A control method and system for automatically conveying a slab data following a 5G driving crane

By using structured processing of slab data from the hot rolling production line and 5G communication technology, the automatic transmission of slab data on the hot rolling production line was realized, solving the problems of low accuracy and poor efficiency caused by frequent manual operation, and improving production efficiency and data accuracy.

CN117185136BActive Publication Date: 2026-06-26LIUZHOU IRON & STEEL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
LIUZHOU IRON & STEEL CO LTD
Filing Date
2023-08-31
Publication Date
2026-06-26

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Abstract

The application discloses a kind of slab data follow 5G crane hoisting automatic conveying control method and system, comprising: obtaining hot-rolled strip mill slab data, and the slab data is structured processing;Based on the slab data after structured processing hoisting automatic transmission control;Structured processing includes the unstructured slab data structured processing is slab furnace number, slab length, slab width, slab number, steel coil number;When slab hoisting to the load weight of target roller is not greater than minimum clamp weight and not less than empty hook weight, target roller then obtains limit switch signal to realize slab data follow 5G crane hoisting automatic conveying.The application will slab data follow 5G crane hoisting slab automatic conveying to furnace roller, make slab data from artificial check to program automatic check leap, improve data accuracy, reduce artificial conveying, check link, steel efficiency, capacity significantly improve, improve the operation intensity of operator.
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Description

Technical Field

[0001] This invention relates to the technical field of slab data control, and in particular to a control method and system for the automatic transmission of slab data following 5G overhead crane transport. Background Technology

[0002] In the furnace area of ​​the hot rolling production line, the process of transmitting slab data (including slab number, coil number, slab length, slab width, and furnace number, hereinafter collectively referred to as slab data) from the secondary stage to the primary furnace feed roller conveyor A0 is as follows: The operator uses a secondary computer at the steel loading control table in the furnace area to verify and transmit the slab data to be loaded into the furnace. After the raw material crane hoists the slab onto the furnace feed roller conveyor A0, the operator clicks the "Verify to A0" button on the primary computer monitoring screen at the steel loading control table, and only then can the slab data be transmitted to the furnace feed roller conveyor A0. After the slab data arrives at the furnace feed roller conveyor A0, it follows the slab and is automatically transmitted to the next process as the furnace feed roller conveyor moves, controlled by the primary program. Currently, the raw material warehouse has completed the construction of a 5G-based intelligent slab warehouse management system, which is already in operation. All cranes in the raw material warehouse are now controlled by 5G technology. The original method of transmitting slab data from the secondary stage to the primary furnace feed roller conveyor A0, which involved frequent manual operation, is clearly unable to keep up with the pace of 5G crane production. Summary of the Invention

[0003] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.

[0004] In view of the aforementioned existing problems, the present invention is proposed.

[0005] Therefore, this invention provides a control method and system for the automatic transmission of slab data following 5G overhead crane transport, solving the problems of low accuracy and poor efficiency of traditional manual verification.

[0006] To solve the above-mentioned technical problems, the present invention provides the following technical solution:

[0007] In a first aspect, embodiments of the present invention provide a control method for the automatic transmission of slab data following 5G overhead crane transport, comprising: acquiring slab data from a hot-rolled strip mill and performing structured processing on the slab data;

[0008] Automatic hoisting and transmission control is performed based on the slab data after the structured processing; the structured processing includes structuring the unstructured slab data into slab furnace number, slab length, slab width, slab number, and coil number;

[0009] When the load weight of the slab being hoisted to the target roller conveyor is not greater than the minimum clamping weight and not less than the empty hook weight, the target roller conveyor receives a limit switch signal to realize the automatic transmission of slab data following the 5G overhead crane.

[0010] Secondly, the present invention provides a control system for automatic transmission of slab data following 5G overhead crane transport, comprising: a data acquisition unit, a 5G communication unit, a control unit, a display unit, and a database;

[0011] The data acquisition unit is used to acquire slab data and crane operation information from the hot-rolled strip mill. The slab data is transmitted to the database via a 5G communication unit, and the database performs structured processing on the slab data. The data acquisition unit is also used to receive slab weight information acquired by the target roller conveyor.

[0012] The 5G communication unit is used to support data transmission between various units;

[0013] The control unit is used to receive the slab data after the database has been structured using the 5G communication unit, and control the slab to reach the target roller conveyor based on the structured slab data and the crane operation information.

[0014] The display unit is used to monitor the working status of the control unit. When the control unit fails to control the slab to reach the target roller table, the display unit will issue an alarm and feed back the fault information to the database for recording, reminding the user to perform manual control.

[0015] The database is also used to store the data information acquired by the data acquisition unit.

[0016] As a preferred embodiment of the control system for automatic transmission of slab data following 5G overhead crane transport according to the present invention, the data acquisition unit includes: a first information acquisition module, a second information acquisition module, a third information acquisition module and a fourth information acquisition module.

[0017] The first information acquisition module acquires slab data from a hot-rolled strip mill. The slab data is transmitted to a database for storage via a 5G communication unit. The database performs structured processing on the hot-rolled strip mill slab data acquired by the first information acquisition module. The control unit acquires the structured slab data via a 5G communication unit.

[0018] Select any point in space as the origin of the spatial rectangular coordinate system. The crane is located in the first octant of the spatial rectangular coordinate system. The second information acquisition module acquires the crane position information within the first octant and monitors it through the display unit.

[0019] As a preferred embodiment of the control system for automatic transmission of slab data following 5G overhead crane transport according to the present invention, the data acquisition unit further includes: the third information acquisition module acquiring a first signal of the crane operation information, and the fourth information acquisition module acquiring a second signal.

[0020] As a preferred embodiment of the control system for the automatic transmission of slab data following 5G overhead crane transport as described in this invention, the control unit includes:

[0021] The control unit, in conjunction with the slab data obtained by the first information acquisition module after structured processing, controls the crane position so that the crane is located in the first area;

[0022] If the control unit fails to position the crane within the first zone, the display unit will monitor the fault and issue an alarm. The database will then retrieve the fault information and remind the user to perform manual control.

[0023] As a preferred embodiment of the control system for the automatic transmission of slab data following 5G overhead crane transport as described in this invention, it further includes:

[0024] The control unit receives the first signal and the second signal through the 5G communication unit, and controls the crane to lift the slab based on the signals.

[0025] When the first signal received by the control unit does not meet the first threshold range, the display unit monitors the fault and issues an alarm. The database retrieves the recorded fault information and reminds the user to perform manual control.

[0026] When the first signal received by the control unit meets the first threshold range, it combines the second signal to determine whether the slab has been hoisted to the target roller conveyor.

[0027] As a preferred embodiment of the control system for the automatic transmission of slab data following 5G overhead crane transport as described in this invention, it further includes:

[0028] When the control unit controls the crane to transport the slab to the first area and the first signal meets the first threshold range, the slab data is automatically transmitted following the 5G overhead crane transport by combining the second signal.

[0029] If any condition is not met, the control unit will send the fault information to the display unit via the 5G communication unit. The display unit will detect the fault and issue an alarm. The database will then retrieve the fault information and remind the user to perform manual control.

[0030] As a preferred embodiment of the control system for the automatic transmission of slab data following 5G overhead crane transport as described in this invention, the display unit includes: a button module, a monitoring module, and a data retrieval module.

[0031] When the monitoring module detects a fault, the database obtains and stores the fault information through the 5G communication unit, reminding the user to perform manual control.

[0032] The manual control requires the user to retrieve the slab data stored in the database through the data retrieval module. When the control unit controls the crane to lift the slab, the user manually judges whether the slab delivery meets the requirements.

[0033] If it is manually determined that the control unit can control the crane to transport the slab to the first area and the first signal meets the first threshold range, and combined with the second signal, it can transport the slab to the target roller conveyor, then the control button module is calibrated.

[0034] When the calibration conditions are met, the slab data is automatically transmitted along with the 5G overhead crane.

[0035] Thirdly, the present invention provides a computing device, comprising:

[0036] Memory and processor;

[0037] The memory is used to store computer-executable instructions, and the processor is used to execute the computer-executable instructions. When the computer-executable instructions are executed by the processor, the steps of the control method for automatically transmitting slab data following 5G overhead crane are implemented.

[0038] Fourthly, the present invention provides a computer-readable storage medium storing computer-executable instructions, which, when executed by a processor, implement the steps of a control method for automatically transmitting slab data following a 5G overhead crane.

[0039] Compared with the prior art, the beneficial effects of the present invention are as follows: The present invention automatically transmits slab data to the furnace roller conveyor along with the 5G overhead crane, which is a leap from manual verification to automatic verification of slab data, improves data accuracy, reduces manual transmission and verification links, significantly improves steel loading efficiency and production capacity, and reduces the operating intensity of operators. Attached Figure Description

[0040] To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort. Wherein:

[0041] Fig. 1 This is a flowchart of a control method and system for automatic transmission of slab data following 5G overhead crane transport, according to one embodiment of the present invention.

[0042] Fig. 2 This is a system structure diagram of a control method and system for automatic transmission of slab data following 5G overhead crane transport, as described in one embodiment of the present invention. Detailed Implementation

[0043] To make the above-mentioned objects, features, and advantages of the present invention more apparent and understandable, specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all of them. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort should fall within the protection scope of the present invention.

[0044] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.

[0045] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that is mutually exclusive with other embodiments.

[0046] This invention is described in detail with reference to the schematic diagrams. When detailing the embodiments of this invention, for ease of explanation, the cross-sectional views illustrating the device structure may be partially enlarged, not adhering to the usual scale. Furthermore, the schematic diagrams are merely examples and should not be construed as limiting the scope of protection of this invention. In actual fabrication, the three-dimensional spatial dimensions of length, width, and depth should be included.

[0047] Furthermore, in the description of this invention, it should be noted that the terms "upper," "lower," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. These terms are used solely for the convenience of describing the invention and for simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on the invention. In addition, the terms "first," "second," or "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0048] Unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" in this invention should be interpreted broadly. For example, they can refer to fixed connections, detachable connections, or integral connections; similarly, they can refer to mechanical connections, electrical connections, or direct connections, or indirect connections through an intermediate medium, or internal connections between two components. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances.

[0049] Example 1

[0050] Reference Figs. 1-2 As one embodiment of the present invention, this embodiment provides a control method and system for the automatic transmission of slab data following 5G overhead crane transport, including:

[0051] Obtain slab data from hot-rolled strip mills and perform structured processing on the slab data;

[0052] Automatic hoisting and transmission control is performed based on the structured slab data; the structured processing includes transforming unstructured slab data into slab furnace number, slab length, slab width, slab number, and coil number;

[0053] When the load weight of the slab being hoisted to the target roller conveyor is not greater than the minimum clamping weight and not less than the empty hook weight, the target roller conveyor receives a limit switch signal to realize the automatic transmission of slab data following the 5G overhead crane.

[0054] This embodiment of a control system for the automatic transmission of slab data following 5G overhead crane transport includes: a data acquisition unit 100, a 5G communication unit 200, a control unit 300, a display unit 400, and a database 500.

[0055] The data acquisition unit 100 is used to acquire slab data and crane operation information from the hot-rolled strip mill. The slab data is transmitted to the database 500 via the 5G communication unit 200, and the database 500 performs structured processing on the slab data. The data acquisition unit 100 is also used to receive slab weight information acquired by the target roller conveyor.

[0056] 5G communication unit 200 is used to support data transmission between various units;

[0057] The control unit 300 is used to receive slab data after structured processing by the database 500 using the 5G communication unit 200, and control the slab to reach the target roller conveyor based on the structured slab data and crane operation information.

[0058] The display unit 400 is used to monitor the working status of the control unit 300. When the control unit 300 fails to control the slab to reach the target roller table, the display unit 400 will issue an alarm and send the fault information to the database 500 for recording, reminding the user to perform manual control.

[0059] Database 500 is also used to store data information acquired by data acquisition unit 100.

[0060] Furthermore, the data acquisition unit 100 includes: a first information acquisition module 101, a second information acquisition module 102, a third information acquisition module 103, and a fourth information acquisition module 104;

[0061] The first information acquisition module 101 acquires slab data from the hot-rolled strip mill. The slab data is transmitted to the database 500 for storage via the 5G communication unit 200. The database 500 performs structured processing on the hot-rolled strip mill slab data acquired by the first information acquisition module 101. The control unit 300 acquires the structured slab data via the 5G communication unit 200.

[0062] Select any point in space as the origin of the spatial rectangular coordinate system. The crane is located in the first octant of the spatial rectangular coordinate system. The second information acquisition module 102 acquires the crane position information of the crane running in the first octant and monitors it through the display unit 400.

[0063] Furthermore, the data acquisition unit 100 also includes: a third information acquisition module 103 acquiring a first signal of crane operation information, and a fourth information acquisition module 104 acquiring a second signal.

[0064] Furthermore, the control unit 300 includes:

[0065] The control unit 300 combines the slab data obtained by the first information acquisition module 101 after structured processing to control the position of the crane so that the crane is located in the first area.

[0066] If the control unit 300 fails to control the crane to reach the first zone, the display unit 400 will monitor the fault and issue an alarm, and the database 500 will retrieve the fault information and remind the user to perform manual control.

[0067] Specifically, it also includes:

[0068] The control unit 300 receives the first signal and the second signal through the 5G communication unit 200, and controls the crane to lift the slab based on the signal.

[0069] When the first signal received by the control unit 300 does not meet the first threshold range, the display unit 400 monitors the fault and issues an alarm, and the database 500 retrieves the recorded fault information to remind the user to perform manual control.

[0070] When the first signal received by the control unit 300 meets the first threshold range, it combines the second signal to determine whether the slab has been hoisted to the target roller conveyor.

[0071] It should be noted that in this embodiment, the first signal is the load weight; the second signal is the limit switch signal for the clamp to open; when the first signal is not greater than the minimum clamping weight and not less than the empty hook weight, the first threshold range is satisfied.

[0072] Specifically, it also includes:

[0073] When the control unit 300 controls the crane to transport the slab to the first area and the first signal meets the first threshold range, the slab data is automatically transported following the 5G overhead crane in conjunction with the second signal.

[0074] If any condition is not met, the control unit 300 will send the fault information to the display unit 400 via the 5G communication unit 200. The display unit 400 will detect the fault and issue an alarm. The database 500 will retrieve the fault information and remind the user to perform manual control.

[0075] Furthermore, the display unit 400 includes: a button module 401, a monitoring module 402, and a data retrieval module 403;

[0076] When the monitoring module 402 detects a fault, the database 500 obtains and stores the fault information through the 5G communication unit 200, reminding the user to perform manual control.

[0077] Manual control requires the user to retrieve the slab data stored in the database 500 through the data retrieval module 403. When the control unit 300 controls the crane to lift the slab, the user manually judges whether the slab delivery meets the requirements.

[0078] If the manual judgment control unit 300 controls the crane to be able to transfer the slab to the first area and the first signal meets the first threshold range, and the second signal is combined with the ability to transfer the slab to the target roller conveyor, then the control button module 401 will perform calibration.

[0079] When the calibration conditions are met, the slab data is automatically transmitted along with the 5G overhead crane.

[0080] This embodiment also provides a computing device applicable to the control method of automatically transmitting slab data following 5G overhead crane transport, including:

[0081] The system includes a memory and a processor. The memory stores computer-executable instructions, and the processor executes these instructions to implement the control method for automatically transmitting slab data following a 5G overhead crane, as proposed in the above embodiments.

[0082] This embodiment also provides a storage medium on which a computer program is stored. When the program is executed by a processor, it implements the control method for automatically transmitting slab data following 5G overhead crane transport as proposed in the above embodiment.

[0083] The storage medium proposed in this embodiment and the control method for automatically transmitting slab data following 5G crane transportation proposed in the above embodiments belong to the same inventive concept. Technical details not described in detail in this embodiment can be found in the above embodiments, and this embodiment has the same beneficial effects as the above embodiments.

[0084] Based on the above description of the implementation methods, those skilled in the art can clearly understand that the present invention can be implemented using software and necessary general-purpose hardware, and of course, it can also be implemented using hardware, but in many cases the former is a better implementation method. Based on this understanding, the technical solution of the present invention, or the part that contributes to the prior art, can be embodied in the form of a software product. This computer software product can be stored in a computer-readable storage medium, such as a computer floppy disk, read-only memory (ROM), random access memory (RAM), flash memory, hard disk, or optical disk, etc., including several instructions to cause a computer device (which may be a personal computer, server, or network device, etc.) to execute the methods of the various embodiments of the present invention.

[0085] Example 2

[0086] Reference Figs. 1-2 This is one embodiment of the present invention. Unlike the first embodiment, this embodiment provides a control process for transmitting slab data from the 5G slab warehouse system to the furnace area primary PLC system.

[0087] In this embodiment, the 5G slab database control software controls the 5G crane to lift the corresponding slab. When the 5G slab database control software receives the signal that the 5G crane has lifted the slab to the A0 roller conveyor, the 5G slab database control software sends the slab data to the furnace area level-one PLC system.

[0088] It should be noted that the completion signal for the 5G crane to transport the slab to the A0 roller conveyor depends on the load weight and the limit switch signal for the clamp to open. The load weight is input to the 5G crane PLC system via the output signal (4-20mA) of the weight sensor of the lifting limiter to detect the clamp and the slab. When the slab is transported to the A0 roller conveyor, if the load weight meets the condition of "minimum clamped slab weight ≥ load weight ≥ empty hook weight" and the limit switch signal for the clamp to open is received, it is determined that the 5G crane has completed the transport of the slab to the A0 roller conveyor.

[0089] Add "Manual Billet Data Loading" and "Automatic Billet Data Loading" operation buttons to the primary steel loading monitoring computer screen. When "Manual Billet Data Loading" is selected, the "Manual Billet Data Loading" operation button is red, and the "Automatic Billet Data Loading" operation button is gray; when "Automatic Billet Data Loading" is selected, the "Automatic Billet Data Loading" operation button is red, and the "Manual Billet Data Loading" operation button is gray. When the variable M603.0 is in the state of "1", it indicates that "Automatic Billet Data Loading" is selected; when the variable M603.0 is in the state of "0", it indicates that "Manual Billet Data Loading" is selected.

[0090] A judgment program is added to the secondary communication counter (DB2101.DBW4) to avoid frequently receiving the same data from the secondary system. Its control variable is M198.2. A judgment program is added to the 5G communication counter (DB1201.DBW76) to avoid frequently receiving the same data from the 5G slab intelligent warehouse management system. Its control variable is M698.2. The change in the data of the variable DB1201.DBW2, which is the "accumulation after the data of the message changes" in the function block (DB1201) of the 5G slab intelligent warehouse management system, is used to determine whether the communication between the 5G slab intelligent warehouse management system and the furnace area PLC system is normal. The variable is M521.2. The variable M521.2 is used to generate a "communication failure between the 5G slab intelligent warehouse management system and the furnace area PLC system" alarm on the steel loading primary monitoring screen, and participates in the control of the automatic transmission of slab data to the furnace roller conveyor as the 5G overhead crane transports the slab.

[0091] Under normal communication conditions between the 5G slab intelligent warehouse management system and the furnace area PLC system, after the 5G overhead crane places the slab onto the primary furnace feed roller conveyor A0, the 5G slab intelligent warehouse management system transmits the slab data (slab number, coil number, slab length, slab width, and furnace number) to the corresponding variables in the function block (DB1201). When the "Automatic Loading of Billet Data" operation key is selected, "AN M521.2", "AM603.0", and "AM698.2" are simultaneously satisfied. The slab data (slab number, coil number, slab length, slab width, and furnace number) in the function block (DB1201) are then transmitted to the corresponding variables in the function block (DB85), meaning the slab data is automatically transmitted to the furnace feed roller conveyor A0.

[0092] When the communication between the 5G slab intelligent warehouse management system and the furnace area PLC system is abnormal (i.e., when the "Communication Failure between 5G Slab Intelligent Warehouse Management System and Furnace Area PLC System" alarm is displayed on the primary steel loading monitoring screen), the 5G slab intelligent warehouse management system can no longer transmit slab data (slab number, coil number, slab length, slab width, and furnace number) to the corresponding variables in the function block (DB1201). To continue production, simply select the "Manual Loading of Slab Data" operation key on the steel loading monitoring screen; the "Manual Loading of Slab Data" operation key will turn red. The slab data is received by the function block (DB2101) of the primary furnace area PLC system, which receives the slab data transmitted from the secondary system. After the overhead crane has hoisted the slab to the primary furnace feed roller conveyor A0, click the "Check to A0" operation key (variable M1148.0) on the primary computer steel loading monitoring screen. This ensures that "A M198.2", "AM1148.0", and "AN" are simultaneously satisfied. The slab data (slab number, coil number, slab length, slab width and furnace number) in function block (DB2101) are transferred to the corresponding variables in function block (DB85). The manual loading operation key command "AN M603.0" is added to transfer the slab data to the furnace feed roller A0.

[0093] It should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, and all such modifications or substitutions should be covered within the scope of the claims of the present invention.

Claims

1. A control method for the automatic transmission of slab data following 5G overhead crane transport, characterized in that, include: Obtain slab data from hot-rolled strip mills and perform structured processing on the slab data; Automatic hoisting and transmission control is performed based on the structured slab data. The structuring process includes structuring unstructured slab data into slab furnace number, slab length, slab width, slab number, and coil number; When the load weight of the slab being hoisted to the target roller conveyor is not greater than the minimum clamping weight and not less than the empty hook weight, the target roller conveyor receives the limit switch signal of the clamp opening to realize the automatic transmission of slab data following the 5G overhead crane.

2. A control system for automatic transmission of slab data following 5G overhead crane transport, characterized in that, include: Data acquisition unit (100), 5G communication unit (200), control unit (300), display unit (400), database (500); The data acquisition unit (100) is used to acquire slab data and crane operation information from the hot-rolled strip mill. The slab data is transmitted to the database (500) via the 5G communication unit (200). The database (500) performs structured processing on the slab data. The data acquisition unit (100) is also used to receive slab weight information acquired by the target roller conveyor. 5G communication unit (200) is used to support data transmission between various units; The control unit (300) is used to receive the slab data after structured processing in the database (500) using the 5G communication unit (200), and control the slab to reach the target roller conveyor based on the structured slab data and crane operation information; the control unit (300) receives a first signal and a second signal through the 5G communication unit (200); wherein, the first signal is the load weight, and the second signal is the limit switch signal for clamp opening; When the control unit (300) receives the second signal and the first signal meets the first threshold range, the control unit (300) determines that the slab has been successfully hoisted to the target roller conveyor and sends the slab data to the furnace area PLC system; When the control unit (300) receives the second signal, if the first signal does not meet the first threshold range, the display unit (400) monitors the fault at that time and issues an alarm, and the database (500) records the fault information to remind the user to perform manual control; specifically, when the first signal is not greater than the minimum clamping weight and not less than the empty hook weight, the first threshold range is met; The display unit (400) is used to monitor the working status of the control unit (300). When the control unit (300) fails to control the slab to reach the target roller table, the display unit (400) will issue an alarm and send the fault information to the database (500) for recording, reminding the user to perform manual control. The database (500) is also used to store data information acquired by the data acquisition unit (100).

3. The control system for automatic transmission of slab data following 5G overhead crane transport as described in claim 2, characterized in that, The data acquisition unit (100) includes: a first information acquisition module (101), a second information acquisition module (102), a third information acquisition module (103), and a fourth information acquisition module (104). The first information acquisition module (101) acquires slab data from the hot-rolled strip mill. The slab data is transmitted to the database (500) for storage via a 5G communication unit (200). The database (500) performs structured processing on the hot-rolled strip mill slab data acquired by the first information acquisition module (101). The control unit (300) acquires the structured slab data via the 5G communication unit (200). Select any point in space as the origin of the spatial rectangular coordinate system. The crane is located in the first octant of the spatial rectangular coordinate system. The second information acquisition module (102) acquires the crane position information of the crane running in the first octant and monitors it through the display unit (400).

4. The control system for automatic transmission of slab data following 5G overhead crane transport as described in claim 3, characterized in that, The data acquisition unit (100) further includes: the third information acquisition module (103) acquires the first signal of the crane operation information, and the fourth information acquisition module (104) acquires the second signal.

5. The control system for automatic transmission of slab data following 5G overhead crane transport as described in claim 4, characterized in that, The control unit (300) includes: The control unit (300) combines the slab data obtained by the first information acquisition module (101) after structured processing to control the crane position so that the crane is located in the first area; When the control unit (300) fails to control the crane to reach the first area, the display unit (400) monitors the fault and issues an alarm. The database (500) records the fault information and reminds the user to perform manual control.

6. The control system for automatic transmission of slab data following 5G overhead crane transport as described in claim 5, characterized in that, Also includes: When the control unit (300) controls the crane to transport the slab to the first area and the first signal meets the first threshold range, the slab data is automatically transported following the 5G crane transport by combining the second signal; If any condition is not met, the control unit (300) will send the fault information to the display unit (400) through the 5G communication unit (200). The display unit (400) will detect the fault and issue an alarm. The database (500) will record the fault information and remind the user to perform manual control.

7. The control system for automatic transmission of slab data following 5G overhead crane transport as described in claim 6, characterized in that, The display unit (400) includes: a button module (401), a monitoring module (402), and a data retrieval module (403). When the monitoring module (402) detects a fault, the database (500) obtains and stores the fault information through the 5G communication unit (200) to remind the user to perform manual control; The manual control requires the user to retrieve the slab data stored in the database (500) through the data retrieval module (403). When the control unit (300) controls the crane to lift the slab, the user manually judges whether the slab delivery meets the requirements. If it is manually determined that the control unit (300) can control the crane to transfer the slab to the first area and the first signal meets the first threshold range, and the second signal can transfer the slab to the target roller conveyor, then the control button module (401) will perform calibration. When the calibration conditions are met, the slab data is automatically transmitted along with the 5G overhead crane.

8. An electronic device, comprising: Memory and processor; The memory is used to store computer-executable instructions, and the processor is used to execute the computer-executable instructions. When the computer-executable instructions are executed by the processor, they implement the steps of the control method for automatic transmission of slab data following 5G overhead crane as described in claim 1.

9. A computer-readable storage medium storing computer-executable instructions that, when executed by a processor, implement the steps of the control method for automatic transmission of slab data following a 5G overhead crane as described in claim 1.