CN116720720A - Geotechnical engineering equipment interconnection scheduling management method and system - Google Patents

Abstract

The application discloses a geotechnical engineering equipment interconnection scheduling management method and system, wherein the method comprises the following steps: the edge node collects construction data to generate a construction report and sends the construction report to the server; the server analyzes and judges whether the construction progress is abnormal according to the construction report; if the abnormal condition exists, analyzing the abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme; the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme; and the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to the first preset terminal. According to the application, the edge nodes are used for collecting and sorting construction data of a construction site, the auxiliary server is used for processing the data, and the construction task is adjusted according to the equipment scheduling scheme, so that the data processing efficiency is improved.

Description

Geotechnical engineering equipment interconnection scheduling management method and system

Technical Field

The application relates to the field of data processing and data transmission, in particular to a geotechnical engineering equipment interconnection scheduling management method and system.

Background

Due to the rapid development of informatization technology, more and more geotechnical engineering equipment has begun to use internet of things technology for remote monitoring and management. However, the existing geotechnical engineering equipment interconnection scheduling management method still has some problems, such as unstable data transmission between equipment and high complexity of equipment management.

Currently, in the process of managing geotechnical engineering equipment, scheduling information of operators and equipment needs to be arranged and managed manually. On this premise, the engineering device needs to follow the corresponding instruction to perform the corresponding work. However, such automated management requires a large amount of manual intervention, and thus is costly.

The management difficulty of geotechnical engineering equipment is increased due to the existence of the problems, and the efficiency and benefits of the whole industry are affected.

Therefore, the prior art has defects, and improvement is needed.

Disclosure of Invention

In view of the above problems, the invention aims to provide a geotechnical engineering equipment interconnection scheduling management method and system, which can more effectively and more rapidly schedule and manage geotechnical engineering equipment.

The first aspect of the invention provides a geotechnical engineering equipment interconnection scheduling management method, which comprises the following steps:

The edge node collects construction data to generate a construction report and sends the construction report to the server;

the server analyzes and judges whether the construction progress is abnormal according to the construction report;

if the construction report is abnormal, analyzing an abnormal reason, and generating a device scheduling scheme according to the construction report;

if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme;

and the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to a first preset terminal.

In this scheme, the server analyzes and judges whether the construction progress has abnormality according to the construction report, including:

comparing the construction data with a construction plan, and judging whether the construction progress is abnormal or not;

if the abnormality exists, analyzing according to the abnormal construction data to obtain an abnormality reason; otherwise, filtering;

and sending the abnormal reason to a second preset terminal.

In this solution, the generating a device scheduling solution according to the construction report includes:

Drawing a construction progress curve according to the construction report;

analyzing according to the construction progress curve to obtain the predicted completion time of the construction task;

judging whether the predicted completion time of the construction task is smaller than a first preset time or not;

if yes, no treatment is carried out;

if not, making a device scheduling scheme according to the implementation construction progress curve.

In this scheme, the equipment scheduling scheme is formulated according to the implementation construction progress curve, including:

analyzing according to the construction progress curve, and calculating the residual construction tasks to obtain the type information of the equipment to be scheduled;

generating a device scheduling application according to the device type information to be scheduled and uploading the device scheduling application to a server;

and the server inquires the callable time intervals of the devices of the same type bound by other edge nodes according to the device scheduling application, calculates the callable time intervals through a preset scheduling rule, and generates a device scheduling scheme.

In this scheme, still include:

acquiring equipment state data;

analyzing according to the equipment state data, and predicting the overhaul and maintenance time of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time;

And generating an equipment scheduling application according to the overhaul maintenance time.

In this scheme, still include:

analyzing according to the equipment scheduling application;

if the equipment scheduling application is an emergency scheduling application, the emergency scheduling application is sent to other edge nodes through a server;

the other edge nodes analyze the emergency dispatching application, adjust the working plan of the emergency dispatching equipment in a controllable range and judge whether the emergency dispatching application is met or not;

if yes, marking the edge node as a pending emergency dispatch node; otherwise, filtering;

after all other edge nodes are analyzed, the server selects an optimal emergency dispatching node from all undetermined emergency dispatching nodes according to a preset dispatching rule;

the server generates an emergency scheduling scheme and sends the emergency scheduling scheme to the optimal emergency scheduling node;

and the optimal emergency dispatching node generates an emergency dispatching instruction according to the emergency dispatching scheme and sends the emergency dispatching instruction to a first preset terminal.

In this solution, if the device scheduling scheme cannot be generated, performing device scheduling by generating a coordinated scheduling scheme through a plurality of edge nodes includes:

Defining an edge node applying for equipment scheduling as a first node;

analyzing according to other edge nodes, and selecting a second node according to a preset scheduling rule;

selecting a plurality of undetermined third nodes between the first node and the second node;

analyzing according to the plurality of third nodes to be determined, respectively calculating the equipment scheduling time interval of each third node to be determined, calculating the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and defining the third nodes to be determined meeting the conditions as third nodes;

and generating a coordinated scheduling scheme through the server, scheduling the equipment of the third node to the first node, and scheduling the construction task distributed by the second node equipment to the third node after the construction task is completed.

In this scheme, still include:

analyzing according to the equipment state data, and marking the equipment as idle equipment if the equipment does not work and does not have work task arrangement within a second preset time;

generating an idle equipment scheduling request according to the idle equipment and uploading the idle equipment scheduling request to a server;

the server sends the idle equipment scheduling request to other edge nodes;

the other edge nodes analyze the idle equipment scheduling request and judge whether equipment scheduling is needed or not;

If so, analyzing according to the construction progress to obtain a device scheduling time interval and uploading the device scheduling time interval to a server; otherwise, filtering;

and the server analyzes according to the equipment scheduling time intervals uploaded by the other edge nodes to generate idle equipment scheduling tasks.

The second aspect of the invention provides an interconnected scheduling management system for geotechnical engineering equipment, which comprises the following components:

the edge node data processing module is used for collecting construction data through the edge node to generate a construction report and sending the construction report to the server;

the system analysis module is used for analyzing and judging whether the construction progress is abnormal or not according to the construction report through the server; if the construction report is abnormal, analyzing an abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

the system sending module is used for analyzing and selecting a corresponding edge node according to the equipment scheduling scheme through the server and issuing the equipment scheduling scheme;

and the edge node scheduling module is used for generating equipment scheduling instructions according to the equipment scheduling schemes through the corresponding edge nodes and sending the equipment scheduling instructions to a first preset terminal.

In this scheme, the server analyzes and judges whether the construction progress has abnormality according to the construction report, including:

comparing the construction data with a construction plan, and judging whether the construction progress is abnormal or not;

if the abnormality exists, analyzing according to the abnormal construction data to obtain an abnormality reason; otherwise, filtering;

and sending the abnormal reason to a second preset terminal.

In this solution, the generating a device scheduling solution according to the construction report includes:

drawing a construction progress curve according to the construction report;

analyzing according to the construction progress curve to obtain the predicted completion time of the construction task;

judging whether the predicted completion time of the construction task is smaller than a first preset time or not;

if yes, no treatment is carried out;

if not, making a device scheduling scheme according to the implementation construction progress curve.

In this scheme, the equipment scheduling scheme is formulated according to the implementation construction progress curve, including:

analyzing according to the construction progress curve, and calculating the residual construction tasks to obtain the type information of the equipment to be scheduled;

generating a device scheduling application according to the device type information to be scheduled and uploading the device scheduling application to a server;

And the server inquires the callable time intervals of the devices of the same type bound by other edge nodes according to the device scheduling application, calculates the callable time intervals through a preset scheduling rule, and generates a device scheduling scheme.

In this scheme, still include:

acquiring equipment state data;

analyzing according to the equipment state data, and predicting the overhaul and maintenance time of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time;

and generating an equipment scheduling application according to the overhaul maintenance time.

In this scheme, still include:

analyzing according to the equipment scheduling application;

if the equipment scheduling application is an emergency scheduling application, the emergency scheduling application is sent to other edge nodes through a server;

the other edge nodes analyze the emergency dispatching application, adjust the working plan of the emergency dispatching equipment in a controllable range and judge whether the emergency dispatching application is met or not;

if yes, marking the edge node as a pending emergency dispatch node; otherwise, filtering;

after all other edge nodes are analyzed, the server selects an optimal emergency dispatching node from all undetermined emergency dispatching nodes according to a preset dispatching rule;

The server generates an emergency scheduling scheme and sends the emergency scheduling scheme to the optimal emergency scheduling node;

and the optimal emergency dispatching node generates an emergency dispatching instruction according to the emergency dispatching scheme and sends the emergency dispatching instruction to a first preset terminal.

In this solution, if the device scheduling scheme cannot be generated, performing device scheduling by generating a coordinated scheduling scheme through a plurality of edge nodes includes:

defining an edge node applying for equipment scheduling as a first node;

analyzing according to other edge nodes, and selecting a second node according to a preset scheduling rule;

selecting a plurality of undetermined third nodes between the first node and the second node;

analyzing according to the plurality of third nodes to be determined, respectively calculating the equipment scheduling time interval of each third node to be determined, calculating the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and defining the third nodes to be determined meeting the conditions as third nodes;

and generating a coordinated scheduling scheme through the server, scheduling the equipment of the third node to the first node, and scheduling the construction task distributed by the second node equipment to the third node after the construction task is completed.

In this scheme, still include:

analyzing according to the equipment state data, and marking the equipment as idle equipment if the equipment does not work and does not have work task arrangement within a second preset time;

generating an idle equipment scheduling request according to the idle equipment and uploading the idle equipment scheduling request to a server;

the server sends the idle equipment scheduling request to other edge nodes;

the other edge nodes analyze the idle equipment scheduling request and judge whether equipment scheduling is needed or not;

if so, analyzing according to the construction progress to obtain a device scheduling time interval and uploading the device scheduling time interval to a server; otherwise, filtering;

and the server analyzes according to the equipment scheduling time intervals uploaded by the other edge nodes to generate idle equipment scheduling tasks.

A third aspect of the present invention provides a computer-readable storage medium, the computer-readable storage medium including therein a geotechnical engineering equipment interconnection schedule management method program, which when executed by a processor, implements the steps of a geotechnical engineering equipment interconnection schedule management method according to any one of the above.

The invention discloses a geotechnical engineering equipment interconnection scheduling management method and system, wherein the method comprises the following steps: the edge node collects construction data to generate a construction report and sends the construction report to the server; the server analyzes and judges whether the construction progress is abnormal according to the construction report; if the abnormal condition exists, analyzing the abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme; the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme; and the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to the first preset terminal. According to the invention, the edge nodes are used for collecting and sorting construction data of a construction site, the auxiliary server is used for processing the data, and the construction task is adjusted according to the equipment scheduling scheme, so that the data processing efficiency is improved.

Drawings

FIG. 1 shows a flow chart of an geotechnical engineering equipment interconnection scheduling management method of the invention;

FIG. 2 shows a flow chart of a geotechnical engineering equipment scheduling scheme formulation method of the present invention;

FIG. 3 shows a flow chart of a geotechnical engineering equipment co-scheduling method of the present application;

fig. 4 shows a block diagram of an geotechnical engineering equipment interconnection scheduling management system of the present application.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will be more clearly understood, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, without conflict, the embodiments of the present application and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, however, the present application may be practiced in other ways than those described herein, and therefore the scope of the present application is not limited to the specific embodiments disclosed below.

Fig. 1 shows a flow chart of an geotechnical engineering equipment interconnection scheduling management method of the application.

As shown in fig. 1, the application discloses a geotechnical engineering equipment interconnection scheduling management method, which comprises the following steps:

s102, collecting construction data by an edge node to generate a construction report and sending the construction report to a server;

s104, the server analyzes and judges whether the construction progress is abnormal according to the construction report;

S106, if the construction report is abnormal, analyzing the reason of the abnormality, and generating an equipment scheduling scheme according to the construction report;

s108, if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

s110, the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme;

and S112, the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to a first preset terminal.

According to the embodiment of the invention, one or more edge nodes are configured on each construction site, and the edge nodes are used for cleaning data and integrating data by collecting the use data of geotechnical engineering equipment bound with the edge nodes and the work report uploaded by constructors, and filtering useless data to obtain a construction report.

The server inputs the construction data in the received construction report to the construction progress curve in a numerical value or percentage mode, and judges whether the construction progress is within the construction plan range or not by comparing the construction progress with the construction plan, and if not, the server indicates that the construction progress is abnormal. The server processes abnormal conditions by applying for equipment scheduling, sends the generated equipment scheduling scheme to the corresponding edge node, adjusts the construction task of the edge node binding construction site by the edge server of the edge node, generates equipment scheduling instructions and sends the equipment scheduling instructions to the corresponding geotechnical engineering equipment terminal, namely the first preset terminal. In addition, the device scheduling method can be used for processing in the same cooperative scheduling mode for the case that the device scheduling cannot be performed. The device scheduling schemes comprise a common device scheduling scheme, an emergency scheduling scheme, a cooperative scheduling scheme, an idle device scheduling scheme and the like.

According to the embodiment of the invention, the server analyzes and judges whether the construction progress is abnormal according to the construction report, and the method comprises the following steps:

comparing the construction data with a construction plan, and judging whether the construction progress is abnormal or not;

if the abnormality exists, analyzing according to the abnormal construction data to obtain an abnormality reason; otherwise, filtering;

and sending the abnormal reason to a second preset terminal.

The construction method is characterized in that the construction method comprises the steps of performing field investigation before a construction task starts, and making a construction plan according to the investigation result, wherein the construction plan comprises a required geotechnical engineering equipment list, constructor distribution conditions, construction task arrangement and the like, and whether the construction progress is abnormal or not is judged by comparing construction data collected by edge nodes with the construction task arrangement in the construction plan, and when the progress difference of the construction data and the construction task arrangement is large, the construction progress is shown to be abnormal. Under the condition of abnormal construction progress, determining an abnormality reason by analyzing construction data uploaded by the edge nodes, wherein the abnormality reason comprises human factors, environmental factors and the like, and if the abnormality is caused by the human factors, the abnormality can be adjusted by replacing constructors; if the environment factors cause abnormality, such as unnoticed environmental conditions around the construction site, irregular measurement methods, complex geological environment of the construction site, large change and the like, the construction plan can be adjusted according to the current environment parameters, and the construction task can be completed within a specified time by adding equipment or replacing equipment. And simultaneously, the reasons and the adjustment modes of the abnormality are sent to a second preset terminal, wherein the second preset terminal can be a background display terminal, and the background display terminal is used for visual display.

According to an embodiment of the present invention, the generating a device scheduling scheme according to the construction report includes:

drawing a construction progress curve according to the construction report;

analyzing according to the construction progress curve to obtain the predicted completion time of the construction task;

judging whether the predicted completion time of the construction task is smaller than a first preset time or not;

if yes, no treatment is carried out;

if not, making a device scheduling scheme according to the implementation construction progress curve.

By collecting the construction report uploaded by each edge node, inputting construction data in the construction report into a construction progress curve in a numerical value or percentage format, displaying the construction progress in a visual mode, and then predicting the construction task of an unfinished part by the construction data of the finished part to obtain the predicted completion time of the construction task. And comparing the obtained predicted completion time of the construction task with a first preset time, and judging whether the current construction progress meets the expected engineering requirement. If yes, continuing to monitor; otherwise, analyzing according to the current construction progress and the construction tasks of the unfinished part to generate an equipment scheduling scheme, so that the construction efficiency of geotechnical engineering is ensured. The first preset time is geotechnical engineering completion time set in a construction plan. In addition, the server sends the generated construction progress curve to the corresponding edge node.

Fig. 2 shows a flow chart of a scheduling scheme formulation method of geotechnical engineering equipment.

As shown in fig. 2, according to an embodiment of the present invention, the device scheduling scheme according to the implementation construction progress curve includes:

s202, analyzing according to the construction progress curve, and calculating the residual construction tasks to obtain the type information of the equipment to be scheduled;

s204, generating a device scheduling application according to the device type information to be scheduled and uploading the device scheduling application to a server;

s206, the server inquires the callable time intervals of the devices of the same type bound by other edge nodes according to the device scheduling application, calculates the callable time intervals through a preset scheduling rule, and generates a device scheduling scheme.

The edge node analyzes the construction progress curve through the edge server, determines equipment type information required by the remaining construction tasks, compares geotechnical engineering equipment configured on a construction site, judges whether equipment scheduling is required, and if scheduling is required to be set, outputs the equipment type information required to be scheduled. The server issues scheduling equipment type query applications to other edge nodes according to the equipment scheduling applications, and the other edge nodes analyze according to equipment types in the scheduling equipment type query applications, determine callable time intervals of equipment of the same type and feed back the callable time intervals to the server. The server calculates through a preset scheduling rule to generate an equipment scheduling scheme, wherein the preset scheduling rule is specifically that scheduling parameters such as a geotechnical engineering equipment transportation method, transportation time, transportation cost and the like are calculated according to the relative distance between two scheduling places, the scheduling parameters are adjusted by combining user setting preferences (such as lowest cost, shortest time and the like), and the most suitable scheduling parameters are selected to generate the equipment scheduling scheme. And then the equipment scheduling scheme is sent to an auditing department, after the system or professional audits the equipment scheduling scheme, the equipment scheduling scheme is issued to a corresponding edge node, and the edge node generates an equipment scheduling instruction according to the equipment scheduling scheme and adds scheduling tasks to the corresponding equipment.

According to an embodiment of the present invention, further comprising:

acquiring equipment state data;

analyzing according to the equipment state data, and predicting the overhaul and maintenance time of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time;

and generating an equipment scheduling application according to the overhaul maintenance time.

When the edge node binds geotechnical engineering equipment, the normal working state data interval of the geotechnical engineering equipment is determined by reading the set parameters, whether the real-time equipment state data acquired by the edge node is in the normal working state data interval or not is analyzed, and equipment maintenance application is carried out if the real-time equipment state data acquired by the edge node is not in the normal working state data interval; and predicting the presence of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time. And then the edge node applies for equipment scheduling according to the obtained recommended maintenance time, so that the abnormal engineering construction progress caused by equipment maintenance is avoided. The equipment state data comprise equipment working duration time, working temperature, equipment rotating speed, vibration frequency and the like.

According to an embodiment of the present invention, further comprising:

analyzing according to the equipment scheduling application;

if the equipment scheduling application is an emergency scheduling application, the emergency scheduling application is sent to other edge nodes through a server;

The other edge nodes analyze the emergency dispatching application, adjust the working plan of the emergency dispatching equipment in a controllable range and judge whether the emergency dispatching application is met or not;

if yes, marking the edge node as a pending emergency dispatch node; otherwise, filtering;

after all other edge nodes are analyzed, the server selects an optimal emergency dispatching node from all undetermined emergency dispatching nodes according to a preset dispatching rule;

the server generates an emergency scheduling scheme and sends the emergency scheduling scheme to the optimal emergency scheduling node;

and the optimal emergency dispatching node generates an emergency dispatching instruction according to the emergency dispatching scheme and sends the emergency dispatching instruction to a first preset terminal.

It should be noted that, after receiving the equipment scheduling application sent by the edge node, the server determines the application type according to the content of the equipment scheduling application, if the application is an emergency scheduling application (such as the equipment scheduling application performed by the edge node under the condition that the equipment cannot work due to the equipment abnormality in the working process of the equipment), the server preferentially processes the application, sends the emergency scheduling application to other edge nodes, and the other edge nodes extract the data of the equipment type, the equipment model and the like of the equipment to be scheduled according to the emergency scheduling application, and judges whether the geotechnical engineering equipment of the same type exists in the equipment bound by the current edge node. If yes, adjusting a construction plan of a construction site where the current edge node is located according to the scheduling time in the emergency scheduling application, judging whether geotechnical engineering equipment of the same type can be scheduled at the scheduling time in the emergency scheduling application, and if not, filtering the current node; if yes, marking the current node as the undetermined emergency dispatching node, and feeding back to the server. And after all other edge nodes are analyzed, the server determines the optimal emergency dispatching node according to the preset dispatching rule of the system. The first preset terminal is an equipment terminal of geotechnical engineering equipment which needs scheduling of the equipment.

Fig. 3 shows a flow chart of a geotechnical engineering equipment co-scheduling method of the invention.

As shown in fig. 3, according to an embodiment of the present invention, if the device scheduling scheme cannot be generated, performing device scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme includes:

s302, defining an edge node applying for equipment scheduling as a first node;

s304, analyzing according to other edge nodes, and selecting a second node according to a preset scheduling rule;

s306, selecting a plurality of undetermined third nodes between the first node and the second node;

s308, analyzing according to the plurality of third nodes to be determined, respectively calculating the equipment scheduling time interval of each third node to be determined, calculating the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and defining the third nodes to be determined meeting the conditions as third nodes;

and S310, generating a coordinated scheduling scheme through the server, scheduling the equipment of the third node to the first node, and scheduling the construction task distributed by the second node equipment to the third node after the construction task is completed.

When the device scheduling is performed, if all edge nodes bound with the server cannot meet the device scheduling application, the device scheduling can be performed in a mode of performing cooperative scheduling by the plurality of nodes. Firstly, according to the schedulable time of the equipment fed back by all other edge nodes, selecting an optimal edge node from all other edge nodes as a second node by combining a preset scheduling rule. And then respectively taking the first node and the second node as circle centers, selecting a plurality of edge nodes as undetermined third nodes according to a preset range (such as within 30 KM) of the system, respectively analyzing each undetermined third node, and determining a schedulable time interval for scheduling geotechnical engineering equipment and feeding back to a server under the condition of not affecting other construction tasks. The server calculates according to schedulable time intervals of the geotechnical engineering equipment needing to be scheduled fed back by all the third nodes to be scheduled and combining the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and selects the third nodes to be scheduled, which comprise the equipment application scheduling time of the first node and the earliest scheduling time of the second node, as the third nodes. The server generates a coordination scheduling scheme according to the first node, the second node and the third node and sends the coordination scheduling scheme to the first node, the second node and the third node respectively, and the first node, the second node and the third node respectively adjust the construction task arrangement according to the coordination scheduling scheme.

In addition, the cooperative scheduling scheme is not limited to the cooperative scheduling by three nodes, but can also perform the cooperative scheduling by more edge nodes.

According to an embodiment of the present invention, further comprising:

analyzing according to the equipment state data, and marking the equipment as idle equipment if the equipment does not work and does not have work task arrangement within a second preset time;

generating an idle equipment scheduling request according to the idle equipment and uploading the idle equipment scheduling request to a server;

the server sends the idle equipment scheduling request to other edge nodes;

the other edge nodes analyze the idle equipment scheduling request and judge whether equipment scheduling is needed or not;

if so, analyzing according to the construction progress to obtain a device scheduling time interval and uploading the device scheduling time interval to a server; otherwise, filtering;

and the server analyzes according to the equipment scheduling time intervals uploaded by the other edge nodes to generate idle equipment scheduling tasks.

When the idle equipment is scheduled, the server selects a plurality of edge nodes to analyze according to a system preset range by taking a construction site where the idle equipment is located as a circle center, and marks the edge nodes needing to be scheduled by the rock-soil equipment. The marked edge nodes analyze according to the bound construction tasks to obtain equipment scheduling time intervals and feed back the equipment scheduling time intervals to the server, the server analyzes according to the received equipment scheduling time intervals of all the marked edge nodes and judges whether the scheduling expense requirements are met, so that idle equipment scheduling tasks are formulated, the idle equipment scheduling tasks are sent to the corresponding edge nodes, and the corresponding edge nodes adjust the bound construction tasks according to the received idle equipment scheduling tasks. The second preset time is 48 hours, namely when the geotechnical engineering equipment does not perform construction work and does not have construction work task arrangement in 48 continuous hours, the current geotechnical engineering equipment is in an idle state, and idle equipment scheduling can be performed on the geotechnical engineering equipment.

The method for judging whether the scheduling cost requirement is met is specifically to analyze other edge nodes in a preset range (such as within 30 KM) of the system and respectively calculate whether the scheduling cost of each other edge node is lower than the corresponding highest scheduling cost. The highest dispatching expense is obtained by multiplying the dispatching expense factor set by the system by the working time of the geotechnical engineering equipment at the construction site corresponding to the edge node, and the dispatching expense factors of different types of geotechnical engineering equipment are different.

In addition, the edge nodes which are not of the same type of geotechnical engineering equipment as the idle equipment are preferentially selected when the idle equipment is scheduled.

Fig. 4 shows a block diagram of an geotechnical engineering equipment interconnection scheduling management system of the present invention.

As shown in fig. 4, a second aspect of the present invention provides an geotechnical engineering equipment interconnection scheduling management system, including:

the edge node data processing module is used for collecting construction data through the edge node to generate a construction report and sending the construction report to the server;

the system analysis module is used for analyzing and judging whether the construction progress is abnormal or not according to the construction report through the server; if the construction report is abnormal, analyzing an abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

The system sending module is used for analyzing and selecting a corresponding edge node according to the equipment scheduling scheme through the server and issuing the equipment scheduling scheme;

and the edge node scheduling module is used for generating equipment scheduling instructions according to the equipment scheduling schemes through the corresponding edge nodes and sending the equipment scheduling instructions to a first preset terminal.

According to the embodiment of the invention, one or more edge nodes are configured on each construction site, and the edge nodes are used for cleaning data and integrating data by collecting the use data of geotechnical engineering equipment bound with the edge nodes and the work report uploaded by constructors, and filtering useless data to obtain a construction report.

The server inputs the construction data in the received construction report to the construction progress curve in a numerical value or percentage mode, and judges whether the construction progress is within the construction plan range or not by comparing the construction progress with the construction plan, and if not, the server indicates that the construction progress is abnormal. The server processes abnormal conditions by applying for equipment scheduling, sends the generated equipment scheduling scheme to the corresponding edge node, adjusts the construction task of the edge node binding construction site by the edge server of the edge node, generates equipment scheduling instructions and sends the equipment scheduling instructions to the corresponding geotechnical engineering equipment terminal, namely the first preset terminal. In addition, the device scheduling method can be used for processing in the same cooperative scheduling mode for the case that the device scheduling cannot be performed. The device scheduling schemes comprise a common device scheduling scheme, an emergency scheduling scheme, a cooperative scheduling scheme, an idle device scheduling scheme and the like.

According to the embodiment of the invention, the server analyzes and judges whether the construction progress is abnormal according to the construction report, and the method comprises the following steps:

comparing the construction data with a construction plan, and judging whether the construction progress is abnormal or not;

if the abnormality exists, analyzing according to the abnormal construction data to obtain an abnormality reason; otherwise, filtering;

and sending the abnormal reason to a second preset terminal.

The construction method is characterized in that the construction method comprises the steps of performing field investigation before a construction task starts, and making a construction plan according to the investigation result, wherein the construction plan comprises a required geotechnical engineering equipment list, constructor distribution conditions, construction task arrangement and the like, and whether the construction progress is abnormal or not is judged by comparing construction data collected by edge nodes with the construction task arrangement in the construction plan, and when the progress difference of the construction data and the construction task arrangement is large, the construction progress is shown to be abnormal. Under the condition of abnormal construction progress, determining an abnormality reason by analyzing construction data uploaded by the edge nodes, wherein the abnormality reason comprises human factors, environmental factors and the like, and if the abnormality is caused by the human factors, the abnormality can be adjusted by replacing constructors; if the environment factors cause abnormality, such as unnoticed environmental conditions around the construction site, irregular measurement methods, complex geological environment of the construction site, large change and the like, the construction plan can be adjusted according to the current environment parameters, and the construction task can be completed within a specified time by adding equipment or replacing equipment. And simultaneously, the reasons and the adjustment modes of the abnormality are sent to a second preset terminal, wherein the second preset terminal can be a background display terminal, and the background display terminal is used for visual display.

According to an embodiment of the present invention, the generating a device scheduling scheme according to the construction report includes:

drawing a construction progress curve according to the construction report;

analyzing according to the construction progress curve to obtain the predicted completion time of the construction task;

judging whether the predicted completion time of the construction task is smaller than a first preset time or not;

if yes, no treatment is carried out;

if not, making a device scheduling scheme according to the implementation construction progress curve.

By collecting the construction report uploaded by each edge node, inputting construction data in the construction report into a construction progress curve in a numerical value or percentage format, displaying the construction progress in a visual mode, and then predicting the construction task of an unfinished part by the construction data of the finished part to obtain the predicted completion time of the construction task. And comparing the obtained predicted completion time of the construction task with a first preset time, and judging whether the current construction progress meets the expected engineering requirement. If yes, continuing to monitor; otherwise, analyzing according to the current construction progress and the construction tasks of the unfinished part to generate an equipment scheduling scheme, so that the construction efficiency of geotechnical engineering is ensured. The first preset time is geotechnical engineering completion time set in a construction plan. In addition, the server sends the generated construction progress curve to the corresponding edge node.

According to the embodiment of the invention, the equipment scheduling scheme is formulated according to the implementation construction progress curve, and the equipment scheduling scheme comprises the following steps:

analyzing according to the construction progress curve, and calculating the residual construction tasks to obtain the type information of the equipment to be scheduled;

generating a device scheduling application according to the device type information to be scheduled and uploading the device scheduling application to a server;

and the server inquires the callable time intervals of the devices of the same type bound by other edge nodes according to the device scheduling application, calculates the callable time intervals through a preset scheduling rule, and generates a device scheduling scheme.

The edge node analyzes the construction progress curve through the edge server, determines equipment type information required by the remaining construction tasks, compares geotechnical engineering equipment configured on a construction site, judges whether equipment scheduling is required, and if scheduling is required to be set, outputs the equipment type information required to be scheduled. The server issues scheduling equipment type query applications to other edge nodes according to the equipment scheduling applications, and the other edge nodes analyze according to equipment types in the scheduling equipment type query applications, determine callable time intervals of equipment of the same type and feed back the callable time intervals to the server. The server calculates through a preset scheduling rule to generate an equipment scheduling scheme, wherein the preset scheduling rule is specifically that scheduling parameters such as a geotechnical engineering equipment transportation method, transportation time, transportation cost and the like are calculated according to the relative distance between two scheduling places, the scheduling parameters are adjusted by combining user setting preferences (such as lowest cost, shortest time and the like), and the most suitable scheduling parameters are selected to generate the equipment scheduling scheme. And then the equipment scheduling scheme is sent to an auditing department, after the system or professional audits the equipment scheduling scheme, the equipment scheduling scheme is issued to a corresponding edge node, and the edge node generates an equipment scheduling instruction according to the equipment scheduling scheme and adds scheduling tasks to the corresponding equipment.

According to an embodiment of the present invention, further comprising:

acquiring equipment state data;

analyzing according to the equipment state data, and predicting the overhaul and maintenance time of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time;

and generating an equipment scheduling application according to the overhaul maintenance time.

When the edge node binds geotechnical engineering equipment, the normal working state data interval of the geotechnical engineering equipment is determined by reading the set parameters, whether the real-time equipment state data acquired by the edge node is in the normal working state data interval or not is analyzed, and equipment maintenance application is carried out if the real-time equipment state data acquired by the edge node is not in the normal working state data interval; and predicting the presence of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time. And then the edge node applies for equipment scheduling according to the obtained recommended maintenance time, so that the abnormal engineering construction progress caused by equipment maintenance is avoided. The equipment state data comprise equipment working duration time, working temperature, equipment rotating speed, vibration frequency and the like.

According to an embodiment of the present invention, further comprising:

analyzing according to the equipment scheduling application;

if the equipment scheduling application is an emergency scheduling application, the emergency scheduling application is sent to other edge nodes through a server;

The other edge nodes analyze the emergency dispatching application, adjust the working plan of the emergency dispatching equipment in a controllable range and judge whether the emergency dispatching application is met or not;

if yes, marking the edge node as a pending emergency dispatch node; otherwise, filtering;

after all other edge nodes are analyzed, the server selects an optimal emergency dispatching node from all undetermined emergency dispatching nodes according to a preset dispatching rule;

the server generates an emergency scheduling scheme and sends the emergency scheduling scheme to the optimal emergency scheduling node;

and the optimal emergency dispatching node generates an emergency dispatching instruction according to the emergency dispatching scheme and sends the emergency dispatching instruction to a first preset terminal.

It should be noted that, after receiving the equipment scheduling application sent by the edge node, the server determines the application type according to the content of the equipment scheduling application, if the application is an emergency scheduling application (such as the equipment scheduling application performed by the edge node under the condition that the equipment cannot work due to the equipment abnormality in the working process of the equipment), the server preferentially processes the application, sends the emergency scheduling application to other edge nodes, and the other edge nodes extract the data of the equipment type, the equipment model and the like of the equipment to be scheduled according to the emergency scheduling application, and judges whether the geotechnical engineering equipment of the same type exists in the equipment bound by the current edge node. If yes, adjusting a construction plan of a construction site where the current edge node is located according to the scheduling time in the emergency scheduling application, judging whether geotechnical engineering equipment of the same type can be scheduled at the scheduling time in the emergency scheduling application, and if not, filtering the current node; if yes, marking the current node as the undetermined emergency dispatching node, and feeding back to the server. And after all other edge nodes are analyzed, the server determines the optimal emergency dispatching node according to the preset dispatching rule of the system. The first preset terminal is an equipment terminal of geotechnical engineering equipment which needs scheduling of the equipment.

According to the embodiment of the invention, if the device scheduling scheme cannot be generated, the device scheduling is performed through a plurality of edge nodes by generating the coordinated scheduling scheme, including:

defining an edge node applying for equipment scheduling as a first node;

analyzing according to other edge nodes, and selecting a second node according to a preset scheduling rule;

selecting a plurality of undetermined third nodes between the first node and the second node;

analyzing according to the plurality of third nodes to be determined, respectively calculating the equipment scheduling time interval of each third node to be determined, calculating the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and defining the third nodes to be determined meeting the conditions as third nodes;

and generating a coordinated scheduling scheme through the server, scheduling the equipment of the third node to the first node, and scheduling the construction task distributed by the second node equipment to the third node after the construction task is completed.

When the device scheduling is performed, if all edge nodes bound with the server cannot meet the device scheduling application, the device scheduling can be performed in a mode of performing cooperative scheduling by the plurality of nodes. Firstly, according to the schedulable time of the equipment fed back by all other edge nodes, selecting an optimal edge node from all other edge nodes as a second node by combining a preset scheduling rule. And then respectively taking the first node and the second node as circle centers, selecting a plurality of edge nodes as undetermined third nodes according to a preset range (such as within 30 KM) of the system, respectively analyzing each undetermined third node, and determining a schedulable time interval for scheduling geotechnical engineering equipment and feeding back to a server under the condition of not affecting other construction tasks. The server calculates according to schedulable time intervals of the geotechnical engineering equipment needing to be scheduled fed back by all the third nodes to be scheduled and combining the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and selects the third nodes to be scheduled, which comprise the equipment application scheduling time of the first node and the earliest scheduling time of the second node, as the third nodes. The server generates a coordination scheduling scheme according to the first node, the second node and the third node and sends the coordination scheduling scheme to the first node, the second node and the third node respectively, and the first node, the second node and the third node respectively adjust the construction task arrangement according to the coordination scheduling scheme.

In addition, the cooperative scheduling scheme is not limited to the cooperative scheduling by three nodes, but can also perform the cooperative scheduling by more edge nodes.

According to an embodiment of the present invention, further comprising:

analyzing according to the equipment state data, and marking the equipment as idle equipment if the equipment does not work and does not have work task arrangement within a second preset time;

generating an idle equipment scheduling request according to the idle equipment and uploading the idle equipment scheduling request to a server;

the server sends the idle equipment scheduling request to other edge nodes;

the other edge nodes analyze the idle equipment scheduling request and judge whether equipment scheduling is needed or not;

if so, analyzing according to the construction progress to obtain a device scheduling time interval and uploading the device scheduling time interval to a server; otherwise, filtering;

and the server analyzes according to the equipment scheduling time intervals uploaded by the other edge nodes to generate idle equipment scheduling tasks.

When the idle equipment is scheduled, the server selects a plurality of edge nodes to analyze according to a system preset range by taking a construction site where the idle equipment is located as a circle center, and marks the edge nodes needing to be scheduled by the rock-soil equipment. The marked edge nodes analyze according to the bound construction tasks to obtain equipment scheduling time intervals and feed back the equipment scheduling time intervals to the server, the server analyzes according to the received equipment scheduling time intervals of all the marked edge nodes and judges whether the scheduling expense requirements are met, so that idle equipment scheduling tasks are formulated, the idle equipment scheduling tasks are sent to the corresponding edge nodes, and the corresponding edge nodes adjust the bound construction tasks according to the received idle equipment scheduling tasks. The second preset time is 48 hours, namely when the geotechnical engineering equipment does not perform construction work and does not have construction work task arrangement in 48 continuous hours, the current geotechnical engineering equipment is in an idle state, and idle equipment scheduling can be performed on the geotechnical engineering equipment.

The method for judging whether the scheduling cost requirement is met is specifically to analyze other edge nodes in a preset range (such as within 30 KM) of the system and respectively calculate whether the scheduling cost of each other edge node is lower than the corresponding highest scheduling cost. The highest dispatching expense is obtained by multiplying the dispatching expense factor set by the system by the working time of the geotechnical engineering equipment at the construction site corresponding to the edge node, and the dispatching expense factors of different types of geotechnical engineering equipment are different.

In addition, the edge nodes which are not of the same type of geotechnical engineering equipment as the idle equipment are preferentially selected when the idle equipment is scheduled.

A third aspect of the present invention provides a computer-readable storage medium, the computer-readable storage medium including therein a geotechnical engineering equipment interconnection schedule management method program, which when executed by a processor, implements the steps of a geotechnical engineering equipment interconnection schedule management method according to any one of the above.

The invention discloses a geotechnical engineering equipment interconnection scheduling management method, a geotechnical engineering equipment interconnection scheduling management system and a storage medium, wherein the method comprises the following steps: the edge node collects construction data to generate a construction report and sends the construction report to the server; the server analyzes and judges whether the construction progress is abnormal according to the construction report; if the abnormal condition exists, analyzing the abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme; the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme; and the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to the first preset terminal. According to the invention, the edge nodes are used for collecting and sorting construction data of a construction site, the auxiliary server is used for processing the data, and the construction task is adjusted according to the equipment scheduling scheme, so that the data processing efficiency is improved.

In the several embodiments provided by the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above described device embodiments are only illustrative, e.g. the division of the units is only one logical function division, and there may be other divisions in practice, such as: multiple units or components may be combined or may be integrated into another system, or some features may be omitted, or not performed. In addition, the various components shown or discussed may be coupled or directly coupled or communicatively coupled to each other via some interface, whether indirectly coupled or communicatively coupled to devices or units, whether electrically, mechanically, or otherwise.

The units described above as separate components may or may not be physically separate, and components shown as units may or may not be physical units; can be located in one place or distributed to a plurality of network units; some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated in one processing unit, or each unit may be separately used as one unit, or two or more units may be integrated in one unit; the integrated units may be implemented in hardware or in hardware plus software functional units.

Those of ordinary skill in the art will appreciate that: all or part of the steps for implementing the above method embodiments may be implemented by hardware related to program instructions, and the foregoing program may be stored in a computer readable storage medium, where the program, when executed, performs steps including the above method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk or an optical disk, or the like, which can store program codes.

Alternatively, the above-described integrated units of the present invention may be stored in a computer-readable storage medium if implemented in the form of software functional modules and sold or used as separate products. Based on such understanding, the technical solutions of the embodiments of the present invention may be embodied in essence or a part contributing to the prior art in the form of a software product stored in a storage medium, including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the methods described in the embodiments of the present invention. And the aforementioned storage medium includes: a removable storage device, ROM, RAM, magnetic or optical disk, or other medium capable of storing program code.

Claims (10)

1. The geotechnical engineering equipment interconnection scheduling management method is characterized by comprising the following steps of:

the edge node collects construction data to generate a construction report and sends the construction report to the server;

the server analyzes and judges whether the construction progress is abnormal according to the construction report;

if the construction report is abnormal, analyzing an abnormal reason, and generating a device scheduling scheme according to the construction report;

if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

the server analyzes and selects a corresponding edge node according to the equipment scheduling scheme and issues the equipment scheduling scheme;

and the corresponding edge node generates a device scheduling instruction according to the device scheduling scheme and sends the device scheduling instruction to a first preset terminal.

2. The geotechnical engineering equipment interconnection scheduling management method according to claim 1, wherein the server performs analysis according to the construction report to determine whether there is an abnormality in the construction progress, comprising:

comparing the construction data with a construction plan, and judging whether the construction progress is abnormal or not;

if the abnormality exists, analyzing according to the abnormal construction data to obtain an abnormality reason; otherwise, filtering;

And sending the abnormal reason to a second preset terminal.

3. The geotechnical engineering equipment interconnection scheduling management method according to claim 1, wherein the generating equipment scheduling scheme according to the construction report comprises:

drawing a construction progress curve according to the construction report;

analyzing according to the construction progress curve to obtain the predicted completion time of the construction task;

judging whether the predicted completion time of the construction task is smaller than a first preset time or not;

if yes, no treatment is carried out;

if not, making a device scheduling scheme according to the implementation construction progress curve.

4. The geotechnical engineering equipment interconnection scheduling management method according to claim 3, wherein the equipment scheduling scheme is formulated according to the implementation construction progress curve, and the method comprises the following steps:

analyzing according to the construction progress curve, and calculating the residual construction tasks to obtain the type information of the equipment to be scheduled;

generating a device scheduling application according to the device type information to be scheduled and uploading the device scheduling application to a server;

and the server inquires the callable time intervals of the devices of the same type bound by other edge nodes according to the device scheduling application, calculates the callable time intervals through a preset scheduling rule, and generates a device scheduling scheme.

5. The geotechnical engineering equipment interconnection scheduling management method according to claim 3, further comprising:

acquiring equipment state data;

analyzing according to the equipment state data, and predicting the overhaul and maintenance time of the equipment by combining the historical state data of the equipment to obtain recommended overhaul and maintenance time;

and generating an equipment scheduling application according to the overhaul maintenance time.

6. The geotechnical engineering equipment interconnection scheduling management method according to claim 3, further comprising:

analyzing according to the equipment scheduling application;

if the equipment scheduling application is an emergency scheduling application, the emergency scheduling application is sent to other edge nodes through a server;

the other edge nodes analyze the emergency dispatching application, adjust the working plan of the emergency dispatching equipment in a controllable range and judge whether the emergency dispatching application is met or not;

if yes, marking the edge node as a pending emergency dispatch node; otherwise, filtering;

after all other edge nodes are analyzed, the server selects an optimal emergency dispatching node from all undetermined emergency dispatching nodes according to a preset dispatching rule;

The server generates an emergency scheduling scheme and sends the emergency scheduling scheme to the optimal emergency scheduling node;

and the optimal emergency dispatching node generates an emergency dispatching instruction according to the emergency dispatching scheme and sends the emergency dispatching instruction to a first preset terminal.

7. The geotechnical engineering equipment interconnection scheduling management method according to claim 1, wherein if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme, comprises:

defining an edge node applying for equipment scheduling as a first node;

analyzing according to other edge nodes, and selecting a second node according to a preset scheduling rule;

selecting a plurality of undetermined third nodes between the first node and the second node;

analyzing according to the plurality of third nodes to be determined, respectively calculating the equipment scheduling time interval of each third node to be determined, calculating the equipment application scheduling time of the first node and the earliest scheduling time of the second node, and defining the third nodes to be determined meeting the conditions as third nodes;

and generating a coordinated scheduling scheme through the server, scheduling the equipment of the third node to the first node, and scheduling the construction task distributed by the second node equipment to the third node after the construction task is completed.

8. The geotechnical engineering equipment interconnection scheduling management method according to claim 5, further comprising:

analyzing according to the equipment state data, and marking the equipment as idle equipment if the equipment does not work and does not have work task arrangement within a second preset time;

generating an idle equipment scheduling request according to the idle equipment and uploading the idle equipment scheduling request to a server;

the server sends the idle equipment scheduling request to other edge nodes;

the other edge nodes analyze the idle equipment scheduling request and judge whether equipment scheduling is needed or not;

if so, analyzing according to the construction progress to obtain a device scheduling time interval and uploading the device scheduling time interval to a server; otherwise, filtering;

and the server analyzes according to the equipment scheduling time intervals uploaded by the other edge nodes to generate idle equipment scheduling tasks.

9. An geotechnical engineering equipment interconnection scheduling management system, which is characterized by comprising:

the edge node data processing module is used for collecting construction data through the edge node to generate a construction report and sending the construction report to the server;

the system analysis module is used for analyzing and judging whether the construction progress is abnormal or not according to the construction report through the server; if the construction report is abnormal, analyzing an abnormal reason, and generating a device scheduling scheme according to the construction report; if the equipment scheduling scheme cannot be generated, performing equipment scheduling through a plurality of edge nodes by generating a coordinated scheduling scheme;

The system sending module is used for analyzing and selecting a corresponding edge node according to the equipment scheduling scheme through the server and issuing the equipment scheduling scheme;

and the edge node scheduling module is used for generating equipment scheduling instructions according to the equipment scheduling schemes through the corresponding edge nodes and sending the equipment scheduling instructions to a first preset terminal.

10. A computer-readable storage medium, wherein the computer-readable storage medium includes a geotechnical engineering equipment interconnection schedule management method program, and when the geotechnical engineering equipment interconnection schedule management method program is executed by a processor, the steps of the geotechnical engineering equipment interconnection schedule management method according to any one of claims 1 to 8 are implemented.