CN110091505B - Intelligent control system based on 3D printer - Google Patents

Abstract

The invention relates to an intelligent control system based on a 3D printer, which relates to the technical field of printing and solves the problems that the on-site operation is required in both scanning and modeling modes, so that required data is acquired and acquired, long-time waiting is required for acquisition, and careful and accurate checking is required, so that the preparation work before printing is overlong; login reference information is preset in the master control terminal; entering the system when the login information is consistent with the login reference information; otherwise, the system is not entered; when the processing module receives the acquisition signal, the connection between the mobile terminal and the 3D printer corresponding to the processing module is established and the binding is realized. The invention has the effects of remote operation and preparation time saving.

Description

Intelligent control system based on 3D printer

Technical Field

The invention relates to the technical field of printing, in particular to an intelligent control system based on a 3D printer.

Background

The 3D printer is 3DP for short, is one kind of printer, can print the shape of any required article through the 3D printer. And meanwhile, the 3D printing is the model of the object, and the function of the object cannot be printed.

When the 3D printer is used at any time, model data to be printed needs to be input, and there are 2 input methods commonly used in the market:

1. scanning a product to be printed on site by using a scanning instrument;

2. and carrying out on-site modeling on the three-dimensional data through a computer.

The above prior art solutions have the following drawbacks: the scanning and modeling methods are both adopted, and field operation is needed, so that required data is acquired, long-time waiting is needed for acquisition, careful and accurate checking is needed, preparation work before printing is too long, and improvement space is provided.

Disclosure of Invention

The invention aims to provide an intelligent control system based on a 3D printer, which can be remotely operated and saves the preparation time.

The above object of the present invention is achieved by the following technical solutions:

an intelligent control system based on a 3D printer, comprising:

the information receiving module is arranged on the 3D printer and used for receiving the printing signal and outputting an information receiving signal;

the processing module is arranged on the 3D printer and connected with the information receiving module and receives the information receiving signal to control the 3D printer to print;

the main control terminal is connected with the user side and carries out information interaction;

the mobile terminal is carried by a user and used for storing and processing data;

the login module is arranged on the mobile terminal and is used for a user to input login information;

the acquisition module is arranged on the mobile terminal and is used for scanning the two-dimensional code on the 3D printer to acquire and output an acquisition signal;

the model building module is arranged on the mobile terminal and used for building a printing model and browsing locally;

the information transmitting module is connected with the model establishing module and sends the three-dimensional model to the information receiving module for printing;

login reference information is preset in the master control terminal;

entering the system when the login information is consistent with the login reference information; otherwise, the system is not entered;

and when the processing module receives the acquisition signal, the mobile terminal is connected with the 3D printer corresponding to the processing module and is bound.

Through adopting above-mentioned technical scheme, through the setting of logging in the module to the security of system has been improved, and the acquisition module acquires the two-dimensional code, thereby will remove end and 3D printer and establish the connection, the setting of model establishment module makes the user carry out the establishment of model on removing the end, and information emission module cooperates the setting of information receiving module, thereby carries out the interaction of information, thereby controls through processing module to print to the 3D printer.

The invention is further configured to: the model building module comprises:

a three-dimensional establishing unit for calling three-dimensional model data and splicing the three-dimensional model data to generate a printing model

The model scanning unit is used for scanning a product to be printed and generating a printing model;

the picture acquisition unit is used for scanning the boundary line of the product in the picture to simulate a printing model;

and three-dimensional model data are preset in the main control terminal.

By adopting the technical scheme, the three-dimensional model data are called and spliced through the setting of the three-dimensional establishing unit, so that the establishing efficiency is improved, the model is scanned through the setting of the model scanning unit, the three-dimensional model is acquired and established through the picture, and the practicability is high.

The invention is further configured to: the three-dimensional building unit includes:

the model calling part is used for calling three-dimensional model data from the main control terminal;

a model matching part for separating and combining the three-dimensional model data;

a model local locking part for locally locking the combined model to generate a model block for calling;

a model combining section for combining the model blocks to generate a print model.

By adopting the technical scheme, the model calling part calls the three-dimensional model from the main control terminal, the model splicing part is arranged to separate and combine the three-dimensional model data so as to form a new three-dimensional model, the model local locking part locks the combined three-dimensional model and changes the combined three-dimensional model into the model block, and finally the model block is combined and formed through the model combining part, so that the practicability is high.

The invention is further configured to: the model scanning unit includes:

the scanning fixing part is used for placing and uniformly rotating products;

the model scanning part is used for scanning the product on the scanning fixing part and outputting a primary model;

the displacement part is used for controlling the scanning fixing part to displace in the corresponding space and controlling the model scanning part to scan for multiple times;

an integration part which acquires a plurality of preliminary models and locks the overlapped parts in the plurality of preliminary models to identify the distinguishing parts;

and a detail scanning part for acquiring the distinguished parts marked in the integration part and scanning to perfect the model and generate the printing model.

Through adopting above-mentioned technical scheme, through the setting of scanning fixed part, place the product and rotate, and model scanning portion carries out preliminary scanning with the product, and displacement portion adjusts the position of scanning fixed part, and integration portion integrates the locking with the part of coincidence to the scanning efficiency who has improved, detail scanning portion carries out secondary scanning to the part of not locking, thereby perfects the model.

The invention is further configured to: the picture acquisition unit includes:

the picture identification part is used for selecting and obtaining picture objects;

a product frame selection part for selecting a product range from the obtained picture object;

a wire frame acquiring unit for acquiring a boundary frame of the product from the selected product range;

a simulation generation unit that generates a preliminary model from the bounding box;

and a model adjusting part which debugs on the preliminary model according to the detail characteristics to generate a printing model.

By adopting the technical scheme, the picture is acquired through the picture identification part, the picture is framed and selected by the product framing and selecting part, so that redundant background is removed, the boundary of the product is acquired through the setting of the wire frame acquiring part, and a preliminary model and a model adjusting part are generated through the simulation generating part.

The invention is further configured to: the login module comprises:

the fingerprint identification unit is used for inputting fingerprint information by a user;

the pattern input unit is used for a user to input pattern information in the fingerprint identification unit;

fingerprint reference information and pattern reference information corresponding to the fingerprint reference information are preset in the master control terminal;

when the fingerprint information is consistent with the fingerprint reference information, the pattern input unit is activated; otherwise, the activation is not carried out;

entering the system when the pattern information is consistent with the pattern reference signal; otherwise, the system is not entered.

By adopting the technical scheme, the fingerprint information is received through the setting of the fingerprint identification unit, and the image input unit is arranged, so that the image is input in the fingerprint identification unit, and the overall safety is improved.

The invention is further configured to: the printing system further comprises a cloud server connected with the main control terminal and a recording module arranged on the mobile terminal, wherein the cloud server acquires the printed printing model, stores and records the printed printing model, and the recording module is used for a user to input verification information;

the master control terminal is preset with verification reference information;

and when the verification information is consistent with the verification reference information, the mobile terminal acquires a printing module in the cloud server for the processing module to receive and print.

By adopting the technical scheme, the cloud server is arranged and is matched with the recording module, so that the linkage is improved, the cloud acquisition capability is realized, the overall flexibility is improved, and the practicability is high.

The invention is further configured to: further comprising:

the material detection module is connected with the main control terminal and is used for detecting printing materials in the 3D printer and outputting material detection signals;

the model estimation module estimates the quantity of the printing material according to the printing model and outputs an estimation signal;

when the estimated signal is greater than the material detection signal, the main control terminal realizes alarm; otherwise, no alarm is given.

Through adopting above-mentioned technical scheme, through the setting of material detection module to detect the raw materials, the cooperation model predicts the setting of module, thereby predicts the raw materials that need print the model, thereby has improved holistic stability, prevents to print the state of lack of material midway, and the practicality is strong.

The invention is further configured to: the material detection module includes:

a material variety detection unit for detecting a variety of a material and outputting a variety detection signal;

the material conversion unit is used for acquiring the conversion rate of the corresponding material from the database;

a material cross-sectional area detection unit for detecting a cross-sectional area of the material and outputting a cross-sectional area detection signal;

a material length detection unit for detecting the length of the material and outputting a length detection signal;

a database is preset in the main control terminal, and the database is provided with conversion rates of different materials for reshaping after melting;

defining the cross section area of the currently detected material as S, the conversion rate as Q, the material usage amount for printing the current model as Y, and the current length of the material as L;

then, when S is Q is L < Y, the master control terminal realizes alarm; otherwise, no alarm is given.

By adopting the technical scheme, the material variety detection unit is arranged, so that the material is detected, and the conversion rate of each material is different, so that the conversion rate is matched with the material conversion unit, the cross-sectional area detection unit detects the cross-sectional area, and finally, the material length detection unit is matched, so that the overall stability is improved.

The invention is further configured to: further comprising:

the warehouse material detection module is connected with the main control terminal, detects the quantity of the materials and outputs material detection signals;

the indicating module is connected with the main control terminal and is used for indicating the missing materials;

a material reference signal corresponding to the minimum material is preset in the main control terminal;

the indication module is activated when the material detection signal is less than the material reference signal; otherwise, it is not activated.

Through adopting above-mentioned technical scheme, through the setting of warehouse material detection module to detect the quantity of the material of storage in the warehouse, the setting of instruction module has improved indicateability, in case the material is not enough, just can carry out the replenishment of material, and the practicality is strong.

In conclusion, the beneficial technical effects of the invention are as follows:

1. remote operation is realized, and meanwhile, preparation time is saved;

2. and the material is monitored in real time and quickly prompted.

Drawings

Fig. 1 is a schematic diagram of a mobile terminal system according to the present invention.

Fig. 2 is a system diagram of a main control terminal in the present invention.

Fig. 3 is a system flow diagram of a 3D printer based intelligent control system.

In the figure, 1, an information receiving module; 2. a processing module; 3. a master control terminal; 4. a mobile terminal; 5. a login module; 6. an acquisition module; 7. a model building module; 8. an information transmitting module; 9. a three-dimensional building unit; 10. a model scanning unit; 11. a picture acquisition unit; 12. a model calling unit; 13. a model matching part; 14. a model partial locking portion; 15. a model combining part; 16. a scanning fixing part; 17. a model scanning unit; 18. a displacement section; 19. an integration part; 20. a detail scanning section; 21. a picture recognition unit; 22. a product frame selection part; 23. a wire frame acquisition unit; 24. a simulation generation unit; 25. a model adjusting section; 26. a fingerprint recognition unit; 27. a pattern input unit; 28. a cloud server; 29. a recording module; 30. a material detection module; 31. a model pre-estimation module; 32. a material variety detection unit; 33. a material conversion unit; 34. a material cross-sectional area detection unit; 35. a material length detection unit; 36. a warehouse material detection module; 37. and indicating the module.

Detailed Description

The present invention is described in further detail below with reference to figures 1-3.

Referring to fig. 1 and 2, the intelligent control system based on the 3D printer disclosed by the invention comprises a mobile terminal 4 and a main control terminal 3, wherein the main control terminal 3 is a microcomputer single chip, and the main control terminal 3 is equivalent to a chip and is arranged on the 3D printer and controls the 3D printer to print and print objects. The mobile terminal 4 is a portable intelligent device such as a smart phone or a smart watch. The mobile terminal 4 and the main control terminal 3 establish connection through a network and perform information interaction to realize remote data transmission.

Referring to fig. 1, the mobile terminal 4 is further connected to a login module 5, an acquisition module 6, a model building module 7, and an information transmitting module 8. The login module 5 is used for a user to input login information so as to enter the system, login reference information is preset in the main control terminal 3, and when the login information is consistent with the login reference information, the system enters the system; and when the login information is inconsistent with the login reference information, the terminal does not enter the system.

The login module 5 includes a fingerprint recognition unit 26 and a pattern input unit 27. The fingerprint identification unit 26 is used for inputting fingerprint information by a user, and the pattern input unit 27 is used for inputting pattern information in the fingerprint identification unit 26 by the user, wherein the fingerprint information and the pattern information belong to login information. And the fingerprint identification unit 26 is provided with pattern information input in addition to the input of fingerprint information.

The main control terminal 3 is preset with fingerprint reference information and pattern reference information corresponding to the fingerprint reference information, and both the fingerprint reference information and the pattern reference information belong to login reference information.

When the fingerprint information coincides with the fingerprint reference information, the pattern input unit 27 is activated; when the fingerprint information does not coincide with the fingerprint reference information, the pattern input unit 27 is not activated.

Entering the system when the pattern information is consistent with the pattern reference signal; when the pattern information does not coincide with the pattern reference signal, the system is not entered.

The 3D printer is provided with the only two-dimensional code, and after entering the system, a user can scan and acquire the two-dimensional code through the acquisition module 6. And the acquisition module 6 is arranged on the mobile terminal 4, and the acquisition module 6 is used for scanning the two-dimensional code on the 3D printer to acquire and output an acquisition signal.

The model building module 7 is disposed on the mobile terminal 4, and the model building module 7 is configured to build a printing model and browse locally. The model establishing module 7 comprises a three-dimensional establishing unit 9, a model scanning unit 10 and a picture acquiring unit 11. The three-dimensional establishing unit 9 is used for calling three-dimensional model data and splicing the three-dimensional model data to generate a printing model; the model scanning unit 10 is used for scanning a product to be printed and generating a printing model; the picture acquisition unit 11 is used for scanning the boundary line of the product in the picture to simulate a printing model.

Three-dimensional model data are preset in the main control terminal 3, and the three-dimensional model is built through one of the three-dimensional building unit 9, the model scanning unit 10 and the picture obtaining unit 11.

The three-dimensional building unit 9 includes a model retrieving portion 12, a model patch portion 13, a model local locking portion 14, and a model combining portion 15.

The model retrieving part 12 is used for retrieving three-dimensional model data from the main control terminal 3, the model assembling part 13 is used for separating and combining the retrieved three-dimensional model data, the model local locking part 14 is used for locally locking the combined models to generate model blocks for retrieval, and the model combining part 15 is used for combining the model blocks to generate a printing model.

The model scanning unit 10 includes a scan fixing unit 16, a model scanning unit 17, a displacement unit 18, an integration unit 19, and a detail scanning unit 20.

Scanning fixed part 16 supplies the product to place and carry out even rotation, model scanning portion 17 is used for scanning and exporting the primary model to the product on the scanning fixed part 16, displacement portion 18 is used for controlling scanning fixed part 16 to carry out the displacement and control model scanning portion 17 and scan many times in corresponding space, integration portion 19 obtains a plurality of primary models and locks the coincidence in a plurality of primary models and distinguish the part with the sign, detail scanning portion 20 obtains the difference part of sign in the integration portion 19 and scans and generate the printing model with perfecting the model.

The picture acquisition unit 11 includes a picture recognition unit 21, a product frame selection unit 22, a wire frame acquisition unit 23, a simulation generation unit 24, and a model adjustment unit 25.

The picture recognition part 21 is used for framing and obtaining picture objects, the product framing part 22 frames and selects a product range from the obtained picture objects, the wire frame obtaining part 23 obtains a boundary frame of a product from the selected product range, the simulation generation part 24 generates a preliminary model according to the boundary frame, and the model adjusting part 25 debugs the preliminary model according to detail characteristics to generate a printing model.

The information transmitting module 8 is connected with the model establishing module 7, and the information transmitting module 8 sends the three-dimensional model to the information receiving module 1 for printing.

Referring to fig. 2, the main control terminal 3 is connected to the cloud server 28, the recording module 29, the information receiving module 1, the processing module 2, the material detecting module 30, the model estimating module 31, the warehouse material detecting module 36, and the indicating module 37.

The cloud server 28 obtains the printed printing model, stores and records the printing model, and the recording module 29 is used for a user to input verification information. The main control terminal 3 is preset with verification reference information; when the verification information is consistent with the verification reference information, the mobile terminal 4 acquires a printing module in the cloud server 28 for the processing module 2 to receive and print; when the verification information is inconsistent with the verification reference information, the mobile terminal 4 cannot acquire the printing module in the cloud server 28 for the processing module 2 to receive the printing. When the processing module 2 receives the acquisition signal, the mobile terminal 4 is connected with the 3D printer corresponding to the processing module 2, and binding is achieved.

The information receiving module 1 is connected with the information transmitting module 8, and the information receiving module 1 is arranged on the 3D printer and used for receiving a printing signal and outputting an information receiving signal. Processing module 2 sets up on the 3D printer, and processing module 2 is connected and is received information reception signal in order to control the 3D printer and print with information reception module 1.

The material detection module 30 is connected with the main control terminal 3, and the material detection module 30 is used for detecting the printing material in the 3D printer and outputting a material detection signal. The material detection module 30 includes a material variety detection unit 32, a material conversion unit 33, a material cross-sectional area detection unit 34, and a material length detection unit 35.

The material variety detecting unit 32 is configured to detect a variety of a material and output a variety detection signal, the material converting unit 33 acquires a conversion rate of the corresponding material from the database, the material cross-sectional area detecting unit 34 is configured to detect a cross-sectional area of the material and output a cross-sectional area detection signal, and the material length detecting unit 35 is configured to detect a length of the material and output a length detection signal.

A database is preset in the main control terminal 3, and the database is provided with conversion rates of different materials for reshaping after melting, and defines:

the cross-sectional area of the currently detected material is S;

the conversion rate is Q;

the material usage amount of the current printing model is Y;

the current length of the material is L;

then, when S × Q × L is less than Y, the main control terminal 3 implements an alarm; when other relations are met, no alarm is given. When an alarm is given, the current material cannot meet the printing requirement, so that the material needs to be supplemented in advance to continue printing, the efficiency is improved, the service life of the equipment is prolonged, and the equipment is damaged when the printing is stopped midway.

The model estimation module 31 estimates the amount of the printing material according to the printing model and outputs an estimation signal, and when the estimation signal is greater than the material detection signal, the main control terminal 3 realizes an alarm; and when the estimated signal is not greater than the material detection signal, the main control terminal 3 does not give an alarm.

The warehouse material detection module 36 is connected with the main control terminal 3, and the warehouse material detection module 36 detects the quantity of the material and outputs a material detection signal. And the indicating module 37 is connected with the main control terminal 3 and is used for indicating the missing material.

The main control terminal 3 is preset with a material reference signal corresponding to the minimum material. When the material detection signal is less than the material reference signal, indicating module 37 to activate; when the material detection signal is not less than the material reference signal, the indicating module 37 is not activated.

Referring to fig. 3, a user inputs login information through a login module, and once the login information is input correctly, the user enters the system, so that the two-dimensional code on the 3D printer is scanned through the acquisition module 6, and the mobile terminal 4 is bound with the current 3D printer by matching with the processing module 2.

And then, a model to be printed is established through the model establishing module 7, a signal is transmitted through the information transmitting module 8, information is received through the information receiving module 1, and meanwhile, when the processing module 2 receives the signal, the 3D printer is controlled to print.

The material detection module 30 detects the material to be printed in advance, the model estimation module 31 is matched to estimate the material required by printing, and once the material meets the condition, the processing module 2 controls the 3D printer to print.

Finally, the printing model is stored through the cloud server 28 and is matched with the recording module 29 for recording, so that the printing model can be directly called in the later period conveniently.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims (8)

1. An intelligent control system based on 3D printer, its characterized in that includes:

the information receiving module (1) is arranged on the 3D printer and is used for receiving the printing signal and outputting an information receiving signal;

the processing module (2) is arranged on the 3D printer and is connected with the information receiving module (1) and receives the information receiving signal to control the 3D printer to print;

the main control terminal (3) is connected with the user side and carries out information interaction;

the mobile terminal (4) is carried by a user and used for storing and processing data;

the login module (5) is arranged on the mobile terminal (4) and is used for a user to input login information;

the acquisition module (6) is arranged on the mobile terminal (4) and is used for scanning the two-dimensional code on the 3D printer to acquire and output an acquisition signal;

the model building module (7) is arranged on the mobile terminal (4) and is used for building a printing model and browsing locally;

the information transmitting module (8) is connected with the model establishing module (7) and sends the three-dimensional model to the information receiving module (1) for printing;

login reference information is preset in the master control terminal (3);

entering the system when the login information is consistent with the login reference information; otherwise, the system is not entered;

when the processing module (2) receives the acquisition signal, the mobile terminal (4) is connected with the 3D printer corresponding to the processing module (2) and binding is realized;

the model building module (7) comprises:

a three-dimensional establishing unit (9) for calling three-dimensional model data and splicing the three-dimensional model data to generate a printing model;

the model scanning unit (10) is used for scanning a product to be printed and generating a printing model;

the picture acquisition unit (11) is used for scanning the boundary line of the product in the picture to simulate a printing model;

three-dimensional model data are preset in the main control terminal (3);

the three-dimensional building unit (9) comprises:

a model retrieving unit (12) for retrieving three-dimensional model data from the main control terminal (3);

a model matching unit (13) for separating and combining the retrieved three-dimensional model data;

a model local locking section (14) for locally locking the combined models to generate model blocks for use in retrieval;

and a model combining unit (15) for combining the model blocks to generate a print model.

2. The intelligent control system based on the 3D printer according to claim 1, characterized in that: the model scanning unit (10) comprises:

a scanning fixing part (16) for placing and uniformly rotating products;

a model scanning part (17) for scanning the product on the scanning fixing part (16) and outputting a preliminary model;

a displacement part (18) for controlling the displacement of the scanning fixing part (16) in the corresponding space and controlling the model scanning part (17) to scan for a plurality of times;

an integration section (19) that acquires a plurality of preliminary models and locks overlapping portions of the plurality of preliminary models to identify a distinctive portion;

and a detail scanning unit (20) which acquires the difference part identified in the integration unit (19) and scans the difference part to complete the model and generate a printing model.

3. The intelligent control system based on the 3D printer according to claim 1, characterized in that: the picture acquisition unit (11) comprises:

a picture recognition unit (21) for framing and acquiring a picture object;

a product frame selection unit (22) for selecting a product range from the acquired picture object;

a wire frame acquisition unit (23) for acquiring a product boundary frame from the selected product range;

a simulation generation unit (24) that generates a preliminary model from the bounding box;

and a model adjusting part (25) which debugs the preliminary model according to the detail characteristics to generate a printing model.

4. The intelligent control system based on the 3D printer according to claim 1, characterized in that: the login module (5) comprises:

a fingerprint recognition unit (26) for a user to input fingerprint information;

a pattern input unit (27) for a user to input pattern information in the fingerprint recognition unit (26);

fingerprint reference information and pattern reference information corresponding to the fingerprint reference information are preset in the main control terminal (3);

when the fingerprint information coincides with the fingerprint reference information, the pattern input unit (27) is activated; otherwise, the activation is not carried out;

entering the system when the pattern information is consistent with the pattern reference signal; otherwise, the system is not entered.

5. The intelligent control system based on the 3D printer according to claim 1, characterized in that: the printing system further comprises a cloud server (28) connected with the main control terminal (3) and a recording module (29) arranged on the mobile terminal (4), wherein the cloud server (28) acquires the printed printing model and stores and records the printing model, and the recording module (29) is used for a user to input verification information;

the master control terminal (3) is preset with verification reference information;

and when the verification information is consistent with the verification reference information, the mobile terminal (4) acquires a printing module in the cloud server (28) for the processing module (2) to receive and print.

6. The intelligent control system based on the 3D printer according to claim 1, characterized in that: further comprising:

the material detection module (30) is connected with the main control terminal (3) and is used for detecting the printing material in the 3D printer and outputting a material detection signal;

the model estimation module (31) estimates the amount of the printing material according to the printing model and outputs an estimation signal;

when the estimated signal is greater than the material detection signal, the main control terminal (3) realizes alarm; otherwise, no alarm is given.

7. The intelligent control system based on the 3D printer according to claim 6, characterized in that: the material detection module (30) comprises:

a material type detection unit (32) for detecting the type of the material and outputting a type detection signal;

a material conversion unit (33) for acquiring a conversion rate of the corresponding material from the database;

a material cross-sectional area detection unit (34) for detecting a cross-sectional area of the material and outputting a cross-sectional area detection signal;

a material length detection unit (35) for detecting the length of the material and outputting a length detection signal;

a database is preset in the main control terminal (3), and the database is provided with conversion rates of different materials for reshaping after melting;

defining the cross section area of the currently detected material as S, the conversion rate as Q, the material usage amount for printing the current model as Y, and the current length of the material as L;

then, when S X Q L < Y, the master control terminal (3) realizes alarm; otherwise, no alarm is given.

8. The intelligent control system based on the 3D printer according to claim 6, characterized in that: further comprising:

the warehouse material detection module (36) is connected with the main control terminal (3), detects the quantity of the materials and outputs material detection signals;

the indicating module (37) is connected with the main control terminal (3) and is used for indicating the missing materials;

a material reference signal corresponding to the minimum material is preset in the main control terminal (3);

the indication module (37) is activated when the material detection signal is less than the material reference signal; otherwise, it is not activated.

Images