CN220200339U - Automatic feeding system of ceramic press - Google Patents

Abstract

The application discloses ceramic press autoloading system, wherein, including conveyer belt subassembly and hopper subassembly, conveyer belt subassembly includes: first feed conveyor belt, second feed conveyor belt, third feed conveyor belt, fourth feed conveyor belt, the hopper assembly includes: a first press hopper, a second press hopper, a third press hopper, a fourth press hopper, and a fifth press hopper. According to the automatic feeding device, the condition that 5 press hoppers can feed circularly in turn can be met, feeding is carried out on a plurality of press hoppers on one production line, the working efficiency of equipment is improved, the cost of the equipment is reduced, the conveyer belt is monitored by using the induction switch, material blocking and material leakage in a fault section of the conveyer belt are prevented, and the labor intensity of staff for cleaning powder is reduced; the press hopper is monitored by the material level sensor, so that the purpose of automatic feeding is achieved, the labor intensity of staff is reduced, and the working efficiency is improved.

Description

Automatic feeding system of ceramic press

Technical Field

The application relates to the technical field of ceramic production, in particular to an automatic feeding system of a ceramic press.

Background

In the ceramic tile production process, the transportation and storage of raw materials are very important procedures, and the raw material powder feeding and the production line press hopper need to be synchronously carried out, so that the conventional requirement is that the procedures need to be continuously produced.

The feeding and distributing process is one of important processes for producing ceramic tiles, and the process is related to the stability of ceramic tile production and the efficiency of ceramic tile production.

For example, application number 202010182471.4 discloses an automatic ceramic powder bin changing system with on-line monitoring and an automatic feeding method thereof, the automatic ceramic powder bin changing system comprises a press hopper, a main conveying belt and a plurality of powder conveying groups, wherein the discharge end of each powder conveying group is connected with the feeding end of the press hopper through the main conveying belt, one end of the main conveying belt, which is close to the press hopper, is communicated with a material distributing conveying belt, one end, which is far away from the main conveying belt, of the material distributing conveying belt is provided with two material distributing openings, and one material distributing opening is connected with the feeding end of one press hopper. The main conveying belt can meet the requirement of feeding powder from 2 press hoppers, and if the press hoppers are added, the powder feeding production line needs to be added, and the line building input cost needs to be increased.

Accordingly, the prior art is in need of improvement.

Disclosure of Invention

The utility model aims at providing a ceramic press autoloading system, aims at solving the technical problem that the press hopper that single powder feeding production line supplied is few among the prior art.

In order to achieve the above purpose, the technical scheme adopted in the application is as follows:

the application provides a ceramic press autoloading system, wherein, include: conveyor belt assembly and hopper assembly, conveyor belt assembly includes: first feed conveyor belt, second feed conveyor belt, third feed conveyor belt, fourth feed conveyor belt, the hopper assembly includes: a first press hopper, a second press hopper, a third press hopper, a fourth press hopper, and a fifth press hopper;

one end of the first material distributing and conveying belt is communicated with the second material distributing and conveying belt, and the other end of the first material distributing and conveying belt is communicated with the third material distributing and conveying belt;

one end of the second material dividing conveying belt is communicated with the middle position of the fourth material dividing conveying belt, and the other end of the second material dividing conveying belt is communicated with the first press hopper;

one end of the fourth material distributing and conveying belt is communicated with the second press hopper, and the other end of the fourth material distributing and conveying belt is communicated with the third press hopper;

one end of the third material distributing and conveying belt is communicated with the fourth press hopper, and the other end of the third material distributing and conveying belt is communicated with the fifth press hopper.

In one embodiment, the first split conveyor belt, the second split conveyor belt and the first press hopper are connected to form a first conveyor line for conveying powder to the first press hopper.

In one embodiment, the first, second, fourth and second separating conveyor belts are connected to form a second conveyor line for conveying powder to the second press hopper.

In one embodiment, the first, second, fourth and third press hoppers are connected to form a third conveying line for conveying powder to the third press hoppers.

In one embodiment, the first, third and fourth press hoppers are connected to form a fourth conveying line for conveying powder to the fourth press hopper.

In one embodiment, the first, third and fifth press hoppers are connected to form a fifth transfer line for transferring powder to the fifth press hopper.

In one embodiment, the method further comprises: the switch assembly, the switch assembly connect in the conveyer belt subassembly, the switch assembly includes: a first proximity switch, a second proximity switch, a third proximity switch, and a fourth proximity switch;

the first proximity switch is connected with the first material distribution conveying belt;

the second proximity switch is connected with the second distributing and conveying belt;

the third proximity switch is connected with the third material distribution conveying belt;

the fourth proximity switch is connected with the fourth material distributing and conveying belt.

In one embodiment, the switch assembly includes: the automatic transmission device comprises an induction switch body and a fluted disc induction part matched with the induction switch body, wherein the induction switch body is positioned on a conveying belt line frame of a conveying belt assembly, and the fluted disc induction part is positioned on a driving roller of the conveying belt assembly.

In one embodiment, the method further comprises: the material level sensor, the material level sensor is located in the hopper subassembly, the material level sensor is used for detecting the storage condition of hopper subassembly, wherein, the material level sensor includes: high level sensor and low level sensor.

In one embodiment, the method further comprises:

a bin assembly;

the conveyor belt assembly further comprises: the first conveyer belt and second conveyer belt, first conveyer belt with feed bin subassembly intercommunication, first conveyer belt warp the second conveyer belt with first branch material conveyer belt intercommunication is used for the realization will feed bin subassembly to first branch material conveyer belt carries.

The application provides a ceramic press autoloading system's beneficial effect lies in at least:

the application discloses ceramic press autoloading system, wherein, including conveyer belt subassembly and hopper subassembly, conveyer belt subassembly includes: first feed conveyor belt, second feed conveyor belt, third feed conveyor belt, fourth feed conveyor belt, the hopper assembly includes: a first press hopper, a second press hopper, a third press hopper, a fourth press hopper, and a fifth press hopper; one end of the first material distributing and conveying belt is communicated with the second material distributing and conveying belt, and the other end of the first material distributing and conveying belt is communicated with the third material distributing and conveying belt; one end of the second material dividing conveying belt is communicated with the middle position of the fourth material dividing conveying belt, and the other end of the second material dividing conveying belt is communicated with the first press hopper; one end of the fourth material distributing and conveying belt is communicated with the second press hopper, and the other end of the fourth material distributing and conveying belt is communicated with the third press hopper; one end of the third material distributing and conveying belt is communicated with the fourth press hopper, and the other end of the third material distributing and conveying belt is communicated with the fifth press hopper. According to the automatic feeding device, the condition that 5 press hoppers can feed circularly in turn can be met, feeding is carried out on a plurality of press hoppers on one production line, the working efficiency of equipment is improved, the cost of the equipment is reduced, the conveyer belt is monitored by using the induction switch, material blocking and material leakage in a fault section of the conveyer belt are prevented, and the labor intensity of staff for cleaning powder is reduced; the press hopper is monitored by the material level sensor, so that the purpose of automatic feeding is achieved, the labor intensity of staff is reduced, and the working efficiency is improved.

Drawings

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

Fig. 1 is a schematic structural diagram of an automatic feeding system of a ceramic press according to an embodiment of the present application;

FIG. 2 is a block diagram of a particular embodiment of a switch assembly provided in an embodiment of the present application;

fig. 3 is a block diagram of a specific embodiment of a level sensor according to an embodiment of the present application.

Wherein, each reference sign in the figure:

100. a conveyor belt assembly; 200. a hopper assembly; 300. a switch assembly; 400. a level sensor; 500. a bin assembly; 700. a PLC; 101. a conveyor line frame; 102. a driving motor; 103. a driving roller; 104. a driven roller; 105. a belt body; 110. a first distributing and conveying belt; 120. a second split conveyor belt; 130. a third material-separating conveying belt; 140. a fourth distributing and conveying belt; 150. a first conveyor belt; 160. a second conveyor belt; 210. a first press hopper; 220. a second press hopper; 230. a third press hopper; 240. a fourth press hopper; 250. a fifth press hopper; 310. an inductive switch body; 320. a fluted disc sensing part; 410. a high-level sensor; 420. a low level sensor; 411. a first high sensor; 421. a first low sensor; 412. a second high sensor; 422. a second low sensor; 413. a third high sensor; 423. a third low sensor; 414. a fourth high sensor; 424. a fourth low sensor; 415. a fifth high sensor; 425. a fifth low sensor; 710. a first delivery line; 720. a second delivery line; 730. a third delivery line; 740. a fourth delivery line; 750. and a fifth conveying pipeline.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved by the present application more clear, the present application 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 present application.

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.

Referring to fig. 1, the embodiment provides an automatic feeding system of a ceramic press, which includes: conveyor belt assembly 100 and hopper assembly 200, conveyor belt assembly 100 includes: first, second, third, and fourth separating conveyor belts 110, 120, 130, 140, hopper assembly 200 includes: a first press hopper 210, a second press hopper 220, a third press hopper 230, a fourth press hopper 240, and a fifth press hopper 250;

one end of the first material separating and conveying belt 110 is communicated with the second material separating and conveying belt 120, and the other end is communicated with the third material separating and conveying belt 130;

one end of the second material dividing and conveying belt 120 is communicated with the middle position of the fourth material dividing and conveying belt 140, and the other end is communicated with the first press hopper 210;

one end of the fourth material-dividing conveying belt 140 is communicated with the second press hopper 220, and the other end is communicated with the third press hopper 230;

the third split conveyor belt 130 communicates at one end with the fourth press hopper 240 and at the other end with the fifth press hopper 250.

In this embodiment, the first material-dividing conveying belt 110 is connected with the second material-dividing conveying belt 120 and the third material-dividing conveying belt 130 respectively, the second material-dividing conveying belt 120 is connected with the first press hopper 210 and the fourth material-dividing conveying belt 140 respectively, the fourth material-dividing conveying belt 140 is communicated with the second press hopper 220 and the third press hopper 230 respectively, the third material-dividing conveying belt 130 is communicated with the fourth press hopper 240 and the fifth press hopper 250 respectively, so as to realize feeding to 5 press hoppers on one production line, solve the problem of less press hoppers supplied by a single powder-feeding production line, realize feeding to a plurality of press hoppers on one production line, improve the working efficiency of equipment and reduce the cost of equipment.

Specifically, referring to fig. 1, the first distribution conveyor belt 110, the second distribution conveyor belt 120, and the first press hopper 210 are connected to form a first conveying pipeline 710, and the first conveying pipeline 710 is used for conveying powder to the first press hopper 210.

In the present embodiment, the first distribution conveyor belt 110 rotates forward, the first distribution conveyor belt 110 conveys the powder to the second distribution conveyor belt 120, the second distribution conveyor belt 120 rotates reversely, and the second distribution conveyor belt 120 conveys the powder to the first press hopper 210.

The first split conveyor belt 110, the second split conveyor belt 120, the fourth split conveyor belt 140, and the second press hopper 220 are connected to form a second conveyor line 720, and the second conveyor line 720 is used to convey powder to the second press hopper 220.

In the present embodiment, the first distribution conveyor 110 rotates forward, the first distribution conveyor 110 conveys the powder to the second distribution conveyor 120, the second distribution conveyor 120 rotates forward, the second distribution conveyor 120 conveys the powder to the fourth distribution conveyor 140, the fourth distribution conveyor 140 rotates forward, and the fourth distribution conveyor 140 conveys the powder to the second press hopper 220.

The first, second, fourth and third discharge conveyor belts 110, 120, 140 and 230 are connected to form a third transfer line 730, the third transfer line 730 being for transferring powder to the third press hopper 230.

In the present embodiment, the first distribution conveyor 110 rotates forward, the first distribution conveyor 110 conveys the powder to the second distribution conveyor 120, the second distribution conveyor 120 rotates forward, the second distribution conveyor 120 conveys the powder to the fourth distribution conveyor 140, the fourth distribution conveyor 140 rotates backward, and the fourth distribution conveyor 140 conveys the powder to the third press hopper 230.

The first split conveyor belt 110, the third split conveyor belt 130, and the fourth press hopper 240 are connected to form a fourth conveyor line 740, and the fourth conveyor line 740 is used to convey powder to the fourth press hopper 240.

The first distribution conveyor belt 110 is reversed, the first distribution conveyor belt 110 conveys the powder to the third distribution conveyor belt 130, the third distribution conveyor belt 130 is rotated forward, and the third distribution conveyor belt 130 conveys the powder to the fourth press hopper 240.

The first split conveyor belt 110, the third split conveyor belt 130, and the fifth press hopper 250 are connected to form a fifth conveyor line 750, and the fifth conveyor line 750 is used to convey powder to the fifth press hopper 250.

The first distribution conveyor belt 110 is reversed, the first distribution conveyor belt 110 conveys the powder to the third distribution conveyor belt 130, the third distribution conveyor belt 130 is reversed, and the third distribution conveyor belt 130 conveys the powder to the fifth press hopper 250.

In this embodiment, the first conveying pipeline 710, the second conveying pipeline 720, the third conveying pipeline 730, the fourth conveying pipeline 740 and the fifth conveying pipeline 750 are formed by the first distributing conveying belt 110, the second distributing conveying belt 120, the third distributing conveying belt 130, the fourth distributing conveying belt 140, the first press hopper 210, the second press hopper 220, the third press hopper 230, the fourth press hopper 240 and the fifth press hopper 250, so as to feed the first press hopper 210, the second press hopper 220, the third press hopper 230, the fourth press hopper 240 and the fifth press hopper 250, that is, to realize feeding to 5 press hoppers on one production line, improve the working efficiency of equipment and reduce the equipment cost.

Specifically, referring to fig. 1 and 2, the automatic feeding system of the ceramic press further includes: switch assembly 300, level sensor 400 and feed bin assembly 500, switch assembly 300 is connected to conveyor belt assembly 100, switch assembly 300 includes: a first proximity switch, a second proximity switch, a third proximity switch, and a fourth proximity switch; the first proximity switch is connected to the first material distribution conveyor belt 110; the second proximity switch is connected to the second split conveying belt 120; the third proximity switch is connected to the third material-dividing conveying belt 130; the fourth proximity switch is connected to a fourth dispensing conveyor belt 140.

The switch assembly 300 includes: the inductive switch body 310 and the fluted disc sensing part 320 matched with the inductive switch body 310, the inductive switch body 310 is positioned on the conveyor belt frame 101 of the conveyor belt assembly 100, and the fluted disc sensing part 320 is positioned on the driving roller 103 of the conveyor belt assembly 100.

A level sensor 400 is located within the hopper assembly 200, the level sensor 400 being for detecting a storage condition of the hopper assembly 200, wherein the level sensor 400 comprises: a high sensor 410 and a low sensor 420.

The conveyor belt assembly 100 further includes: the first conveyor belt 150 and the second conveyor belt 160, the first conveyor belt 150 is communicated with the bin assembly 500, and the first conveyor belt 150 is communicated with the first distributing conveyor belt 110 through the second conveyor belt 160 so as to realize conveying of the bin assembly 500 to the first distributing conveyor belt 110.

In this embodiment, the conveyor belt assembly 100 may include a conveyor belt frame 101, a driving motor 102, a driving roller 103, a driven roller 104 and a belt body 105, where the conveyor belt frame 101 is provided with the driving motor 102, the driving roller 103 and the driven roller 104, the driving motor 102 is in driving connection with the driving roller 103, the belt body 105 is wound on the driving roller 103 and the driven roller 104, the driving motor 102 drives the driving roller 103 to rotate so as to drive the belt body 105 to rotate, where the driving roller 103 of each conveyor belt is provided with a fluted disc sensing part 320, the fluted disc sensing part 320 may be a 3-tooth iron fluted disc, the sensing switch body 310 is located on the conveyor belt frame 101 of the conveyor belt assembly 100, the sensing switch body 310 is matched with the fluted disc sensing part 320, when the driving roller 103 rotates a circle, the sensing switch body 310 may output 3 high level signals to the input point of the PLC700, and the PLC700 may determine whether the conveyor belt device is normal through the interval time of the high level signals input by the sensing switch body 310. For example, when the high level signal interval time arrives within the normal range, it can be determined that the conveyor belt device is operating normally; when the time of the high-level signal interval is not overtime, the faults of the conveying belt equipment, such as breakage of a transmission shaft of the conveying belt equipment, chain dropping of a transmission chain disc, abrasion and slipping of an output shaft key of a motor, and the like, can be judged, if the conveying belt equipment is out of order, the PLC700 can be used for controlling the automatic alarm and stopping, so that the blocking and leakage of the fault section of the conveying belt equipment are prevented, and the labor intensity of staff for cleaning powder is reduced. For example, the first separating conveyor 110, the second separating conveyor 120, the third separating conveyor 130, the fourth separating conveyor 140, the first conveyor 150 and the second conveyor 160 are all provided with a switch assembly 300, the operation state of the first separating conveyor 110, the second separating conveyor 120, the third separating conveyor 130 and the fourth separating conveyor 140 is detected by the switch assembly 300, and if an abnormal signal exists, an automatic stop alarm is realized by the PLC 700. For example, a fluted disc sensing part 320 is arranged on the driving roller 103 of the fourth material distribution conveying belt 140, the sensing switch body 310 is positioned on the conveying belt frame 101 of the fourth material distribution conveying belt 140, and when the fourth material distribution conveying belt 140 has faults such as broken transmission shafts, broken transmission chain discs, abrasion and slipping of motor output shaft keys, etc., the machine is immediately stopped in an alarm mode under the control of the PLC700, material blocking and material leakage are prevented from occurring at the fault section of the fourth material distribution conveying belt 140, and labor intensity of staff cleaning powder is reduced.

Referring to fig. 1 and 3, a level sensor 400 is located in the hopper assembly 200, the level sensor 400 is used for detecting a storage condition of the hopper assembly 200, wherein the level sensor 400 includes: if the low level sensor 420 detects that there is insufficient powder in the hopper assembly 200, the low level sensor 420 sends a signal to the PLC700, the PLC700 controls the corresponding conveying line to feed the hopper assembly 200, for example, the first high level sensor 411 and the first low level sensor 421 are provided in the first press hopper 210, the second high level sensor 412 and the second low level sensor 422 are provided in the second press hopper 220, the third high level sensor 413 and the third low level sensor 423 are provided in the third press hopper 230, the fourth high level sensor 414 and the fourth low level sensor 424 are provided in the fourth press hopper 240, the fifth high level sensor 415 and the fifth low level sensor 425 are provided in the fifth press hopper 250, when the first low level sensor 421 detects that there is insufficient powder in the first press hopper 210, the PLC700 controls the first conveying line 710 to feed the first press hopper 210, and when the first high level sensor 413 detects that there is sufficient powder in the first press hopper 210, the PLC700 controls the first conveying line 710 to stop feeding the first press hopper 210.

In the embodiment, the RS485 communication can be performed with a human-computer interface through an industrial computer (PLC), so that the monitoring of the running state of the equipment is realized, and the equipment can be remotely controlled; the abnormal stop is realized by the abnormal detection signal of the operation of the conveyor belt and the blocking signal of the conveyor belt; whether the press hopper lacks material is judged through press hopper material level signal, reaches autoloading purpose, lightens staff intensity of labour, improves work efficiency.

To sum up, the application discloses ceramic press autoloading system, wherein, including conveyer belt subassembly and hopper subassembly, conveyer belt subassembly includes: first feed conveyor belt, second feed conveyor belt, third feed conveyor belt, fourth feed conveyor belt, the hopper assembly includes: a first press hopper, a second press hopper, a third press hopper, a fourth press hopper, and a fifth press hopper; one end of the first material separating and conveying belt is communicated with the second material separating and conveying belt, and the other end of the first material separating and conveying belt is communicated with the third material separating and conveying belt; one end of the second material dividing conveying belt is communicated with the middle position of the fourth material dividing conveying belt, and the other end of the second material dividing conveying belt is communicated with the first press hopper; one end of the fourth material distributing and conveying belt is communicated with the second press hopper, and the other end of the fourth material distributing and conveying belt is communicated with the third press hopper; one end of the third material distributing and conveying belt is communicated with the fourth press hopper, and the other end of the third material distributing and conveying belt is communicated with the fifth press hopper. According to the automatic feeding device, the condition that 5 press hoppers can feed circularly in turn can be met, feeding is carried out on a plurality of press hoppers on one production line, the working efficiency of equipment is improved, the cost of the equipment is reduced, the conveyer belt is monitored by using the induction switch, material blocking and material leakage in a fault section of the conveyer belt are prevented, and the labor intensity of staff for cleaning powder is reduced; the press hopper is monitored by the material level sensor, so that the purpose of automatic feeding is achieved, the labor intensity of staff is reduced, and the working efficiency is improved.

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

Claims (10)

1. An automatic feeding system for a ceramic press, comprising: conveyor belt assembly and hopper assembly, conveyor belt assembly includes: first feed conveyor belt, second feed conveyor belt, third feed conveyor belt, fourth feed conveyor belt, the hopper assembly includes: a first press hopper, a second press hopper, a third press hopper, a fourth press hopper, and a fifth press hopper;

one end of the first material distributing and conveying belt is communicated with the second material distributing and conveying belt, and the other end of the first material distributing and conveying belt is communicated with the third material distributing and conveying belt;

one end of the second material dividing conveying belt is communicated with the middle position of the fourth material dividing conveying belt, and the other end of the second material dividing conveying belt is communicated with the first press hopper;

one end of the fourth material distributing and conveying belt is communicated with the second press hopper, and the other end of the fourth material distributing and conveying belt is communicated with the third press hopper;

one end of the third material distributing and conveying belt is communicated with the fourth press hopper, and the other end of the third material distributing and conveying belt is communicated with the fifth press hopper.

2. The ceramic press autoloading system of claim 1, wherein the first split conveyor belt, the second split conveyor belt, and the first press hopper are connected to form a first conveyor line for conveying powder to the first press hopper.

3. The ceramic press autoloading system of claim 1, wherein the first split conveyor belt, the second split conveyor belt, the fourth split conveyor belt, and the second press hopper are connected to form a second conveyor line for conveying powder to the second press hopper.

4. The ceramic press autoloading system of claim 1, wherein the first split conveyor belt, the second split conveyor belt, the fourth split conveyor belt, and the third press hopper are connected to form a third conveyor line for conveying powder to the third press hopper.

5. The ceramic press autoloading system of claim 1, wherein the first split conveyor belt, the third split conveyor belt, and the fourth press hopper are connected to form a fourth conveyor line for conveying powder to the fourth press hopper.

6. The ceramic press autoloading system of claim 1, wherein the first split conveyor belt, the third split conveyor belt, and the fifth press hopper are connected to form a fifth conveyor line for conveying powder to the fifth press hopper.

7. The ceramic press autoloading system of claim 1, further comprising: the switch assembly, the switch assembly connect in the conveyer belt subassembly, the switch assembly includes: a first proximity switch, a second proximity switch, a third proximity switch, and a fourth proximity switch;

the first proximity switch is connected with the first material distribution conveying belt;

the second proximity switch is connected with the second distributing and conveying belt;

the third proximity switch is connected with the third material distribution conveying belt;

the fourth proximity switch is connected with the fourth material distributing and conveying belt.

8. The ceramic press autoloading system of claim 7, wherein the switch assembly comprises: the automatic transmission device comprises an induction switch body and a fluted disc induction part matched with the induction switch body, wherein the induction switch body is positioned on a conveying belt line frame of a conveying belt assembly, and the fluted disc induction part is positioned on a driving roller of the conveying belt assembly.

9. The ceramic press autoloading system of claim 1, further comprising: the material level sensor, the material level sensor is located in the hopper subassembly, the material level sensor is used for detecting the storage condition of hopper subassembly, wherein, the material level sensor includes: high level sensor and low level sensor.

10. The ceramic press autoloading system of claim 1, further comprising:

a bin assembly;

the conveyor belt assembly further comprises: the first conveyer belt and second conveyer belt, first conveyer belt with feed bin subassembly intercommunication, first conveyer belt warp the second conveyer belt with first branch material conveyer belt intercommunication is used for the realization will feed bin subassembly to first branch material conveyer belt carries.