CN117273403A - Intelligent guarantee power dispatching system, method, computer equipment and storage medium - Google Patents

Abstract

The invention discloses an intelligent guarantee power dispatching system, an intelligent guarantee power dispatching method, computer equipment and a storage medium, and belongs to the field of power dispatching; the system comprises a data acquisition module, a dispatching control center, a dispatching management module and a server; starting from historical detection power consumption data of the power monitoring points mi, screening monitoring points needing power detection from the monitoring points of a plurality of target areas through calculation of power detection values, and greatly reducing the task amount of detection of the plurality of target areas; in addition, the electric power monitoring points needing to be subjected to electric power detection are selected by electric power inspection personnel, the electric power inspection personnel are initially selected from the sleeping condition and the fatigue condition of the electric power inspection personnel, and the most suitable electric power inspection personnel are selected to perform work task allocation in consideration of the safety and the personal care of the electric power detection; the same power detection personnel are prevented from being scheduled for multiple times, and meanwhile, the scheduling of all the power detection personnel is fair and fair.

Description

Intelligent guarantee power dispatching system, method, computer equipment and storage medium

Technical Field

The invention belongs to the field of power dispatching, and particularly relates to an intelligent guarantee power dispatching system, an intelligent guarantee power dispatching method, computer equipment and a storage medium.

Background

The power dispatching is an effective management means for ensuring safe and stable operation of the power grid, external reliable power supply and orderly execution of various power production works. The specific work content of the power dispatching is that according to data information fed back by various information acquisition devices or information provided by monitoring personnel, the actual operation parameters of the power grid, such as voltage, current, frequency, load and the like, are combined, the development condition of various production works is comprehensively considered, the safe and economic operation state of the power grid is judged, and an operation instruction is issued through a telephone or an automatic system to command on-site operators or an automatic control system to adjust, such as adjusting the output of a generator, adjusting the load distribution, switching capacitors, reactors and the like, so that the continuous safe and stable operation of the power grid is ensured.

In the power dispatching management system, when monitoring personnel perform data feedback, the monitoring personnel often need to perform data feedback after a plurality of power inspection points are inspected, but because the technology is increasingly advanced, power equipment of the plurality of power inspection points can safely and stably run for a long time, each power inspection point does not need to be inspected every time, a larger inspection period can be set, and the power inspection points which are easy to fail or have other problems need to be inspected for a plurality of times; the problem of large power inspection workload is easily caused without sorting inspection points, and reasonable arrangement is also required for arrangement of power inspection personnel.

Therefore, the invention provides an intelligent guarantee power dispatching system, an intelligent guarantee power dispatching method, computer equipment and a storage medium.

Disclosure of Invention

The purpose of the application is to provide intelligent guarantee power dispatching system, method, computer equipment and storage medium, solved among the prior art electric power patrol workload big and electric power patrol personnel arrange and have unreasonable phenomenon's problem.

In order to achieve the above purpose, the application provides an intelligent guarantee power dispatching system, which comprises a data acquisition module, a dispatching control center, a dispatching management module and a server;

the data acquisition module is used for acquiring the electricity consumption of the electric equipment and sending the electricity consumption to the server for storage; the dispatching control center is in remote wireless connection with the server;

the dispatching control center is used for acquiring the electricity information stored in the server and sending dispatching inspection signals, and the working process of the dispatching control center comprises the following steps:

step one: dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas; each target area comprises a plurality of power monitoring points, and the data acquisition module marks the power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; marking the power consumption data corresponding to the power monitoring point mi as DLmi;

step two: acquiring power consumption data of Q times before a power monitoring point mi; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

step three: obtaining a power required detection value XJui of a power monitoring point mi by using a formula;

the calculation formula of the power requirement detection value XJui is as follows:

；

in the middle ofIs a fixed value of the proportionality coefficient, and +.>；

Step four: the dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated;

step five: and the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module.

Preferably, the scheduling management module is connected with a scheduling distribution module, and the scheduling distribution module is in wireless connection with the intelligent wearable equipment;

the intelligent wearable device is used for collecting body index information of the power inspection personnel in real time and sending the body index information to the state acquisition module;

the physical index information includes a sleep time period of a previous day.

Preferably, the sleep duration includes a deep sleep duration, a shallow sleep duration, and a wake duration.

Preferably, the state acquisition module is used for receiving the sleeping time of the power inspection personnel, which is sent by the intelligent wearable equipment, and sending the received sleeping time to the data processing module for processing;

the state acquisition module is also used for acquiring the working state value of the power inspection personnel, wherein the working state value comprises the continuous working time length, the working environment temperature and the working environment light value of the power inspection personnel.

Preferably, the state acquisition module sends the acquired working state value of the power inspection personnel to the data processing module; the data processing module processes, including the following:

calculating a sleep index;

the data processing module marks the received deep sleep time, shallow sleep time and awake time as Tss, tjs, tqx; the data processing module calculates and acquires the total sleeping time Tsz;

the data processing module marks the sleep index as Zsm;

sleep index Zsm is calculated byWherein alpha and beta are correction factors of the deep sleep time length and the light sleep time length respectively, and 0<α+β≤1；

Calculating a fatigue index;

the data processing module marks the continuous working time, the working environment temperature and the working environment light value of the received power inspection personnel as Sgi, wdi, gxi respectively;

numbering the continuous working times of the power inspection personnel, wherein i is a positive integer, i=1, 2 … … n, and n represents the total continuous working times;

the data processing module sets a continuous working time threshold Sgy, wherein the continuous working time threshold is set according to the capability of the power inspection personnel;

the data processing module marks the fatigue index as Zpl;

the fatigue index Zpl is calculated by

Wherein a1 and a2 are correction coefficients, and a1 and a2 are both larger than 0;

wd0 is a working environment proper temperature, gx0 is a working environment proper light value, and the working environment proper temperature and the working environment proper light value are set by the data processing module.

Preferably, the data processing module calculates the shift factor of the current day in combination with the sleep index and the fatigue index, including:

the data processing module marks the scheduling coefficient as Xpb;

the calculation formula is as follows: xpb= (1-b1× Zsm) +b2× Zpl;

the data processing module sends the calculated scheduling coefficient Xpb to the scheduling distribution module, wherein b1 and b2 are preset influence coefficients, and b1> b2>0.

The scheduling distribution module receives the scheduling coefficient Xpb sent by the data processing module and performs scheduling initial distribution, and the process comprises the following steps:

the scheduling distribution module receives the scheduling coefficients Xpb of the power inspection personnel and sequentially and orderly arranges the scheduling coefficients Xpb of all the power inspection personnel; the method comprises the steps of acquiring the first q power inspection workers, and marking the first q power inspection workers as workers to be scheduled;

the scheduling distribution module sends the selected list of the staff to be scheduled to the automatic adjustment module, and the automatic adjustment module sends a scheduling confirmation signal to the mobile terminal of the staff to be scheduled;

the automatic adjustment module sends the list of the staff to the data statistics module, and the data statistics module performs the scheduling statistics of the staff.

The intelligent guarantee power dispatching method is realized based on an intelligent guarantee power dispatching system, and comprises the following steps:

dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas; each target area comprises a plurality of power monitoring points, and the data acquisition module marks the power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; meanwhile, marking the power consumption data corresponding to the power monitoring point mi as DLmi;

acquiring power consumption data of Q times before a power monitoring point mi through a server; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

obtaining a power required detection value XJui of a power monitoring point mi by using a formula; the calculation formula of the power requirement detection value XJui is as follows:in the formula->Is a fixed value of the proportionality coefficient, and +.>；

The dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated; the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module;

the data processing module acquires the deep sleep time, the shallow sleep time and the awake time through an intelligent bracelet which is bound on the wrist of the power inspection personnel in real time, and marks Tss, tjs, tqx; the data processing module calculates and acquires the total sleeping time Tsz; the data processing module marks the continuous working time, the working environment temperature and the working environment light value of the received power inspection personnel as Sgi, wdi, gxi respectively;

the data processing module sets a continuous working time threshold Sgy, wherein the continuous working time threshold is set according to the capability of the power inspection personnel;

the data processing module marks the fatigue index as Zpl;

calculating a scheduling coefficient;

the data processing module is used for calculating the scheduling coefficient of the current day by combining the sleep index and the fatigue index, and the specific calculation process comprises the following steps:

the data processing module marks the scheduling coefficient as Xpb; the calculation formula is Xpb= (1-b1× Zsm) +b2× Zpl, the data processing module sends the calculated scheduling coefficient Xpb to the scheduling distribution module, wherein b1 and b2 are preset influence coefficients, and b1> b2>0.

The scheduling distribution module receives the scheduling coefficients Xpb sent by the data processing module, performs scheduling initial distribution, receives the scheduling coefficients Xpb of the power inspection personnel, and sequentially and orderly arranges the scheduling coefficients Xpb of all the power inspection personnel; the method comprises the steps of acquiring the first q power inspection workers, and marking the first q power inspection workers as workers to be scheduled; the scheduling distribution module sends the selected list of the staff to be scheduled to the automatic adjustment module, and the automatic adjustment module sends a scheduling confirmation signal to the mobile terminal of the staff to be scheduled; the automatic adjustment module sends the list of the staff to the data statistics module, and the data statistics module performs the scheduling statistics of the staff.

Compared with the prior art, the invention has the beneficial effects that:

according to the intelligent guarantee power dispatching system, from historical detection power consumption data of the power monitoring points mi, monitoring points needing power detection are screened out from the monitoring points of a plurality of target areas through calculation of power detection values, the task quantity of detection of the plurality of target areas is greatly reduced, and the power consumption data is selected to exceed a set power detection threshold; in addition, the electric power monitoring points needing to be subjected to electric power detection are selected by electric power inspection personnel, the electric power inspection personnel are initially selected from the sleeping condition and the fatigue condition of the electric power inspection personnel, and the most suitable electric power inspection personnel are selected to perform work task allocation in consideration of the safety and the personal care of the electric power detection;

the intelligent guarantee power dispatching system provided by the invention not only reduces the workload of power monitoring point inspection, but also selects power detection personnel according to actual conditions, avoids multiple scheduling of the same power detection personnel, and simultaneously is fair and fair to scheduling of all the power detection personnel.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required in the prior art and the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a block diagram of a power dispatching system with intelligent guarantee according to the invention.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely 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, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

Referring to fig. 1 specifically, an embodiment of the present invention proposes an intelligent guaranteed power dispatching system, which includes a data acquisition module, a dispatching control center, a dispatching management module and a server;

the data acquisition module is used for acquiring electricity consumption information of the electric equipment; the power consumption information acquired by the data acquisition module is sent to a server for storage; the dispatching control center is in remote wireless connection with the server; the dispatching control center is used for acquiring the electricity information stored in the server and sending dispatching inspection signals, and specifically, the working process of the dispatching control center comprises the following steps:

step one: dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas;

in the application, each target area comprises a plurality of power monitoring points, and the data acquisition module marks the plurality of power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; meanwhile, marking the power consumption data corresponding to the power monitoring point mi as DLmi;

step two: acquiring power consumption data of Q times before a power monitoring point mi through a server; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

step three: obtaining a power required detection value XJui of a power monitoring point mi by using a formula;

the calculation formula of the power requirement detection value XJui is as follows:the method comprises the steps of carrying out a first treatment on the surface of the In->Is a fixed value of the proportionality coefficient, and +.>；

Step four: the dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated;

step five: the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module;

in the application, the scheduling management module is connected with a scheduling distribution module, and the scheduling distribution module is in wireless connection with the intelligent wearable equipment;

the intelligent wearable device is specifically an intelligent bracelet which is bound on the wrist of the power inspection personnel in real time, the intelligent bracelet is a common intelligent bracelet on the market, and the intelligent bracelet is used for collecting body index information of the power inspection personnel in real time, wherein the body index information comprises sleeping time of the previous day; the intelligent wearable device is connected with the state acquisition module, and the intelligent wearable device sends the acquired sleeping time of the power inspection personnel on the previous day to the state acquisition module;

the sleeping time length comprises deep sleep time length, shallow sleep time length and awake time length; the acquisition modes of the deep sleep time, the shallow sleep time and the awake time are all the prior art, and can be realized through most intelligent bracelets on the market; and through the measurement of the prior art, a cerebral awake state can exist in the sleeping process, so the cerebral awake state duration is marked as the awake duration;

the deep sleep time length, the shallow sleep time length and the awake time length are the total time length of three states in the sleep process;

the state acquisition module is used for receiving the sleeping time of the power inspection personnel sent by the intelligent wearable equipment, sending the received sleeping time to the data processing module for processing, and synchronizing, and the state acquisition module is also used for acquiring the working state value of the power inspection personnel, wherein the working state value comprises but not limited to the continuous working time, the working environment temperature and the working environment light value of the power inspection personnel;

the method is characterized in that when the electric power patrol personnel carry out electric power equipment patrol, the electric power patrol personnel always feel tired, not the total patrol duration, but continuous operation without interruption, and the electric power patrol personnel feel tired and also the continuous operation duration, so that the continuous operation duration is adopted as an expression form of the working state value of the electric power patrol personnel; when the power inspection personnel performs power equipment inspection, environmental factors also affect the body and the mind of the power inspection personnel, and the working environment temperature and the working environment light value are used as one factor of the working state value of the power inspection personnel.

The state acquisition module sends the acquired working state value of the power inspection personnel to the data processing module; it should be emphasized that the process of the data processing module for processing the received related data includes the following steps:

the first step: calculating a sleep index;

the data processing module marks the received deep sleep time, shallow sleep time and awake time as Tss, tjs, tqx; the data processing module calculates and acquires the total sleeping time Tsz; it is easy to see that tsz=tss+ Tjs + Tqx;

the data processing module marks the sleep index as Zsm; the sleep index Zsm disclosed in the invention is calculated byIt should be noted that α and β are correction factors of the deep sleep duration and the light sleep duration, respectively, and 0<α+β≤1；

And a second step of: calculating a fatigue index;

the data processing module marks the continuous working time, the working environment temperature and the working environment light value of the received power inspection personnel as Sgi, wdi, gxi respectively; in this embodiment, because there may be a working state and an idle state in relation to a day of work of the power inspection personnel, the number of continuous working times of the power inspection personnel is numbered, i is a positive integer, i=1, 2 … … n, n represents the total number of continuous working times;

the data processing module sets a continuous working time threshold Sgy, wherein the continuous working time threshold is set according to the capability of the power inspection personnel;

the data processing module marks the fatigue index as Zpl; the invention discloses a fatigue index Zpl calculation mode which comprises the following steps:

;

it should be noted that, a1 and a2 are correction coefficients, and a1 and a2 are both greater than 0; wherein Wd0 is a working environment suitable temperature, gx0 is a working environment suitable light value, and the working environment suitable temperature and the working environment suitable light value are set by the data processing module;

and a third step of: calculating a scheduling coefficient;

the data processing module is used for calculating the scheduling coefficient of the current day by combining the sleep index and the fatigue index, and the specific calculation process comprises the following steps:

the data processing module marks the scheduling coefficient as Xpb; the calculation formula is Xpb= (1-b1× Zsm) +b2× Zpl, the data processing module sends the calculated scheduling coefficient Xpb to the scheduling distribution module, wherein b1 and b2 are preset influence coefficients, and b1> b2>0.

The scheduling distribution module is used for receiving the scheduling coefficient Xpb sent by the data processing module and performing scheduling primary distribution, and the working process of the specific scheduling distribution module comprises the following steps:

step one: the scheduling distribution module receives the scheduling coefficients Xpb of the power inspection personnel and sequentially and orderly arranges the scheduling coefficients Xpb of all the power inspection personnel; the method comprises the steps of acquiring the first q power inspection workers, and marking the first q power inspection workers as workers to be scheduled;

step two: the scheduling distribution module sends the selected list of the staff to be scheduled to the automatic adjustment module, and the automatic adjustment module sends a scheduling confirmation signal to the mobile terminal of the staff to be scheduled;

step three: the automatic adjustment module sends the list of the staff to the data statistics module, and the data statistics module performs the scheduling statistics of the staff.

According to the intelligent guarantee power dispatching system, from historical detection power consumption data of the power monitoring points mi, monitoring points needing power detection are screened out from the monitoring points of a plurality of target areas through calculation of power detection values, the task quantity of detection of the plurality of target areas is greatly reduced, and the power consumption data is selected to exceed a set power detection threshold; in addition, the electric power monitoring points needing to be subjected to electric power detection are selected by electric power inspection personnel, the electric power inspection personnel are initially selected from the sleeping condition and the fatigue condition of the electric power inspection personnel, and the most suitable electric power inspection personnel are selected to perform work task allocation in consideration of the safety and the personal care of the electric power detection;

the intelligent guarantee power dispatching system provided by the invention not only reduces the workload of power monitoring point inspection, but also selects power detection personnel according to actual conditions, avoids multiple scheduling of the same power detection personnel, and simultaneously is fair and fair to scheduling of all the power detection personnel.

An embodiment of the invention provides an intelligent guarantee power dispatching method, which mainly comprises the following steps:

step one: dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas; each target area comprises a plurality of power monitoring points, and the data acquisition module marks the power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; meanwhile, marking the power consumption data corresponding to the power monitoring point mi as DLmi;

acquiring power consumption data of Q times before a power monitoring point mi through a server; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

step two: obtaining a power required detection value XJui of a power monitoring point mi by using a formula; the calculation formula of the power requirement detection value XJui is as follows:

;

in the middle ofIs a fixed value of the proportionality coefficient, and +.>；

Step three: the dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated; the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module;

step four: the data processing module acquires the deep sleep time, the shallow sleep time and the awake time through an intelligent bracelet which is bound on the wrist of the power inspection personnel in real time, and marks Tss, tjs, tqx; the data processing module calculates and acquires the total sleeping time Tsz; the data processing module marks the continuous working time, the working environment temperature and the working environment light value of the received power inspection personnel as Sgi, wdi, gxi respectively; the data processing module sets a continuous working time threshold Sgy, wherein the continuous working time threshold is set according to the capability of the power inspection personnel;

the data processing module marks the fatigue index as Zpl;

step five: calculating a scheduling coefficient;

the data processing module is used for calculating the scheduling coefficient of the current day by combining the sleep index and the fatigue index, and the specific calculation process comprises the following steps:

the data processing module marks the scheduling coefficient as Xpb; the calculation formula is Xpb= (1-b1× Zsm) +b2× Zpl, the data processing module sends the calculated scheduling coefficient Xpb to the scheduling distribution module, wherein b1 and b2 are preset influence coefficients, and b1> b2>0.

Step six: the scheduling distribution module receives the scheduling coefficients Xpb sent by the data processing module, performs scheduling primary distribution, receives the scheduling coefficients Xpb of the power inspection personnel, and sequentially and orderly arranges the scheduling coefficients Xpb of all the power inspection personnel; the method comprises the steps of acquiring the first q power inspection workers, and marking the first q power inspection workers as workers to be scheduled; the scheduling distribution module sends the selected list of the staff to be scheduled to the automatic adjustment module, and the automatic adjustment module sends a scheduling confirmation signal to the mobile terminal of the staff to be scheduled; the automatic adjustment module sends the list of the staff to the data statistics module, and the data statistics module performs the scheduling statistics of the staff.

The above formulas are all formulas with dimensions removed and numerical values calculated, the formulas are formulas which are obtained by acquiring a large amount of data and performing software simulation to obtain the closest actual situation, and preset parameters and preset thresholds in the formulas are set by a person skilled in the art according to the actual situation or are obtained by simulating a large amount of data.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. The intelligent guarantee power dispatching system is characterized by comprising a data acquisition module, a dispatching control center, a dispatching management module and a server;

the data acquisition module is used for acquiring the electricity consumption of the electric equipment and sending the electricity consumption to the server for storage; the dispatching control center is in remote wireless connection with the server;

the dispatching control center is used for acquiring the electricity information stored in the server and sending dispatching inspection signals, and the working process of the dispatching control center comprises the following steps:

step one: dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas; each target area comprises a plurality of power monitoring points, and the data acquisition module marks the power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; marking the power consumption data corresponding to the power monitoring point mi as DLmi;

step two: acquiring power consumption data of Q times before a power monitoring point mi; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

step three: obtaining a power required detection value XJui of a power monitoring point mi by using a formula;

the calculation formula of the power requirement detection value XJui is as follows:

the method comprises the steps of carrying out a first treatment on the surface of the In->Is a fixed value of the proportionality coefficient, and +.>；

Step four: the dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated;

step five: and the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module.

2. The intelligent guaranteed power dispatching system of claim 1, wherein the dispatching management module is connected with a scheduling distribution module, and the scheduling distribution module is in wireless connection with intelligent wearable equipment;

the intelligent wearable device is used for collecting body index information of the power inspection personnel in real time and sending the body index information to the state acquisition module;

the physical index information includes a sleep time period of a previous day.

3. The intelligently secured power scheduling system of claim 2, wherein the sleep durations include a deep sleep duration, a shallow sleep duration, and a wake duration.

4. The intelligent security power dispatching system of claim 3, wherein the status acquisition module is configured to receive a sleep time of a previous day of a power inspection person sent by the intelligent wearable device, and send the received sleep time to the data processing module for processing;

the state acquisition module is also used for acquiring the working state value of the power inspection personnel, wherein the working state value comprises the continuous working time length, the working environment temperature and the working environment light value of the power inspection personnel.

5. The intelligent security power dispatching system of claim 4, wherein the status acquisition module sends the collected working status value of the power inspection personnel to the data processing module; the data processing module processes, including the following:

calculating a sleep index;

the data processing module marks the received deep sleep time, shallow sleep time and awake time as Tss, tjs, tqx; the data processing module calculates and acquires the total sleeping time Tsz;

the data processing module marks the sleep index as Zsm;

sleep index Zsm is calculated by:wherein alpha and beta are correction factors of the deep sleep time length and the light sleep time length respectively, and 0<α+β≤1；

Calculating a fatigue index;

the data processing module marks the continuous working time, the working environment temperature and the working environment light value of the received power inspection personnel as Sgi, wdi, gxi respectively;

numbering the continuous working times of the power inspection personnel, marking the continuous working times as i, wherein i is a positive integer,

i=1, 2 … … n, n representing the total number of continuous operations;

the data processing module sets a continuous working time threshold Sgy, wherein the continuous working time threshold is set according to the capability of the power inspection personnel;

the data processing module marks the fatigue index as Zpl;

the fatigue index Zpl is calculated by

Wherein a1 and a2 are correction coefficients, and a1 and a2 are both larger than 0; wd0 is a working environment proper temperature, gx0 is a working environment proper light value, and the working environment proper temperature and the working environment proper light value are set by the data processing module.

6. The intelligent guaranteed power scheduling system of claim 5, wherein the data processing module calculates the current day's scheduling coefficients in combination with the sleep index and the fatigue index, comprising:

the data processing module marks the scheduling coefficient as Xpb; the calculation formula is Xpb= (1-b1× Zsm) +b2× Zpl, the data processing module sends the calculated scheduling coefficient Xpb to the scheduling distribution module, wherein b1 and b2 are preset influence coefficients, and b1> b2>0;

the scheduling distribution module receives the scheduling coefficient Xpb sent by the data processing module and performs scheduling initial distribution, and the process comprises the following steps:

the scheduling distribution module receives the scheduling coefficients Xpb of the power inspection personnel and sequentially and orderly arranges the scheduling coefficients Xpb of all the power inspection personnel; the method comprises the steps of acquiring the first q power inspection workers, and marking the first q power inspection workers as workers to be scheduled;

the scheduling distribution module sends the selected list of the staff to be scheduled to the automatic adjustment module, and the automatic adjustment module sends a scheduling confirmation signal to the mobile terminal of the staff to be scheduled;

the automatic adjustment module sends the list of the staff to the data statistics module, and the data statistics module performs the scheduling statistics of the staff.

7. An intelligent guarantee power scheduling method, which is implemented based on the intelligent guarantee power scheduling system according to any one of claims 1 to 6, and is characterized in that the method comprises the following steps:

dividing the electricity utilization area into a plurality of target areas, and marking the plurality of target areas as m, m=1, 2, … … and S; s represents the total number of target areas; each target area comprises a plurality of power monitoring points, and the data acquisition module marks the power monitoring points as mi, i=1, 2, … … and x respectively; wherein x represents the total number of power monitoring points in the target area; meanwhile, marking the power consumption data corresponding to the power monitoring point mi as DLmi;

acquiring power consumption data of Q times before a power monitoring point mi through a server; calculating an average value of the power consumption data of the previous Q times to obtain an average power consumption value, and marking the average power consumption value as PJui; wherein Q is set by the data acquisition module; marking the power consumption data of the previous Q times as Dlmiq;

obtaining a power required detection value XJui of a power monitoring point mi by using a formula; the calculation formula of the power requirement detection value XJui is as follows:

in the formula->Is a fixed value of the proportionality coefficient, and +.>；

The dispatching control center sets a power requirement detection threshold, and when the calculated power requirement detection value XJui is larger than the power requirement detection threshold, a dispatching inspection signal is generated; and the dispatching control center sends the position coordinates of the power monitoring points mi and dispatching inspection signals to the dispatching management module.

8. A computer device, comprising: a memory, a processor, and an intelligent guaranteed power scheduling system according to any one of claims 1 to 6;

the processor is connected with the intelligent guarantee power dispatching system and the memory through buses;

the memory is used for storing computer execution instructions; the processor is configured to execute the computer-executable instructions stored in the memory.

9. A storage medium, comprising: a readable storage medium and a computer program for controlling the intelligent guaranteed power scheduling method of claim 7 to implement power scheduling.