CN115002226B - Intelligent cable monitoring system capable of reporting sensor data in time-sharing mode - Google Patents

Abstract

The embodiment of the invention discloses a smart cable monitoring system for reporting sensor data in a time-sharing way, wherein a main server is configured to acquire sensor device information of acquisition nodes, and determine the time-sharing reporting communication time of each sensor parameter according to the sensor device information; the main server is configured to respectively send the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node; each collection node is configured to wake up at the received reporting communication time sent by the main server, collect corresponding sensor data during the wake up period and report the sensor data to an intermediate node, and the intermediate node is configured to process information according to the received reporting communication time sent by the main server and send the processed information to the main server for displaying monitoring results. According to the scheme, the power consumption of the node equipment is obviously reduced, and reasonable and effective monitoring of cable parameters is ensured.

Description

Intelligent cable monitoring system capable of reporting sensor data in time-sharing mode

Technical Field

The embodiment of the application relates to the technical field of cables, in particular to an intelligent cable monitoring system for time-sharing reporting of sensor data.

Background

Along with the development of the Internet of things and the intelligent equipment, the intelligent cable has higher and higher popularity, and replaces the original traditional cable in many scenes. In the existing intelligent cable monitoring process, along with the increase of monitoring parameters, the number of sensor integration is also increased, and the existing data transmission mode causes the excessively high electric quantity consumption of node equipment and needs improvement.

In the related art, as disclosed in publication number CN104050793a, an intelligent online monitoring and early warning system for the cable operation condition is provided, which comprises a monitoring terminal and a monitoring center main station, wherein the monitoring terminal collects various monitoring parameters (grounding current of a cable metal sheath, cable joint temperature, combustible gas content, toxic gas content, oxygen content, smoke, water level, well cover theft prevention and the like) of the cable operation condition in real time, and reports collected data to the monitoring center main station through a wireless network at fixed time; the monitoring center main station timely stores, counts, analyzes, displays and processes the reported collected data, and has the functions of comprehensive data collection of cable operation, real-time monitoring of operation states, image data display, fault early warning and alarming, statistical analysis of information data and the like. However, under the condition that the number of sensors integrated by the intelligent cable is large, data cannot be reported efficiently, so that the electric quantity consumption of each node is saved, and meanwhile, the reliability of monitoring is ensured.

Disclosure of Invention

The embodiment of the invention provides an intelligent cable monitoring system for reporting sensor data in a time-sharing way, and a reasonable data reporting method, which obviously reduces the power consumption of node equipment and ensures reasonable and effective monitoring of cable parameters.

In a first aspect, an embodiment of the present invention provides a smart cable monitoring system for time-sharing reporting of sensor data, where the system includes:

the system comprises a main server, a monitoring system and a monitoring system, wherein the main server is configured to acquire sensor device information of an acquisition node, and determine time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data;

the main server is configured to respectively send the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections;

each acquisition node is configured to wake up at the received reporting communication time sent by the main server, acquire corresponding sensor data during the wake up period and report the sensor data to the intermediate node,

and the intermediate node is configured to process information according to the received reporting communication time sent by the main server and send the information to the main server for displaying the monitoring result.

Optionally, the main server is configured to:

determining the position of each acquisition node and sensor parameters according to the sensor device information;

reporting intervals of each acquisition node are determined according to the positions of the acquisition nodes and the preset position reporting distribution relation;

and generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval.

Optionally, the intermediate node is configured to:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

Optionally, the intermediate node is configured to:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

In a second aspect, an embodiment of the present invention further provides a method for monitoring a smart cable for time-sharing reporting of sensor data, including:

the method comprises the steps that a main server obtains sensor device information of acquisition nodes, and time-sharing reporting communication time of each sensor parameter is determined according to the sensor device information, wherein the acquisition nodes are used for monitoring corresponding cable data;

the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections;

each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results.

Optionally, the determining the time-sharing reporting communication time of each sensor parameter according to the sensor device information includes:

determining the position of each acquisition node and sensor parameters according to the sensor device information;

reporting intervals of each acquisition node are determined according to the positions of the acquisition nodes and the preset position reporting distribution relation;

and generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval.

Optionally, the intermediate node performs information processing according to the received reporting communication time sent by the main server, including:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

Optionally, the filtering the sensor data includes:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

In a third aspect, an embodiment of the present invention further provides a smart cable monitoring device for time-sharing reporting of sensor data, where the device includes:

one or more processors;

storage means for storing one or more programs,

and when the one or more programs are executed by the one or more processors, the one or more processors realize the intelligent cable monitoring method for reporting the sensor data in a time-sharing way.

In a fourth aspect, the embodiment of the present invention further provides a storage medium storing computer executable instructions, where the computer executable instructions when executed by a computer processor are used to perform the smart cable monitoring method for time-sharing reporting of sensor data according to the embodiment of the present invention.

In the embodiment of the invention, a main server acquires sensor device information of an acquisition node, and determines time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data; the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections; each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results. According to the scheme, the power consumption of the node equipment is obviously reduced, and reasonable and effective monitoring of cable parameters is ensured.

Drawings

Fig. 1 is a flowchart of a smart cable monitoring method for reporting sensor data in a time-sharing manner according to an embodiment of the present invention;

FIG. 2 is a flowchart of another smart cable monitoring method for time-sharing reporting of sensor data according to an embodiment of the present invention;

fig. 3 is a block diagram of a module structure of an intelligent cable monitoring system for reporting sensor data in a time-sharing manner according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of an intelligent cable monitoring device for reporting sensor data in a time-sharing manner according to an embodiment of the present invention.

Detailed Description

Embodiments of the present invention will be described in further detail below with reference to the drawings and examples. It should be understood that the particular embodiments described herein are illustrative only and are not limiting of embodiments of the invention. It should be further noted that, for convenience of description, only some, but not all of the structures related to the embodiments of the present invention are shown in the drawings.

Fig. 1 is a flowchart of a smart cable monitoring method for reporting sensor data in a time-sharing manner, which is provided by the embodiment of the invention, and specifically includes the following steps:

step S101, a main server acquires sensor device information of an acquisition node, and time-sharing reporting communication time of each sensor parameter is determined according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data.

In one embodiment, the main server may be a device server corresponding to the system monitoring total platform, and the device server acquires information of the sensor devices of the collection nodes and performs unified allocation of reporting communication time of the collection nodes. Each collection node is used for monitoring corresponding cable data, such as a collection node implanted in an inner joint of a smart cable or monitoring the surface temperature of the smart cable, and is an exemplary low-power consumption monitoring device of a small-sized internet of things with a temperature sensor. Optionally, an acquisition node may be set in the smart cable at intervals, so as to monitor the whole line of the cable through each acquisition node. The monitored cable data may be, for example, temperature data, tension data, etc. of the cable, which are collected by a sensor device integrated inside the collection node.

In one embodiment, when each acquisition node performs data reporting, a time-sharing reporting mode is adopted, wherein the master server determines the time-sharing reporting communication time of each sensor parameter according to the sensor device information. Optionally, the determining method includes: determining the position of each acquisition node and sensor parameters according to the sensor device information; reporting intervals of each acquisition node are determined according to the positions of the acquisition nodes and the preset position reporting distribution relation; and generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval. The sensor device information comprises the positions of the acquisition nodes and sensor parameters, such as the corresponding positions of each acquisition node and the corresponding acquired sensor parameters of each acquisition node, through the information record of the sensor device, the main server can analyze the sensor device information after acquiring the sensor device information to obtain the positions of the acquisition nodes and the sensor parameters. The position comprises specific geographic position information and relative position information among intelligent cables, sensor parameters are data type parameters acquired by specific sensors, such as temperature parameters, tension parameters and the like, and different acquisition nodes can acquire different types of data, namely, different sensor parameters are provided. The reporting interval of each collecting node is determined according to the position of each collecting node and the reporting distribution relation of the preset position, namely, the reporting distribution relation is preset for different positions, and the reporting interval is set for positions close to the cable connector, and other reporting intervals are set for positions far away from the cable connector, wherein the different reporting intervals correspond to different reporting time periods. Taking a reporting interval of a cable connector position as an example, for a day as a reporting period, the reporting interval comprises a plurality of (e.g. 5) reporting intervals, wherein the reporting intervals are respectively exemplified by a 0-point interval, a 6-point interval, a 12-point interval, a 16-point interval and a 21-point interval, and the duration of each interval is exemplified by 5 minutes; for reporting intervals of non-cable joint positions, for a day, reporting periods are included, which include a plurality of (e.g., 3) reporting intervals, and are exemplified as 10-point intervals, 16-point intervals, and 20-point intervals, respectively.

In another embodiment, the preset position reporting distribution relationship may also be different reporting intervals that are equally set for a single intelligent cable line. For example, 24 reporting intervals are respectively set, and each reporting interval corresponds to each whole point time, and for the acquisition nodes of the intelligent cable, the 24 reporting intervals are sequentially allocated according to the sequence, for example, the reporting interval of the first acquisition node is 0 point, the reporting interval of the second acquisition node is 1 point, the reporting time of the third acquisition node is 2 points, and so on.

After determining the reporting interval of the acquisition nodes, generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval. Optionally, when a plurality of sensors exist for the acquisition node, for example, when the acquisition node includes a temperature sensor and a tension sensor, corresponding reporting time nodes are respectively determined for different sensor parameters in reporting intervals, for example, a 16-point reporting interval is taken as an example, each reporting interval lasts for 10 minutes, namely, the reporting intervals are divided into 16-point reporting intervals from 15 points 55 to 16 points 05, the reporting intervals are equally divided according to the number of the sensor parameters, for example, 2 sensor parameters (temperature parameters and tension parameters) divide the 16-point reporting interval into 2 time points respectively from 15 points 55 to 16 points as one time point to 16 points 05 as one time point, the first time point reports the temperature parameters, and the second time point reports the tension parameters.

Step S102, the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections.

In one embodiment, after determining the reporting communication time of each collection node, the master server sends the reporting communication time to each corresponding collection node and an intermediate node associated with the collection node. Each intermediate node corresponds to a plurality of acquisition nodes, for example, the intermediate nodes are arranged in the area where a plurality of adjacent acquisition nodes are located, so that data collection of the plurality of acquisition nodes in the area is performed, and the data are reported to a main server in a centralized manner.

Step S103, each acquisition node wakes up at the received reporting communication time sent by the main server, and acquires and reports corresponding sensor data to an intermediate node during the wake-up period, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results.

In one embodiment, after each acquisition node receives the reporting communication time sent by the main server, each acquisition node wakes up at the reporting communication time, and acquires and reports corresponding sensor data to the intermediate node during the wake-up period. And the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying the monitoring result.

Optionally, the intermediate node performs information processing according to the received reporting communication time sent by the main server, including: the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server; and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data. The continuous wake-up time is a union set of wake-up times of the corresponding acquisition nodes, namely, the continuous wake-up time comprises wake-up times covering the acquisition nodes. After receiving the sensor data sent by each acquisition node, the intermediate node performs screening processing on the sensor data so as to screen out part of useless data.

Specifically, the method comprises the following steps: determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold; and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions. The preset range is a range formed by corresponding acquisition nodes in the area set by the intermediate node. Firstly, determining nodes meeting reporting conditions in a mode that sensor data exceeds a preset sensor data threshold, such as temperature data uploaded by a certain acquisition node exceeds a set temperature threshold. In the nodes meeting the reporting condition, for example, if the temperature data reported by the adjacent continuous 5 collecting nodes exceeds a preset threshold, the 5 collecting nodes are nodes meeting the reporting condition, and then the reporting nodes are further selected according to the distribution condition of the collecting nodes and the specific sensor values. Alternatively, the node with the highest temperature value in the 5 collection nodes may be used as the determined reporting node, or the collection node corresponding to the maximum interval value in the temperature distribution value curve may be determined as the reporting node according to the specific temperature value distribution condition. For example, for 6 acquisition nodes meeting the reporting condition, the temperature values are sequentially corresponding to 80 °,100 °, 70 °, 80 °, 120 ° and 90 °, and as the distribution of the temperature values of the acquisition nodes is known, the temperature values of the acquisition nodes are respectively two interval maxima, and the acquisition nodes corresponding to 100 ° and 120 ° are determined to be the final reporting node. Therefore, reasonable data screening is performed, and reported data has more pertinence and can be referred to.

From the above, the main server obtains the sensor device information of the acquisition node, and determines the time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring the corresponding cable data; the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections; each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results. According to the scheme, the power consumption of the node equipment is obviously reduced, and reasonable and effective monitoring of cable parameters is ensured.

Fig. 2 is a flowchart of another smart cable monitoring method for reporting sensor data in a time-sharing manner, which is provided in an embodiment of the present invention, and a specific and complete example is given as shown in fig. 2. The method specifically comprises the following steps:

step S201, a main server acquires sensor device information of acquisition nodes, positions and sensor parameters of the acquisition nodes are determined according to the sensor device information, a reporting interval of each acquisition node is determined according to the positions of the acquisition nodes and a preset position reporting distribution relation, and reporting time nodes of each sensor parameter of each acquisition node are generated in the reporting interval.

Step 202, the main server sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections.

Step 203, each collecting node wakes up at the received reporting communication time sent by the main server, and collects and reports the corresponding sensor data to the intermediate node during the wake-up period, where the intermediate node determines the continuous wake-up time according to the received reporting communication time sent by the main server.

Step S204, receiving sensor data sent by each acquisition node in the continuous awakening time, and determining nodes meeting reporting conditions in the acquisition nodes within a preset range, wherein the reporting conditions comprise that the sensor data exceeds a preset sensor data threshold value, and screening the reporting nodes according to the distribution condition of the acquisition nodes and specific sensor values in the nodes meeting the reporting conditions.

According to the scheme, the main server acquires sensor device information of the acquisition node, and determines time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data; the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections; each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results. According to the scheme, the power consumption of the node equipment is obviously reduced, and reasonable and effective monitoring of cable parameters is ensured.

Fig. 3 is a block diagram of a module structure of an intelligent cable monitoring system for reporting sensor data in a time-sharing manner, where the intelligent cable is used for executing the intelligent cable monitoring method for reporting sensor data in a time-sharing manner, provided by the embodiment of the invention, and has corresponding functional modules and beneficial effects of the execution method. As shown in fig. 3, the apparatus specifically includes: a main server 101, an acquisition node 102 and an intermediate node 103, wherein,

the main server 101 is configured to acquire sensor device information of an acquisition node, and determine time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data;

the main server 101 is configured to send the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, where different acquisition nodes correspond to the reporting communication time of different sections;

each collection node 102 is configured to wake up at the respective received reporting communication time sent by the main server, collect and report corresponding sensor data to the intermediate node during the wake up period,

the intermediate node 103 is configured to process information according to the received reporting communication time sent by the main server, and send the processed information to the main server for displaying the monitoring result.

According to the scheme, the main server acquires sensor device information of the acquisition node, and determines time-sharing reporting communication time of each sensor parameter according to the sensor device information, wherein the acquisition node is used for monitoring corresponding cable data; the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections; each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results. According to the scheme, the power consumption of the node equipment is obviously reduced, and reasonable and effective monitoring of cable parameters is ensured.

In one possible embodiment, the primary server is configured to:

determining the position of each acquisition node and sensor parameters according to the sensor device information;

reporting intervals of each acquisition node are determined according to the positions of the acquisition nodes and the preset position reporting distribution relation;

and generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval.

In one possible embodiment, the intermediate node is configured to:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

In one possible embodiment, the intermediate node is configured to:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

Fig. 4 is a schematic structural diagram of a smart cable monitoring device for time-sharing reporting of sensor data according to an embodiment of the present invention, where, as shown in fig. 4, the device includes a processor 201, a memory 202, an input device 203, and an output device 204; the number of processors 201 in the device may be one or more, one processor 201 being taken as an example in fig. 4; the processor 201, memory 202, input devices 203, and output devices 204 in the apparatus may be connected by a bus or other means, for example in fig. 4. The memory 202 is used as a computer readable storage medium for storing software programs, computer executable programs and modules, such as program instructions/modules corresponding to the smart cable monitoring method for time-sharing reporting of sensor data in the embodiment of the present invention. The processor 201 executes various functional applications and data processing of the device by running software programs, instructions and modules stored in the memory 202, that is, implements the above-described smart cable monitoring method for time-sharing reporting of sensor data. The input means 203 may be used to receive entered numeric or character information and to generate key signal inputs related to user settings and function control of the device. The output device 204 may include a display device such as a display screen.

The embodiment of the invention also provides a storage medium containing computer executable instructions, which when executed by a computer processor, are used for executing a smart cable monitoring method for time-sharing reporting of sensor data, the method comprises the following steps:

the method comprises the steps that a main server obtains sensor device information of acquisition nodes, and time-sharing reporting communication time of each sensor parameter is determined according to the sensor device information, wherein the acquisition nodes are used for monitoring corresponding cable data;

the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections;

each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results.

Optionally, the determining the time-sharing reporting communication time of each sensor parameter according to the sensor device information includes:

determining the position of each acquisition node and sensor parameters according to the sensor device information;

reporting intervals of each acquisition node are determined according to the positions of the acquisition nodes and the preset position reporting distribution relation;

and generating reporting time nodes of each sensor parameter of each acquisition node in the reporting interval.

Optionally, the intermediate node performs information processing according to the received reporting communication time sent by the main server, including:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

Optionally, the filtering the sensor data includes:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

It should be noted that, in the embodiment of the intelligent cable monitoring system device for reporting sensor data in a time-sharing manner, each unit and module included in the intelligent cable monitoring system device are only divided according to the functional logic, but are not limited to the above-mentioned division, so long as the corresponding functions can be realized; in addition, the specific names of the functional units are also only for distinguishing from each other, and are not used to limit the protection scope of the embodiments of the present invention.

Note that the above is only a preferred embodiment of the present invention and the technical principle applied. It will be understood by those skilled in the art that the embodiments of the present invention are not limited to the particular embodiments described herein, but are capable of numerous obvious changes, rearrangements and substitutions without departing from the scope of the embodiments of the present invention. Therefore, while the embodiments of the present invention have been described in connection with the above embodiments, the embodiments of the present invention are not limited to the above embodiments, but may include many other equivalent embodiments without departing from the spirit of the embodiments of the present invention, and the scope of the embodiments of the present invention is determined by the scope of the appended claims.

Claims (8)

1. The intelligent cable monitoring system capable of reporting sensor data in a time-sharing manner comprises a main server, an intermediate node and an acquisition node, and is characterized in that:

the system comprises a main server, a monitoring server and a monitoring server, wherein the main server is configured to acquire sensor device information of acquisition nodes, determine time-sharing reporting communication time of each sensor parameter according to the sensor device information, determine the position of each acquisition node and the sensor parameters according to the sensor device information, determine the reporting interval of each acquisition node according to the position of each acquisition node and a preset position reporting distribution relation, and generate reporting time nodes of each sensor parameter of each acquisition node in the reporting interval, wherein the acquisition nodes are used for monitoring corresponding cable data;

the main server is configured to respectively send the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections;

each acquisition node is configured to wake up at the received reporting communication time sent by the main server, acquire corresponding sensor data during the wake up period and report the sensor data to the intermediate node,

and the intermediate node is configured to process information according to the received reporting communication time sent by the main server and send the information to the main server for displaying the monitoring result.

2. The smart cable monitoring system of claim 1, wherein the intermediate node is configured to:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

3. The smart cable monitoring system of claim 2, wherein the intermediate node is configured to:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

4. The intelligent cable monitoring method for time-sharing reporting of sensor data is characterized by comprising the following steps of:

the method comprises the steps that a main server obtains sensor device information of acquisition nodes, time-sharing reporting communication time of each sensor parameter is determined according to the sensor device information, the position of each acquisition node and the sensor parameters are determined according to the sensor device information, a reporting interval of each acquisition node is determined according to the position of each acquisition node and a preset position reporting distribution relation, and reporting time nodes of each sensor parameter of each acquisition node are generated in the reporting interval, wherein the acquisition nodes are used for monitoring corresponding cable data;

the main server respectively sends the reporting communication time of each acquisition node to the corresponding acquisition node and the intermediate node associated with the acquisition node, wherein different acquisition nodes correspond to the reporting communication time of different sections;

each acquisition node wakes up at the received reporting communication time sent by the main server, acquires corresponding sensor data during the wake-up period and reports the sensor data to the intermediate node, and the intermediate node processes information according to the received reporting communication time sent by the main server and sends the information to the main server for displaying monitoring results.

5. The intelligent cable monitoring method for time-sharing reporting of sensor data according to claim 4, wherein the intermediate node performs information processing according to the received reporting communication time sent by the main server, and the method comprises the following steps:

the intermediate node determines continuous awakening time according to the received reported communication time sent by the main server;

and in the continuous awakening time, receiving sensor data sent by each acquisition node, and screening the sensor data.

6. The smart cable monitoring method of claim 5, wherein said screening said sensor data comprises:

determining nodes meeting reporting conditions in acquisition nodes within a preset range, wherein the reporting conditions comprise that sensor data exceeds a preset sensor data threshold;

and screening the reporting nodes according to the distribution condition of the acquisition nodes and the specific sensor values among the nodes meeting the reporting conditions.

7. A smart cable monitoring device for time-sharing reporting of sensor data, the device comprising: one or more processors; storage means for storing one or more programs which, when executed by the one or more processors, cause the one or more processors to implement the smart cable monitoring method of time-sharing reporting of sensor data as claimed in any one of claims 4 to 6.

8. A storage medium storing computer executable instructions which when executed by a computer processor are for performing the smart cable monitoring method of time-sharing reporting of sensor data as claimed in any one of claims 4 to 6.