CN216031576U - Wall material distributing system - Google Patents

Abstract

The utility model discloses a wall material distributing system, in particular to the technical field of wall material distribution, which comprises a first storage hopper, a screw extruder, a discharge hopper and a distributing mold, wherein the first storage hopper is connected with a first conveying pipeline for conveying raw materials, a stirring mechanism for stirring the raw materials is arranged in the first storage hopper, and the first storage hopper is provided with a discharge hole for discharging mixed materials; the screw extruder is connected with a discharge port of the first material storage hopper, is driven by a screw motor and extrudes the mixture through the discharge door; the discharge hopper is fixedly or movably arranged on the supporting platform and is positioned below the discharge door, and the discharge hopper senses the weight of the mixture received by the discharge hopper through a weighing sensor and feeds back a weight signal to the screw motor; the cloth mould is arranged on the conveying platform and is positioned below the discharge hopper. The automatic control effect of extrusion of the mixture between the screw extruder and the discharge hopper is realized, the wall material distribution process is fully automatic, the labor cost is reduced, and the processing generation efficiency of the wall material is improved.

Description

Wall material distributing system

Technical Field

The application relates to the technical field of wall material cloth, in particular to a wall material cloth system.

Background

The wall board can be used in the building or household industry, and the production of the wall board relates to various wall materials (materials of the wall board), such as slurry, steel mesh wires, adhesives and the like, so that the various materials of the wall materials need to be conveyed and distributed in the production process of the wall board.

At present, the automation degree of the production and processing of the wallboard is generally lower, a large amount of manpower needs to be invested, and particularly, the process of walling and distributing of the wallboard is a process. Between the material receiving process and the material storing process, and on the feeding die, manual work is needed, so that the labor cost is very high, and the production efficiency is low.

SUMMERY OF THE UTILITY MODEL

In view of this, the purpose of this application is through providing a walling cloth system, solves the technical problem that the manual operation that needs of present walling cloth process leads to the human cost very high, and production efficiency low grade.

In order to achieve the above technical object, the present application provides a wall material distribution system, including:

the device comprises a first storage hopper, a second storage hopper and a control system, wherein the first storage hopper is connected with a first conveying pipeline for conveying raw materials, a stirring mechanism for stirring the raw materials is arranged in the first storage hopper, and the first storage hopper is provided with a discharge hole for discharging mixed materials;

the screw extruder is connected with the discharge hole of the first material storage hopper, is driven by a screw motor and extrudes a mixture through a discharge door;

the discharging hopper is fixedly or movably arranged on the supporting platform and is positioned below the discharging door, the discharging hopper is connected with a weighing sensor, and the weighing sensor senses the weight of the mixed materials received by the discharging hopper and feeds back weight signals to the screw motor;

the cloth mould is arranged on the conveying table and located below the discharge hopper.

Furthermore, a slide rail is arranged on the surface of the supporting platform, the discharge hopper is mounted on the slide rail and slides in a reciprocating manner along the direction of the slide rail, the discharge hopper is provided with a discharge port, when the weighing sensor senses that the weight of the mixture received by the discharge hopper reaches a set value, a signal is fed back to the screw motor to stop the action of extruding the mixture, and the mixture of the discharge hopper falls into the distribution mold from the discharge port.

Further, after the screw extruder stops extruding the mixture, the discharge hopper slides along the direction of the slide rail and puts the mixture into the distribution mold, and after the discharge hopper finishes feeding, the discharge hopper returns along the original path of the slide rail and scrapes the mixture on the distribution mold.

Furthermore, the discharge hopper is fixedly installed on the supporting platform and provided with a discharge port, the weighing sensor senses that when the weight of the mixture received by the discharge hopper reaches a set value, a signal is fed back to the screw motor to stop extruding the mixture, and the mixture of the discharge hopper falls into the distribution mold from the discharge port.

Further, still include:

the material receiving vehicle is used for receiving raw materials and is provided with a discharge hole;

the second material storage hopper is used for receiving raw materials thrown from a discharge hole of the material receiving vehicle and is provided with a discharge hole;

the second conveying pipeline is provided with a feeding hole and a discharging hole, and the feeding hole of the second conveying pipeline is connected with the discharging hole of the second storage hopper;

and the pumping device is used for pumping raw materials and is connected with the discharge hole of the second material conveying pipeline, and the pumping device is connected with the feed hole of the first material conveying pipeline.

Furthermore, the pumping device is connected with the feed inlet of the first material conveying pipeline through a one-way check valve, and raw materials conveyed by the first material conveying pipeline are discharged to the plurality of first material storage hoppers through the plurality of discharge outlets.

Further, the first material conveying pipeline is connected with one end of the one-way check valve, the main pipeline of the first material conveying pipeline is provided with a water inlet valve and a pneumatic ball valve, the water inlet valve is located between the pneumatic ball valve and a feed inlet of the first material conveying pipeline, the first material conveying pipeline is connected with one end of the first material storage hopper, the branch pipelines of the first material conveying pipeline are provided with a plurality of pneumatic ball valves, and the branch pipelines of the first material conveying pipeline are respectively provided with the pneumatic ball valves.

Furthermore, the second material conveying pipeline is provided with a drain valve and a pneumatic ball valve, and the drain valve is located between the pneumatic ball valve and the feeding hole of the second material conveying pipeline.

Furthermore, a plurality of receiving motors are arranged above the receiving vehicle, the receiving motors drive the receiving vehicle to move to the position above the second material storage hopper, and the receiving vehicle puts received raw materials into the second material storage hopper through a discharge hole.

Furthermore, a plurality of sticks are arranged on the surface of the conveying table, the cloth mold is arranged on the plurality of sticks, and the plurality of sticks are driven by the motor and drive the cloth mold.

According to the technical scheme, the wall material distributing system provided by the application has the advantages that raw materials are conveyed to the first storage hopper through the first conveying pipeline, meanwhile, the first storage hopper is used for stirring and mixing various raw materials, then, the mixed materials are conveyed and extruded to the discharge hopper through the screw extruder, and the weighing sensor is used for carrying out weight sensing and feeding back weight signals in the process that the mixed materials are extruded to the discharge hopper by the screw extruder, so that the effect of automatic control of the extrusion of the mixed materials between the screw extruder and the discharge hopper is realized; when the weighing sensor senses that the mixture received by the discharge hopper reaches a set value, the screw extruder is stopped to extrude the mixture, and the discharge hopper is enabled to throw the mixture into the distribution mould and carry out strickle processing, so that the full-automatic operation of a wall material distribution process is realized, the labor cost is effectively reduced, and the processing generation efficiency of the wall material is improved.

Drawings

Fig. 1 is a front view of a connection relationship among a receiving vehicle, a storage hopper, a conveying pipeline, a pumping device, a screw extruder, a discharge hopper and a distributing mold of a wall material distributing system provided in an embodiment of the present application;

fig. 2 is a side view of the connection relationship between the storage hopper, the screw extruder, the discharge hopper and the material distribution mold of the wall material distribution system according to the embodiment of the present application.

In the figure:

11. a receiving vehicle; 12. a material receiving motor;

21. a first storage hopper; 211. a stirring motor; 22. a second storage hopper;

31. a first delivery conduit; 32. a second delivery pipeline;

41. a pumping device; 42. a one-way check valve;

51. a screw extruder; 511. a screw motor; 512. a discharge door;

61. a discharge hopper; 62. a support platform; 621. a slide rail; 63. a weighing sensor; 64. a weighing bracket;

71. a material distribution mold; 72. a transfer table;

81. a pneumatic ball valve; 82. a water inlet valve; 83. a drain valve;

91a, 91b, 91c, feed inlet;

92a, 92b, 92c, 92d, 92e, a spout.

Detailed Description

The technical solutions of the embodiments of the present application will be described clearly and completely with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all, of the embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without any creative effort belong to the protection scope of the embodiments in the present application.

In the description of the embodiments of the present application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the embodiments of the present application and simplifying the description, but do not indicate or imply that the referred devices or elements must have specific orientations, be configured in specific orientations, and operate, and thus, should not be construed as limiting the embodiments of the present application. 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.

In the description of the embodiments of the present application, it should be noted that the terms "mounted," "connected," and "connected" are used broadly and are defined as, for example, a fixed connection, an exchangeable connection, an integrated connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection through an intermediate medium, and a communication between two elements, unless otherwise explicitly stated or limited. Specific meanings of the above terms in the embodiments of the present application can be understood in specific cases by those of ordinary skill in the art.

The embodiment of the application discloses a wall material distributing system.

First embodiment

Referring to fig. 1-2, the wall material distributing system provided in the embodiment of the present application includes a first material storage hopper 21, a first material conveying pipeline 31, a screw extruder 51, a material discharging hopper 61, and a material distributing mold 71, where the first material storage hopper 21 of the embodiment includes more than two material conveying pipelines 31, the first material conveying pipeline 31 conveys raw materials from above the first material storage hopper 21, the raw materials include aggregate, emulsion, and other components, and therefore the first material conveying pipeline 31 conveys the aggregate, the emulsion, and other components into the first material storage hopper 21. The first storage hopper 21 is provided with a stirring mechanism for stirring the raw material therein, the first storage hopper 21 is provided with a fixing rod or a transmission shaft in a horizontal direction, the stirring mechanism is mounted on the fixing rod or the transmission shaft, and a stirring motor 211 connected to the fixing rod or the transmission shaft is provided on a side surface of the first storage hopper 21. Like this, when in actual operation, start agitator motor 211 and drive the rabbling mechanism through the transmission shaft and stir the raw materials in first storage hopper 21, multiple raw materials form mixture (wall material) after the rabbling mechanism stirs, and the mixture that stirs is discharged through the discharge gate 92a that first storage hopper 21 bottom set up.

The screw extruder 51 of this embodiment is disposed below the first material storage hopper 21, a screw is disposed inside the screw extruder 51, the screw is driven by a screw motor 511 disposed at one end of the screw extruder 51, a discharge door 512 for discharging is disposed at the other end of the screw extruder 51, and a feed inlet 91c is disposed at the top of the screw extruder 51 corresponding to the screw. The feed port 91c at the top of the screw extruder 51 is connected to the discharge port 92a at the bottom of the first storage hopper 21, so that when the raw materials in the first storage hopper 21 are completely mixed, the formed mixture falls into the screw extruder 51, is conveyed by the screw extruder 51, and is extruded from the discharge gate 512.

The mixture extruded by the screw extruder 51 finally falls into the discharge hopper 61, and specifically, the screw extruder 51 and the discharge hopper 61 are respectively mounted on the supporting platform 62, wherein the discharge hopper 61 is movably mounted on the supporting platform 62 and located below the discharge door 512. The fixed or movable connection between the discharge hopper 61 and the support platform 62 means: the discharge hopper 61 can be fixedly arranged on the supporting platform 62 and needs to correspond to the lower part of the discharge door 512 of the screw extruder 51, so that the discharge hopper 61 can smoothly receive materials; the discharging hopper 61 is movably mounted on the supporting platform 62, and particularly, the discharging hopper 61 needs to be connected between the supporting platform 62 and the supporting platform 61 through a movable part, so that the discharging hopper 61 can smoothly reciprocate on the supporting platform 62. Therefore, the mixture in the screw extruder 51 can be smoothly dropped into the discharge hopper 61 by the reasonable arrangement between the screw extruder 51 and the discharge hopper 61.

Preferably, in order to complete the feeding and receiving work between the screw extruder 51 and the discharge hopper 61, the discharge hopper 61 is connected with a weighing sensor 63, the weighing sensor 63 senses the weight of the mixture received by the discharge hopper 61 and feeds back a weight signal to the screw motor 511, so that the extrusion action of the screw extruder 51 is automatically stopped after the discharge hopper 61 receives enough mixture. Specifically, be equipped with the weighing support 64 that is used for installing weighing sensor 63 on supporting platform 62, this weighing support 64 locates out the both sides limit of hopper 61 and is higher than the limit mouth portion of hopper 61, and wherein weighing sensor 63's one end fixed connection weighing support 64, the limit portion of hopper 61 is connected out to the other end, and the bottom of hopper 61 is the unsettled state in fact to this realization is weighed the mixture in the hopper 61.

The cloth mould 71 of this embodiment is used for the shape of design mixture formation wallboard, cloth mould 71 is installed on conveying platform 72 and is located the below of going out hopper 61, like this, stops to connect the material when weighing sensor 63 senses the mixture that goes out hopper 61 and receive and reaches the setting value, then goes out hopper 61 and opens the discharge gate and put in the mixture on cloth mould 71. The feeding mode and the action of the discharging hopper 61 can be analyzed according to the assembly relation between the discharging hopper 61 and the supporting platform 62, generally, when the discharging hopper 61 is connected with the supporting platform 62 through a movable part, after the discharging hopper 61 stops receiving materials, the discharging hopper 61 moves on the supporting platform 62 through the movable part and towards the direction of the cloth mold 71 while throwing in the mixture, the pouring of the discharging hopper 61 is finished or the mixture is thrown to meet the requirements, and then the discharging hopper 61 scrapes the mixture on the cloth mold 71 during the return process. After the mixture on the distributing mold 71 meets the feeding and scraping requirements, the mixture is conveyed to a target position through the conveying table 72, so that the distributing process of the wall material is automatically completed.

In this way, the raw materials are conveyed to the first material storage hopper 21 through the first material conveying pipeline 31, meanwhile, the first material storage hopper 21 stirs and mixes a plurality of raw materials, then the mixture is conveyed and extruded to the discharging hopper 61 through the screw extruder 51, and the weighing sensor 63 is used for weight sensing and weight signal feedback in the process that the screw extruder 51 extrudes the mixture to the discharging hopper 61, so that the effect of automatic control on the extrusion of the mixture between the screw extruder 51 and the discharging hopper 61 is realized; when the weighing sensor 63 senses that the mixture received by the discharge hopper 61 reaches a set value, the screw extruder 51 is stopped to extrude the mixture, and the discharge hopper 61 is enabled to throw the mixture into the distribution mold 71 and conduct strickle processing, so that the full-automatic operation of the wall material distribution process is realized, the labor cost is effectively reduced, and the processing generation efficiency of the wall material is improved.

Referring to fig. 2, in the present embodiment, the discharging hopper 61 is mounted on the supporting platform 62 through a movable component, and the discharging hopper 61 can slide back and forth along the direction of the sliding rail 621 by arranging the sliding rail 621 on the supporting platform 62, then arranging a sliding block matching with the sliding rail 621 at the bottom of the discharging hopper 61, and then controlling the discharging hopper 61 through a motor or an air cylinder. The used discharging hopper 61 is provided with a discharging port for putting in the mixture, specifically, when the weighing sensor 63 senses that the weight of the mixture received by the discharging hopper 61 reaches a set value, a feedback signal is sent to the screw motor 511 to stop the action of extruding the mixture, and after the screw extruder 51 stops extruding the mixture, the discharging hopper 61 discharges the mixture from the discharging port to the distributing mold 71. Thereby achieving the effect of automatic feeding and quantitative feeding between the screw extruder 51 and the discharge hopper 61.

Preferably, after the screw extruder 51 stops extruding the mixture by the signal fed back by the load cell 63, the discharge port of the discharge hopper 61 is opened, and the discharge hopper 61 drops the mixture into the distribution mold 71 while sliding along the slide rail 621, so that the mixture is spread on the distribution mold 71 as uniformly as possible. In practical application, preferentially make out hopper 61 satisfy the throwing material requirement of cloth mould 71 when first sliding, like this, go out hopper 61 throw material after finishing along slide rail 621 when returning along the original way can strickle the action to the mixture on the cloth mould 71, promptly go back and forth one of hopper 61 and can accomplish throwing material and scraping of cloth mould 71, effectively improve wall material cloth efficiency.

Preferably, as shown in fig. 1, the wall material distributing system provided in this embodiment further includes: a receiving vehicle 11 for receiving the raw material, a second storage hopper 22, a second conveying pipeline 32 for conveying the raw material, and a pumping device 41 for pumping the raw material. The bottom of the material receiving vehicle 11 is provided with a discharge hole 92e for discharging raw materials, the discharge of the material receiving vehicle 11 is provided with a material cutting plate, the second material storage hopper 22 is arranged below the material receiving vehicle 11, and the second material storage hopper 22 is used for receiving the raw materials thrown from the discharge hole 92b of the material receiving vehicle 11. The second storage hopper 22 has a discharge port 92b at the bottom, the second transporting pipe 32 has a feed port 91a and a discharge port 92c, and the feed port 91a of the second transporting pipe 32 is connected to the discharge port 92b of the second storage hopper 22, so that when a predetermined amount of the raw material is stored in the second storage hopper 22, the raw material is transported through the second transporting pipe 32.

The discharge port 92c at the other end of the second material conveying pipeline 32 is connected to the pumping device 41, so that the pumping device 41 pumps the raw material of the second material conveying pipeline 32, and further, the feed port 91b of the first material conveying pipeline 31 is connected to the pumping device 41, so that the pumping device 41 can pump the raw material of the second material conveying pipeline 32 to the first material conveying pipeline 31, and according to the above scheme, the first material conveying pipeline 31 is connected to the first material storage hopper 21, so that the effect of conveying the raw material received by the material receiving vehicle 11 to the first material storage hopper 21 after mutual support and interaction between the pumping device 41 and the material conveying pipeline is achieved.

The pumping device 41 of this embodiment is connected to the one-way check valve 42 at the end of the feeding hole 91b of the first material conveying pipeline 31, the first material conveying pipeline 31 is provided with a plurality of discharging holes 92d, the plurality of discharging holes 92d correspond to the plurality of first material storage hoppers 21, that is, each discharging hole 92d of the first material conveying pipeline 31 corresponds to one first material storage hopper 21. Like this, pumping device 41 is under one-way check valve 42's effect with during raw materials pump sending to a plurality of first storing hoppers 21 through first conveying pipeline 31, stirs the mixture by first storing hopper 21, through the rational design of first conveying pipeline 31, and the connected relation between pumping device 41 and the first conveying pipeline 31, effectively promotes the transport efficiency of raw materials.

The pumping device 41 of this embodiment combines the second material delivery pipe 32 and the first material delivery pipe 31 to pump the raw material to the first storage hopper 21, and the design requirement of the first material delivery pipe 31 is that one end of the first material delivery pipe 31 connected to the one-way check valve 42 of the pumping device 41 is a main pipe, and one end of the first material delivery pipe 31 connected to the first storage hopper 21 is a branch pipe. Wherein, the main pipe of the first material conveying pipeline 31 is provided with a water inlet valve 82 for inputting clean water and a pneumatic ball valve 81 for cutting off and opening the main pipe, the water inlet valve 82 is arranged in front of the pneumatic ball valve 81, that is, the water inlet valve 82 is positioned between the pneumatic ball valve 81 and the feed port 91b of the first material conveying pipeline 31.

Thus, when the first delivery pipe 31 is filled with clean water, the pneumatic ball valve 81 is closed first to prevent the clean water from flowing into the first storage hopper 21, so that the clean water flows toward the pumping device 41. The branch pipes of the first material conveying pipeline 31 are provided with a plurality of branch pipes, that is, the branch pipe of each first material conveying pipeline 31 corresponds to one discharge port 92d, and the front section of the discharge port 92d of each branch pipe is provided with a pneumatic ball valve 81 for independently controlling the cut-off and opening of each branch pipe. Through the reasonable connection and arrangement between the first material conveying pipeline 31 and the first storage hopper 21, and the pneumatic ball valve 81 and the water inlet valve 82 arranged on the first material conveying pipeline 31, the flow direction and the cleaning of the raw materials can be effectively controlled.

The second material conveying pipeline 32 of this embodiment is also provided with a pneumatic ball valve 81, the cut-off and the opening of the second material conveying pipeline 32 are controlled by the pneumatic ball valve 81, the second material conveying pipeline 32 is further provided with a drain valve 83, the drain valve 83 is arranged between the pneumatic ball valve 81 and the feed port 91a of the second material conveying pipeline 32, and the drain valve 83 is mainly used for discharging the clean water filled from the feed valve 82 of the first material conveying pipeline 31.

The material receiving vehicle 11 of this embodiment is provided with a plurality of material receiving motors 12 above, the material receiving motor 12 drives the material receiving vehicle 11 to move to the top of the second material storage hopper 22, specifically, the top of the material receiving vehicle 11 is connected with the driving slide rail 621, and slides along the direction of the driving slide rail 621 under the driving of the material receiving motor 12, the bottom of the material receiving vehicle 11 is provided with a material outlet 92e, and when the material receiving vehicle 11 needs to put raw materials into the second material storage hopper 22, the material receiving vehicle can slide to the top of the second material storage hopper 22 and is connected with the second material storage through the material outlet 92 b. Thereby achieving the purpose that the receiving vehicle 11 feeds the second storage hopper 22.

In the embodiment, a plurality of rods are disposed on the surface of the conveying table 72, and the fabric mold 71 is disposed on the plurality of rods, so that when the fabric mold 71 needs to be distributed or the distribution is completed, the plurality of rods can be driven by the motor to drive the fabric mold 71, so that the fabric mold 71 reaches a designated position.

Second embodiment

The difference between this embodiment and the first embodiment is that the connection relationship between the discharge hopper 61 and the support platform 62 is the same, and the description thereof is omitted here.

Referring to fig. 2, the discharge hopper 61 is fixedly connected to the supporting platform 62, and the discharge hopper 61 is located below the discharge door 512 of the screw extruder 51. The bottom of the discharge hopper 61 is provided with a discharge port, that is, when the weighing sensor 63 senses that the weight of the mixture received by the discharge hopper 61 reaches a set value, a feedback signal is sent to the screw motor 511 to stop the action of extruding the mixture, then the discharge hopper 61 drops the mixture into the distribution mold 71 from the discharge port at the original position, and the feeding of the discharge hopper 61 is finished or the mixture is fed to meet the requirements. Therefore, the material conveying action between the screw extruder 51 and the discharge hopper 61 is realized, excessive manpower is not required to be input in the whole process, and the cost is effectively saved.

While the wall material distribution system provided in the present application has been described in detail, those skilled in the art will appreciate that the various modifications, additions, substitutions, and substitutions are possible, without departing from the scope and spirit of the utility model as disclosed in the accompanying claims.

Claims (10)

1. A wall distribution system, comprising:

the device comprises a first storage hopper, a second storage hopper and a control system, wherein the first storage hopper is connected with a first conveying pipeline for conveying raw materials, a stirring mechanism for stirring the raw materials is arranged in the first storage hopper, and the first storage hopper is provided with a discharge hole for discharging mixed materials;

the screw extruder is connected with the discharge hole of the first material storage hopper, is driven by a screw motor and extrudes a mixture through a discharge door;

the discharging hopper is fixedly or movably arranged on the supporting platform and is positioned below the discharging door, the discharging hopper is connected with a weighing sensor, and the weighing sensor senses the weight of the mixed materials received by the discharging hopper and feeds back weight signals to the screw motor;

the cloth mould is arranged on the conveying table and located below the discharge hopper.

2. The wall material distributing system according to claim 1, wherein a slide rail is arranged on the surface of the supporting platform, the discharge hopper is mounted on the slide rail and slides back and forth along the slide rail, the discharge hopper is provided with a discharge port, when the weighing sensor senses that the weight of the mixed material received by the discharge hopper reaches a set value, a signal is fed back to the screw motor to stop the action of extruding the mixed material, and the mixed material of the discharge hopper falls into the distributing mold from the discharge port.

3. The wall material distributing system according to claim 2, wherein after the screw extruder stops extruding the mixture, the discharge hopper slides along the direction of the slide rail and throws the mixture into the distributing mold, and after the discharge hopper finishes throwing, the discharge hopper returns along the original path of the slide rail and scrapes the mixture on the distributing mold.

4. The wall material distributing system according to claim 1, wherein the discharge hopper is fixedly mounted on the supporting platform, the discharge hopper is provided with a discharge port, when the weighing sensor senses that the weight of the mixture received by the discharge hopper reaches a set value, a signal is fed back to the screw motor to stop the action of extruding the mixture, and the mixture of the discharge hopper falls into the distributing mold from the discharge port.

5. A walling distribution system according to claim 3 or 4, further comprising:

the material receiving vehicle is used for receiving raw materials and is provided with a discharge hole;

the second material storage hopper is used for receiving raw materials thrown from a discharge hole of the material receiving vehicle and is provided with a discharge hole;

the second conveying pipeline is provided with a feeding hole and a discharging hole, and the feeding hole of the second conveying pipeline is connected with the discharging hole of the second storage hopper;

and the pumping device is used for pumping raw materials and is connected with the discharge hole of the second material conveying pipeline, and the pumping device is connected with the feed hole of the first material conveying pipeline.

6. A wall distribution system as claimed in claim 5, wherein said pumping means is connected to the inlet of said first delivery conduit by a one-way check valve, and wherein material delivered by said first delivery conduit is discharged through a plurality of outlets to a plurality of said first hoppers.

7. A wall material distribution system as claimed in claim 6, wherein the end of said first material delivery pipe connected to said one-way check valve is a main pipe, said main pipe of said first material delivery pipe is provided with a water inlet valve and a pneumatic ball valve, said water inlet valve is located between said pneumatic ball valve and the inlet of said first material delivery pipe, the end of said first material delivery pipe connected to said first storage hopper is a branch pipe, and said branch pipe of said first material delivery pipe is provided with a plurality of pneumatic ball valves.

8. A wall distribution system as claimed in claim 5, wherein said second conduit is provided with a drain valve and a pneumatic ball valve, said drain valve being located between said pneumatic ball valve and the inlet of said second conduit.

9. A wall material distribution system as claimed in claim 5, wherein a plurality of material receiving motors are arranged above the material receiving vehicle, the material receiving motors drive the material receiving vehicle to move above the second material storage hopper, and the material receiving vehicle delivers the received raw materials to the second material storage hopper through a material outlet.

10. A wall distribution system as claimed in claim 5, wherein a plurality of rollers are disposed on the surface of the transfer table, and wherein the distribution mold is disposed on the plurality of rollers, the plurality of rollers being driven by a motor and driving the distribution mold.

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