cloth driving device 3 can precisely control each metering plate 22 to move, thereby ensuring precise material spreading.

The technical principle of the present invention is described above with reference to specific embodiments. The description is made for the purpose of illustrating the principles of the invention and should not be construed in any way as limiting the scope of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without any inventive effort, which would fall within the scope of the present invention.

Claims (10)

1. The distribution equipment of the artificial board textures is characterized by comprising a stock bin assembly, a quantitative material scattering assembly and a distribution driving device;

the bin assembly is provided with a discharge hole;

the quantitative material spreading assemblies comprise at least two;

the quantitative material scattering assemblies are arranged under the discharge port in the width direction;

the material distribution driving device is used for independently driving each quantitative material scattering assembly, and the quantitative material scattering assemblies are driven by the material distribution driving device to enable the quantitative material scattering assemblies to seal the discharge port and stop material distribution or distribute powder material to a material distribution area right below the discharge port.

2. The distribution equipment for artificial board textures according to claim 1, wherein a transport platform is arranged below the quantitative scattering assembly along a length direction;

the transportation platform is used for driving the cloth carrier to move under all the quantitative material scattering assemblies.

3. The distribution equipment for artificial board texture according to claim 2, wherein the quantitative distribution assembly comprises a bottom plate and a quantitative plate;

the bottom plate is provided with a material distribution hole;

the quantitative plate is arranged between the discharge hole and the bottom plate, and the bottom surface of the quantitative plate is tightly attached to the top surface of the bottom plate;

the quantitative plate is provided with a buffer hole;

the quantitative plate is in transmission connection with the cloth driving device, and the cloth driving device can drive the quantitative plate to slide along the length direction relative to the bottom plate, so that the cache hole is communicated with the discharge hole or the cloth hole.

4. The distribution equipment for artificial board texture as claimed in claim 3, wherein the quantitative plate is provided with at least two buffer holes along the length direction, and the radial sizes of the buffer holes on the same quantitative plate are not completely equal.

5. The distribution equipment for artificial board textures as claimed in claim 3, wherein the discharge port is provided with an elastic rib, the upper side of the elastic rib is fixedly connected with the discharge port, and the lower side of the elastic rib is installed in an abutting manner with the top surface of the quantitative plate.

6. The artificial board texture material distribution apparatus of claim 3, wherein the top surface of the transportation platform is provided with mounting supports;

the cloth driving device is a telescopic cylinder;

the telescopic cylinder is installed on the installation support, and a telescopic driving end of the telescopic cylinder is in transmission connection with the quantitative plate.

7. The apparatus for distributing artificial board texture according to claim 6, wherein the mounting base further comprises a plurality of mounting holes,

the mounting holes are uniformly arranged at intervals along the length direction;

the telescopic cylinder is connected with the mounting hole through a connecting piece, so that the telescopic cylinder is adjustably mounted on the mounting support.

8. The distribution equipment for artificial board textures as claimed in claim 1, wherein a screw assembly is provided at a bottom of the bin assembly;

the screw assembly comprises a rotary driving piece and a screw;

the screw rod penetrates along the width direction;

the screw rod is in transmission connection with the rotary driving piece, so that the screw rod can rotate along the axis direction of the screw rod.

9. The apparatus for distributing artificial board texture as claimed in claim 8, wherein the screw further comprises a plurality of stirring blades.

10. The apparatus for distributing artificial board texture according to claim 8, further comprising a controller, wherein the controller is electrically connected to the distribution driving device.

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