CN116562495A - Cable tool return management device, method and equipment based on RFID (radio frequency identification) tag - Google Patents

Abstract

The application discloses a cable tool return management device, method and equipment based on RFID (radio frequency identification) tags, and belongs to the technical field of power equipment. The device comprises: the RFID tag is used for writing parameter information of the cable tool; the return operation identification module is used for identifying the information of the staff and determining a cable tool used by the staff to execute maintenance tasks according to the information; the target position determining module determines a return target position of each cable tool, and inputs information of the RFID tag to be identified for a reader-writer arranged for the return target position; and the dislocation recognition module is used for generating return position error prompt information if the RFID label read by the reader-writer is inconsistent with the RFID label to be recognized. The RFID tag is used in the scheme, the accuracy and the efficiency of cable tool management can be improved, the cable tool used by a worker in executing maintenance tasks can be better determined, the cable tool is prevented from returning to an error position, and the accuracy and the reliability of management are improved.

Description

Cable tool return management device, method and equipment based on RFID (radio frequency identification) tag

Technical Field

The application belongs to the technical field of power equipment, and particularly relates to a cable tool return management device, method and equipment based on an RFID (radio frequency identification) tag.

Background

With the development of digitization and intellectualization, the cable becomes an indispensable part of the power system, and provides an effective power transmission and distribution mode, and can transmit power from a power generation source to electric equipment, so as to meet the power demand. The cable can connect various equipment, makes them can carry out information transmission, such as computer, smart mobile phone and intelligent house etc. makes our life more convenient. Due to the influence of external factors and the influence of the service time of the cable itself, the cable is often required to be maintained. Management of maintenance tools is also one of the concerns during cable repair.

The present-day return management of cable maintenance tools utilizes an electronic management system in which tool lending information and return information are recorded and the expiration date of the tool is tracked. When returning the cable maintenance tool, the tool needs to be sent to a management place, a manager registers the tool in the system, records information of the returning tool, and completes the returning of the cable maintenance tool.

However, in the returning process of the cable maintenance tool, a manager still needs to manually put and record information of the returning tool, and the problems of wrong placement and wrong recording may occur, so that the returning management efficiency of the maintenance tool is reduced. Therefore, how to automatically perform the return management of the cable maintenance tool, avoid the problems of wrong placement position and wrong return record of the cable maintenance tool caused by manual operation, and how to save labor cost are the problems to be solved in the field.

Disclosure of Invention

The embodiment of the application provides a cable tool return management device, method and equipment based on an RFID tag, and aims to solve the problem that in the prior art, return management of a cable maintenance tool cannot be automatically carried out, and errors in the placement position and return recording of the cable maintenance tool can be caused due to manual operation. Through a cable tool returns management device based on RFID label, use accuracy and the efficiency that the cable tool managed can be improved to the RFID label, cable tool that can confirm better that the staff used when carrying out maintenance task to can effectively avoid cable tool to return to the wrong position, thereby improve the accuracy and the reliability of management.

In a first aspect, an embodiment of the present application provides an RFID tag-based cable tool return management device, the device including:

the RFID tag is arranged in the cable tool and used for writing parameter information of the cable tool;

the return operation identification module is used for identifying the information of the staff and determining a cable tool used by the staff when the staff executes maintenance tasks according to the information of the staff;

the target position determining module is used for determining a return target position of each cable tool and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position;

And the dislocation recognition module is used for generating return position error prompt information if the RFID label read by the reader-writer is inconsistent with the RFID label to be recognized.

Further, the device further comprises:

the target position display module is used for displaying the return target positions of the cable tools on a preset display device after determining the return target positions of the cable tools; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

Further, the target position determining module is specifically configured to:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

Further, the target position determining module is specifically configured to:

acquiring a tool number of each cable tool;

determining type parameters and shape parameters of the cable tool according to the tool number of the cable tool and a pre-stored association relation table of the tool number of the cable tool and the type parameters and shape parameters;

Determining a first using heat parameter of the type of the cable tool and a second using heat parameter of the cable tool according to the type parameter and the shape parameter of the cable tool;

and determining the using heat parameter of the cable tool according to the first using heat parameter and the second using heat parameter.

Further, the return operation identification module is specifically configured to:

identifying staff information according to the biological characteristics of staff; wherein the biological characteristics comprise at least one of a morphological characteristic, a fingerprint characteristic, an iris characteristic and a voiceprint characteristic of the staff;

reading maintenance tasks executed by the staff from a task system according to the staff information, and determining a cable tool to be returned according to a cable tool taking record of the staff;

or,

according to the staff information, determining a task plate maintained by a staff when the staff executes a maintenance task; and determining a cable tool to be returned according to the task plate.

Further, the dislocation recognition module is specifically configured to:

reading the RFID tag through a reader-writer;

identifying parameter information in the RFID tag, and judging whether the parameter information is consistent with the parameter information of the RFID tag to be identified;

If the return position error prompt information is inconsistent, generating the return position error prompt information;

if the answer is consistent, generating a return success prompt message.

In a second aspect, an embodiment of the present application provides a cable tool return management method based on an RFID tag, where the method includes:

parameter information of the cable tool is written in through the RFID tag; wherein the RFID tag is disposed in the cable plant;

identifying staff information through a return operation identification module, and determining a cable tool used by a staff to execute maintenance tasks according to the staff information;

determining a return target position of each cable tool through a target position determining module, and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position;

and generating return position error prompt information when the RFID tag read by the reader-writer is inconsistent with the RFID tag to be identified through the dislocation identification module.

Further, after determining the return target position for each of the cable tools, the method further comprises:

displaying the returned target position on a preset display device through a target position display module; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

Further, determining a return target position of each cable tool, and inputting information of the RFID tag to be identified to a reader/writer set for the return target position, including:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

In a third aspect, embodiments of the present application provide an electronic device comprising a processor, a memory and a program or instruction stored on the memory and executable on the processor, the program or instruction implementing the steps of the method according to the first aspect when executed by the processor.

In a fourth aspect, embodiments of the present application provide a readable storage medium having stored thereon a program or instructions which when executed by a processor implement the steps of the method according to the first aspect.

In a fifth aspect, embodiments of the present application provide a chip, where the chip includes a processor and a communication interface, where the communication interface is coupled to the processor, and where the processor is configured to execute a program or instructions to implement a method according to the first aspect.

In the embodiment of the application, the RFID tag is arranged in the cable tool and is used for writing parameter information of the cable tool; the return operation identification module is used for identifying the information of the staff and determining a cable tool used by the staff when the staff executes maintenance tasks according to the information of the staff; the target position determining module is used for determining a return target position of each cable tool and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position; and the dislocation recognition module is used for generating return position error prompt information if the RFID label read by the reader-writer is inconsistent with the RFID label to be recognized. Through the cable tool return management device based on the RFID tag, the accuracy and the efficiency of cable tool management can be improved by using the RFID tag, the cable tool used by a worker when executing maintenance tasks can be better determined, and the cable tool can be effectively prevented from returning to an error position, so that the accuracy and the reliability of management are improved.

Drawings

Fig. 1 is a schematic structural diagram of a cable tool return management device based on an RFID tag according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a cable tool return management device based on an RFID tag according to a second embodiment of the present application;

Fig. 3 is a flowchart of a cable tool return management method based on an RFID tag according to a third embodiment of the present application;

fig. 4 is a schematic structural diagram of an electronic device according to a fourth embodiment of the present application.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present application more apparent, the following detailed description of specific embodiments thereof is given with reference to the accompanying drawings. It is to be understood that the specific embodiments described herein are merely illustrative of the application and not limiting thereof. It should be further noted that, for convenience of description, only some, but not all of the matters related to the present application are shown in the accompanying drawings. Before discussing exemplary embodiments in more detail, it should be mentioned that some exemplary embodiments are described as processes or methods depicted as flowcharts. Although a flowchart depicts operations (or steps) as a sequential process, many of the operations can be performed in parallel, concurrently, or at the same time. Furthermore, the order of the operations may be rearranged. The process may be terminated when its operations are completed, but may have additional steps not included in the figures. The processes may correspond to methods, functions, procedures, subroutines, and the like.

Technical solutions in the embodiments of the present application will be clearly described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application are within the scope of the protection of the present application.

The terms first, second and the like in the description and in the claims, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged, as appropriate, such that embodiments of the present application may be implemented in sequences other than those illustrated or described herein, and that the objects identified by "first," "second," etc. are generally of a type and not limited to the number of objects, e.g., the first object may be one or more. Furthermore, in the description and claims, "and/or" means at least one of the connected objects, and the character "/", generally means that the associated object is an "or" relationship.

The cable tool return management device, method and equipment based on the RFID tag provided by the embodiment of the application are described in detail below through specific embodiments and application scenes thereof with reference to the accompanying drawings.

Example 1

Fig. 1 is a schematic structural diagram of a cable tool return management device based on an RFID tag according to an embodiment of the present application. As shown in fig. 1, the method specifically includes the following steps:

an RFID tag 101 disposed in the cable tool for writing parameter information of the cable tool;

a return operation identification module 102 for identifying staff information and determining a cable tool used by a staff member when the staff member performs maintenance tasks according to the staff member information;

a target position determining module 103, configured to determine a return target position of each cable tool, and input information of an RFID tag to be identified to a reader/writer set for the return target position;

the misalignment recognition module 104 generates a return position error indication message if the RFID tag read by the reader-writer is inconsistent with the RFID tag to be recognized.

Firstly, the use scene of the scheme can be a scene that after the intelligent terminal or the platform of the internet of things identifies the information of the staff, the return position of the cable tool is determined according to the cable tool used by the staff, and return position error prompt information is generated when the reader-writer identifies that the return position is wrong.

Based on the above usage scenario, it can be understood that the execution subject of the application may be the intelligent terminal or the internet of things platform, which is not limited herein too much.

In this scheme, each maintenance tool is provided with a unique RFID tag, that is, each maintenance tool has a different ID, and other information of the tool can be determined by identifying the ID information of the maintenance tool, for example, information such as the name and purpose of the tool can be determined.

The cable tool may be the tool required to service the cable and other equipment contained in the power system and may include a knife, pliers, wrench, hand saw, wire crimping pliers, and the like. The types of cables are different, the maintenance tools are different, the communication cables are different from the power transmission cables, and the power transmission video voltage levels are different.

The parameter information of the cable tool may include information of the number, type, name, size, etc. of the cable tool.

There are various methods for writing parameter information of the cable tool by the RFID tag, and mainly include a magneto-electric writing method and a circuit writing method. The magneto-electric writing method is to convert the computer instruction of the parameter information written in the cable tool into an electromagnetic signal by utilizing a magneto, and then transmit the signal to the RFID tag so as to realize the writing of the tag.

The circuit writing method is to convert the computer instruction written into the parameter information of the cable tool into an electric signal, transmit the signal to the RFID tag, and directly write into the internal memory of the tag to realize writing.

The worker information may be information for verifying whether the worker has the right to return the cable tool and determining the cable tool used by the worker, and may include information such as a worker name, an ID, and a department. The staff information can be pre-stored in a database table of the intelligent terminal or the internet of things platform in the cable tool return management device.

The maintenance task may be a task that a worker needs to maintain cables and other devices included in the power system, may include information such as a fault location, a fault that occurs, a fault device name, and a fault device ID, and may be represented as a fault that occurs with a fault device ID-a fault device name-a fault location. The fault location may be the geographical location of the device that is faulty and may be expressed in terms of (longitude, latitude). The failed device ID may be represented in numerical form. For example, when the fault device ID is 1001, the fault device name is a power transformation box, the fault occurs as a cable break in the power transformation box, and the fault position is 30 degrees north latitude and 120 degrees east longitude. The maintenance task may be denoted 1001-substation box-cable disconnection- (30°n,120°e).

The staff can register account numbers in the related software of the intelligent terminal or the internet of things platform in advance, a database table for storing the account numbers and passwords of the staff and the staff information can be created in the database of the intelligent terminal or the internet of things platform in advance, when the user inputs the account numbers and passwords on a login interface, the intelligent terminal or the internet of things platform automatically compares the account numbers and passwords of the user with the account numbers and passwords in the database table, and if the account numbers and passwords are the same, the user is considered as a legal user and can log in normally. After the user successfully logs in, the intelligent terminal or the internet of things platform can use the account number and password as a query condition to query a database so as to identify the information of the staff.

The maintenance tasks can be sent by the task management platform, and when the sensors in the devices of the power system detect the occurrence of faults, the occurrence of fault information can be transmitted to the task management platform by a wireless communication technology. And the task management platform also stores a database table of the staff information, automatically generates a maintenance task according to the received fault information and distributes the maintenance task to the corresponding staff. Meanwhile, a cable tool used in maintenance can be determined according to a maintenance task through a preset program, and the maintenance task, the cable tool used and corresponding staff information for executing the maintenance task are transmitted to the intelligent terminal or the internet of things platform through a wireless communication technology. The database table for storing the maintenance tasks, the used cable tools and the corresponding staff information can be established in the intelligent terminal or the internet of things platform in advance, and the maintenance tasks, the used cable tools and the corresponding staff information are stored in the database table after the intelligent terminal or the internet of things platform receives the maintenance tasks, the used cable tools and the corresponding staff information. The database table can be queried according to the information of the staff after the staff successfully logs in, so that the cable tool used by the staff when the staff executes maintenance tasks is determined. The task management platform can be an intelligent terminal or an internet of things platform for generating and managing maintenance tasks of cables and other devices contained in the power system. The preset program may be a program for analyzing and obtaining a cable tool used in maintenance by information such as a fault position, a fault occurring in a maintenance task, a fault device name, and a fault device ID. For example, if the fault device is a power transformation box, the program can analyze that the cable tool is a wrench when the fault is that a cable in the power transformation box is broken.

Based on the above technical solutions, optionally, the return operation identifying module 102 is specifically configured to:

identifying staff information according to the biological characteristics of staff; wherein the biological characteristics comprise at least one of a morphological characteristic, a fingerprint characteristic, an iris characteristic and a voiceprint characteristic of the staff;

reading maintenance tasks executed by the staff from a task system according to the staff information, and determining a cable tool to be returned according to a cable tool taking record of the staff;

or,

according to the staff information, determining a task plate maintained by a staff when the staff executes a maintenance task; and determining a cable tool to be returned according to the task plate.

In this scenario, the biometric of the staff member may be used to determine staff member identity information.

The topographical features may include eye shapes, nose shapes, mouth shapes, facial contours, eyebrow shapes, facial textures, and the like.

The physical characteristics may include limb posture, behavioral actions, expression characteristics, and the like.

The fingerprint features may include fingerprint patterns, fingerprint lines, fingerprint acupoints, fingerprint sizes, and the like.

Iris features may include iris images, iris structures, iris textures, iris details, iris patterns, iris templates, iris fingerprints, iris proportions, iris lines, and the like.

Voiceprint features can include tone, timbre, speed of speech, tone volume, and the like.

The intelligent terminal or the internet of things platform can use machine learning and deep learning algorithms to identify staff information. For example, the topographical features may be identified using image recognition techniques; physical characteristics can be identified using body joint localization techniques; fingerprint features can be identified using fingerprint identification techniques; iris features may be identified using iris identification techniques; voiceprint features can be identified using voiceprint identification techniques.

The task system may be a computer system that integrates the maintenance tasks that the presentation worker is required to perform and the cable tool retrieval records of the worker. The ultrasonic sensor can be arranged in each groove of the tool cabinet, when tools are taken away, the sensor can send out ultrasonic signals and transmit the ultrasonic signals to the intelligent terminal through a wireless communication technology, the intelligent terminal can detect that the tools in the groove of the tool cabinet are taken away, and cable tools are added at corresponding positions in a maintenance task database table of staff to take out records. For example, when the maintenance task performed is 1001-transformer box-cable disconnection- (31 ° N,117 ° E), and the extracted cable tool is a large caliber wrench, a cable tool extraction record of a worker may be added after the maintenance task performed, which may be expressed as 1001-transformer box-cable disconnection- (31 ° N,117 ° E) -large caliber wrench. After the staff information is successfully identified, the intelligent terminal or the internet of things platform can read maintenance tasks executed by the staff and cable tool taking-out records of the staff from a maintenance task database table according to the staff information and display the records in a task system, and then the cable tool to be returned can be determined according to the displayed cable tool taking-out records.

Task boards maintained by personnel in performing maintenance tasks may include connecting cables, replacing cables, inspecting cables, cleaning cables, replacing accessories required for the cables, and the like. Different task boards correspond to different cable tools, and in particular, maintenance task boards and corresponding cable tools may be stored in a database table. Similarly, when a maintenance task executed by a worker is determined in the task system, a corresponding maintenance task plate is also required to be associated with the maintenance task, when the intelligent terminal or the internet of things platform successfully identifies the worker information, the task plate maintained when the worker executes the maintenance task can be determined in the task system, the maintenance task plate and a database table of a corresponding cable tool are searched and stored according to the task plate maintained when the worker executes the maintenance task, and the cable tool which is correspondingly used is determined to be the cable tool to be returned.

In this scheme, through the biological characteristics according to the staff, discernment staff information can strengthen the security, prevents that illegal personnel from getting into the system. Meanwhile, the cable tool to be returned is determined according to the cable tool taking-out record or the task plate maintained by the staff when the maintenance task is executed, so that the cable tool to be returned can be rapidly determined, and the working efficiency is improved.

The return target position can be the original position of the cable tool, and can also be the position of the vacancy where the cable tool of the same type is positioned. For example, when the cable tool is a wrench, the return target position may be a position where the wrench is originally placed; if a plurality of vacant spanner placing positions exist, the spanner can be returned to any vacant spanner placing position.

The reader-writer can be an RFID reader-writer, and the RFID reader-writer is a radio frequency identification technology. The radio frequency signal can be transmitted to the radio frequency chip and the data can be read from the radio frequency chip, so that the functions of remotely identifying, tracking and recording the articles are realized.

When the return target position of each cable tool needs to be determined, the intelligent terminal or the internet of things platform sends a reading instruction to the reader-writers at the corresponding positions of all the cable tools of the type through a wireless communication technology, and when the reader-writers read RFID tags, the read RFID tag information can be fed back to the intelligent terminal or the internet of things platform; when the reader-writer cannot read the RFID tag, information of read errors can be fed back to the intelligent terminal or the Internet of things platform, namely, no cable tool is placed at the position. The intelligent terminal or the internet of things platform can determine the positions of all readers which cannot read the RFID tag as the returning target positions of all cable tools. For example, when the cable tool to be returned is a wrench, the intelligent terminal or the internet of things platform sends a reading instruction to the readers corresponding to all the wrenches, the readers receive the reading instruction and then read RFID tag information, and then feedback is carried out to the intelligent terminal or the internet of things platform, and the intelligent terminal or the internet of things platform inquires positions of the readers corresponding to all the information of 'reading errors', and determines that the positions are the returning target positions of the wrenches. Among them, wireless communication is a communication system that performs information exchange by utilizing the property that electromagnetic wave signals can propagate in free space.

When the returning target positions of all the cable tools are determined, the intelligent terminal or the internet of things platform can input RFID tag information of the cable tools which are required to be identified into the reader-writers arranged at the returning target positions through a wireless communication technology, and when a plurality of returning targets exist, after the reader-writer of one returning target identifies the information of the RFID tags which are required to be identified, the reader-writers at other positions automatically fail.

On the basis of the above technical solutions, optionally, the apparatus further includes:

the target position display module is used for displaying the return target positions of the cable tools on a preset display device after determining the return target positions of the cable tools; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

In this scheme, preset display device can be intelligent terminal or thing networking platform. The tool chest may be a chest specially designed for cable tools that can be placed to protect them from moisture, rust and vandalism. The tool cabinet number can be in the form of numbers and letters, and in the scheme, the tool cabinet number can be expressed in the form of numbers. Because a plurality of tool cabinets can exist at the same time, the tool cabinets can be arranged into a plurality of rows, the rows of the tool cabinets can be expressed in the form of letters, and the rows of the tool cabinets can be expressed from front to back and are ordered in the form of a-z. The tool cabinet position can be indicated by the letter number of the row in which the tool cabinet is located. The target slot in the tool cabinet can be the target position for placing the cable tools, and the target slot can be expressed in a digital form. The information ultimately displayed may be the tool chest location-tool chest number-the target slot of the cable tool in the tool chest. For example, when the wrench needs to be returned to the tool slot number 1 of the row 1 a cabinet, the information finally displayed may be row 1-1.

The format of the displayed information can be preset on the preset display equipment, after the return target position of each cable tool is determined, the reader-writer can transmit the position to the preset display equipment through a wireless communication technology, the preset display equipment edits the position of the reader-writer according to the preset format of the displayed information, and finally the edited position is displayed to a user, so that the user returns the cable tools according to the position.

In the scheme, by setting the target position display module, the time for returning the cable tool can be reduced, and the worker can quickly position and return the tool directly according to the displayed information. In addition, the module can also effectively help staff reduce tool return errors and avoid property loss caused by error of placement positions.

The return position error prompt message may be a message prompting the worker that the cable tool returns to a position error and is placed at a correct position.

If the RFID tag read by the reader-writer is inconsistent with the RFID tag to be identified, error information can be transmitted to the intelligent terminal or the internet of things platform through a wireless transmission technology, the intelligent terminal or the internet of things platform can firstly read the corresponding position of the reader-writer, and return position error prompt information is generated according to the position of the reader-writer and the placed cable tool, and specifically, the return position error prompt information can be in a form of error of the position of the reader-writer, the cable tool and the placement. For example, when it is desired to place the No. 3 wrench in the No. 1 grid of the No. 1 tool cabinet, but the worker places the No. 2 pliers in this position, the return position error notification message may be the No. 1 grid of the No. 1 tool cabinet-No. 3 wrench-placed error.

Based on the above technical solutions, optionally, the misalignment identification module 104 is specifically configured to:

reading the RFID tag through a reader-writer;

identifying parameter information in the RFID tag, and judging whether the parameter information is consistent with the parameter information of the RFID tag to be identified;

if the return position error prompt information is inconsistent, generating the return position error prompt information;

if the answer is consistent, generating a return success prompt message.

In the scheme, when the parameter information read by the reader-writer and the information of the RFID tag to be identified, which is transmitted by the intelligent terminal or the Internet of things platform, are inconsistent, error information can be transmitted to the intelligent terminal or the Internet of things platform through a wireless transmission technology, the intelligent terminal or the Internet of things platform can firstly read the corresponding position of the reader-writer, and return position error prompt information is generated according to the position of the reader-writer and a placed cable tool. When the parameter information read by the reader-writer is consistent with the information of the RFID tag which is transmitted by the intelligent terminal or the Internet of things platform and is required to be identified, successful information can be transmitted to the intelligent terminal or the Internet of things platform through a wireless transmission technology, the intelligent terminal or the Internet of things platform can firstly read the corresponding position of the reader-writer, and return successful prompt information is generated according to the position of the reader-writer and the placed cable tool.

In this scheme, through the mode that utilizes the read-write machine to read the RFID label in order to confirm whether the position of returning is correct, can the angelica in time suggest staff when returning to the mistake to the staff misplaces cable tool, avoids appearing returning the wrong problem in position, improves cable tool management's accuracy and efficiency.

According to the technical scheme provided by the embodiment, the RFID tag is arranged in the cable tool and is used for writing parameter information of the cable tool; the return operation identification module is used for identifying the information of the staff and determining a cable tool used by the staff when the staff executes maintenance tasks according to the information of the staff; the target position determining module is used for determining a return target position of each cable tool and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position; and the dislocation recognition module is used for generating return position error prompt information if the RFID label read by the reader-writer is inconsistent with the RFID label to be recognized. Through the cable tool return management device based on the RFID tag, the accuracy and the efficiency of cable tool management can be improved by using the RFID tag, the cable tool used by a worker when executing maintenance tasks can be better determined, and the cable tool can be effectively prevented from returning to an error position, so that the accuracy and the reliability of management are improved.

The cable tool return management device based on the RFID tag in the embodiment of the application can be a device, and also can be a component, an integrated circuit or a chip in a terminal. The device may be a mobile electronic device or a non-mobile electronic device. By way of example, the mobile electronic device may be a cell phone, tablet computer, notebook computer, palm computer, vehicle-mounted electronic device, wearable device, ultra-mobile personal computer (ultra-mobile personal computer, UMPC), netbook or personal digital assistant (personal digital assistant, PDA), etc., and the non-mobile electronic device may be a server, network attached storage (Network Attached Storage, NAS), personal computer (personal computer, PC), television (TV), teller machine or self-service machine, etc., and the embodiments of the present application are not limited in particular.

The cable tool return management device based on the RFID tag in the embodiment of the present application may be a device with an operating system. The operating system may be an Android operating system, an ios operating system, or other possible operating systems, which are not specifically limited in the embodiments of the present application.

Example two

Fig. 2 is a schematic structural diagram of a cable tool return management device based on an RFID tag according to a second embodiment of the present application. As shown in fig. 2, the method specifically includes the following steps:

the target position determining module 103 is specifically configured to:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

In this solution, the type parameter of the cable tool may be the name of the cable tool, for example, the cable tool name is a pliers, and correspondingly, the type parameter of the cable tool is also a pliers.

Because the maintenance requirements of different types of cables are different, different shapes of cable tools exist in the same type, and specifically, the caliber of the cable tool can be used as a shape parameter of the cable tool. The large-caliber cable tool can be used for repairing large-caliber cables, and the small-caliber cable tool can be used for repairing small-caliber cables and the like. In addition, different sized cable tools may also be satisfactory for different installation environments, such as small gauge cable tools may be used for compact space installation, while large gauge cable tools may be used for installation of large cables.

The usage heat parameter may be a usage frequency of the cable tool, and in particular, the usage heat parameter may be represented by a number. The higher the frequency of use, the greater the heat of use parameter; the lower the frequency of use, the smaller the heat of use parameter. For example, the usage heat parameters are numbered in the order of 1 to 10 from the smaller usage frequency to the larger usage frequency. The type parameter, the shape parameter and the using heat parameter of each cable tool can be pre-stored in a database table of the intelligent terminal or the internet of things platform.

After the intelligent terminal or the internet of things platform recognizes the information of the worker, the cable tool used by the worker can be displayed, and the worker can click a return button of the corresponding tool to return the tool. After a worker clicks a return button of a corresponding tool, the intelligent terminal or the internet of things platform can automatically call a database table storing type parameters, shape parameters and using heat parameters of each cable tool, and query the database table according to the cable tool selected by the worker to acquire the type parameters, the shape parameters and the using heat parameters corresponding to the tool.

The tool cabinet information and the slot position information in the tool cabinet can be stored in the intelligent terminal or the internet of things platform in advance, and after the type parameter, the shape parameter and the using heat parameter of each cable tool are acquired, the intelligent terminal or the internet of things platform can inquire the tool cabinet capable of storing the type and the shape of the cable tool and the slot position in the tool cabinet from a database table storing the tool cabinet information and the slot position information in the tool cabinet. The cable tool with higher using heat parameter should be placed in the tool cabinet easy to take and place and the slot in the tool cabinet, so the intelligent terminal or the internet of things platform can determine the returning target tool cabinet of the cable tool and the target slot in the target tool cabinet according to the using heat of the cable tool. For example, when the cable tool is a large-caliber wrench, the two tool cabinets respectively have a target slot position for placing the large-caliber wrench, and the using heat parameter of the large-caliber wrench is 1, so that the intelligent terminal or the internet of things platform can determine that the large-caliber wrench can be placed in the target slot position of the far tool cabinet.

After a return target tool cabinet of the pre-return cable tool and a target slot position in the target tool cabinet are determined, the intelligent terminal or the internet of things platform can automatically write information of the RFID tag of the pre-return cable tool into a reader-writer of the target slot position through a wireless communication technology.

In this embodiment, by determining the return position of the cable tool according to the type parameter, the shape parameter and the use heat parameter of each cable tool, not only the automatic return of the multi-cable tool can be realized, but also the cable tool with high use frequency can be placed at a position easy to take. The cable tool management efficiency can be effectively improved, the labor cost can be saved, and the manual positioning time is shortened.

Based on the above technical solutions, optionally, the target position determining module 103 is specifically configured to:

acquiring a tool number of each cable tool;

determining type parameters and shape parameters of the cable tool according to the tool number of the cable tool and a pre-stored association relation table of the tool number of the cable tool and the type parameters and shape parameters;

determining a first using heat parameter of the type of the cable tool and a second using heat parameter of the cable tool according to the type parameter and the shape parameter of the cable tool;

And determining the using heat parameter of the cable tool according to the first using heat parameter and the second using heat parameter.

In this solution, the tool number of the cable tool may be the ID of the cable tool, and the tool number of the cable tool may be stored in a cable tool database table in the database. After the worker selects the returned cable tools, the intelligent terminal or the internet of things platform automatically queries the database table to obtain the tool numbers of the cable tools.

The association table of the tool number of the cable tool with the type parameter and the shape parameter may be a database table storing the tool number of the cable tool, the type parameter of the cable tool, and the shape parameter of the cable tool. When the tool number of the cable tool is obtained, the type parameter and the shape parameter of the cable tool can be searched in the association relation table according to the tool number.

The first heat of use parameter may be the frequency of use of different types of cable tools, which may include, for example, wrenches, knives, pliers, etc., since the cable tool comprises a plurality of types. The frequencies of different types of cable tools in the use process are also different, so that the respective using heat parameters can be determined according to the frequencies of the different types of cable tools, and the higher the using frequency of the type of cable tools is, the higher the first using heat parameter is, and the cable tools need to be placed in a closer tool cabinet; the lower the frequency of use of this type of cable tool, the lower the first heat of use parameter, which can be placed in a remote tool cabinet.

The second heat using parameter can be the using frequency of the cable tool, and different types of cable tools can be distinguished according to different shapes, for example, a wrench can be classified according to different diameters, and the heat using parameter is lower when the using frequency of the large-caliber wrench is lower; the small-caliber wrench has higher use frequency, and the use heat parameter is also higher. Correspondingly, the use frequencies of different shapes can be counted after the cable tool is classified according to the shape parameters of the cable tool, and then the second use parameters of the cable tool can be determined. The higher the frequency of use of the cable tool in the shape under the type is, the higher the second use parameter is, and the cable tool can be placed in a groove position which is easy to take in a tool cabinet; the lower the frequency of use of the cable tool of this shape in this type, the lower the second use parameter, which can be placed in a difficult-to-take slot in the tool chest.

After the type parameter and the shape parameter of the cable tool are determined, the use frequency of the cable tools with different types and different shapes can be queried, and the use frequency is input into a preset program, and the first use heat parameter of the type of the cable tool and the second use heat parameter of the cable tool are determined through the program. The preset program may be a program for determining a cable usage heat parameter according to a usage frequency of the cable tool. When the first heat utilization parameter needs to be determined, the type parameter and the frequency of use need to be input in the program in advance, and the first heat utilization parameter is output after calculation through the program. When the second heat use parameter needs to be determined, the type parameter, the shape parameter and the use frequency need to be input, and the second heat use parameter is output after calculation through a program.

The weights of the first usage heat parameter and the second usage heat parameter can be input in a preset program, then the first usage heat parameter and the second usage heat parameter are input in the preset program, and the usage heat parameters of the cable tool are calculated through intra-program algorithm integration.

In this scheme, through the type parameter and the shape parameter according to the cable instrument confirm the heat parameter of cable instrument, can be according to the better maintenance demand of understanding staff of the heat parameter of cable instrument to can be according to maintenance demand adjustment cable instrument's the position of putting, make things convenient for the staff to take the cable instrument, improve staff's work efficiency.

Example III

Fig. 3 is a flowchart of a cable tool return management method based on an RFID tag according to a third embodiment of the present application. As shown in fig. 3, the method specifically comprises the following steps:

s301, writing parameter information of the cable tool through an RFID tag; wherein the RFID tag is disposed in the cable plant;

s302, identifying staff information through a return operation identification module, and determining a cable tool used by a staff to execute maintenance tasks according to the staff information;

S303, determining a return target position of each cable tool through a target position determining module, and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position;

s304, generating return position error prompt information when the RFID label read by the reader-writer is inconsistent with the RFID label to be identified through the dislocation identification module.

Further, after determining the return target position for each of the cable tools, the method further comprises:

displaying the returned target position on a preset display device through a target position display module; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

Further, determining a return target position of each cable tool, and inputting information of the RFID tag to be identified to a reader/writer set for the return target position, including:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

In the embodiment of the application, the parameter information of the cable tool is written in through the RFID tag; wherein the RFID tag is disposed in the cable plant; identifying staff information through a return operation identification module, and determining a cable tool used by a staff to execute maintenance tasks according to the staff information; determining a return target position of each cable tool through a target position determining module, and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position; and generating return position error prompt information when the RFID tag read by the reader-writer is inconsistent with the RFID tag to be identified through the dislocation identification module. According to the cable tool return management method based on the RFID tag, the accuracy and the efficiency of cable tool management can be improved by using the RFID tag, the cable tool used by a worker when executing a maintenance task can be better determined, and the cable tool can be effectively prevented from returning to an error position, so that the management accuracy and reliability are improved.

The cable tool return management method based on the RFID tag provided in this embodiment corresponds to the device provided in each embodiment and has an execution process and beneficial effects corresponding to the device provided in each embodiment, which are not described herein.

Example IV

As shown in fig. 4, the embodiment of the present application further provides an electronic device 400, including a processor 401, a memory 402, and a program or an instruction stored in the memory 402 and capable of running on the processor 401, where the program or the instruction implements each process of the embodiment of the cable tool return management device based on the RFID tag when executed by the processor 401, and the process can achieve the same technical effect, so that repetition is avoided, and no redundant description is provided herein.

The electronic device in the embodiment of the application includes the mobile electronic device and the non-mobile electronic device described above.

Example five

The embodiment of the application further provides a readable storage medium, on which a program or an instruction is stored, where the program or the instruction realizes each process of the embodiment of the cable tool return management device based on the RFID tag when being executed by the processor, and the same technical effect can be achieved, so that repetition is avoided, and no redundant description is provided here.

Wherein the processor is a processor in the electronic device described in the above embodiment. The readable storage medium includes a computer readable storage medium such as a Read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a magnetic disk or an optical disk, and the like.

Example six

The embodiment of the application further provides a chip, the chip includes a processor and a communication interface, the communication interface is coupled with the processor, the processor is used for running a program or an instruction, implementing each process of the above embodiment of the cable tool return management device based on the RFID tag, and achieving the same technical effect, so as to avoid repetition, and no further description is provided here.

It should be understood that the chips referred to in the embodiments of the present application may also be referred to as system-on-chip chips, chip systems, or system-on-chip chips, etc.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element. Furthermore, it should be noted that the scope of the methods and apparatus in the embodiments of the present application is not limited to performing the functions in the order shown or discussed, but may also include performing the functions in a substantially simultaneous manner or in an opposite order depending on the functions involved, e.g., the described methods may be performed in an order different from that described, and various steps may also be added, omitted, or combined. Additionally, features described with reference to certain examples may be combined in other examples.

From the above description of the embodiments, it will be clear to those skilled in the art that the above-described embodiment method may be implemented by means of software plus a necessary general hardware platform, but of course may also be implemented by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solutions of the present application may be embodied essentially or in a part contributing to the prior art in the form of a computer software product stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk), comprising several instructions for causing a terminal (which may be a mobile phone, a computer, a server, or a network device, etc.) to perform the methods described in the embodiments of the present application.

The embodiments of the present application have been described above with reference to the accompanying drawings, but the present application is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many forms may be made by those of ordinary skill in the art without departing from the spirit of the present application and the scope of the claims, which are also within the protection of the present application.

The foregoing description is only of the preferred embodiments of the present application and the technical principles employed. The present application is not limited to the specific embodiments described herein, but is capable of numerous obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the present application. Therefore, while the present application has been described in connection with the above embodiments, the present application is not limited to the above embodiments, but may include many other equivalent embodiments without departing from the spirit of the present application, and the scope of the present application is determined by the scope of the claims.

Claims (10)

1. An RFID tag-based cable tool return management device, the device comprising:

the RFID tag is arranged in the cable tool and used for writing parameter information of the cable tool;

the return operation identification module is used for identifying the information of the staff and determining a cable tool used by the staff when the staff executes maintenance tasks according to the information of the staff;

the target position determining module is used for determining a return target position of each cable tool and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position;

And the dislocation recognition module is used for generating return position error prompt information if the RFID label read by the reader-writer is inconsistent with the RFID label to be recognized.

2. The RFID tag-based cable tool return management device of claim 1, further comprising:

the target position display module is used for displaying the return target positions of the cable tools on a preset display device after determining the return target positions of the cable tools; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

3. The RFID tag-based cable tool return management device of claim 1, wherein the target location determination module is specifically configured to:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

4. The RFID tag-based cable tool return management device of claim 3, wherein the target location determination module is specifically configured to:

Acquiring a tool number of each cable tool;

determining type parameters and shape parameters of the cable tool according to the tool number of the cable tool and a pre-stored association relation table of the tool number of the cable tool and the type parameters and shape parameters;

determining a first using heat parameter of the type of the cable tool and a second using heat parameter of the cable tool according to the type parameter and the shape parameter of the cable tool;

and determining the using heat parameter of the cable tool according to the first using heat parameter and the second using heat parameter.

5. The RFID tag-based cable tool return management device of claim 1, wherein the return operation identification module is specifically configured to:

identifying staff information according to the biological characteristics of staff; wherein the biological characteristics comprise at least one of a morphological characteristic, a fingerprint characteristic, an iris characteristic and a voiceprint characteristic of the staff;

reading maintenance tasks executed by the staff from a task system according to the staff information, and determining a cable tool to be returned according to a cable tool taking record of the staff;

Or,

according to the staff information, determining a task plate maintained by a staff when the staff executes a maintenance task; and determining a cable tool to be returned according to the task plate.

6. The RFID tag-based cable tool return management device of claim 1, wherein the misalignment identification module is specifically configured to:

reading the RFID tag through a reader-writer;

identifying parameter information in the RFID tag, and judging whether the parameter information is consistent with the parameter information of the RFID tag to be identified;

if the return position error prompt information is inconsistent, generating the return position error prompt information;

if the answer is consistent, generating a return success prompt message.

7. A method of managing cable tool return based on RFID tags, the method comprising:

parameter information of the cable tool is written in through the RFID tag; wherein the RFID tag is disposed in the cable plant;

identifying staff information through a return operation identification module, and determining a cable tool used by a staff to execute maintenance tasks according to the staff information;

determining a return target position of each cable tool through a target position determining module, and inputting information of the RFID tag to be identified into a reader-writer arranged for the return target position;

And generating return position error prompt information when the RFID tag read by the reader-writer is inconsistent with the RFID tag to be identified through the dislocation identification module.

8. The RFID tag-based cable plant return management method of claim 7, wherein after determining a return target location for each cable plant, the method further comprises:

displaying the returned target position on a preset display device through a target position display module; the displayed information comprises a tool cabinet number, a tool cabinet position and a target groove position of the cable tool in the tool cabinet.

9. The RFID tag-based cable tool return management method of claim 7, wherein determining a return target location of each cable tool and inputting information of an RFID tag to be identified to a reader/writer provided for the return target location includes:

acquiring type parameters, shape parameters and using heat parameters of each cable tool;

determining a return target tool cabinet of each cable tool and a target slot position in the target tool cabinet according to the type parameter, the shape parameter and the using heat parameter;

and writing the information of the RFID tag of the pre-returning cable tool of the target slot into a reader-writer of the target slot.

10. An electronic device comprising a processor, a memory and a program or instruction stored on the memory and executable on the processor, which when executed by the processor, implements the steps of the RFID tag-based cable tool return management method according to any one of claims 7-9.