CN116170709A

CN116170709A - Electronic networking control method

Info

Publication number: CN116170709A
Application number: CN202310322423.4A
Authority: CN
Inventors: 赵作磊; 徐乐
Original assignee: Uscbets Shanghai Network Technology Co ltd
Current assignee: Uscbets Shanghai Network Technology Co ltd
Priority date: 2023-03-29
Filing date: 2023-03-29
Publication date: 2023-05-26

Abstract

The application discloses an electronic networking control method, which comprises the steps of outputting a port ID read-write instruction to a corresponding port under the condition that first port change information is obtained; in the embodiment of the application, the state information of the patch cord of the changed port is directly obtained in the distribution frame control unit, the port information is sent to the management server after the instruction information of the management server is obtained, a scanner is not required to be arranged, communication interaction between the port and the management server is reduced, the uploading speed of the port information is improved, the management server can directly judge the connection legal state of the patch cord after the port information is obtained, and an instruction is output to display the connection legal state of the patch cord, so that the visualization of electronic networking control is realized.

Description

Electronic networking control method

Technical Field

The invention relates to the technical field of electronic wiring systems, in particular to an electronic networking control method.

Background

The electronic distribution frame is a system for managing the patch cords in the wiring in real time by adopting computer technology and electronic distribution equipment, and is mainly used for realizing the following functions: automatically detecting the link relation between the distribution frame and the jumper wire in real time; automatically generating a database of the detected link relation in real time; and automatically updating the database in real time according to the detected jump-connection change.

The electronic distribution frame system on the market consists of three layers of electronic distribution frames, scanners and management servers, wherein each scanner is connected with 24-48 distribution frames (576-1152 ports), the scanner adopts a polling mechanism to scan the port state of each distribution frame in real time and upload state information to the management server, and as all management and control are realized in the scanners, the scanner has complex logic and high price, and the following problems exist in engineering use:

1. the connection state of the port jumper wire is detected through the microswitch, the structure is complex, the detection sensitivity is affected after the jumper wire is plugged and pulled for a long time, and the disassembly, the assembly and the maintenance are inconvenient;

2. when one scanner is connected with a small number of distribution frames, equipment waste is caused;

3. when the scanner fails, all electronic distribution frames managed by the scanner can not be networked, so that multipoint faults are caused;

4. when one scanner is connected with more distribution frames, the polling time is longer, and the reading efficiency of the electronic distribution frames to the port state is lower;

5. when the port jumper information is changed, the communication between the management server and the corresponding port is complex, and the port jumper information interaction speed is slow due to the fact that one management server corresponds to a plurality of distribution frames.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the electronic networking control method with strong jumper detection stability and high response speed.

In order to achieve the above object, the present invention is achieved by the following technical scheme.

The application provides an electronic networking control method, which comprises the following steps of;

outputting a port ID read-write instruction to a corresponding port under the condition that the first port change information is obtained;

acquiring a port ID read-write result of a corresponding port and generating port information based on the first port change information and the port ID read-write result;

the first port change information includes a port number of a change port, and the port ID read-write result includes a jumper tag ID number corresponding to the change port.

Further defined, in the above electronic networking control method, the obtaining the first port change information specifically includes:

and after the micro switch on the distribution frame senses that the jumper wire is inserted into the port, the first port change information is generated.

Further defined, in the above electronic networking control method, the obtaining a port ID read-write result of the corresponding port specifically includes:

the method comprises the steps that an inductive contact on a distribution frame obtains a coupling state with an information module on a jumper;

outputting the port ID read-write result as a jumper tag ID number corresponding to the jumper wire if the coupling is established, and outputting the port ID read-write result as a jumper tag ID number which is not acquired if the coupling is not established.

Further defined, the electronic networking control method further includes, after generating the port information:

outputting second port change information to a main distribution frame control unit or a management server;

and outputting the port information to the main distribution frame control unit or the management server under the condition that the first instruction information of the main distribution frame control unit or the management server is acquired.

outputting first instruction information to a sub-distribution frame control unit under the condition that second port change information of the sub-distribution frame control unit is obtained;

acquiring port information output by the control unit of the sub-distribution frame, and outputting third port change information to a management server;

outputting the port information to the management server under the condition that the second instruction information of the management server is acquired;

the port information includes port numbers of the ports of the sub-distribution frame change and corresponding jumper tag ID numbers.

under the condition that second port change information or third port change information of the main distribution frame control unit is obtained, outputting first instruction information or second instruction information to the main distribution frame control unit;

Acquiring port information output by a control unit corresponding to the main distribution frame, and generating a judging result based on the port information;

outputting an instruction based on the judgment result;

the port information includes the port number of the main distribution frame or the sub distribution frame change port and the corresponding jumper tag ID number.

Further defined, in the above electronic networking control method, the generating a judgment result based on the port information specifically includes:

and comparing the port information with a preset standard library, and confirming whether the jumper type or the jumper tag ID number of the changed port has deviation.

Further defined, in the above electronic networking control method, the outputting the instruction based on the determination result specifically includes:

if the jumper type or the jumper tag ID number of the changed port is deviated from the standard stock, outputting the instruction as a warning instruction;

if the jumper type or the jumper tag ID number of the changed port is consistent with the standard library, outputting the instruction as an approval instruction;

the warning instruction is used for marking the corresponding change port.

The invention has at least the following beneficial effects:

1. the method comprises the steps that state information of a patch cord of a change port is directly obtained in a distribution frame control unit, the port information is sent to a management server after instruction information of the management server is obtained, a scanner is not required to be arranged, communication interaction between the port and the management server is reduced, uploading speed of the port information is improved, the management server can directly judge the connection legal state of the patch cord after the port information is obtained, and an instruction is output to display the connection legal state of the patch cord, so that visualization of electronic networking control is achieved;

2. The interaction of port change information and jumper information between the sub-distribution frames and the management server is realized through the transition of the main distribution frame, so that the workload of the management server for directly scanning all distribution frames is greatly reduced, and the acquisition efficiency of the port change information and the jumper information is improved.

Drawings

Fig. 1 is a schematic structural diagram of an electronic distribution frame according to an embodiment of the present application;

fig. 2 is a schematic exploded view of an electronic distribution frame according to an embodiment of the present disclosure;

fig. 3 is a schematic exploded view of an electronic distribution frame according to an embodiment of the present disclosure;

fig. 4 is a schematic structural diagram of an "electronic antenna 210" in the electronic distribution frame according to the embodiment of the present application;

fig. 5 is a schematic structural view of a "mounting frame 130" in the electronic distribution frame according to the embodiment of the present application;

fig. 6 is a schematic structural diagram of a "transition bracket 240" in the electronic distribution frame according to the embodiment of the present application;

fig. 7 is an enlarged schematic view of the "trigger 230" part of the electronic distribution frame according to the embodiment of the present application;

fig. 8 is a schematic structural diagram of a chip jumper according to an embodiment of the present application;

fig. 9 is a schematic structural diagram of a networking system according to an embodiment of the present application;

fig. 10 is a schematic structural diagram of a networking system according to an embodiment of the present application;

FIG. 11 is a schematic structural diagram of a networking system according to an embodiment of the present disclosure;

FIG. 12 is a schematic diagram of an electrical networking system according to an embodiment of the present disclosure;

fig. 13 is a schematic structural diagram of an electronic networking system according to an embodiment of the present application;

fig. 14 is a schematic flow chart of an electronic networking control method according to an embodiment of the present application;

fig. 15 is a schematic flow chart of an electronic networking control method according to an embodiment of the present application;

FIG. 16 is a flow chart of a method for controlling an electronic worksheet of a networking system according to an embodiment of the present application;

FIG. 17 is a flow chart of a method for controlling an electronic worksheet of a networking system according to an embodiment of the present application;

FIG. 18 is a flowchart of a method for controlling an electronic work order of a networking system according to an embodiment of the present disclosure;

fig. 19 is a flow chart of a method for controlling an electronic work order of a networking system according to an embodiment of the present application.

Reference numerals

The main distribution frame-A1, the sub distribution frame-A2, the distribution frame body-100, the bottom plate-110, the fixed lug-120, the mounting frame-130, the main frame body-131, the first caulking groove-132, the positioning groove-133, the antenna system-200, the electronic antenna-210, the antenna board-211, the micro switch-212, the sensing contact-213, the reinforcing plate-220, the trigger-230, the sliding plate-231, the abutting groove-232, the sensing protrusion-233, the transition bracket-240, the bracket body-241, the second caulking groove-242, the sliding groove-243, the detection hole-244, the identification strip-250, the covering plate-260, the management server-300, the scanner-400, the jumper plug-510 and the sensing pin-520.

Detailed Description

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 electronic networking control method provided by the embodiment of the application is described in detail below through specific embodiments and application scenes thereof with reference to the accompanying drawings.

An embodiment of the present application provides an electronic distribution frame, as shown in fig. 1-2, including an antenna system 200 and a distribution frame body 100 for mounting the antenna system 200.

At least one port is disposed on the distribution frame 100, and the antenna system 200 is provided with an intelligent information unit coupled to the port on the distribution frame 100, where the intelligent information unit is configured to scan the port on the distribution frame 11, so as to obtain jumper connection information of the port on the distribution frame 100.

As shown in fig. 3, the antenna system 200 includes a reinforcing plate 220 fixedly disposed on the distribution frame 100, the intelligent information unit includes an electronic antenna 210 fixedly disposed on an end surface of a side, far away from the distribution frame 100, of the reinforcing plate 220, the antenna system 200 further includes a transition support 240 disposed on a side, far away from the reinforcing plate 220, of the electronic antenna 210 and fixedly connected with the distribution frame 100, a marking strip 250 is fixedly disposed on an end surface of a side, far away from the reinforcing plate 220, of the transition support 240, the marking strip 250 is used for marking a position and a number of an upper port of the distribution frame 100, a covering plate 260 fixedly connected with the transition support 240 is disposed on a side, far away from the transition support 240, of the marking strip 250, and the covering plate 260 is made of a transparent material and is used for protecting the marking strip 250 and displaying marking contents of the marking strip 250.

In this embodiment of the application, adopt foretell electronic distribution frame, detect the jumper wire connection state information of port in real time through intelligent information unit, detect port jumper wire connection state through directly on electronic distribution frame to make can save external scanner, reduce equipment cost.

It is understood that the reinforcing plate 220 is mainly used to strengthen the overall strength of the electronic antenna 210, and can be made of bent iron or other rigid materials.

In a preferred embodiment, as shown in fig. 3 and 4, the electronic antenna 210 includes an antenna board 211 and a micro switch 212 disposed on the antenna board 211, where the micro switch 212 is disposed on the antenna board 211 and corresponds to a plurality of port positions on the distribution frame 100, and when a port on the distribution frame 100 is connected to a jumper, the micro switch 212 can be triggered, so that a jumper connection state of the port on the distribution frame 100 is obtained through a trigger result of the micro switch 212.

The intelligent information unit further comprises a plurality of triggering pieces 230 located between the electronic antenna 210 and the transition support 240, wherein the triggering pieces 230 are located at corresponding positions of the ports on the distribution frame 100 and can trigger the micro-switch 212 at the corresponding positions under the interference of the port connection jumpers.

The intelligent information unit further includes an indicator light disposed on the identification strip 250 and coupled to the electronic antenna 210, where the indicator light can output different types (different colors or different blinking manners) of indicator lights based on the jumper status of the port on the distribution frame 100, so as to implement indication or warning of the jumper status.

It is to be understood that the arrangement form of the indicator light is not limited to the above-mentioned one, and the indicator light can be directly arranged on the distribution frame 100 or the transition bracket 240, so long as the port jumper state can be displayed, and detailed description thereof is omitted.

In a preferred embodiment, as shown in fig. 3, the distribution frame 100 includes a base plate 110, and a mounting frame 130 and a fixing lug 120 fixedly disposed on the base plate 110, where the mounting frame 130 is used for connecting a reinforcing plate 220 and provided with a plurality of ports, and the reinforcing plate 220 is fixedly disposed on the fixing lug 120 by bolts.

In a preferred embodiment, as shown in fig. 5, the mounting frame 130 includes a main frame body 131, a positioning slot 133 for matching with the trigger member 230 is disposed on the main frame body 131 at a position corresponding to a port, and a first caulking groove 132 capable of being in caulking connection with the reinforcing plate 220 is disposed on an end surface of the main frame body 131 far from the bottom plate 110.

As shown in fig. 6 and 7, the transition support 240 includes a support main body 241, a sliding groove 243 capable of being slidably connected with the trigger 230 is provided on a position corresponding to the trigger 230 on the support main body 241, and a second caulking groove 242 capable of being caulked with the identification strip 250 is provided on an end surface of the support main body 241, which is far from the distribution frame 100.

As shown in fig. 7, the trigger member 230 includes a sliding plate 231 slidably disposed in the sliding groove 243, a supporting groove 232 is disposed on the sliding plate 231 in a penetrating manner, the micro switch 212 at a corresponding position on the antenna board 211 is located in the supporting groove 232, the triggering end abuts against the corresponding side inner wall of the supporting groove 232, the sliding plate 231 is also fixedly provided with a sensing protrusion 233 embedded in the corresponding position positioning groove 133, when the port on the mounting rack 130 is inserted into the jumper, the jumper abuts against the sensing protrusion 233 at the corresponding port position, the sliding plate 231 slides in the sliding groove 243 under the action of the jumper abutting, and meanwhile, the inner wall of the supporting groove 232 abuts against the sensing end of the micro switch 212, and the micro switch 212 triggers the jumper connection state of the port position.

It can be understood that the sliding direction of the sliding plate 231 in the sliding slot 243 is the same as the triggering direction of the sensing end of the micro switch 212, and the sensing end of the micro switch 212 is an elastic member, so that the triggering member 230 can be automatically reset under the action of the elastic force of the sensing end of the micro switch 212 after the port jumper is released.

In a preferred embodiment, as shown in fig. 1 to 3, 24 ports are provided on the distribution frame 100, 24 micro switches 212 and triggering members 230 are provided corresponding to the 24 ports, four transition supports 240 are provided, and each transition support 240 corresponds to 6 ports, so as to reduce the processing difficulty and facilitate the disassembly and maintenance of local faults.

In a preferred embodiment, the smart information unit further comprises a base unit disposed on the electronic antenna 210:

the DC socket is used for supplying power to the electronic distribution frame, and adopts a low-energy chip and a 5V1A power supply;

the voltage stabilizing chip is arranged at a position corresponding to the DC socket and used for stabilizing voltage of power supply;

the main control chip is used for sensing the jumper wire of the port position and recording and outputting the jumper wire connection information of the port;

the sensing contacts 213 are provided with a plurality of sensing contacts and are respectively positioned at corresponding positions of the upper port of the distribution frame body 100, are connected with the main control chip and are used for coupling the chip jumper with the main control chip;

the Type-C interface is coupled with the main control chip and is used for inputting or updating programs and also can be connected with mobile phone terminal software to check and control port information of the electronic distribution frame and the like;

the double-port RJ45 socket is used for cascading among a plurality of electronic distribution frames and POE power supply, the RJ45 socket is provided with 8 pins, 6 pins are used for data transmission, and 2 pins are used for power supply;

After any one of the electronic distribution frames is plugged into a DC power supply through a DC socket, POE power supply can be performed on the 11 electronic distribution frames through double-port RJ45 sockets at maximum.

The jumper wire is divided into a common jumper wire and a chip jumper wire, as shown in fig. 8, the chip jumper wire comprises a jumper plug part 510 and an induction needle 520 arranged on the jumper plug part 510, an information chip is arranged in the jumper plug part 510, the induction needle 520 is connected with the information chip in the jumper plug part 510, and the common jumper wire is not provided with the information chip and the corresponding induction needle 520.

As shown in fig. 4, a detection hole 244 is formed in the bracket main body 241 corresponding to the position 213, and a sensing needle 520 on the chip jumper can be connected with the sensing contact 213 by inserting into the detection hole 244, i.e. the chip jumper can be connected with the main control chip, and at this time, the main control chip can read the jumper connection information of the chip jumper, thereby monitoring the port state.

It can be understood that, whether a chip jumper or a common jumper is inserted into the port, the micro switch 212 can be triggered, and the trigger result of the micro switch 212 is only responsible for the jumper connection condition of the port, so that the specific jumper type cannot be judged, and the jumper type is directly read and judged by the main control chip through the sensing contact 213.

In this embodiment of the present application, by adopting the electronic distribution frame, an independent main control chip is designed in each intelligent information unit, and the jumper connection state of each port of the electronic distribution frame is scanned in real time by the main control chip, and as only 24 ports need to be managed by a single main control chip, the scanning speed is greatly improved.

In a preferred embodiment, the smart information unit further includes a network port chip and/or a crystal oscillator and a communication chip disposed on the electronic antenna 210 and located at a position corresponding to the main control chip.

It will be appreciated that the network port chip adopts the TCP/ip protocol, and is used for connecting to the management server 300, and the communication chip is mainly used for cascading between a plurality of electronic distribution frames.

the logic chips are provided with a plurality of indicating lamps, each logic chip is coupled with the indicating lamps at four port positions, and the logic chips are used for controlling the corresponding indicating lamps to be turned on based on port jumper connection information output by the main control chip;

the distribution frame 100 is provided with 24 ports, the logic chips are correspondingly provided with 6 logic chips, and the 6 logic chips are respectively positioned at the 2 nd, 6 th, 10 th, 14 th, 18 th and 22 nd indicator lamps.

The embodiment of the present application provides a networking system, as shown in fig. 9, including a main distribution frame A1 and a management server 300 connected to the main distribution frame A1, where the main distribution frame A1 adopts the above-mentioned electronic distribution frame structure.

The intelligent information unit of the main distribution frame A1 comprises a micro switch 212 for detecting the connection state of the port jumper, an induction contact 213 for detecting and judging the common jumper and the chip jumper, a network port chip and a communication chip.

The main distribution frame A1 is directly connected with the management server 300 through the double-port RJ45 socket for networking, plug and play is realized, and networking is flexible and convenient.

In this embodiment of the present application, the above networking system is adopted, and an electronic distribution frame and a management server 300 are adopted, so that a scanner 400 is not required to be additionally arranged, and not only can a common jumper be detected, but also a chip jumper can be detected, thereby reducing the use cost of the system and enabling networking to be more flexible.

In a preferred embodiment, as shown in fig. 10, a plurality of main distribution frames A1 are arranged in series, wherein one main distribution frame A1 is directly connected to the management server 300 through a dual-port RJ45 socket, thereby forming a network.

It will be appreciated that one of the main distribution frames A1 is connected to a power source via a DC jack and the other main distribution frames A1 are connected in series via a dual port RJ45 jack and POE powered.

In this embodiment of the present application, the networking system is adopted, and networking is achieved by connecting multiple main distribution frames A1 in series, each electronic distribution frame is independent, when equipment fails, the damage is only the current equipment, so that the failure nodes are reduced, and the scanner 400 is not added, so that the problem that all the electronic distribution frames connected with the scanner 400 cannot be used due to the damage of the scanner 400 is avoided.

In a preferred embodiment, as shown in fig. 11, the main distribution frame A1 is provided with a plurality of connection devices and is connected to the scanner 400 through dual-port RJ45 sockets, and the scanner 400 is directly connected to the management server 300, thereby forming a network.

In this embodiment of the present application, the above networking system is adopted, and the traditional three-layer architecture of the electronic distribution frame, the management server 300 and the scanner 400 is adopted, and since the main control chip scans 24 ports on a single main distribution frame A1, the scanner 400 can directly obtain port state information on each port through the main control chip on a plurality of main distribution frames A1, so that the scanning amount of the scanner 400 is greatly reduced, and the scanning speed is improved.

The networking system further comprises a radar sensor, when a person is present, the networking system works, and after the radar sensor detects unmanned operation, the networking system enters a standby state, so that the overall service life of the networking system is prolonged.

The networking system further comprises a visual sensing unit, when the networking system has unauthorized operation, the visual sensing unit photographs or records videos and sends the videos to the management server 300, so that monitoring and recording of illegal operation are realized.

The embodiment of the present application further provides a networking system, as shown in fig. 12, including a main distribution frame A1, a sub distribution frame A2, and a management server 300 connected to the main distribution frame A1, where the main distribution frame A1 and the sub distribution frame A2 adopt the above-mentioned electronic distribution frame structure.

The intelligent information units of the main distribution frame A1 and the sub distribution frame A2 comprise micro switches 212 used for detecting the connection state of port jumpers and sensing contacts 213 used for detecting and judging common jumpers and chip jumpers.

The main distribution frame A1 further includes a network port chip and a communication chip, and the sub distribution frame A2 is not provided with the network port chip and is only provided with the communication chip.

The main distribution frame A1 and the sub distribution frame A2 are connected in series through a dual-port RJ45 socket, and one main distribution frame A1 is directly connected with the management server 300 through the dual-port RJ45 socket, so as to form a network.

It will be appreciated that one of the main distribution frame A1 or the sub distribution frame A2 is connected to a power source via a DC outlet, and the other main distribution frame A1 or sub distribution frame A2 is POE powered via a dual port RJ45 outlet.

It can be understood that, since the scanner 400 is not provided and the main distribution frame A1 is provided with a network port chip, the main distribution frame A1 can be connected to the management server 300, the main distribution frame A1 and the sub distribution frame A2 realize information transmission through the communication chip, and the sub distribution frame A2 does not contain a network port chip, so that it cannot be separately connected to the management server 300.

It will be appreciated that the main distribution frame A1 or the sub distribution frame A2 can also be configured to include only the micro switch 212, and the sensing contacts 213 are omitted, so that the access to the port jumper connection state can be achieved through the micro switch 212, but the access cannot be directed to the common jumper. And the chip jumper wire is used for distinguishing judgment.

It will be appreciated that the main distribution frame A1 or the sub distribution frame A2 can also be configured to include only the sensing contacts 213, and omit the micro switch 212, so that the distribution frame can only acquire the port connection information of the chip jumper, and is suitable for the connection scenario of a single chip jumper.

In the embodiment of the application, the networking system is adopted, and the combination of the main distribution frame A1 and the sub distribution frame A2 is selected to realize the detection of different types of jumpers, so that the networking flexibility is improved while the cost is controlled.

In a preferred embodiment, as shown in fig. 13, the sub-distribution frame A2 is provided with a plurality of sub-distribution frames and is connected to the scanner 400 through dual-port RJ45 sockets, respectively, and the scanner 400 is directly connected to the management server 300, thereby forming a network.

It can be understood that, although the sub-distribution frame A2 does not contain a network port chip, connection can be achieved with the management server 300 through the scanner 400, and the scanner 400 can directly obtain port status information on each port through the main control chips on the plurality of sub-distribution frames A2, so that the scanning amount of the scanner 400 is greatly reduced, and the scanning speed is improved.

The embodiment of the application also provides an electronic networking control method, as shown in fig. 14, including:

s1, after a main distribution frame is inserted into a jumper, a corresponding port outputs first port change information to a main distribution frame control unit;

s2, after receiving the first port change information, the main distribution frame control unit outputs a port ID read-write instruction to a corresponding port, and the corresponding port outputs a port ID read-write result to the main distribution frame control unit under the condition that the port ID read-write instruction is received;

s3, after receiving the port ID read-write result, the main distribution frame control unit outputs second port change information to the management server;

s4, after receiving the second port change information, the management server outputs first instruction information to the main distribution frame control unit, and the main distribution frame control unit outputs port information to the main distribution frame control unit under the condition that the first instruction information is received;

S5, the management server generates a judging result based on the port information after receiving the port information, and outputs an instruction to the electronic networking system based on the judging result.

In step S1, the first port change information is specifically induction information generated by the micro switch on the main distribution frame based on jumper insertion trigger;

in step S2, after the main distribution frame control unit receives the first port change information, the change condition of the main distribution frame port is obtained, so that a port ID read-write instruction is output to the port with the changed jumper connection state, so that the corresponding port is controlled to perform scanning on the jumper type, the scanning result can determine whether the jumper is a common jumper or a chip jumper, and the port ID read-write result is output to the main distribution frame control unit based on the scanning result, and it can be understood that the port ID read-write result includes two cases, namely, the case one is that the jumper tag ID number is obtained, the jumper type is determined to be the chip jumper at this time, the case two is that the jumper tag ID number is not obtained, and the jumper type is determined to be the common jumper at this time;

in step S3, after receiving the port ID read-write result, the main distribution frame control system outputs second port change information to the management server, where the second port change information is used to inform the management server of a port jumper change condition, so as to trigger a subsequent control instruction of the management server;

In step S4, the main distribution frame control unit outputs port information to the main distribution frame control unit after receiving the first instruction information, where the port information includes a changed port number and a jumper type, and if the jumper type is a chip jumper, the main distribution frame control unit further includes a corresponding jumper tag ID number;

in step S5, after receiving the port information, the management server compares the port information with a preset standard library, if the jumper type or the jumper tag ID number has a deviation, a warning instruction is output to the electronic networking system, otherwise, an approval instruction is output, and the electronic networking system executes a corresponding instruction action based on the instruction output by the management server.

In the embodiment of the application, the electronic networking control method is adopted to directly scan and acquire the state information of the port jumper in the main distribution frame control unit, send the port information to the management server after acquiring the instruction information of the management server without arranging a scanner, the management server can directly judge the connection legal state of the jumper after acquiring the port information, realize the display of the connection legal state of the jumper through the electronic networking system, reduce the communication interaction between the port and the management server, improve the uploading speed of the port information, realize the identification and the connection legal indication of the common jumper and the chip jumper, improve the visualization of the electronic networking control,

In a preferred embodiment, the common jumper is inserted into the main distribution frame, so that the micro switch level is triggered to be changed from high to low, and then the external interrupt of the falling edge of the corresponding port of the main distribution frame MCU is triggered, the main distribution frame MCU recognizes that the jumper is inserted, sends a port ID read-write command to the corresponding port, and after the port ID read-write result is obtained, the condition that no jumper tag ID number returns is found, so that the common jumper is recognized as the common jumper insertion.

The main distribution frame MCU reports port change information to the management server through the network port, and after receiving the port change information, the management server sends instruction information to the main distribution frame MCU through the network port, and the main distribution frame MCU receives the network port interruption and reports port information of a corresponding port.

After receiving the port information, the management server identifies the port information as the insertion of a common jumper, generates an illegal insertion alarm, displays the illegal insertion alarm in a main UI interface, simultaneously issues the alarm to a main distribution frame MCU through a network port, analyzes the port number in the alarm after receiving the alarm command, writes the port number into a display screen through an SPI bus, displays the alarm information on the screen, and simultaneously lights a red LED indicator lamp of a corresponding port.

In a preferred embodiment, the chip jumper is inserted into the main distribution frame, so that the micro switch level is triggered to be changed from high to low, and then the external interrupt of the falling edge of the corresponding port of the main distribution frame MCU is triggered, the main distribution frame MCU recognizes that the jumper is inserted, sends a port ID read-write command to the corresponding port, obtains the jumper tag ID number of the corresponding port after the port ID read-write result is obtained, and recognizes the jumper as the chip jumper.

After receiving the port information, the management server identifies the port information as chip jumper insertion, extracts the port number and the corresponding jumper tag ID number, compares the port number with the jumper tag ID number stored in the standard library in advance at the current management server, generates illegal insertion alarm if the port information is inconsistent with the jumper tag ID number, displays the illegal insertion alarm in a main UI interface, simultaneously issues the alarm to a main distribution frame MCU through a network port, analyzes the port number after receiving the alarm command, writes the alarm command into a display screen through an SPI bus, displays the alarm information on the screen, and simultaneously lights a red LED indicator lamp of the corresponding port.

The embodiment of the application also provides an electronic networking control method, as shown in fig. 15, including:

s1, after a sub-distribution frame is inserted into a jumper, a corresponding port outputs first port change information to a sub-distribution frame control unit;

s2, after receiving the first port change information, the sub-distribution frame control unit outputs a port ID read-write instruction to a corresponding port, and the corresponding port outputs a port ID read-write result to the sub-distribution frame control unit under the condition that the port ID read-write instruction is received;

S3, the sub-distribution frame control unit receives the port ID read-write result and outputs second port change information to the main distribution frame control unit;

s4, the main distribution frame control unit receives the second port change information and then outputs first instruction information to the sub distribution frame control unit, and the sub distribution frame control unit outputs port information to the main distribution frame control unit under the condition that the sub distribution frame control unit receives the first instruction information;

s5, the main distribution frame control unit receives the port information and then outputs third port change information to the management server;

s6, after receiving the change information of the third port, the management server outputs second instruction information to the main distribution frame control unit, and the main distribution frame control unit outputs port information to the main distribution frame control unit after receiving the second instruction information;

and S7, after receiving the port information, the management server generates a judging result based on the port information, and outputs an instruction to the electronic networking system based on the judging result.

The main distributing frame is directly connected with the management server, and the main distributing frame is connected with at least one sub distributing frame.

In the embodiment of the application, the electronic networking control method is adopted, the interaction of port change information and jumper information between the sub-distribution frames and the management server is realized through the transition of the main distribution frame, and the plurality of sub-distribution frames are connected through one main distribution frame, so that the workload of the management server for directly scanning all distribution frames is reduced, and the acquisition efficiency of the port change information and the jumper information is improved.

In a preferred embodiment, the common jumper is inserted into the sub-distribution frame, so that the micro-switch level is triggered to be changed from high to low, and then the external interrupt of the falling edge of the port corresponding to the sub-distribution frame MCU is triggered, the sub-distribution frame MCU recognizes that the jumper is inserted, sends a port ID read-write instruction to the corresponding port, and after the port ID read-write result is obtained, the fact that no jumper tag ID number returns is found, so that the common jumper is recognized as the common jumper insertion.

The method comprises the steps that a sub-distribution frame MCU sends port change information to inform a main distribution frame MCU, the main distribution frame MCU receives serial port interruption, extracted information is identified as port change, then the sub-distribution frame MCU is informed of changing port numbers through serial port sending instruction information, the sub-distribution frame MCU receives serial port interruption, port numbers inserted by common jumpers are reported through serial ports, the main distribution frame MCU receives serial port interruption, port information in data is extracted, port change information is reported to a management server through a network port, the management server receives the port change information and then sends instruction information to the main distribution frame MCU through the network port, and the main distribution frame MCU receives the network port interruption and reports the port change information.

After receiving the port information, the management server identifies the port information as the insertion of a common jumper, generates an illegal insertion alarm, displays the illegal insertion alarm in a main UI interface, simultaneously issues the alarm to a main distribution frame MCU through a network port, writes the alarm information into a display screen through an SPI bus after receiving an alarm command, displays the alarm information on the screen, simultaneously issues the alarm information to a corresponding sub distribution frame MCU through a serial port, analyzes the port number in the alarm after receiving the alarm information, and lights a red LED indicator lamp of the corresponding port.

In a preferred embodiment, the chip jumper is inserted into the sub-distribution frame, so that the micro-switch level is triggered to be changed from high to low, and then the external interrupt of the falling edge of the corresponding port of the sub-distribution frame MCU is triggered, the sub-distribution frame MCU recognizes that the jumper is inserted, sends a port ID read-write instruction to the corresponding port, obtains the jumper tag ID number of the corresponding port after the port ID read-write result is obtained, and recognizes the jumper as the chip jumper.

The method comprises the steps that a sub-distribution frame MCU sends port change information to inform a main distribution frame MCU, the main distribution frame MCU receives serial port interruption, extracted information is identified as port change, then the sub-distribution frame MCU is informed of changing port numbers and jumper tag ID numbers through serial port sending instruction information, the sub-distribution frame MCU receives the serial port interruption, the main distribution frame MCU receives the serial port interruption through serial port reporting of inserting port numbers and jumper tag ID numbers of chip jumpers, port information in data is extracted, the port change information is reported to a management server through a network port, the management server receives the port change information and then sends instruction information to the main distribution frame MCU through the network port, and the main distribution frame MCU receives the network port interruption and reports the change port information.

After receiving the port information, the management server identifies the port information as chip jumper insertion, extracts the port number and the corresponding jumper tag ID number, compares the port number with the jumper tag ID number stored in the standard library in advance at the current management server, generates illegal insertion alarm if the port number is inconsistent with the jumper tag ID number, displays the illegal insertion alarm in a main UI interface, issues the alarm to a main distribution frame MCU through a network port, writes the alarm information into a display screen through an SPI bus after receiving the alarm command, and simultaneously issues the alarm information to a corresponding sub distribution frame MCU through a serial port, and analyzes the port number in the alarm after receiving the alarm information by the sub distribution frame MCU, and lights a red LED indicator lamp of the corresponding port.

The embodiment of the application also provides a method for controlling the electronic worksheet of the networking system, which comprises the following steps:

s1, a management server sends electronic work order information to a main distribution frame control unit, and the main distribution frame control unit extracts a change port number and a jumper tag ID number contained in the electronic work order information;

s2, the main distribution frame control unit outputs first indication information to a first target port on the main distribution frame based on the electronic work order information;

s3, when the first target port senses that a worker pulls out the jumper wire of the first target port, outputting first feedback information to the main distribution frame control unit;

s4, after the main distribution frame control unit acquires the first feedback information, outputting second indication information to a second target port on the main distribution frame;

s5, outputting second feedback information to the main distribution frame control unit after the second target port senses that the staff inserts the jumper in the second target port;

s6, after the main distribution frame control unit acquires the second feedback information, outputting a read-write instruction to a second target port on the main distribution frame;

s7, after receiving the read-write instruction, the second target port scans the jumper wire in the port, and directly outputs the jumper wire scanning result to the main distribution frame control unit;

S8, the main distribution frame control unit compares the acquired scanning result with the electronic work order information, if the comparison is not passed, an instruction is output to the second target port, the second target port sends an alarm after receiving the instruction, and if the comparison result is passed, a work order completion instruction is output to the management server.

It can be understood that the above steps are used for transposition of jumpers on the same main distribution frame, the first indication information and the second indication information are specifically expressed as indication conditions of the indication lamps on the corresponding ports, and the expression forms are not limited to changes of colors of the indication lamps, changes of flickering modes and the like.

In a preferred embodiment, a user issues a work order on a software interface, a management server issues corresponding electronic work order information to a main distribution frame MCU through a network port, the main distribution frame MCU analyzes the work order into a work order command, a port number and a jumper tag ID number contained in the work order are extracted, if the port number is changed in the main electronic distribution frame, a corresponding position light blue lamp before the port is changed is firstly turned on, after a person pulls out a jumper of the port, the micro switch level is changed from low to high, a rising edge external interrupt of the corresponding port of the main distribution frame MCU is triggered, the main distribution frame MCU identifies that a jumper is pulled out, further, a port blue LED lamp to be inserted is lightened, when the person inserts the jumper into the port, the micro switch level is changed from high to low, the descending edge external interrupt of the corresponding port of the main distribution frame is triggered, the main distribution frame MCU sends a jumper tag ID number reading command to the port, the tag ID number of the port is obtained, if the port ID number is changed in the port is not the same as the port ID number, the jumper is not pulled out, the micro switch level triggers the corresponding port to the rising edge of the port to be pulled out, the work order is triggered, and the work order management server completes a management order to finish a work order, and a work order is completed at the same time.

s4, after the main distribution frame control unit acquires the first feedback information, outputting second target information to the sub distribution frame control unit where the second target port is located;

s5, after receiving the second target information, the sub-distribution frame control unit outputs second indication information to the second target port;

s6, outputting second feedback information to the sub-distribution frame control unit after the second target port senses that the worker inserts the jumper in the second target port;

s7, after the sub-distribution frame control unit acquires the second feedback information, outputting a read-write instruction to the second target port;

S8, after receiving the read-write instruction, the second target port scans the jumper wire in the port, and directly outputs the jumper wire scanning result to the sub-distribution frame control unit;

s9, the sub-distribution frame control unit compares the acquired scanning result with the second target information, if the comparison is not passed, an instruction is output to the second target port, the second target port sends an alarm after receiving the instruction, if the comparison is passed, the main distribution frame control unit outputs the complete order information, and the main distribution frame control unit outputs a work order completion instruction to the management server after receiving the complete order information.

It can be understood that the above steps are used for the jumper wire on the main distribution frame to perform transposition to the sub distribution frame connected with the jumper wire, and one main distribution frame can be connected with at least one sub distribution frame.

In a preferred embodiment, a work order is a work order, a port of a main distribution frame is switched to a port of a sub distribution frame, a blue light is firstly lighted at a corresponding position before the port on the main distribution frame changes, after a worker pulls out the jumper, the micro switch level is changed from low to high, the rising edge external interrupt of the corresponding port of the main distribution frame MCU is triggered, the main distribution frame MCU recognizes that the jumper has been pulled out, then a work order command, a port number to be inserted and a jumper tag ID are issued to the corresponding sub distribution frame MCU through the serial port, the corresponding sub distribution frame MCU receives serial port interrupt, serial port information is extracted, the work order is recognized as the work order, meanwhile, the port number and the jumper tag ID are extracted, a blue LED light of the corresponding port is lighted, after the worker inserts the jumper into the port, the micro switch level is changed from high to low, the falling edge external interrupt of the corresponding port of the sub distribution frame MCU is triggered, the sub distribution frame MCU is compared with the jumper tag ID number contained in the work order after the sub distribution frame MCU is sent, if the work order is not consistent, the second target port to be triggered is not pulled out, the work order is received, the work order is recognized by the single-order is received through the corresponding sub distribution frame MCU, and the single-port management server is completed after the work order is completed, and the work order is completed is received by the single-order server is received, and the work order is completed by the single-order server is received.

s2, the main distribution frame control unit outputs first target information to the sub distribution frame control unit corresponding to the first target port based on the electronic work order information;

s3, the sub-distribution frame control unit outputs first indication information to the first target port based on the first target information;

s4, when the first target port senses that a worker pulls out the jumper wire of the first target port, outputting first feedback information to the sub-distribution frame control unit;

s5, the sub-distribution frame control unit receives the first feedback information and then outputs the first feedback information to the main distribution frame control unit;

s6, after the main distribution frame control unit acquires the first feedback information, outputting second indication information to a second target port on the main distribution frame;

s7, outputting second feedback information to the main distribution frame control unit after the second target port senses that the staff inserts the jumper in the second target port;

S8, after the main distribution frame control unit acquires the second feedback information, outputting a read-write instruction to a second target port on the main distribution frame;

s9, after receiving the read-write instruction, the second target port scans the jumper wire in the port, and directly outputs the jumper wire scanning result to the main distribution frame control unit;

s10, the main distribution frame control unit compares the acquired scanning result with the electronic work order information, if the comparison is not passed, an instruction is output to the second target port, the second target port sends an alarm after receiving the instruction, and if the comparison result is passed, a work order completion instruction is output to the management server.

It can be understood that the above steps are used for the jumper wire on the sub-distribution frame to be connected with the main distribution frame for transposition, and one main distribution frame can be connected with at least one sub-distribution frame.

The embodiment of the application also provides a method for controlling the electronic worksheet of the networking system, as shown in fig. 19, including:

S2, the main distribution frame control unit outputs first target information to a first sub distribution frame control unit corresponding to a first target port based on the electronic work order information;

s3, the first sub-distribution frame control unit outputs first indication information to the first target port based on the first target information;

s4, after the first target port senses that a worker pulls out the jumper wire of the first target port, outputting first feedback information to the first sub-distribution frame control unit;

s5, the first sub-distribution frame control unit receives the first feedback information and then outputs the first feedback information to the main distribution frame control unit;

s6, after the main distribution frame control unit acquires the first feedback information, outputting second target information to a second sub distribution frame control unit where a second target port is located;

s7, after receiving the second target information, the second sub-distribution frame control unit outputs second indication information to the second target port;

s8, outputting second feedback information to the second sub-distribution frame control unit after the second target port senses that the worker inserts the jumper in the second target port;

s9, after the second feedback information is acquired by the second sub-distribution frame control unit, a read-write instruction is output to the second target port;

S10, after receiving the read-write instruction, the second target port scans the jumper wire in the port, and directly outputs the jumper wire scanning result to the second sub-distribution frame control unit;

s11, the second sub-distribution frame control unit compares the acquired scanning result with second target information, if the comparison is not passed, an instruction is output to the second target port, the second target port sends an alarm after receiving the instruction, if the comparison is passed, the main distribution frame control unit outputs the complete order information, and the main distribution frame control unit outputs a work order completion instruction to the management server after receiving the complete order information.

It can be understood that the above steps are used for jumper wire transposition on two sub-distribution frames, the two sub-distribution frames are connected with the same main distribution frame, and through the above steps, the jumper wire can be indicated, detected and monitored in the transferring process between the two sub-distribution frames.

According to the electronic work order control method of the networking system, the control units are arranged in the main distribution frame and the sub distribution frames, when the jumper connection state on the distribution frames changes, the state indication and detection check of the jumper are directly executed in the control units, the scanning and identification actions of the scanner on a plurality of ports in the traditional electronic work order process are omitted, the complicated communication degree in the jumper switching process between the distribution frames is reduced, and therefore the control efficiency is greatly improved while the accuracy of the electronic work order is guaranteed.

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.

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.

Claims

1. An electronic networking control method is characterized by comprising the following steps of;

2. The electronic networking control method according to claim 1, wherein the obtaining the first port change information is specifically:

3. The electronic networking control method according to claim 1, wherein the obtaining the port ID read-write result of the corresponding port specifically includes:

4. A method of electronic networking control according to any one of claims 1 to 3, further comprising, after generating a port message:

5. An electronic networking control method is characterized by comprising the following steps of;

6. An electronic networking control method is characterized by comprising the following steps:

Outputting an instruction based on the judgment result;

7. The method of claim 6, wherein generating a determination result based on the port information is specifically:

8. The electronic networking control method according to claim 7, wherein outputting an instruction based on the judgment result is specifically:

the warning instruction is used for marking the corresponding change port.