CN219820207U - Ceramic raw material homogenization system - Google Patents

Abstract

The utility model discloses a ceramic raw material homogenizing system which comprises a plurality of feeder assemblies, a feeding conveyor belt, a crusher, a movable cloth conveyor belt and a homogenizing bin, wherein the feeder assemblies are communicated with the crusher through the feeding conveyor belt, the movable cloth conveyor belt is communicated with the crusher, and the movable cloth conveyor belt is movably arranged on the homogenizing bin, so that the movable cloth conveyor belt can distribute materials back and forth on the homogenizing bin by means of the movable arrangement of the movable cloth conveyor belt. According to the utility model, the material is distributed back and forth on the homogenizing bin by moving the material distribution conveyor belt, so that the material homogenizing and mixing effect is achieved by layer-by-layer bedding during material discharging, the problem that the materials are locally piled up at the outlet position of the material feeding conveyor belt can be solved, and the ceramic raw material process formula is more stable.

Description

Ceramic raw material homogenization system

Technical Field

The utility model relates to the technical field of ceramic production, in particular to a ceramic raw material homogenizing system.

Background

The raw materials of the ceramic tile blank are usually more than ten or more, and after various raw materials are purchased from the outside, part of the raw materials are subjected to pretreatment and then stored in corresponding indoor storage bins for standby. For example, after a raw material workshop receives a production recipe, a loader driver can take materials and weigh each raw material into a feeder according to the order of the recipe so as to meet the requirements of the recipe. The batch mode generally uses a single feeder, and various raw materials are matched according to weight proportion and then are fed into an intermittent ball mill through a feeding belt. The whole process is complex in operation and easy to produce mismatch.

As mentioned above, some of the raw materials of the green part require pretreatment, such as mixing several raw materials first. The existing mixing method is to weigh the raw materials, then mix them manually or by a mixer, and then send them to a feeding conveyor belt after mixing them uniformly.

For example, application number 202010684145.3 discloses a ceramic raw material continuous mixing homogenization system, comprising a plurality of hoppers in a row, wherein electromagnetic valves are arranged at the outlets of the hoppers; the bottom of the hopper is provided with a weighing conveyor belt; the weighing conveyor belt is provided with a total conveyor belt below, the lower part of the transmission end of the total conveyor belt is provided with an inclined conveyor belt, the lower part of the transmission end of the inclined conveyor belt is provided with a mixer, and the lower part of the mixer is provided with a feeding conveyor belt. However, it is disadvantageous in that it is fed by a feeding conveyor, which is generally fixed to the homogenization silo, which easily results in a local accumulation of material at the outlet position of the feeding conveyor.

Accordingly, the prior art is in need of improvement.

Disclosure of Invention

The utility model aims to provide a ceramic raw material homogenizing system, which aims to solve the technical problem that materials are easy to be accumulated locally at the outlet position of a feeding conveyor belt in the prior art.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a ceramic raw material homogenizing system which comprises a plurality of feeder assemblies, a feeding conveyor belt, a crusher, a movable cloth conveyor belt and a homogenizing bin, wherein the feeder assemblies are communicated with the crusher through the feeding conveyor belt, the movable cloth conveyor belt is communicated with the crusher, and is movably arranged on the homogenizing bin, and the movable cloth conveyor belt can be enabled to distribute materials back and forth on the homogenizing bin by means of the movable arrangement of the movable cloth conveyor belt.

In one embodiment, the moving cloth conveyor belt comprises:

the cloth support is arranged on the homogenization bin;

the cloth conveying belt is connected with the cloth support in a sliding manner;

the cloth conveying belt is connected with the cloth bracket in a sliding way through the moving part;

the rotary driving source is in transmission connection with the moving part and is used for driving the moving part to slide along the cloth support.

In one embodiment, the rotation driving source includes:

a rotating electric machine;

the first driving gear is in transmission connection with the rotating motor;

the first driven gear is matched and connected with the first driving gear, and the first driven gear is in transmission connection with the moving wheel;

the first transmission chain is wound on the first driving gear and the first driven gear, the rotating motor is used for driving the first driving gear to rotate, the first driving gear drives the first driven gear to rotate through the first transmission chain, and then the moving wheel is driven to rotate, so that the cloth conveying belt is driven to move back and forth in the homogenizing bin.

In one embodiment, the cloth conveyor belt includes:

the bottom of the first bracket is provided with the moving part, and the first bracket is in sliding connection with the cloth bracket through the moving part;

the first motor is arranged on the first bracket;

the first driving roller is arranged on the first bracket and is in transmission connection with the first motor;

the first driven roller is arranged on the first bracket and is matched with the first driving roller;

the first cloth belt is wound on the first driving roller and the first driven roller, the first motor is used for driving the first driving roller to rotate, and the first driving roller drives the first cloth belt to rotate through the first driven roller;

the first baffle plate is arranged on the first bracket and is positioned on two sides of the first cloth belt.

In one embodiment, a transfer feeding belt is arranged between the crusher and the movable cloth conveying belt, and two ends of the transfer feeding belt are connected with the movable cloth conveying belt side by side.

In one embodiment, the transfer feed belt comprises:

the first transfer belt is communicated with the crusher;

the second transfer belt, the second transfer belt with first transfer belt intercommunication, just the second transfer belt is transversely setting up on the homogenization storehouse, there are two at the both ends of second transfer belt remove the cloth conveyer belt side by side, remove the cloth conveyer belt and be vertical setting up on the homogenization storehouse.

In one embodiment, the feeder assembly includes:

a feeder body;

the weighing driving belt is positioned below the feeder body and is communicated with the feeder body;

and the total transmission belt is positioned below the weighing transmission belt and is communicated with the weighing transmission belt and the feeding transmission belt.

In one embodiment, the total drive belt comprises:

the first sub-transmission belt is positioned below the weighing transmission belt of the feeder assembly at the left side and is communicated with the weighing transmission belt;

the second sub-transmission belt is positioned below the weighing transmission belt of the feeder assembly on the right side and is communicated with the weighing transmission belt;

and one end of the summarizing transmission belt is respectively communicated with the first sub transmission belt and the second sub transmission belt, and the other end of the summarizing transmission belt is communicated with the feeding transmission belt.

In one embodiment, the feeder body comprises a plurality of chain plate feeders, a plurality of screw feeders and a plurality of belt feeders, wherein the chain plate feeders, the screw feeders and the belt feeders are all located above the weighing conveyer belt.

The ceramic raw material homogenizing system provided by the utility model has the beneficial effects that:

the utility model discloses a ceramic raw material homogenizing system which comprises a plurality of feeder assemblies, a feeding conveyor belt, a crusher, a movable cloth conveyor belt and a homogenizing bin, wherein the feeder assemblies are communicated with the crusher through the feeding conveyor belt, the movable cloth conveyor belt is communicated with the crusher, and is movably arranged on the homogenizing bin, and the movable cloth conveyor belt can be enabled to distribute materials back and forth on the homogenizing bin by means of the movable arrangement of the movable cloth conveyor belt. According to the utility model, the material is distributed back and forth on the homogenizing bin by moving the material distribution conveyor belt, so that the material homogenizing and mixing effect is achieved by layer-by-layer bedding during material discharging, and the problem that the materials are locally stacked at the outlet position of the material feeding conveyor belt can be solved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments or the description of the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a ceramic raw material homogenizing system according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram of a ceramic raw material homogenizing system according to an embodiment of the present utility model in a top view;

FIG. 3 is a schematic diagram of a side view of a ceramic raw material homogenizing system according to an embodiment of the present utility model;

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

fig. 5 is a schematic structural diagram of a specific embodiment of a moving fabric conveyer belt according to an embodiment of the present utility model;

fig. 6 is a schematic structural diagram of a moving fabric conveyer belt according to an embodiment of the present utility model;

fig. 7 is a schematic diagram of an assembly structure of a first baffle according to an embodiment of the present utility model;

fig. 8 is a schematic structural view of a screw feeder and a belt feeder according to an embodiment of the present utility model.

Wherein, each reference sign in the figure:

100. a feeder assembly; 200. a feeding conveyor belt; 300. a crusher; 400. moving a cloth conveying belt; 500. a homogenizing bin; 600. a transfer feeding belt; 110. a feeder body; 120. a weighing driving belt; 130. a total drive belt; 111. a chain plate feeder; 112. a screw feeder; 113. a belt feeder; 131. a first sub-belt; 132. a second belt; 133. summarizing the transmission belt; 410. a cloth bracket; 420. a cloth conveyer belt; 430. a moving member; 431. a moving wheel; 440. a rotation driving source; 421. a first bracket; 422. a first motor; 423. a first driving roller; 424. a roller; 426. a first cloth belt; 427. a first baffle; 441. a rotating electric machine; 442. a first drive gear; 443. a first driven gear; 444. a first drive chain; 610. a first transfer belt; 620. and a second transfer belt.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The directions or positions indicated by the terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are directions or positions based on the drawings, and are merely for convenience of description and are not to be construed as limiting the present technical solution. The terms "first," "second," and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "a plurality of" is two or more, unless specifically defined otherwise.

The embodiment provides a ceramic raw material homogenizing system, which comprises a plurality of feeder assemblies 100, a feeding conveyor belt 200, a crusher 300, a movable cloth conveyor belt 400 and a homogenizing bin 500, wherein the feeder assemblies 100 are communicated with the crusher 300 through the feeding conveyor belt 200, the movable cloth conveyor belt 400 is communicated with the crusher 300, the movable cloth conveyor belt 400 is movably arranged on the homogenizing bin 500, and the movable cloth conveyor belt 400 can be used for distributing materials back and forth on the homogenizing bin 500 by means of the movable arrangement of the movable cloth conveyor belt 400.

In this embodiment, the material is distributed back and forth on the homogenization bin 500 by moving the distribution conveyor 400, so that the material is layered and padded layer by layer during material discharging to achieve the effect of homogenizing and mixing, and the problem that the material is locally stacked at the outlet position of the feeding conveyor 200 can be solved. For example, ceramic tiles are usually prepared from more than ten raw materials, and after various raw materials are purchased from the outside, part of the raw materials are subjected to homogenization pretreatment and then stored in corresponding indoor bins for later use. After the raw material workshops receive the production recipe, a loader driver sequentially takes and weighs each raw material into the feeder assembly 100 according to the recipe so as to meet the recipe requirements.

For the classification of raw materials of the blank, the raw materials can be fed according to the serial numbers of each raw material and the serial numbers of the feeder assembly 100, and then are conveyed to the movable material distribution conveying belt 400 through the feeding conveying belt 200 and the crusher 300, and then are subjected to homogenization and throwing through the movable material distribution conveying belt 400, for example, the material homogenization mixing effect is achieved through the layer-by-layer bedding of the movable material distribution conveying belt 400, the formula stability of the raw materials of the blank is improved, the raw materials of the blank are put into corresponding bins for storage, the raw materials are shoveled into the feeder for conveying to the rapid continuous balls for coarse grinding during the material preparation, and are pumped into a high-level pond for pulp homogenization, and then are pumped into three sections of continuous balls for fine grinding for improving the stability of the fineness of the pulp, stabilizing the firing size change, improving the stability of the temperature of the blank and improving the fluctuation of the kiln during the firing.

Therefore, in this embodiment, the material is distributed back and forth on the homogenization bin 500 by moving the material distribution conveyor 400, so that the material is layered and laid up to achieve the material homogenization mixing effect during material discharging, and the problem that the material is locally stacked at the outlet of the material feeding conveyor 200 can be solved, so that the ceramic raw material process formula is more stable.

For example, referring to fig. 2, 3 and 4, taking 19 raw materials as an example, 19 feeder assemblies 100 can be configured in this embodiment, and each feeder assembly 100 is configured with a single raw material, so as to increase the batching speed of the forklift and reduce the time for the forklift to run back and forth.

The 19 feeding machine assemblies 100 can automatically dose materials, and the dosing speed is adjusted according to the proportion of the formula, so that the accuracy of the materials can be improved, and the labor intensity of staff in frequent operation can be reduced.

The movable cloth conveyer belt 400 is used for running back and forth, so that the raw materials (mud sand materials) are layered and padded layer by layer to achieve a homogenizing and mixing effect when being discharged. For example, the raw materials (mud sand) can be made into a batch of 1000 tons, so that the formula is more stable.

And then, the assembled raw materials (mud sand) directly enter two sections of rapid continuous balls to be connected together by a conveying belt, so that the effects of high efficiency and high speed are achieved, the fineness of the discharged mud is consistent, the production temperature change is ensured to be reduced, and the stable production of the product is ensured.

Referring to fig. 5, the moving cloth conveyer 400 includes: the cloth support 410, the cloth conveyer 420, the moving part 430 that a plurality of removal wheels 431 are constituteed and rotatory drive source 440, cloth support 410 sets up on homogenization storehouse 500, and cloth conveyer 420 and cloth support 410 sliding connection, moving part 430 set up on cloth conveyer 420, and cloth conveyer 420 passes through moving part 430 and cloth support 410 sliding connection, and rotatory drive source 440 is connected with moving part 430 transmission, and rotatory drive source 440 is used for driving moving part 430 and slides along cloth support 410.

In this embodiment, the rotary driving source 440 drives the moving part 430 to slide back and forth on the cloth holder 410, so that the cloth conveyer 420 moves back and forth on the cloth holder 410, so as to realize that the cloth conveyer 400 moves to and fro for cloth on the homogenization chamber 500, wherein the cloth holder 410 can be erected on the homogenization chamber 500, and a moving track matched with the moving wheel 431 is arranged on the cloth holder 410, so that the cloth conveyer 420 can move on the cloth holder 410 in an oriented manner.

Referring to fig. 5, the rotation driving source 440 includes: the rotary motor 441, the first driving gear 442, the first driven gear 443 and the first drive chain 444, the first driving gear 442 is in transmission connection with the rotary motor 441, the first driven gear 443 is in matched connection with the first driving gear 442, the first driven gear 443 is in transmission connection with the movable wheel 431, the first drive chain 444 is wound on the first driving gear 442 and the first driven gear 443, the rotary motor 441 is used for driving the first driving gear 442 to rotate, the first driving gear 442 drives the first driven gear 443 to rotate through the first drive chain 444, and then the movable wheel 431 is driven to rotate, so that the cloth conveying belt 420 is driven to move back and forth in the homogenization bin 500.

In this embodiment, the rotating motor 441 may drive the first driving gear 442 to rotate, and drive the first driven gear 443 to rotate through the first transmission chain 444, so as to drive the moving wheel 431 to rotate, so as to realize moving the cloth conveyer belt 400 to and fro for distributing the cloth on the homogenization bin 500, where the rotating motor 441 may be disposed on the first bracket 421 of the cloth conveyer belt 420, and when the cloth conveyer belt 420 moves, the rotating motor 441 may move along with the cloth conveyer belt 420.

Referring to fig. 5 and 6, the cloth conveyer belt 420 includes: the first support 421, the first motor 422, the first driving roller 423, the first driven roller, the first cloth belt 426 and the first baffle 427 (shown in fig. 7), the moving part 430 is arranged at the bottom of the first support 421, the first support 421 is slidably connected with the cloth support 410 through the moving part 430, the first motor 422 is arranged on the first support 421, the first driving roller 423 is in transmission connection with the first motor 422, the first driven roller is arranged on the first support 421, the first driven roller is matched with the first driving roller 423, the first cloth belt 426 is wound on the first driving roller 423 and the first driven roller, the first motor 422 is used for driving the first driving roller 423 to rotate, the first driving roller 423 drives the first cloth belt 426 to rotate through the first driven roller, the first baffle 427 is arranged on the first support 421, and the first baffle 427 is located on two sides of the first cloth belt 426.

In this embodiment, the first motor 422 may drive the first driving roller 423 to rotate, the first driving roller 423 drives the first driven roller to rotate through the first cloth belt 426, so as to implement that the first cloth belt 426 rotates around the first driving roller 423 and the first driven roller, when the raw material falls on the first cloth belt 426, the raw material may be layered on the homogenization bin 500 through the first cloth belt 426, a plurality of rollers 424 may be disposed between the first driving roller 423 and the first driven roller at intervals, so as to support the first cloth belt 426, the first baffle 427 is located at two sides of the first cloth belt 426, and the first baffle 427 may reduce the raw material falling on two sides of the first cloth belt 426.

Referring to fig. 1 and 2, a transfer feeding belt 600 is disposed between the crusher 300 and the movable cloth conveyer 400, and two side-by-side movable cloth conveyer 400 are connected to two ends of the transfer feeding belt 600.

As described above, 1000 tons of raw materials (silt materials) can be formed into a batch, so that the homogenizing bin 500 occupies a larger space, and the embodiment adopts two parallel movable material distribution conveyor belts 400 for distributing the raw materials back and forth in the homogenizing bin 500 with a larger space, so that the raw materials (silt materials) are layered and laid up to achieve the homogenizing and mixing effect during discharging. For example, the middle transfer belt 600 may be rotated forward such that the middle transfer belt 600 feeds the left moving cloth conveyor 400, then the left moving cloth conveyor 400 again feeds back and forth on the homogenizing bin 500, and then the middle transfer belt 600 may be rotated backward such that the middle transfer belt 600 feeds the right moving cloth conveyor 400, and then the right moving cloth conveyor 400 again feeds back and forth on the homogenizing bin 500.

Referring to fig. 1, the transfer feeding belt 600 includes: the first transfer belt 610 and the second transfer belt 620, the first transfer belt 610 is communicated with the crusher 300, the second transfer belt 620 is communicated with the first transfer belt 610, the second transfer belt 620 is transversely arranged on the homogenizing bin 500, two side-by-side movable cloth conveying belts 400 are arranged at two ends of the second transfer belt, and the movable cloth conveying belts 400 are longitudinally arranged on the homogenizing bin 500.

In this embodiment, a first transfer belt 610 is used to connect the crusher 300 and a second transfer belt 620, wherein the second transfer belt is transversely disposed on the homogenization silo 500, and two side-by-side moving cloth conveyors 400 are disposed at two ends of the second transfer belt 620. For example, the second transfer belt 620 may be rotated forward such that the second transfer belt 620 carries out feeding to the left side of the moving cloth conveyor belt 400, then the left side of the moving cloth conveyor belt 400 carries out feeding back and forth on the homogenizing bin 500, then the second transfer belt 620 may be rotated reversely such that the second transfer belt 620 carries out feeding to the right side of the moving cloth conveyor belt 400, and then the right side of the moving cloth conveyor belt 400 carries out feeding back and forth on the homogenizing bin 500.

Referring to fig. 1 and 4, the feeder assembly 100 includes: the feeding machine comprises a feeding machine body 110, a weighing driving belt 120 and a total driving belt 130, wherein the weighing driving belt 120 is positioned below the feeding machine body 110, the weighing driving belt 120 is communicated with the feeding machine body 110, the total driving belt 130 is positioned below the weighing driving belt 120, and the total driving belt 130 is communicated with the weighing driving belt 120 and the feeding driving belt 200.

In this embodiment, the weighing conveyer belt 120 is located below the feeder body 110, the total conveyer belt 130 is located below the weighing conveyer belt 120, the weighing conveyer belt 120 is used for metering the discharge of the feeder body 110, the total conveyer belt 130 is used for transferring the raw materials on the weighing conveyer belt 120 to the feeding conveyer belt 200 so as to achieve continuous and uninterrupted material proportioning requirements, each feeder body 110 can be provided with an audible and visual alarm, and when the raw materials in the feeder body 110 are lower than a set weight, the audible and visual alarm can give out an alarm to remind a forklift master to timely supplement the feeder body 110.

Referring to fig. 1, the total transmission belt 130 includes: the first sub-conveyor belt 131, the second sub-conveyor belt 132 and the summarizing conveyor belt 133, the first sub-conveyor belt 131 is located below the weighing conveyor belt 120 of the left feeder assembly 100, the first sub-conveyor belt 131 is communicated with the weighing conveyor belt 120, the second sub-conveyor belt 132 is located below the weighing conveyor belt 120 of the right feeder assembly 100, the second sub-conveyor belt 132 is communicated with the weighing conveyor belt 120, one end of the summarizing conveyor belt 133 is respectively communicated with the first sub-conveyor belt 131 and the second sub-conveyor belt 132, the other end of the summarizing conveyor belt 133 is communicated with the feeding conveyor belt 200, the feeding conveyor belt 200 is communicated with the crusher 300, and the crusher 300 has the effect of scattering and crushing raw materials.

As described above, taking 19 raw materials as an example, each raw material corresponds to one weighing conveyer 120, and the total conveyer 130 is used for transferring the raw materials on the weighing conveyer 120 to the feeding conveyer 200, wherein the total conveyer 130 includes: the first and second sub-belts 131 and 132 and the summary belt 133 can improve the dispensing efficiency and the homogenizing mixing effect. Of course, the raw materials of the blank side are not limited to the above 19 kinds, the number of types of raw materials in the billet may be other, and is not limited herein.

Referring to fig. 2, the plurality of feeder bodies 110 include a plurality of link plate feeders 111, a plurality of screw feeders 112, and a plurality of belt feeders 113, and the link plate feeders 111, the screw feeders 112, and the belt feeders 113 are all located above the weighing conveyer 120.

For example, the plurality of feeder assemblies 100 may include 12 belt feeders 113, 5 chain plate feeders 111 and 2 screw feeders 112, and weighing driving belts 120 are correspondingly disposed under the 12 belt feeders 113, 5 chain plate feeders 111 and 2 screw feeders 112, wherein, referring to fig. 8, the belt feeders 113, the chain plate feeders 111 and the screw feeders 112 may be disposed at a mixing interval, and the 12 belt feeders 113, 5 chain plate feeders 111 and 2 screw feeders 112 may adjust the mixing speed according to the ratio of the formulation, thereby improving the accuracy of the mixing and the homogenization mixing effect, and reducing the frequent labor intensity of staff operation. The belt feeder 113, the chain plate feeder 111, the screw feeder 112, the weighing conveyer 120 and the crusher 300 may be all of the prior art, so specific structures of the belt feeder 113, the chain plate feeder 111, the screw feeder 112, the weighing conveyer 120 and the crusher 300 are not described herein.

In summary, the utility model discloses a ceramic raw material homogenizing system, which comprises a plurality of feeder assemblies, a feeding conveyor belt, a crusher, a movable cloth conveyor belt and a homogenizing bin, wherein the feeder assemblies are communicated with the crusher through the feeding conveyor belt, the movable cloth conveyor belt is communicated with the crusher and is movably arranged on the homogenizing bin, and the movable cloth conveyor belt can be used for distributing materials back and forth on the homogenizing bin by virtue of the movable arrangement of the movable cloth conveyor belt. According to the utility model, the material is distributed back and forth on the homogenizing bin by moving the material distribution conveyor belt, so that the material homogenizing and mixing effect is achieved by layer-by-layer bedding during material discharging, the problem that the materials are locally piled up at the outlet position of the material feeding conveyor belt can be solved, and the ceramic raw material process formula is more stable.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (9)

1. The utility model provides a ceramic raw materials homogenization system, its characterized in that includes a plurality of feeding machine subassemblies, pay-off conveyer belt, breaker, removal cloth conveyer belt and homogenization storehouse, the feeding machine subassembly warp the pay-off conveyer belt with the breaker intercommunication, remove the cloth conveyer belt with the breaker is linked together, just remove the cloth conveyer belt movably set up in on the homogenization storehouse, with the help of the movable setting of removal cloth conveyer belt can make remove the cloth conveyer belt and make a round trip to distribute on the homogenization storehouse.

2. The ceramic raw material homogenization system of claim 1, wherein the moving cloth conveyor belt includes:

the cloth support is arranged on the homogenization bin;

the cloth conveying belt is connected with the cloth support in a sliding manner;

the cloth conveying belt is connected with the cloth bracket in a sliding way through the moving part;

the rotary driving source is in transmission connection with the moving part and is used for driving the moving part to slide along the cloth support.

3. The ceramic raw material homogenization system of claim 2, wherein the rotary drive source includes:

a rotating electric machine;

the first driving gear is in transmission connection with the rotating motor;

the first driven gear is matched and connected with the first driving gear, and the first driven gear is in transmission connection with the moving wheel;

the first transmission chain is wound on the first driving gear and the first driven gear, the rotating motor is used for driving the first driving gear to rotate, the first driving gear drives the first driven gear to rotate through the first transmission chain, and then the moving wheel is driven to rotate, so that the cloth conveying belt is driven to move back and forth in the homogenizing bin.

4. The ceramic raw material homogenization system of claim 2, wherein the cloth conveyor belt includes:

the bottom of the first bracket is provided with the moving part, and the first bracket is in sliding connection with the cloth bracket through the moving part;

the first motor is arranged on the first bracket;

the first driving roller is arranged on the first bracket and is in transmission connection with the first motor;

the first driven roller is arranged on the first bracket and is matched with the first driving roller;

the first cloth belt winds around the first driving roller and the first driven roller, the first motor is used for driving the first driving roller to rotate, and the first driving roller drives the first cloth belt to rotate through the first driven roller.

5. The ceramic raw material homogenizing system of claim 1, wherein a transfer feed belt is arranged between the crusher and the moving cloth conveyor belt, and two ends of the transfer feed belt are connected with the two moving cloth conveyor belts side by side.

6. The ceramic raw material homogenization system of claim 5, wherein the transfer feed belt includes:

the first transfer belt is communicated with the crusher;

the second transfer belt, the second transfer belt with first transfer belt intercommunication, just the second transfer belt is transversely setting up on the homogenization storehouse, there are two at the both ends of second transfer belt remove the cloth conveyer belt side by side, remove the cloth conveyer belt and be vertical setting up on the homogenization storehouse.

7. The ceramic raw material homogenization system of claim 1, wherein the feeder assembly includes:

a feeder body;

the weighing driving belt is positioned below the feeder body and is communicated with the feeder body;

and the total transmission belt is positioned below the weighing transmission belt and is communicated with the weighing transmission belt and the feeding transmission belt.

8. The ceramic raw material homogenization system of claim 7, wherein the aggregate drive belt includes:

the first sub-transmission belt is positioned below the weighing transmission belt of the feeder assembly at the left side and is communicated with the weighing transmission belt;

the second sub-transmission belt is positioned below the weighing transmission belt of the feeder assembly on the right side and is communicated with the weighing transmission belt;

and one end of the summarizing transmission belt is respectively communicated with the first sub transmission belt and the second sub transmission belt, and the other end of the summarizing transmission belt is communicated with the feeding transmission belt.

9. The ceramic raw material homogenizing system of claim 7, wherein the feeder body comprises a plurality of flight feeders, a plurality of screw feeders, and a plurality of belt feeders, each of the flight feeders, the screw feeders, and the belt feeders being located above the weighing conveyor.