CN116797179A - Monitoring system, method and readable storage medium for whole life cycle of building engineering - Google Patents

Abstract

The invention provides a monitoring system, a method and a readable storage medium for the whole life cycle of a building engineering, which belong to the technical field of engineering supervision, wherein the system comprises: the system comprises a task classification distribution module, a task management module, a quality supervision module, a security risk supervision module, a progress control module, a dispute tracking module, an environment protection supervision module and a technical difficulty module. According to the invention, each task in the project is associated for monitoring, the task, quality, safety risk, progress, environmental protection related to each task and technical difficulties related to each task are monitored in real time, and project manager can clearly monitor the conditions of each task through the system, discover the conditions in time and process the conditions in time. By the application of the system, each node of the engineering task and the condition of each node can be monitored in real time, so that the efficiency of engineering supervision and the treatment timeliness of the problems in the supervision process are improved.

Description

Monitoring system, method and readable storage medium for whole life cycle of building engineering

Technical Field

The invention belongs to the technical field of engineering supervision, and particularly relates to a system and a method for monitoring the whole life cycle of a building engineering and a readable storage medium.

Background

The project supervision refers to the commission of the supervision unit with relevant qualification by the first party, and represents a specialized service activity of monitoring the project construction of the second party by the first party according to the project task construction files approved by the country, laws and regulations related to the project construction, the project construction supervision contracts and other project construction contracts. Engineering supervision is a paid engineering consultation service; is entrusted by the first party; the main basis of supervision is laws, regulations, technical standards, related contracts and files; the supervision criteria are law conservation, integrity, fairness and science, the supervision aims to ensure the engineering construction quality and safety, improve the engineering construction level, fully exert the investment benefit and gradually deepen along with the reform of the national construction field and gradually perfect the building legislation, and the construction supervision system becomes a legal basic system in the engineering construction field of China, and the supervision of the position in the engineering construction is of importance.

The engineering supervision system provided by the related technology is used for constructing a special standard service event of the industry by utilizing a computer system based on the characteristics and standards of the software task research and development supervision industry and providing an information processing module aiming at a software task research and development enterprise around the standard service event. The project supervision system provided by the related system only aims at circulation and processing of information related to the project, can not comprehensively monitor and process activities related to the project, and is not beneficial to supervision personnel to conduct node supervision management on each task.

Disclosure of Invention

The invention aims to solve the technical problem that the existing engineering supervision information management in the background technology cannot provide monitoring and management of data in the supervision process, and is not beneficial to supervision personnel to conduct node supervision management on each task.

In order to solve the technical problems, the invention provides the following technical scheme:

a system for monitoring a full life cycle of a building project, the system comprising: the task classification distribution module comprises a task classification module and a task distribution module, wherein the task classification module is used for classifying engineering tasks according to engineering task attributes, and the task distribution module distributes the engineering tasks according to the classification;

the task management module is established in the task classification module and is associated with the task distribution module, and the task distribution module distributes engineering tasks to the task management module according to the classification of the engineering tasks; the task management module comprises a main task management module, a main task key point management module, a main task key section management module, a subtask key point management module and a subtask key section management module; each main task management module comprises at least one group of main task key section management modules, and each main task key section management module comprises at least one main task key point management module; each subtask management module comprises at least one group of subtask key segment management modules, and each subtask key segment management module comprises at least one subtask key point management module;

the quality monitoring modules are established in the task management modules, and each task management module is provided with a quality monitoring module which is associated with the task management module and used for monitoring the quality of each engineering task; the quality supervision module comprises a national quality standard module, a design quality standard module and a current task quality module;

the safety risk supervision module is associated with the quality supervision module and is used for monitoring risks in engineering tasks in the whole process; the safety risk supervision module comprises a risk type module, a risk level module, a risk prevention module, a risk processing module and a current risk processing progress module;

the progress control module comprises a main task progress control module, a main task key point progress control module, a main task key section progress control module, a subtask key point progress control module and a subtask key section progress control module; the progress control module is used for controlling and monitoring the progress of each engineering task under different time;

the dispute tracking module is established in the task management module and is used for tracking, recording, solving and feeding back various disputes generated in the engineering process; the dispute tracking module comprises a dispute type module, a dispute processing progress module, a dispute processing mode module, a dispute responsibility person module and a dispute processing result module;

the environment protection supervision module is used for monitoring and tracking the environment protection of the whole engineering process; the environment supervision module comprises an environment-friendly national standard module of each engineering task, an environment-friendly design module, an emergency management module aiming at different environment problems and an environment-friendly supervision module;

the technical difficulty module is used for integrating, summarizing and outputting the technical difficulty problems encountered by each task in different modules for technical staff to review and solve; the technical difficulty integrating module comprises a technical difficulty integrating module, an expert database inquiring module, an expert distributing module and a technical difficulty solving module.

In an alternative embodiment, the task classification module includes:

the hierarchy dividing module is used for dividing the supervision engineering task into preset hierarchies according to the supervision process;

the attribute giving module is used for giving different attributes to the engineering task of each level according to the preset level;

the dimension and query condition establishing module is used for establishing the query dimension and query condition of the engineering task according to the preset level and different attributes;

and the characteristic value typing module is used for typing the characteristic value for the engineering task according to the query dimension and the query condition of the engineering task.

In an alternative embodiment, the hierarchy dividing module is configured to:

dividing the engineering task into a longitudinal hierarchy and a transverse hierarchy according to the attribute, the content and the result of the engineering task, wherein the longitudinal hierarchy comprises a plurality of longitudinal sub-hierarchies, and the transverse hierarchy comprises a plurality of transverse sub-hierarchies;

the vertical sub-hierarchy is connected with the horizontal sub-hierarchy through a protocol.

In an alternative embodiment, the quality supervision module further comprises a quality comparison module;

the national quality standard module is used for acquiring task national quality standard parameters;

the design quality standard module is used for acquiring task design quality standard parameters;

the current task quality module is used for acquiring current quality parameters of the task;

the quality comparison module is used for comparing the national quality standard parameter, the design quality standard parameter and the current quality parameter of the task, and outputting the quality standard result of the task when the current quality parameter of the task simultaneously meets the national quality standard parameter and the design quality standard parameter.

In an alternative embodiment, the risk type module is configured to divide risk types for different tasks according to task types;

the risk level module is used for classifying risks according to classified risk types;

the risk prevention module is used for providing a risk prevention method and a solution according to the risk type and the risk level;

the risk processing module is used for acquiring the risk type and the risk grade of the current task risk and issuing a processing method or strategy according to the risk type and the risk grade;

the processing progress module of the current risk is used for monitoring the processing progress of the current risk, acquiring a processing method and a processing result of the current risk, and feeding back the processing progress, the processing method and the processing result to a user interface.

In an alternative embodiment, the progress control module further includes a timing module for timing each engineering task.

In an alternative embodiment, the environmental protection supervision module further comprises a current environmental protection parameter acquisition module, which is used for acquiring the current environmental protection parameters of the engineering task.

In an optional embodiment, the technical difficulty module is configured to integrate technical difficulties in each engineering task, and match the technical difficulties in each engineering task with the technical difficulties in the expert database to obtain a matching result;

and according to the matching result searching solution, outputting the technical difficulties which cannot be matched when the technical difficulties cannot be matched with the technical difficulties of the expert database, and allowing a supervisor to check and discuss.

In yet another aspect, a method for monitoring a full life cycle of a building engineering is provided, the method comprising:

the task classification module classifies engineering tasks according to engineering task attributes, and the task distribution module distributes the engineering tasks according to the classification;

distributing the engineering task to the task management module according to the classification of the engineering task;

the quality monitoring module monitors the quality of each engineering task;

the safety risk supervision module monitors risks in engineering tasks in the whole process;

the progress control module controls and monitors the progress of each task at different time;

the dispute tracking module is used for tracking, recording, solving and feeding back various disputes generated in the engineering process;

the environment protection supervision module monitors and tracks the environment protection of the whole engineering process;

the technical difficulty module integrates, gathers and outputs the technical difficulty problems encountered by each task in different modules for technical staff to review and solve.

In a further aspect, there is provided a readable storage medium having stored thereon computer instructions which when executed by a processor perform the steps of the method described above.

Compared with the prior art, the invention has at least the following beneficial effects:

the system provided by the embodiment of the invention is used for associating each task in the project, monitoring, and carrying out real-time monitoring on the task, quality, security risk, progress, environmental protection, disputes related to each task and technical difficulties related to each task, so that engineering supervision personnel can clearly monitor the conditions of each task through the system, discover the conditions in time and process the conditions in time. By the application of the system, each node of the engineering task and the condition of each node can be monitored in real time, so that the efficiency of engineering supervision and the treatment timeliness of the problems in the supervision process are improved.

Drawings

The accompanying drawings, which are incorporated herein and form a part of the specification, illustrate embodiments of the present disclosure and, together with the description, further serve to explain the principles of the disclosure and to enable a person skilled in the pertinent art to make and use the disclosure.

FIG. 1 is a schematic diagram of a monitoring system for the whole life cycle of the building engineering according to the present invention;

fig. 2 is a flow chart of a method for monitoring the whole life cycle of the building engineering.

Description of the embodiments

The following describes in detail a system, a method and a readable storage medium for monitoring the life cycle of a building engineering according to the present invention with reference to the accompanying drawings and specific embodiments. While the invention has been described herein in terms of the preferred and preferred embodiments, the following embodiments are intended to be more illustrative, and may be implemented in many alternative ways as will occur to those of skill in the art; and the accompanying drawings are only for the purpose of describing the embodiments more specifically and are not intended to limit the invention specifically.

It is noted that references in the specification to "one embodiment," "an example embodiment," "some embodiments," etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the relevant art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.

Generally, the terminology may be understood, at least in part, from the use of context. For example, the term "one or more" as used herein may be used to describe any feature, structure, or characteristic in a singular sense, or may be used to describe a combination of features, structures, or characteristics in a plural sense, depending at least in part on the context. In addition, the term "based on" may be understood as not necessarily intended to convey an exclusive set of factors, but may instead, depending at least in part on the context, allow for other factors that are not necessarily explicitly described.

As shown in fig. 1, an embodiment of the present invention provides a monitoring system for a full life cycle of a construction project, the system comprising: the system comprises a task classification distribution module 11, a task management module 12, a quality supervision module 13, a security risk supervision module 14, a progress control module 15, a dispute tracking module 16, an environment protection supervision module 17 and a technical difficulty module 18.

The task classification and distribution module 11 includes a task classification module and a task distribution module, where the task classification module is configured to classify the engineering task according to the engineering task attribute, and the task distribution module distributes the engineering task according to the classification.

The task management module 12 is built in a task classification module, and is associated with a task distribution module, which distributes engineering tasks to the task management module 12 according to the classification of the engineering tasks. The task management module 12 includes a main task management module 12, a main task key point management module, a main task key segment management module, a subtask management module 12, a subtask key point management module, and a subtask key segment management module. Each primary task management module 12 includes at least one set of primary task key segment management modules, and each primary task key segment management module includes at least one primary task key point management module. Each subtask management module 12 includes at least one set of subtask critical section management modules, each subtask critical section management module including at least one subtask critical point management module.

The quality supervision modules 13 are built in the task management modules 12, and one quality supervision module 13 is arranged in each task management module 12, and the quality supervision modules 13 are associated with the task management modules 12 and are used for supervising the quality of each engineering task. The quality supervision module 13 comprises a national quality standard module, a design quality standard module and a current task quality module.

The safety risk supervision module 14 is associated with the quality supervision module 13 and is used for monitoring risks in engineering tasks in the whole process; the security risk management module 14 includes a risk type module, a risk level module, a risk prevention module, a risk processing module, and a current risk processing progress module.

The progress control module 15 comprises a main task progress control module 15, a main task key point progress control module 15, a main task key section progress control module 15, a subtask key point progress control module 15 and a subtask key section progress control module 15; the progress control module 15 is used for controlling and monitoring the progress of each engineering task at different times.

The dispute tracking module 16 is built in the task management module 12 and is used for tracking, recording, solving and feeding back various disputes generated in the engineering process. The dispute tracking module 16 includes a dispute type module, a dispute handling progress module, a dispute handling mode module, a dispute liability person module, and a dispute handling result module.

The environment protection supervision module 17 is used for monitoring and tracking the environment protection of the whole engineering process; the environment supervision module comprises an environment-friendly national standard module of each engineering task, an environment-friendly design module, an emergency management module aiming at different environmental problems and an environment-friendly supervision module.

The technical difficulty module 18 is used for integrating, summarizing and outputting technical difficulty problems encountered by each task in different modules for technical staff to review and solve. The technical difficulty integrating module comprises a technical difficulty integrating module, an expert database inquiring module, an expert distributing module and a technical difficulty solving module.

The system provided by embodiments of the present invention will be further explained and described below by alternative embodiments.

In an alternative embodiment, the task classification module includes:

the hierarchy dividing module is used for dividing the supervision engineering task into preset hierarchies according to the supervision process;

the attribute giving module is used for giving different attributes to engineering tasks of each level according to preset levels;

the dimension and query condition establishing module is used for establishing query dimensions and query conditions of the engineering task according to a preset level and different attributes;

and the characteristic value typing module is used for typing characteristic values for the engineering task according to the query dimension and the query condition of the engineering task.

It should be noted that, based on the different engineering properties, engineering types and engineering results, there may be a great difference in engineering tasks that need to be monitored and managed in the engineering supervision process. The method and the device are convenient for engineering task management and supervision, and in the embodiment, the engineering tasks are divided into preset layers according to the supervision process according to engineering attributes, engineering contents and engineering results of engineering supervision, and the supervision engineering tasks are divided into the preset layers according to the supervision process, wherein the first layer comprises tasks in the preparation process of engineering construction, the second layer comprises tasks in the preliminary construction process of engineering, and the third layer comprises supporting facility construction tasks involved in the engineering construction process, such as safety protection engineering tasks and the like; the fourth level includes other tasks involved in the engineering construction process, such as environmental engineering tasks.

It can be understood that after the engineering tasks are classified, the engineering tasks of each level have different attributes, and the engineering tasks of different levels are given different attributes in turn, so that the user can check and manage conveniently.

And establishing the query dimension and the query condition of the engineering task according to the preset level and the different attributes. After classifying the engineering tasks, establishing query dimensions and query conditions of the engineering tasks according to preset layers and different attributes. Therefore, the user can inquire the engineering task in different dimensions according to the confidentiality type or importance degree of the engineering task, namely, different dimensions can represent different inquiry grades, and the different inquiry grades correspond to the confidentiality degree of the engineering task or the importance degree of the engineering task by the user. Further, the higher the confidentiality degree of the engineering task, the higher the query latitude, the more important the engineering task, the higher the dimension, and the higher the corresponding query condition.

And matching the characteristic values with query dimensions and query conditions of the engineering tasks to obtain matching results, typing the characteristic values for each engineering task according to the matching results, wherein the engineering tasks with different query dimensions and query conditions have at least one characteristic value, and each characteristic value is not repeated.

It can be understood that when a user queries, the user needs to input a certain characteristic value to query information or data, and the characteristic value provided by the embodiment of the invention includes but is not limited to keywords, special instructions and the like.

It can be understood that the feature values of the engineering task under different dimensions and query conditions are necessarily different, so that by matching the feature values with the query dimensions and query conditions of the engineering task, that is, each feature value corresponds to the engineering task with a specific dimension and a specific query condition, a corresponding matching result is obtained, the feature value is typed into each engineering task according to the matching result, the engineering task with different query dimensions and query conditions has at least one feature value, and each feature value is not repeated.

By setting the engineering task with different query dimensions and query conditions to have at least one characteristic value, and each characteristic value is not repeated, corresponding engineering task data can be ensured to be output instead of null values after each characteristic value is input.

In an alternative embodiment, the characteristic values include a main characteristic value and a sub-characteristic value, the data of the engineering task of one type has at least one main characteristic value and at least one sub-characteristic value, and the main characteristic value range is larger than the sub-characteristic value range;

the data of one engineering task is provided with a plurality of sub-characteristic values, and one main characteristic value corresponds to the data of a plurality of engineering tasks.

Further, the main feature value may be a keyword or a keyword code or a specific instruction or the like that expresses the content, attribute or result of the engineering task data. The sub-feature value can be a keyword or a keyword code or a specific instruction of engineering task data with different attributes under the engineering content.

The engineering task data has a plurality of sub-characteristic values, namely the same engineering task data can be detected through a plurality of different sub-characteristic values, and the data retrieval and supervision efficiency is improved. One main characteristic value corresponds to a plurality of engineering data, namely a plurality of engineering task data under a plurality of types of engineering data can be searched under one main characteristic value, and the searching range is further narrowed through sub-characteristic value searching, so that a progressive searching mode is formed.

In an alternative embodiment, the feature value entry module is configured to:

establishing at least one sub-characteristic value and at least one main characteristic value for the engineering task of the first query dimension, and establishing at least one sub-characteristic value and at least one main characteristic value for the engineering task of the second query dimension, wherein the at least one sub-characteristic value is associated with one main characteristic value;

the first query dimension query information range is less than the second query dimension query information range.

It should be noted that, the dimensions of the engineering task provided by the embodiment of the present invention may include multiple dimensions, and the higher the dimensions, the higher the query condition of the engineering task, that is, the more keywords need to be input to obtain information.

Further, establishing a sub-feature value and at least one main feature value for the engineering task of the first query dimension means that engineering task data of the first query dimension can be obtained through the related at least one sub-feature value and at least one main feature value, establishing at least one sub-feature value and at least one main feature value for the engineering task of the second query dimension with higher query dimension, and associating at least one sub-feature value with one main feature value, namely, obtaining the engineering task data of the query dimension only under the condition that the at least one sub-feature value is associated with one main feature value. The difficulty and the condition for inquiring engineering data in the second inquiry dimension are improved, and important data leakage is avoided.

In an alternative embodiment, the quality supervision module 13 further comprises a quality comparison module;

the national quality standard module is used for acquiring task national quality standard parameters;

the design quality standard module is used for acquiring task design quality standard parameters;

the current task quality module is used for acquiring current quality parameters of the task;

the quality comparison module is used for comparing the national quality standard parameter, the design quality standard parameter and the current quality parameter of the task, and outputting the quality standard result of the task when the current quality parameter of the task simultaneously meets the national quality standard parameter and the design quality standard parameter.

It should be noted that, the quality supervision module 13 provided in the embodiment of the present invention is associated with the main task management module 12, the main task key point management module, the main task key section management module, the subtask management module 12, the subtask key point management module and the subtask key section management module in the task management module 12, so as to perform quality supervision on each engineering task, ensure that each engineering task section and each engineering task key point are within the supervision range, and the supervision personnel can check the quality of each engineering task section and each engineering task key point in real time.

Further, the main task key point, the main task key section, the subtask key point and the subtask key section all have corresponding national quality standard parameter design quality standard parameters, and when the current quality parameters of the task simultaneously meet the national quality standard parameters and the design quality standard parameters, the quality standard reaching results of the task are output. And outputting a quality substandard result of the task when the current quality parameter of the task does not meet one of the national quality standard parameter and the design quality standard parameter.

As an example, in the embodiment of the present invention, the main task may be a main task in the present engineering project, for example, building construction in commercial building construction may be regarded as a main task, the main task key point may be a specific building floor or a construction stage of a specific floor in the building construction, the main task key section may be an entire construction stage of a specific floor in the building construction, the subtask may be a construction of an auxiliary facility in the building construction process, for example, a security fire setting, a construction of an environmental protection facility, etc., the subtask key point may be a key point of the construction of the auxiliary facility, for example, an overground fire facility or an underground fire facility in fire protection facility construction, and the subtask key section may be an entire process stage of the construction of the auxiliary facility, for example, an overground fire facility construction entire stage or an underground fire facility construction stage.

In an alternative embodiment, the risk type module is configured to divide risk types for different tasks according to task types;

the risk level module is used for classifying risks according to the classified risk types;

the risk prevention module is used for providing a risk prevention method and a solution according to the risk type and the risk level;

the risk processing module is used for acquiring the risk type and the risk grade of the current task risk and issuing a processing method or strategy according to the risk type and the risk grade;

the processing progress module of the current risk is used for monitoring the processing progress of the current risk, acquiring a processing method and a processing result of the current risk, and feeding back the processing progress, the processing method and the processing result to the user interface.

It can be understood that many risks are encountered in the fitness process of the engineering project, and the progress process of the engineering project is different, the types of risks and the sizes of risks are also different, so that the whole process of the engineering needs to be completely monitored in real time to ensure the construction safety. According to the embodiment of the invention, each stage and each task in the engineering task are supervised and followed in real time through the risk type module, so that the risk of the whole engineering is ensured to be controlled, and timely coping can be realized when the risk occurs.

Further, the risk type module divides risk types for different tasks according to task types, divides risks in different tasks, namely determines the types of risks in different tasks, namely determines the risk types of the main task, the main task key point, the main task key section, the subtask key point and the subtask key section according to the main task, the main task key point, the subtask key point and the subtask key section, and divides the risk into risk grades according to the divided risk types through the risk grade module; providing a risk prevention method and a solution according to the risk type and the risk level through a risk prevention module; the risk processing module obtains the risk type and the risk grade of the current task risk, and a processing method or strategy is provided according to the risk type and the risk grade; the processing progress module of the current risk is used for monitoring the processing progress of the current risk, acquiring a processing method and a processing result of the current risk, and feeding back the processing progress, the processing method and the processing result to the user interface. The risk of all tasks is monitored and processed in real time through the method, the risk results are summarized to form a risk history database, and when new risks occur, the risk history database can be compared with the risks in the risk history database to find out corresponding risk processing methods or processing modes and the like.

In an alternative embodiment, the progress control module 15 further includes a timing module for timing each engineering task.

Each engineering task can be timed through the timing module, when the current construction time exceeds the related construction time, the reasons need to be searched, the work is removed in time, and engineering delay is avoided.

The progress control module 15 comprises a main task progress control module 15, a main task key point progress control module 15, a main task key section progress control module 15, a subtask key point progress control module 15 and a subtask key section progress control module 15; the progress control module 15 is used for controlling and monitoring the progress of each engineering task at different times.

According to the embodiment of the invention, the progress control module 15 is arranged to monitor and manage the progress of each engineering task in real time, so that statistics and management are facilitated.

According to the embodiment of the invention, the dispute tracking module 16 is arranged, the dispute tracking module 16 is built in the task management module 12, and various disputes generated in the engineering process are tracked, recorded, solved and fed back; the dispute tracking module 16 includes a dispute type module, i.e., a classification storage for disputes generated in the project, for easy inspection by a supervisor. The dispute handling progress module records and feeds back the dispute progress related to each project, so that a supervision person can conveniently follow up the dispute handling progress in real time, and the dispute handling progress module can be used for rapidly intervening when a problem occurs in dispute handling or can be used for rapidly replacing a solution mode when dispute handling is improper, and the expansion of the disputes is avoided. The dispute handling mode module is used for recording and feeding back different engineering dispute handling modes, such as mediation or litigation. The dispute responsibility person module records and feeds back who the dispute responsibility person is, so that further follow-up and subsequent processing of the dispute are facilitated. The dispute handling result module can conveniently and quickly display dispute handling results, such as mediation or litigation, a mediation result or a litigation result and the like.

The environment protection supervision module 17 is used for monitoring and tracking the environment protection of the whole engineering process; the environment supervision module comprises an environment-friendly national standard module of each engineering task, an environment-friendly design module, an emergency management module aiming at different environment problems and an environment-friendly supervision module.

It will be appreciated that many environmental problems may occur during construction of the project, or that many environmental problems may need to be solved and addressed, so that the environmental protection of the entire process of the project is monitored and tracked by the environmental protection manager module 17 according to embodiments of the present invention. Optionally, the environmental protection proctoring module 17 further includes a current environmental protection parameter obtaining module, configured to obtain a current environmental protection parameter of the engineering task. The environment-friendly national standard module is used for comparing the current environment-friendly parameter with the environment-friendly national standard parameter, the environment-friendly design module is used for comparing the current environment-friendly parameter with the environment-friendly design standard parameter, and when the current environment-friendly parameter is the same as the environment-friendly national standard parameter and the environment-friendly design standard parameter, the environment-friendly passing result is output. When the current environmental protection parameter is different from the environmental protection national standard parameter and the environmental protection design standard parameter, the current environmental protection parameter is compared with the environmental protection national standard parameter and the current environmental protection parameter is compared with the environmental protection design standard parameter respectively, so that two comparison results are obtained. The emergency management module aiming at different environmental problems is used for outputting a response processing method and a response processing mode according to two comparison results, and the environment-friendly supervision module is used for supervising the engineering task after processing or rectifying in real time.

In an alternative embodiment, the technical difficulty module 18 is configured to integrate the technical difficulty in each engineering task, and match the technical difficulty in each engineering task with the technical difficulty of the expert database to obtain a matching result;

and according to the matching result searching solution, outputting the technical difficulties which cannot be matched when the technical difficulties cannot be matched with the technical difficulties of the expert database, and allowing a supervisor to check and discuss.

It can be understood that numerous technical difficulties are inevitably encountered in the whole engineering construction process, and the problems encountered at any time need to be analyzed and solved. According to the embodiment of the invention, the technical difficulties in each engineering task are integrated through the technical difficulty module 18, and the technical difficulties in each engineering task are matched with the technical difficulties of the expert database, so that a matching result is obtained; and according to the matching result searching solution, outputting the technical difficulties which cannot be matched when the technical difficulties cannot be matched with the technical difficulties of the expert database, and allowing a supervisor to check and discuss. The solution efficiency of the technical problem is improved, and the problem that the whole progress of the engineering is influenced due to the arrangement of the technical problem is avoided.

In another aspect, referring to fig. 2, there is provided a method of monitoring a full life cycle of a construction project, the method comprising:

s21, a task classification module classifies engineering tasks according to engineering task attributes, and a task distribution module distributes the engineering tasks according to the classification;

s22, distributing the engineering task to a task management module according to the classification of the engineering task;

s23, monitoring the quality of each engineering task by a quality monitoring module;

s24, a safety risk supervision module monitors risks in engineering tasks in the whole process;

s25, a progress control module controls and monitors the progress of each task at different times;

s26, carrying out tracking record, solving and feedback on various disputes generated in the engineering process by using a dispute tracking module;

s27, an environment protection supervision module monitors and tracks the environment protection of the whole engineering process;

and S28, integrating, summarizing and outputting the technical difficulties encountered by each task in different modules by using the technical difficulty module, so as to be referred and solved by technicians.

The method provided by the embodiment of the invention is used for associating each task in the project, monitoring, and carrying out real-time monitoring on the task, quality, security risk, progress, environmental protection, disputes related to each task and technical difficulties related to each task, so that engineering supervision personnel can clearly monitor the conditions of each task through the system, discover the conditions in time and process the conditions in time. By the application of the system, each node of the engineering task and the condition of each node can be monitored in real time, so that the efficiency of engineering supervision and the treatment timeliness of the problems in the supervision process are improved.

In yet another aspect, a computer readable storage medium is provided, the computer readable storage medium comprising a stored computer program, wherein the computer program when executed by a processor controls a device in which the storage medium resides to perform the above-described method.

The invention is intended to cover any alternatives, modifications, equivalents, and variations that fall within the spirit and scope of the invention. In the following description of preferred embodiments of the invention, specific details are set forth in order to provide a thorough understanding of the invention, and the invention will be fully understood to those skilled in the art without such details. In other instances, well-known methods, procedures, flows, components, circuits, and the like have not been described in detail so as not to unnecessarily obscure aspects of the present invention.

Those of ordinary skill in the art will appreciate that all or a portion of the steps in implementing the methods of the embodiments described above may be implemented by a program that instructs associated hardware, and the program may be stored on a computer readable storage medium, such as: ROM/RAM, magnetic disks, optical disks, etc.

The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention.

Claims (10)

1. A monitoring system for a full life cycle of a building project, the system comprising:

the task classification distribution module comprises a task classification module and a task distribution module, wherein the task classification module is used for classifying engineering tasks according to engineering task attributes, and the task distribution module distributes the engineering tasks according to the classification;

the task management module is established in the task classification module and is associated with the task distribution module, and the task distribution module distributes engineering tasks to the task management module according to the classification of the engineering tasks; the task management module comprises a main task management module, a main task key point management module, a main task key section management module, a subtask key point management module and a subtask key section management module; each main task management module comprises at least one group of main task key section management modules, and each main task key section management module comprises at least one main task key point management module; each subtask management module comprises at least one group of subtask key segment management modules, and each subtask key segment management module comprises at least one subtask key point management module;

the quality monitoring modules are established in the task management modules, and each task management module is provided with a quality monitoring module which is associated with the task management module and used for monitoring the quality of each engineering task; the quality supervision module comprises a national quality standard module, a design quality standard module and a current task quality module;

the safety risk supervision module is associated with the quality supervision module and is used for monitoring risks in engineering tasks in the whole process; the safety risk supervision module comprises a risk type module, a risk level module, a risk prevention module, a risk processing module and a current risk processing progress module;

the progress control module comprises a main task progress control module, a main task key point progress control module, a main task key section progress control module, a subtask key point progress control module and a subtask key section progress control module; the progress control module is used for controlling and monitoring the progress of each engineering task under different time;

the dispute tracking module is established in the task management module and is used for tracking, recording, solving and feeding back various disputes generated in the engineering process; the dispute tracking module comprises a dispute type module, a dispute processing progress module, a dispute processing mode module, a dispute responsibility person module and a dispute processing result module;

the environment protection supervision module is used for monitoring and tracking the environment protection of the whole engineering process; the environment supervision module comprises an environment-friendly national standard module of each engineering task, an environment-friendly design module, an emergency management module aiming at different environment problems and an environment-friendly supervision module;

the technical difficulty module is used for integrating, summarizing and outputting the technical difficulty problems encountered by each engineering task in different modules for technical staff to review and solve; the technical difficulty integrating module comprises a technical difficulty integrating module, an expert database inquiring module, an expert distributing module and a technical difficulty solving module.

2. The system for monitoring a full life cycle of a building project according to claim 1, wherein the task classification module comprises:

the hierarchy dividing module is used for dividing the supervision engineering task into preset hierarchies according to the supervision process;

the attribute giving module is used for giving different attributes to the engineering task of each level according to the preset level;

the dimension and query condition establishing module is used for establishing the query dimension and query condition of the engineering task according to the preset level and different attributes;

and the characteristic value typing module is used for typing the characteristic value for the engineering task according to the query dimension and the query condition of the engineering task.

3. The system for monitoring the entire life cycle of a building project according to claim 2, wherein the hierarchical dividing module is configured to:

dividing the engineering task into a longitudinal hierarchy and a transverse hierarchy according to the attribute, the content and the result of the engineering task, wherein the longitudinal hierarchy comprises a plurality of longitudinal sub-hierarchies, and the transverse hierarchy comprises a plurality of transverse sub-hierarchies;

the vertical sub-hierarchy is connected with the horizontal sub-hierarchy through a protocol.

4. The system of claim 1, wherein the quality supervision module further comprises a quality comparison module;

the national quality standard module is used for acquiring task national quality standard parameters;

the design quality standard module is used for acquiring task design quality standard parameters;

the current task quality module is used for acquiring current quality parameters of the task;

the quality comparison module is used for comparing the national quality standard parameter, the design quality standard parameter and the current quality parameter of the task, and outputting the quality standard result of the task when the current quality parameter of the task simultaneously meets the national quality standard parameter and the design quality standard parameter.

5. The system for monitoring the life cycle of a building engineering according to claim 1, wherein,

the risk type module is used for dividing risk types for different tasks according to task types;

the risk level module is used for classifying risks according to classified risk types;

the risk prevention module is used for providing a risk prevention method and a solution according to the risk type and the risk level;

the risk processing module is used for acquiring the risk type and the risk grade of the current task risk and issuing a processing method or strategy according to the risk type and the risk grade;

the processing progress module of the current risk is used for monitoring the processing progress of the current risk, acquiring a processing method and a processing result of the current risk, and feeding back the processing progress, the processing method and the processing result to a user interface.

6. The system of claim 1, wherein the progress control module further comprises a timing module for timing each engineering task.

7. The system of claim 1, further comprising a current environmental parameter acquisition module configured to acquire current environmental parameters of the engineering task.

8. The system for monitoring the whole life cycle of the building engineering according to claim 1, wherein the technical difficulty module is used for integrating technical difficulties in each engineering task, and matching the technical difficulties in each engineering task with the technical difficulties of the expert database to obtain a matching result;

and according to the matching result searching solution, outputting the technical difficulties which cannot be matched when the technical difficulties cannot be matched with the technical difficulties of the expert database, and allowing a supervisor to check and discuss.

9. A method for monitoring a full life cycle of a building engineering, the method comprising:

the task classification module classifies engineering tasks according to engineering task attributes, and the task distribution module distributes the engineering tasks according to the classification;

distributing the engineering task to the task management module according to the classification of the engineering task;

the quality monitoring module monitors the quality of each engineering task;

the safety risk supervision module monitors risks in engineering tasks in the whole process;

the progress control module controls and monitors the progress of each task at different time;

the dispute tracking module is used for tracking, recording, solving and feeding back various disputes generated in the engineering process;

the environment protection supervision module monitors and tracks the environment protection of the whole engineering process;

the technical difficulty module integrates, gathers and outputs the technical difficulty problems encountered by each task in different modules for technical staff to review and solve.

10. A computer readable storage medium, characterized in that the computer readable storage medium comprises a stored computer program, wherein the computer program, when run by a processor, controls a device in which the storage medium is located to perform the method of claim 9.